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/** @file */
#pragma once
using UINT8_t = unsigned char;
using UINT16_t = unsigned short;
using UINT32_t = unsigned int;
using UINT64_t = unsigned long long;
/**
* @defgroup intel_manual \
* Intel Manual
*
* @remarks All references are based on <b>Intel(R) 64 and IA-32 architectures software developer's manual combined volumes:
* 1, 2A, 2B, 2C, 2D, 3A, 3B, 3C, 3D, and 4</b> (May 2018).
* @{
*/
/**
* @defgroup control_registers \
* Control registers
*
* Control registers (CR0, CR1, CR2, CR3, and CR4) determine operating mode of the processor and the characteristics of the
* currently executing task. These registers are 32 bits in all 32-bit modes and compatibility mode.
* In 64-bit mode, control registers are expanded to 64 bits. The MOV CRn instructions are used to manipulate the register
* bits. Operand-size prefixes for these instructions are ignored. The following is also true:
* - The control registers can be read and loaded (or modified) using the move-to-or-from-control-registers forms of the
* MOV instruction. In protected mode, the MOV instructions allow the control registers to be read or loaded (at privilege
* level 0 only). This restriction means that application programs or operating-system procedures (running at privilege
* levels 1, 2, or 3) are prevented from reading or loading the control registers.
* - Bits 63:32 of CR0 and CR4 are reserved and must be written with zeros. Writing a nonzero value to any of the upper 32
* bits results in a general-protection exception, \#GP(0).
* - All 64 bits of CR2 are writable by software.
* - Bits 51:40 of CR3 are reserved and must be 0.
* - The MOV CRn instructions do not check that addresses written to CR2 and CR3 are within the linear-address or
* physical-address limitations of the implementation.
* - Register CR8 is available in 64-bit mode only. The control registers are summarized below, and each architecturally
* defined control field in these control registers is described individually.
* - CR0 - Contains system control flags that control operating mode and states of the processor.
* - CR1 - Reserved.
* - CR2 - Contains the page-fault linear address (the linear address that caused a page fault).
* - CR3 - Contains the physical address of the base of the paging-structure hierarchy and two flags (PCD and PWT). Only
* the most-significant bits (less the lower 12 bits) of the base address are specified; the lower 12 bits of the address
* are assumed to be 0. The first paging structure must thus be aligned to a page (4-KByte) boundary. The PCD and PWT flags
* control caching of that paging structure in the processor's internal data caches (they do not control TLB caching of
* page-directory information). When using the physical address extension, the CR3 register contains the base address of
* the page-directorypointer table. In IA-32e mode, the CR3 register contains the base address of the PML4 table.
* - CR4 - Contains a group of flags that enable several architectural extensions, and indicate operating system or
* executive support for specific processor capabilities.
* - CR8 - Provides read and write access to the Task Priority Register (TPR). It specifies the priority threshold value
* that operating systems use to control the priority class of external interrupts allowed to interrupt the processor. This
* register is available only in 64-bit mode. However, interrupt filtering continues to apply in compatibility mode.
*
* @see Vol3A[2.5(CONTROL REGISTERS)] (reference)
* @{
*/
typedef union
{
struct
{
/**
* @brief Protection Enable
*
* [Bit 0] Enables protected mode when set; enables real-address mode when clear. This flag does not enable paging
* directly. It only enables segment-level protection. To enable paging, both the PE and PG flags must be set.
*
* @see Vol3A[9.9(Mode Switching)]
*/
UINT64_t protection_enable : 1;
#define CR0_PROTECTION_ENABLE_BIT 0
#define CR0_PROTECTION_ENABLE_FLAG 0x01
#define CR0_PROTECTION_ENABLE_MASK 0x01
#define CR0_PROTECTION_ENABLE(_) (((_) >> 0) & 0x01)
/**
* @brief Monitor Coprocessor
*
* [Bit 1] Controls the interaction of the WAIT (or FWAIT) instruction with the TS flag (bit 3 of CR0). If the MP flag is
* set, a WAIT instruction generates a device-not-available exception (\#NM) if the TS flag is also set. If the MP flag is
* clear, the WAIT instruction ignores the setting of the TS flag.
*/
UINT64_t monitor_coprocessor : 1;
#define CR0_MONITOR_COPROCESSOR_BIT 1
#define CR0_MONITOR_COPROCESSOR_FLAG 0x02
#define CR0_MONITOR_COPROCESSOR_MASK 0x01
#define CR0_MONITOR_COPROCESSOR(_) (((_) >> 1) & 0x01)
/**
* @brief FPU Emulation
*
* [Bit 2] Indicates that the processor does not have an internal or external x87 FPU when set; indicates an x87 FPU is
* present when clear. This flag also affects the execution of MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instructions.
* When the EM flag is set, execution of an x87 FPU instruction generates a device-not-available exception (\#NM). This
* flag must be set when the processor does not have an internal x87 FPU or is not connected to an external math
* coprocessor. Setting this flag forces all floating-point instructions to be handled by software emulation.
* Also, when the EM flag is set, execution of an MMX instruction causes an invalid-opcode exception (\#UD) to be
* generated. Thus, if an IA-32 or Intel 64 processor incorporates MMX technology, the EM flag must be set to 0 to enable
* execution of MMX instructions. Similarly for SSE/SSE2/SSE3/SSSE3/SSE4 extensions, when the EM flag is set, execution of
* most SSE/SSE2/SSE3/SSSE3/SSE4 instructions causes an invalid opcode exception (\#UD) to be generated. If an IA-32 or
* Intel 64 processor incorporates the SSE/SSE2/SSE3/SSSE3/SSE4 extensions, the EM flag must be set to 0 to enable
* execution of these extensions. SSE/SSE2/SSE3/SSSE3/SSE4 instructions not affected by the EM flag include: PAUSE,
* PREFETCHh, SFENCE, LFENCE, MFENCE, MOVNTI, CLFLUSH, CRC32, and POPCNT.
*/
UINT64_t emulate_fpu : 1;
#define CR0_EMULATE_FPU_BIT 2
#define CR0_EMULATE_FPU_FLAG 0x04
#define CR0_EMULATE_FPU_MASK 0x01
#define CR0_EMULATE_FPU(_) (((_) >> 2) & 0x01)
/**
* @brief Task Switched
*
* [Bit 3] Allows the saving of the x87 FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 context on a task switch to be delayed until an
* x87 FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instruction is actually executed by the new task. The processor sets this flag on
* every task switch and tests it when executing x87 FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instructions.
* - If the TS flag is set and the EM flag (bit 2 of CR0) is clear, a device-not-available exception (\#NM) is raised prior
* to the execution of any x87 FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instruction; with the exception of PAUSE, PREFETCHh,
* SFENCE, LFENCE, MFENCE, MOVNTI, CLFLUSH, CRC32, and POPCNT.
* - If the TS flag is set and the MP flag (bit 1 of CR0) and EM flag are clear, an \#NM exception is not raised prior to
* the execution of an x87 FPU WAIT/FWAIT instruction.
* - If the EM flag is set, the setting of the TS flag has no effect on the execution of x87
* FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instructions.
* The processor does not automatically save the context of the x87 FPU, XMM, and MXCSR registers on a task switch.
* Instead, it sets the TS flag, which causes the processor to raise an \#NM exception whenever it encounters an x87
* FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instruction in the instruction stream for the new task (with the exception of the
* instructions listed above).
* The fault handler for the \#NM exception can then be used to clear the TS flag (with the CLTS instruction) and save
* the context of the x87 FPU, XMM, and MXCSR registers. If the task never encounters an x87
* FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 instruction, the x87 FPU/MMX/SSE/SSE2/SSE3/SSSE3/SSE4 context is never saved.
*/
UINT64_t task_switched : 1;
#define CR0_TASK_SWITCHED_BIT 3
#define CR0_TASK_SWITCHED_FLAG 0x08
#define CR0_TASK_SWITCHED_MASK 0x01
#define CR0_TASK_SWITCHED(_) (((_) >> 3) & 0x01)
/**
* @brief Extension Type
*
* [Bit 4] Reserved in the Pentium 4, Intel Xeon, P6 family, and Pentium processors. In the Pentium 4, Intel Xeon, and P6
* family processors, this flag is hardcoded to 1. In the Intel386 and Intel486 processors, this flag indicates support of
* Intel 387 DX math coprocessor instructions when set.
*/
UINT64_t extension_type : 1;
#define CR0_EXTENSION_TYPE_BIT 4
#define CR0_EXTENSION_TYPE_FLAG 0x10
#define CR0_EXTENSION_TYPE_MASK 0x01
#define CR0_EXTENSION_TYPE(_) (((_) >> 4) & 0x01)
/**
* @brief Numeric Error
*
* [Bit 5] Enables the native (internal) mechanism for reporting x87 FPU errors when set; enables the PC-style x87 FPU
* error reporting mechanism when clear. When the NE flag is clear and the IGNNE\# input is asserted, x87 FPU errors are
* ignored. When the NE flag is clear and the IGNNE\# input is deasserted, an unmasked x87 FPU error causes the processor
* to assert the FERR\# pin to generate an external interrupt and to stop instruction execution immediately before
* executing the next waiting floating-point instruction or WAIT/FWAIT instruction.
* The FERR\# pin is intended to drive an input to an external interrupt controller (the FERR\# pin emulates the ERROR\#
* pin of the Intel 287 and Intel 387 DX math coprocessors). The NE flag, IGNNE\# pin, and FERR\# pin are used with
* external logic to implement PC-style error reporting. Using FERR\# and IGNNE\# to handle floating-point exceptions is
* deprecated by modern operating systems; this non-native approach also limits newer processors to operate with one
* logical processor active.
*
* @see Vol1[8.7(Handling x87 FPU Exceptions in Software)]
* @see Vol1[A.1(APPENDIX A | EFLAGS Cross-Reference)]
*/
UINT64_t numeric_error : 1;
#define CR0_NUMERIC_ERROR_BIT 5
#define CR0_NUMERIC_ERROR_FLAG 0x20
#define CR0_NUMERIC_ERROR_MASK 0x01
#define CR0_NUMERIC_ERROR(_) (((_) >> 5) & 0x01)
UINT64_t reserved1 : 10;
/**
* @brief Write Protect
*
* [Bit 16] When set, inhibits supervisor-level procedures from writing into readonly pages; when clear, allows
* supervisor-level procedures to write into read-only pages (regardless of the U/S bit setting). This flag facilitates
* implementation of the copy-onwrite method of creating a new process (forking) used by operating systems such as UNIX.
*
* @see Vol3A[4.1.3(Paging-Mode Modifiers)]
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT64_t write_protect : 1;
#define CR0_WRITE_PROTECT_BIT 16
#define CR0_WRITE_PROTECT_FLAG 0x10000
#define CR0_WRITE_PROTECT_MASK 0x01
#define CR0_WRITE_PROTECT(_) (((_) >> 16) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief Alignment Mask
*
* [Bit 18] Enables automatic alignment checking when set; disables alignment checking when clear. Alignment checking is
* performed only when the AM flag is set, the AC flag in the EFLAGS register is set, CPL is 3, and the processor is
* operating in either protected or virtual-8086 mode.
*/
UINT64_t alignment_mask : 1;
#define CR0_ALIGNMENT_MASK_BIT 18
#define CR0_ALIGNMENT_MASK_FLAG 0x40000
#define CR0_ALIGNMENT_MASK_MASK 0x01
#define CR0_ALIGNMENT_MASK(_) (((_) >> 18) & 0x01)
UINT64_t reserved3 : 10;
/**
* @brief Not Write-through
*
* [Bit 29] When the NW and CD flags are clear, write-back (for Pentium 4, Intel Xeon, P6 family, and Pentium processors)
* or write-through (for Intel486 processors) is enabled for writes that hit the cache and invalidation cycles are enabled.
*/
UINT64_t not_write_through : 1;
#define CR0_NOT_WRITE_THROUGH_BIT 29
#define CR0_NOT_WRITE_THROUGH_FLAG 0x20000000
#define CR0_NOT_WRITE_THROUGH_MASK 0x01
#define CR0_NOT_WRITE_THROUGH(_) (((_) >> 29) & 0x01)
/**
* @brief Cache Disable
*
* [Bit 30] When the CD and NW flags are clear, caching of memory locations for the whole of physical memory in the
* processor's internal (and external) caches is enabled. When the CD flag is set, caching is restricted. To prevent the
* processor from accessing and updating its caches, the CD flag must be set and the caches must be invalidated so that no
* cache hits can occur.
*
* @see Vol3A[11.5.3(Preventing Caching)]
* @see Vol3A[11.5(CACHE CONTROL)]
*/
UINT64_t cache_disable : 1;
#define CR0_CACHE_DISABLE_BIT 30
#define CR0_CACHE_DISABLE_FLAG 0x40000000
#define CR0_CACHE_DISABLE_MASK 0x01
#define CR0_CACHE_DISABLE(_) (((_) >> 30) & 0x01)
/**
* @brief Paging Enable
*
* [Bit 31] Enables paging when set; disables paging when clear. When paging is disabled, all linear addresses are treated
* as physical addresses. The PG flag has no effect if the PE flag (bit 0 of register CR0) is not also set; setting the PG
* flag when the PE flag is clear causes a general-protection exception (\#GP).
* On Intel 64 processors, enabling and disabling IA-32e mode operation also requires modifying CR0.PG.
*
* @see Vol3A[4(PAGING)]
*/
UINT64_t paging_enable : 1;
#define CR0_PAGING_ENABLE_BIT 31
#define CR0_PAGING_ENABLE_FLAG 0x80000000
#define CR0_PAGING_ENABLE_MASK 0x01
#define CR0_PAGING_ENABLE(_) (((_) >> 31) & 0x01)
UINT64_t reserved4 : 32;
};
UINT64_t flags;
} cr0;
typedef union
{
struct
{
UINT64_t reserved1 : 3;
/**
* @brief Page-level Write-Through
*
* [Bit 3] Controls the memory type used to access the first paging structure of the current paging-structure hierarchy.
* This bit is not used if paging is disabled, with PAE paging, or with 4-level paging if CR4.PCIDE=1.
*
* @see Vol3A[4.9(PAGING AND MEMORY TYPING)]
*/
UINT64_t page_level_write_through : 1;
#define CR3_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define CR3_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define CR3_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define CR3_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* @brief Page-level Cache Disable
*
* [Bit 4] Controls the memory type used to access the first paging structure of the current paging-structure hierarchy.
* This bit is not used if paging is disabled, with PAE paging, or with 4-level paging2 if CR4.PCIDE=1.
*
* @see Vol3A[4.9(PAGING AND MEMORY TYPING)]
*/
UINT64_t page_level_cache_disable : 1;
#define CR3_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define CR3_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define CR3_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define CR3_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
UINT64_t reserved2 : 7;
/**
* @brief Address of page directory
*
* [Bits 47:12] Physical address of the 4-KByte aligned page directory (32-bit paging) or PML4 table (64-bit paging) used
* for linear-address translation.
*
* @see Vol3A[4.3(32-BIT PAGING)]
* @see Vol3A[4.5(4-LEVEL PAGING)]
*/
UINT64_t address_of_page_directory : 36;
#define CR3_ADDRESS_OF_PAGE_DIRECTORY_BIT 12
#define CR3_ADDRESS_OF_PAGE_DIRECTORY_FLAG 0xFFFFFFFFF000
#define CR3_ADDRESS_OF_PAGE_DIRECTORY_MASK 0xFFFFFFFFF
#define CR3_ADDRESS_OF_PAGE_DIRECTORY(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved3 : 16;
};
UINT64_t flags;
} cr3;
typedef union
{
struct
{
/**
* @brief Virtual-8086 Mode Extensions
*
* [Bit 0] Enables interrupt- and exception-handling extensions in virtual-8086 mode when set; disables the extensions when
* clear. Use of the virtual mode extensions can improve the performance of virtual-8086 applications by eliminating the
* overhead of calling the virtual- 8086 monitor to handle interrupts and exceptions that occur while executing an 8086
* program and, instead, redirecting the interrupts and exceptions back to the 8086 program's handlers. It also provides
* hardware support for a virtual interrupt flag (VIF) to improve reliability of running 8086 programs in multitasking and
* multiple-processor environments.
*
* @see Vol3B[20.3(INTERRUPT AND EXCEPTION HANDLING IN VIRTUAL-8086 MODE)]
*/
UINT64_t virtual_mode_extensions : 1;
#define CR4_VIRTUAL_MODE_EXTENSIONS_BIT 0
#define CR4_VIRTUAL_MODE_EXTENSIONS_FLAG 0x01
#define CR4_VIRTUAL_MODE_EXTENSIONS_MASK 0x01
#define CR4_VIRTUAL_MODE_EXTENSIONS(_) (((_) >> 0) & 0x01)
/**
* @brief Protected-Mode Virtual Interrupts
*
* [Bit 1] Enables hardware support for a virtual interrupt flag (VIF) in protected mode when set; disables the VIF flag in
* protected mode when clear.
*
* @see Vol3B[20.4(PROTECTED-MODE VIRTUAL INTERRUPTS)]
*/
UINT64_t protected_mode_virtual_interrupts : 1;
#define CR4_PROTECTED_MODE_VIRTUAL_INTERRUPTS_BIT 1
#define CR4_PROTECTED_MODE_VIRTUAL_INTERRUPTS_FLAG 0x02
#define CR4_PROTECTED_MODE_VIRTUAL_INTERRUPTS_MASK 0x01
#define CR4_PROTECTED_MODE_VIRTUAL_INTERRUPTS(_) (((_) >> 1) & 0x01)
/**
* @brief Time Stamp Disable
*
* [Bit 2] Restricts the execution of the RDTSC instruction to procedures running at privilege level 0 when set; allows
* RDTSC instruction to be executed at any privilege level when clear. This bit also applies to the RDTSCP instruction if
* supported (if CPUID.80000001H:EDX[27] = 1).
*/
UINT64_t timestamp_disable : 1;
#define CR4_TIMESTAMP_DISABLE_BIT 2
#define CR4_TIMESTAMP_DISABLE_FLAG 0x04
#define CR4_TIMESTAMP_DISABLE_MASK 0x01
#define CR4_TIMESTAMP_DISABLE(_) (((_) >> 2) & 0x01)
/**
* @brief Debugging Extensions
*
* [Bit 3] References to debug registers DR4 and DR5 cause an undefined opcode (\#UD) exception to be generated when set;
* when clear, processor aliases references to registers DR4 and DR5 for compatibility with software written to run on
* earlier IA-32 processors.
*
* @see Vol3B[17.2.2(Debug Registers DR4 and DR5)]
*/
UINT64_t debugging_extensions : 1;
#define CR4_DEBUGGING_EXTENSIONS_BIT 3
#define CR4_DEBUGGING_EXTENSIONS_FLAG 0x08
#define CR4_DEBUGGING_EXTENSIONS_MASK 0x01
#define CR4_DEBUGGING_EXTENSIONS(_) (((_) >> 3) & 0x01)
/**
* @brief Page Size Extensions
*
* [Bit 4] Enables 4-MByte pages with 32-bit paging when set; restricts 32-bit paging to pages of 4 KBytes when clear.
*
* @see Vol3A[4.3(32-BIT PAGING)]
*/
UINT64_t page_size_extensions : 1;
#define CR4_PAGE_SIZE_EXTENSIONS_BIT 4
#define CR4_PAGE_SIZE_EXTENSIONS_FLAG 0x10
#define CR4_PAGE_SIZE_EXTENSIONS_MASK 0x01
#define CR4_PAGE_SIZE_EXTENSIONS(_) (((_) >> 4) & 0x01)
/**
* @brief Physical Address Extension
*
* [Bit 5] When set, enables paging to produce physical addresses with more than 32 bits. When clear, restricts physical
* addresses to 32 bits. PAE must be set before entering IA-32e mode.
*
* @see Vol3A[4(PAGING)]
*/
UINT64_t physical_address_extension : 1;
#define CR4_PHYSICAL_ADDRESS_EXTENSION_BIT 5
#define CR4_PHYSICAL_ADDRESS_EXTENSION_FLAG 0x20
#define CR4_PHYSICAL_ADDRESS_EXTENSION_MASK 0x01
#define CR4_PHYSICAL_ADDRESS_EXTENSION(_) (((_) >> 5) & 0x01)
/**
* @brief Machine-Check Enable
*
* [Bit 6] Enables the machine-check exception when set; disables the machine-check exception when clear.
*
* @see Vol3B[15(MACHINE-CHECK ARCHITECTURE)]
*/
UINT64_t machine_check_enable : 1;
#define CR4_MACHINE_CHECK_ENABLE_BIT 6
#define CR4_MACHINE_CHECK_ENABLE_FLAG 0x40
#define CR4_MACHINE_CHECK_ENABLE_MASK 0x01
#define CR4_MACHINE_CHECK_ENABLE(_) (((_) >> 6) & 0x01)
/**
* @brief Page Global Enable
*
* [Bit 7] (Introduced in the P6 family processors.) Enables the global page feature when set; disables the global page
* feature when clear. The global page feature allows frequently used or shared pages to be marked as global to all users
* (done with the global flag, bit 8, in a page-directory or page-table entry). Global pages are not flushed from the
* translation-lookaside buffer (TLB) on a task switch or a write to register CR3. When enabling the global page feature,
* paging must be enabled (by setting the PG flag in control register CR0) before the PGE flag is set. Reversing this
* sequence may affect program correctness, and processor performance will be impacted.
*
* @see Vol3A[4.10(CACHING TRANSLATION INFORMATION)]
*/
UINT64_t page_global_enable : 1;
#define CR4_PAGE_GLOBAL_ENABLE_BIT 7
#define CR4_PAGE_GLOBAL_ENABLE_FLAG 0x80
#define CR4_PAGE_GLOBAL_ENABLE_MASK 0x01
#define CR4_PAGE_GLOBAL_ENABLE(_) (((_) >> 7) & 0x01)
/**
* @brief Performance-Monitoring Counter Enable
*
* [Bit 8] Enables execution of the RDPMC instruction for programs or procedures running at any protection level when set;
* RDPMC instruction can be executed only at protection level 0 when clear.
*/
UINT64_t performance_monitoring_counter_enable : 1;
#define CR4_PERFORMANCE_MONITORING_COUNTER_ENABLE_BIT 8
#define CR4_PERFORMANCE_MONITORING_COUNTER_ENABLE_FLAG 0x100
#define CR4_PERFORMANCE_MONITORING_COUNTER_ENABLE_MASK 0x01
#define CR4_PERFORMANCE_MONITORING_COUNTER_ENABLE(_) (((_) >> 8) & 0x01)
/**
* @brief Operating System Support for FXSAVE and FXRSTOR instructions
*
* [Bit 9] When set, this flag:
* -# indicates to software that the operating system supports the use of the FXSAVE and FXRSTOR instructions,
* -# enables the FXSAVE and FXRSTOR instructions to save and restore the contents of the XMM and MXCSR registers along
* with the contents of the x87 FPU and MMX registers, and
* -# enables the processor to execute SSE/SSE2/SSE3/SSSE3/SSE4 instructions, with the exception of the PAUSE, PREFETCHh,
* SFENCE, LFENCE, MFENCE, MOVNTI, CLFLUSH, CRC32, and POPCNT.
* If this flag is clear, the FXSAVE and FXRSTOR instructions will save and restore the contents of the x87 FPU and MMX
* registers, but they may not save and restore the contents of the XMM and MXCSR registers. Also, the processor will
* generate an invalid opcode exception (\#UD) if it attempts to execute any SSE/SSE2/SSE3 instruction, with the exception
* of PAUSE, PREFETCHh, SFENCE, LFENCE, MFENCE, MOVNTI, CLFLUSH, CRC32, and POPCNT. The operating system or executive must
* explicitly set this flag.
*
* @remarks CPUID feature flag FXSR indicates availability of the FXSAVE/FXRSTOR instructions. The OSFXSR bit provides
* operating system software with a means of enabling FXSAVE/FXRSTOR to save/restore the contents of the X87 FPU, XMM and
* MXCSR registers. Consequently OSFXSR bit indicates that the operating system provides context switch support for
* SSE/SSE2/SSE3/SSSE3/SSE4.
*/
UINT64_t os_fxsave_fxrstor_support : 1;
#define CR4_OS_FXSAVE_FXRSTOR_SUPPORT_BIT 9
#define CR4_OS_FXSAVE_FXRSTOR_SUPPORT_FLAG 0x200
#define CR4_OS_FXSAVE_FXRSTOR_SUPPORT_MASK 0x01
#define CR4_OS_FXSAVE_FXRSTOR_SUPPORT(_) (((_) >> 9) & 0x01)
/**
* @brief Operating System Support for Unmasked SIMD Floating-Point Exceptions
*
* [Bit 10] Operating System Support for Unmasked SIMD Floating-Point Exceptions - When set, indicates that the operating
* system supports the handling of unmasked SIMD floating-point exceptions through an exception handler that is invoked
* when a SIMD floating-point exception (\#XM) is generated. SIMD floating-point exceptions are only generated by
* SSE/SSE2/SSE3/SSE4.1 SIMD floatingpoint instructions.
* The operating system or executive must explicitly set this flag. If this flag is not set, the processor will generate an
* invalid opcode exception (\#UD) whenever it detects an unmasked SIMD floating-point exception.
*/
UINT64_t os_xmm_exception_support : 1;
#define CR4_OS_XMM_EXCEPTION_SUPPORT_BIT 10
#define CR4_OS_XMM_EXCEPTION_SUPPORT_FLAG 0x400
#define CR4_OS_XMM_EXCEPTION_SUPPORT_MASK 0x01
#define CR4_OS_XMM_EXCEPTION_SUPPORT(_) (((_) >> 10) & 0x01)
/**
* @brief User-Mode Instruction Prevention
*
* [Bit 11] When set, the following instructions cannot be executed if CPL > 0: SGDT, SIDT, SLDT, SMSW, and STR. An attempt
* at such execution causes a generalprotection exception (\#GP).
*/
UINT64_t usermode_instruction_prevention : 1;
#define CR4_USERMODE_INSTRUCTION_PREVENTION_BIT 11
#define CR4_USERMODE_INSTRUCTION_PREVENTION_FLAG 0x800
#define CR4_USERMODE_INSTRUCTION_PREVENTION_MASK 0x01
#define CR4_USERMODE_INSTRUCTION_PREVENTION(_) (((_) >> 11) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief VMX-Enable
*
* [Bit 13] Enables VMX operation when set.
*
* @see Vol3C[23(INTRODUCTION TO VIRTUAL MACHINE EXTENSIONS)]
*/
UINT64_t vmx_enable : 1;
#define CR4_VMX_ENABLE_BIT 13
#define CR4_VMX_ENABLE_FLAG 0x2000
#define CR4_VMX_ENABLE_MASK 0x01
#define CR4_VMX_ENABLE(_) (((_) >> 13) & 0x01)
/**
* @brief SMX-Enable
*
* [Bit 14] Enables SMX operation when set.
*
* @see Vol2[6(SAFER MODE EXTENSIONS REFERENCE)]
*/
UINT64_t smx_enable : 1;
#define CR4_SMX_ENABLE_BIT 14
#define CR4_SMX_ENABLE_FLAG 0x4000
#define CR4_SMX_ENABLE_MASK 0x01
#define CR4_SMX_ENABLE(_) (((_) >> 14) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief FSGSBASE-Enable
*
* [Bit 16] Enables the instructions RDFSBASE, RDGSBASE, WRFSBASE, and WRGSBASE.
*/
UINT64_t fsgsbase_enable : 1;
#define CR4_FSGSBASE_ENABLE_BIT 16
#define CR4_FSGSBASE_ENABLE_FLAG 0x10000
#define CR4_FSGSBASE_ENABLE_MASK 0x01
#define CR4_FSGSBASE_ENABLE(_) (((_) >> 16) & 0x01)
/**
* @brief PCID-Enable
*
* [Bit 17] Enables process-context identifiers (PCIDs) when set. Can be set only in IA-32e mode (if IA32_EFER.LMA = 1).
*
* @see Vol3A[4.10.1(Process-Context Identifiers (PCIDs))]
*/
UINT64_t pcid_enable : 1;
#define CR4_PCID_ENABLE_BIT 17
#define CR4_PCID_ENABLE_FLAG 0x20000
#define CR4_PCID_ENABLE_MASK 0x01
#define CR4_PCID_ENABLE(_) (((_) >> 17) & 0x01)
/**
* @brief XSAVE and Processor Extended States-Enable
*
* [Bit 18] When set, this flag:
* -# indicates (via CPUID.01H:ECX.OSXSAVE[bit 27]) that the operating system supports the use of the XGETBV, XSAVE and
* XRSTOR instructions by general software;
* -# enables the XSAVE and XRSTOR instructions to save and restore the x87 FPU state (including MMX registers), the SSE
* state (XMM registers and MXCSR), along with other processor extended states enabled in XCR0;
* -# enables the processor to execute XGETBV and XSETBV instructions in order to read and write XCR0.
*
* @see Vol3A[2.6(EXTENDED CONTROL REGISTERS (INCLUDING XCR0))]
* @see Vol3A[13(SYSTEM PROGRAMMING FOR INSTRUCTION SET EXTENSIONS AND PROCESSOR EXTENDED)]
*/
UINT64_t os_xsave : 1;
#define CR4_OS_XSAVE_BIT 18
#define CR4_OS_XSAVE_FLAG 0x40000
#define CR4_OS_XSAVE_MASK 0x01
#define CR4_OS_XSAVE(_) (((_) >> 18) & 0x01)
UINT64_t reserved3 : 1;
/**
* @brief SMEP-Enable
*
* [Bit 20] Enables supervisor-mode execution prevention (SMEP) when set.
*
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT64_t smep_enable : 1;
#define CR4_SMEP_ENABLE_BIT 20
#define CR4_SMEP_ENABLE_FLAG 0x100000
#define CR4_SMEP_ENABLE_MASK 0x01
#define CR4_SMEP_ENABLE(_) (((_) >> 20) & 0x01)
/**
* @brief SMAP-Enable
*
* [Bit 21] Enables supervisor-mode access prevention (SMAP) when set.
*
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT64_t smap_enable : 1;
#define CR4_SMAP_ENABLE_BIT 21
#define CR4_SMAP_ENABLE_FLAG 0x200000
#define CR4_SMAP_ENABLE_MASK 0x01
#define CR4_SMAP_ENABLE(_) (((_) >> 21) & 0x01)
/**
* @brief Protection-Key-Enable
*
* [Bit 22] Enables 4-level paging to associate each linear address with a protection key. The PKRU register specifies, for
* each protection key, whether user-mode linear addresses with that protection key can be read or written. This bit also
* enables access to the PKRU register using the RDPKRU and WRPKRU instructions.
*/
UINT64_t protection_key_enable : 1;
#define CR4_PROTECTION_KEY_ENABLE_BIT 22
#define CR4_PROTECTION_KEY_ENABLE_FLAG 0x400000
#define CR4_PROTECTION_KEY_ENABLE_MASK 0x01
#define CR4_PROTECTION_KEY_ENABLE(_) (((_) >> 22) & 0x01)
UINT64_t reserved4 : 41;
};
UINT64_t flags;
} cr4;
typedef union
{
struct
{
/**
* @brief Task Priority Level
*
* [Bits 3:0] This sets the threshold value corresponding to the highestpriority interrupt to be blocked. A value of 0
* means all interrupts are enabled. This field is available in 64- bit mode. A value of 15 means all interrupts will be
* disabled.
*/
UINT64_t task_priority_level : 4;
#define CR8_TASK_PRIORITY_LEVEL_BIT 0
#define CR8_TASK_PRIORITY_LEVEL_FLAG 0x0F
#define CR8_TASK_PRIORITY_LEVEL_MASK 0x0F
#define CR8_TASK_PRIORITY_LEVEL(_) (((_) >> 0) & 0x0F)
/**
* @brief Reserved
*
* [Bits 63:4] Reserved and must be written with zeros. Failure to do this causes a general-protection exception.
*/
UINT64_t reserved : 60;
#define CR8_RESERVED_BIT 4
#define CR8_RESERVED_FLAG 0xFFFFFFFFFFFFFFF0
#define CR8_RESERVED_MASK 0xFFFFFFFFFFFFFFF
#define CR8_RESERVED(_) (((_) >> 4) & 0xFFFFFFFFFFFFFFF)
};
UINT64_t flags;
} cr8;
/**
* @}
*/
/**
* @defgroup debug_registers \
* Debug registers
*
* Eight debug registers control the debug operation of the processor. These registers can be written to and read using the
* move to/from debug register form of the MOV instruction. A debug register may be the source or destination operand for
* one of these instructions.
* Debug registers are privileged resources; a MOV instruction that accesses these registers can only be executed in
* real-address mode, in SMM or in protected mode at a CPL of 0. An attempt to read or write the debug registers from any
* other privilege level generates a general-protection exception (\#GP). The primary function of the debug registers is to
* set up and monitor from 1 to 4 breakpoints, numbered 0 though 3. For each breakpoint, the following information can be
* specified:
* - The linear address where the breakpoint is to occur.
* - The length of the breakpoint location: 1, 2, 4, or 8 bytes.
* - The operation that must be performed at the address for a debug exception to be generated.
* - Whether the breakpoint is enabled.
* - Whether the breakpoint condition was present when the debug exception was generated.
*
* @see Vol3B[17.2.4(Debug Control Register (DR7))]
* @see Vol3B[17.2(DEBUG REGISTERS)] (reference)
* @{
*/
typedef union
{
struct
{
/**
* @brief B0 through B3 (breakpoint condition detected) flags
*
* [Bits 3:0] Indicates (when set) that its associated breakpoint condition was met when a debug exception was generated.
* These flags are set if the condition described for each breakpoint by the LENn, and R/Wn flags in debug control register
* DR7 is true. They may or may not be set if the breakpoint is not enabled by the Ln or the Gn flags in register DR7.
* Therefore on a \#DB, a debug handler should check only those B0-B3 bits which correspond to an enabled breakpoint.
*/
UINT64_t breakpoint_condition : 4;
#define DR6_BREAKPOINT_CONDITION_BIT 0
#define DR6_BREAKPOINT_CONDITION_FLAG 0x0F
#define DR6_BREAKPOINT_CONDITION_MASK 0x0F
#define DR6_BREAKPOINT_CONDITION(_) (((_) >> 0) & 0x0F)
UINT64_t reserved1 : 9;
/**
* @brief BD (debug register access detected) flag
*
* [Bit 13] Indicates that the next instruction in the instruction stream accesses one of the debug registers (DR0 through
* DR7). This flag is enabled when the GD (general detect) flag in debug control register DR7 is set.
*
* @see Vol3B[17.2.4(Debug Control Register (DR7))]
*/
UINT64_t debug_register_access_detected : 1;
#define DR6_DEBUG_REGISTER_ACCESS_DETECTED_BIT 13
#define DR6_DEBUG_REGISTER_ACCESS_DETECTED_FLAG 0x2000
#define DR6_DEBUG_REGISTER_ACCESS_DETECTED_MASK 0x01
#define DR6_DEBUG_REGISTER_ACCESS_DETECTED(_) (((_) >> 13) & 0x01)
/**
* @brief BS (single step) flag
*
* [Bit 14] Indicates (when set) that the debug exception was triggered by the singlestep execution mode (enabled with the
* TF flag in the EFLAGS register). The single-step mode is the highestpriority debug exception. When the BS flag is set,
* any of the other debug status bits also may be set.
*/
UINT64_t single_instruction : 1;
#define DR6_SINGLE_INSTRUCTION_BIT 14
#define DR6_SINGLE_INSTRUCTION_FLAG 0x4000
#define DR6_SINGLE_INSTRUCTION_MASK 0x01
#define DR6_SINGLE_INSTRUCTION(_) (((_) >> 14) & 0x01)
/**
* @brief BT (task switch) flag
*
* [Bit 15] Indicates (when set) that the debug exception was triggered by the singlestep execution mode (enabled with the
* TF flag in the EFLAGS register). The single-step mode is the highestpriority debug exception. When the BS flag is set,
* any of the other debug status bits also may be set.
*/
UINT64_t task_switch : 1;
#define DR6_TASK_SWITCH_BIT 15
#define DR6_TASK_SWITCH_FLAG 0x8000
#define DR6_TASK_SWITCH_MASK 0x01
#define DR6_TASK_SWITCH(_) (((_) >> 15) & 0x01)
/**
* @brief RTM (restricted transactional memory) flag
*
* [Bit 16] Indicates (when clear) that a debug exception (\#DB) or breakpoint exception (\#BP) occurred inside an RTM
* region while advanced debugging of RTM transactional regions was enabled. This bit is set for any other debug exception
* (including all those that occur when advanced debugging of RTM transactional regions is not enabled). This bit is always
* 1 if the processor does not support RTM.
*
* @see Vol3B[17.3.3(Debug Exceptions, Breakpoint Exceptions, and Restricted Transactional Memory (RTM))]
*/
UINT64_t restricted_transactional_memory : 1;
#define DR6_RESTRICTED_TRANSACTIONAL_MEMORY_BIT 16
#define DR6_RESTRICTED_TRANSACTIONAL_MEMORY_FLAG 0x10000
#define DR6_RESTRICTED_TRANSACTIONAL_MEMORY_MASK 0x01
#define DR6_RESTRICTED_TRANSACTIONAL_MEMORY(_) (((_) >> 16) & 0x01)
UINT64_t reserved2 : 47;
};
UINT64_t flags;
} dr6;
typedef union
{
struct
{
/**
* @brief L0 through L3 (local breakpoint enable) flags (bits 0, 2, 4, and 6)
*
* [Bit 0] Enables (when set) the breakpoint condition for the associated breakpoint for the current task. When a
* breakpoint condition is detected and its associated Ln flag is set, a debug exception is generated. The processor
* automatically clears these flags on every task switch to avoid unwanted breakpoint conditions in the new task.
*/
UINT64_t local_breakpoint_0 : 1;
#define DR7_LOCAL_BREAKPOINT_0_BIT 0
#define DR7_LOCAL_BREAKPOINT_0_FLAG 0x01
#define DR7_LOCAL_BREAKPOINT_0_MASK 0x01
#define DR7_LOCAL_BREAKPOINT_0(_) (((_) >> 0) & 0x01)
/**
* @brief G0 through G3 (global breakpoint enable) flags (bits 1, 3, 5, and 7)
*
* [Bit 1] Enables (when set) the breakpoint condition for the associated breakpoint for all tasks. When a breakpoint
* condition is detected and its associated Gn flag is set, a debug exception is generated. The processor does not clear
* these flags on a task switch, allowing a breakpoint to be enabled for all tasks.
*/
UINT64_t global_breakpoint_0 : 1;
#define DR7_GLOBAL_BREAKPOINT_0_BIT 1
#define DR7_GLOBAL_BREAKPOINT_0_FLAG 0x02
#define DR7_GLOBAL_BREAKPOINT_0_MASK 0x01
#define DR7_GLOBAL_BREAKPOINT_0(_) (((_) >> 1) & 0x01)
UINT64_t local_breakpoint_1 : 1;
#define DR7_LOCAL_BREAKPOINT_1_BIT 2
#define DR7_LOCAL_BREAKPOINT_1_FLAG 0x04
#define DR7_LOCAL_BREAKPOINT_1_MASK 0x01
#define DR7_LOCAL_BREAKPOINT_1(_) (((_) >> 2) & 0x01)
UINT64_t global_breakpoint_1 : 1;
#define DR7_GLOBAL_BREAKPOINT_1_BIT 3
#define DR7_GLOBAL_BREAKPOINT_1_FLAG 0x08
#define DR7_GLOBAL_BREAKPOINT_1_MASK 0x01
#define DR7_GLOBAL_BREAKPOINT_1(_) (((_) >> 3) & 0x01)
UINT64_t local_breakpoint_2 : 1;
#define DR7_LOCAL_BREAKPOINT_2_BIT 4
#define DR7_LOCAL_BREAKPOINT_2_FLAG 0x10
#define DR7_LOCAL_BREAKPOINT_2_MASK 0x01
#define DR7_LOCAL_BREAKPOINT_2(_) (((_) >> 4) & 0x01)
UINT64_t global_breakpoint_2 : 1;
#define DR7_GLOBAL_BREAKPOINT_2_BIT 5
#define DR7_GLOBAL_BREAKPOINT_2_FLAG 0x20
#define DR7_GLOBAL_BREAKPOINT_2_MASK 0x01
#define DR7_GLOBAL_BREAKPOINT_2(_) (((_) >> 5) & 0x01)
UINT64_t local_breakpoint_3 : 1;
#define DR7_LOCAL_BREAKPOINT_3_BIT 6
#define DR7_LOCAL_BREAKPOINT_3_FLAG 0x40
#define DR7_LOCAL_BREAKPOINT_3_MASK 0x01
#define DR7_LOCAL_BREAKPOINT_3(_) (((_) >> 6) & 0x01)
UINT64_t global_breakpoint_3 : 1;
#define DR7_GLOBAL_BREAKPOINT_3_BIT 7
#define DR7_GLOBAL_BREAKPOINT_3_FLAG 0x80
#define DR7_GLOBAL_BREAKPOINT_3_MASK 0x01
#define DR7_GLOBAL_BREAKPOINT_3(_) (((_) >> 7) & 0x01)
/**
* @brief LE (local exact breakpoint enable)
*
* [Bit 8] This feature is not supported in the P6 family processors, later IA-32 processors, and Intel 64 processors. When
* set, these flags cause the processor to detect the exact instruction that caused a data breakpoint condition. For
* backward and forward compatibility with other Intel processors, we recommend that the LE and GE flags be set to 1 if
* exact breakpoints are required.
*/
UINT64_t local_exact_breakpoint : 1;
#define DR7_LOCAL_EXACT_BREAKPOINT_BIT 8
#define DR7_LOCAL_EXACT_BREAKPOINT_FLAG 0x100
#define DR7_LOCAL_EXACT_BREAKPOINT_MASK 0x01
#define DR7_LOCAL_EXACT_BREAKPOINT(_) (((_) >> 8) & 0x01)
UINT64_t global_exact_breakpoint : 1;
#define DR7_GLOBAL_EXACT_BREAKPOINT_BIT 9
#define DR7_GLOBAL_EXACT_BREAKPOINT_FLAG 0x200
#define DR7_GLOBAL_EXACT_BREAKPOINT_MASK 0x01
#define DR7_GLOBAL_EXACT_BREAKPOINT(_) (((_) >> 9) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief RTM (restricted transactional memory) flag
*
* [Bit 11] Enables (when set) advanced debugging of RTM transactional regions. This advanced debugging is enabled only if
* IA32_DEBUGCTL.RTM is also set.
*
* @see Vol3B[17.3.3(Debug Exceptions, Breakpoint Exceptions, and Restricted Transactional Memory (RTM))]
*/
UINT64_t restricted_transactional_memory : 1;
#define DR7_RESTRICTED_TRANSACTIONAL_MEMORY_BIT 11
#define DR7_RESTRICTED_TRANSACTIONAL_MEMORY_FLAG 0x800
#define DR7_RESTRICTED_TRANSACTIONAL_MEMORY_MASK 0x01
#define DR7_RESTRICTED_TRANSACTIONAL_MEMORY(_) (((_) >> 11) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief GD (general detect enable) flag
*
* [Bit 13] Enables (when set) debug-register protection, which causes a debug exception to be generated prior to any MOV
* instruction that accesses a debug register. When such a condition is detected, the BD flag in debug status register DR6
* is set prior to generating the exception. This condition is provided to support in-circuit emulators.
* When the emulator needs to access the debug registers, emulator software can set the GD flag to prevent interference
* from the program currently executing on the processor.
* The processor clears the GD flag upon entering to the debug exception handler, to allow the handler access to the debug
* registers.
*/
UINT64_t general_detect : 1;
#define DR7_GENERAL_DETECT_BIT 13
#define DR7_GENERAL_DETECT_FLAG 0x2000
#define DR7_GENERAL_DETECT_MASK 0x01
#define DR7_GENERAL_DETECT(_) (((_) >> 13) & 0x01)
UINT64_t reserved3 : 2;
/**
* @brief R/W0 through R/W3 (read/write) fields (bits 16, 17, 20, 21, 24, 25, 28, and 29)
*
* [Bits 17:16] Specifies the breakpoint condition for the corresponding breakpoint. The DE (debug extensions) flag in
* control register CR4 determines how the bits in the R/Wn fields are interpreted. When the DE flag is set, the processor
* interprets bits as follows:
* - 00 - Break on instruction execution only.
* - 01 - Break on data writes only.
* - 10 - Break on I/O reads or writes.
* - 11 - Break on data reads or writes but not instruction fetches.
* When the DE flag is clear, the processor interprets the R/Wn bits the same as for the Intel386(TM) and Intel486(TM)
* processors, which is as follows:
* - 00 - Break on instruction execution only.
* - 01 - Break on data writes only.
* - 10 - Undefined.
* - 11 - Break on data reads or writes but not instruction fetches.
*/
UINT64_t read_write_0 : 2;
#define DR7_READ_WRITE_0_BIT 16
#define DR7_READ_WRITE_0_FLAG 0x30000
#define DR7_READ_WRITE_0_MASK 0x03
#define DR7_READ_WRITE_0(_) (((_) >> 16) & 0x03)
/**
* @brief LEN0 through LEN3 (Length) fields (bits 18, 19, 22, 23, 26, 27, 30, and 31)
*
* [Bits 19:18] Specify the size of the memory location at the address specified in the corresponding breakpoint address
* register (DR0 through DR3). These fields are interpreted as follows:
* - 00 - 1-byte length.
* - 01 - 2-byte length.
* - 10 - Undefined (or 8 byte length, see note below).
* - 11 - 4-byte length.
* If the corresponding RWn field in register DR7 is 00 (instruction execution), then the LENn field should also be 00. The
* effect of using other lengths is undefined.
*
* @see Vol3B[17.2.5(Breakpoint Field Recognition)]
*/
UINT64_t length_0 : 2;
#define DR7_LENGTH_0_BIT 18
#define DR7_LENGTH_0_FLAG 0xC0000
#define DR7_LENGTH_0_MASK 0x03
#define DR7_LENGTH_0(_) (((_) >> 18) & 0x03)
UINT64_t read_write_1 : 2;
#define DR7_READ_WRITE_1_BIT 20
#define DR7_READ_WRITE_1_FLAG 0x300000
#define DR7_READ_WRITE_1_MASK 0x03
#define DR7_READ_WRITE_1(_) (((_) >> 20) & 0x03)
UINT64_t length_1 : 2;
#define DR7_LENGTH_1_BIT 22
#define DR7_LENGTH_1_FLAG 0xC00000
#define DR7_LENGTH_1_MASK 0x03
#define DR7_LENGTH_1(_) (((_) >> 22) & 0x03)
UINT64_t read_write_2 : 2;
#define DR7_READ_WRITE_2_BIT 24
#define DR7_READ_WRITE_2_FLAG 0x3000000
#define DR7_READ_WRITE_2_MASK 0x03
#define DR7_READ_WRITE_2(_) (((_) >> 24) & 0x03)
UINT64_t length_2 : 2;
#define DR7_LENGTH_2_BIT 26
#define DR7_LENGTH_2_FLAG 0xC000000
#define DR7_LENGTH_2_MASK 0x03
#define DR7_LENGTH_2(_) (((_) >> 26) & 0x03)
UINT64_t read_write_3 : 2;
#define DR7_READ_WRITE_3_BIT 28
#define DR7_READ_WRITE_3_FLAG 0x30000000
#define DR7_READ_WRITE_3_MASK 0x03
#define DR7_READ_WRITE_3(_) (((_) >> 28) & 0x03)
UINT64_t length_3 : 2;
#define DR7_LENGTH_3_BIT 30
#define DR7_LENGTH_3_FLAG 0xC0000000
#define DR7_LENGTH_3_MASK 0x03
#define DR7_LENGTH_3(_) (((_) >> 30) & 0x03)
UINT64_t reserved4 : 32;
};
UINT64_t flags;
} dr7;
/**
* @}
*/
/**
* @defgroup cpuid \
* CPUID
*
* @see Vol2A[3.2(CPUID)] (reference)
* @{
*/
/**
* @brief Returns CPUID's Highest Value for Basic Processor Information and the Vendor Identification String
*
* When CPUID executes with EAX set to 0, the processor returns the highest value the CPUID recognizes for returning basic
* processor information. The value is returned in the EAX register and is processor specific.
* A vendor identification string is also returned in EBX, EDX, and ECX. For Intel processors, the string is "GenuineIntel"
* and is expressed:
* - EBX <- 756e6547h (* "Genu", with G in the low eight bits of BL *)
* - EDX <- 49656e69h (* "ineI", with i in the low eight bits of DL *)
* - ECX <- 6c65746eh (* "ntel", with n in the low eight bits of CL *)
*/
#define CPUID_SIGNATURE 0x00000000
typedef struct
{
/**
* @brief EAX
*
* Maximum Input Value for Basic CPUID Information.
*/
UINT32_t max_cpuid_input_value;
/**
* @brief EBX
*
* "Genu"
*/
UINT32_t ebx_value_genu;
/**
* @brief ECX
*
* "ntel"
*/
UINT32_t ecx_value_ntel;
/**
* @brief EDX
*
* "ineI"
*/
UINT32_t edx_value_inei;
} cpuid_eax_00;
/**
* @brief Returns Model, Family, Stepping Information, Additional Information and Feature Information
*
* Returns:
* * Model, Family, Stepping Information in EAX
* * Additional Information in EBX
* * Feature Information in ECX and EDX
*/
#define CPUID_VERSION_INFORMATION 0x00000001
typedef struct
{
/**
* @brief When CPUID executes with EAX set to 01H, version information is returned in EAX
*/
union
{
struct
{
UINT32_t stepping_id : 4;
#define CPUID_VERSION_INFORMATION_STEPPING_ID_BIT 0
#define CPUID_VERSION_INFORMATION_STEPPING_ID_FLAG 0x0F
#define CPUID_VERSION_INFORMATION_STEPPING_ID_MASK 0x0F
#define CPUID_VERSION_INFORMATION_STEPPING_ID(_) (((_) >> 0) & 0x0F)
UINT32_t model : 4;
#define CPUID_VERSION_INFORMATION_MODEL_BIT 4
#define CPUID_VERSION_INFORMATION_MODEL_FLAG 0xF0
#define CPUID_VERSION_INFORMATION_MODEL_MASK 0x0F
#define CPUID_VERSION_INFORMATION_MODEL(_) (((_) >> 4) & 0x0F)
UINT32_t family_id : 4;
#define CPUID_VERSION_INFORMATION_FAMILY_ID_BIT 8
#define CPUID_VERSION_INFORMATION_FAMILY_ID_FLAG 0xF00
#define CPUID_VERSION_INFORMATION_FAMILY_ID_MASK 0x0F
#define CPUID_VERSION_INFORMATION_FAMILY_ID(_) (((_) >> 8) & 0x0F)
/**
* [Bits 13:12] - 0 - Original OEM Processor
* - 1 - Intel OverDrive(R) Processor
* - 2 - Dual processor (not applicable to Intel486 processors)
* - 3 - Intel reserved
*/
UINT32_t processor_type : 2;
#define CPUID_VERSION_INFORMATION_PROCESSOR_TYPE_BIT 12
#define CPUID_VERSION_INFORMATION_PROCESSOR_TYPE_FLAG 0x3000
#define CPUID_VERSION_INFORMATION_PROCESSOR_TYPE_MASK 0x03
#define CPUID_VERSION_INFORMATION_PROCESSOR_TYPE(_) (((_) >> 12) & 0x03)
UINT32_t reserved1 : 2;
/**
* [Bits 19:16] The Extended Model ID needs to be examined only when the Family ID is 06H or 0FH.
*/
UINT32_t extended_model_id : 4;
#define CPUID_VERSION_INFORMATION_EXTENDED_MODEL_ID_BIT 16
#define CPUID_VERSION_INFORMATION_EXTENDED_MODEL_ID_FLAG 0xF0000
#define CPUID_VERSION_INFORMATION_EXTENDED_MODEL_ID_MASK 0x0F
#define CPUID_VERSION_INFORMATION_EXTENDED_MODEL_ID(_) (((_) >> 16) & 0x0F)
/**
* [Bits 27:20] The Extended Family ID needs to be examined only when the Family ID is 0FH.
*/
UINT32_t extended_family_id : 8;
#define CPUID_VERSION_INFORMATION_EXTENDED_FAMILY_ID_BIT 20
#define CPUID_VERSION_INFORMATION_EXTENDED_FAMILY_ID_FLAG 0xFF00000
#define CPUID_VERSION_INFORMATION_EXTENDED_FAMILY_ID_MASK 0xFF
#define CPUID_VERSION_INFORMATION_EXTENDED_FAMILY_ID(_) (((_) >> 20) & 0xFF)
UINT32_t reserved2 : 4;
};
UINT32_t flags;
} cpuid_version_information;
/**
* @brief When CPUID executes with EAX set to 01H, additional information is returned to the EBX register
*/
union
{
struct
{
/**
* [Bits 7:0] This number provides an entry into a brand string table that contains brand strings for IA-32 processors.
* More information about this field is provided later in this section.
*/
UINT32_t brand_index : 8;
#define CPUID_ADDITIONAL_INFORMATION_BRAND_INDEX_BIT 0
#define CPUID_ADDITIONAL_INFORMATION_BRAND_INDEX_FLAG 0xFF
#define CPUID_ADDITIONAL_INFORMATION_BRAND_INDEX_MASK 0xFF
#define CPUID_ADDITIONAL_INFORMATION_BRAND_INDEX(_) (((_) >> 0) & 0xFF)
/**
* @brief Value * 8 = cache line size in bytes; used also by CLFLUSHOPT
*
* [Bits 15:8] This number indicates the size of the cache line flushed by the CLFLUSH and CLFLUSHOPT instructions in
* 8-byte increments. This field was introduced in the Pentium 4 processor.
*/
UINT32_t clflush_line_size : 8;
#define CPUID_ADDITIONAL_INFORMATION_CLFLUSH_LINE_SIZE_BIT 8
#define CPUID_ADDITIONAL_INFORMATION_CLFLUSH_LINE_SIZE_FLAG 0xFF00
#define CPUID_ADDITIONAL_INFORMATION_CLFLUSH_LINE_SIZE_MASK 0xFF
#define CPUID_ADDITIONAL_INFORMATION_CLFLUSH_LINE_SIZE(_) (((_) >> 8) & 0xFF)
/**
* [Bits 23:16] Maximum number of addressable IDs for logical processors in this physical package.
*
* @remarks The nearest power-of-2 integer that is not smaller than EBX[23:16] is the number of unique initial APIC IDs
* reserved for addressing different logical processors in a physical package. This field is only valid if
* CPUID.1.EDX.HTT[bit 28] = 1.
*/
UINT32_t max_addressable_ids : 8;
#define CPUID_ADDITIONAL_INFORMATION_MAX_ADDRESSABLE_IDS_BIT 16
#define CPUID_ADDITIONAL_INFORMATION_MAX_ADDRESSABLE_IDS_FLAG 0xFF0000
#define CPUID_ADDITIONAL_INFORMATION_MAX_ADDRESSABLE_IDS_MASK 0xFF
#define CPUID_ADDITIONAL_INFORMATION_MAX_ADDRESSABLE_IDS(_) (((_) >> 16) & 0xFF)
/**
* [Bits 31:24] This number is the 8-bit ID that is assigned to the local APIC on the processor during power up. This field
* was introduced in the Pentium 4 processor.
*/
UINT32_t initial_apic_id : 8;
#define CPUID_ADDITIONAL_INFORMATION_INITIAL_APIC_ID_BIT 24
#define CPUID_ADDITIONAL_INFORMATION_INITIAL_APIC_ID_FLAG 0xFF000000
#define CPUID_ADDITIONAL_INFORMATION_INITIAL_APIC_ID_MASK 0xFF
#define CPUID_ADDITIONAL_INFORMATION_INITIAL_APIC_ID(_) (((_) >> 24) & 0xFF)
};
UINT32_t flags;
} cpuid_additional_information;
/**
* @brief When CPUID executes with EAX set to 01H, feature information is returned in ECX and EDX
*/
union
{
struct
{
/**
* @brief Streaming SIMD Extensions 3 (SSE3)
*
* [Bit 0] A value of 1 indicates the processor supports this technology.
*/
UINT32_t streaming_simd_extensions_3 : 1;
#define CPUID_FEATURE_INFORMATION_ECX_STREAMING_SIMD_EXTENSIONS_3_BIT 0
#define CPUID_FEATURE_INFORMATION_ECX_STREAMING_SIMD_EXTENSIONS_3_FLAG 0x01
#define CPUID_FEATURE_INFORMATION_ECX_STREAMING_SIMD_EXTENSIONS_3_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_STREAMING_SIMD_EXTENSIONS_3(_) (((_) >> 0) & 0x01)
/**
* @brief PCLMULQDQ instruction
*
* [Bit 1] A value of 1 indicates the processor supports the PCLMULQDQ instruction.
*/
UINT32_t pclmulqdq_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_PCLMULQDQ_INSTRUCTION_BIT 1
#define CPUID_FEATURE_INFORMATION_ECX_PCLMULQDQ_INSTRUCTION_FLAG 0x02
#define CPUID_FEATURE_INFORMATION_ECX_PCLMULQDQ_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_PCLMULQDQ_INSTRUCTION(_) (((_) >> 1) & 0x01)
/**
* @brief 64-bit DS Area
*
* [Bit 2] A value of 1 indicates the processor supports DS area using 64-bit layout.
*/
UINT32_t ds_area_64bit_layout : 1;
#define CPUID_FEATURE_INFORMATION_ECX_DS_AREA_64BIT_LAYOUT_BIT 2
#define CPUID_FEATURE_INFORMATION_ECX_DS_AREA_64BIT_LAYOUT_FLAG 0x04
#define CPUID_FEATURE_INFORMATION_ECX_DS_AREA_64BIT_LAYOUT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_DS_AREA_64BIT_LAYOUT(_) (((_) >> 2) & 0x01)
/**
* @brief MONITOR/MWAIT instruction
*
* [Bit 3] A value of 1 indicates the processor supports this feature.
*/
UINT32_t monitor_mwait_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_MONITOR_MWAIT_INSTRUCTION_BIT 3
#define CPUID_FEATURE_INFORMATION_ECX_MONITOR_MWAIT_INSTRUCTION_FLAG 0x08
#define CPUID_FEATURE_INFORMATION_ECX_MONITOR_MWAIT_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_MONITOR_MWAIT_INSTRUCTION(_) (((_) >> 3) & 0x01)
/**
* @brief CPL Qualified Debug Store
*
* [Bit 4] A value of 1 indicates the processor supports the extensions to the Debug Store feature to allow for branch
* message storage qualified by CPL.
*/
UINT32_t cpl_qualified_debug_store : 1;
#define CPUID_FEATURE_INFORMATION_ECX_CPL_QUALIFIED_DEBUG_STORE_BIT 4
#define CPUID_FEATURE_INFORMATION_ECX_CPL_QUALIFIED_DEBUG_STORE_FLAG 0x10
#define CPUID_FEATURE_INFORMATION_ECX_CPL_QUALIFIED_DEBUG_STORE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_CPL_QUALIFIED_DEBUG_STORE(_) (((_) >> 4) & 0x01)
/**
* @brief Virtual Machine Extensions
*
* [Bit 5] A value of 1 indicates that the processor supports this technology.
*/
UINT32_t virtual_machine_extensions : 1;
#define CPUID_FEATURE_INFORMATION_ECX_VIRTUAL_MACHINE_EXTENSIONS_BIT 5
#define CPUID_FEATURE_INFORMATION_ECX_VIRTUAL_MACHINE_EXTENSIONS_FLAG 0x20
#define CPUID_FEATURE_INFORMATION_ECX_VIRTUAL_MACHINE_EXTENSIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_VIRTUAL_MACHINE_EXTENSIONS(_) (((_) >> 5) & 0x01)
/**
* @brief Safer Mode Extensions
*
* [Bit 6] A value of 1 indicates that the processor supports this technology.
*
* @see Vol2[6(SAFER MODE EXTENSIONS REFERENCE)]
*/
UINT32_t safer_mode_extensions : 1;
#define CPUID_FEATURE_INFORMATION_ECX_SAFER_MODE_EXTENSIONS_BIT 6
#define CPUID_FEATURE_INFORMATION_ECX_SAFER_MODE_EXTENSIONS_FLAG 0x40
#define CPUID_FEATURE_INFORMATION_ECX_SAFER_MODE_EXTENSIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_SAFER_MODE_EXTENSIONS(_) (((_) >> 6) & 0x01)
/**
* @brief Enhanced Intel SpeedStep(R) technology
*
* [Bit 7] A value of 1 indicates that the processor supports this technology.
*/
UINT32_t enhanced_intel_speedstep_technology : 1;
#define CPUID_FEATURE_INFORMATION_ECX_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_BIT 7
#define CPUID_FEATURE_INFORMATION_ECX_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_FLAG 0x80
#define CPUID_FEATURE_INFORMATION_ECX_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY(_) (((_) >> 7) & 0x01)
/**
* @brief Thermal Monitor 2
*
* [Bit 8] A value of 1 indicates whether the processor supports this technology.
*/
UINT32_t thermal_monitor_2 : 1;
#define CPUID_FEATURE_INFORMATION_ECX_THERMAL_MONITOR_2_BIT 8
#define CPUID_FEATURE_INFORMATION_ECX_THERMAL_MONITOR_2_FLAG 0x100
#define CPUID_FEATURE_INFORMATION_ECX_THERMAL_MONITOR_2_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_THERMAL_MONITOR_2(_) (((_) >> 8) & 0x01)
/**
* @brief Supplemental Streaming SIMD Extensions 3 (SSSE3)
*
* [Bit 9] A value of 1 indicates the presence of the Supplemental Streaming SIMD Extensions 3 (SSSE3). A value of 0
* indicates the instruction extensions are not present in the processor.
*/
UINT32_t supplemental_streaming_simd_extensions_3 : 1;
#define CPUID_FEATURE_INFORMATION_ECX_SUPPLEMENTAL_STREAMING_SIMD_EXTENSIONS_3_BIT 9
#define CPUID_FEATURE_INFORMATION_ECX_SUPPLEMENTAL_STREAMING_SIMD_EXTENSIONS_3_FLAG 0x200
#define CPUID_FEATURE_INFORMATION_ECX_SUPPLEMENTAL_STREAMING_SIMD_EXTENSIONS_3_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_SUPPLEMENTAL_STREAMING_SIMD_EXTENSIONS_3(_) (((_) >> 9) & 0x01)
/**
* @brief L1 Context ID
*
* [Bit 10] A value of 1 indicates the L1 data cache mode can be set to either adaptive mode or shared mode. A value of 0
* indicates this feature is not supported. See definition of the IA32_MISC_ENABLE MSR Bit 24 (L1 Data Cache Context Mode)
* for details.
*/
UINT32_t l1_context_id : 1;
#define CPUID_FEATURE_INFORMATION_ECX_L1_CONTEXT_ID_BIT 10
#define CPUID_FEATURE_INFORMATION_ECX_L1_CONTEXT_ID_FLAG 0x400
#define CPUID_FEATURE_INFORMATION_ECX_L1_CONTEXT_ID_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_L1_CONTEXT_ID(_) (((_) >> 10) & 0x01)
/**
* @brief IA32_DEBUG_INTERFACE MSR for silicon debug
*
* [Bit 11] A value of 1 indicates the processor supports IA32_DEBUG_INTERFACE MSR for silicon debug.
*/
UINT32_t silicon_debug : 1;
#define CPUID_FEATURE_INFORMATION_ECX_SILICON_DEBUG_BIT 11
#define CPUID_FEATURE_INFORMATION_ECX_SILICON_DEBUG_FLAG 0x800
#define CPUID_FEATURE_INFORMATION_ECX_SILICON_DEBUG_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_SILICON_DEBUG(_) (((_) >> 11) & 0x01)
/**
* @brief FMA extensions using YMM state
*
* [Bit 12] A value of 1 indicates the processor supports FMA (Fused Multiple Add) extensions using YMM state.
*/
UINT32_t fma_extensions : 1;
#define CPUID_FEATURE_INFORMATION_ECX_FMA_EXTENSIONS_BIT 12
#define CPUID_FEATURE_INFORMATION_ECX_FMA_EXTENSIONS_FLAG 0x1000
#define CPUID_FEATURE_INFORMATION_ECX_FMA_EXTENSIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_FMA_EXTENSIONS(_) (((_) >> 12) & 0x01)
/**
* @brief CMPXCHG16B instruction
*
* [Bit 13] A value of 1 indicates that the feature is available.
*/
UINT32_t cmpxchg16b_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_CMPXCHG16B_INSTRUCTION_BIT 13
#define CPUID_FEATURE_INFORMATION_ECX_CMPXCHG16B_INSTRUCTION_FLAG 0x2000
#define CPUID_FEATURE_INFORMATION_ECX_CMPXCHG16B_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_CMPXCHG16B_INSTRUCTION(_) (((_) >> 13) & 0x01)
/**
* @brief xTPR Update Control
*
* [Bit 14] A value of 1 indicates that the processor supports changing IA32_MISC_ENABLE[bit 23].
*/
UINT32_t xtpr_update_control : 1;
#define CPUID_FEATURE_INFORMATION_ECX_XTPR_UPDATE_CONTROL_BIT 14
#define CPUID_FEATURE_INFORMATION_ECX_XTPR_UPDATE_CONTROL_FLAG 0x4000
#define CPUID_FEATURE_INFORMATION_ECX_XTPR_UPDATE_CONTROL_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_XTPR_UPDATE_CONTROL(_) (((_) >> 14) & 0x01)
/**
* @brief Perfmon and Debug Capability
*
* [Bit 15] A value of 1 indicates the processor supports the performance and debug feature indication MSR
* IA32_PERF_CAPABILITIES.
*/
UINT32_t perfmon_and_debug_capability : 1;
#define CPUID_FEATURE_INFORMATION_ECX_PERFMON_AND_DEBUG_CAPABILITY_BIT 15
#define CPUID_FEATURE_INFORMATION_ECX_PERFMON_AND_DEBUG_CAPABILITY_FLAG 0x8000
#define CPUID_FEATURE_INFORMATION_ECX_PERFMON_AND_DEBUG_CAPABILITY_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_PERFMON_AND_DEBUG_CAPABILITY(_) (((_) >> 15) & 0x01)
UINT32_t reserved1 : 1;
/**
* @brief Process-context identifiers
*
* [Bit 17] A value of 1 indicates that the processor supports PCIDs and that software may set CR4.PCIDE to 1.
*/
UINT32_t process_context_identifiers : 1;
#define CPUID_FEATURE_INFORMATION_ECX_PROCESS_CONTEXT_IDENTIFIERS_BIT 17
#define CPUID_FEATURE_INFORMATION_ECX_PROCESS_CONTEXT_IDENTIFIERS_FLAG 0x20000
#define CPUID_FEATURE_INFORMATION_ECX_PROCESS_CONTEXT_IDENTIFIERS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_PROCESS_CONTEXT_IDENTIFIERS(_) (((_) >> 17) & 0x01)
/**
* @brief Direct Cache Access
*
* [Bit 18] A value of 1 indicates the processor supports the ability to prefetch data from a memory mapped device (Direct
* Cache Access).
*/
UINT32_t direct_cache_access : 1;
#define CPUID_FEATURE_INFORMATION_ECX_DIRECT_CACHE_ACCESS_BIT 18
#define CPUID_FEATURE_INFORMATION_ECX_DIRECT_CACHE_ACCESS_FLAG 0x40000
#define CPUID_FEATURE_INFORMATION_ECX_DIRECT_CACHE_ACCESS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_DIRECT_CACHE_ACCESS(_) (((_) >> 18) & 0x01)
/**
* @brief SSE4.1 support
*
* [Bit 19] A value of 1 indicates that the processor supports SSE4.1.
*/
UINT32_t sse41_support : 1;
#define CPUID_FEATURE_INFORMATION_ECX_SSE41_SUPPORT_BIT 19
#define CPUID_FEATURE_INFORMATION_ECX_SSE41_SUPPORT_FLAG 0x80000
#define CPUID_FEATURE_INFORMATION_ECX_SSE41_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_SSE41_SUPPORT(_) (((_) >> 19) & 0x01)
/**
* @brief SSE4.2 support
*
* [Bit 20] A value of 1 indicates that the processor supports SSE4.2.
*/
UINT32_t sse42_support : 1;
#define CPUID_FEATURE_INFORMATION_ECX_SSE42_SUPPORT_BIT 20
#define CPUID_FEATURE_INFORMATION_ECX_SSE42_SUPPORT_FLAG 0x100000
#define CPUID_FEATURE_INFORMATION_ECX_SSE42_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_SSE42_SUPPORT(_) (((_) >> 20) & 0x01)
/**
* @brief x2APIC support
*
* [Bit 21] A value of 1 indicates that the processor supports x2APIC feature.
*/
UINT32_t x2apic_support : 1;
#define CPUID_FEATURE_INFORMATION_ECX_X2APIC_SUPPORT_BIT 21
#define CPUID_FEATURE_INFORMATION_ECX_X2APIC_SUPPORT_FLAG 0x200000
#define CPUID_FEATURE_INFORMATION_ECX_X2APIC_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_X2APIC_SUPPORT(_) (((_) >> 21) & 0x01)
/**
* @brief MOVBE instruction
*
* [Bit 22] A value of 1 indicates that the processor supports MOVBE instruction.
*/
UINT32_t movbe_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_MOVBE_INSTRUCTION_BIT 22
#define CPUID_FEATURE_INFORMATION_ECX_MOVBE_INSTRUCTION_FLAG 0x400000
#define CPUID_FEATURE_INFORMATION_ECX_MOVBE_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_MOVBE_INSTRUCTION(_) (((_) >> 22) & 0x01)
/**
* @brief POPCNT instruction
*
* [Bit 23] A value of 1 indicates that the processor supports the POPCNT instruction.
*/
UINT32_t popcnt_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_POPCNT_INSTRUCTION_BIT 23
#define CPUID_FEATURE_INFORMATION_ECX_POPCNT_INSTRUCTION_FLAG 0x800000
#define CPUID_FEATURE_INFORMATION_ECX_POPCNT_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_POPCNT_INSTRUCTION(_) (((_) >> 23) & 0x01)
/**
* @brief TSC Deadline
*
* [Bit 24] A value of 1 indicates that the processor's local APIC timer supports one-shot operation using a TSC deadline
* value.
*/
UINT32_t tsc_deadline : 1;
#define CPUID_FEATURE_INFORMATION_ECX_TSC_DEADLINE_BIT 24
#define CPUID_FEATURE_INFORMATION_ECX_TSC_DEADLINE_FLAG 0x1000000
#define CPUID_FEATURE_INFORMATION_ECX_TSC_DEADLINE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_TSC_DEADLINE(_) (((_) >> 24) & 0x01)
/**
* @brief AESNI instruction extensions
*
* [Bit 25] A value of 1 indicates that the processor supports the AESNI instruction extensions.
*/
UINT32_t aesni_instruction_extensions : 1;
#define CPUID_FEATURE_INFORMATION_ECX_AESNI_INSTRUCTION_EXTENSIONS_BIT 25
#define CPUID_FEATURE_INFORMATION_ECX_AESNI_INSTRUCTION_EXTENSIONS_FLAG 0x2000000
#define CPUID_FEATURE_INFORMATION_ECX_AESNI_INSTRUCTION_EXTENSIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_AESNI_INSTRUCTION_EXTENSIONS(_) (((_) >> 25) & 0x01)
/**
* @brief XSAVE/XRSTOR instruction extensions
*
* [Bit 26] A value of 1 indicates that the processor supports the XSAVE/XRSTOR processor extended states feature, the
* XSETBV/XGETBV instructions, and XCR0.
*/
UINT32_t xsave_xrstor_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_XSAVE_XRSTOR_INSTRUCTION_BIT 26
#define CPUID_FEATURE_INFORMATION_ECX_XSAVE_XRSTOR_INSTRUCTION_FLAG 0x4000000
#define CPUID_FEATURE_INFORMATION_ECX_XSAVE_XRSTOR_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_XSAVE_XRSTOR_INSTRUCTION(_) (((_) >> 26) & 0x01)
/**
* @brief CR4.OSXSAVE[bit 18] set
*
* [Bit 27] A value of 1 indicates that the OS has set CR4.OSXSAVE[bit 18] to enable XSETBV/XGETBV instructions to access
* XCR0 and to support processor extended state management using XSAVE/XRSTOR.
*/
UINT32_t osx_save : 1;
#define CPUID_FEATURE_INFORMATION_ECX_OSX_SAVE_BIT 27
#define CPUID_FEATURE_INFORMATION_ECX_OSX_SAVE_FLAG 0x8000000
#define CPUID_FEATURE_INFORMATION_ECX_OSX_SAVE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_OSX_SAVE(_) (((_) >> 27) & 0x01)
/**
* @brief AVX instruction extensions support
*
* [Bit 28] A value of 1 indicates the processor supports the AVX instruction extensions.
*/
UINT32_t avx_support : 1;
#define CPUID_FEATURE_INFORMATION_ECX_AVX_SUPPORT_BIT 28
#define CPUID_FEATURE_INFORMATION_ECX_AVX_SUPPORT_FLAG 0x10000000
#define CPUID_FEATURE_INFORMATION_ECX_AVX_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_AVX_SUPPORT(_) (((_) >> 28) & 0x01)
/**
* @brief 16-bit floating-point conversion instructions support
*
* [Bit 29] A value of 1 indicates that processor supports 16-bit floating-point conversion instructions.
*/
UINT32_t half_precision_conversion_instructions : 1;
#define CPUID_FEATURE_INFORMATION_ECX_HALF_PRECISION_CONVERSION_INSTRUCTIONS_BIT 29
#define CPUID_FEATURE_INFORMATION_ECX_HALF_PRECISION_CONVERSION_INSTRUCTIONS_FLAG 0x20000000
#define CPUID_FEATURE_INFORMATION_ECX_HALF_PRECISION_CONVERSION_INSTRUCTIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_HALF_PRECISION_CONVERSION_INSTRUCTIONS(_) (((_) >> 29) & 0x01)
/**
* @brief RDRAND instruction support
*
* [Bit 30] A value of 1 indicates that processor supports RDRAND instruction.
*/
UINT32_t rdrand_instruction : 1;
#define CPUID_FEATURE_INFORMATION_ECX_RDRAND_INSTRUCTION_BIT 30
#define CPUID_FEATURE_INFORMATION_ECX_RDRAND_INSTRUCTION_FLAG 0x40000000
#define CPUID_FEATURE_INFORMATION_ECX_RDRAND_INSTRUCTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_ECX_RDRAND_INSTRUCTION(_) (((_) >> 30) & 0x01)
UINT32_t reserved2 : 1;
};
UINT32_t flags;
} cpuid_feature_information_ecx;
/**
* @brief When CPUID executes with EAX set to 01H, feature information is returned in ECX and EDX
*/
union
{
struct
{
/**
* @brief Floating Point Unit On-Chip
*
* [Bit 0] The processor contains an x87 FPU.
*/
UINT32_t floating_point_unit_on_chip : 1;
#define CPUID_FEATURE_INFORMATION_EDX_FLOATING_POINT_UNIT_ON_CHIP_BIT 0
#define CPUID_FEATURE_INFORMATION_EDX_FLOATING_POINT_UNIT_ON_CHIP_FLAG 0x01
#define CPUID_FEATURE_INFORMATION_EDX_FLOATING_POINT_UNIT_ON_CHIP_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_FLOATING_POINT_UNIT_ON_CHIP(_) (((_) >> 0) & 0x01)
/**
* @brief Virtual 8086 Mode Enhancements
*
* [Bit 1] Virtual 8086 mode enhancements, including CR4.VME for controlling the feature, CR4.PVI for protected mode
* virtual interrupts, software interrupt indirection, expansion of the TSS with the software indirection bitmap, and
* EFLAGS.VIF and EFLAGS.VIP flags.
*/
UINT32_t virtual_8086_mode_enhancements : 1;
#define CPUID_FEATURE_INFORMATION_EDX_VIRTUAL_8086_MODE_ENHANCEMENTS_BIT 1
#define CPUID_FEATURE_INFORMATION_EDX_VIRTUAL_8086_MODE_ENHANCEMENTS_FLAG 0x02
#define CPUID_FEATURE_INFORMATION_EDX_VIRTUAL_8086_MODE_ENHANCEMENTS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_VIRTUAL_8086_MODE_ENHANCEMENTS(_) (((_) >> 1) & 0x01)
/**
* @brief Debugging Extensions
*
* [Bit 2] Support for I/O breakpoints, including CR4.DE for controlling the feature, and optional trapping of accesses to
* DR4 and DR5.
*/
UINT32_t debugging_extensions : 1;
#define CPUID_FEATURE_INFORMATION_EDX_DEBUGGING_EXTENSIONS_BIT 2
#define CPUID_FEATURE_INFORMATION_EDX_DEBUGGING_EXTENSIONS_FLAG 0x04
#define CPUID_FEATURE_INFORMATION_EDX_DEBUGGING_EXTENSIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_DEBUGGING_EXTENSIONS(_) (((_) >> 2) & 0x01)
/**
* @brief Page Size Extension
*
* [Bit 3] Large pages of size 4 MByte are supported, including CR4.PSE for controlling the feature, the defined dirty bit
* in PDE (Page Directory Entries), optional reserved bit trapping in CR3, PDEs, and PTEs.
*/
UINT32_t page_size_extension : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_BIT 3
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_FLAG 0x08
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION(_) (((_) >> 3) & 0x01)
/**
* @brief Time Stamp Counter
*
* [Bit 4] The RDTSC instruction is supported, including CR4.TSD for controlling privilege.
*/
UINT32_t timestamp_counter : 1;
#define CPUID_FEATURE_INFORMATION_EDX_TIMESTAMP_COUNTER_BIT 4
#define CPUID_FEATURE_INFORMATION_EDX_TIMESTAMP_COUNTER_FLAG 0x10
#define CPUID_FEATURE_INFORMATION_EDX_TIMESTAMP_COUNTER_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_TIMESTAMP_COUNTER(_) (((_) >> 4) & 0x01)
/**
* @brief Model Specific Registers RDMSR and WRMSR Instructions
*
* [Bit 5] The RDMSR and WRMSR instructions are supported. Some of the MSRs are implementation dependent.
*/
UINT32_t rdmsr_wrmsr_instructions : 1;
#define CPUID_FEATURE_INFORMATION_EDX_RDMSR_WRMSR_INSTRUCTIONS_BIT 5
#define CPUID_FEATURE_INFORMATION_EDX_RDMSR_WRMSR_INSTRUCTIONS_FLAG 0x20
#define CPUID_FEATURE_INFORMATION_EDX_RDMSR_WRMSR_INSTRUCTIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_RDMSR_WRMSR_INSTRUCTIONS(_) (((_) >> 5) & 0x01)
/**
* @brief Physical Address Extension
*
* [Bit 6] Physical addresses greater than 32 bits are supported: extended page table entry formats, an extra level in the
* page translation tables is defined, 2-MByte pages are supported instead of 4 Mbyte pages if PAE bit is 1.
*/
UINT32_t physical_address_extension : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PHYSICAL_ADDRESS_EXTENSION_BIT 6
#define CPUID_FEATURE_INFORMATION_EDX_PHYSICAL_ADDRESS_EXTENSION_FLAG 0x40
#define CPUID_FEATURE_INFORMATION_EDX_PHYSICAL_ADDRESS_EXTENSION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PHYSICAL_ADDRESS_EXTENSION(_) (((_) >> 6) & 0x01)
/**
* @brief Machine Check Exception
*
* [Bit 7] Exception 18 is defined for Machine Checks, including CR4.MCE for controlling the feature. This feature does not
* define the model-specific implementations of machine-check error logging, reporting, and processor shutdowns. Machine
* Check exception handlers may have to depend on processor version to do model specific processing of the exception, or
* test for the presence of the Machine Check feature.
*/
UINT32_t machine_check_exception : 1;
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_EXCEPTION_BIT 7
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_EXCEPTION_FLAG 0x80
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_EXCEPTION_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_EXCEPTION(_) (((_) >> 7) & 0x01)
/**
* @brief CMPXCHG8B Instruction
*
* [Bit 8] The compare-and-exchange 8 bytes (64 bits) instruction is supported (implicitly locked and atomic).
*/
UINT32_t cmpxchg8b : 1;
#define CPUID_FEATURE_INFORMATION_EDX_CMPXCHG8B_BIT 8
#define CPUID_FEATURE_INFORMATION_EDX_CMPXCHG8B_FLAG 0x100
#define CPUID_FEATURE_INFORMATION_EDX_CMPXCHG8B_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_CMPXCHG8B(_) (((_) >> 8) & 0x01)
/**
* @brief APIC On-Chip
*
* [Bit 9] The processor contains an Advanced Programmable Interrupt Controller (APIC), responding to memory mapped
* commands in the physical address range FFFE0000H to FFFE0FFFH (by default - some processors permit the APIC to be
* relocated).
*/
UINT32_t apic_on_chip : 1;
#define CPUID_FEATURE_INFORMATION_EDX_APIC_ON_CHIP_BIT 9
#define CPUID_FEATURE_INFORMATION_EDX_APIC_ON_CHIP_FLAG 0x200
#define CPUID_FEATURE_INFORMATION_EDX_APIC_ON_CHIP_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_APIC_ON_CHIP(_) (((_) >> 9) & 0x01)
UINT32_t reserved1 : 1;
/**
* @brief SYSENTER and SYSEXIT Instructions
*
* [Bit 11] The SYSENTER and SYSEXIT and associated MSRs are supported.
*/
UINT32_t sysenter_sysexit_instructions : 1;
#define CPUID_FEATURE_INFORMATION_EDX_SYSENTER_SYSEXIT_INSTRUCTIONS_BIT 11
#define CPUID_FEATURE_INFORMATION_EDX_SYSENTER_SYSEXIT_INSTRUCTIONS_FLAG 0x800
#define CPUID_FEATURE_INFORMATION_EDX_SYSENTER_SYSEXIT_INSTRUCTIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_SYSENTER_SYSEXIT_INSTRUCTIONS(_) (((_) >> 11) & 0x01)
/**
* @brief Memory Type Range Registers
*
* [Bit 12] MTRRs are supported. The MTRRcap MSR contains feature bits that describe what memory types are supported, how
* many variable MTRRs are supported, and whether fixed MTRRs are supported.
*/
UINT32_t memory_type_range_registers : 1;
#define CPUID_FEATURE_INFORMATION_EDX_MEMORY_TYPE_RANGE_REGISTERS_BIT 12
#define CPUID_FEATURE_INFORMATION_EDX_MEMORY_TYPE_RANGE_REGISTERS_FLAG 0x1000
#define CPUID_FEATURE_INFORMATION_EDX_MEMORY_TYPE_RANGE_REGISTERS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_MEMORY_TYPE_RANGE_REGISTERS(_) (((_) >> 12) & 0x01)
/**
* @brief Page Global Bit
*
* [Bit 13] The global bit is supported in paging-structure entries that map a page, indicating TLB entries that are common
* to different processes and need not be flushed. The CR4.PGE bit controls this feature.
*/
UINT32_t page_global_bit : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_GLOBAL_BIT_BIT 13
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_GLOBAL_BIT_FLAG 0x2000
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_GLOBAL_BIT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_GLOBAL_BIT(_) (((_) >> 13) & 0x01)
/**
* @brief Machine Check Architecture
*
* [Bit 14] A value of 1 indicates the Machine Check Architecture of reporting machine errors is supported. The MCG_CAP MSR
* contains feature bits describing how many banks of error reporting MSRs are supported.
*/
UINT32_t machine_check_architecture : 1;
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_ARCHITECTURE_BIT 14
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_ARCHITECTURE_FLAG 0x4000
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_ARCHITECTURE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_MACHINE_CHECK_ARCHITECTURE(_) (((_) >> 14) & 0x01)
/**
* @brief Conditional Move Instructions
*
* [Bit 15] The conditional move instruction CMOV is supported. In addition, if x87 FPU is present as indicated by the
* CPUID.FPU feature bit, then the FCOMI and FCMOV instructions are supported
*/
UINT32_t conditional_move_instructions : 1;
#define CPUID_FEATURE_INFORMATION_EDX_CONDITIONAL_MOVE_INSTRUCTIONS_BIT 15
#define CPUID_FEATURE_INFORMATION_EDX_CONDITIONAL_MOVE_INSTRUCTIONS_FLAG 0x8000
#define CPUID_FEATURE_INFORMATION_EDX_CONDITIONAL_MOVE_INSTRUCTIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_CONDITIONAL_MOVE_INSTRUCTIONS(_) (((_) >> 15) & 0x01)
/**
* @brief Page Attribute Table
*
* [Bit 16] Page Attribute Table is supported. This feature augments the Memory Type Range Registers (MTRRs), allowing an
* operating system to specify attributes of memory accessed through a linear address on a 4KB granularity.
*/
UINT32_t page_attribute_table : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_ATTRIBUTE_TABLE_BIT 16
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_ATTRIBUTE_TABLE_FLAG 0x10000
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_ATTRIBUTE_TABLE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_ATTRIBUTE_TABLE(_) (((_) >> 16) & 0x01)
/**
* @brief 36-Bit Page Size Extension
*
* [Bit 17] 4-MByte pages addressing physical memory beyond 4 GBytes are supported with 32-bit paging. This feature
* indicates that upper bits of the physical address of a 4-MByte page are encoded in bits 20:13 of the page-directory
* entry. Such physical addresses are limited by MAXPHYADDR and may be up to 40 bits in size.
*/
UINT32_t page_size_extension_36bit : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_36BIT_BIT 17
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_36BIT_FLAG 0x20000
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_36BIT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PAGE_SIZE_EXTENSION_36BIT(_) (((_) >> 17) & 0x01)
/**
* @brief Processor Serial Number
*
* [Bit 18] The processor supports the 96-bit processor identification number feature and the feature is enabled.
*/
UINT32_t processor_serial_number : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PROCESSOR_SERIAL_NUMBER_BIT 18
#define CPUID_FEATURE_INFORMATION_EDX_PROCESSOR_SERIAL_NUMBER_FLAG 0x40000
#define CPUID_FEATURE_INFORMATION_EDX_PROCESSOR_SERIAL_NUMBER_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PROCESSOR_SERIAL_NUMBER(_) (((_) >> 18) & 0x01)
/**
* @brief CLFLUSH Instruction
*
* [Bit 19] CLFLUSH Instruction is supported.
*/
UINT32_t clflush : 1;
#define CPUID_FEATURE_INFORMATION_EDX_CLFLUSH_BIT 19
#define CPUID_FEATURE_INFORMATION_EDX_CLFLUSH_FLAG 0x80000
#define CPUID_FEATURE_INFORMATION_EDX_CLFLUSH_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_CLFLUSH(_) (((_) >> 19) & 0x01)
UINT32_t reserved2 : 1;
/**
* @brief Debug Store
*
* [Bit 21] The processor supports the ability to write debug information into a memory resident buffer. This feature is
* used by the branch trace store (BTS) and processor event-based sampling (PEBS) facilities.
*
* @see Vol3C[23(INTRODUCTION TO VIRTUAL MACHINE EXTENSIONS)]
*/
UINT32_t debug_store : 1;
#define CPUID_FEATURE_INFORMATION_EDX_DEBUG_STORE_BIT 21
#define CPUID_FEATURE_INFORMATION_EDX_DEBUG_STORE_FLAG 0x200000
#define CPUID_FEATURE_INFORMATION_EDX_DEBUG_STORE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_DEBUG_STORE(_) (((_) >> 21) & 0x01)
/**
* @brief Thermal Monitor and Software Controlled Clock Facilities
*
* [Bit 22] The processor implements internal MSRs that allow processor temperature to be monitored and processor
* performance to be modulated in predefined duty cycles under software control.
*/
UINT32_t thermal_control_msrs_for_acpi : 1;
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_CONTROL_MSRS_FOR_ACPI_BIT 22
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_CONTROL_MSRS_FOR_ACPI_FLAG 0x400000
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_CONTROL_MSRS_FOR_ACPI_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_CONTROL_MSRS_FOR_ACPI(_) (((_) >> 22) & 0x01)
/**
* @brief Intel MMX Technology
*
* [Bit 23] The processor supports the Intel MMX technology.
*/
UINT32_t mmx_support : 1;
#define CPUID_FEATURE_INFORMATION_EDX_MMX_SUPPORT_BIT 23
#define CPUID_FEATURE_INFORMATION_EDX_MMX_SUPPORT_FLAG 0x800000
#define CPUID_FEATURE_INFORMATION_EDX_MMX_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_MMX_SUPPORT(_) (((_) >> 23) & 0x01)
/**
* @brief FXSAVE and FXRSTOR Instructions
*
* [Bit 24] The FXSAVE and FXRSTOR instructions are supported for fast save and restore of the floating point context.
* Presence of this bit also indicates that CR4.OSFXSR is available for an operating system to indicate that it supports
* the FXSAVE and FXRSTOR instructions.
*/
UINT32_t fxsave_fxrstor_instructions : 1;
#define CPUID_FEATURE_INFORMATION_EDX_FXSAVE_FXRSTOR_INSTRUCTIONS_BIT 24
#define CPUID_FEATURE_INFORMATION_EDX_FXSAVE_FXRSTOR_INSTRUCTIONS_FLAG 0x1000000
#define CPUID_FEATURE_INFORMATION_EDX_FXSAVE_FXRSTOR_INSTRUCTIONS_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_FXSAVE_FXRSTOR_INSTRUCTIONS(_) (((_) >> 24) & 0x01)
/**
* @brief SSE extensions support
*
* [Bit 25] The processor supports the SSE extensions.
*/
UINT32_t sse_support : 1;
#define CPUID_FEATURE_INFORMATION_EDX_SSE_SUPPORT_BIT 25
#define CPUID_FEATURE_INFORMATION_EDX_SSE_SUPPORT_FLAG 0x2000000
#define CPUID_FEATURE_INFORMATION_EDX_SSE_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_SSE_SUPPORT(_) (((_) >> 25) & 0x01)
/**
* @brief SSE2 extensions support
*
* [Bit 26] The processor supports the SSE2 extensions.
*/
UINT32_t sse2_support : 1;
#define CPUID_FEATURE_INFORMATION_EDX_SSE2_SUPPORT_BIT 26
#define CPUID_FEATURE_INFORMATION_EDX_SSE2_SUPPORT_FLAG 0x4000000
#define CPUID_FEATURE_INFORMATION_EDX_SSE2_SUPPORT_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_SSE2_SUPPORT(_) (((_) >> 26) & 0x01)
/**
* @brief Self Snoop
*
* [Bit 27] The processor supports the management of conflicting memory types by performing a snoop of its own cache
* structure for transactions issued to the bus.
*/
UINT32_t self_snoop : 1;
#define CPUID_FEATURE_INFORMATION_EDX_SELF_SNOOP_BIT 27
#define CPUID_FEATURE_INFORMATION_EDX_SELF_SNOOP_FLAG 0x8000000
#define CPUID_FEATURE_INFORMATION_EDX_SELF_SNOOP_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_SELF_SNOOP(_) (((_) >> 27) & 0x01)
/**
* @brief Max APIC IDs reserved field is Valid
*
* [Bit 28] A value of 0 for HTT indicates there is only a single logical processor in the package and software should
* assume only a single APIC ID is reserved. A value of 1 for HTT indicates the value in CPUID.1.EBX[23:16] (the Maximum
* number of addressable IDs for logical processors in this package) is valid for the package.
*/
UINT32_t hyper_threading_technology : 1;
#define CPUID_FEATURE_INFORMATION_EDX_HYPER_THREADING_TECHNOLOGY_BIT 28
#define CPUID_FEATURE_INFORMATION_EDX_HYPER_THREADING_TECHNOLOGY_FLAG 0x10000000
#define CPUID_FEATURE_INFORMATION_EDX_HYPER_THREADING_TECHNOLOGY_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_HYPER_THREADING_TECHNOLOGY(_) (((_) >> 28) & 0x01)
/**
* @brief Thermal Monitor
*
* [Bit 29] The processor implements the thermal monitor automatic thermal control circuitry (TCC).
*/
UINT32_t thermal_monitor : 1;
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_MONITOR_BIT 29
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_MONITOR_FLAG 0x20000000
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_MONITOR_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_THERMAL_MONITOR(_) (((_) >> 29) & 0x01)
UINT32_t reserved3 : 1;
/**
* @brief Pending Break Enable
*
* [Bit 31] The processor supports the use of the FERR\#/PBE\# pin when the processor is in the stop-clock state (STPCLK\#
* is asserted) to signal the processor that an interrupt is pending and that the processor should return to normal
* operation to handle the interrupt. Bit 10 (PBE enable) in the IA32_MISC_ENABLE MSR enables this capability.
*/
UINT32_t pending_break_enable : 1;
#define CPUID_FEATURE_INFORMATION_EDX_PENDING_BREAK_ENABLE_BIT 31
#define CPUID_FEATURE_INFORMATION_EDX_PENDING_BREAK_ENABLE_FLAG 0x80000000
#define CPUID_FEATURE_INFORMATION_EDX_PENDING_BREAK_ENABLE_MASK 0x01
#define CPUID_FEATURE_INFORMATION_EDX_PENDING_BREAK_ENABLE(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} cpuid_feature_information_edx;
} cpuid_eax_01;
/**
* @brief Deterministic Cache Parameters Leaf
*
* When CPUID executes with EAX set to 04H and ECX contains an index value, the processor returns encoded data that
* describe a set of deterministic cache parameters (for the cache level associated with the input in ECX). Valid index
* values start from 0.
* Software can enumerate the deterministic cache parameters for each level of the cache hierarchy starting with an index
* value of 0, until the parameters report the value associated with the cache type field is 0. The architecturally defined
* fields reported by deterministic cache parameters are documented in Table 3-8.
* This Cache Size in Bytes
* - = (Ways + 1) * (Partitions + 1) * (Line_Size + 1) * (Sets + 1)
* - = (EBX[31:22] + 1) * (EBX[21:12] + 1) * (EBX[11:0] + 1) * (ECX + 1)
* The CPUID leaf 04H also reports data that can be used to derive the topology of processor cores in a physical package.
* This information is constant for all valid index values. Software can query the raw data reported by executing CPUID
* with EAX=04H and ECX=0 and use it as part of the topology enumeration algorithm.
*
* @see Vol3A[8(Multiple-Processor Management)]
*/
#define CPUID_CACHE_PARAMETERS 0x00000004
typedef struct
{
union
{
struct
{
/**
* [Bits 4:0] - 0 = Null - No more caches.
* - 1 = Data Cache.
* - 2 = Instruction Cache.
* - 3 = Unified Cache.
* - 4-31 = Reserved.
*/
UINT32_t cache_type_field : 5;
#define CPUID_EAX_CACHE_TYPE_FIELD_BIT 0
#define CPUID_EAX_CACHE_TYPE_FIELD_FLAG 0x1F
#define CPUID_EAX_CACHE_TYPE_FIELD_MASK 0x1F
#define CPUID_EAX_CACHE_TYPE_FIELD(_) (((_) >> 0) & 0x1F)
/**
* [Bits 7:5] Cache Level (starts at 1).
*/
UINT32_t cache_level : 3;
#define CPUID_EAX_CACHE_LEVEL_BIT 5
#define CPUID_EAX_CACHE_LEVEL_FLAG 0xE0
#define CPUID_EAX_CACHE_LEVEL_MASK 0x07
#define CPUID_EAX_CACHE_LEVEL(_) (((_) >> 5) & 0x07)
/**
* [Bit 8] Self Initializing cache level (does not need SW initialization).
*/
UINT32_t self_initializing_cache_level : 1;
#define CPUID_EAX_SELF_INITIALIZING_CACHE_LEVEL_BIT 8
#define CPUID_EAX_SELF_INITIALIZING_CACHE_LEVEL_FLAG 0x100
#define CPUID_EAX_SELF_INITIALIZING_CACHE_LEVEL_MASK 0x01
#define CPUID_EAX_SELF_INITIALIZING_CACHE_LEVEL(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Fully Associative cache.
*/
UINT32_t fully_associative_cache : 1;
#define CPUID_EAX_FULLY_ASSOCIATIVE_CACHE_BIT 9
#define CPUID_EAX_FULLY_ASSOCIATIVE_CACHE_FLAG 0x200
#define CPUID_EAX_FULLY_ASSOCIATIVE_CACHE_MASK 0x01
#define CPUID_EAX_FULLY_ASSOCIATIVE_CACHE(_) (((_) >> 9) & 0x01)
UINT32_t reserved1 : 4;
/**
* [Bits 25:14] Maximum number of addressable IDs for logical processors sharing this cache.
*
* @note Add one to the return value to get the result.
* The nearest power-of-2 integer that is not smaller than (1 + EAX[25:14]) is the number of unique initial APIC IDs
* reserved for addressing different logical processors sharing this cache.
*/
UINT32_t max_addressable_ids_for_logical_processors_sharing_this_cache : 12;
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_SHARING_THIS_CACHE_BIT 14
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_SHARING_THIS_CACHE_FLAG 0x3FFC000
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_SHARING_THIS_CACHE_MASK 0xFFF
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_SHARING_THIS_CACHE(_) (((_) >> 14) & 0xFFF)
/**
* [Bits 31:26] Maximum number of addressable IDs for processor cores in the physical package.
*
* @note Add one to the return value to get the result.
* The nearest power-of-2 integer that is not smaller than (1 + EAX[31:26]) is the number of unique Core_IDs reserved for
* addressing different processor cores in a physical package. Core ID is a subset of bits of the initial APIC ID.
* The returned value is constant for valid initial values in ECX. Valid ECX values start from 0.
*/
UINT32_t max_addressable_ids_for_processor_cores_in_physical_package : 6;
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_PROCESSOR_CORES_IN_PHYSICAL_PACKAGE_BIT 26
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_PROCESSOR_CORES_IN_PHYSICAL_PACKAGE_FLAG 0xFC000000
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_PROCESSOR_CORES_IN_PHYSICAL_PACKAGE_MASK 0x3F
#define CPUID_EAX_MAX_ADDRESSABLE_IDS_FOR_PROCESSOR_CORES_IN_PHYSICAL_PACKAGE(_) (((_) >> 26) & 0x3F)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 11:0] System Coherency Line Size.
*
* @note Add one to the return value to get the result.
*/
UINT32_t system_coherency_line_size : 12;
#define CPUID_EBX_SYSTEM_COHERENCY_LINE_SIZE_BIT 0
#define CPUID_EBX_SYSTEM_COHERENCY_LINE_SIZE_FLAG 0xFFF
#define CPUID_EBX_SYSTEM_COHERENCY_LINE_SIZE_MASK 0xFFF
#define CPUID_EBX_SYSTEM_COHERENCY_LINE_SIZE(_) (((_) >> 0) & 0xFFF)
/**
* [Bits 21:12] Physical Line partitions.
*
* @note Add one to the return value to get the result.
*/
UINT32_t physical_line_partitions : 10;
#define CPUID_EBX_PHYSICAL_LINE_PARTITIONS_BIT 12
#define CPUID_EBX_PHYSICAL_LINE_PARTITIONS_FLAG 0x3FF000
#define CPUID_EBX_PHYSICAL_LINE_PARTITIONS_MASK 0x3FF
#define CPUID_EBX_PHYSICAL_LINE_PARTITIONS(_) (((_) >> 12) & 0x3FF)
/**
* [Bits 31:22] Ways of associativity.
*
* @note Add one to the return value to get the result.
*/
UINT32_t ways_of_associativity : 10;
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_BIT 22
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_FLAG 0xFFC00000
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_MASK 0x3FF
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY(_) (((_) >> 22) & 0x3FF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Number of Sets.
*
* @note Add one to the return value to get the result.
*/
UINT32_t number_of_sets : 32;
#define CPUID_ECX_NUMBER_OF_SETS_BIT 0
#define CPUID_ECX_NUMBER_OF_SETS_FLAG 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS_MASK 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* @brief Write-Back Invalidate/Invalidate
*
* [Bit 0] - 0 = WBINVD/INVD from threads sharing this cache acts upon lower level caches for threads sharing this cache.
* - 1 = WBINVD/INVD is not guaranteed to act upon lower level caches of non-originating threads sharing this cache.
*/
UINT32_t write_back_invalidate : 1;
#define CPUID_EDX_WRITE_BACK_INVALIDATE_BIT 0
#define CPUID_EDX_WRITE_BACK_INVALIDATE_FLAG 0x01
#define CPUID_EDX_WRITE_BACK_INVALIDATE_MASK 0x01
#define CPUID_EDX_WRITE_BACK_INVALIDATE(_) (((_) >> 0) & 0x01)
/**
* @brief Cache Inclusiveness
*
* [Bit 1] - 0 = Cache is not inclusive of lower cache levels.
* - 1 = Cache is inclusive of lower cache levels.
*/
UINT32_t cache_inclusiveness : 1;
#define CPUID_EDX_CACHE_INCLUSIVENESS_BIT 1
#define CPUID_EDX_CACHE_INCLUSIVENESS_FLAG 0x02
#define CPUID_EDX_CACHE_INCLUSIVENESS_MASK 0x01
#define CPUID_EDX_CACHE_INCLUSIVENESS(_) (((_) >> 1) & 0x01)
/**
* @brief Complex Cache Indexing
*
* [Bit 2] - 0 = Direct mapped cache.
* - 1 = A complex function is used to index the cache, potentially using all address bits.
*/
UINT32_t complex_cache_indexing : 1;
#define CPUID_EDX_COMPLEX_CACHE_INDEXING_BIT 2
#define CPUID_EDX_COMPLEX_CACHE_INDEXING_FLAG 0x04
#define CPUID_EDX_COMPLEX_CACHE_INDEXING_MASK 0x01
#define CPUID_EDX_COMPLEX_CACHE_INDEXING(_) (((_) >> 2) & 0x01)
UINT32_t reserved1 : 29;
};
UINT32_t flags;
} edx;
} cpuid_eax_04;
/**
* @brief MONITOR/MWAIT Leaf
*
* When CPUID executes with EAX set to 05H, the processor returns information about features available to MONITOR/MWAIT
* instructions. The MONITOR instruction is used for address-range monitoring in conjunction with MWAIT instruction. The
* MWAIT instruction optionally provides additional extensions for advanced power management.
*/
#define CPUID_MONITOR_MWAIT 0x00000005
typedef struct
{
union
{
struct
{
/**
* [Bits 15:0] Smallest monitor-line size in bytes (default is processor's monitor granularity).
*/
UINT32_t smallest_monitor_line_size : 16;
#define CPUID_EAX_SMALLEST_MONITOR_LINE_SIZE_BIT 0
#define CPUID_EAX_SMALLEST_MONITOR_LINE_SIZE_FLAG 0xFFFF
#define CPUID_EAX_SMALLEST_MONITOR_LINE_SIZE_MASK 0xFFFF
#define CPUID_EAX_SMALLEST_MONITOR_LINE_SIZE(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 15:0] Largest monitor-line size in bytes (default is processor's monitor granularity).
*/
UINT32_t largest_monitor_line_size : 16;
#define CPUID_EBX_LARGEST_MONITOR_LINE_SIZE_BIT 0
#define CPUID_EBX_LARGEST_MONITOR_LINE_SIZE_FLAG 0xFFFF
#define CPUID_EBX_LARGEST_MONITOR_LINE_SIZE_MASK 0xFFFF
#define CPUID_EBX_LARGEST_MONITOR_LINE_SIZE(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] Enumeration of Monitor-Mwait extensions (beyond EAX and EBX registers) supported.
*/
UINT32_t enumeration_of_monitor_mwait_extensions : 1;
#define CPUID_ECX_ENUMERATION_OF_MONITOR_MWAIT_EXTENSIONS_BIT 0
#define CPUID_ECX_ENUMERATION_OF_MONITOR_MWAIT_EXTENSIONS_FLAG 0x01
#define CPUID_ECX_ENUMERATION_OF_MONITOR_MWAIT_EXTENSIONS_MASK 0x01
#define CPUID_ECX_ENUMERATION_OF_MONITOR_MWAIT_EXTENSIONS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Supports treating interrupts as break-event for MWAIT, even when interrupts disabled.
*/
UINT32_t supports_treating_interrupts_as_break_event_for_mwait : 1;
#define CPUID_ECX_SUPPORTS_TREATING_INTERRUPTS_AS_BREAK_EVENT_FOR_MWAIT_BIT 1
#define CPUID_ECX_SUPPORTS_TREATING_INTERRUPTS_AS_BREAK_EVENT_FOR_MWAIT_FLAG 0x02
#define CPUID_ECX_SUPPORTS_TREATING_INTERRUPTS_AS_BREAK_EVENT_FOR_MWAIT_MASK 0x01
#define CPUID_ECX_SUPPORTS_TREATING_INTERRUPTS_AS_BREAK_EVENT_FOR_MWAIT(_) (((_) >> 1) & 0x01)
UINT32_t reserved1 : 30;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 3:0] Number of C0 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c0_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C0_SUB_C_STATES_BIT 0
#define CPUID_EDX_NUMBER_OF_C0_SUB_C_STATES_FLAG 0x0F
#define CPUID_EDX_NUMBER_OF_C0_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C0_SUB_C_STATES(_) (((_) >> 0) & 0x0F)
/**
* [Bits 7:4] Number of C1 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c1_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C1_SUB_C_STATES_BIT 4
#define CPUID_EDX_NUMBER_OF_C1_SUB_C_STATES_FLAG 0xF0
#define CPUID_EDX_NUMBER_OF_C1_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C1_SUB_C_STATES(_) (((_) >> 4) & 0x0F)
/**
* [Bits 11:8] Number of C2 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c2_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C2_SUB_C_STATES_BIT 8
#define CPUID_EDX_NUMBER_OF_C2_SUB_C_STATES_FLAG 0xF00
#define CPUID_EDX_NUMBER_OF_C2_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C2_SUB_C_STATES(_) (((_) >> 8) & 0x0F)
/**
* [Bits 15:12] Number of C3 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c3_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C3_SUB_C_STATES_BIT 12
#define CPUID_EDX_NUMBER_OF_C3_SUB_C_STATES_FLAG 0xF000
#define CPUID_EDX_NUMBER_OF_C3_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C3_SUB_C_STATES(_) (((_) >> 12) & 0x0F)
/**
* [Bits 19:16] Number of C4 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c4_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C4_SUB_C_STATES_BIT 16
#define CPUID_EDX_NUMBER_OF_C4_SUB_C_STATES_FLAG 0xF0000
#define CPUID_EDX_NUMBER_OF_C4_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C4_SUB_C_STATES(_) (((_) >> 16) & 0x0F)
/**
* [Bits 23:20] Number of C5 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c5_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C5_SUB_C_STATES_BIT 20
#define CPUID_EDX_NUMBER_OF_C5_SUB_C_STATES_FLAG 0xF00000
#define CPUID_EDX_NUMBER_OF_C5_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C5_SUB_C_STATES(_) (((_) >> 20) & 0x0F)
/**
* [Bits 27:24] Number of C6 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c6_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C6_SUB_C_STATES_BIT 24
#define CPUID_EDX_NUMBER_OF_C6_SUB_C_STATES_FLAG 0xF000000
#define CPUID_EDX_NUMBER_OF_C6_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C6_SUB_C_STATES(_) (((_) >> 24) & 0x0F)
/**
* [Bits 31:28] Number of C7 sub C-states supported using MWAIT.
*/
UINT32_t number_of_c7_sub_c_states : 4;
#define CPUID_EDX_NUMBER_OF_C7_SUB_C_STATES_BIT 28
#define CPUID_EDX_NUMBER_OF_C7_SUB_C_STATES_FLAG 0xF0000000
#define CPUID_EDX_NUMBER_OF_C7_SUB_C_STATES_MASK 0x0F
#define CPUID_EDX_NUMBER_OF_C7_SUB_C_STATES(_) (((_) >> 28) & 0x0F)
};
UINT32_t flags;
} edx;
} cpuid_eax_05;
/**
* @brief Thermal and Power Management Leaf
*
* When CPUID executes with EAX set to 06H, the processor returns information about thermal and power management features.
*/
#define CPUID_THERMAL_AND_POWER_MANAGEMENT 0x00000006
typedef struct
{
union
{
struct
{
/**
* [Bit 0] Digital temperature sensor is supported if set.
*/
UINT32_t temperature_sensor_supported : 1;
#define CPUID_EAX_TEMPERATURE_SENSOR_SUPPORTED_BIT 0
#define CPUID_EAX_TEMPERATURE_SENSOR_SUPPORTED_FLAG 0x01
#define CPUID_EAX_TEMPERATURE_SENSOR_SUPPORTED_MASK 0x01
#define CPUID_EAX_TEMPERATURE_SENSOR_SUPPORTED(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Intel Turbo Boost Technology available (see description of IA32_MISC_ENABLE[38]).
*/
UINT32_t intel_turbo_boost_technology_available : 1;
#define CPUID_EAX_INTEL_TURBO_BOOST_TECHNOLOGY_AVAILABLE_BIT 1
#define CPUID_EAX_INTEL_TURBO_BOOST_TECHNOLOGY_AVAILABLE_FLAG 0x02
#define CPUID_EAX_INTEL_TURBO_BOOST_TECHNOLOGY_AVAILABLE_MASK 0x01
#define CPUID_EAX_INTEL_TURBO_BOOST_TECHNOLOGY_AVAILABLE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] ARAT. APIC-Timer-always-running feature is supported if set.
*/
UINT32_t apic_timer_always_running : 1;
#define CPUID_EAX_APIC_TIMER_ALWAYS_RUNNING_BIT 2
#define CPUID_EAX_APIC_TIMER_ALWAYS_RUNNING_FLAG 0x04
#define CPUID_EAX_APIC_TIMER_ALWAYS_RUNNING_MASK 0x01
#define CPUID_EAX_APIC_TIMER_ALWAYS_RUNNING(_) (((_) >> 2) & 0x01)
UINT32_t reserved1 : 1;
/**
* [Bit 4] PLN. Power limit notification controls are supported if set.
*/
UINT32_t power_limit_notification : 1;
#define CPUID_EAX_POWER_LIMIT_NOTIFICATION_BIT 4
#define CPUID_EAX_POWER_LIMIT_NOTIFICATION_FLAG 0x10
#define CPUID_EAX_POWER_LIMIT_NOTIFICATION_MASK 0x01
#define CPUID_EAX_POWER_LIMIT_NOTIFICATION(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] ECMD. Clock modulation duty cycle extension is supported if set.
*/
UINT32_t clock_modulation_duty : 1;
#define CPUID_EAX_CLOCK_MODULATION_DUTY_BIT 5
#define CPUID_EAX_CLOCK_MODULATION_DUTY_FLAG 0x20
#define CPUID_EAX_CLOCK_MODULATION_DUTY_MASK 0x01
#define CPUID_EAX_CLOCK_MODULATION_DUTY(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] PTM. Package thermal management is supported if set.
*/
UINT32_t package_thermal_management : 1;
#define CPUID_EAX_PACKAGE_THERMAL_MANAGEMENT_BIT 6
#define CPUID_EAX_PACKAGE_THERMAL_MANAGEMENT_FLAG 0x40
#define CPUID_EAX_PACKAGE_THERMAL_MANAGEMENT_MASK 0x01
#define CPUID_EAX_PACKAGE_THERMAL_MANAGEMENT(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] HWP. HWP base registers (IA32_PM_ENABLE[bit 0], IA32_HWP_CAPABILITIES, IA32_HWP_REQUEST, IA32_HWP_STATUS) are
* supported if set.
*/
UINT32_t hwp_base_registers : 1;
#define CPUID_EAX_HWP_BASE_REGISTERS_BIT 7
#define CPUID_EAX_HWP_BASE_REGISTERS_FLAG 0x80
#define CPUID_EAX_HWP_BASE_REGISTERS_MASK 0x01
#define CPUID_EAX_HWP_BASE_REGISTERS(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] HWP_Notification. IA32_HWP_INTERRUPT MSR is supported if set.
*/
UINT32_t hwp_notification : 1;
#define CPUID_EAX_HWP_NOTIFICATION_BIT 8
#define CPUID_EAX_HWP_NOTIFICATION_FLAG 0x100
#define CPUID_EAX_HWP_NOTIFICATION_MASK 0x01
#define CPUID_EAX_HWP_NOTIFICATION(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] HWP_Activity_Window. IA32_HWP_REQUEST[bits 41:32] is supported if set.
*/
UINT32_t hwp_activity_window : 1;
#define CPUID_EAX_HWP_ACTIVITY_WINDOW_BIT 9
#define CPUID_EAX_HWP_ACTIVITY_WINDOW_FLAG 0x200
#define CPUID_EAX_HWP_ACTIVITY_WINDOW_MASK 0x01
#define CPUID_EAX_HWP_ACTIVITY_WINDOW(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] HWP_Energy_Performance_Preference. IA32_HWP_REQUEST[bits 31:24] is supported if set.
*/
UINT32_t hwp_energy_performance_preference : 1;
#define CPUID_EAX_HWP_ENERGY_PERFORMANCE_PREFERENCE_BIT 10
#define CPUID_EAX_HWP_ENERGY_PERFORMANCE_PREFERENCE_FLAG 0x400
#define CPUID_EAX_HWP_ENERGY_PERFORMANCE_PREFERENCE_MASK 0x01
#define CPUID_EAX_HWP_ENERGY_PERFORMANCE_PREFERENCE(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] HWP_Package_Level_Request. IA32_HWP_REQUEST_PKG MSR is supported if set.
*/
UINT32_t hwp_package_level_request : 1;
#define CPUID_EAX_HWP_PACKAGE_LEVEL_REQUEST_BIT 11
#define CPUID_EAX_HWP_PACKAGE_LEVEL_REQUEST_FLAG 0x800
#define CPUID_EAX_HWP_PACKAGE_LEVEL_REQUEST_MASK 0x01
#define CPUID_EAX_HWP_PACKAGE_LEVEL_REQUEST(_) (((_) >> 11) & 0x01)
UINT32_t reserved2 : 1;
/**
* [Bit 13] HDC. HDC base registers IA32_PKG_HDC_CTL, IA32_PM_CTL1, IA32_THREAD_STALL MSRs are supported if set.
*/
UINT32_t hdc : 1;
#define CPUID_EAX_HDC_BIT 13
#define CPUID_EAX_HDC_FLAG 0x2000
#define CPUID_EAX_HDC_MASK 0x01
#define CPUID_EAX_HDC(_) (((_) >> 13) & 0x01)
/**
* [Bit 14] Intel(R) Turbo Boost Max Technology 3.0 available.
*/
UINT32_t intel_turbo_boost_max_technology_3_available : 1;
#define CPUID_EAX_INTEL_TURBO_BOOST_MAX_TECHNOLOGY_3_AVAILABLE_BIT 14
#define CPUID_EAX_INTEL_TURBO_BOOST_MAX_TECHNOLOGY_3_AVAILABLE_FLAG 0x4000
#define CPUID_EAX_INTEL_TURBO_BOOST_MAX_TECHNOLOGY_3_AVAILABLE_MASK 0x01
#define CPUID_EAX_INTEL_TURBO_BOOST_MAX_TECHNOLOGY_3_AVAILABLE(_) (((_) >> 14) & 0x01)
/**
* [Bit 15] HWP Capabilities. Highest Performance change is supported if set.
*/
UINT32_t hwp_capabilities : 1;
#define CPUID_EAX_HWP_CAPABILITIES_BIT 15
#define CPUID_EAX_HWP_CAPABILITIES_FLAG 0x8000
#define CPUID_EAX_HWP_CAPABILITIES_MASK 0x01
#define CPUID_EAX_HWP_CAPABILITIES(_) (((_) >> 15) & 0x01)
/**
* [Bit 16] HWP PECI override is supported if set.
*/
UINT32_t hwp_peci_override : 1;
#define CPUID_EAX_HWP_PECI_OVERRIDE_BIT 16
#define CPUID_EAX_HWP_PECI_OVERRIDE_FLAG 0x10000
#define CPUID_EAX_HWP_PECI_OVERRIDE_MASK 0x01
#define CPUID_EAX_HWP_PECI_OVERRIDE(_) (((_) >> 16) & 0x01)
/**
* [Bit 17] Flexible HWP is supported if set.
*/
UINT32_t flexible_hwp : 1;
#define CPUID_EAX_FLEXIBLE_HWP_BIT 17
#define CPUID_EAX_FLEXIBLE_HWP_FLAG 0x20000
#define CPUID_EAX_FLEXIBLE_HWP_MASK 0x01
#define CPUID_EAX_FLEXIBLE_HWP(_) (((_) >> 17) & 0x01)
/**
* [Bit 18] Fast access mode for the IA32_HWP_REQUEST MSR is supported if set.
*/
UINT32_t fast_access_mode_for_hwp_request_msr : 1;
#define CPUID_EAX_FAST_ACCESS_MODE_FOR_HWP_REQUEST_MSR_BIT 18
#define CPUID_EAX_FAST_ACCESS_MODE_FOR_HWP_REQUEST_MSR_FLAG 0x40000
#define CPUID_EAX_FAST_ACCESS_MODE_FOR_HWP_REQUEST_MSR_MASK 0x01
#define CPUID_EAX_FAST_ACCESS_MODE_FOR_HWP_REQUEST_MSR(_) (((_) >> 18) & 0x01)
UINT32_t reserved3 : 1;
/**
* [Bit 20] Ignoring Idle Logical Processor HWP request is supported if set.
*/
UINT32_t ignoring_idle_logical_processor_hwp_request : 1;
#define CPUID_EAX_IGNORING_IDLE_LOGICAL_PROCESSOR_HWP_REQUEST_BIT 20
#define CPUID_EAX_IGNORING_IDLE_LOGICAL_PROCESSOR_HWP_REQUEST_FLAG 0x100000
#define CPUID_EAX_IGNORING_IDLE_LOGICAL_PROCESSOR_HWP_REQUEST_MASK 0x01
#define CPUID_EAX_IGNORING_IDLE_LOGICAL_PROCESSOR_HWP_REQUEST(_) (((_) >> 20) & 0x01)
UINT32_t reserved4 : 11;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 3:0] Number of Interrupt Thresholds in Digital Thermal Sensor.
*/
UINT32_t number_of_interrupt_thresholds_in_thermal_sensor : 4;
#define CPUID_EBX_NUMBER_OF_INTERRUPT_THRESHOLDS_IN_THERMAL_SENSOR_BIT 0
#define CPUID_EBX_NUMBER_OF_INTERRUPT_THRESHOLDS_IN_THERMAL_SENSOR_FLAG 0x0F
#define CPUID_EBX_NUMBER_OF_INTERRUPT_THRESHOLDS_IN_THERMAL_SENSOR_MASK 0x0F
#define CPUID_EBX_NUMBER_OF_INTERRUPT_THRESHOLDS_IN_THERMAL_SENSOR(_) (((_) >> 0) & 0x0F)
UINT32_t reserved1 : 28;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] Hardware Coordination Feedback Capability (Presence of IA32_MPERF and IA32_APERF). The capability to provide a
* measure of delivered processor performance (since last reset of the counters), as a percentage of the expected processor
* performance when running at the TSC frequency.
*/
UINT32_t hardware_coordination_feedback_capability : 1;
#define CPUID_ECX_HARDWARE_COORDINATION_FEEDBACK_CAPABILITY_BIT 0
#define CPUID_ECX_HARDWARE_COORDINATION_FEEDBACK_CAPABILITY_FLAG 0x01
#define CPUID_ECX_HARDWARE_COORDINATION_FEEDBACK_CAPABILITY_MASK 0x01
#define CPUID_ECX_HARDWARE_COORDINATION_FEEDBACK_CAPABILITY(_) (((_) >> 0) & 0x01)
UINT32_t reserved1 : 2;
/**
* [Bit 3] The processor supports performance-energy bias preference if CPUID.06H:ECX.SETBH[bit 3] is set and it also
* implies the presence of a new architectural MSR called IA32_ENERGY_PERF_BIAS (1B0H).
*/
UINT32_t performance_energy_bias_preference : 1;
#define CPUID_ECX_PERFORMANCE_ENERGY_BIAS_PREFERENCE_BIT 3
#define CPUID_ECX_PERFORMANCE_ENERGY_BIAS_PREFERENCE_FLAG 0x08
#define CPUID_ECX_PERFORMANCE_ENERGY_BIAS_PREFERENCE_MASK 0x01
#define CPUID_ECX_PERFORMANCE_ENERGY_BIAS_PREFERENCE(_) (((_) >> 3) & 0x01)
UINT32_t reserved2 : 28;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_06;
/**
* @brief Structured Extended Feature Flags Enumeration Leaf (Output depends on ECX input value)
*
* When CPUID executes with EAX set to 07H and ECX = 0, the processor returns information about the maximum input value for
* sub-leaves that contain extended feature flags.
* When CPUID executes with EAX set to 07H and the input value of ECX is invalid (see leaf 07H entry in Table 3-8), the
* processor returns 0 in EAX/EBX/ECX/EDX. In subleaf 0, EAX returns the maximum input value of the highest leaf 7
* sub-leaf, and EBX, ECX & EDX contain information of extended feature flags.
*/
#define CPUID_STRUCTURED_EXTENDED_FEATURE_FLAGS 0x00000007
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reports the maximum input value for supported leaf 7 sub-leaves.
*/
UINT32_t number_of_sub_leaves : 32;
#define CPUID_EAX_NUMBER_OF_SUB_LEAVES_BIT 0
#define CPUID_EAX_NUMBER_OF_SUB_LEAVES_FLAG 0xFFFFFFFF
#define CPUID_EAX_NUMBER_OF_SUB_LEAVES_MASK 0xFFFFFFFF
#define CPUID_EAX_NUMBER_OF_SUB_LEAVES(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bit 0] Supports RDFSBASE/RDGSBASE/WRFSBASE/WRGSBASE if 1.
*/
UINT32_t fsgsbase : 1;
#define CPUID_EBX_FSGSBASE_BIT 0
#define CPUID_EBX_FSGSBASE_FLAG 0x01
#define CPUID_EBX_FSGSBASE_MASK 0x01
#define CPUID_EBX_FSGSBASE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] IA32_TSC_ADJUST MSR is supported if 1.
*/
UINT32_t ia32_tsc_adjust_msr : 1;
#define CPUID_EBX_IA32_TSC_ADJUST_MSR_BIT 1
#define CPUID_EBX_IA32_TSC_ADJUST_MSR_FLAG 0x02
#define CPUID_EBX_IA32_TSC_ADJUST_MSR_MASK 0x01
#define CPUID_EBX_IA32_TSC_ADJUST_MSR(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Supports Intel(R) Software Guard Extensions (Intel(R) SGX Extensions) if 1.
*/
UINT32_t sgx : 1;
#define CPUID_EBX_SGX_BIT 2
#define CPUID_EBX_SGX_FLAG 0x04
#define CPUID_EBX_SGX_MASK 0x01
#define CPUID_EBX_SGX(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] BMI1.
*/
UINT32_t bmi1 : 1;
#define CPUID_EBX_BMI1_BIT 3
#define CPUID_EBX_BMI1_FLAG 0x08
#define CPUID_EBX_BMI1_MASK 0x01
#define CPUID_EBX_BMI1(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] HLE.
*/
UINT32_t hle : 1;
#define CPUID_EBX_HLE_BIT 4
#define CPUID_EBX_HLE_FLAG 0x10
#define CPUID_EBX_HLE_MASK 0x01
#define CPUID_EBX_HLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] AVX2.
*/
UINT32_t avx2 : 1;
#define CPUID_EBX_AVX2_BIT 5
#define CPUID_EBX_AVX2_FLAG 0x20
#define CPUID_EBX_AVX2_MASK 0x01
#define CPUID_EBX_AVX2(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] x87 FPU Data Pointer updated only on x87 exceptions if 1.
*/
UINT32_t fdp_excptn_only : 1;
#define CPUID_EBX_FDP_EXCPTN_ONLY_BIT 6
#define CPUID_EBX_FDP_EXCPTN_ONLY_FLAG 0x40
#define CPUID_EBX_FDP_EXCPTN_ONLY_MASK 0x01
#define CPUID_EBX_FDP_EXCPTN_ONLY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Supports Supervisor-Mode Execution Prevention if 1.
*/
UINT32_t smep : 1;
#define CPUID_EBX_SMEP_BIT 7
#define CPUID_EBX_SMEP_FLAG 0x80
#define CPUID_EBX_SMEP_MASK 0x01
#define CPUID_EBX_SMEP(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] BMI2.
*/
UINT32_t bmi2 : 1;
#define CPUID_EBX_BMI2_BIT 8
#define CPUID_EBX_BMI2_FLAG 0x100
#define CPUID_EBX_BMI2_MASK 0x01
#define CPUID_EBX_BMI2(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Supports Enhanced REP MOVSB/STOSB if 1.
*/
UINT32_t enhanced_rep_movsb_stosb : 1;
#define CPUID_EBX_ENHANCED_REP_MOVSB_STOSB_BIT 9
#define CPUID_EBX_ENHANCED_REP_MOVSB_STOSB_FLAG 0x200
#define CPUID_EBX_ENHANCED_REP_MOVSB_STOSB_MASK 0x01
#define CPUID_EBX_ENHANCED_REP_MOVSB_STOSB(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] If 1, supports INVPCID instruction for system software that manages process-context identifiers.
*/
UINT32_t invpcid : 1;
#define CPUID_EBX_INVPCID_BIT 10
#define CPUID_EBX_INVPCID_FLAG 0x400
#define CPUID_EBX_INVPCID_MASK 0x01
#define CPUID_EBX_INVPCID(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] RTM.
*/
UINT32_t rtm : 1;
#define CPUID_EBX_RTM_BIT 11
#define CPUID_EBX_RTM_FLAG 0x800
#define CPUID_EBX_RTM_MASK 0x01
#define CPUID_EBX_RTM(_) (((_) >> 11) & 0x01)
/**
* [Bit 12] Supports Intel(R) Resource Director Technology (Intel(R) RDT) Monitoring capability if 1.
*/
UINT32_t rdt_m : 1;
#define CPUID_EBX_RDT_M_BIT 12
#define CPUID_EBX_RDT_M_FLAG 0x1000
#define CPUID_EBX_RDT_M_MASK 0x01
#define CPUID_EBX_RDT_M(_) (((_) >> 12) & 0x01)
/**
* [Bit 13] Deprecates FPU CS and FPU DS values if 1.
*/
UINT32_t deprecates : 1;
#define CPUID_EBX_DEPRECATES_BIT 13
#define CPUID_EBX_DEPRECATES_FLAG 0x2000
#define CPUID_EBX_DEPRECATES_MASK 0x01
#define CPUID_EBX_DEPRECATES(_) (((_) >> 13) & 0x01)
/**
* [Bit 14] Supports Intel(R) Memory Protection Extensions if 1.
*/
UINT32_t mpx : 1;
#define CPUID_EBX_MPX_BIT 14
#define CPUID_EBX_MPX_FLAG 0x4000
#define CPUID_EBX_MPX_MASK 0x01
#define CPUID_EBX_MPX(_) (((_) >> 14) & 0x01)
/**
* [Bit 15] Supports Intel(R) Resource Director Technology (Intel(R) RDT) Allocation capability if 1.
*/
UINT32_t rdt : 1;
#define CPUID_EBX_RDT_BIT 15
#define CPUID_EBX_RDT_FLAG 0x8000
#define CPUID_EBX_RDT_MASK 0x01
#define CPUID_EBX_RDT(_) (((_) >> 15) & 0x01)
/**
* [Bit 16] AVX512F.
*/
UINT32_t avx512f : 1;
#define CPUID_EBX_AVX512F_BIT 16
#define CPUID_EBX_AVX512F_FLAG 0x10000
#define CPUID_EBX_AVX512F_MASK 0x01
#define CPUID_EBX_AVX512F(_) (((_) >> 16) & 0x01)
/**
* [Bit 17] AVX512DQ.
*/
UINT32_t avx512dq : 1;
#define CPUID_EBX_AVX512DQ_BIT 17
#define CPUID_EBX_AVX512DQ_FLAG 0x20000
#define CPUID_EBX_AVX512DQ_MASK 0x01
#define CPUID_EBX_AVX512DQ(_) (((_) >> 17) & 0x01)
/**
* [Bit 18] RDSEED.
*/
UINT32_t rdseed : 1;
#define CPUID_EBX_RDSEED_BIT 18
#define CPUID_EBX_RDSEED_FLAG 0x40000
#define CPUID_EBX_RDSEED_MASK 0x01
#define CPUID_EBX_RDSEED(_) (((_) >> 18) & 0x01)
/**
* [Bit 19] ADX.
*/
UINT32_t adx : 1;
#define CPUID_EBX_ADX_BIT 19
#define CPUID_EBX_ADX_FLAG 0x80000
#define CPUID_EBX_ADX_MASK 0x01
#define CPUID_EBX_ADX(_) (((_) >> 19) & 0x01)
/**
* [Bit 20] Supports Supervisor-Mode Access Prevention (and the CLAC/STAC instructions) if 1.
*/
UINT32_t smap : 1;
#define CPUID_EBX_SMAP_BIT 20
#define CPUID_EBX_SMAP_FLAG 0x100000
#define CPUID_EBX_SMAP_MASK 0x01
#define CPUID_EBX_SMAP(_) (((_) >> 20) & 0x01)
/**
* [Bit 21] AVX512_IFMA.
*/
UINT32_t avx512_ifma : 1;
#define CPUID_EBX_AVX512_IFMA_BIT 21
#define CPUID_EBX_AVX512_IFMA_FLAG 0x200000
#define CPUID_EBX_AVX512_IFMA_MASK 0x01
#define CPUID_EBX_AVX512_IFMA(_) (((_) >> 21) & 0x01)
UINT32_t reserved1 : 1;
/**
* [Bit 23] CLFLUSHOPT.
*/
UINT32_t clflushopt : 1;
#define CPUID_EBX_CLFLUSHOPT_BIT 23
#define CPUID_EBX_CLFLUSHOPT_FLAG 0x800000
#define CPUID_EBX_CLFLUSHOPT_MASK 0x01
#define CPUID_EBX_CLFLUSHOPT(_) (((_) >> 23) & 0x01)
/**
* [Bit 24] CLWB.
*/
UINT32_t clwb : 1;
#define CPUID_EBX_CLWB_BIT 24
#define CPUID_EBX_CLWB_FLAG 0x1000000
#define CPUID_EBX_CLWB_MASK 0x01
#define CPUID_EBX_CLWB(_) (((_) >> 24) & 0x01)
/**
* [Bit 25] Intel Processor Trace.
*/
UINT32_t intel : 1;
#define CPUID_EBX_INTEL_BIT 25
#define CPUID_EBX_INTEL_FLAG 0x2000000
#define CPUID_EBX_INTEL_MASK 0x01
#define CPUID_EBX_INTEL(_) (((_) >> 25) & 0x01)
/**
* [Bit 26] (Intel(R) Xeon Phi(TM) only).
*/
UINT32_t avx512pf : 1;
#define CPUID_EBX_AVX512PF_BIT 26
#define CPUID_EBX_AVX512PF_FLAG 0x4000000
#define CPUID_EBX_AVX512PF_MASK 0x01
#define CPUID_EBX_AVX512PF(_) (((_) >> 26) & 0x01)
/**
* [Bit 27] (Intel(R) Xeon Phi(TM) only).
*/
UINT32_t avx512er : 1;
#define CPUID_EBX_AVX512ER_BIT 27
#define CPUID_EBX_AVX512ER_FLAG 0x8000000
#define CPUID_EBX_AVX512ER_MASK 0x01
#define CPUID_EBX_AVX512ER(_) (((_) >> 27) & 0x01)
/**
* [Bit 28] AVX512CD.
*/
UINT32_t avx512cd : 1;
#define CPUID_EBX_AVX512CD_BIT 28
#define CPUID_EBX_AVX512CD_FLAG 0x10000000
#define CPUID_EBX_AVX512CD_MASK 0x01
#define CPUID_EBX_AVX512CD(_) (((_) >> 28) & 0x01)
/**
* [Bit 29] Supports Intel(R) Secure Hash Algorithm Extensions (Intel(R) SHA Extensions) if 1.
*/
UINT32_t sha : 1;
#define CPUID_EBX_SHA_BIT 29
#define CPUID_EBX_SHA_FLAG 0x20000000
#define CPUID_EBX_SHA_MASK 0x01
#define CPUID_EBX_SHA(_) (((_) >> 29) & 0x01)
/**
* [Bit 30] AVX512BW.
*/
UINT32_t avx512bw : 1;
#define CPUID_EBX_AVX512BW_BIT 30
#define CPUID_EBX_AVX512BW_FLAG 0x40000000
#define CPUID_EBX_AVX512BW_MASK 0x01
#define CPUID_EBX_AVX512BW(_) (((_) >> 30) & 0x01)
/**
* [Bit 31] AVX512VL.
*/
UINT32_t avx512vl : 1;
#define CPUID_EBX_AVX512VL_BIT 31
#define CPUID_EBX_AVX512VL_FLAG 0x80000000
#define CPUID_EBX_AVX512VL_MASK 0x01
#define CPUID_EBX_AVX512VL(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] (Intel(R) Xeon Phi(TM) only).
*/
UINT32_t prefetchwt1 : 1;
#define CPUID_ECX_PREFETCHWT1_BIT 0
#define CPUID_ECX_PREFETCHWT1_FLAG 0x01
#define CPUID_ECX_PREFETCHWT1_MASK 0x01
#define CPUID_ECX_PREFETCHWT1(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] AVX512_VBMI.
*/
UINT32_t avx512_vbmi : 1;
#define CPUID_ECX_AVX512_VBMI_BIT 1
#define CPUID_ECX_AVX512_VBMI_FLAG 0x02
#define CPUID_ECX_AVX512_VBMI_MASK 0x01
#define CPUID_ECX_AVX512_VBMI(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Supports user-mode instruction prevention if 1.
*/
UINT32_t umip : 1;
#define CPUID_ECX_UMIP_BIT 2
#define CPUID_ECX_UMIP_FLAG 0x04
#define CPUID_ECX_UMIP_MASK 0x01
#define CPUID_ECX_UMIP(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Supports protection keys for user-mode pages if 1.
*/
UINT32_t pku : 1;
#define CPUID_ECX_PKU_BIT 3
#define CPUID_ECX_PKU_FLAG 0x08
#define CPUID_ECX_PKU_MASK 0x01
#define CPUID_ECX_PKU(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] If 1, OS has set CR4.PKE to enable protection keys (and the RDPKRU/WRPKRU instructions).
*/
UINT32_t ospke : 1;
#define CPUID_ECX_OSPKE_BIT 4
#define CPUID_ECX_OSPKE_FLAG 0x10
#define CPUID_ECX_OSPKE_MASK 0x01
#define CPUID_ECX_OSPKE(_) (((_) >> 4) & 0x01)
UINT32_t reserved1 : 12;
/**
* [Bits 21:17] The value of MAWAU used by the BNDLDX and BNDSTX instructions in 64-bit mode.
*/
UINT32_t mawau : 5;
#define CPUID_ECX_MAWAU_BIT 17
#define CPUID_ECX_MAWAU_FLAG 0x3E0000
#define CPUID_ECX_MAWAU_MASK 0x1F
#define CPUID_ECX_MAWAU(_) (((_) >> 17) & 0x1F)
/**
* [Bit 22] RDPID and IA32_TSC_AUX are available if 1.
*/
UINT32_t rdpid : 1;
#define CPUID_ECX_RDPID_BIT 22
#define CPUID_ECX_RDPID_FLAG 0x400000
#define CPUID_ECX_RDPID_MASK 0x01
#define CPUID_ECX_RDPID(_) (((_) >> 22) & 0x01)
UINT32_t reserved2 : 7;
/**
* [Bit 30] Supports SGX Launch Configuration if 1.
*/
UINT32_t sgx_lc : 1;
#define CPUID_ECX_SGX_LC_BIT 30
#define CPUID_ECX_SGX_LC_FLAG 0x40000000
#define CPUID_ECX_SGX_LC_MASK 0x01
#define CPUID_ECX_SGX_LC(_) (((_) >> 30) & 0x01)
UINT32_t reserved3 : 1;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_07;
/**
* @brief Direct Cache Access Information Leaf
*
* When CPUID executes with EAX set to 09H, the processor returns information about Direct Cache Access capabilities.
*/
#define CPUID_DIRECT_CACHE_ACCESS_INFORMATION 0x00000009
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Value of bits [31:0] of IA32_PLATFORM_DCA_CAP MSR (address 1F8H).
*/
UINT32_t ia32_platform_dca_cap : 32;
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_BIT 0
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_FLAG 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_MASK 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_09;
/**
* @brief Architectural Performance Monitoring Leaf
*
* When CPUID executes with EAX set to 0AH, the processor returns information about support for architectural performance
* monitoring capabilities. Architectural performance monitoring is supported if the version ID is greater than Pn 0. For
* each version of architectural performance monitoring capability, software must enumerate this leaf to discover the
* programming facilities and the architectural performance events available in the processor.
*
* @see Vol3C[23(Introduction to Virtual-Machine Extensions)]
*/
#define CPUID_ARCHITECTURAL_PERFORMANCE_MONITORING 0x0000000A
typedef struct
{
union
{
struct
{
/**
* [Bits 7:0] Version ID of architectural performance monitoring.
*/
UINT32_t version_id_of_architectural_performance_monitoring : 8;
#define CPUID_EAX_VERSION_ID_OF_ARCHITECTURAL_PERFORMANCE_MONITORING_BIT 0
#define CPUID_EAX_VERSION_ID_OF_ARCHITECTURAL_PERFORMANCE_MONITORING_FLAG 0xFF
#define CPUID_EAX_VERSION_ID_OF_ARCHITECTURAL_PERFORMANCE_MONITORING_MASK 0xFF
#define CPUID_EAX_VERSION_ID_OF_ARCHITECTURAL_PERFORMANCE_MONITORING(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Number of general-purpose performance monitoring counter per logical processor.
*/
UINT32_t number_of_performance_monitoring_counter_per_logical_processor : 8;
#define CPUID_EAX_NUMBER_OF_PERFORMANCE_MONITORING_COUNTER_PER_LOGICAL_PROCESSOR_BIT 8
#define CPUID_EAX_NUMBER_OF_PERFORMANCE_MONITORING_COUNTER_PER_LOGICAL_PROCESSOR_FLAG 0xFF00
#define CPUID_EAX_NUMBER_OF_PERFORMANCE_MONITORING_COUNTER_PER_LOGICAL_PROCESSOR_MASK 0xFF
#define CPUID_EAX_NUMBER_OF_PERFORMANCE_MONITORING_COUNTER_PER_LOGICAL_PROCESSOR(_) (((_) >> 8) & 0xFF)
/**
* [Bits 23:16] Bit width of general-purpose, performance monitoring counter.
*/
UINT32_t bit_width_of_performance_monitoring_counter : 8;
#define CPUID_EAX_BIT_WIDTH_OF_PERFORMANCE_MONITORING_COUNTER_BIT 16
#define CPUID_EAX_BIT_WIDTH_OF_PERFORMANCE_MONITORING_COUNTER_FLAG 0xFF0000
#define CPUID_EAX_BIT_WIDTH_OF_PERFORMANCE_MONITORING_COUNTER_MASK 0xFF
#define CPUID_EAX_BIT_WIDTH_OF_PERFORMANCE_MONITORING_COUNTER(_) (((_) >> 16) & 0xFF)
/**
* [Bits 31:24] Length of EBX bit vector to enumerate architectural performance monitoring events.
*/
UINT32_t ebx_bit_vector_length : 8;
#define CPUID_EAX_EBX_BIT_VECTOR_LENGTH_BIT 24
#define CPUID_EAX_EBX_BIT_VECTOR_LENGTH_FLAG 0xFF000000
#define CPUID_EAX_EBX_BIT_VECTOR_LENGTH_MASK 0xFF
#define CPUID_EAX_EBX_BIT_VECTOR_LENGTH(_) (((_) >> 24) & 0xFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bit 0] Core cycle event not available if 1.
*/
UINT32_t core_cycle_event_not_available : 1;
#define CPUID_EBX_CORE_CYCLE_EVENT_NOT_AVAILABLE_BIT 0
#define CPUID_EBX_CORE_CYCLE_EVENT_NOT_AVAILABLE_FLAG 0x01
#define CPUID_EBX_CORE_CYCLE_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_CORE_CYCLE_EVENT_NOT_AVAILABLE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Instruction retired event not available if 1.
*/
UINT32_t instruction_retired_event_not_available : 1;
#define CPUID_EBX_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_BIT 1
#define CPUID_EBX_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_FLAG 0x02
#define CPUID_EBX_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Reference cycles event not available if 1.
*/
UINT32_t reference_cycles_event_not_available : 1;
#define CPUID_EBX_REFERENCE_CYCLES_EVENT_NOT_AVAILABLE_BIT 2
#define CPUID_EBX_REFERENCE_CYCLES_EVENT_NOT_AVAILABLE_FLAG 0x04
#define CPUID_EBX_REFERENCE_CYCLES_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_REFERENCE_CYCLES_EVENT_NOT_AVAILABLE(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Last-level cache reference event not available if 1.
*/
UINT32_t last_level_cache_reference_event_not_available : 1;
#define CPUID_EBX_LAST_LEVEL_CACHE_REFERENCE_EVENT_NOT_AVAILABLE_BIT 3
#define CPUID_EBX_LAST_LEVEL_CACHE_REFERENCE_EVENT_NOT_AVAILABLE_FLAG 0x08
#define CPUID_EBX_LAST_LEVEL_CACHE_REFERENCE_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_LAST_LEVEL_CACHE_REFERENCE_EVENT_NOT_AVAILABLE(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Last-level cache misses event not available if 1.
*/
UINT32_t last_level_cache_misses_event_not_available : 1;
#define CPUID_EBX_LAST_LEVEL_CACHE_MISSES_EVENT_NOT_AVAILABLE_BIT 4
#define CPUID_EBX_LAST_LEVEL_CACHE_MISSES_EVENT_NOT_AVAILABLE_FLAG 0x10
#define CPUID_EBX_LAST_LEVEL_CACHE_MISSES_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_LAST_LEVEL_CACHE_MISSES_EVENT_NOT_AVAILABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Branch instruction retired event not available if 1.
*/
UINT32_t branch_instruction_retired_event_not_available : 1;
#define CPUID_EBX_BRANCH_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_BIT 5
#define CPUID_EBX_BRANCH_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_FLAG 0x20
#define CPUID_EBX_BRANCH_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_BRANCH_INSTRUCTION_RETIRED_EVENT_NOT_AVAILABLE(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Branch mispredict retired event not available if 1.
*/
UINT32_t branch_mispredict_retired_event_not_available : 1;
#define CPUID_EBX_BRANCH_MISPREDICT_RETIRED_EVENT_NOT_AVAILABLE_BIT 6
#define CPUID_EBX_BRANCH_MISPREDICT_RETIRED_EVENT_NOT_AVAILABLE_FLAG 0x40
#define CPUID_EBX_BRANCH_MISPREDICT_RETIRED_EVENT_NOT_AVAILABLE_MASK 0x01
#define CPUID_EBX_BRANCH_MISPREDICT_RETIRED_EVENT_NOT_AVAILABLE(_) (((_) >> 6) & 0x01)
UINT32_t reserved1 : 25;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 4:0] Number of fixed-function performance counters (if Version ID > 1).
*/
UINT32_t number_of_fixed_function_performance_counters : 5;
#define CPUID_EDX_NUMBER_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_BIT 0
#define CPUID_EDX_NUMBER_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_FLAG 0x1F
#define CPUID_EDX_NUMBER_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_MASK 0x1F
#define CPUID_EDX_NUMBER_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS(_) (((_) >> 0) & 0x1F)
/**
* [Bits 12:5] Bit width of fixed-function performance counters (if Version ID > 1).
*/
UINT32_t bit_width_of_fixed_function_performance_counters : 8;
#define CPUID_EDX_BIT_WIDTH_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_BIT 5
#define CPUID_EDX_BIT_WIDTH_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_FLAG 0x1FE0
#define CPUID_EDX_BIT_WIDTH_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS_MASK 0xFF
#define CPUID_EDX_BIT_WIDTH_OF_FIXED_FUNCTION_PERFORMANCE_COUNTERS(_) (((_) >> 5) & 0xFF)
UINT32_t reserved1 : 2;
/**
* [Bit 15] AnyThread deprecation.
*/
UINT32_t any_thread_deprecation : 1;
#define CPUID_EDX_ANY_THREAD_DEPRECATION_BIT 15
#define CPUID_EDX_ANY_THREAD_DEPRECATION_FLAG 0x8000
#define CPUID_EDX_ANY_THREAD_DEPRECATION_MASK 0x01
#define CPUID_EDX_ANY_THREAD_DEPRECATION(_) (((_) >> 15) & 0x01)
UINT32_t reserved2 : 16;
};
UINT32_t flags;
} edx;
} cpuid_eax_0a;
/**
* @brief Extended Topology Enumeration Leaf
*
* When CPUID executes with EAX set to 0BH, the processor returns information about extended topology enumeration data.
* Software must detect the presence of CPUID leaf 0BH by verifying
* - the highest leaf index supported by CPUID is >= 0BH, and
* - CPUID.0BH:EBX[15:0] reports a non-zero value.
*
* @note Most of Leaf 0BH output depends on the initial value in ECX. The EDX output of leaf 0BH is always valid and does
* not vary with input value in ECX. Output value in ECX[7:0] always equals input value in ECX[7:0]. Sub-leaf index 0
* enumerates SMT level. Each subsequent higher sub-leaf index enumerates a higherlevel topological entity in hierarchical
* order. For sub-leaves that return an invalid level-type of 0 in ECX[15:8]; EAX and EBX will return 0. If an input value
* n in ECX returns the invalid level-type of 0 in ECX[15:8], other input values with ECX > n also return 0 in ECX[15:8].
*/
#define CPUID_EXTENDED_TOPOLOGY 0x0000000B
typedef struct
{
union
{
struct
{
/**
* [Bits 4:0] Number of bits to shift right on x2APIC ID to get a unique topology ID of the next level type. All logical
* processors with the same next level ID share current level.
*
* @note Software should use this field (EAX[4:0]) to enumerate processor topology of the system.
*/
UINT32_t x2apic_id_to_unique_topology_id_shift : 5;
#define CPUID_EAX_X2APIC_ID_TO_UNIQUE_TOPOLOGY_ID_SHIFT_BIT 0
#define CPUID_EAX_X2APIC_ID_TO_UNIQUE_TOPOLOGY_ID_SHIFT_FLAG 0x1F
#define CPUID_EAX_X2APIC_ID_TO_UNIQUE_TOPOLOGY_ID_SHIFT_MASK 0x1F
#define CPUID_EAX_X2APIC_ID_TO_UNIQUE_TOPOLOGY_ID_SHIFT(_) (((_) >> 0) & 0x1F)
UINT32_t reserved1 : 27;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 15:0] Number of logical processors at this level type. The number reflects configuration as shipped by Intel.
*
* @note Software must not use EBX[15:0] to enumerate processor topology of the system. This value in this field
* (EBX[15:0]) is only intended for display/diagnostic purposes. The actual number of logical processors available to
* BIOS/OS/Applications may be different from the value of EBX[15:0], depending on software and platform hardware
* configurations.
*/
UINT32_t number_of_logical_processors_at_this_level_type : 16;
#define CPUID_EBX_NUMBER_OF_LOGICAL_PROCESSORS_AT_THIS_LEVEL_TYPE_BIT 0
#define CPUID_EBX_NUMBER_OF_LOGICAL_PROCESSORS_AT_THIS_LEVEL_TYPE_FLAG 0xFFFF
#define CPUID_EBX_NUMBER_OF_LOGICAL_PROCESSORS_AT_THIS_LEVEL_TYPE_MASK 0xFFFF
#define CPUID_EBX_NUMBER_OF_LOGICAL_PROCESSORS_AT_THIS_LEVEL_TYPE(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 7:0] Level number. Same value in ECX input.
*/
UINT32_t level_number : 8;
#define CPUID_ECX_LEVEL_NUMBER_BIT 0
#define CPUID_ECX_LEVEL_NUMBER_FLAG 0xFF
#define CPUID_ECX_LEVEL_NUMBER_MASK 0xFF
#define CPUID_ECX_LEVEL_NUMBER(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Level type.
*
* @note The value of the "level type" field is not related to level numbers in any way, higher "level type" values do not
* mean higher levels. Level type field has the following encoding:
* - 0: Invalid.
* - 1: SMT.
* - 2: Core.
* - 3-255: Reserved.
*/
UINT32_t level_type : 8;
#define CPUID_ECX_LEVEL_TYPE_BIT 8
#define CPUID_ECX_LEVEL_TYPE_FLAG 0xFF00
#define CPUID_ECX_LEVEL_TYPE_MASK 0xFF
#define CPUID_ECX_LEVEL_TYPE(_) (((_) >> 8) & 0xFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] x2APIC ID the current logical processor.
*/
UINT32_t x2apic_id : 32;
#define CPUID_EDX_X2APIC_ID_BIT 0
#define CPUID_EDX_X2APIC_ID_FLAG 0xFFFFFFFF
#define CPUID_EDX_X2APIC_ID_MASK 0xFFFFFFFF
#define CPUID_EDX_X2APIC_ID(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_0b;
/**
* @defgroup cpuid_eax_0d \
* EAX = 0x0D
*
* When CPUID executes with EAX set to 0DH and ECX = 0, the processor returns information about the bit-vector
* representation of all processor state extensions that are supported in the processor and storage size requirements of
* the XSAVE/XRSTOR area.
* When CPUID executes with EAX set to 0DH and ECX = n (n > 1, and is a valid sub-leaf index), the processor returns
* information about the size and offset of each processor extended state save area within the XSAVE/XRSTOR area. Software
* can use the forward-extendable technique depicted below to query the valid sub-leaves and obtain size and offset
* information for each processor extended state save area:
* <pre> For i = 2 to 62 // sub-leaf 1 is reserved IF (CPUID.(EAX=0DH, ECX=0):VECTOR[i] = 1) // VECTOR is the 64-bit value
* of EDX:EAX Execute CPUID.(EAX=0DH, ECX = i) to examine size and offset for sub-leaf i; FI; </pre>
* @{
*/
#define CPUID_EXTENDED_STATE_INFORMATION 0x0000000D
/**
* @brief Processor Extended State Enumeration Main Leaf (EAX = 0DH, ECX = 0)
*/
typedef struct
{
/**
* @brief Reports the supported bits of the lower 32 bits of XCR0. XCR0[n] can be set to 1 only if EAX[n] is 1
*/
union
{
struct
{
/**
* [Bit 0] x87 state.
*/
UINT32_t x87_state : 1;
#define CPUID_EAX_X87_STATE_BIT 0
#define CPUID_EAX_X87_STATE_FLAG 0x01
#define CPUID_EAX_X87_STATE_MASK 0x01
#define CPUID_EAX_X87_STATE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] SSE state.
*/
UINT32_t sse_state : 1;
#define CPUID_EAX_SSE_STATE_BIT 1
#define CPUID_EAX_SSE_STATE_FLAG 0x02
#define CPUID_EAX_SSE_STATE_MASK 0x01
#define CPUID_EAX_SSE_STATE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] AVX state.
*/
UINT32_t avx_state : 1;
#define CPUID_EAX_AVX_STATE_BIT 2
#define CPUID_EAX_AVX_STATE_FLAG 0x04
#define CPUID_EAX_AVX_STATE_MASK 0x01
#define CPUID_EAX_AVX_STATE(_) (((_) >> 2) & 0x01)
/**
* [Bits 4:3] MPX state.
*/
UINT32_t mpx_state : 2;
#define CPUID_EAX_MPX_STATE_BIT 3
#define CPUID_EAX_MPX_STATE_FLAG 0x18
#define CPUID_EAX_MPX_STATE_MASK 0x03
#define CPUID_EAX_MPX_STATE(_) (((_) >> 3) & 0x03)
/**
* [Bits 7:5] AVX-512 state.
*/
UINT32_t avx_512_state : 3;
#define CPUID_EAX_AVX_512_STATE_BIT 5
#define CPUID_EAX_AVX_512_STATE_FLAG 0xE0
#define CPUID_EAX_AVX_512_STATE_MASK 0x07
#define CPUID_EAX_AVX_512_STATE(_) (((_) >> 5) & 0x07)
/**
* [Bit 8] Used for IA32_XSS.
*/
UINT32_t used_for_ia32_xss_1 : 1;
#define CPUID_EAX_USED_FOR_IA32_XSS_1_BIT 8
#define CPUID_EAX_USED_FOR_IA32_XSS_1_FLAG 0x100
#define CPUID_EAX_USED_FOR_IA32_XSS_1_MASK 0x01
#define CPUID_EAX_USED_FOR_IA32_XSS_1(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] PKRU state.
*/
UINT32_t pkru_state : 1;
#define CPUID_EAX_PKRU_STATE_BIT 9
#define CPUID_EAX_PKRU_STATE_FLAG 0x200
#define CPUID_EAX_PKRU_STATE_MASK 0x01
#define CPUID_EAX_PKRU_STATE(_) (((_) >> 9) & 0x01)
UINT32_t reserved1 : 3;
/**
* [Bit 13] Used for IA32_XSS.
*/
UINT32_t used_for_ia32_xss_2 : 1;
#define CPUID_EAX_USED_FOR_IA32_XSS_2_BIT 13
#define CPUID_EAX_USED_FOR_IA32_XSS_2_FLAG 0x2000
#define CPUID_EAX_USED_FOR_IA32_XSS_2_MASK 0x01
#define CPUID_EAX_USED_FOR_IA32_XSS_2(_) (((_) >> 13) & 0x01)
UINT32_t reserved2 : 18;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Maximum size (bytes, from the beginning of the XSAVE/XRSTOR save area) required by enabled features in XCR0.
* May be different than ECX if some features at the end of the XSAVE save area are not enabled.
*/
UINT32_t max_size_required_by_enabled_features_in_xcr0 : 32;
#define CPUID_EBX_MAX_SIZE_REQUIRED_BY_ENABLED_FEATURES_IN_XCR0_BIT 0
#define CPUID_EBX_MAX_SIZE_REQUIRED_BY_ENABLED_FEATURES_IN_XCR0_FLAG 0xFFFFFFFF
#define CPUID_EBX_MAX_SIZE_REQUIRED_BY_ENABLED_FEATURES_IN_XCR0_MASK 0xFFFFFFFF
#define CPUID_EBX_MAX_SIZE_REQUIRED_BY_ENABLED_FEATURES_IN_XCR0(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Maximum size (bytes, from the beginning of the XSAVE/XRSTOR save area) of the XSAVE/XRSTOR save area
* required by all supported features in the processor, i.e., all the valid bit fields in XCR0.
*/
UINT32_t max_size_of_xsave_xrstor_save_area : 32;
#define CPUID_ECX_MAX_SIZE_OF_XSAVE_XRSTOR_SAVE_AREA_BIT 0
#define CPUID_ECX_MAX_SIZE_OF_XSAVE_XRSTOR_SAVE_AREA_FLAG 0xFFFFFFFF
#define CPUID_ECX_MAX_SIZE_OF_XSAVE_XRSTOR_SAVE_AREA_MASK 0xFFFFFFFF
#define CPUID_ECX_MAX_SIZE_OF_XSAVE_XRSTOR_SAVE_AREA(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Reports the supported bits of the upper 32 bits of XCR0. XCR0[n+32] can be set to 1 only if EDX[n] is 1.
*/
UINT32_t xcr0_supported_bits : 32;
#define CPUID_EDX_XCR0_SUPPORTED_BITS_BIT 0
#define CPUID_EDX_XCR0_SUPPORTED_BITS_FLAG 0xFFFFFFFF
#define CPUID_EDX_XCR0_SUPPORTED_BITS_MASK 0xFFFFFFFF
#define CPUID_EDX_XCR0_SUPPORTED_BITS(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_0d_ecx_00;
/**
* @brief Direct Cache Access Information Leaf
*/
typedef struct
{
union
{
struct
{
UINT32_t reserved1 : 1;
/**
* [Bit 1] Supports XSAVEC and the compacted form of XRSTOR if set.
*/
UINT32_t supports_xsavec_and_compacted_xrstor : 1;
#define CPUID_EAX_SUPPORTS_XSAVEC_AND_COMPACTED_XRSTOR_BIT 1
#define CPUID_EAX_SUPPORTS_XSAVEC_AND_COMPACTED_XRSTOR_FLAG 0x02
#define CPUID_EAX_SUPPORTS_XSAVEC_AND_COMPACTED_XRSTOR_MASK 0x01
#define CPUID_EAX_SUPPORTS_XSAVEC_AND_COMPACTED_XRSTOR(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Supports XGETBV with ECX = 1 if set.
*/
UINT32_t supports_xgetbv_with_ecx_1 : 1;
#define CPUID_EAX_SUPPORTS_XGETBV_WITH_ECX_1_BIT 2
#define CPUID_EAX_SUPPORTS_XGETBV_WITH_ECX_1_FLAG 0x04
#define CPUID_EAX_SUPPORTS_XGETBV_WITH_ECX_1_MASK 0x01
#define CPUID_EAX_SUPPORTS_XGETBV_WITH_ECX_1(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Supports XSAVES/XRSTORS and IA32_XSS if set.
*/
UINT32_t supports_xsave_xrstor_and_ia32_xss : 1;
#define CPUID_EAX_SUPPORTS_XSAVE_XRSTOR_AND_IA32_XSS_BIT 3
#define CPUID_EAX_SUPPORTS_XSAVE_XRSTOR_AND_IA32_XSS_FLAG 0x08
#define CPUID_EAX_SUPPORTS_XSAVE_XRSTOR_AND_IA32_XSS_MASK 0x01
#define CPUID_EAX_SUPPORTS_XSAVE_XRSTOR_AND_IA32_XSS(_) (((_) >> 3) & 0x01)
UINT32_t reserved2 : 28;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] The size in bytes of the XSAVE area containing all states enabled by XCRO | IA32_XSS.
*/
UINT32_t size_of_xsave_aread : 32;
#define CPUID_EBX_SIZE_OF_XSAVE_AREAD_BIT 0
#define CPUID_EBX_SIZE_OF_XSAVE_AREAD_FLAG 0xFFFFFFFF
#define CPUID_EBX_SIZE_OF_XSAVE_AREAD_MASK 0xFFFFFFFF
#define CPUID_EBX_SIZE_OF_XSAVE_AREAD(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 7:0] Used for XCR0.
*/
UINT32_t used_for_xcr0_1 : 8;
#define CPUID_ECX_USED_FOR_XCR0_1_BIT 0
#define CPUID_ECX_USED_FOR_XCR0_1_FLAG 0xFF
#define CPUID_ECX_USED_FOR_XCR0_1_MASK 0xFF
#define CPUID_ECX_USED_FOR_XCR0_1(_) (((_) >> 0) & 0xFF)
/**
* [Bit 8] PT state.
*/
UINT32_t pt_state : 1;
#define CPUID_ECX_PT_STATE_BIT 8
#define CPUID_ECX_PT_STATE_FLAG 0x100
#define CPUID_ECX_PT_STATE_MASK 0x01
#define CPUID_ECX_PT_STATE(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Used for XCR0.
*/
UINT32_t used_for_xcr0_2 : 1;
#define CPUID_ECX_USED_FOR_XCR0_2_BIT 9
#define CPUID_ECX_USED_FOR_XCR0_2_FLAG 0x200
#define CPUID_ECX_USED_FOR_XCR0_2_MASK 0x01
#define CPUID_ECX_USED_FOR_XCR0_2(_) (((_) >> 9) & 0x01)
UINT32_t reserved1 : 3;
/**
* [Bit 13] HWP state.
*/
UINT32_t hwp_state : 1;
#define CPUID_ECX_HWP_STATE_BIT 13
#define CPUID_ECX_HWP_STATE_FLAG 0x2000
#define CPUID_ECX_HWP_STATE_MASK 0x01
#define CPUID_ECX_HWP_STATE(_) (((_) >> 13) & 0x01)
UINT32_t reserved2 : 18;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_0d_ecx_01;
/**
* @brief Processor Extended State Enumeration Sub-leaves (EAX = 0DH, ECX = n, n > 1)
*
* @note Leaf 0DH output depends on the initial value in ECX. Each sub-leaf index (starting at position 2) is supported if
* it corresponds to a supported bit in either the XCR0 register or the IA32_XSS MSR.
* If ECX contains an invalid sub-leaf index, EAX/EBX/ECX/EDX return 0. Sub-leaf n (0 <= n <= 31) is invalid if sub-leaf 0
* returns 0 in EAX[n] and sub-leaf 1 returns 0 in ECX[n]. Sub-leaf n (32 <= n <= 63) is invalid if sub-leaf 0 returns 0 in
* EDX[n-32] and sub-leaf 1 returns 0 in EDX[n-32].
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] The size in bytes (from the offset specified in EBX) of the save area for an extended state feature
* associated with a valid sub-leaf index, n.
*/
UINT32_t ia32_platform_dca_cap : 32;
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_BIT 0
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_FLAG 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_MASK 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] The offset in bytes of this extended state component's save area from the beginning of the XSAVE/XRSTOR
* area.
* This field reports 0 if the sub-leaf index, n, does not map to a valid bit in the XCR0 register.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] Is set if the bit n (corresponding to the sub-leaf index) is supported in the IA32_XSS MSR; it is clear if bit n
* is instead supported in XCR0.
*/
UINT32_t ecx_2 : 1;
#define CPUID_ECX_ECX_2_BIT 0
#define CPUID_ECX_ECX_2_FLAG 0x01
#define CPUID_ECX_ECX_2_MASK 0x01
#define CPUID_ECX_ECX_2(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Is set if, when the compacted format of an XSAVE area is used, this extended state component located on the next
* 64-byte boundary following the preceding state component (otherwise, it is located immediately following the preceding
* state component).
*/
UINT32_t ecx_1 : 1;
#define CPUID_ECX_ECX_1_BIT 1
#define CPUID_ECX_ECX_1_FLAG 0x02
#define CPUID_ECX_ECX_1_MASK 0x01
#define CPUID_ECX_ECX_1(_) (((_) >> 1) & 0x01)
UINT32_t reserved1 : 30;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] This field reports 0 if the sub-leaf index, n, is invalid; otherwise it is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_0d_ecx_n;
/**
* @}
*/
/**
* @defgroup cpuid_eax_0f \
* EAX = 0x0F
*
* When CPUID executes with EAX set to 0FH and ECX = 0, the processor returns information about the bit-vector
* representation of QoS monitoring resource types that are supported in the processor and maximum range of RMID values the
* processor can use to monitor of any supported resource types. Each bit, starting from bit 1, corresponds to a specific
* resource type if the bit is set. The bit position corresponds to the sub-leaf index (or ResID) that software must use to
* query QoS monitoring capability available for that type. See Table 3-8.
* When CPUID executes with EAX set to 0FH and ECX = n (n >= 1, and is a valid ResID), the processor returns information
* software can use to program IA32_PQR_ASSOC, IA32_QM_EVTSEL MSRs before reading QoS data from the IA32_QM_CTR MSR.
* @{
*/
#define CPUID_INTEL_RESOURCE_DIRECTOR_TECHNOLOGY_MONITORING_INFORMATION 0x0000000F
/**
* @brief Intel Resource Director Technology (Intel RDT) Monitoring Enumeration Sub-leaf (EAX = 0FH, ECX = 0)
*
* @note Leaf 0FH output depends on the initial value in ECX. Sub-leaf index 0 reports valid resource type starting at bit
* position 1 of EDX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Maximum range (zero-based) of RMID within this physical processor of all types.
*/
UINT32_t rmid_max_range : 32;
#define CPUID_EBX_RMID_MAX_RANGE_BIT 0
#define CPUID_EBX_RMID_MAX_RANGE_FLAG 0xFFFFFFFF
#define CPUID_EBX_RMID_MAX_RANGE_MASK 0xFFFFFFFF
#define CPUID_EBX_RMID_MAX_RANGE(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
UINT32_t reserved1 : 1;
/**
* [Bit 1] Supports L3 Cache Intel RDT Monitoring if 1.
*/
UINT32_t supports_l3_cache_intel_rdt_monitoring : 1;
#define CPUID_EDX_SUPPORTS_L3_CACHE_INTEL_RDT_MONITORING_BIT 1
#define CPUID_EDX_SUPPORTS_L3_CACHE_INTEL_RDT_MONITORING_FLAG 0x02
#define CPUID_EDX_SUPPORTS_L3_CACHE_INTEL_RDT_MONITORING_MASK 0x01
#define CPUID_EDX_SUPPORTS_L3_CACHE_INTEL_RDT_MONITORING(_) (((_) >> 1) & 0x01)
UINT32_t reserved2 : 30;
};
UINT32_t flags;
} edx;
} cpuid_eax_0f_ecx_00;
/**
* @brief L3 Cache Intel RDT Monitoring Capability Enumeration Sub-leaf (EAX = 0FH, ECX = 1)
*
* @note Leaf 0FH output depends on the initial value in ECX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Conversion factor from reported IA32_QM_CTR value to occupancy metric (bytes).
*/
UINT32_t conversion_factor : 32;
#define CPUID_EBX_CONVERSION_FACTOR_BIT 0
#define CPUID_EBX_CONVERSION_FACTOR_FLAG 0xFFFFFFFF
#define CPUID_EBX_CONVERSION_FACTOR_MASK 0xFFFFFFFF
#define CPUID_EBX_CONVERSION_FACTOR(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Maximum range (zero-based) of RMID within this physical processor of all types.
*/
UINT32_t rmid_max_range : 32;
#define CPUID_ECX_RMID_MAX_RANGE_BIT 0
#define CPUID_ECX_RMID_MAX_RANGE_FLAG 0xFFFFFFFF
#define CPUID_ECX_RMID_MAX_RANGE_MASK 0xFFFFFFFF
#define CPUID_ECX_RMID_MAX_RANGE(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bit 0] Supports L3 occupancy monitoring if 1.
*/
UINT32_t supports_l3_occupancy_monitoring : 1;
#define CPUID_EDX_SUPPORTS_L3_OCCUPANCY_MONITORING_BIT 0
#define CPUID_EDX_SUPPORTS_L3_OCCUPANCY_MONITORING_FLAG 0x01
#define CPUID_EDX_SUPPORTS_L3_OCCUPANCY_MONITORING_MASK 0x01
#define CPUID_EDX_SUPPORTS_L3_OCCUPANCY_MONITORING(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Supports L3 Total Bandwidth monitoring if 1.
*/
UINT32_t supports_l3_total_bandwidth_monitoring : 1;
#define CPUID_EDX_SUPPORTS_L3_TOTAL_BANDWIDTH_MONITORING_BIT 1
#define CPUID_EDX_SUPPORTS_L3_TOTAL_BANDWIDTH_MONITORING_FLAG 0x02
#define CPUID_EDX_SUPPORTS_L3_TOTAL_BANDWIDTH_MONITORING_MASK 0x01
#define CPUID_EDX_SUPPORTS_L3_TOTAL_BANDWIDTH_MONITORING(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Supports L3 Local Bandwidth monitoring if 1.
*/
UINT32_t supports_l3_local_bandwidth_monitoring : 1;
#define CPUID_EDX_SUPPORTS_L3_LOCAL_BANDWIDTH_MONITORING_BIT 2
#define CPUID_EDX_SUPPORTS_L3_LOCAL_BANDWIDTH_MONITORING_FLAG 0x04
#define CPUID_EDX_SUPPORTS_L3_LOCAL_BANDWIDTH_MONITORING_MASK 0x01
#define CPUID_EDX_SUPPORTS_L3_LOCAL_BANDWIDTH_MONITORING(_) (((_) >> 2) & 0x01)
UINT32_t reserved1 : 29;
};
UINT32_t flags;
} edx;
} cpuid_eax_0f_ecx_01;
/**
* @}
*/
/**
* @defgroup cpuid_eax_10 \
* EAX = 0x10
*
* When CPUID executes with EAX set to 10H and ECX = 0, the processor returns information about the bit-vector
* representation of QoS Enforcement resource types that are supported in the processor. Each bit, starting from bit 1,
* corresponds to a specific resource type if the bit is set. The bit position corresponds to the sub-leaf index (or ResID)
* that software must use to query QoS enforcement capability available for that type.
* When CPUID executes with EAX set to 10H and ECX = n (n >= 1, and is a valid ResID), the processor returns information
* about available classes of service and range of QoS mask MSRs that software can use to configure each class of services
* using capability bit masks in the QoS Mask registers, IA32_resourceType_Mask_n.
* @{
*/
#define CPUID_INTEL_RESOURCE_DIRECTOR_TECHNOLOGY_ALLOCATION_INFORMATION 0x00000010
/**
* @brief Intel Resource Director Technology (Intel RDT) Allocation Enumeration Sub-leaf (EAX = 10H, ECX = 0)
*
* @note Leaf 10H output depends on the initial value in ECX. Sub-leaf index 0 reports valid resource identification
* (ResID) starting at bit position 1 of EBX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Value of bits [31:0] of IA32_PLATFORM_DCA_CAP MSR (address 1F8H).
*/
UINT32_t ia32_platform_dca_cap : 32;
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_BIT 0
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_FLAG 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP_MASK 0xFFFFFFFF
#define CPUID_EAX_IA32_PLATFORM_DCA_CAP(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
UINT32_t reserved1 : 1;
/**
* [Bit 1] Supports L3 Cache Allocation Technology if 1.
*/
UINT32_t supports_l3_cache_allocation_technology : 1;
#define CPUID_EBX_SUPPORTS_L3_CACHE_ALLOCATION_TECHNOLOGY_BIT 1
#define CPUID_EBX_SUPPORTS_L3_CACHE_ALLOCATION_TECHNOLOGY_FLAG 0x02
#define CPUID_EBX_SUPPORTS_L3_CACHE_ALLOCATION_TECHNOLOGY_MASK 0x01
#define CPUID_EBX_SUPPORTS_L3_CACHE_ALLOCATION_TECHNOLOGY(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Supports L2 Cache Allocation Technology if 1.
*/
UINT32_t supports_l2_cache_allocation_technology : 1;
#define CPUID_EBX_SUPPORTS_L2_CACHE_ALLOCATION_TECHNOLOGY_BIT 2
#define CPUID_EBX_SUPPORTS_L2_CACHE_ALLOCATION_TECHNOLOGY_FLAG 0x04
#define CPUID_EBX_SUPPORTS_L2_CACHE_ALLOCATION_TECHNOLOGY_MASK 0x01
#define CPUID_EBX_SUPPORTS_L2_CACHE_ALLOCATION_TECHNOLOGY(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Supports Memory Bandwidth Allocation if 1.
*/
UINT32_t supports_memory_bandwidth_allocation : 1;
#define CPUID_EBX_SUPPORTS_MEMORY_BANDWIDTH_ALLOCATION_BIT 3
#define CPUID_EBX_SUPPORTS_MEMORY_BANDWIDTH_ALLOCATION_FLAG 0x08
#define CPUID_EBX_SUPPORTS_MEMORY_BANDWIDTH_ALLOCATION_MASK 0x01
#define CPUID_EBX_SUPPORTS_MEMORY_BANDWIDTH_ALLOCATION(_) (((_) >> 3) & 0x01)
UINT32_t reserved2 : 28;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_10_ecx_00;
/**
* @brief L3 Cache Allocation Technology Enumeration Sub-leaf (EAX = 10H, ECX = ResID = 1)
*
* @note Leaf 10H output depends on the initial value in ECX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 4:0] Length of the capacity bit mask for the corresponding ResID using minus-one notation.
*/
UINT32_t length_of_capacity_bit_mask : 5;
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_BIT 0
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_FLAG 0x1F
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_MASK 0x1F
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK(_) (((_) >> 0) & 0x1F)
UINT32_t reserved1 : 27;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Bit-granular map of isolation/contention of allocation units.
*/
UINT32_t ebx_0 : 32;
#define CPUID_EBX_EBX_0_BIT 0
#define CPUID_EBX_EBX_0_FLAG 0xFFFFFFFF
#define CPUID_EBX_EBX_0_MASK 0xFFFFFFFF
#define CPUID_EBX_EBX_0(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
UINT32_t reserved1 : 2;
/**
* [Bit 2] Code and Data Prioritization Technology supported if 1.
*/
UINT32_t code_and_data_priorization_technology_supported : 1;
#define CPUID_ECX_CODE_AND_DATA_PRIORIZATION_TECHNOLOGY_SUPPORTED_BIT 2
#define CPUID_ECX_CODE_AND_DATA_PRIORIZATION_TECHNOLOGY_SUPPORTED_FLAG 0x04
#define CPUID_ECX_CODE_AND_DATA_PRIORIZATION_TECHNOLOGY_SUPPORTED_MASK 0x01
#define CPUID_ECX_CODE_AND_DATA_PRIORIZATION_TECHNOLOGY_SUPPORTED(_) (((_) >> 2) & 0x01)
UINT32_t reserved2 : 29;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 15:0] Highest COS number supported for this ResID.
*/
UINT32_t highest_cos_number_supported : 16;
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_BIT 0
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_FLAG 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_MASK 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} edx;
} cpuid_eax_10_ecx_01;
/**
* @brief L2 Cache Allocation Technology Enumeration Sub-leaf (EAX = 10H, ECX = ResID = 2)
*
* @note Leaf 10H output depends on the initial value in ECX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 4:0] Length of the capacity bit mask for the corresponding ResID using minus-one notation.
*/
UINT32_t length_of_capacity_bit_mask : 5;
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_BIT 0
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_FLAG 0x1F
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK_MASK 0x1F
#define CPUID_EAX_LENGTH_OF_CAPACITY_BIT_MASK(_) (((_) >> 0) & 0x1F)
UINT32_t reserved1 : 27;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Bit-granular map of isolation/contention of allocation units.
*/
UINT32_t ebx_0 : 32;
#define CPUID_EBX_EBX_0_BIT 0
#define CPUID_EBX_EBX_0_FLAG 0xFFFFFFFF
#define CPUID_EBX_EBX_0_MASK 0xFFFFFFFF
#define CPUID_EBX_EBX_0(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 15:0] Highest COS number supported for this ResID.
*/
UINT32_t highest_cos_number_supported : 16;
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_BIT 0
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_FLAG 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_MASK 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} edx;
} cpuid_eax_10_ecx_02;
/**
* @brief Memory Bandwidth Allocation Enumeration Sub-leaf (EAX = 10H, ECX = ResID = 3)
*
* @note Leaf 10H output depends on the initial value in ECX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 11:0] Reports the maximum MBA throttling value supported for the corresponding ResID using minus-one notation.
*/
UINT32_t max_mba_throttling_value : 12;
#define CPUID_EAX_MAX_MBA_THROTTLING_VALUE_BIT 0
#define CPUID_EAX_MAX_MBA_THROTTLING_VALUE_FLAG 0xFFF
#define CPUID_EAX_MAX_MBA_THROTTLING_VALUE_MASK 0xFFF
#define CPUID_EAX_MAX_MBA_THROTTLING_VALUE(_) (((_) >> 0) & 0xFFF)
UINT32_t reserved1 : 20;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
UINT32_t reserved1 : 2;
/**
* [Bit 2] Reports whether the response of the delay values is linear.
*/
UINT32_t response_of_delay_is_linear : 1;
#define CPUID_ECX_RESPONSE_OF_DELAY_IS_LINEAR_BIT 2
#define CPUID_ECX_RESPONSE_OF_DELAY_IS_LINEAR_FLAG 0x04
#define CPUID_ECX_RESPONSE_OF_DELAY_IS_LINEAR_MASK 0x01
#define CPUID_ECX_RESPONSE_OF_DELAY_IS_LINEAR(_) (((_) >> 2) & 0x01)
UINT32_t reserved2 : 29;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 15:0] Highest COS number supported for this ResID.
*/
UINT32_t highest_cos_number_supported : 16;
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_BIT 0
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_FLAG 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED_MASK 0xFFFF
#define CPUID_EDX_HIGHEST_COS_NUMBER_SUPPORTED(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} edx;
} cpuid_eax_10_ecx_03;
/**
* @}
*/
/**
* @defgroup cpuid_eax_12 \
* EAX = 0x12
*
* When CPUID executes with EAX set to 12H and ECX = 0H, the processor returns information about Intel SGX capabilities.
* When CPUID executes with EAX set to 12H and ECX = 1H, the processor returns information about Intel SGX attributes.
* When CPUID executes with EAX set to 12H and ECX = n (n > 1), the processor returns information about Intel SGX Enclave
* Page Cache.
* @{
*/
#define CPUID_INTEL_SGX 0x00000012
/**
* @brief Intel SGX Capability Enumeration Leaf, sub-leaf 0 (EAX = 12H, ECX = 0)
*
* @note Leaf 12H sub-leaf 0 (ECX = 0) is supported if CPUID.(EAX=07H, ECX=0H):EBX[SGX] = 1.
*/
typedef struct
{
union
{
struct
{
/**
* [Bit 0] If 1, Indicates Intel SGX supports the collection of SGX1 leaf functions.
*/
UINT32_t sgx1 : 1;
#define CPUID_EAX_SGX1_BIT 0
#define CPUID_EAX_SGX1_FLAG 0x01
#define CPUID_EAX_SGX1_MASK 0x01
#define CPUID_EAX_SGX1(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] If 1, Indicates Intel SGX supports the collection of SGX2 leaf functions.
*/
UINT32_t sgx2 : 1;
#define CPUID_EAX_SGX2_BIT 1
#define CPUID_EAX_SGX2_FLAG 0x02
#define CPUID_EAX_SGX2_MASK 0x01
#define CPUID_EAX_SGX2(_) (((_) >> 1) & 0x01)
UINT32_t reserved1 : 3;
/**
* [Bit 5] If 1, indicates Intel SGX supports ENCLV instruction leaves EINCVIRTCHILD, EDECVIRTCHILD, and ESETCONTEXT.
*/
UINT32_t sgx_enclv_advanced : 1;
#define CPUID_EAX_SGX_ENCLV_ADVANCED_BIT 5
#define CPUID_EAX_SGX_ENCLV_ADVANCED_FLAG 0x20
#define CPUID_EAX_SGX_ENCLV_ADVANCED_MASK 0x01
#define CPUID_EAX_SGX_ENCLV_ADVANCED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] If 1, indicates Intel SGX supports ENCLS instruction leaves ETRACKC, ERDINFO, ELDBC, and ELDUC.
*/
UINT32_t sgx_encls_advanced : 1;
#define CPUID_EAX_SGX_ENCLS_ADVANCED_BIT 6
#define CPUID_EAX_SGX_ENCLS_ADVANCED_FLAG 0x40
#define CPUID_EAX_SGX_ENCLS_ADVANCED_MASK 0x01
#define CPUID_EAX_SGX_ENCLS_ADVANCED(_) (((_) >> 6) & 0x01)
UINT32_t reserved2 : 25;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Bit vector of supported extended SGX features.
*/
UINT32_t miscselect : 32;
#define CPUID_EBX_MISCSELECT_BIT 0
#define CPUID_EBX_MISCSELECT_FLAG 0xFFFFFFFF
#define CPUID_EBX_MISCSELECT_MASK 0xFFFFFFFF
#define CPUID_EBX_MISCSELECT(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 7:0] The maximum supported enclave size in non-64-bit mode is 2^(EDX[7:0]).
*/
UINT32_t max_enclave_size_not64 : 8;
#define CPUID_EDX_MAX_ENCLAVE_SIZE_NOT64_BIT 0
#define CPUID_EDX_MAX_ENCLAVE_SIZE_NOT64_FLAG 0xFF
#define CPUID_EDX_MAX_ENCLAVE_SIZE_NOT64_MASK 0xFF
#define CPUID_EDX_MAX_ENCLAVE_SIZE_NOT64(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] The maximum supported enclave size in 64-bit mode is 2^(EDX[15:8]).
*/
UINT32_t max_enclave_size_64 : 8;
#define CPUID_EDX_MAX_ENCLAVE_SIZE_64_BIT 8
#define CPUID_EDX_MAX_ENCLAVE_SIZE_64_FLAG 0xFF00
#define CPUID_EDX_MAX_ENCLAVE_SIZE_64_MASK 0xFF
#define CPUID_EDX_MAX_ENCLAVE_SIZE_64(_) (((_) >> 8) & 0xFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} edx;
} cpuid_eax_12_ecx_00;
/**
* @brief Intel SGX Attributes Enumeration Leaf, sub-leaf 1 (EAX = 12H, ECX = 1)
*
* @note Leaf 12H sub-leaf 1 (ECX = 1) is supported if CPUID.(EAX=07H, ECX=0H):EBX[SGX] = 1.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reports the valid bits of SECS.ATTRIBUTES[31:0] that software can set with ECREATE.
*/
UINT32_t valid_secs_attributes_0 : 32;
#define CPUID_EAX_VALID_SECS_ATTRIBUTES_0_BIT 0
#define CPUID_EAX_VALID_SECS_ATTRIBUTES_0_FLAG 0xFFFFFFFF
#define CPUID_EAX_VALID_SECS_ATTRIBUTES_0_MASK 0xFFFFFFFF
#define CPUID_EAX_VALID_SECS_ATTRIBUTES_0(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Reports the valid bits of SECS.ATTRIBUTES[63:32] that software can set with ECREATE.
*/
UINT32_t valid_secs_attributes_1 : 32;
#define CPUID_EBX_VALID_SECS_ATTRIBUTES_1_BIT 0
#define CPUID_EBX_VALID_SECS_ATTRIBUTES_1_FLAG 0xFFFFFFFF
#define CPUID_EBX_VALID_SECS_ATTRIBUTES_1_MASK 0xFFFFFFFF
#define CPUID_EBX_VALID_SECS_ATTRIBUTES_1(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Reports the valid bits of SECS.ATTRIBUTES[95:64] that software can set with ECREATE.
*/
UINT32_t valid_secs_attributes_2 : 32;
#define CPUID_ECX_VALID_SECS_ATTRIBUTES_2_BIT 0
#define CPUID_ECX_VALID_SECS_ATTRIBUTES_2_FLAG 0xFFFFFFFF
#define CPUID_ECX_VALID_SECS_ATTRIBUTES_2_MASK 0xFFFFFFFF
#define CPUID_ECX_VALID_SECS_ATTRIBUTES_2(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Reports the valid bits of SECS.ATTRIBUTES[127:96] that software can set with ECREATE.
*/
UINT32_t valid_secs_attributes_3 : 32;
#define CPUID_EDX_VALID_SECS_ATTRIBUTES_3_BIT 0
#define CPUID_EDX_VALID_SECS_ATTRIBUTES_3_FLAG 0xFFFFFFFF
#define CPUID_EDX_VALID_SECS_ATTRIBUTES_3_MASK 0xFFFFFFFF
#define CPUID_EDX_VALID_SECS_ATTRIBUTES_3(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_12_ecx_01;
/**
* @brief Intel SGX EPC Enumeration Leaf, sub-leaves (EAX = 12H, ECX = 2 or higher)
*
* @note Leaf 12H sub-leaf 2 or higher (ECX >= 2) is supported if CPUID.(EAX=07H, ECX=0H):EBX[SGX] = 1.
* This structure describes sub-leaf type 0.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 3:0] Sub-leaf Type 0. Indicates this sub-leaf is invalid.
*/
UINT32_t sub_leaf_type : 4;
#define CPUID_EAX_SUB_LEAF_TYPE_BIT 0
#define CPUID_EAX_SUB_LEAF_TYPE_FLAG 0x0F
#define CPUID_EAX_SUB_LEAF_TYPE_MASK 0x0F
#define CPUID_EAX_SUB_LEAF_TYPE(_) (((_) >> 0) & 0x0F)
UINT32_t reserved1 : 28;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is zero.
*/
UINT32_t zero : 32;
#define CPUID_EBX_ZERO_BIT 0
#define CPUID_EBX_ZERO_FLAG 0xFFFFFFFF
#define CPUID_EBX_ZERO_MASK 0xFFFFFFFF
#define CPUID_EBX_ZERO(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is zero.
*/
UINT32_t zero : 32;
#define CPUID_ECX_ZERO_BIT 0
#define CPUID_ECX_ZERO_FLAG 0xFFFFFFFF
#define CPUID_ECX_ZERO_MASK 0xFFFFFFFF
#define CPUID_ECX_ZERO(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is zero.
*/
UINT32_t zero : 32;
#define CPUID_EDX_ZERO_BIT 0
#define CPUID_EDX_ZERO_FLAG 0xFFFFFFFF
#define CPUID_EDX_ZERO_MASK 0xFFFFFFFF
#define CPUID_EDX_ZERO(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_12_ecx_02p_slt_0;
/**
* @brief Intel SGX EPC Enumeration Leaf, sub-leaves (EAX = 12H, ECX = 2 or higher)
*
* @note Leaf 12H sub-leaf 2 or higher (ECX >= 2) is supported if CPUID.(EAX=07H, ECX=0H):EBX[SGX] = 1.
* This structure describes sub-leaf type 1.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 3:0] Sub-leaf Type 1. This sub-leaf enumerates an EPC section. EBX:EAX and EDX:ECX provide information on the
* Enclave Page Cache (EPC) section.
*/
UINT32_t sub_leaf_type : 4;
#define CPUID_EAX_SUB_LEAF_TYPE_BIT 0
#define CPUID_EAX_SUB_LEAF_TYPE_FLAG 0x0F
#define CPUID_EAX_SUB_LEAF_TYPE_MASK 0x0F
#define CPUID_EAX_SUB_LEAF_TYPE(_) (((_) >> 0) & 0x0F)
UINT32_t reserved1 : 8;
/**
* [Bits 31:12] Bits 31:12 of the physical address of the base of the EPC section.
*/
UINT32_t epc_base_physical_address_1 : 20;
#define CPUID_EAX_EPC_BASE_PHYSICAL_ADDRESS_1_BIT 12
#define CPUID_EAX_EPC_BASE_PHYSICAL_ADDRESS_1_FLAG 0xFFFFF000
#define CPUID_EAX_EPC_BASE_PHYSICAL_ADDRESS_1_MASK 0xFFFFF
#define CPUID_EAX_EPC_BASE_PHYSICAL_ADDRESS_1(_) (((_) >> 12) & 0xFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 19:0] Bits 51:32 of the physical address of the base of the EPC section.
*/
UINT32_t epc_base_physical_address_2 : 20;
#define CPUID_EBX_EPC_BASE_PHYSICAL_ADDRESS_2_BIT 0
#define CPUID_EBX_EPC_BASE_PHYSICAL_ADDRESS_2_FLAG 0xFFFFF
#define CPUID_EBX_EPC_BASE_PHYSICAL_ADDRESS_2_MASK 0xFFFFF
#define CPUID_EBX_EPC_BASE_PHYSICAL_ADDRESS_2(_) (((_) >> 0) & 0xFFFFF)
UINT32_t reserved1 : 12;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 3:0] EPC section property encoding defined as follows:
* - If EAX[3:0] 0000b, then all bits of the EDX:ECX pair are enumerated as 0.
* - If EAX[3:0] 0001b, then this section has confidentiality and integrity protection.
* All other encodings are reserved.
*/
UINT32_t epc_section_property : 4;
#define CPUID_ECX_EPC_SECTION_PROPERTY_BIT 0
#define CPUID_ECX_EPC_SECTION_PROPERTY_FLAG 0x0F
#define CPUID_ECX_EPC_SECTION_PROPERTY_MASK 0x0F
#define CPUID_ECX_EPC_SECTION_PROPERTY(_) (((_) >> 0) & 0x0F)
UINT32_t reserved1 : 8;
/**
* [Bits 31:12] Bits 31:12 of the size of the corresponding EPC section within the Processor Reserved Memory.
*/
UINT32_t epc_size_1 : 20;
#define CPUID_ECX_EPC_SIZE_1_BIT 12
#define CPUID_ECX_EPC_SIZE_1_FLAG 0xFFFFF000
#define CPUID_ECX_EPC_SIZE_1_MASK 0xFFFFF
#define CPUID_ECX_EPC_SIZE_1(_) (((_) >> 12) & 0xFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 19:0] Bits 51:32 of the size of the corresponding EPC section within the Processor Reserved Memory.
*/
UINT32_t epc_size_2 : 20;
#define CPUID_EDX_EPC_SIZE_2_BIT 0
#define CPUID_EDX_EPC_SIZE_2_FLAG 0xFFFFF
#define CPUID_EDX_EPC_SIZE_2_MASK 0xFFFFF
#define CPUID_EDX_EPC_SIZE_2(_) (((_) >> 0) & 0xFFFFF)
UINT32_t reserved1 : 12;
};
UINT32_t flags;
} edx;
} cpuid_eax_12_ecx_02p_slt_1;
/**
* @}
*/
/**
* @defgroup cpuid_eax_14 \
* EAX = 0x14
*
* When CPUID executes with EAX set to 14H and ECX = 0H, the processor returns information about Intel Processor Trace
* extensions.
* When CPUID executes with EAX set to 14H and ECX = n (n > 0 and less than the number of non-zero bits in CPUID.(EAX=14H,
* ECX= 0H).EAX), the processor returns information about packet generation in Intel Processor Trace.
* @{
*/
#define CPUID_INTEL_PROCESSOR_TRACE_INFORMATION 0x00000014
/**
* @brief Intel Processor Trace Enumeration Main Leaf (EAX = 14H, ECX = 0)
*
* @note Leaf 14H main leaf (ECX = 0).
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reports the maximum sub-leaf supported in leaf 14H.
*/
UINT32_t max_sub_leaf : 32;
#define CPUID_EAX_MAX_SUB_LEAF_BIT 0
#define CPUID_EAX_MAX_SUB_LEAF_FLAG 0xFFFFFFFF
#define CPUID_EAX_MAX_SUB_LEAF_MASK 0xFFFFFFFF
#define CPUID_EAX_MAX_SUB_LEAF(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bit 0] If 1, indicates that IA32_RTIT_CTL.CR3Filter can be set to 1, and that IA32_RTIT_CR3_MATCH MSR can be accessed.
*/
UINT32_t flag0 : 1;
#define CPUID_EBX_FLAG0_BIT 0
#define CPUID_EBX_FLAG0_FLAG 0x01
#define CPUID_EBX_FLAG0_MASK 0x01
#define CPUID_EBX_FLAG0(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] If 1, indicates support of Configurable PSB and Cycle-Accurate Mode.
*/
UINT32_t flag1 : 1;
#define CPUID_EBX_FLAG1_BIT 1
#define CPUID_EBX_FLAG1_FLAG 0x02
#define CPUID_EBX_FLAG1_MASK 0x01
#define CPUID_EBX_FLAG1(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If 1, indicates support of IP Filtering, TraceStop filtering, and preservation of Intel PT MSRs across warm
* reset.
*/
UINT32_t flag2 : 1;
#define CPUID_EBX_FLAG2_BIT 2
#define CPUID_EBX_FLAG2_FLAG 0x04
#define CPUID_EBX_FLAG2_MASK 0x01
#define CPUID_EBX_FLAG2(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] If 1, indicates support of MTC timing packet and suppression of COFI-based packets.
*/
UINT32_t flag3 : 1;
#define CPUID_EBX_FLAG3_BIT 3
#define CPUID_EBX_FLAG3_FLAG 0x08
#define CPUID_EBX_FLAG3_MASK 0x01
#define CPUID_EBX_FLAG3(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] If 1, indicates support of PTWRITE. Writes can set IA32_RTIT_CTL[12] (PTWEn) and IA32_RTIT_CTL[5] (FUPonPTW),
* and PTWRITE can generate packets.
*/
UINT32_t flag4 : 1;
#define CPUID_EBX_FLAG4_BIT 4
#define CPUID_EBX_FLAG4_FLAG 0x10
#define CPUID_EBX_FLAG4_MASK 0x01
#define CPUID_EBX_FLAG4(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] If 1, indicates support of Power Event Trace. Writes can set IA32_RTIT_CTL[4] (PwrEvtEn), enabling Power Event
* Trace packet generation.
*/
UINT32_t flag5 : 1;
#define CPUID_EBX_FLAG5_BIT 5
#define CPUID_EBX_FLAG5_FLAG 0x20
#define CPUID_EBX_FLAG5_MASK 0x01
#define CPUID_EBX_FLAG5(_) (((_) >> 5) & 0x01)
UINT32_t reserved1 : 26;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] If 1, Tracing can be enabled with IA32_RTIT_CTL.ToPA = 1, hence utilizing the ToPA output scheme;
* IA32_RTIT_OUTPUT_BASE and IA32_RTIT_OUTPUT_MASK_PTRS MSRs can be accessed.
*/
UINT32_t flag0 : 1;
#define CPUID_ECX_FLAG0_BIT 0
#define CPUID_ECX_FLAG0_FLAG 0x01
#define CPUID_ECX_FLAG0_MASK 0x01
#define CPUID_ECX_FLAG0(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] If 1, ToPA tables can hold any number of output entries, up to the maximum allowed by the MaskOrTableOffset
* field of IA32_RTIT_OUTPUT_MASK_PTRS.
*/
UINT32_t flag1 : 1;
#define CPUID_ECX_FLAG1_BIT 1
#define CPUID_ECX_FLAG1_FLAG 0x02
#define CPUID_ECX_FLAG1_MASK 0x01
#define CPUID_ECX_FLAG1(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If 1, indicates support of Single-Range Output scheme.
*/
UINT32_t flag2 : 1;
#define CPUID_ECX_FLAG2_BIT 2
#define CPUID_ECX_FLAG2_FLAG 0x04
#define CPUID_ECX_FLAG2_MASK 0x01
#define CPUID_ECX_FLAG2(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] If 1, indicates support of output to Trace Transport subsystem.
*/
UINT32_t flag3 : 1;
#define CPUID_ECX_FLAG3_BIT 3
#define CPUID_ECX_FLAG3_FLAG 0x08
#define CPUID_ECX_FLAG3_MASK 0x01
#define CPUID_ECX_FLAG3(_) (((_) >> 3) & 0x01)
UINT32_t reserved1 : 27;
/**
* [Bit 31] If 1, generated packets which contain IP payloads have LIP values, which include the CS base component.
*/
UINT32_t flag31 : 1;
#define CPUID_ECX_FLAG31_BIT 31
#define CPUID_ECX_FLAG31_FLAG 0x80000000
#define CPUID_ECX_FLAG31_MASK 0x01
#define CPUID_ECX_FLAG31(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_14_ecx_00;
/**
* @brief Intel Processor Trace Enumeration Sub-leaf (EAX = 14H, ECX = 1)
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 2:0] Number of configurable Address Ranges for filtering.
*/
UINT32_t number_of_configurable_address_ranges_for_filtering : 3;
#define CPUID_EAX_NUMBER_OF_CONFIGURABLE_ADDRESS_RANGES_FOR_FILTERING_BIT 0
#define CPUID_EAX_NUMBER_OF_CONFIGURABLE_ADDRESS_RANGES_FOR_FILTERING_FLAG 0x07
#define CPUID_EAX_NUMBER_OF_CONFIGURABLE_ADDRESS_RANGES_FOR_FILTERING_MASK 0x07
#define CPUID_EAX_NUMBER_OF_CONFIGURABLE_ADDRESS_RANGES_FOR_FILTERING(_) (((_) >> 0) & 0x07)
UINT32_t reserved1 : 13;
/**
* [Bits 31:16] Bitmap of supported MTC period encodings.
*/
UINT32_t bitmap_of_supported_mtc_period_encodings : 16;
#define CPUID_EAX_BITMAP_OF_SUPPORTED_MTC_PERIOD_ENCODINGS_BIT 16
#define CPUID_EAX_BITMAP_OF_SUPPORTED_MTC_PERIOD_ENCODINGS_FLAG 0xFFFF0000
#define CPUID_EAX_BITMAP_OF_SUPPORTED_MTC_PERIOD_ENCODINGS_MASK 0xFFFF
#define CPUID_EAX_BITMAP_OF_SUPPORTED_MTC_PERIOD_ENCODINGS(_) (((_) >> 16) & 0xFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 15:0] Bitmap of supported Cycle Threshold value encodings.
*/
UINT32_t bitmap_of_supported_cycle_threshold_value_encodings : 16;
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CYCLE_THRESHOLD_VALUE_ENCODINGS_BIT 0
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CYCLE_THRESHOLD_VALUE_ENCODINGS_FLAG 0xFFFF
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CYCLE_THRESHOLD_VALUE_ENCODINGS_MASK 0xFFFF
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CYCLE_THRESHOLD_VALUE_ENCODINGS(_) (((_) >> 0) & 0xFFFF)
/**
* [Bits 31:16] Bitmap of supported Configurable PSB frequency encodings.
*/
UINT32_t bitmap_of_supported_configurable_psb_frequency_encodings : 16;
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CONFIGURABLE_PSB_FREQUENCY_ENCODINGS_BIT 16
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CONFIGURABLE_PSB_FREQUENCY_ENCODINGS_FLAG 0xFFFF0000
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CONFIGURABLE_PSB_FREQUENCY_ENCODINGS_MASK 0xFFFF
#define CPUID_EBX_BITMAP_OF_SUPPORTED_CONFIGURABLE_PSB_FREQUENCY_ENCODINGS(_) (((_) >> 16) & 0xFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_14_ecx_01;
/**
* @}
*/
/**
* @brief Stamp Counter and Nominal Core Crystal Clock Information Leaf
*
* When CPUID executes with EAX set to 15H and ECX = 0H, the processor returns information about Time Stamp Counter and
* Core Crystal Clock.
*
* @note If EBX[31:0] is 0, the TSC/"core crystal clock" ratio is not enumerated. EBX[31:0]/EAX[31:0] indicates the ratio
* of the TSC frequency and the core crystal clock frequency.
* If ECX is 0, the nominal core crystal clock frequency is not enumerated. "TSC frequency" = "core crystal clock
* frequency" * EBX/EAX.
*/
#define CPUID_TIME_STAMP_COUNTER_INFORMATION 0x00000015
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] An unsigned integer which is the denominator of the TSC/"core crystal clock" ratio.
*/
UINT32_t denominator : 32;
#define CPUID_EAX_DENOMINATOR_BIT 0
#define CPUID_EAX_DENOMINATOR_FLAG 0xFFFFFFFF
#define CPUID_EAX_DENOMINATOR_MASK 0xFFFFFFFF
#define CPUID_EAX_DENOMINATOR(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] An unsigned integer which is the numerator of the TSC/"core crystal clock" ratio.
*/
UINT32_t numerator : 32;
#define CPUID_EBX_NUMERATOR_BIT 0
#define CPUID_EBX_NUMERATOR_FLAG 0xFFFFFFFF
#define CPUID_EBX_NUMERATOR_MASK 0xFFFFFFFF
#define CPUID_EBX_NUMERATOR(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] An unsigned integer which is the nominal frequency of the core crystal clock in Hz.
*/
UINT32_t nominal_frequency : 32;
#define CPUID_ECX_NOMINAL_FREQUENCY_BIT 0
#define CPUID_ECX_NOMINAL_FREQUENCY_FLAG 0xFFFFFFFF
#define CPUID_ECX_NOMINAL_FREQUENCY_MASK 0xFFFFFFFF
#define CPUID_ECX_NOMINAL_FREQUENCY(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_15;
/**
* @brief Processor Frequency Information Leaf
*
* When CPUID executes with EAX set to 16H, the processor returns information about Processor Frequency Information.
*
* @note Data is returned from this interface in accordance with the processor's specification and does not reflect actual
* values. Suitable use of this data includes the display of processor information in like manner to the processor brand
* string and for determining the appropriate range to use when displaying processor information e.g. frequency history
* graphs. The returned information should not be used for any other purpose as the returned information does not
* accurately correlate to information / counters returned by other processor interfaces.
* While a processor may support the Processor Frequency Information leaf, fields that return a value of zero are not
* supported.
*/
#define CPUID_PROCESSOR_FREQUENCY_INFORMATION 0x00000016
typedef struct
{
union
{
struct
{
/**
* [Bits 15:0] Processor Base Frequency (in MHz).
*/
UINT32_t procesor_base_frequency_mhz : 16;
#define CPUID_EAX_PROCESOR_BASE_FREQUENCY_MHZ_BIT 0
#define CPUID_EAX_PROCESOR_BASE_FREQUENCY_MHZ_FLAG 0xFFFF
#define CPUID_EAX_PROCESOR_BASE_FREQUENCY_MHZ_MASK 0xFFFF
#define CPUID_EAX_PROCESOR_BASE_FREQUENCY_MHZ(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 15:0] Maximum Frequency (in MHz).
*/
UINT32_t processor_maximum_frequency_mhz : 16;
#define CPUID_EBX_PROCESSOR_MAXIMUM_FREQUENCY_MHZ_BIT 0
#define CPUID_EBX_PROCESSOR_MAXIMUM_FREQUENCY_MHZ_FLAG 0xFFFF
#define CPUID_EBX_PROCESSOR_MAXIMUM_FREQUENCY_MHZ_MASK 0xFFFF
#define CPUID_EBX_PROCESSOR_MAXIMUM_FREQUENCY_MHZ(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 15:0] Bus (Reference) Frequency (in MHz).
*/
UINT32_t bus_frequency_mhz : 16;
#define CPUID_ECX_BUS_FREQUENCY_MHZ_BIT 0
#define CPUID_ECX_BUS_FREQUENCY_MHZ_FLAG 0xFFFF
#define CPUID_ECX_BUS_FREQUENCY_MHZ_MASK 0xFFFF
#define CPUID_ECX_BUS_FREQUENCY_MHZ(_) (((_) >> 0) & 0xFFFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_16;
/**
* @defgroup cpuid_eax_17 \
* EAX = 0x17
*
* When CPUID executes with EAX set to 17H, the processor returns information about the System-On-Chip Vendor Attribute
* Enumeration.
* @{
*/
#define CPUID_SOC_VENDOR_INFORMATION 0x00000017
/**
* @brief System-On-Chip Vendor Attribute Enumeration Main Leaf (EAX = 17H, ECX = 0)
*
* @note Leaf 17H main leaf (ECX = 0). Leaf 17H output depends on the initial value in ECX. Leaf 17H sub-leaves 1 through 3
* reports SOC Vendor Brand String. Leaf 17H is valid if MaxSOCID_Index >= 3. Leaf 17H sub-leaves 4 and above are reserved.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reports the maximum input value of supported sub-leaf in leaf 17H.
*/
UINT32_t max_soc_id_index : 32;
#define CPUID_EAX_MAX_SOC_ID_INDEX_BIT 0
#define CPUID_EAX_MAX_SOC_ID_INDEX_FLAG 0xFFFFFFFF
#define CPUID_EAX_MAX_SOC_ID_INDEX_MASK 0xFFFFFFFF
#define CPUID_EAX_MAX_SOC_ID_INDEX(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 15:0] SOC Vendor ID.
*/
UINT32_t soc_vendor_id : 16;
#define CPUID_EBX_SOC_VENDOR_ID_BIT 0
#define CPUID_EBX_SOC_VENDOR_ID_FLAG 0xFFFF
#define CPUID_EBX_SOC_VENDOR_ID_MASK 0xFFFF
#define CPUID_EBX_SOC_VENDOR_ID(_) (((_) >> 0) & 0xFFFF)
/**
* [Bit 16] If 1, the SOC Vendor ID field is assigned via an industry standard enumeration scheme. Otherwise, the SOC
* Vendor ID field is assigned by Intel.
*/
UINT32_t is_vendor_scheme : 1;
#define CPUID_EBX_IS_VENDOR_SCHEME_BIT 16
#define CPUID_EBX_IS_VENDOR_SCHEME_FLAG 0x10000
#define CPUID_EBX_IS_VENDOR_SCHEME_MASK 0x01
#define CPUID_EBX_IS_VENDOR_SCHEME(_) (((_) >> 16) & 0x01)
UINT32_t reserved1 : 15;
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] A unique number an SOC vendor assigns to its SOC projects.
*/
UINT32_t project_id : 32;
#define CPUID_ECX_PROJECT_ID_BIT 0
#define CPUID_ECX_PROJECT_ID_FLAG 0xFFFFFFFF
#define CPUID_ECX_PROJECT_ID_MASK 0xFFFFFFFF
#define CPUID_ECX_PROJECT_ID(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] A unique number within an SOC project that an SOC vendor assigns.
*/
UINT32_t stepping_id : 32;
#define CPUID_EDX_STEPPING_ID_BIT 0
#define CPUID_EDX_STEPPING_ID_FLAG 0xFFFFFFFF
#define CPUID_EDX_STEPPING_ID_MASK 0xFFFFFFFF
#define CPUID_EDX_STEPPING_ID(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_17_ecx_00;
/**
* @brief System-On-Chip Vendor Attribute Enumeration Sub-leaf (EAX = 17H, ECX = 1..3)
*
* @note Leaf 17H output depends on the initial value in ECX. SOC Vendor Brand String is a UTF-8 encoded string padded with
* trailing bytes of 00H. The complete SOC Vendor Brand String is constructed by concatenating in ascending order of
* EAX:EBX:ECX:EDX and from the sub-leaf 1 fragment towards sub-leaf 3.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] SOC Vendor Brand String. UTF-8 encoded string.
*/
UINT32_t soc_vendor_brand_string : 32;
#define CPUID_EAX_SOC_VENDOR_BRAND_STRING_BIT 0
#define CPUID_EAX_SOC_VENDOR_BRAND_STRING_FLAG 0xFFFFFFFF
#define CPUID_EAX_SOC_VENDOR_BRAND_STRING_MASK 0xFFFFFFFF
#define CPUID_EAX_SOC_VENDOR_BRAND_STRING(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] SOC Vendor Brand String. UTF-8 encoded string.
*/
UINT32_t soc_vendor_brand_string : 32;
#define CPUID_EBX_SOC_VENDOR_BRAND_STRING_BIT 0
#define CPUID_EBX_SOC_VENDOR_BRAND_STRING_FLAG 0xFFFFFFFF
#define CPUID_EBX_SOC_VENDOR_BRAND_STRING_MASK 0xFFFFFFFF
#define CPUID_EBX_SOC_VENDOR_BRAND_STRING(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] SOC Vendor Brand String. UTF-8 encoded string.
*/
UINT32_t soc_vendor_brand_string : 32;
#define CPUID_ECX_SOC_VENDOR_BRAND_STRING_BIT 0
#define CPUID_ECX_SOC_VENDOR_BRAND_STRING_FLAG 0xFFFFFFFF
#define CPUID_ECX_SOC_VENDOR_BRAND_STRING_MASK 0xFFFFFFFF
#define CPUID_ECX_SOC_VENDOR_BRAND_STRING(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] SOC Vendor Brand String. UTF-8 encoded string.
*/
UINT32_t soc_vendor_brand_string : 32;
#define CPUID_EDX_SOC_VENDOR_BRAND_STRING_BIT 0
#define CPUID_EDX_SOC_VENDOR_BRAND_STRING_FLAG 0xFFFFFFFF
#define CPUID_EDX_SOC_VENDOR_BRAND_STRING_MASK 0xFFFFFFFF
#define CPUID_EDX_SOC_VENDOR_BRAND_STRING(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_17_ecx_01_03;
/**
* @brief System-On-Chip Vendor Attribute Enumeration Sub-leaves (EAX = 17H, ECX > MaxSOCID_Index)
*
* @note Leaf 17H output depends on the initial value in ECX.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reserved = 0.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Reserved = 0.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Reserved = 0.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Reserved = 0.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_17_ecx_n;
/**
* @}
*/
/**
* @defgroup cpuid_eax_18 \
* EAX = 0x18
*
* When CPUID executes with EAX set to 18H, the processor returns information about the Deterministic Address Translation
* Parameters.
* @{
*/
#define CPUID_DETERMINISTIC_ADDRESS_TRANSLATION_PARAMETERS 0x00000018
/**
* @brief Deterministic Address Translation Parameters Main Leaf (EAX = 18H, ECX = 0)
*
* @note Each sub-leaf enumerates a different address translation structure.
* If ECX contains an invalid sub-leaf index, EAX/EBX/ECX/EDX return 0. Sub-leaf index n is invalid if n exceeds the value
* that sub-leaf 0 returns in EAX. A sub-leaf index is also invalid if EDX[4:0] returns 0. Valid sub-leaves do not need to
* be contiguous or in any particular order. A valid sub-leaf may be in a higher input ECX value than an invalid sub-leaf
* or than a valid sub-leaf of a higher or lower-level structure.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Reports the maximum input value of supported sub-leaf in leaf 18H.
*/
UINT32_t max_sub_leaf : 32;
#define CPUID_EAX_MAX_SUB_LEAF_BIT 0
#define CPUID_EAX_MAX_SUB_LEAF_FLAG 0xFFFFFFFF
#define CPUID_EAX_MAX_SUB_LEAF_MASK 0xFFFFFFFF
#define CPUID_EAX_MAX_SUB_LEAF(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bit 0] 4K page size entries supported by this structure.
*/
UINT32_t page_entries_4kb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_BIT 0
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_FLAG 0x01
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] 2MB page size entries supported by this structure.
*/
UINT32_t page_entries_2mb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_BIT 1
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_FLAG 0x02
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] 4MB page size entries supported by this structure.
*/
UINT32_t page_entries_4mb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_BIT 2
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_FLAG 0x04
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] 1 GB page size entries supported by this structure.
*/
UINT32_t page_entries_1gb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_BIT 3
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_FLAG 0x08
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED(_) (((_) >> 3) & 0x01)
UINT32_t reserved1 : 4;
/**
* [Bits 10:8] Partitioning (0: Soft partitioning between the logical processors sharing this structure).
*/
UINT32_t partitioning : 3;
#define CPUID_EBX_PARTITIONING_BIT 8
#define CPUID_EBX_PARTITIONING_FLAG 0x700
#define CPUID_EBX_PARTITIONING_MASK 0x07
#define CPUID_EBX_PARTITIONING(_) (((_) >> 8) & 0x07)
UINT32_t reserved2 : 5;
/**
* [Bits 31:16] W = Ways of associativity.
*/
UINT32_t ways_of_associativity_00 : 16;
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_00_BIT 16
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_00_FLAG 0xFFFF0000
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_00_MASK 0xFFFF
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_00(_) (((_) >> 16) & 0xFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Number of Sets.
*/
UINT32_t number_of_sets : 32;
#define CPUID_ECX_NUMBER_OF_SETS_BIT 0
#define CPUID_ECX_NUMBER_OF_SETS_FLAG 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS_MASK 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 4:0] Translation cache type field.
* - 00000b: Null (indicates this sub-leaf is not valid).
* - 00001b: Data TLB.
* - 00010b: Instruction TLB.
* - 00011b: Unified TLB.
* All other encodings are reserved.
*
* @note Some unified TLBs will allow a single TLB entry to satisfy data read/write and instruction fetches. Others will
* require separate entries (e.g., one loaded on data read/write and another loaded on an instruction fetch) . Please see
* the Intel(R) 64 and IA-32 Architectures Optimization Reference Manual for details of a particular product.
*/
UINT32_t translation_cache_type_field : 5;
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_BIT 0
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_FLAG 0x1F
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_MASK 0x1F
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD(_) (((_) >> 0) & 0x1F)
/**
* [Bits 7:5] Translation cache level (starts at 1).
*/
UINT32_t translation_cache_level : 3;
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_BIT 5
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_FLAG 0xE0
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_MASK 0x07
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL(_) (((_) >> 5) & 0x07)
/**
* [Bit 8] Fully associative structure.
*/
UINT32_t fully_associative_structure : 1;
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_BIT 8
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_FLAG 0x100
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_MASK 0x01
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE(_) (((_) >> 8) & 0x01)
UINT32_t reserved1 : 5;
/**
* [Bits 25:14] Maximum number of addressable IDs for logical processors sharing this translation cache.
*
* @note Add one to the return value to get the result.
*/
UINT32_t max_addressable_ids_for_logical_processors : 12;
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_BIT 14
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_FLAG 0x3FFC000
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_MASK 0xFFF
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS(_) (((_) >> 14) & 0xFFF)
UINT32_t reserved2 : 6;
};
UINT32_t flags;
} edx;
} cpuid_eax_18_ecx_00;
/**
* @brief Deterministic Address Translation Parameters Sub-leaf (EAX = 18H, ECX >= 1)
*
* @note Each sub-leaf enumerates a different address translation structure.
* If ECX contains an invalid sub-leaf index, EAX/EBX/ECX/EDX return 0. Sub-leaf index n is invalid if n exceeds the value
* that sub-leaf 0 returns in EAX. A sub-leaf index is also invalid if EDX[4:0] returns 0. Valid sub-leaves do not need to
* be contiguous or in any particular order. A valid sub-leaf may be in a higher input ECX value than an invalid sub-leaf
* or than a valid sub-leaf of a higher or lower-level structure.
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bit 0] 4K page size entries supported by this structure.
*/
UINT32_t page_entries_4kb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_BIT 0
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_FLAG 0x01
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_4KB_SUPPORTED(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] 2MB page size entries supported by this structure.
*/
UINT32_t page_entries_2mb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_BIT 1
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_FLAG 0x02
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_2MB_SUPPORTED(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] 4MB page size entries supported by this structure.
*/
UINT32_t page_entries_4mb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_BIT 2
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_FLAG 0x04
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_4MB_SUPPORTED(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] 1 GB page size entries supported by this structure.
*/
UINT32_t page_entries_1gb_supported : 1;
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_BIT 3
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_FLAG 0x08
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED_MASK 0x01
#define CPUID_EBX_PAGE_ENTRIES_1GB_SUPPORTED(_) (((_) >> 3) & 0x01)
UINT32_t reserved1 : 4;
/**
* [Bits 10:8] Partitioning (0: Soft partitioning between the logical processors sharing this structure).
*/
UINT32_t partitioning : 3;
#define CPUID_EBX_PARTITIONING_BIT 8
#define CPUID_EBX_PARTITIONING_FLAG 0x700
#define CPUID_EBX_PARTITIONING_MASK 0x07
#define CPUID_EBX_PARTITIONING(_) (((_) >> 8) & 0x07)
UINT32_t reserved2 : 5;
/**
* [Bits 31:16] W = Ways of associativity.
*/
UINT32_t ways_of_associativity_01 : 16;
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_01_BIT 16
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_01_FLAG 0xFFFF0000
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_01_MASK 0xFFFF
#define CPUID_EBX_WAYS_OF_ASSOCIATIVITY_01(_) (((_) >> 16) & 0xFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Number of Sets.
*/
UINT32_t number_of_sets : 32;
#define CPUID_ECX_NUMBER_OF_SETS_BIT 0
#define CPUID_ECX_NUMBER_OF_SETS_FLAG 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS_MASK 0xFFFFFFFF
#define CPUID_ECX_NUMBER_OF_SETS(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 4:0] Translation cache type field.
* - 00000b: Null (indicates this sub-leaf is not valid).
* - 00001b: Data TLB.
* - 00010b: Instruction TLB.
* - 00011b: Unified TLB.
* All other encodings are reserved.
*
* @note Some unified TLBs will allow a single TLB entry to satisfy data read/write and instruction fetches. Others will
* require separate entries (e.g., one loaded on data read/write and another loaded on an instruction fetch) . Please see
* the Intel(R) 64 and IA-32 Architectures Optimization Reference Manual for details of a particular product.
*/
UINT32_t translation_cache_type_field : 5;
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_BIT 0
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_FLAG 0x1F
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD_MASK 0x1F
#define CPUID_EDX_TRANSLATION_CACHE_TYPE_FIELD(_) (((_) >> 0) & 0x1F)
/**
* [Bits 7:5] Translation cache level (starts at 1).
*/
UINT32_t translation_cache_level : 3;
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_BIT 5
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_FLAG 0xE0
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL_MASK 0x07
#define CPUID_EDX_TRANSLATION_CACHE_LEVEL(_) (((_) >> 5) & 0x07)
/**
* [Bit 8] Fully associative structure.
*/
UINT32_t fully_associative_structure : 1;
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_BIT 8
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_FLAG 0x100
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE_MASK 0x01
#define CPUID_EDX_FULLY_ASSOCIATIVE_STRUCTURE(_) (((_) >> 8) & 0x01)
UINT32_t reserved1 : 5;
/**
* [Bits 25:14] Maximum number of addressable IDs for logical processors sharing this translation cache.
*
* @note Add one to the return value to get the result.
*/
UINT32_t max_addressable_ids_for_logical_processors : 12;
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_BIT 14
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_FLAG 0x3FFC000
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS_MASK 0xFFF
#define CPUID_EDX_MAX_ADDRESSABLE_IDS_FOR_LOGICAL_PROCESSORS(_) (((_) >> 14) & 0xFFF)
UINT32_t reserved2 : 6;
};
UINT32_t flags;
} edx;
} cpuid_eax_18_ecx_01p;
/**
* @}
*/
/**
* @brief Extended Function CPUID Information
*
* When CPUID executes with EAX set to 80000000H, the processor returns the highest value the processor recognizes for
* returning extended processor information. The value is returned in the EAX register and is processor specific.
*/
#define CPUID_EXTENDED_FUNCTION_INFORMATION 0x80000000
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Maximum Input Value for Extended Function CPUID Information.
*/
UINT32_t max_extended_functions : 32;
#define CPUID_EAX_MAX_EXTENDED_FUNCTIONS_BIT 0
#define CPUID_EAX_MAX_EXTENDED_FUNCTIONS_FLAG 0xFFFFFFFF
#define CPUID_EAX_MAX_EXTENDED_FUNCTIONS_MASK 0xFFFFFFFF
#define CPUID_EAX_MAX_EXTENDED_FUNCTIONS(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000000;
/**
* Extended Function CPUID Information.
*/
#define CPUID_EXTENDED_CPU_SIGNATURE 0x80000001
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bit 0] LAHF/SAHF available in 64-bit mode.
*/
UINT32_t lahf_sahf_available_in_64_bit_mode : 1;
#define CPUID_ECX_LAHF_SAHF_AVAILABLE_IN_64_BIT_MODE_BIT 0
#define CPUID_ECX_LAHF_SAHF_AVAILABLE_IN_64_BIT_MODE_FLAG 0x01
#define CPUID_ECX_LAHF_SAHF_AVAILABLE_IN_64_BIT_MODE_MASK 0x01
#define CPUID_ECX_LAHF_SAHF_AVAILABLE_IN_64_BIT_MODE(_) (((_) >> 0) & 0x01)
UINT32_t reserved1 : 4;
/**
* [Bit 5] LZCNT.
*/
UINT32_t lzcnt : 1;
#define CPUID_ECX_LZCNT_BIT 5
#define CPUID_ECX_LZCNT_FLAG 0x20
#define CPUID_ECX_LZCNT_MASK 0x01
#define CPUID_ECX_LZCNT(_) (((_) >> 5) & 0x01)
UINT32_t reserved2 : 2;
/**
* [Bit 8] PREFETCHW.
*/
UINT32_t prefetchw : 1;
#define CPUID_ECX_PREFETCHW_BIT 8
#define CPUID_ECX_PREFETCHW_FLAG 0x100
#define CPUID_ECX_PREFETCHW_MASK 0x01
#define CPUID_ECX_PREFETCHW(_) (((_) >> 8) & 0x01)
UINT32_t reserved3 : 23;
};
UINT32_t flags;
} ecx;
union
{
struct
{
UINT32_t reserved1 : 11;
/**
* [Bit 11] SYSCALL/SYSRET available in 64-bit mode.
*/
UINT32_t syscall_sysret_available_in_64_bit_mode : 1;
#define CPUID_EDX_SYSCALL_SYSRET_AVAILABLE_IN_64_BIT_MODE_BIT 11
#define CPUID_EDX_SYSCALL_SYSRET_AVAILABLE_IN_64_BIT_MODE_FLAG 0x800
#define CPUID_EDX_SYSCALL_SYSRET_AVAILABLE_IN_64_BIT_MODE_MASK 0x01
#define CPUID_EDX_SYSCALL_SYSRET_AVAILABLE_IN_64_BIT_MODE(_) (((_) >> 11) & 0x01)
UINT32_t reserved2 : 8;
/**
* [Bit 20] Execute Disable Bit available.
*/
UINT32_t execute_disable_bit_available : 1;
#define CPUID_EDX_EXECUTE_DISABLE_BIT_AVAILABLE_BIT 20
#define CPUID_EDX_EXECUTE_DISABLE_BIT_AVAILABLE_FLAG 0x100000
#define CPUID_EDX_EXECUTE_DISABLE_BIT_AVAILABLE_MASK 0x01
#define CPUID_EDX_EXECUTE_DISABLE_BIT_AVAILABLE(_) (((_) >> 20) & 0x01)
UINT32_t reserved3 : 5;
/**
* [Bit 26] 1-GByte pages are available if 1.
*/
UINT32_t pages_1gb_available : 1;
#define CPUID_EDX_PAGES_1GB_AVAILABLE_BIT 26
#define CPUID_EDX_PAGES_1GB_AVAILABLE_FLAG 0x4000000
#define CPUID_EDX_PAGES_1GB_AVAILABLE_MASK 0x01
#define CPUID_EDX_PAGES_1GB_AVAILABLE(_) (((_) >> 26) & 0x01)
/**
* [Bit 27] RDTSCP and IA32_TSC_AUX are available if 1.
*/
UINT32_t rdtscp_available : 1;
#define CPUID_EDX_RDTSCP_AVAILABLE_BIT 27
#define CPUID_EDX_RDTSCP_AVAILABLE_FLAG 0x8000000
#define CPUID_EDX_RDTSCP_AVAILABLE_MASK 0x01
#define CPUID_EDX_RDTSCP_AVAILABLE(_) (((_) >> 27) & 0x01)
UINT32_t reserved4 : 1;
/**
* [Bit 29] Intel(R) 64 Architecture available if 1.
*/
UINT32_t ia64_available : 1;
#define CPUID_EDX_IA64_AVAILABLE_BIT 29
#define CPUID_EDX_IA64_AVAILABLE_FLAG 0x20000000
#define CPUID_EDX_IA64_AVAILABLE_MASK 0x01
#define CPUID_EDX_IA64_AVAILABLE(_) (((_) >> 29) & 0x01)
UINT32_t reserved5 : 2;
};
UINT32_t flags;
} edx;
} cpuid_eax_80000001;
/**
* Extended Function CPUID Information.
*/
#define CPUID_BRAND_STRING1 0x80000002
/**
* Extended Function CPUID Information.
*/
#define CPUID_BRAND_STRING2 0x80000003
/**
* Extended Function CPUID Information.
*/
#define CPUID_BRAND_STRING3 0x80000004
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String.
*/
UINT32_t processor_brand_string_1 : 32;
#define CPUID_EAX_PROCESSOR_BRAND_STRING_1_BIT 0
#define CPUID_EAX_PROCESSOR_BRAND_STRING_1_FLAG 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_1_MASK 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_1(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_2 : 32;
#define CPUID_EBX_PROCESSOR_BRAND_STRING_2_BIT 0
#define CPUID_EBX_PROCESSOR_BRAND_STRING_2_FLAG 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_2_MASK 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_2(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_3 : 32;
#define CPUID_ECX_PROCESSOR_BRAND_STRING_3_BIT 0
#define CPUID_ECX_PROCESSOR_BRAND_STRING_3_FLAG 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_3_MASK 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_3(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_4 : 32;
#define CPUID_EDX_PROCESSOR_BRAND_STRING_4_BIT 0
#define CPUID_EDX_PROCESSOR_BRAND_STRING_4_FLAG 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_4_MASK 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_4(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000002;
/**
* @brief Extended Function CPUID Information
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_5 : 32;
#define CPUID_EAX_PROCESSOR_BRAND_STRING_5_BIT 0
#define CPUID_EAX_PROCESSOR_BRAND_STRING_5_FLAG 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_5_MASK 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_5(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_6 : 32;
#define CPUID_EBX_PROCESSOR_BRAND_STRING_6_BIT 0
#define CPUID_EBX_PROCESSOR_BRAND_STRING_6_FLAG 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_6_MASK 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_6(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_7 : 32;
#define CPUID_ECX_PROCESSOR_BRAND_STRING_7_BIT 0
#define CPUID_ECX_PROCESSOR_BRAND_STRING_7_FLAG 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_7_MASK 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_7(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_8 : 32;
#define CPUID_EDX_PROCESSOR_BRAND_STRING_8_BIT 0
#define CPUID_EDX_PROCESSOR_BRAND_STRING_8_FLAG 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_8_MASK 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_8(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000003;
/**
* @brief Extended Function CPUID Information
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_9 : 32;
#define CPUID_EAX_PROCESSOR_BRAND_STRING_9_BIT 0
#define CPUID_EAX_PROCESSOR_BRAND_STRING_9_FLAG 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_9_MASK 0xFFFFFFFF
#define CPUID_EAX_PROCESSOR_BRAND_STRING_9(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_10 : 32;
#define CPUID_EBX_PROCESSOR_BRAND_STRING_10_BIT 0
#define CPUID_EBX_PROCESSOR_BRAND_STRING_10_FLAG 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_10_MASK 0xFFFFFFFF
#define CPUID_EBX_PROCESSOR_BRAND_STRING_10(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_11 : 32;
#define CPUID_ECX_PROCESSOR_BRAND_STRING_11_BIT 0
#define CPUID_ECX_PROCESSOR_BRAND_STRING_11_FLAG 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_11_MASK 0xFFFFFFFF
#define CPUID_ECX_PROCESSOR_BRAND_STRING_11(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] Processor Brand String Continued.
*/
UINT32_t processor_brand_string_12 : 32;
#define CPUID_EDX_PROCESSOR_BRAND_STRING_12_BIT 0
#define CPUID_EDX_PROCESSOR_BRAND_STRING_12_FLAG 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_12_MASK 0xFFFFFFFF
#define CPUID_EDX_PROCESSOR_BRAND_STRING_12(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000004;
/**
* @brief Extended Function CPUID Information
*/
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000005;
/**
* Extended Function CPUID Information.
*/
#define CPUID_EXTENDED_CACHE_INFO 0x80000006
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 7:0] Cache Line size in bytes.
*/
UINT32_t cache_line_size_inUINT8s : 8;
#define CPUID_ECX_CACHE_LINE_SIZE_INUINT8S_BIT 0
#define CPUID_ECX_CACHE_LINE_SIZE_INUINT8S_FLAG 0xFF
#define CPUID_ECX_CACHE_LINE_SIZE_INUINT8S_MASK 0xFF
#define CPUID_ECX_CACHE_LINE_SIZE_INUINT8S(_) (((_) >> 0) & 0xFF)
UINT32_t reserved1 : 4;
/**
* [Bits 15:12] L2 Associativity field.
* L2 associativity field encodings:
* - 00H - Disabled.
* - 01H - Direct mapped.
* - 02H - 2-way.
* - 04H - 4-way.
* - 06H - 8-way.
* - 08H - 16-way.
* - 0FH - Fully associative.
*/
UINT32_t l2_associativity_field : 4;
#define CPUID_ECX_L2_ASSOCIATIVITY_FIELD_BIT 12
#define CPUID_ECX_L2_ASSOCIATIVITY_FIELD_FLAG 0xF000
#define CPUID_ECX_L2_ASSOCIATIVITY_FIELD_MASK 0x0F
#define CPUID_ECX_L2_ASSOCIATIVITY_FIELD(_) (((_) >> 12) & 0x0F)
/**
* [Bits 31:16] Cache size in 1K units.
*/
UINT32_t cache_size_in_1k_units : 16;
#define CPUID_ECX_CACHE_SIZE_IN_1K_UNITS_BIT 16
#define CPUID_ECX_CACHE_SIZE_IN_1K_UNITS_FLAG 0xFFFF0000
#define CPUID_ECX_CACHE_SIZE_IN_1K_UNITS_MASK 0xFFFF
#define CPUID_ECX_CACHE_SIZE_IN_1K_UNITS(_) (((_) >> 16) & 0xFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
/**
* [Bits 31:0] EDX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EDX_RESERVED_BIT 0
#define CPUID_EDX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EDX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EDX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} edx;
} cpuid_eax_80000006;
/**
* Extended Function CPUID Information.
*/
#define CPUID_EXTENDED_TIME_STAMP_COUNTER 0x80000007
typedef struct
{
union
{
struct
{
/**
* [Bits 31:0] EAX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EAX_RESERVED_BIT 0
#define CPUID_EAX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EAX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EAX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} eax;
union
{
struct
{
/**
* [Bits 31:0] EBX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_EBX_RESERVED_BIT 0
#define CPUID_EBX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_EBX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_EBX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ebx;
union
{
struct
{
/**
* [Bits 31:0] ECX is reserved.
*/
UINT32_t reserved : 32;
#define CPUID_ECX_RESERVED_BIT 0
#define CPUID_ECX_RESERVED_FLAG 0xFFFFFFFF
#define CPUID_ECX_RESERVED_MASK 0xFFFFFFFF
#define CPUID_ECX_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
};
UINT32_t flags;
} ecx;
union
{
struct
{
UINT32_t reserved1 : 8;
/**
* [Bit 8] Invariant TSC available if 1.
*/
UINT32_t invariant_tsc_available : 1;
#define CPUID_EDX_INVARIANT_TSC_AVAILABLE_BIT 8
#define CPUID_EDX_INVARIANT_TSC_AVAILABLE_FLAG 0x100
#define CPUID_EDX_INVARIANT_TSC_AVAILABLE_MASK 0x01
#define CPUID_EDX_INVARIANT_TSC_AVAILABLE(_) (((_) >> 8) & 0x01)
UINT32_t reserved2 : 23;
};
UINT32_t flags;
} edx;
} cpuid_eax_80000007;
/**
* @}
*/
/**
* @defgroup model_specific_registers \
* Model Specific Registers
*
* @see Vol2A[3.2(CPUID)] (reference)
* @{
*/
/**
* @defgroup ia32_p5_mc \
* IA32_P5_MC_(x)
*
* When machine-check exceptions are enabled for the Pentium processor (MCE flag is set in control register CR4), the
* machine-check exception handler uses the RDMSR instruction to read the error type from the P5_MC_TYPE register and the
* machine check address from the P5_MC_ADDR register. The handler then normally reports these register values to the
* system console before aborting execution.
*
* @see Vol3B[15.10.2(Pentium Processor Machine-Check Exception Handling)] (reference)
* @{
*/
/**
* Machine-check exception address.
*
* @remarks 05_01H
* @see Vol4[2.22(MSRS IN PENTIUM PROCESSORS)]
*/
#define IA32_P5_MC_ADDR 0x00000000
/**
* Machine-check exception type.
*
* @remarks 05_01H
* @see Vol4[2.22(MSRS IN PENTIUM PROCESSORS)]
*/
#define IA32_P5_MC_TYPE 0x00000001
/**
* @}
*/
/**
* System coherence line size.
*
* @remarks 0F_03H
* @see Vol3A[8.10.5(Monitor/Mwait Address Range Determination)]
* @see Vol3A[8.10.5(Monitor/Mwait Address Range Determination)] (reference)
*/
#define IA32_MONITOR_FILTER_LINE_SIZE 0x00000006
/**
* Value as returned by instruction RDTSC.
*
* @remarks 05_01H
* @see Vol3B[17.17(TIME-STAMP COUNTER)]
*/
#define IA32_TIME_STAMP_COUNTER 0x00000010
/**
* The operating system can use this MSR to determine "slot" information for the processor and the proper microcode update
* to load.
*
* @remarks 06_01H
*/
#define IA32_PLATFORM_ID 0x00000017
typedef union
{
struct
{
UINT64_t reserved1 : 50;
/**
* @brief Platform Id <b>(RO)</b>
*
* [Bits 52:50] Contains information concerning the intended platform for the processor.
*
*
* 52 | 51 | 50 | _
* --:|:--:|:---|-----------------
* 0 | 0 | 0 | Processor Flag 0
* 0 | 0 | 1 | Processor Flag 1
* 0 | 1 | 0 | Processor Flag 2
* 0 | 1 | 1 | Processor Flag 3
* 1 | 0 | 0 | Processor Flag 4
* 1 | 0 | 1 | Processor Flag 5
* 1 | 1 | 0 | Processor Flag 6
* 1 | 1 | 1 | Processor Flag 7
*/
UINT64_t platform_id : 3;
#define IA32_PLATFORM_ID_PLATFORM_ID_BIT 50
#define IA32_PLATFORM_ID_PLATFORM_ID_FLAG 0x1C000000000000
#define IA32_PLATFORM_ID_PLATFORM_ID_MASK 0x07
#define IA32_PLATFORM_ID_PLATFORM_ID(_) (((_) >> 50) & 0x07)
UINT64_t reserved2 : 11;
};
UINT64_t flags;
} ia32_platform_id_register;
/**
* This register holds the APIC base address, permitting the relocation of the APIC memory map.
*
* @remarks 06_01H
* @see Vol3A[10.4.4(Local APIC Status and Location)]
* @see Vol3A[10.4.5(Relocating the Local APIC Registers)]
*/
#define IA32_APIC_BASE 0x0000001B
typedef union
{
struct
{
UINT64_t reserved1 : 8;
/**
* [Bit 8] BSP flag.
*/
UINT64_t bsp_flag : 1;
#define IA32_APIC_BASE_BSP_FLAG_BIT 8
#define IA32_APIC_BASE_BSP_FLAG_FLAG 0x100
#define IA32_APIC_BASE_BSP_FLAG_MASK 0x01
#define IA32_APIC_BASE_BSP_FLAG(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 10] Enable x2APIC mode.
*/
UINT64_t enable_x2apic_mode : 1;
#define IA32_APIC_BASE_ENABLE_X2APIC_MODE_BIT 10
#define IA32_APIC_BASE_ENABLE_X2APIC_MODE_FLAG 0x400
#define IA32_APIC_BASE_ENABLE_X2APIC_MODE_MASK 0x01
#define IA32_APIC_BASE_ENABLE_X2APIC_MODE(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] APIC Global Enable.
*/
UINT64_t apic_global_enable : 1;
#define IA32_APIC_BASE_APIC_GLOBAL_ENABLE_BIT 11
#define IA32_APIC_BASE_APIC_GLOBAL_ENABLE_FLAG 0x800
#define IA32_APIC_BASE_APIC_GLOBAL_ENABLE_MASK 0x01
#define IA32_APIC_BASE_APIC_GLOBAL_ENABLE(_) (((_) >> 11) & 0x01)
/**
* [Bits 47:12] APIC Base.
*/
UINT64_t apic_base : 36;
#define IA32_APIC_BASE_APIC_BASE_BIT 12
#define IA32_APIC_BASE_APIC_BASE_FLAG 0xFFFFFFFFF000
#define IA32_APIC_BASE_APIC_BASE_MASK 0xFFFFFFFFF
#define IA32_APIC_BASE_APIC_BASE(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved3 : 16;
};
UINT64_t flags;
} ia32_apic_base_register;
/**
* Control Features in Intel 64 Processor.
*
* @remarks If any one enumeration condition for defined bit field holds.
*/
#define IA32_FEATURE_CONTROL 0x0000003A
typedef union
{
struct
{
/**
* @brief Lock bit <b>(R/WO)</b>
*
* [Bit 0] When set, locks this MSR from being written; writes to this bit will result in GP(0).
*
* @note Once the Lock bit is set, the contents of this register cannot be modified. Therefore the lock bit must be set
* after configuring support for Intel Virtualization Technology and prior to transferring control to an option ROM or the
* OS. Hence, once the Lock bit is set, the entire IA32_FEATURE_CONTROL contents are preserved across RESET when PWRGOOD is
* not deasserted.
* @remarks If any one enumeration condition for defined bit field position greater than bit 0 holds.
*/
UINT64_t lock_bit : 1;
#define IA32_FEATURE_CONTROL_LOCK_BIT_BIT 0
#define IA32_FEATURE_CONTROL_LOCK_BIT_FLAG 0x01
#define IA32_FEATURE_CONTROL_LOCK_BIT_MASK 0x01
#define IA32_FEATURE_CONTROL_LOCK_BIT(_) (((_) >> 0) & 0x01)
/**
* @brief Enable VMX inside SMX operation <b>(R/WL)</b>
*
* [Bit 1] This bit enables a system executive to use VMX in conjunction with SMX to support Intel(R) Trusted Execution
* Technology. BIOS must set this bit only when the CPUID function 1 returns VMX feature flag and SMX feature flag set (ECX
* bits 5 and 6 respectively).
*
* @remarks If CPUID.01H:ECX[5] = 1 && CPUID.01H:ECX[6] = 1
*/
UINT64_t enable_vmx_inside_smx : 1;
#define IA32_FEATURE_CONTROL_ENABLE_VMX_INSIDE_SMX_BIT 1
#define IA32_FEATURE_CONTROL_ENABLE_VMX_INSIDE_SMX_FLAG 0x02
#define IA32_FEATURE_CONTROL_ENABLE_VMX_INSIDE_SMX_MASK 0x01
#define IA32_FEATURE_CONTROL_ENABLE_VMX_INSIDE_SMX(_) (((_) >> 1) & 0x01)
/**
* @brief Enable VMX outside SMX operation <b>(R/WL)</b>
*
* [Bit 2] This bit enables VMX for a system executive that does not require SMX. BIOS must set this bit only when the
* CPUID function 1 returns the VMX feature flag set (ECX bit 5).
*
* @remarks If CPUID.01H:ECX[5] = 1
*/
UINT64_t enable_vmx_outside_smx : 1;
#define IA32_FEATURE_CONTROL_ENABLE_VMX_OUTSIDE_SMX_BIT 2
#define IA32_FEATURE_CONTROL_ENABLE_VMX_OUTSIDE_SMX_FLAG 0x04
#define IA32_FEATURE_CONTROL_ENABLE_VMX_OUTSIDE_SMX_MASK 0x01
#define IA32_FEATURE_CONTROL_ENABLE_VMX_OUTSIDE_SMX(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 5;
/**
* @brief SENTER Local Function Enable <b>(R/WL)</b>
*
* [Bits 14:8] When set, each bit in the field represents an enable control for a corresponding SENTER function. This field
* is supported only if CPUID.1:ECX.[bit 6] is set.
*
* @remarks If CPUID.01H:ECX[6] = 1
*/
UINT64_t senter_local_function_enables : 7;
#define IA32_FEATURE_CONTROL_SENTER_LOCAL_FUNCTION_ENABLES_BIT 8
#define IA32_FEATURE_CONTROL_SENTER_LOCAL_FUNCTION_ENABLES_FLAG 0x7F00
#define IA32_FEATURE_CONTROL_SENTER_LOCAL_FUNCTION_ENABLES_MASK 0x7F
#define IA32_FEATURE_CONTROL_SENTER_LOCAL_FUNCTION_ENABLES(_) (((_) >> 8) & 0x7F)
/**
* @brief SENTER Global Enable <b>(R/WL)</b>
*
* [Bit 15] This bit must be set to enable SENTER leaf functions. This bit is supported only if CPUID.1:ECX.[bit 6] is set.
*
* @remarks If CPUID.01H:ECX[6] = 1
*/
UINT64_t senter_global_enable : 1;
#define IA32_FEATURE_CONTROL_SENTER_GLOBAL_ENABLE_BIT 15
#define IA32_FEATURE_CONTROL_SENTER_GLOBAL_ENABLE_FLAG 0x8000
#define IA32_FEATURE_CONTROL_SENTER_GLOBAL_ENABLE_MASK 0x01
#define IA32_FEATURE_CONTROL_SENTER_GLOBAL_ENABLE(_) (((_) >> 15) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief SGX Launch Control Enable <b>(R/WL)</b>
*
* [Bit 17] This bit must be set to enable runtime reconfiguration of SGX Launch Control via the IA32_SGXLEPUBKEYHASHn MSR.
*
* @remarks If CPUID.(EAX=07H, ECX=0H): ECX[30] = 1
*/
UINT64_t sgx_launch_control_enable : 1;
#define IA32_FEATURE_CONTROL_SGX_LAUNCH_CONTROL_ENABLE_BIT 17
#define IA32_FEATURE_CONTROL_SGX_LAUNCH_CONTROL_ENABLE_FLAG 0x20000
#define IA32_FEATURE_CONTROL_SGX_LAUNCH_CONTROL_ENABLE_MASK 0x01
#define IA32_FEATURE_CONTROL_SGX_LAUNCH_CONTROL_ENABLE(_) (((_) >> 17) & 0x01)
/**
* @brief SGX Global Enable <b>(R/WL)</b>
*
* [Bit 18] This bit must be set to enable SGX leaf functions.
*
* @remarks If CPUID.(EAX=07H, ECX=0H): EBX[2] = 1
*/
UINT64_t sgx_global_enable : 1;
#define IA32_FEATURE_CONTROL_SGX_GLOBAL_ENABLE_BIT 18
#define IA32_FEATURE_CONTROL_SGX_GLOBAL_ENABLE_FLAG 0x40000
#define IA32_FEATURE_CONTROL_SGX_GLOBAL_ENABLE_MASK 0x01
#define IA32_FEATURE_CONTROL_SGX_GLOBAL_ENABLE(_) (((_) >> 18) & 0x01)
UINT64_t reserved3 : 1;
/**
* @brief LMCE On <b>(R/WL)</b>
*
* [Bit 20] When set, system software can program the MSRs associated with LMCE to configure delivery of some machine check
* exceptions to a single logical processor.
*
* @remarks If IA32_MCG_CAP[27] = 1
*/
UINT64_t lmce_on : 1;
#define IA32_FEATURE_CONTROL_LMCE_ON_BIT 20
#define IA32_FEATURE_CONTROL_LMCE_ON_FLAG 0x100000
#define IA32_FEATURE_CONTROL_LMCE_ON_MASK 0x01
#define IA32_FEATURE_CONTROL_LMCE_ON(_) (((_) >> 20) & 0x01)
UINT64_t reserved4 : 43;
};
UINT64_t flags;
} ia32_feature_control_register;
/**
* Per Logical Processor TSC Adjust.
*
* @remarks If CPUID.(EAX=07H, ECX=0H): EBX[1] = 1
*/
#define IA32_TSC_ADJUST 0x0000003B
typedef struct
{
/**
* Local offset value of the IA32_TSC for a logical processor. Reset value is zero. A write to IA32_TSC will modify the
* local offset in IA32_TSC_ADJUST and the content of IA32_TSC, but does not affect the internal invariant TSC hardware.
*/
UINT64_t thread_adjust;
} ia32_tsc_adjust_register;
/**
* @brief BIOS Update Trigger <b>(W)</b>
*
* Executing a WRMSR instruction to this MSR causes a microcode update to be loaded into the processor. A processor may
* prevent writing to this MSR when loading guest states on VM entries or saving guest states on VM exits.
*
* @remarks 06_01H
* @see Vol3A[9.11.6(Microcode Update Loader)]
*/
#define IA32_BIOS_UPDATE_TRIGGER 0x00000079
/**
* @brief BIOS Update Signature <b>(RO)</b>
*
* Returns the microcode update signature following the execution of CPUID.01H. A processor may prevent writing to this MSR
* when loading guest states on VM entries or saving guest states on VM exits.
*
* @remarks 06_01H
*/
#define IA32_BIOS_UPDATE_SIGNATURE 0x0000008B
typedef union
{
struct
{
/**
* [Bits 31:0] Reserved.
*/
UINT64_t reserved : 32;
#define IA32_BIOS_UPDATE_SIGNATURE_RESERVED_BIT 0
#define IA32_BIOS_UPDATE_SIGNATURE_RESERVED_FLAG 0xFFFFFFFF
#define IA32_BIOS_UPDATE_SIGNATURE_RESERVED_MASK 0xFFFFFFFF
#define IA32_BIOS_UPDATE_SIGNATURE_RESERVED(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* @brief Microcode update signature
*
* [Bits 63:32] This field contains the signature of the currently loaded microcode update when read following the
* execution of the CPUID instruction, function 1. It is required that this register field be pre-loaded with zero prior to
* executing the CPUID, function 1. If the field remains equal to zero, then there is no microcode update loaded. Another
* nonzero value will be the signature.
*
* @see Vol3A[9.11.7.1(Determining the Signature)] (reference)
*/
UINT64_t microcode_update_signature : 32;
#define IA32_BIOS_UPDATE_SIGNATURE_MICROCODE_UPDATE_SIGNATURE_BIT 32
#define IA32_BIOS_UPDATE_SIGNATURE_MICROCODE_UPDATE_SIGNATURE_FLAG 0xFFFFFFFF00000000
#define IA32_BIOS_UPDATE_SIGNATURE_MICROCODE_UPDATE_SIGNATURE_MASK 0xFFFFFFFF
#define IA32_BIOS_UPDATE_SIGNATURE_MICROCODE_UPDATE_SIGNATURE(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_bios_update_signature_register;
/**
* @defgroup ia32_sgxlepubkeyhash \
* IA32_SGXLEPUBKEYHASH[(64*n+63):(64*n)]
*
* Bits (64*n+63):(64*n) of the SHA256 digest of the SIGSTRUCT.MODULUS for SGX Launch Enclave. On reset, the default value
* is the digest of Intel's signing key.
*
* @remarks Read permitted If CPUID.(EAX=12H,ECX=0H): EAX[0]=1 && CPUID.(EAX=07H,ECX=0H):ECX[30]=1. Write permitted if
* CPUID.(EAX=12H,ECX=0H): EAX[0]=1 && IA32_FEATURE_CONTROL[17] = 1 && IA32_FEATURE_CONTROL[0] = 1.
* @{
*/
#define IA32_SGXLEPUBKEYHASH0 0x0000008C
#define IA32_SGXLEPUBKEYHASH1 0x0000008D
#define IA32_SGXLEPUBKEYHASH2 0x0000008E
#define IA32_SGXLEPUBKEYHASH3 0x0000008F
/**
* @}
*/
/**
* SMM Monitor Configuration.
*
* @remarks If CPUID.01H: ECX[5]=1 || CPUID.01H: ECX[6] = 1
*/
#define IA32_SMM_MONITOR_CTL 0x0000009B
typedef union
{
struct
{
/**
* @brief Valid <b>(R/W)</b>
*
* [Bit 0] The STM may be invoked using VMCALL only if this bit is 1. Because VMCALL is used to activate the dual-monitor
* treatment, the dual-monitor treatment cannot be activated if the bit is 0. This bit is cleared when the logical
* processor is reset.
*
* @see Vol3C[34.15.6(Activating the Dual-Monitor Treatment)]
* @see Vol3C[34.15.5(Enabling the Dual-Monitor Treatment)] (reference)
*/
UINT64_t valid : 1;
#define IA32_SMM_MONITOR_CTL_VALID_BIT 0
#define IA32_SMM_MONITOR_CTL_VALID_FLAG 0x01
#define IA32_SMM_MONITOR_CTL_VALID_MASK 0x01
#define IA32_SMM_MONITOR_CTL_VALID(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief Controls SMI unblocking by VMXOFF
*
* [Bit 2] Determines whether executions of VMXOFF unblock SMIs under the default treatment of SMIs and SMM. Executions of
* VMXOFF unblock SMIs unless bit 2 is 1 (the value of bit 0 is irrelevant).
*
* @remarks If IA32_VMX_MISC[28]
* @see Vol3C[34.14.4(VMXOFF and SMI Unblocking)]
* @see Vol3C[34.15.5(Enabling the Dual-Monitor Treatment)] (reference)
*/
UINT64_t smi_unblocking_by_vmxoff : 1;
#define IA32_SMM_MONITOR_CTL_SMI_UNBLOCKING_BY_VMXOFF_BIT 2
#define IA32_SMM_MONITOR_CTL_SMI_UNBLOCKING_BY_VMXOFF_FLAG 0x04
#define IA32_SMM_MONITOR_CTL_SMI_UNBLOCKING_BY_VMXOFF_MASK 0x01
#define IA32_SMM_MONITOR_CTL_SMI_UNBLOCKING_BY_VMXOFF(_) (((_) >> 2) & 0x01)
UINT64_t reserved2 : 9;
/**
* @brief MSEG Base <b>(R/W)</b>
*
* [Bits 31:12] Value that, when shifted left 12 bits, is the physical address of MSEG (the MSEG base address).
*
* @see Vol3C[34.15.5(Enabling the Dual-Monitor Treatment)] (reference)
*/
UINT64_t mseg_base : 20;
#define IA32_SMM_MONITOR_CTL_MSEG_BASE_BIT 12
#define IA32_SMM_MONITOR_CTL_MSEG_BASE_FLAG 0xFFFFF000
#define IA32_SMM_MONITOR_CTL_MSEG_BASE_MASK 0xFFFFF
#define IA32_SMM_MONITOR_CTL_MSEG_BASE(_) (((_) >> 12) & 0xFFFFF)
UINT64_t reserved3 : 32;
};
UINT64_t flags;
} ia32_smm_monitor_ctl_register;
typedef struct
{
/**
* @brief MSEG revision identifier
*
* Different processors may use different MSEG revision identifiers. These identifiers enable software to avoid using an
* MSEG header formatted for one processor on a processor that uses a different format. Software can discover the MSEG
* revision identifier that a processor uses by reading the VMX capability MSR IA32_VMX_MISC.
*
* @see Vol3D[A.6(MISCELLANEOUS DATA)]
*/
UINT32_t mseg_header_revision;
/**
* @brief SMM-transfer monitor features field
*
* Bits 31:1 of this field are reserved and must be zero. Bit 0 of the field is the IA-32e mode SMM feature bit. It
* indicates whether the logical processor will be in IA-32e mode after the STM is activated.
*
* @see Vol3C[34.15.6(Activating the Dual-Monitor Treatment)]
*/
UINT32_t monitor_features;
/**
* Define values for the MonitorFeatures field of MSEG_HEADER.
*/
#define IA32_STM_FEATURES_IA32E 0x00000001
/**
* Fields that determine how processor state is loaded when the STM is activated. SMM code should establish these fields so
* that activating of the STM invokes the STM's initialization code.
*
* @see Vol3C[34.15.6.5(Loading Host State)]
*/
UINT32_t gdtr_limit;
UINT32_t gdtr_base_offset;
UINT32_t cs_selector;
UINT32_t eip_offset;
UINT32_t esp_offset;
UINT32_t cr3_offset;
} ia32_mseg_header;
/**
* Base address of the logical processor's SMRAM image.
*
* @remarks If IA32_VMX_MISC[15]
*/
#define IA32_SMBASE 0x0000009E
/**
* @defgroup ia32_pmc \
* IA32_PMC(n)
*
* General Performance Counters.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
* @{
*/
#define IA32_PMC0 0x000000C1
#define IA32_PMC1 0x000000C2
#define IA32_PMC2 0x000000C3
#define IA32_PMC3 0x000000C4
#define IA32_PMC4 0x000000C5
#define IA32_PMC5 0x000000C6
#define IA32_PMC6 0x000000C7
#define IA32_PMC7 0x000000C8
/**
* @}
*/
/**
* TSC Frequency Clock Counter.
*
* @remarks If CPUID.06H: ECX[0] = 1
*/
#define IA32_MPERF 0x000000E7
typedef struct
{
/**
* @brief C0 TSC Frequency Clock Count
*
* Increments at fixed interval (relative to TSC freq.) when the logical processor is in C0. Cleared upon overflow /
* wrap-around of IA32_APERF.
*/
UINT64_t c0_mcnt;
} ia32_mperf_register;
/**
* Actual Performance Clock Counter
*
* @remarks If CPUID.06H: ECX[0] = 1
*/
#define IA32_APERF 0x000000E8
typedef struct
{
/**
* @brief C0 Actual Frequency Clock Count
*
* Accumulates core clock counts at the coordinated clock frequency, when the logical processor is in C0. Cleared upon
* overflow / wrap-around of IA32_MPERF.
*/
UINT64_t c0_acnt;
} ia32_aperf_register;
/**
* MTRR Capability.
*
* @see Vol3A[11.11.2.1(IA32_MTRR_DEF_TYPE MSR)]
* @see Vol3A[11.11.1(MTRR Feature Identification)] (reference)
*/
#define IA32_MTRR_CAPABILITIES 0x000000FE
typedef union
{
struct
{
/**
* @brief VCNT (variable range registers count) field
*
* [Bits 7:0] Indicates the number of variable ranges implemented on the processor.
*/
UINT64_t variable_range_count : 8;
#define IA32_MTRR_CAPABILITIES_VARIABLE_RANGE_COUNT_BIT 0
#define IA32_MTRR_CAPABILITIES_VARIABLE_RANGE_COUNT_FLAG 0xFF
#define IA32_MTRR_CAPABILITIES_VARIABLE_RANGE_COUNT_MASK 0xFF
#define IA32_MTRR_CAPABILITIES_VARIABLE_RANGE_COUNT(_) (((_) >> 0) & 0xFF)
/**
* @brief FIX (fixed range registers supported) flag
*
* [Bit 8] Fixed range MTRRs (IA32_MTRR_FIX64K_00000 through IA32_MTRR_FIX4K_0F8000) are supported when set; no fixed range
* registers are supported when clear.
*/
UINT64_t fixed_range_supported : 1;
#define IA32_MTRR_CAPABILITIES_FIXED_RANGE_SUPPORTED_BIT 8
#define IA32_MTRR_CAPABILITIES_FIXED_RANGE_SUPPORTED_FLAG 0x100
#define IA32_MTRR_CAPABILITIES_FIXED_RANGE_SUPPORTED_MASK 0x01
#define IA32_MTRR_CAPABILITIES_FIXED_RANGE_SUPPORTED(_) (((_) >> 8) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief WC (write combining) flag
*
* [Bit 10] The write-combining (WC) memory type is supported when set; the WC type is not supported when clear.
*/
UINT64_t wc_supported : 1;
#define IA32_MTRR_CAPABILITIES_WC_SUPPORTED_BIT 10
#define IA32_MTRR_CAPABILITIES_WC_SUPPORTED_FLAG 0x400
#define IA32_MTRR_CAPABILITIES_WC_SUPPORTED_MASK 0x01
#define IA32_MTRR_CAPABILITIES_WC_SUPPORTED(_) (((_) >> 10) & 0x01)
/**
* @brief SMRR (System-Management Range Register) flag
*
* [Bit 11] The system-management range register (SMRR) interface is supported when bit 11 is set; the SMRR interface is
* not supported when clear.
*/
UINT64_t smrr_supported : 1;
#define IA32_MTRR_CAPABILITIES_SMRR_SUPPORTED_BIT 11
#define IA32_MTRR_CAPABILITIES_SMRR_SUPPORTED_FLAG 0x800
#define IA32_MTRR_CAPABILITIES_SMRR_SUPPORTED_MASK 0x01
#define IA32_MTRR_CAPABILITIES_SMRR_SUPPORTED(_) (((_) >> 11) & 0x01)
UINT64_t reserved2 : 52;
};
UINT64_t flags;
} ia32_mtrr_capabilities_register;
/**
* @brief SYSENTER_CS_MSR <b>(R/W)</b>
*
* The lower 16 bits of this MSR are the segment selector for the privilege level 0 code segment. This value is also used
* to determine the segment selector of the privilege level 0 stack segment. This value cannot indicate a null selector.
*
* @remarks 06_01H
* @see Vol2B[4.3(Instructions (M-U) | SYSCALL - Fast System Call)] (reference)
*/
#define IA32_SYSENTER_CS 0x00000174
typedef union
{
struct
{
/**
* [Bits 15:0] CS Selector.
*/
UINT64_t cs_selector : 16;
#define IA32_SYSENTER_CS_CS_SELECTOR_BIT 0
#define IA32_SYSENTER_CS_CS_SELECTOR_FLAG 0xFFFF
#define IA32_SYSENTER_CS_CS_SELECTOR_MASK 0xFFFF
#define IA32_SYSENTER_CS_CS_SELECTOR(_) (((_) >> 0) & 0xFFFF)
/**
* [Bits 31:16] Not used.
*
* @remarks Can be read and written.
*/
UINT64_t not_used_1 : 16;
#define IA32_SYSENTER_CS_NOT_USED_1_BIT 16
#define IA32_SYSENTER_CS_NOT_USED_1_FLAG 0xFFFF0000
#define IA32_SYSENTER_CS_NOT_USED_1_MASK 0xFFFF
#define IA32_SYSENTER_CS_NOT_USED_1(_) (((_) >> 16) & 0xFFFF)
/**
* [Bits 63:32] Not used.
*
* @remarks Writes ignored; reads return zero.
*/
UINT64_t not_used_2 : 32;
#define IA32_SYSENTER_CS_NOT_USED_2_BIT 32
#define IA32_SYSENTER_CS_NOT_USED_2_FLAG 0xFFFFFFFF00000000
#define IA32_SYSENTER_CS_NOT_USED_2_MASK 0xFFFFFFFF
#define IA32_SYSENTER_CS_NOT_USED_2(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_sysenter_cs_register;
/**
* @brief SYSENTER_ESP_MSR <b>(R/W)</b>
*
* The value of this MSR is loaded into RSP (thus, this value contains the stack pointer for the privilege level 0 stack).
* This value cannot represent a non-canonical address. In protected mode, only bits 31:0 are loaded.
*
* @remarks 06_01H
* @see Vol2B[4.3(Instructions (M-U) | SYSCALL - Fast System Call)] (reference)
*/
#define IA32_SYSENTER_ESP 0x00000175
/**
* @brief SYSENTER_EIP_MSR <b>(R/W)</b>
*
* The value of this MSR is loaded into RIP (thus, this value references the first instruction of the selected operating
* procedure or routine). In protected mode, only bits 31:0 are loaded.
*
* @remarks 06_01H
* @see Vol2B[4.3(Instructions (M-U) | SYSCALL - Fast System Call)] (reference)
*/
#define IA32_SYSENTER_EIP 0x00000176
/**
* Global Machine Check Capability.
*
* @remarks 06_01H
*/
#define IA32_MCG_CAP 0x00000179
typedef union
{
struct
{
/**
* [Bits 7:0] Number of reporting banks.
*/
UINT64_t count : 8;
#define IA32_MCG_CAP_COUNT_BIT 0
#define IA32_MCG_CAP_COUNT_FLAG 0xFF
#define IA32_MCG_CAP_COUNT_MASK 0xFF
#define IA32_MCG_CAP_COUNT(_) (((_) >> 0) & 0xFF)
/**
* [Bit 8] IA32_MCG_CTL is present if this bit is set.
*/
UINT64_t mcg_ctl_p : 1;
#define IA32_MCG_CAP_MCG_CTL_P_BIT 8
#define IA32_MCG_CAP_MCG_CTL_P_FLAG 0x100
#define IA32_MCG_CAP_MCG_CTL_P_MASK 0x01
#define IA32_MCG_CAP_MCG_CTL_P(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Extended machine check state registers are present if this bit is set.
*/
UINT64_t mcg_ext_p : 1;
#define IA32_MCG_CAP_MCG_EXT_P_BIT 9
#define IA32_MCG_CAP_MCG_EXT_P_FLAG 0x200
#define IA32_MCG_CAP_MCG_EXT_P_MASK 0x01
#define IA32_MCG_CAP_MCG_EXT_P(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Support for corrected MC error event is present.
*
* @remarks 06_01H
*/
UINT64_t mcp_cmci_p : 1;
#define IA32_MCG_CAP_MCP_CMCI_P_BIT 10
#define IA32_MCG_CAP_MCP_CMCI_P_FLAG 0x400
#define IA32_MCG_CAP_MCP_CMCI_P_MASK 0x01
#define IA32_MCG_CAP_MCP_CMCI_P(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] Threshold-based error status register are present if this bit is set.
*/
UINT64_t mcg_tes_p : 1;
#define IA32_MCG_CAP_MCG_TES_P_BIT 11
#define IA32_MCG_CAP_MCG_TES_P_FLAG 0x800
#define IA32_MCG_CAP_MCG_TES_P_MASK 0x01
#define IA32_MCG_CAP_MCG_TES_P(_) (((_) >> 11) & 0x01)
UINT64_t reserved1 : 4;
/**
* [Bits 23:16] Number of extended machine check state registers present.
*/
UINT64_t mcg_ext_cnt : 8;
#define IA32_MCG_CAP_MCG_EXT_CNT_BIT 16
#define IA32_MCG_CAP_MCG_EXT_CNT_FLAG 0xFF0000
#define IA32_MCG_CAP_MCG_EXT_CNT_MASK 0xFF
#define IA32_MCG_CAP_MCG_EXT_CNT(_) (((_) >> 16) & 0xFF)
/**
* [Bit 24] The processor supports software error recovery if this bit is set.
*/
UINT64_t mcg_ser_p : 1;
#define IA32_MCG_CAP_MCG_SER_P_BIT 24
#define IA32_MCG_CAP_MCG_SER_P_FLAG 0x1000000
#define IA32_MCG_CAP_MCG_SER_P_MASK 0x01
#define IA32_MCG_CAP_MCG_SER_P(_) (((_) >> 24) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 26] Indicates that the processor allows platform firmware to be invoked when an error is detected so that it may
* provide additional platform specific information in an ACPI format "Generic Error Data Entry" that augments the data
* included in machine check bank registers.
*
* @remarks 06_3EH
*/
UINT64_t mcg_elog_p : 1;
#define IA32_MCG_CAP_MCG_ELOG_P_BIT 26
#define IA32_MCG_CAP_MCG_ELOG_P_FLAG 0x4000000
#define IA32_MCG_CAP_MCG_ELOG_P_MASK 0x01
#define IA32_MCG_CAP_MCG_ELOG_P(_) (((_) >> 26) & 0x01)
/**
* [Bit 27] Indicates that the processor supports extended state in IA32_MCG_STATUS and associated MSR necessary to
* configure Local Machine Check Exception (LMCE).
*
* @remarks 06_3EH
*/
UINT64_t mcg_lmce_p : 1;
#define IA32_MCG_CAP_MCG_LMCE_P_BIT 27
#define IA32_MCG_CAP_MCG_LMCE_P_FLAG 0x8000000
#define IA32_MCG_CAP_MCG_LMCE_P_MASK 0x01
#define IA32_MCG_CAP_MCG_LMCE_P(_) (((_) >> 27) & 0x01)
UINT64_t reserved3 : 36;
};
UINT64_t flags;
} ia32_mcg_cap_register;
/**
* Global Machine Check Status.
*
* @remarks 06_01H
*/
#define IA32_MCG_STATUS 0x0000017A
typedef union
{
struct
{
/**
* [Bit 0] Restart IP valid.
*
* @remarks 06_01H
*/
UINT64_t ripv : 1;
#define IA32_MCG_STATUS_RIPV_BIT 0
#define IA32_MCG_STATUS_RIPV_FLAG 0x01
#define IA32_MCG_STATUS_RIPV_MASK 0x01
#define IA32_MCG_STATUS_RIPV(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Error IP valid.
*
* @remarks 06_01H
*/
UINT64_t eipv : 1;
#define IA32_MCG_STATUS_EIPV_BIT 1
#define IA32_MCG_STATUS_EIPV_FLAG 0x02
#define IA32_MCG_STATUS_EIPV_MASK 0x01
#define IA32_MCG_STATUS_EIPV(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Machine check in progress.
*
* @remarks 06_01H
*/
UINT64_t mcip : 1;
#define IA32_MCG_STATUS_MCIP_BIT 2
#define IA32_MCG_STATUS_MCIP_FLAG 0x04
#define IA32_MCG_STATUS_MCIP_MASK 0x01
#define IA32_MCG_STATUS_MCIP(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] If IA32_MCG_CAP.LMCE_P[27] = 1.
*/
UINT64_t lmce_s : 1;
#define IA32_MCG_STATUS_LMCE_S_BIT 3
#define IA32_MCG_STATUS_LMCE_S_FLAG 0x08
#define IA32_MCG_STATUS_LMCE_S_MASK 0x01
#define IA32_MCG_STATUS_LMCE_S(_) (((_) >> 3) & 0x01)
UINT64_t reserved1 : 60;
};
UINT64_t flags;
} ia32_mcg_status_register;
/**
* Global Machine Check Control.
*
* @remarks If IA32_MCG_CAP.CTL_P[8] = 1
*/
#define IA32_MCG_CTL 0x0000017B
/**
* @defgroup ia32_perfevtsel \
* IA32_PERFEVTSEL(n)
*
* Performance Event Select Register n.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
* @{
*/
#define IA32_PERFEVTSEL0 0x00000186
#define IA32_PERFEVTSEL1 0x00000187
#define IA32_PERFEVTSEL2 0x00000188
#define IA32_PERFEVTSEL3 0x00000189
typedef union
{
struct
{
/**
* [Bits 7:0] Selects a performance event logic unit.
*/
UINT64_t event_select : 8;
#define IA32_PERFEVTSEL_EVENT_SELECT_BIT 0
#define IA32_PERFEVTSEL_EVENT_SELECT_FLAG 0xFF
#define IA32_PERFEVTSEL_EVENT_SELECT_MASK 0xFF
#define IA32_PERFEVTSEL_EVENT_SELECT(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Qualifies the microarchitectural condition to detect on the selected event logic.
*/
UINT64_t u_mask : 8;
#define IA32_PERFEVTSEL_U_MASK_BIT 8
#define IA32_PERFEVTSEL_U_MASK_FLAG 0xFF00
#define IA32_PERFEVTSEL_U_MASK_MASK 0xFF
#define IA32_PERFEVTSEL_U_MASK(_) (((_) >> 8) & 0xFF)
/**
* [Bit 16] Counts while in privilege level is not ring 0.
*/
UINT64_t usr : 1;
#define IA32_PERFEVTSEL_USR_BIT 16
#define IA32_PERFEVTSEL_USR_FLAG 0x10000
#define IA32_PERFEVTSEL_USR_MASK 0x01
#define IA32_PERFEVTSEL_USR(_) (((_) >> 16) & 0x01)
/**
* [Bit 17] Counts while in privilege level is ring 0.
*/
UINT64_t os : 1;
#define IA32_PERFEVTSEL_OS_BIT 17
#define IA32_PERFEVTSEL_OS_FLAG 0x20000
#define IA32_PERFEVTSEL_OS_MASK 0x01
#define IA32_PERFEVTSEL_OS(_) (((_) >> 17) & 0x01)
/**
* [Bit 18] Enables edge detection if set.
*/
UINT64_t edge : 1;
#define IA32_PERFEVTSEL_EDGE_BIT 18
#define IA32_PERFEVTSEL_EDGE_FLAG 0x40000
#define IA32_PERFEVTSEL_EDGE_MASK 0x01
#define IA32_PERFEVTSEL_EDGE(_) (((_) >> 18) & 0x01)
/**
* [Bit 19] Enables pin control.
*/
UINT64_t pc : 1;
#define IA32_PERFEVTSEL_PC_BIT 19
#define IA32_PERFEVTSEL_PC_FLAG 0x80000
#define IA32_PERFEVTSEL_PC_MASK 0x01
#define IA32_PERFEVTSEL_PC(_) (((_) >> 19) & 0x01)
/**
* [Bit 20] Enables interrupt on counter overflow.
*/
UINT64_t intr : 1;
#define IA32_PERFEVTSEL_INTR_BIT 20
#define IA32_PERFEVTSEL_INTR_FLAG 0x100000
#define IA32_PERFEVTSEL_INTR_MASK 0x01
#define IA32_PERFEVTSEL_INTR(_) (((_) >> 20) & 0x01)
/**
* [Bit 21] When set to 1, it enables counting the associated event conditions occurring across all logical processors
* sharing a processor core. When set to 0, the counter only increments the associated event conditions occurring in the
* logical processor which programmed the MSR.
*/
UINT64_t any_thread : 1;
#define IA32_PERFEVTSEL_ANY_THREAD_BIT 21
#define IA32_PERFEVTSEL_ANY_THREAD_FLAG 0x200000
#define IA32_PERFEVTSEL_ANY_THREAD_MASK 0x01
#define IA32_PERFEVTSEL_ANY_THREAD(_) (((_) >> 21) & 0x01)
/**
* [Bit 22] Enables the corresponding performance counter to commence counting when this bit is set.
*/
UINT64_t en : 1;
#define IA32_PERFEVTSEL_EN_BIT 22
#define IA32_PERFEVTSEL_EN_FLAG 0x400000
#define IA32_PERFEVTSEL_EN_MASK 0x01
#define IA32_PERFEVTSEL_EN(_) (((_) >> 22) & 0x01)
/**
* [Bit 23] Invert the CMASK.
*/
UINT64_t inv : 1;
#define IA32_PERFEVTSEL_INV_BIT 23
#define IA32_PERFEVTSEL_INV_FLAG 0x800000
#define IA32_PERFEVTSEL_INV_MASK 0x01
#define IA32_PERFEVTSEL_INV(_) (((_) >> 23) & 0x01)
/**
* [Bits 31:24] When CMASK is not zero, the corresponding performance counter increments each cycle if the event count is
* greater than or equal to the CMASK.
*/
UINT64_t cmask : 8;
#define IA32_PERFEVTSEL_CMASK_BIT 24
#define IA32_PERFEVTSEL_CMASK_FLAG 0xFF000000
#define IA32_PERFEVTSEL_CMASK_MASK 0xFF
#define IA32_PERFEVTSEL_CMASK(_) (((_) >> 24) & 0xFF)
UINT64_t reserved1 : 32;
};
UINT64_t flags;
} ia32_perfevtsel_register;
/**
* @}
*/
/**
* Current Performance Status.
*
* @remarks 0F_03H
* @see Vol3B[14.1.1(Software Interface For Initiating Performance State Transitions)]
*/
#define IA32_PERF_STATUS 0x00000198
typedef union
{
struct
{
/**
* [Bits 15:0] Current performance State Value.
*/
UINT64_t state_value : 16;
#define IA32_PERF_STATUS_STATE_VALUE_BIT 0
#define IA32_PERF_STATUS_STATE_VALUE_FLAG 0xFFFF
#define IA32_PERF_STATUS_STATE_VALUE_MASK 0xFFFF
#define IA32_PERF_STATUS_STATE_VALUE(_) (((_) >> 0) & 0xFFFF)
UINT64_t reserved1 : 48;
};
UINT64_t flags;
} ia32_perf_status_register;
/**
* @brief Performance Control <b>(R/W)</b>
*
* Performance Control. Software makes a request for a new Performance state (P-State) by writing this MSR.
*
* @remarks 0F_03H
* @see Vol3B[14.1.1(Software Interface For Initiating Performance State Transitions)]
*/
#define IA32_PERF_CTL 0x00000199
typedef union
{
struct
{
/**
* [Bits 15:0] Target performance State Value.
*/
UINT64_t target_state_value : 16;
#define IA32_PERF_CTL_TARGET_STATE_VALUE_BIT 0
#define IA32_PERF_CTL_TARGET_STATE_VALUE_FLAG 0xFFFF
#define IA32_PERF_CTL_TARGET_STATE_VALUE_MASK 0xFFFF
#define IA32_PERF_CTL_TARGET_STATE_VALUE(_) (((_) >> 0) & 0xFFFF)
UINT64_t reserved1 : 16;
/**
* [Bit 32] IDA Engage.
*
* @remarks 06_0FH (Mobile only)
*/
UINT64_t ida_engage : 1;
#define IA32_PERF_CTL_IDA_ENGAGE_BIT 32
#define IA32_PERF_CTL_IDA_ENGAGE_FLAG 0x100000000
#define IA32_PERF_CTL_IDA_ENGAGE_MASK 0x01
#define IA32_PERF_CTL_IDA_ENGAGE(_) (((_) >> 32) & 0x01)
UINT64_t reserved2 : 31;
};
UINT64_t flags;
} ia32_perf_ctl_register;
/**
* Clock Modulation Control.
*
* @remarks If CPUID.01H:EDX[22] = 1
* @see Vol3B[14.7.3(Software Controlled Clock Modulation)]
*/
#define IA32_CLOCK_MODULATION 0x0000019A
typedef union
{
struct
{
/**
* [Bit 0] Extended On-Demand Clock Modulation Duty Cycle.
*
* @remarks If CPUID.06H:EAX[5] = 1
*/
UINT64_t extended_on_demand_clock_modulation_duty_cycle : 1;
#define IA32_CLOCK_MODULATION_EXTENDED_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_BIT 0
#define IA32_CLOCK_MODULATION_EXTENDED_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_FLAG 0x01
#define IA32_CLOCK_MODULATION_EXTENDED_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_MASK 0x01
#define IA32_CLOCK_MODULATION_EXTENDED_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE(_) (((_) >> 0) & 0x01)
/**
* @brief On-Demand Clock Modulation Duty Cycle
*
* [Bits 3:1] On-Demand Clock Modulation Duty Cycle: Specific encoded values for target duty cycle modulation.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t on_demand_clock_modulation_duty_cycle : 3;
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_BIT 1
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_FLAG 0x0E
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE_MASK 0x07
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_DUTY_CYCLE(_) (((_) >> 1) & 0x07)
/**
* @brief On-Demand Clock Modulation Enable
*
* [Bit 4] On-Demand Clock Modulation Enable: Set 1 to enable modulation.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t on_demand_clock_modulation_enable : 1;
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_ENABLE_BIT 4
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_ENABLE_FLAG 0x10
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_ENABLE_MASK 0x01
#define IA32_CLOCK_MODULATION_ON_DEMAND_CLOCK_MODULATION_ENABLE(_) (((_) >> 4) & 0x01)
UINT64_t reserved1 : 59;
};
UINT64_t flags;
} ia32_clock_modulation_register;
/**
* @brief Thermal Interrupt Control <b>(R/W)</b>
*
* Thermal Interrupt Control. Enables and disables the generation of an interrupt on temperature transitions detected with
* the processor's thermal sensors and thermal monitor.
*
* @remarks If CPUID.01H:EDX[22] = 1
* @see Vol3B[14.7.2(Thermal Monitor)]
*/
#define IA32_THERM_INTERRUPT 0x0000019B
typedef union
{
struct
{
/**
* [Bit 0] High-Temperature Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t high_temperature_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_BIT 0
#define IA32_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_FLAG 0x01
#define IA32_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Low-Temperature Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t low_temperature_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_BIT 1
#define IA32_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_FLAG 0x02
#define IA32_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] PROCHOT\# Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t prochot_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_BIT 2
#define IA32_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_FLAG 0x04
#define IA32_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] FORCEPR\# Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t forcepr_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_FORCEPR_INTERRUPT_ENABLE_BIT 3
#define IA32_THERM_INTERRUPT_FORCEPR_INTERRUPT_ENABLE_FLAG 0x08
#define IA32_THERM_INTERRUPT_FORCEPR_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_FORCEPR_INTERRUPT_ENABLE(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Critical Temperature Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t critical_temperature_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_CRITICAL_TEMPERATURE_INTERRUPT_ENABLE_BIT 4
#define IA32_THERM_INTERRUPT_CRITICAL_TEMPERATURE_INTERRUPT_ENABLE_FLAG 0x10
#define IA32_THERM_INTERRUPT_CRITICAL_TEMPERATURE_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_CRITICAL_TEMPERATURE_INTERRUPT_ENABLE(_) (((_) >> 4) & 0x01)
UINT64_t reserved1 : 3;
/**
* [Bits 14:8] Threshold \#1 Value
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t threshold1_value : 7;
#define IA32_THERM_INTERRUPT_THRESHOLD1_VALUE_BIT 8
#define IA32_THERM_INTERRUPT_THRESHOLD1_VALUE_FLAG 0x7F00
#define IA32_THERM_INTERRUPT_THRESHOLD1_VALUE_MASK 0x7F
#define IA32_THERM_INTERRUPT_THRESHOLD1_VALUE(_) (((_) >> 8) & 0x7F)
/**
* [Bit 15] Threshold \#1 Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t threshold1_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_BIT 15
#define IA32_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_FLAG 0x8000
#define IA32_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE(_) (((_) >> 15) & 0x01)
/**
* [Bits 22:16] Threshold \#2 Value.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t threshold2_value : 7;
#define IA32_THERM_INTERRUPT_THRESHOLD2_VALUE_BIT 16
#define IA32_THERM_INTERRUPT_THRESHOLD2_VALUE_FLAG 0x7F0000
#define IA32_THERM_INTERRUPT_THRESHOLD2_VALUE_MASK 0x7F
#define IA32_THERM_INTERRUPT_THRESHOLD2_VALUE(_) (((_) >> 16) & 0x7F)
/**
* [Bit 23] Threshold \#2 Interrupt Enable.
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t threshold2_interrupt_enable : 1;
#define IA32_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_BIT 23
#define IA32_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_FLAG 0x800000
#define IA32_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE(_) (((_) >> 23) & 0x01)
/**
* [Bit 24] Power Limit Notification Enable.
*
* @remarks If CPUID.06H:EAX[4] = 1
*/
UINT64_t power_limit_notification_enable : 1;
#define IA32_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_BIT 24
#define IA32_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_FLAG 0x1000000
#define IA32_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_MASK 0x01
#define IA32_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE(_) (((_) >> 24) & 0x01)
UINT64_t reserved2 : 39;
};
UINT64_t flags;
} ia32_therm_interrupt_register;
/**
* @brief Thermal Status Information <b>(RO)</b>
*
* Thermal Status Information. Contains status information about the processor's thermal sensor and automatic thermal
* monitoring facilities.
*
* @remarks If CPUID.01H:EDX[22] = 1
* @see Vol3B[14.7.2(Thermal Monitor)]
*/
#define IA32_THERM_STATUS 0x0000019C
typedef union
{
struct
{
/**
* [Bit 0] Thermal Status
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t thermal_status : 1;
#define IA32_THERM_STATUS_THERMAL_STATUS_BIT 0
#define IA32_THERM_STATUS_THERMAL_STATUS_FLAG 0x01
#define IA32_THERM_STATUS_THERMAL_STATUS_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_STATUS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Thermal Status Log
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t thermal_status_log : 1;
#define IA32_THERM_STATUS_THERMAL_STATUS_LOG_BIT 1
#define IA32_THERM_STATUS_THERMAL_STATUS_LOG_FLAG 0x02
#define IA32_THERM_STATUS_THERMAL_STATUS_LOG_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_STATUS_LOG(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] PROCHOT \# or FORCEPR\# event
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t prochot_forcepr_event : 1;
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_EVENT_BIT 2
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_EVENT_FLAG 0x04
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_EVENT_MASK 0x01
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_EVENT(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] PROCHOT \# or FORCEPR\# log
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t prochot_forcepr_log : 1;
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_LOG_BIT 3
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_LOG_FLAG 0x08
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_LOG_MASK 0x01
#define IA32_THERM_STATUS_PROCHOT_FORCEPR_LOG(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Critical Temperature Status
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t critical_temperature_status : 1;
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_BIT 4
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_FLAG 0x10
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_MASK 0x01
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Critical Temperature Status log
*
* @remarks If CPUID.01H:EDX[22] = 1
*/
UINT64_t critical_temperature_status_log : 1;
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_BIT 5
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_FLAG 0x20
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_MASK 0x01
#define IA32_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Thermal Threshold \#1 Status
*
* @remarks If CPUID.01H:ECX[8] = 1
*/
UINT64_t thermal_threshold1_status : 1;
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_BIT 6
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_FLAG 0x40
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_STATUS(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Thermal Threshold \#1 log
*
* @remarks If CPUID.01H:ECX[8] = 1
*/
UINT64_t thermal_threshold1_log : 1;
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_LOG_BIT 7
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_LOG_FLAG 0x80
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_LOG_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_THRESHOLD1_LOG(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Thermal Threshold \#2 Status
*
* @remarks If CPUID.01H:ECX[8] = 1
*/
UINT64_t thermal_threshold2_status : 1;
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_BIT 8
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_FLAG 0x100
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_STATUS(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Thermal Threshold \#2 log
*
* @remarks If CPUID.01H:ECX[8] = 1
*/
UINT64_t thermal_threshold2_log : 1;
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_LOG_BIT 9
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_LOG_FLAG 0x200
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_LOG_MASK 0x01
#define IA32_THERM_STATUS_THERMAL_THRESHOLD2_LOG(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Power Limitation Status
*
* @remarks If CPUID.06H:EAX[4] = 1
*/
UINT64_t power_limitation_status : 1;
#define IA32_THERM_STATUS_POWER_LIMITATION_STATUS_BIT 10
#define IA32_THERM_STATUS_POWER_LIMITATION_STATUS_FLAG 0x400
#define IA32_THERM_STATUS_POWER_LIMITATION_STATUS_MASK 0x01
#define IA32_THERM_STATUS_POWER_LIMITATION_STATUS(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] Power Limitation log
*
* @remarks If CPUID.06H:EAX[4] = 1
*/
UINT64_t power_limitation_log : 1;
#define IA32_THERM_STATUS_POWER_LIMITATION_LOG_BIT 11
#define IA32_THERM_STATUS_POWER_LIMITATION_LOG_FLAG 0x800
#define IA32_THERM_STATUS_POWER_LIMITATION_LOG_MASK 0x01
#define IA32_THERM_STATUS_POWER_LIMITATION_LOG(_) (((_) >> 11) & 0x01)
/**
* [Bit 12] Current Limit Status
*
* @remarks If CPUID.06H:EAX[7] = 1
*/
UINT64_t current_limit_status : 1;
#define IA32_THERM_STATUS_CURRENT_LIMIT_STATUS_BIT 12
#define IA32_THERM_STATUS_CURRENT_LIMIT_STATUS_FLAG 0x1000
#define IA32_THERM_STATUS_CURRENT_LIMIT_STATUS_MASK 0x01
#define IA32_THERM_STATUS_CURRENT_LIMIT_STATUS(_) (((_) >> 12) & 0x01)
/**
* [Bit 13] Current Limit log
*
* @remarks If CPUID.06H:EAX[7] = 1
*/
UINT64_t current_limit_log : 1;
#define IA32_THERM_STATUS_CURRENT_LIMIT_LOG_BIT 13
#define IA32_THERM_STATUS_CURRENT_LIMIT_LOG_FLAG 0x2000
#define IA32_THERM_STATUS_CURRENT_LIMIT_LOG_MASK 0x01
#define IA32_THERM_STATUS_CURRENT_LIMIT_LOG(_) (((_) >> 13) & 0x01)
/**
* [Bit 14] Cross Domain Limit Status
*
* @remarks If CPUID.06H:EAX[7] = 1
*/
UINT64_t cross_domain_limit_status : 1;
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_STATUS_BIT 14
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_STATUS_FLAG 0x4000
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_STATUS_MASK 0x01
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_STATUS(_) (((_) >> 14) & 0x01)
/**
* [Bit 15] Cross Domain Limit log
*
* @remarks If CPUID.06H:EAX[7] = 1
*/
UINT64_t cross_domain_limit_log : 1;
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_LOG_BIT 15
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_LOG_FLAG 0x8000
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_LOG_MASK 0x01
#define IA32_THERM_STATUS_CROSS_DOMAIN_LIMIT_LOG(_) (((_) >> 15) & 0x01)
/**
* [Bits 22:16] Digital Readout
*
* @remarks If CPUID.06H:EAX[0] = 1
*/
UINT64_t digital_readout : 7;
#define IA32_THERM_STATUS_DIGITAL_READOUT_BIT 16
#define IA32_THERM_STATUS_DIGITAL_READOUT_FLAG 0x7F0000
#define IA32_THERM_STATUS_DIGITAL_READOUT_MASK 0x7F
#define IA32_THERM_STATUS_DIGITAL_READOUT(_) (((_) >> 16) & 0x7F)
UINT64_t reserved1 : 4;
/**
* [Bits 30:27] Resolution in Degrees Celsius
*
* @remarks If CPUID.06H:EAX[0] = 1
*/
UINT64_t resolution_in_degrees_celsius : 4;
#define IA32_THERM_STATUS_RESOLUTION_IN_DEGREES_CELSIUS_BIT 27
#define IA32_THERM_STATUS_RESOLUTION_IN_DEGREES_CELSIUS_FLAG 0x78000000
#define IA32_THERM_STATUS_RESOLUTION_IN_DEGREES_CELSIUS_MASK 0x0F
#define IA32_THERM_STATUS_RESOLUTION_IN_DEGREES_CELSIUS(_) (((_) >> 27) & 0x0F)
/**
* [Bit 31] Reading Valid
*
* @remarks If CPUID.06H:EAX[0] = 1
*/
UINT64_t reading_valid : 1;
#define IA32_THERM_STATUS_READING_VALID_BIT 31
#define IA32_THERM_STATUS_READING_VALID_FLAG 0x80000000
#define IA32_THERM_STATUS_READING_VALID_MASK 0x01
#define IA32_THERM_STATUS_READING_VALID(_) (((_) >> 31) & 0x01)
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} ia32_therm_status_register;
/**
* @brief Enable Misc. Processor Features <b>(R/W)</b>
*
* Allows a variety of processor functions to be enabled and disabled.
*/
#define IA32_MISC_ENABLE 0x000001A0
typedef union
{
struct
{
/**
* @brief Fast-Strings Enable
*
* [Bit 0] When set, the fast-strings feature (for REP MOVS and REP STORS) is enabled (default). When clear, fast-strings
* are disabled.
*
* @remarks 0F_0H
*/
UINT64_t fast_strings_enable : 1;
#define IA32_MISC_ENABLE_FAST_STRINGS_ENABLE_BIT 0
#define IA32_MISC_ENABLE_FAST_STRINGS_ENABLE_FLAG 0x01
#define IA32_MISC_ENABLE_FAST_STRINGS_ENABLE_MASK 0x01
#define IA32_MISC_ENABLE_FAST_STRINGS_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 2;
/**
* @brief Automatic Thermal Control Circuit Enable <b>(R/W)</b>
*
* [Bit 3] - 1 = Setting this bit enables the thermal control circuit (TCC) portion of the Intel Thermal Monitor feature.
* This allows the processor to automatically reduce power consumption in response to TCC activation.
* - 0 = Disabled.
*
* @note In some products clearing this bit might be ignored in critical thermal conditions, and TM1, TM2 and adaptive
* thermal throttling will still be activated. The default value of this field varies with product.
* @remarks 0F_0H
*/
UINT64_t automatic_thermal_control_circuit_enable : 1;
#define IA32_MISC_ENABLE_AUTOMATIC_THERMAL_CONTROL_CIRCUIT_ENABLE_BIT 3
#define IA32_MISC_ENABLE_AUTOMATIC_THERMAL_CONTROL_CIRCUIT_ENABLE_FLAG 0x08
#define IA32_MISC_ENABLE_AUTOMATIC_THERMAL_CONTROL_CIRCUIT_ENABLE_MASK 0x01
#define IA32_MISC_ENABLE_AUTOMATIC_THERMAL_CONTROL_CIRCUIT_ENABLE(_) (((_) >> 3) & 0x01)
UINT64_t reserved2 : 3;
/**
* @brief Performance Monitoring Available <b>(R)</b>
*
* [Bit 7] - 1 = Performance monitoring enabled.
* - 0 = Performance monitoring disabled.
*
* @remarks 0F_0H
*/
UINT64_t performance_monitoring_available : 1;
#define IA32_MISC_ENABLE_PERFORMANCE_MONITORING_AVAILABLE_BIT 7
#define IA32_MISC_ENABLE_PERFORMANCE_MONITORING_AVAILABLE_FLAG 0x80
#define IA32_MISC_ENABLE_PERFORMANCE_MONITORING_AVAILABLE_MASK 0x01
#define IA32_MISC_ENABLE_PERFORMANCE_MONITORING_AVAILABLE(_) (((_) >> 7) & 0x01)
UINT64_t reserved3 : 3;
/**
* @brief Branch Trace Storage Unavailable <b>(RO)</b>
*
* [Bit 11] - 1 = Processor doesn't support branch trace storage (BTS).
* - 0 = BTS is supported.
*
* @remarks 0F_0H
*/
UINT64_t branch_trace_storage_unavailable : 1;
#define IA32_MISC_ENABLE_BRANCH_TRACE_STORAGE_UNAVAILABLE_BIT 11
#define IA32_MISC_ENABLE_BRANCH_TRACE_STORAGE_UNAVAILABLE_FLAG 0x800
#define IA32_MISC_ENABLE_BRANCH_TRACE_STORAGE_UNAVAILABLE_MASK 0x01
#define IA32_MISC_ENABLE_BRANCH_TRACE_STORAGE_UNAVAILABLE(_) (((_) >> 11) & 0x01)
/**
* @brief Processor Event Based Sampling (PEBS) Unavailable <b>(RO)</b>
*
* [Bit 12] - 1 = PEBS is not supported.
* - 0 = PEBS is supported.
*
* @remarks 06_0FH
*/
UINT64_t processor_event_based_sampling_unavailable : 1;
#define IA32_MISC_ENABLE_PROCESSOR_EVENT_BASED_SAMPLING_UNAVAILABLE_BIT 12
#define IA32_MISC_ENABLE_PROCESSOR_EVENT_BASED_SAMPLING_UNAVAILABLE_FLAG 0x1000
#define IA32_MISC_ENABLE_PROCESSOR_EVENT_BASED_SAMPLING_UNAVAILABLE_MASK 0x01
#define IA32_MISC_ENABLE_PROCESSOR_EVENT_BASED_SAMPLING_UNAVAILABLE(_) (((_) >> 12) & 0x01)
UINT64_t reserved4 : 3;
/**
* @brief Enhanced Intel SpeedStep Technology Enable <b>(R/W)</b>
*
* [Bit 16] - 0 = Enhanced Intel SpeedStep Technology disabled.
* - 1 = Enhanced Intel SpeedStep Technology enabled.
*
* @remarks If CPUID.01H: ECX[7] = 1
*/
UINT64_t enhanced_intel_speedstep_technology_enable : 1;
#define IA32_MISC_ENABLE_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_ENABLE_BIT 16
#define IA32_MISC_ENABLE_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_ENABLE_FLAG 0x10000
#define IA32_MISC_ENABLE_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_ENABLE_MASK 0x01
#define IA32_MISC_ENABLE_ENHANCED_INTEL_SPEEDSTEP_TECHNOLOGY_ENABLE(_) (((_) >> 16) & 0x01)
UINT64_t reserved5 : 1;
/**
* @brief ENABLE MONITOR FSM <b>(R/W)</b>
*
* [Bit 18] When this bit is set to 0, the MONITOR feature flag is not set (CPUID.01H:ECX[bit3] = 0). This indicates that
* MONITOR/MWAIT are not supported. Software attempts to execute MONITOR/MWAIT will cause \#UD when this bit is 0.
* When this bit is set to 1 (default), MONITOR/MWAIT are supported (CPUID.01H:ECX[bit 3] = 1). If the SSE3 feature flag
* ECX[0] is not set (CPUID.01H:ECX[bit 0] = 0), the OS must not attempt to alter this bit. BIOS must leave it in the
* default state. Writing this bit when the SSE3 feature flag is set to 0 may generate a \#GP exception.
*
* @remarks 0F_03H
*/
UINT64_t enable_monitor_fsm : 1;
#define IA32_MISC_ENABLE_ENABLE_MONITOR_FSM_BIT 18
#define IA32_MISC_ENABLE_ENABLE_MONITOR_FSM_FLAG 0x40000
#define IA32_MISC_ENABLE_ENABLE_MONITOR_FSM_MASK 0x01
#define IA32_MISC_ENABLE_ENABLE_MONITOR_FSM(_) (((_) >> 18) & 0x01)
UINT64_t reserved6 : 3;
/**
* @brief Limit CPUID Maxval <b>(R/W)</b>
*
* [Bit 22] When this bit is set to 1, CPUID.00H returns a maximum value in EAX[7:0] of 2. BIOS should contain a setup
* question that allows users to specify when the installed OS does not support CPUID functions greater than 2.
* Before setting this bit, BIOS must execute the CPUID.0H and examine the maximum value returned in EAX[7:0]. If the
* maximum value is greater than 2, this bit is supported.
* Otherwise, this bit is not supported. Setting this bit when the maximum value is not greater than 2 may generate a \#GP
* exception. Setting this bit may cause unexpected behavior in software that depends on the availability of CPUID leaves
* greater than 2.
*
* @remarks 0F_03H
*/
UINT64_t limit_cpuid_maxval : 1;
#define IA32_MISC_ENABLE_LIMIT_CPUID_MAXVAL_BIT 22
#define IA32_MISC_ENABLE_LIMIT_CPUID_MAXVAL_FLAG 0x400000
#define IA32_MISC_ENABLE_LIMIT_CPUID_MAXVAL_MASK 0x01
#define IA32_MISC_ENABLE_LIMIT_CPUID_MAXVAL(_) (((_) >> 22) & 0x01)
/**
* @brief xTPR Message Disable <b>(R/W)</b>
*
* [Bit 23] When set to 1, xTPR messages are disabled. xTPR messages are optional messages that allow the processor to
* inform the chipset of its priority.
*
* @remarks If CPUID.01H:ECX[14] = 1
*/
UINT64_t xtpr_message_disable : 1;
#define IA32_MISC_ENABLE_XTPR_MESSAGE_DISABLE_BIT 23
#define IA32_MISC_ENABLE_XTPR_MESSAGE_DISABLE_FLAG 0x800000
#define IA32_MISC_ENABLE_XTPR_MESSAGE_DISABLE_MASK 0x01
#define IA32_MISC_ENABLE_XTPR_MESSAGE_DISABLE(_) (((_) >> 23) & 0x01)
UINT64_t reserved7 : 10;
/**
* @brief XD Bit Disable <b>(R/W)</b>
*
* [Bit 34] When set to 1, the Execute Disable Bit feature (XD Bit) is disabled and the XD Bit extended feature flag will
* be clear (CPUID.80000001H: EDX[20]=0).
* When set to a 0 (default), the Execute Disable Bit feature (if available) allows the OS to enable PAE paging and take
* advantage of data only pages.
* BIOS must not alter the contents of this bit location, if XD bit is not supported. Writing this bit to 1 when the XD Bit
* extended feature flag is set to 0 may generate a \#GP exception.
*
* @remarks If CPUID.80000001H:EDX[20] = 1
*/
UINT64_t xd_bit_disable : 1;
#define IA32_MISC_ENABLE_XD_BIT_DISABLE_BIT 34
#define IA32_MISC_ENABLE_XD_BIT_DISABLE_FLAG 0x400000000
#define IA32_MISC_ENABLE_XD_BIT_DISABLE_MASK 0x01
#define IA32_MISC_ENABLE_XD_BIT_DISABLE(_) (((_) >> 34) & 0x01)
UINT64_t reserved8 : 29;
};
UINT64_t flags;
} ia32_misc_enable_register;
/**
* Performance Energy Bias Hint.
*
* @remarks If CPUID.6H:ECX[3] = 1
*/
#define IA32_ENERGY_PERF_BIAS 0x000001B0
typedef union
{
struct
{
/**
* @brief Power Policy Preference
*
* [Bits 3:0] - 0 indicates preference to highest performance.
* - 15 indicates preference to maximize energy saving.
*/
UINT64_t power_policy_preference : 4;
#define IA32_ENERGY_PERF_BIAS_POWER_POLICY_PREFERENCE_BIT 0
#define IA32_ENERGY_PERF_BIAS_POWER_POLICY_PREFERENCE_FLAG 0x0F
#define IA32_ENERGY_PERF_BIAS_POWER_POLICY_PREFERENCE_MASK 0x0F
#define IA32_ENERGY_PERF_BIAS_POWER_POLICY_PREFERENCE(_) (((_) >> 0) & 0x0F)
UINT64_t reserved1 : 60;
};
UINT64_t flags;
} ia32_energy_perf_bias_register;
/**
* @brief Package Thermal Status Information <b>(RO)</b>
*
* Package Thermal Status Information. Contains status information about the package's thermal sensor.
*
* @remarks If CPUID.06H: EAX[6] = 1
* @see Vol3B[14.8(PACKAGE LEVEL THERMAL MANAGEMENT)]
*/
#define IA32_PACKAGE_THERM_STATUS 0x000001B1
typedef union
{
struct
{
/**
* [Bit 0] Pkg Thermal Status
*/
UINT64_t thermal_status : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_BIT 0
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_FLAG 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Pkg Thermal Status Log
*/
UINT64_t thermal_status_log : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_LOG_BIT 1
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_LOG_FLAG 0x02
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_STATUS_LOG(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Pkg PROCHOT \# event
*/
UINT64_t prochot_event : 1;
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_EVENT_BIT 2
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_EVENT_FLAG 0x04
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_EVENT_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_EVENT(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Pkg PROCHOT \# log
*/
UINT64_t prochot_log : 1;
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_LOG_BIT 3
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_LOG_FLAG 0x08
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_PROCHOT_LOG(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Pkg Critical Temperature Status
*/
UINT64_t critical_temperature_status : 1;
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_BIT 4
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_FLAG 0x10
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Pkg Critical Temperature Status Log
*/
UINT64_t critical_temperature_status_log : 1;
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_BIT 5
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_FLAG 0x20
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_CRITICAL_TEMPERATURE_STATUS_LOG(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Pkg Thermal Threshold \#1 Status
*/
UINT64_t thermal_threshold1_status : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_BIT 6
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_FLAG 0x40
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_STATUS_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_STATUS(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Pkg Thermal Threshold \#1 log
*/
UINT64_t thermal_threshold1_log : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_LOG_BIT 7
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_LOG_FLAG 0x80
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD1_LOG(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Pkg Thermal Threshold \#2 Status
*/
UINT64_t thermal_threshold2_status : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_BIT 8
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_FLAG 0x100
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_STATUS_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_STATUS(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] Pkg Thermal Threshold \#2 log
*/
UINT64_t thermal_threshold2_log : 1;
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_LOG_BIT 9
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_LOG_FLAG 0x200
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_THERMAL_THRESHOLD2_LOG(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Pkg Power Limitation Status
*/
UINT64_t power_limitation_status : 1;
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_STATUS_BIT 10
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_STATUS_FLAG 0x400
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_STATUS_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_STATUS(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] Pkg Power Limitation log
*/
UINT64_t power_limitation_log : 1;
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_LOG_BIT 11
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_LOG_FLAG 0x800
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_LOG_MASK 0x01
#define IA32_PACKAGE_THERM_STATUS_POWER_LIMITATION_LOG(_) (((_) >> 11) & 0x01)
UINT64_t reserved1 : 4;
/**
* [Bits 22:16] Pkg Digital Readout
*/
UINT64_t digital_readout : 7;
#define IA32_PACKAGE_THERM_STATUS_DIGITAL_READOUT_BIT 16
#define IA32_PACKAGE_THERM_STATUS_DIGITAL_READOUT_FLAG 0x7F0000
#define IA32_PACKAGE_THERM_STATUS_DIGITAL_READOUT_MASK 0x7F
#define IA32_PACKAGE_THERM_STATUS_DIGITAL_READOUT(_) (((_) >> 16) & 0x7F)
UINT64_t reserved2 : 41;
};
UINT64_t flags;
} ia32_package_therm_status_register;
/**
* @brief Package Thermal Interrupt Control <b>(RO)</b>
*
* Enables and disables the generation of an interrupt on temperature transitions detected with the package's thermal
* sensor.
*
* @remarks If CPUID.06H: EAX[6] = 1
* @see Vol3B[14.8(PACKAGE LEVEL THERMAL MANAGEMENT)]
*/
#define IA32_PACKAGE_THERM_INTERRUPT 0x000001B2
typedef union
{
struct
{
/**
* [Bit 0] Pkg High-Temperature Interrupt Enable.
*/
UINT64_t high_temperature_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_BIT 0
#define IA32_PACKAGE_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_FLAG 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_HIGH_TEMPERATURE_INTERRUPT_ENABLE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Pkg Low-Temperature Interrupt Enable.
*/
UINT64_t low_temperature_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_BIT 1
#define IA32_PACKAGE_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_FLAG 0x02
#define IA32_PACKAGE_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_LOW_TEMPERATURE_INTERRUPT_ENABLE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Pkg PROCHOT\# Interrupt Enable.
*/
UINT64_t prochot_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_BIT 2
#define IA32_PACKAGE_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_FLAG 0x04
#define IA32_PACKAGE_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_PROCHOT_INTERRUPT_ENABLE(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 4] Pkg Overheat Interrupt Enable.
*/
UINT64_t overheat_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_OVERHEAT_INTERRUPT_ENABLE_BIT 4
#define IA32_PACKAGE_THERM_INTERRUPT_OVERHEAT_INTERRUPT_ENABLE_FLAG 0x10
#define IA32_PACKAGE_THERM_INTERRUPT_OVERHEAT_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_OVERHEAT_INTERRUPT_ENABLE(_) (((_) >> 4) & 0x01)
UINT64_t reserved2 : 3;
/**
* [Bits 14:8] Pkg Threshold \#1 Value
*/
UINT64_t threshold1_value : 7;
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_VALUE_BIT 8
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_VALUE_FLAG 0x7F00
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_VALUE_MASK 0x7F
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_VALUE(_) (((_) >> 8) & 0x7F)
/**
* [Bit 15] Pkg Threshold \#1 Interrupt Enable.
*/
UINT64_t threshold1_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_BIT 15
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_FLAG 0x8000
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD1_INTERRUPT_ENABLE(_) (((_) >> 15) & 0x01)
/**
* [Bits 22:16] Pkg Threshold \#2 Value.
*/
UINT64_t threshold2_value : 7;
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_VALUE_BIT 16
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_VALUE_FLAG 0x7F0000
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_VALUE_MASK 0x7F
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_VALUE(_) (((_) >> 16) & 0x7F)
/**
* [Bit 23] Pkg Threshold \#2 Interrupt Enable.
*/
UINT64_t threshold2_interrupt_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_BIT 23
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_FLAG 0x800000
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_THRESHOLD2_INTERRUPT_ENABLE(_) (((_) >> 23) & 0x01)
/**
* [Bit 24] Pkg Power Limit Notification Enable.
*/
UINT64_t power_limit_notification_enable : 1;
#define IA32_PACKAGE_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_BIT 24
#define IA32_PACKAGE_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_FLAG 0x1000000
#define IA32_PACKAGE_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE_MASK 0x01
#define IA32_PACKAGE_THERM_INTERRUPT_POWER_LIMIT_NOTIFICATION_ENABLE(_) (((_) >> 24) & 0x01)
UINT64_t reserved3 : 39;
};
UINT64_t flags;
} ia32_package_therm_interrupt_register;
/**
* Trace/Profile Resource Control.
*
* @remarks 06_0EH
*/
#define IA32_DEBUGCTL 0x000001D9
typedef union
{
struct
{
/**
* [Bit 0] Setting this bit to 1 enables the processor to record a running trace of the most recent branches taken by the
* processor in the LBR stack.
*
* @remarks 06_01H
*/
UINT64_t lbr : 1;
#define IA32_DEBUGCTL_LBR_BIT 0
#define IA32_DEBUGCTL_LBR_FLAG 0x01
#define IA32_DEBUGCTL_LBR_MASK 0x01
#define IA32_DEBUGCTL_LBR(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Setting this bit to 1 enables the processor to treat EFLAGS.TF as single-step on branches instead of single-step
* on instructions.
*
* @remarks 06_01H
*/
UINT64_t btf : 1;
#define IA32_DEBUGCTL_BTF_BIT 1
#define IA32_DEBUGCTL_BTF_FLAG 0x02
#define IA32_DEBUGCTL_BTF_MASK 0x01
#define IA32_DEBUGCTL_BTF(_) (((_) >> 1) & 0x01)
UINT64_t reserved1 : 4;
/**
* [Bit 6] Setting this bit to 1 enables branch trace messages to be sent.
*
* @remarks 06_0EH
*/
UINT64_t tr : 1;
#define IA32_DEBUGCTL_TR_BIT 6
#define IA32_DEBUGCTL_TR_FLAG 0x40
#define IA32_DEBUGCTL_TR_MASK 0x01
#define IA32_DEBUGCTL_TR(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Setting this bit enables branch trace messages (BTMs) to be logged in a BTS buffer.
*
* @remarks 06_0EH
*/
UINT64_t bts : 1;
#define IA32_DEBUGCTL_BTS_BIT 7
#define IA32_DEBUGCTL_BTS_FLAG 0x80
#define IA32_DEBUGCTL_BTS_MASK 0x01
#define IA32_DEBUGCTL_BTS(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] When clear, BTMs are logged in a BTS buffer in circular fashion. When this bit is set, an interrupt is generated
* by the BTS facility when the BTS buffer is full.
*
* @remarks 06_0EH
*/
UINT64_t btint : 1;
#define IA32_DEBUGCTL_BTINT_BIT 8
#define IA32_DEBUGCTL_BTINT_FLAG 0x100
#define IA32_DEBUGCTL_BTINT_MASK 0x01
#define IA32_DEBUGCTL_BTINT(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] When set, BTS or BTM is skipped if CPL = 0.
*
* @remarks 06_0FH
*/
UINT64_t bts_off_os : 1;
#define IA32_DEBUGCTL_BTS_OFF_OS_BIT 9
#define IA32_DEBUGCTL_BTS_OFF_OS_FLAG 0x200
#define IA32_DEBUGCTL_BTS_OFF_OS_MASK 0x01
#define IA32_DEBUGCTL_BTS_OFF_OS(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] When set, BTS or BTM is skipped if CPL > 0.
*
* @remarks 06_0FH
*/
UINT64_t bts_off_usr : 1;
#define IA32_DEBUGCTL_BTS_OFF_USR_BIT 10
#define IA32_DEBUGCTL_BTS_OFF_USR_FLAG 0x400
#define IA32_DEBUGCTL_BTS_OFF_USR_MASK 0x01
#define IA32_DEBUGCTL_BTS_OFF_USR(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] When set, the LBR stack is frozen on a PMI request.
*
* @remarks If CPUID.01H: ECX[15] = 1 && CPUID.0AH: EAX[7:0] > 1
*/
UINT64_t freeze_lbrs_on_pmi : 1;
#define IA32_DEBUGCTL_FREEZE_LBRS_ON_PMI_BIT 11
#define IA32_DEBUGCTL_FREEZE_LBRS_ON_PMI_FLAG 0x800
#define IA32_DEBUGCTL_FREEZE_LBRS_ON_PMI_MASK 0x01
#define IA32_DEBUGCTL_FREEZE_LBRS_ON_PMI(_) (((_) >> 11) & 0x01)
/**
* [Bit 12] When set, each ENABLE bit of the global counter control MSR are frozen (address 38FH) on a PMI request.
*
* @remarks If CPUID.01H: ECX[15] = 1 && CPUID.0AH: EAX[7:0] > 1
*/
UINT64_t freeze_perfmon_on_pmi : 1;
#define IA32_DEBUGCTL_FREEZE_PERFMON_ON_PMI_BIT 12
#define IA32_DEBUGCTL_FREEZE_PERFMON_ON_PMI_FLAG 0x1000
#define IA32_DEBUGCTL_FREEZE_PERFMON_ON_PMI_MASK 0x01
#define IA32_DEBUGCTL_FREEZE_PERFMON_ON_PMI(_) (((_) >> 12) & 0x01)
/**
* [Bit 13] When set, enables the logical processor to receive and generate PMI on behalf of the uncore.
*
* @remarks 06_1AH
*/
UINT64_t enable_uncore_pmi : 1;
#define IA32_DEBUGCTL_ENABLE_UNCORE_PMI_BIT 13
#define IA32_DEBUGCTL_ENABLE_UNCORE_PMI_FLAG 0x2000
#define IA32_DEBUGCTL_ENABLE_UNCORE_PMI_MASK 0x01
#define IA32_DEBUGCTL_ENABLE_UNCORE_PMI(_) (((_) >> 13) & 0x01)
/**
* [Bit 14] When set, freezes perfmon and trace messages while in SMM.
*
* @remarks If IA32_PERF_CAPABILITIES[12] = 1
*/
UINT64_t freeze_while_smm : 1;
#define IA32_DEBUGCTL_FREEZE_WHILE_SMM_BIT 14
#define IA32_DEBUGCTL_FREEZE_WHILE_SMM_FLAG 0x4000
#define IA32_DEBUGCTL_FREEZE_WHILE_SMM_MASK 0x01
#define IA32_DEBUGCTL_FREEZE_WHILE_SMM(_) (((_) >> 14) & 0x01)
/**
* [Bit 15] When set, enables DR7 debug bit on XBEGIN.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[11] = 1)
*/
UINT64_t rtm_debug : 1;
#define IA32_DEBUGCTL_RTM_DEBUG_BIT 15
#define IA32_DEBUGCTL_RTM_DEBUG_FLAG 0x8000
#define IA32_DEBUGCTL_RTM_DEBUG_MASK 0x01
#define IA32_DEBUGCTL_RTM_DEBUG(_) (((_) >> 15) & 0x01)
UINT64_t reserved2 : 48;
};
UINT64_t flags;
} ia32_debugctl_register;
/**
* @brief SMRR Base Address <b>(Writeable only in SMM)</b>
*
* SMRR Base Address. Base address of SMM memory range.
*
* @remarks If IA32_MTRRCAP.SMRR[11] = 1
*/
#define IA32_SMRR_PHYSBASE 0x000001F2
typedef union
{
struct
{
/**
* @brief Type
*
* [Bits 7:0] Type. Specifies memory type of the range.
*/
UINT64_t type : 8;
#define IA32_SMRR_PHYSBASE_TYPE_BIT 0
#define IA32_SMRR_PHYSBASE_TYPE_FLAG 0xFF
#define IA32_SMRR_PHYSBASE_TYPE_MASK 0xFF
#define IA32_SMRR_PHYSBASE_TYPE(_) (((_) >> 0) & 0xFF)
UINT64_t reserved1 : 4;
/**
* [Bits 31:12] SMRR physical Base Address.
*/
UINT64_t smrr_physical_base_address : 20;
#define IA32_SMRR_PHYSBASE_SMRR_PHYSICAL_BASE_ADDRESS_BIT 12
#define IA32_SMRR_PHYSBASE_SMRR_PHYSICAL_BASE_ADDRESS_FLAG 0xFFFFF000
#define IA32_SMRR_PHYSBASE_SMRR_PHYSICAL_BASE_ADDRESS_MASK 0xFFFFF
#define IA32_SMRR_PHYSBASE_SMRR_PHYSICAL_BASE_ADDRESS(_) (((_) >> 12) & 0xFFFFF)
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} ia32_smrr_physbase_register;
/**
* @brief SMRR Range Mask <b>(Writeable only in SMM)</b>
*
* Range Mask of SMM memory range.
*
* @remarks If IA32_MTRRCAP[SMRR] = 1
*/
#define IA32_SMRR_PHYSMASK 0x000001F3
typedef union
{
struct
{
UINT64_t reserved1 : 11;
/**
* [Bit 11] Enable range mask.
*/
UINT64_t enable_range_mask : 1;
#define IA32_SMRR_PHYSMASK_ENABLE_RANGE_MASK_BIT 11
#define IA32_SMRR_PHYSMASK_ENABLE_RANGE_MASK_FLAG 0x800
#define IA32_SMRR_PHYSMASK_ENABLE_RANGE_MASK_MASK 0x01
#define IA32_SMRR_PHYSMASK_ENABLE_RANGE_MASK(_) (((_) >> 11) & 0x01)
/**
* [Bits 31:12] SMRR address range mask.
*/
UINT64_t smrr_address_range_mask : 20;
#define IA32_SMRR_PHYSMASK_SMRR_ADDRESS_RANGE_MASK_BIT 12
#define IA32_SMRR_PHYSMASK_SMRR_ADDRESS_RANGE_MASK_FLAG 0xFFFFF000
#define IA32_SMRR_PHYSMASK_SMRR_ADDRESS_RANGE_MASK_MASK 0xFFFFF
#define IA32_SMRR_PHYSMASK_SMRR_ADDRESS_RANGE_MASK(_) (((_) >> 12) & 0xFFFFF)
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} ia32_smrr_physmask_register;
/**
* DCA Capability.
*
* @remarks If CPUID.01H: ECX[18] = 1
*/
#define IA32_PLATFORM_DCA_CAP 0x000001F8
/**
* If set, CPU supports Prefetch-Hint type.
*
* @remarks If CPUID.01H: ECX[18] = 1
*/
#define IA32_CPU_DCA_CAP 0x000001F9
/**
* DCA type 0 Status and Control register.
*
* @remarks If CPUID.01H: ECX[18] = 1
*/
#define IA32_DCA_0_CAP 0x000001FA
typedef union
{
struct
{
/**
* [Bit 0] Set by HW when DCA is fuseenabled and no defeatures are set.
*/
UINT64_t dca_active : 1;
#define IA32_DCA_0_CAP_DCA_ACTIVE_BIT 0
#define IA32_DCA_0_CAP_DCA_ACTIVE_FLAG 0x01
#define IA32_DCA_0_CAP_DCA_ACTIVE_MASK 0x01
#define IA32_DCA_0_CAP_DCA_ACTIVE(_) (((_) >> 0) & 0x01)
/**
* [Bits 2:1] TRANSACTION.
*/
UINT64_t transaction : 2;
#define IA32_DCA_0_CAP_TRANSACTION_BIT 1
#define IA32_DCA_0_CAP_TRANSACTION_FLAG 0x06
#define IA32_DCA_0_CAP_TRANSACTION_MASK 0x03
#define IA32_DCA_0_CAP_TRANSACTION(_) (((_) >> 1) & 0x03)
/**
* [Bits 6:3] DCA_TYPE.
*/
UINT64_t dca_type : 4;
#define IA32_DCA_0_CAP_DCA_TYPE_BIT 3
#define IA32_DCA_0_CAP_DCA_TYPE_FLAG 0x78
#define IA32_DCA_0_CAP_DCA_TYPE_MASK 0x0F
#define IA32_DCA_0_CAP_DCA_TYPE(_) (((_) >> 3) & 0x0F)
/**
* [Bits 10:7] DCA_QUEUE_SIZE.
*/
UINT64_t dca_queue_size : 4;
#define IA32_DCA_0_CAP_DCA_QUEUE_SIZE_BIT 7
#define IA32_DCA_0_CAP_DCA_QUEUE_SIZE_FLAG 0x780
#define IA32_DCA_0_CAP_DCA_QUEUE_SIZE_MASK 0x0F
#define IA32_DCA_0_CAP_DCA_QUEUE_SIZE(_) (((_) >> 7) & 0x0F)
UINT64_t reserved1 : 2;
/**
* [Bits 16:13] Writes will update the register but have no HW side-effect.
*/
UINT64_t dca_delay : 4;
#define IA32_DCA_0_CAP_DCA_DELAY_BIT 13
#define IA32_DCA_0_CAP_DCA_DELAY_FLAG 0x1E000
#define IA32_DCA_0_CAP_DCA_DELAY_MASK 0x0F
#define IA32_DCA_0_CAP_DCA_DELAY(_) (((_) >> 13) & 0x0F)
UINT64_t reserved2 : 7;
/**
* [Bit 24] SW can request DCA block by setting this bit.
*/
UINT64_t sw_block : 1;
#define IA32_DCA_0_CAP_SW_BLOCK_BIT 24
#define IA32_DCA_0_CAP_SW_BLOCK_FLAG 0x1000000
#define IA32_DCA_0_CAP_SW_BLOCK_MASK 0x01
#define IA32_DCA_0_CAP_SW_BLOCK(_) (((_) >> 24) & 0x01)
UINT64_t reserved3 : 1;
/**
* [Bit 26] Set when DCA is blocked by HW (e.g. CR0.CD = 1).
*/
UINT64_t hw_block : 1;
#define IA32_DCA_0_CAP_HW_BLOCK_BIT 26
#define IA32_DCA_0_CAP_HW_BLOCK_FLAG 0x4000000
#define IA32_DCA_0_CAP_HW_BLOCK_MASK 0x01
#define IA32_DCA_0_CAP_HW_BLOCK(_) (((_) >> 26) & 0x01)
UINT64_t reserved4 : 37;
};
UINT64_t flags;
} ia32_dca_0_cap_register;
/**
* @defgroup ia32_mtrr_physbase \
* IA32_MTRR_PHYSBASE(n)
*
* IA32_MTRR_PHYSBASE(0-9).
*
* @remarks If CPUID.01H: EDX.MTRR[12] = 1
* @see Vol3A[11.11.2.3(Variable Range MTRRs)]
* @{
*/
typedef union
{
struct
{
/**
* [Bits 7:0] Specifies the memory type for the range.
*/
UINT64_t type : 8;
#define IA32_MTRR_PHYSBASE_TYPE_BIT 0
#define IA32_MTRR_PHYSBASE_TYPE_FLAG 0xFF
#define IA32_MTRR_PHYSBASE_TYPE_MASK 0xFF
#define IA32_MTRR_PHYSBASE_TYPE(_) (((_) >> 0) & 0xFF)
UINT64_t reserved1 : 4;
/**
* [Bits 47:12] Specifies the base address of the address range. This 24-bit value, in the case where MAXPHYADDR is 36
* bits, is extended by 12 bits at the low end to form the base address (this automatically aligns the address on a 4-KByte
* boundary).
*/
UINT64_t page_frame_number : 36;
#define IA32_MTRR_PHYSBASE_PAGE_FRAME_NUMBER_BIT 12
#define IA32_MTRR_PHYSBASE_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define IA32_MTRR_PHYSBASE_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define IA32_MTRR_PHYSBASE_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 16;
};
UINT64_t flags;
} ia32_mtrr_physbase_register;
#define IA32_MTRR_PHYSBASE0 0x00000200
#define IA32_MTRR_PHYSBASE1 0x00000202
#define IA32_MTRR_PHYSBASE2 0x00000204
#define IA32_MTRR_PHYSBASE3 0x00000206
#define IA32_MTRR_PHYSBASE4 0x00000208
#define IA32_MTRR_PHYSBASE5 0x0000020A
#define IA32_MTRR_PHYSBASE6 0x0000020C
#define IA32_MTRR_PHYSBASE7 0x0000020E
#define IA32_MTRR_PHYSBASE8 0x00000210
#define IA32_MTRR_PHYSBASE9 0x00000212
/**
* @}
*/
/**
* @defgroup ia32_mtrr_physmask \
* IA32_MTRR_PHYSMASK(n)
*
* IA32_MTRR_PHYSMASK(0-9).
*
* @remarks If CPUID.01H: EDX.MTRR[12] = 1
* @see Vol3A[11.11.2.3(Variable Range MTRRs)]
* @{
*/
typedef union
{
struct
{
/**
* [Bits 7:0] Specifies the memory type for the range.
*/
UINT64_t type : 8;
#define IA32_MTRR_PHYSMASK_TYPE_BIT 0
#define IA32_MTRR_PHYSMASK_TYPE_FLAG 0xFF
#define IA32_MTRR_PHYSMASK_TYPE_MASK 0xFF
#define IA32_MTRR_PHYSMASK_TYPE(_) (((_) >> 0) & 0xFF)
UINT64_t reserved1 : 3;
/**
* [Bit 11] Enables the register pair when set; disables register pair when clear.
*/
UINT64_t valid : 1;
#define IA32_MTRR_PHYSMASK_VALID_BIT 11
#define IA32_MTRR_PHYSMASK_VALID_FLAG 0x800
#define IA32_MTRR_PHYSMASK_VALID_MASK 0x01
#define IA32_MTRR_PHYSMASK_VALID(_) (((_) >> 11) & 0x01)
/**
* [Bits 47:12] Specifies a mask (24 bits if the maximum physical address size is 36 bits, 28 bits if the maximum physical
* address size is 40 bits). The mask determines the range of the region being mapped, according to the following
* relationships:
* - Address_Within_Range AND PhysMask = PhysBase AND PhysMask
* - This value is extended by 12 bits at the low end to form the mask value.
* - The width of the PhysMask field depends on the maximum physical address size supported by the processor.
* CPUID.80000008H reports the maximum physical address size supported by the processor. If CPUID.80000008H is not
* available, software may assume that the processor supports a 36-bit physical address size.
*
* @see Vol3A[11.11.3(Example Base and Mask Calculations)]
*/
UINT64_t page_frame_number : 36;
#define IA32_MTRR_PHYSMASK_PAGE_FRAME_NUMBER_BIT 12
#define IA32_MTRR_PHYSMASK_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define IA32_MTRR_PHYSMASK_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define IA32_MTRR_PHYSMASK_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 16;
};
UINT64_t flags;
} ia32_mtrr_physmask_register;
#define IA32_MTRR_PHYSMASK0 0x00000201
#define IA32_MTRR_PHYSMASK1 0x00000203
#define IA32_MTRR_PHYSMASK2 0x00000205
#define IA32_MTRR_PHYSMASK3 0x00000207
#define IA32_MTRR_PHYSMASK4 0x00000209
#define IA32_MTRR_PHYSMASK5 0x0000020B
#define IA32_MTRR_PHYSMASK6 0x0000020D
#define IA32_MTRR_PHYSMASK7 0x0000020F
#define IA32_MTRR_PHYSMASK8 0x00000211
#define IA32_MTRR_PHYSMASK9 0x00000213
/**
* @}
*/
/**
* @defgroup ia32_mtrr_fix \
* IA32_MTRR_FIX(x)
*
* IA32_MTRR_FIX(x).
*
* @remarks If CPUID.01H: EDX.MTRR[12] = 1
* @see Vol3A[11.11.2.2(Fixed Range MTRRs)]
* @{
*/
/**
* @defgroup ia32_mtrr_fix64k \
* IA32_MTRR_FIX64K(x)
*
* IA32_MTRR_FIX64K(x).
* @{
*/
#define IA32_MTRR_FIX64K_BASE 0x00000000
#define IA32_MTRR_FIX64K_SIZE 0x00010000
#define IA32_MTRR_FIX64K_00000 0x00000250
/**
* @}
*/
/**
* @defgroup ia32_mtrr_fix16k \
* IA32_MTRR_FIX16K(x)
*
* IA32_MTRR_FIX16K(x).
* @{
*/
#define IA32_MTRR_FIX16K_BASE 0x00080000
#define IA32_MTRR_FIX16K_SIZE 0x00004000
#define IA32_MTRR_FIX16K_80000 0x00000258
#define IA32_MTRR_FIX16K_A0000 0x00000259
/**
* @}
*/
/**
* @defgroup ia32_mtrr_fix4k \
* IA32_MTRR_FIX4K(x)
*
* IA32_MTRR_FIX4K(x).
* @{
*/
#define IA32_MTRR_FIX4K_BASE 0x000C0000
#define IA32_MTRR_FIX4K_SIZE 0x00001000
#define IA32_MTRR_FIX4K_C0000 0x00000268
#define IA32_MTRR_FIX4K_C8000 0x00000269
#define IA32_MTRR_FIX4K_D0000 0x0000026A
#define IA32_MTRR_FIX4K_D8000 0x0000026B
#define IA32_MTRR_FIX4K_E0000 0x0000026C
#define IA32_MTRR_FIX4K_E8000 0x0000026D
#define IA32_MTRR_FIX4K_F0000 0x0000026E
#define IA32_MTRR_FIX4K_F8000 0x0000026F
/**
* @}
*/
/**
* Architecture defined number of fixed range MTRRs (1 for 64k, 2 for 16k, 8 for 4k).
*/
#define IA32_MTRR_FIX_COUNT ((1 + 2 + 8) * 8)
/**
* Architecture defined number of variable range MTRRs.
*/
#define IA32_MTRR_VARIABLE_COUNT 0x000000FF
/**
* A size of array to store all possible MTRRs.
*/
#define IA32_MTRR_COUNT (IA32_MTRR_FIX_COUNT + IA32_MTRR_VARIABLE_COUNT)
/**
* @}
*/
/**
* IA32_PAT.
*
* @remarks If CPUID.01H: EDX.MTRR[16] = 1
*/
#define IA32_PAT 0x00000277
typedef union
{
struct
{
/**
* [Bits 2:0] PA0.
*/
UINT64_t pa0 : 3;
#define IA32_PAT_PA0_BIT 0
#define IA32_PAT_PA0_FLAG 0x07
#define IA32_PAT_PA0_MASK 0x07
#define IA32_PAT_PA0(_) (((_) >> 0) & 0x07)
UINT64_t reserved1 : 5;
/**
* [Bits 10:8] PA1.
*/
UINT64_t pa1 : 3;
#define IA32_PAT_PA1_BIT 8
#define IA32_PAT_PA1_FLAG 0x700
#define IA32_PAT_PA1_MASK 0x07
#define IA32_PAT_PA1(_) (((_) >> 8) & 0x07)
UINT64_t reserved2 : 5;
/**
* [Bits 18:16] PA2.
*/
UINT64_t pa2 : 3;
#define IA32_PAT_PA2_BIT 16
#define IA32_PAT_PA2_FLAG 0x70000
#define IA32_PAT_PA2_MASK 0x07
#define IA32_PAT_PA2(_) (((_) >> 16) & 0x07)
UINT64_t reserved3 : 5;
/**
* [Bits 26:24] PA3.
*/
UINT64_t pa3 : 3;
#define IA32_PAT_PA3_BIT 24
#define IA32_PAT_PA3_FLAG 0x7000000
#define IA32_PAT_PA3_MASK 0x07
#define IA32_PAT_PA3(_) (((_) >> 24) & 0x07)
UINT64_t reserved4 : 5;
/**
* [Bits 34:32] PA4.
*/
UINT64_t pa4 : 3;
#define IA32_PAT_PA4_BIT 32
#define IA32_PAT_PA4_FLAG 0x700000000
#define IA32_PAT_PA4_MASK 0x07
#define IA32_PAT_PA4(_) (((_) >> 32) & 0x07)
UINT64_t reserved5 : 5;
/**
* [Bits 42:40] PA5.
*/
UINT64_t pa5 : 3;
#define IA32_PAT_PA5_BIT 40
#define IA32_PAT_PA5_FLAG 0x70000000000
#define IA32_PAT_PA5_MASK 0x07
#define IA32_PAT_PA5(_) (((_) >> 40) & 0x07)
UINT64_t reserved6 : 5;
/**
* [Bits 50:48] PA6.
*/
UINT64_t pa6 : 3;
#define IA32_PAT_PA6_BIT 48
#define IA32_PAT_PA6_FLAG 0x7000000000000
#define IA32_PAT_PA6_MASK 0x07
#define IA32_PAT_PA6(_) (((_) >> 48) & 0x07)
UINT64_t reserved7 : 5;
/**
* [Bits 58:56] PA7.
*/
UINT64_t pa7 : 3;
#define IA32_PAT_PA7_BIT 56
#define IA32_PAT_PA7_FLAG 0x700000000000000
#define IA32_PAT_PA7_MASK 0x07
#define IA32_PAT_PA7(_) (((_) >> 56) & 0x07)
UINT64_t reserved8 : 5;
};
UINT64_t flags;
} ia32_pat_register;
/**
* @defgroup ia32_mc_ctl2 \
* IA32_MC(i)_CTL2
*
* MSR to enable/disable CMCI capability for bank n.
*
* @remarks If IA32_MCG_CAP[10] = 1 && IA32_MCG_CAP[7:0] > n
* @see Vol3B[15.3.2.5(IA32_MCi_CTL2 MSRs)]
* @{
*/
#define IA32_MC0_CTL2 0x00000280
#define IA32_MC1_CTL2 0x00000281
#define IA32_MC2_CTL2 0x00000282
#define IA32_MC3_CTL2 0x00000283
#define IA32_MC4_CTL2 0x00000284
#define IA32_MC5_CTL2 0x00000285
#define IA32_MC6_CTL2 0x00000286
#define IA32_MC7_CTL2 0x00000287
#define IA32_MC8_CTL2 0x00000288
#define IA32_MC9_CTL2 0x00000289
#define IA32_MC10_CTL2 0x0000028A
#define IA32_MC11_CTL2 0x0000028B
#define IA32_MC12_CTL2 0x0000028C
#define IA32_MC13_CTL2 0x0000028D
#define IA32_MC14_CTL2 0x0000028E
#define IA32_MC15_CTL2 0x0000028F
#define IA32_MC16_CTL2 0x00000290
#define IA32_MC17_CTL2 0x00000291
#define IA32_MC18_CTL2 0x00000292
#define IA32_MC19_CTL2 0x00000293
#define IA32_MC20_CTL2 0x00000294
#define IA32_MC21_CTL2 0x00000295
#define IA32_MC22_CTL2 0x00000296
#define IA32_MC23_CTL2 0x00000297
#define IA32_MC24_CTL2 0x00000298
#define IA32_MC25_CTL2 0x00000299
#define IA32_MC26_CTL2 0x0000029A
#define IA32_MC27_CTL2 0x0000029B
#define IA32_MC28_CTL2 0x0000029C
#define IA32_MC29_CTL2 0x0000029D
#define IA32_MC30_CTL2 0x0000029E
#define IA32_MC31_CTL2 0x0000029F
typedef union
{
struct
{
/**
* [Bits 14:0] Corrected error count threshold.
*/
UINT64_t corrected_error_count_threshold : 15;
#define IA32_MC_CTL2_CORRECTED_ERROR_COUNT_THRESHOLD_BIT 0
#define IA32_MC_CTL2_CORRECTED_ERROR_COUNT_THRESHOLD_FLAG 0x7FFF
#define IA32_MC_CTL2_CORRECTED_ERROR_COUNT_THRESHOLD_MASK 0x7FFF
#define IA32_MC_CTL2_CORRECTED_ERROR_COUNT_THRESHOLD(_) (((_) >> 0) & 0x7FFF)
UINT64_t reserved1 : 15;
/**
* [Bit 30] CMCI_EN.
*/
UINT64_t cmci_en : 1;
#define IA32_MC_CTL2_CMCI_EN_BIT 30
#define IA32_MC_CTL2_CMCI_EN_FLAG 0x40000000
#define IA32_MC_CTL2_CMCI_EN_MASK 0x01
#define IA32_MC_CTL2_CMCI_EN(_) (((_) >> 30) & 0x01)
UINT64_t reserved2 : 33;
};
UINT64_t flags;
} ia32_mc_ctl2_register;
/**
* @}
*/
/**
* IA32_MTRR_DEF_TYPE.
*
* @remarks If CPUID.01H: EDX.MTRR[12] = 1
*/
#define IA32_MTRR_DEF_TYPE 0x000002FF
typedef union
{
struct
{
/**
* [Bits 2:0] Default Memory Type.
*/
UINT64_t default_memory_type : 3;
#define IA32_MTRR_DEF_TYPE_DEFAULT_MEMORY_TYPE_BIT 0
#define IA32_MTRR_DEF_TYPE_DEFAULT_MEMORY_TYPE_FLAG 0x07
#define IA32_MTRR_DEF_TYPE_DEFAULT_MEMORY_TYPE_MASK 0x07
#define IA32_MTRR_DEF_TYPE_DEFAULT_MEMORY_TYPE(_) (((_) >> 0) & 0x07)
UINT64_t reserved1 : 7;
/**
* [Bit 10] Fixed Range MTRR Enable.
*/
UINT64_t fixed_range_mtrr_enable : 1;
#define IA32_MTRR_DEF_TYPE_FIXED_RANGE_MTRR_ENABLE_BIT 10
#define IA32_MTRR_DEF_TYPE_FIXED_RANGE_MTRR_ENABLE_FLAG 0x400
#define IA32_MTRR_DEF_TYPE_FIXED_RANGE_MTRR_ENABLE_MASK 0x01
#define IA32_MTRR_DEF_TYPE_FIXED_RANGE_MTRR_ENABLE(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] MTRR Enable.
*/
UINT64_t mtrr_enable : 1;
#define IA32_MTRR_DEF_TYPE_MTRR_ENABLE_BIT 11
#define IA32_MTRR_DEF_TYPE_MTRR_ENABLE_FLAG 0x800
#define IA32_MTRR_DEF_TYPE_MTRR_ENABLE_MASK 0x01
#define IA32_MTRR_DEF_TYPE_MTRR_ENABLE(_) (((_) >> 11) & 0x01)
UINT64_t reserved2 : 52;
};
UINT64_t flags;
} ia32_mtrr_def_type_register;
/**
* @defgroup ia32_fixed_ctr \
* IA32_FIXED_CTR(n)
*
* Fixed-Function Performance Counter n.
*
* @remarks If CPUID.0AH: EDX[4:0] > n
* @{
*/
/**
* Counts Instr_Retired.Any.
*/
#define IA32_FIXED_CTR0 0x00000309
/**
* Counts CPU_CLK_Unhalted.Core
*/
#define IA32_FIXED_CTR1 0x0000030A
/**
* Counts CPU_CLK_Unhalted.Ref
*/
#define IA32_FIXED_CTR2 0x0000030B
/**
* @}
*/
/**
* Read Only MSR that enumerates the existence of performance monitoring features.
*
* @remarks If CPUID.01H: ECX[15] = 1
*/
#define IA32_PERF_CAPABILITIES 0x00000345
typedef union
{
struct
{
/**
* [Bits 5:0] LBR format.
*/
UINT64_t lbr_format : 6;
#define IA32_PERF_CAPABILITIES_LBR_FORMAT_BIT 0
#define IA32_PERF_CAPABILITIES_LBR_FORMAT_FLAG 0x3F
#define IA32_PERF_CAPABILITIES_LBR_FORMAT_MASK 0x3F
#define IA32_PERF_CAPABILITIES_LBR_FORMAT(_) (((_) >> 0) & 0x3F)
/**
* [Bit 6] PEBS Trap.
*/
UINT64_t pebs_trap : 1;
#define IA32_PERF_CAPABILITIES_PEBS_TRAP_BIT 6
#define IA32_PERF_CAPABILITIES_PEBS_TRAP_FLAG 0x40
#define IA32_PERF_CAPABILITIES_PEBS_TRAP_MASK 0x01
#define IA32_PERF_CAPABILITIES_PEBS_TRAP(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] PEBSSaveArchRegs.
*/
UINT64_t pebs_save_arch_regs : 1;
#define IA32_PERF_CAPABILITIES_PEBS_SAVE_ARCH_REGS_BIT 7
#define IA32_PERF_CAPABILITIES_PEBS_SAVE_ARCH_REGS_FLAG 0x80
#define IA32_PERF_CAPABILITIES_PEBS_SAVE_ARCH_REGS_MASK 0x01
#define IA32_PERF_CAPABILITIES_PEBS_SAVE_ARCH_REGS(_) (((_) >> 7) & 0x01)
/**
* [Bits 11:8] PEBS Record Format.
*/
UINT64_t pebs_record_format : 4;
#define IA32_PERF_CAPABILITIES_PEBS_RECORD_FORMAT_BIT 8
#define IA32_PERF_CAPABILITIES_PEBS_RECORD_FORMAT_FLAG 0xF00
#define IA32_PERF_CAPABILITIES_PEBS_RECORD_FORMAT_MASK 0x0F
#define IA32_PERF_CAPABILITIES_PEBS_RECORD_FORMAT(_) (((_) >> 8) & 0x0F)
/**
* [Bit 12] Freeze while SMM is supported.
*/
UINT64_t freeze_while_smm_is_supported : 1;
#define IA32_PERF_CAPABILITIES_FREEZE_WHILE_SMM_IS_SUPPORTED_BIT 12
#define IA32_PERF_CAPABILITIES_FREEZE_WHILE_SMM_IS_SUPPORTED_FLAG 0x1000
#define IA32_PERF_CAPABILITIES_FREEZE_WHILE_SMM_IS_SUPPORTED_MASK 0x01
#define IA32_PERF_CAPABILITIES_FREEZE_WHILE_SMM_IS_SUPPORTED(_) (((_) >> 12) & 0x01)
/**
* [Bit 13] Full width of counter writable via IA32_A_PMCx.
*/
UINT64_t full_width_counter_write : 1;
#define IA32_PERF_CAPABILITIES_FULL_WIDTH_COUNTER_WRITE_BIT 13
#define IA32_PERF_CAPABILITIES_FULL_WIDTH_COUNTER_WRITE_FLAG 0x2000
#define IA32_PERF_CAPABILITIES_FULL_WIDTH_COUNTER_WRITE_MASK 0x01
#define IA32_PERF_CAPABILITIES_FULL_WIDTH_COUNTER_WRITE(_) (((_) >> 13) & 0x01)
UINT64_t reserved1 : 50;
};
UINT64_t flags;
} ia32_perf_capabilities_register;
/**
* @brief Fixed-Function Performance Counter Control <b>(R/W)</b>
*
* Fixed-Function Performance Counter Control. Counter increments while the results of ANDing respective enable bit in
* IA32_PERF_GLOBAL_CTRL with the corresponding OS or USR bits in this MSR is true.
*
* @remarks If CPUID.0AH: EAX[7:0] > 1
*/
#define IA32_FIXED_CTR_CTRL 0x0000038D
typedef union
{
struct
{
/**
* [Bit 0] EN0_OS: Enable Fixed Counter 0 to count while CPL = 0.
*/
UINT64_t en0_os : 1;
#define IA32_FIXED_CTR_CTRL_EN0_OS_BIT 0
#define IA32_FIXED_CTR_CTRL_EN0_OS_FLAG 0x01
#define IA32_FIXED_CTR_CTRL_EN0_OS_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN0_OS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] EN0_Usr: Enable Fixed Counter 0 to count while CPL > 0.
*/
UINT64_t en0_usr : 1;
#define IA32_FIXED_CTR_CTRL_EN0_USR_BIT 1
#define IA32_FIXED_CTR_CTRL_EN0_USR_FLAG 0x02
#define IA32_FIXED_CTR_CTRL_EN0_USR_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN0_USR(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] AnyThread: When set to 1, it enables counting the associated event conditions occurring across all logical
* processors sharing a processor core. When set to 0, the counter only increments the associated event conditions
* occurring in the logical processor which programmed the MSR.
*/
UINT64_t any_thread0 : 1;
#define IA32_FIXED_CTR_CTRL_ANY_THREAD0_BIT 2
#define IA32_FIXED_CTR_CTRL_ANY_THREAD0_FLAG 0x04
#define IA32_FIXED_CTR_CTRL_ANY_THREAD0_MASK 0x01
#define IA32_FIXED_CTR_CTRL_ANY_THREAD0(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] EN0_PMI: Enable PMI when fixed counter 0 overflows.
*/
UINT64_t en0_pmi : 1;
#define IA32_FIXED_CTR_CTRL_EN0_PMI_BIT 3
#define IA32_FIXED_CTR_CTRL_EN0_PMI_FLAG 0x08
#define IA32_FIXED_CTR_CTRL_EN0_PMI_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN0_PMI(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] EN1_OS: Enable Fixed Counter 1 to count while CPL = 0.
*/
UINT64_t en1_os : 1;
#define IA32_FIXED_CTR_CTRL_EN1_OS_BIT 4
#define IA32_FIXED_CTR_CTRL_EN1_OS_FLAG 0x10
#define IA32_FIXED_CTR_CTRL_EN1_OS_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN1_OS(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] EN1_Usr: Enable Fixed Counter 1 to count while CPL > 0.
*/
UINT64_t en1_usr : 1;
#define IA32_FIXED_CTR_CTRL_EN1_USR_BIT 5
#define IA32_FIXED_CTR_CTRL_EN1_USR_FLAG 0x20
#define IA32_FIXED_CTR_CTRL_EN1_USR_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN1_USR(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] AnyThread: When set to 1, it enables counting the associated event conditions occurring across all logical
* processors sharing a processor core. When set to 0, the counter only increments the associated event conditions
* occurring in the logical processor which programmed the MSR.
*
* @remarks If CPUID.0AH: EAX[7:0] > 2
*/
UINT64_t any_thread1 : 1;
#define IA32_FIXED_CTR_CTRL_ANY_THREAD1_BIT 6
#define IA32_FIXED_CTR_CTRL_ANY_THREAD1_FLAG 0x40
#define IA32_FIXED_CTR_CTRL_ANY_THREAD1_MASK 0x01
#define IA32_FIXED_CTR_CTRL_ANY_THREAD1(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] EN1_PMI: Enable PMI when fixed counter 1 overflows.
*/
UINT64_t en1_pmi : 1;
#define IA32_FIXED_CTR_CTRL_EN1_PMI_BIT 7
#define IA32_FIXED_CTR_CTRL_EN1_PMI_FLAG 0x80
#define IA32_FIXED_CTR_CTRL_EN1_PMI_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN1_PMI(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] EN2_OS: Enable Fixed Counter 2 to count while CPL = 0.
*/
UINT64_t en2_os : 1;
#define IA32_FIXED_CTR_CTRL_EN2_OS_BIT 8
#define IA32_FIXED_CTR_CTRL_EN2_OS_FLAG 0x100
#define IA32_FIXED_CTR_CTRL_EN2_OS_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN2_OS(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] EN2_Usr: Enable Fixed Counter 2 to count while CPL > 0.
*/
UINT64_t en2_usr : 1;
#define IA32_FIXED_CTR_CTRL_EN2_USR_BIT 9
#define IA32_FIXED_CTR_CTRL_EN2_USR_FLAG 0x200
#define IA32_FIXED_CTR_CTRL_EN2_USR_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN2_USR(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] AnyThread: When set to 1, it enables counting the associated event conditions occurring across all logical
* processors sharing a processor core. When set to 0, the counter only increments the associated event conditions
* occurring in the logical processor which programmed the MSR.
*
* @remarks If CPUID.0AH: EAX[7:0] > 2
*/
UINT64_t any_thread2 : 1;
#define IA32_FIXED_CTR_CTRL_ANY_THREAD2_BIT 10
#define IA32_FIXED_CTR_CTRL_ANY_THREAD2_FLAG 0x400
#define IA32_FIXED_CTR_CTRL_ANY_THREAD2_MASK 0x01
#define IA32_FIXED_CTR_CTRL_ANY_THREAD2(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] EN2_PMI: Enable PMI when fixed counter 2 overflows.
*/
UINT64_t en2_pmi : 1;
#define IA32_FIXED_CTR_CTRL_EN2_PMI_BIT 11
#define IA32_FIXED_CTR_CTRL_EN2_PMI_FLAG 0x800
#define IA32_FIXED_CTR_CTRL_EN2_PMI_MASK 0x01
#define IA32_FIXED_CTR_CTRL_EN2_PMI(_) (((_) >> 11) & 0x01)
UINT64_t reserved1 : 52;
};
UINT64_t flags;
} ia32_fixed_ctr_ctrl_register;
/**
* Global Performance Counter Status.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
#define IA32_PERF_GLOBAL_STATUS 0x0000038E
typedef union
{
struct
{
/**
* [Bit 0] Ovf_PMC0: Overflow status of IA32_PMC0.
*
* @remarks If CPUID.0AH: EAX[15:8] > 0
*/
UINT64_t ovf_pmc0 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC0_BIT 0
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC0_FLAG 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC0_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC0(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Ovf_PMC1: Overflow status of IA32_PMC1.
*
* @remarks If CPUID.0AH: EAX[15:8] > 1
*/
UINT64_t ovf_pmc1 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC1_BIT 1
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC1_FLAG 0x02
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC1_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC1(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Ovf_PMC2: Overflow status of IA32_PMC2.
*
* @remarks If CPUID.0AH: EAX[15:8] > 2
*/
UINT64_t ovf_pmc2 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC2_BIT 2
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC2_FLAG 0x04
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC2_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC2(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Ovf_PMC3: Overflow status of IA32_PMC3.
*
* @remarks If CPUID.0AH: EAX[15:8] > 3
*/
UINT64_t ovf_pmc3 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC3_BIT 3
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC3_FLAG 0x08
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC3_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_PMC3(_) (((_) >> 3) & 0x01)
UINT64_t reserved1 : 28;
/**
* [Bit 32] Ovf_FixedCtr0: Overflow status of IA32_FIXED_CTR0.
*
* @remarks If CPUID.0AH: EAX[7:0] > 1
*/
UINT64_t ovf_fixedctr0 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR0_BIT 32
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR0_FLAG 0x100000000
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR0_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR0(_) (((_) >> 32) & 0x01)
/**
* [Bit 33] Ovf_FixedCtr1: Overflow status of IA32_FIXED_CTR1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 1
*/
UINT64_t ovf_fixedctr1 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR1_BIT 33
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR1_FLAG 0x200000000
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR1_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR1(_) (((_) >> 33) & 0x01)
/**
* [Bit 34] Ovf_FixedCtr2: Overflow status of IA32_FIXED_CTR2.
*
* @remarks If CPUID.0AH: EAX[7:0] > 1
*/
UINT64_t ovf_fixedctr2 : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR2_BIT 34
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR2_FLAG 0x400000000
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR2_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_FIXEDCTR2(_) (((_) >> 34) & 0x01)
UINT64_t reserved2 : 20;
/**
* [Bit 55] Trace_ToPA_PMI: A PMI occurred due to a ToPA entry memory buffer that was completely filled.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[25] = 1) && IA32_RTIT_CTL.ToPA = 1
*/
UINT64_t trace_topa_pmi : 1;
#define IA32_PERF_GLOBAL_STATUS_TRACE_TOPA_PMI_BIT 55
#define IA32_PERF_GLOBAL_STATUS_TRACE_TOPA_PMI_FLAG 0x80000000000000
#define IA32_PERF_GLOBAL_STATUS_TRACE_TOPA_PMI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_TRACE_TOPA_PMI(_) (((_) >> 55) & 0x01)
UINT64_t reserved3 : 2;
/**
* [Bit 58] LBR_Frz. LBRs are frozen due to:
* * IA32_DEBUGCTL.FREEZE_LBR_ON_PMI=1.
* * The LBR stack overflowed.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t lbr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_LBR_FRZ_BIT 58
#define IA32_PERF_GLOBAL_STATUS_LBR_FRZ_FLAG 0x400000000000000
#define IA32_PERF_GLOBAL_STATUS_LBR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_LBR_FRZ(_) (((_) >> 58) & 0x01)
/**
* [Bit 59] CTR_Frz. Performance counters in the core PMU are frozen due to:
* * IA32_DEBUGCTL.FREEZE_PERFMON_ON_PMI=1.
* * One or more core PMU counters overflowed.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t ctr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_CTR_FRZ_BIT 59
#define IA32_PERF_GLOBAL_STATUS_CTR_FRZ_FLAG 0x800000000000000
#define IA32_PERF_GLOBAL_STATUS_CTR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_CTR_FRZ(_) (((_) >> 59) & 0x01)
/**
* [Bit 60] ASCI: Data in the performance counters in the core PMU may include contributions from the direct or indirect
* operation Intel SGX to protect an enclave.
*
* @remarks If CPUID.(EAX=07H, ECX=0):EBX[2] = 1
*/
UINT64_t asci : 1;
#define IA32_PERF_GLOBAL_STATUS_ASCI_BIT 60
#define IA32_PERF_GLOBAL_STATUS_ASCI_FLAG 0x1000000000000000
#define IA32_PERF_GLOBAL_STATUS_ASCI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_ASCI(_) (((_) >> 60) & 0x01)
/**
* [Bit 61] Uncore counter overflow status.
*
* @remarks If CPUID.0AH: EAX[7:0] > 2
*/
UINT64_t ovf_uncore : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_UNCORE_BIT 61
#define IA32_PERF_GLOBAL_STATUS_OVF_UNCORE_FLAG 0x2000000000000000
#define IA32_PERF_GLOBAL_STATUS_OVF_UNCORE_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_UNCORE(_) (((_) >> 61) & 0x01)
/**
* [Bit 62] OvfBuf: DS SAVE area Buffer overflow status.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
UINT64_t ovf_buf : 1;
#define IA32_PERF_GLOBAL_STATUS_OVF_BUF_BIT 62
#define IA32_PERF_GLOBAL_STATUS_OVF_BUF_FLAG 0x4000000000000000
#define IA32_PERF_GLOBAL_STATUS_OVF_BUF_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_OVF_BUF(_) (((_) >> 62) & 0x01)
/**
* [Bit 63] CondChgd: Status bits of this register have changed.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
UINT64_t cond_chgd : 1;
#define IA32_PERF_GLOBAL_STATUS_COND_CHGD_BIT 63
#define IA32_PERF_GLOBAL_STATUS_COND_CHGD_FLAG 0x8000000000000000
#define IA32_PERF_GLOBAL_STATUS_COND_CHGD_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_COND_CHGD(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} ia32_perf_global_status_register;
/**
* @brief Global Performance Counter Control <b>(R/W)</b>
*
* Global Performance Counter Control. Counter increments while the result of ANDing the respective enable bit in this MSR
* with the corresponding OS or USR bits in the general-purpose or fixed counter control MSR is true.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
#define IA32_PERF_GLOBAL_CTRL 0x0000038F
typedef struct
{
/**
* EN_PMC(n). Enable bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
*/
UINT32_t en_pmcn;
/**
* EN_FIXED_CTR(n). Enable bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*
* @remarks If CPUID.0AH: EDX[4:0] > n
*/
UINT32_t en_fixed_ctrn;
} ia32_perf_global_ctrl_register;
/**
* Global Performance Counter Overflow Reset Control.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
#define IA32_PERF_GLOBAL_STATUS_RESET 0x00000390
typedef union
{
struct
{
/**
* [Bits 31:0] Set 1 to clear Ovf_PMC(n) bit. Clear bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
*/
UINT64_t clear_ovf_pmcn : 32;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_PMCN_BIT 0
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_PMCN_FLAG 0xFFFFFFFF
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_PMCN_MASK 0xFFFFFFFF
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_PMCN(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* [Bits 34:32] Set 1 to clear Ovf_FIXED_CTR(n) bit. Clear bitmask. Only the first n-1 bits are valid. Bits 31:n are
* reserved.
*
* @remarks If CPUID.0AH: EDX[4:0] > n
*/
UINT64_t clear_ovf_fixed_ctrn : 3;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_FIXED_CTRN_BIT 32
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_FIXED_CTRN_FLAG 0x700000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_FIXED_CTRN_MASK 0x07
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_FIXED_CTRN(_) (((_) >> 32) & 0x07)
UINT64_t reserved1 : 20;
/**
* [Bit 55] Set 1 to clear Trace_ToPA_PMI bit.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[25] = 1) && IA32_RTIT_CTL.ToPA = 1
*/
UINT64_t clear_trace_topa_pmi : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_TRACE_TOPA_PMI_BIT 55
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_TRACE_TOPA_PMI_FLAG 0x80000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_TRACE_TOPA_PMI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_TRACE_TOPA_PMI(_) (((_) >> 55) & 0x01)
UINT64_t reserved2 : 2;
/**
* [Bit 58] Set 1 to clear LBR_Frz bit.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t clear_lbr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_LBR_FRZ_BIT 58
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_LBR_FRZ_FLAG 0x400000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_LBR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_LBR_FRZ(_) (((_) >> 58) & 0x01)
/**
* [Bit 59] Set 1 to clear CTR_Frz bit.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t clear_ctr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_CTR_FRZ_BIT 59
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_CTR_FRZ_FLAG 0x800000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_CTR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_CTR_FRZ(_) (((_) >> 59) & 0x01)
/**
* [Bit 60] Set 1 to clear ASCI bit.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t clear_asci : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_ASCI_BIT 60
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_ASCI_FLAG 0x1000000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_ASCI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_ASCI(_) (((_) >> 60) & 0x01)
/**
* [Bit 61] Set 1 to clear Ovf_Uncore bit.
*
* @remarks 06_2EH
*/
UINT64_t clear_ovf_uncore : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_UNCORE_BIT 61
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_UNCORE_FLAG 0x2000000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_UNCORE_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_UNCORE(_) (((_) >> 61) & 0x01)
/**
* [Bit 62] Set 1 to clear OvfBuf bit.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
UINT64_t clear_ovf_buf : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_BUF_BIT 62
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_BUF_FLAG 0x4000000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_BUF_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_OVF_BUF(_) (((_) >> 62) & 0x01)
/**
* [Bit 63] Set 1 to clear CondChgd bit.
*
* @remarks If CPUID.0AH: EAX[7:0] > 0
*/
UINT64_t clear_cond_chgd : 1;
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_COND_CHGD_BIT 63
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_COND_CHGD_FLAG 0x8000000000000000
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_COND_CHGD_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_RESET_CLEAR_COND_CHGD(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} ia32_perf_global_status_reset_register;
/**
* Global Performance Counter Overflow Set Control.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
#define IA32_PERF_GLOBAL_STATUS_SET 0x00000391
typedef union
{
struct
{
/**
* [Bits 31:0] Set 1 to cause Ovf_PMC(n) = 1. Set bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
*/
UINT64_t ovf_pmcn : 32;
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_PMCN_BIT 0
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_PMCN_FLAG 0xFFFFFFFF
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_PMCN_MASK 0xFFFFFFFF
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_PMCN(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* [Bits 34:32] Set 1 to cause Ovf_FIXED_CTR(n) = 1. Set bitmask. Only the first n-1 bits are valid. Bits 31:n are
* reserved.
*
* @remarks If CPUID.0AH: EDX[4:0] > n
*/
UINT64_t ovf_fixed_ctrn : 3;
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_FIXED_CTRN_BIT 32
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_FIXED_CTRN_FLAG 0x700000000
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_FIXED_CTRN_MASK 0x07
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_FIXED_CTRN(_) (((_) >> 32) & 0x07)
UINT64_t reserved1 : 20;
/**
* [Bit 55] Set 1 to cause Trace_ToPA_PMI = 1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t trace_topa_pmi : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_TRACE_TOPA_PMI_BIT 55
#define IA32_PERF_GLOBAL_STATUS_SET_TRACE_TOPA_PMI_FLAG 0x80000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_TRACE_TOPA_PMI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_TRACE_TOPA_PMI(_) (((_) >> 55) & 0x01)
UINT64_t reserved2 : 2;
/**
* [Bit 58] Set 1 to cause LBR_Frz = 1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t lbr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_LBR_FRZ_BIT 58
#define IA32_PERF_GLOBAL_STATUS_SET_LBR_FRZ_FLAG 0x400000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_LBR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_LBR_FRZ(_) (((_) >> 58) & 0x01)
/**
* [Bit 59] Set 1 to cause CTR_Frz = 1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t ctr_frz : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_CTR_FRZ_BIT 59
#define IA32_PERF_GLOBAL_STATUS_SET_CTR_FRZ_FLAG 0x800000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_CTR_FRZ_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_CTR_FRZ(_) (((_) >> 59) & 0x01)
/**
* [Bit 60] Set 1 to cause ASCI = 1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t asci : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_ASCI_BIT 60
#define IA32_PERF_GLOBAL_STATUS_SET_ASCI_FLAG 0x1000000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_ASCI_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_ASCI(_) (((_) >> 60) & 0x01)
/**
* [Bit 61] Set 1 to cause Ovf_Uncore = 1.
*
* @remarks 06_2EH
*/
UINT64_t ovf_uncore : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_UNCORE_BIT 61
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_UNCORE_FLAG 0x2000000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_UNCORE_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_UNCORE(_) (((_) >> 61) & 0x01)
/**
* [Bit 62] Set 1 to cause OvfBuf = 1.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
UINT64_t ovf_buf : 1;
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_BUF_BIT 62
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_BUF_FLAG 0x4000000000000000
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_BUF_MASK 0x01
#define IA32_PERF_GLOBAL_STATUS_SET_OVF_BUF(_) (((_) >> 62) & 0x01)
UINT64_t reserved3 : 1;
};
UINT64_t flags;
} ia32_perf_global_status_set_register;
/**
* Indicator that core perfmon interface is in use.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
#define IA32_PERF_GLOBAL_INUSE 0x00000392
typedef union
{
struct
{
/**
* [Bits 31:0] IA32_PERFEVTSEL(n) in use. Status bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*
* @remarks If CPUID.0AH: EAX[15:8] > n
*/
UINT64_t ia32_perfevtseln_in_use : 32;
#define IA32_PERF_GLOBAL_INUSE_IA32_PERFEVTSELN_IN_USE_BIT 0
#define IA32_PERF_GLOBAL_INUSE_IA32_PERFEVTSELN_IN_USE_FLAG 0xFFFFFFFF
#define IA32_PERF_GLOBAL_INUSE_IA32_PERFEVTSELN_IN_USE_MASK 0xFFFFFFFF
#define IA32_PERF_GLOBAL_INUSE_IA32_PERFEVTSELN_IN_USE(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* [Bits 34:32] IA32_FIXED_CTR(n) in use. Status bitmask. Only the first n-1 bits are valid. Bits 31:n are reserved.
*/
UINT64_t ia32_fixed_ctrn_in_use : 3;
#define IA32_PERF_GLOBAL_INUSE_IA32_FIXED_CTRN_IN_USE_BIT 32
#define IA32_PERF_GLOBAL_INUSE_IA32_FIXED_CTRN_IN_USE_FLAG 0x700000000
#define IA32_PERF_GLOBAL_INUSE_IA32_FIXED_CTRN_IN_USE_MASK 0x07
#define IA32_PERF_GLOBAL_INUSE_IA32_FIXED_CTRN_IN_USE(_) (((_) >> 32) & 0x07)
UINT64_t reserved1 : 28;
/**
* [Bit 63] PMI in use.
*/
UINT64_t pmi_in_use : 1;
#define IA32_PERF_GLOBAL_INUSE_PMI_IN_USE_BIT 63
#define IA32_PERF_GLOBAL_INUSE_PMI_IN_USE_FLAG 0x8000000000000000
#define IA32_PERF_GLOBAL_INUSE_PMI_IN_USE_MASK 0x01
#define IA32_PERF_GLOBAL_INUSE_PMI_IN_USE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} ia32_perf_global_inuse_register;
/**
* PEBS Control.
*
* @remarks If CPUID.0AH: EAX[7:0] > 3
*/
#define IA32_PEBS_ENABLE 0x000003F1
typedef union
{
struct
{
/**
* [Bit 0] Enable PEBS on IA32_PMC0.
*
* @remarks 06_0FH
*/
UINT64_t enable_pebs : 1;
#define IA32_PEBS_ENABLE_ENABLE_PEBS_BIT 0
#define IA32_PEBS_ENABLE_ENABLE_PEBS_FLAG 0x01
#define IA32_PEBS_ENABLE_ENABLE_PEBS_MASK 0x01
#define IA32_PEBS_ENABLE_ENABLE_PEBS(_) (((_) >> 0) & 0x01)
/**
* [Bits 3:1] Reserved or model specific.
*/
UINT64_t reservedormodelspecific1 : 3;
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC1_BIT 1
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC1_FLAG 0x0E
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC1_MASK 0x07
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC1(_) (((_) >> 1) & 0x07)
UINT64_t reserved1 : 28;
/**
* [Bits 35:32] Reserved or model specific.
*/
UINT64_t reservedormodelspecific2 : 4;
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC2_BIT 32
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC2_FLAG 0xF00000000
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC2_MASK 0x0F
#define IA32_PEBS_ENABLE_RESERVEDORMODELSPECIFIC2(_) (((_) >> 32) & 0x0F)
UINT64_t reserved2 : 28;
};
UINT64_t flags;
} ia32_pebs_enable_register;
/**
* @defgroup ia32_mc_ctl \
* IA32_MC(i)_CTL
*
* IA32_MC(0-28)_CTL.
*
* @remarks If IA32_MCG_CAP.CNT > n
* @{
*/
#define IA32_MC0_CTL 0x00000400
#define IA32_MC1_CTL 0x00000404
#define IA32_MC2_CTL 0x00000408
#define IA32_MC3_CTL 0x0000040C
#define IA32_MC4_CTL 0x00000410
#define IA32_MC5_CTL 0x00000414
#define IA32_MC6_CTL 0x00000418
#define IA32_MC7_CTL 0x0000041C
#define IA32_MC8_CTL 0x00000420
#define IA32_MC9_CTL 0x00000424
#define IA32_MC10_CTL 0x00000428
#define IA32_MC11_CTL 0x0000042C
#define IA32_MC12_CTL 0x00000430
#define IA32_MC13_CTL 0x00000434
#define IA32_MC14_CTL 0x00000438
#define IA32_MC15_CTL 0x0000043C
#define IA32_MC16_CTL 0x00000440
#define IA32_MC17_CTL 0x00000444
#define IA32_MC18_CTL 0x00000448
#define IA32_MC19_CTL 0x0000044C
#define IA32_MC20_CTL 0x00000450
#define IA32_MC21_CTL 0x00000454
#define IA32_MC22_CTL 0x00000458
#define IA32_MC23_CTL 0x0000045C
#define IA32_MC24_CTL 0x00000460
#define IA32_MC25_CTL 0x00000464
#define IA32_MC26_CTL 0x00000468
#define IA32_MC27_CTL 0x0000046C
#define IA32_MC28_CTL 0x00000470
/**
* @}
*/
/**
* @defgroup ia32_mc_status \
* IA32_MC(i)_STATUS
*
* IA32_MC(0-28)_STATUS.
*
* @remarks If IA32_MCG_CAP.CNT > n
* @{
*/
#define IA32_MC0_STATUS 0x00000401
#define IA32_MC1_STATUS 0x00000405
#define IA32_MC2_STATUS 0x00000409
#define IA32_MC3_STATUS 0x0000040D
#define IA32_MC4_STATUS 0x00000411
#define IA32_MC5_STATUS 0x00000415
#define IA32_MC6_STATUS 0x00000419
#define IA32_MC7_STATUS 0x0000041D
#define IA32_MC8_STATUS 0x00000421
#define IA32_MC9_STATUS 0x00000425
#define IA32_MC10_STATUS 0x00000429
#define IA32_MC11_STATUS 0x0000042D
#define IA32_MC12_STATUS 0x00000431
#define IA32_MC13_STATUS 0x00000435
#define IA32_MC14_STATUS 0x00000439
#define IA32_MC15_STATUS 0x0000043D
#define IA32_MC16_STATUS 0x00000441
#define IA32_MC17_STATUS 0x00000445
#define IA32_MC18_STATUS 0x00000449
#define IA32_MC19_STATUS 0x0000044D
#define IA32_MC20_STATUS 0x00000451
#define IA32_MC21_STATUS 0x00000455
#define IA32_MC22_STATUS 0x00000459
#define IA32_MC23_STATUS 0x0000045D
#define IA32_MC24_STATUS 0x00000461
#define IA32_MC25_STATUS 0x00000465
#define IA32_MC26_STATUS 0x00000469
#define IA32_MC27_STATUS 0x0000046D
#define IA32_MC28_STATUS 0x00000471
/**
* @}
*/
/**
* @defgroup ia32_mc_addr \
* IA32_MC(i)_ADDR
*
* IA32_MC(0-28)_ADDR.
*
* @remarks If IA32_MCG_CAP.CNT > n
* @{
*/
#define IA32_MC0_ADDR 0x00000402
#define IA32_MC1_ADDR 0x00000406
#define IA32_MC2_ADDR 0x0000040A
#define IA32_MC3_ADDR 0x0000040E
#define IA32_MC4_ADDR 0x00000412
#define IA32_MC5_ADDR 0x00000416
#define IA32_MC6_ADDR 0x0000041A
#define IA32_MC7_ADDR 0x0000041E
#define IA32_MC8_ADDR 0x00000422
#define IA32_MC9_ADDR 0x00000426
#define IA32_MC10_ADDR 0x0000042A
#define IA32_MC11_ADDR 0x0000042E
#define IA32_MC12_ADDR 0x00000432
#define IA32_MC13_ADDR 0x00000436
#define IA32_MC14_ADDR 0x0000043A
#define IA32_MC15_ADDR 0x0000043E
#define IA32_MC16_ADDR 0x00000442
#define IA32_MC17_ADDR 0x00000446
#define IA32_MC18_ADDR 0x0000044A
#define IA32_MC19_ADDR 0x0000044E
#define IA32_MC20_ADDR 0x00000452
#define IA32_MC21_ADDR 0x00000456
#define IA32_MC22_ADDR 0x0000045A
#define IA32_MC23_ADDR 0x0000045E
#define IA32_MC24_ADDR 0x00000462
#define IA32_MC25_ADDR 0x00000466
#define IA32_MC26_ADDR 0x0000046A
#define IA32_MC27_ADDR 0x0000046E
#define IA32_MC28_ADDR 0x00000472
/**
* @}
*/
/**
* @defgroup ia32_mc_misc \
* IA32_MC(i)_MISC
*
* IA32_MC(0-28)_MISC.
*
* @remarks If IA32_MCG_CAP.CNT > n
* @{
*/
#define IA32_MC0_MISC 0x00000403
#define IA32_MC1_MISC 0x00000407
#define IA32_MC2_MISC 0x0000040B
#define IA32_MC3_MISC 0x0000040F
#define IA32_MC4_MISC 0x00000413
#define IA32_MC5_MISC 0x00000417
#define IA32_MC6_MISC 0x0000041B
#define IA32_MC7_MISC 0x0000041F
#define IA32_MC8_MISC 0x00000423
#define IA32_MC9_MISC 0x00000427
#define IA32_MC10_MISC 0x0000042B
#define IA32_MC11_MISC 0x0000042F
#define IA32_MC12_MISC 0x00000433
#define IA32_MC13_MISC 0x00000437
#define IA32_MC14_MISC 0x0000043B
#define IA32_MC15_MISC 0x0000043F
#define IA32_MC16_MISC 0x00000443
#define IA32_MC17_MISC 0x00000447
#define IA32_MC18_MISC 0x0000044B
#define IA32_MC19_MISC 0x0000044F
#define IA32_MC20_MISC 0x00000453
#define IA32_MC21_MISC 0x00000457
#define IA32_MC22_MISC 0x0000045B
#define IA32_MC23_MISC 0x0000045F
#define IA32_MC24_MISC 0x00000463
#define IA32_MC25_MISC 0x00000467
#define IA32_MC26_MISC 0x0000046B
#define IA32_MC27_MISC 0x0000046F
#define IA32_MC28_MISC 0x00000473
/**
* @}
*/
/**
* Reporting Register of Basic VMX Capabilities.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.1(BASIC VMX INFORMATION)]
* @see Vol3D[A.1(Basic VMX Information)] (reference)
*/
#define IA32_VMX_BASIC 0x00000480
typedef union
{
struct
{
/**
* @brief VMCS revision identifier used by the processor
*
* [Bits 30:0] 31-bit VMCS revision identifier used by the processor. Processors that use the same VMCS revision identifier
* use the same size for VMCS regions.
*/
UINT64_t vmcs_revision_id : 31;
#define IA32_VMX_BASIC_VMCS_REVISION_ID_BIT 0
#define IA32_VMX_BASIC_VMCS_REVISION_ID_FLAG 0x7FFFFFFF
#define IA32_VMX_BASIC_VMCS_REVISION_ID_MASK 0x7FFFFFFF
#define IA32_VMX_BASIC_VMCS_REVISION_ID(_) (((_) >> 0) & 0x7FFFFFFF)
/**
* [Bit 31] Bit 31 is always 0.
*/
UINT64_t must_be_zero : 1;
#define IA32_VMX_BASIC_MUST_BE_ZERO_BIT 31
#define IA32_VMX_BASIC_MUST_BE_ZERO_FLAG 0x80000000
#define IA32_VMX_BASIC_MUST_BE_ZERO_MASK 0x01
#define IA32_VMX_BASIC_MUST_BE_ZERO(_) (((_) >> 31) & 0x01)
/**
* @brief Size of the VMCS
*
* [Bits 44:32] Report the number of bytes that software should allocate for the VMXON region and any VMCS region. It is a
* value greater than 0 and at most 4096 (bit 44 is set if and only if bits 43:32 are clear).
*/
UINT64_t vmcs_size_inUINT8s : 13;
#define IA32_VMX_BASIC_VMCS_SIZE_INUINT8S_BIT 32
#define IA32_VMX_BASIC_VMCS_SIZE_INUINT8S_FLAG 0x1FFF00000000
#define IA32_VMX_BASIC_VMCS_SIZE_INUINT8S_MASK 0x1FFF
#define IA32_VMX_BASIC_VMCS_SIZE_INUINT8S(_) (((_) >> 32) & 0x1FFF)
UINT64_t reserved1 : 3;
/**
* @brief Width of physical address used for the VMCS
* - 0 -> limited to the available amount of physical RAM
* - 1 -> within the first 4 GB
*
* [Bit 48] Indicates the width of the physical addresses that may be used for the VMXON region, each VMCS, and data
* structures referenced by pointers in a VMCS (I/O bitmaps, virtual-APIC page, MSR areas for VMX transitions). If the bit
* is 0, these addresses are limited to the processor's physical-address width.2 If the bit is 1, these addresses are
* limited to 32 bits. This bit is always 0 for processors that support Intel 64 architecture.
*/
UINT64_t vmcs_physical_address_width : 1;
#define IA32_VMX_BASIC_VMCS_PHYSICAL_ADDRESS_WIDTH_BIT 48
#define IA32_VMX_BASIC_VMCS_PHYSICAL_ADDRESS_WIDTH_FLAG 0x1000000000000
#define IA32_VMX_BASIC_VMCS_PHYSICAL_ADDRESS_WIDTH_MASK 0x01
#define IA32_VMX_BASIC_VMCS_PHYSICAL_ADDRESS_WIDTH(_) (((_) >> 48) & 0x01)
/**
* @brief Whether the processor supports the dual-monitor treatment of system-management interrupts and system-management
* code (always 1)
*
* [Bit 49] Read as 1, the logical processor supports the dual-monitor treatment of system-management interrupts and
* system-management mode.
*
* @see Vol3C[34.15(DUAL-MONITOR TREATMENT OF SMIs AND SMM)]
*/
UINT64_t dual_monitor_support : 1;
#define IA32_VMX_BASIC_DUAL_MONITOR_SUPPORT_BIT 49
#define IA32_VMX_BASIC_DUAL_MONITOR_SUPPORT_FLAG 0x2000000000000
#define IA32_VMX_BASIC_DUAL_MONITOR_SUPPORT_MASK 0x01
#define IA32_VMX_BASIC_DUAL_MONITOR_SUPPORT(_) (((_) >> 49) & 0x01)
/**
* @brief Memory type that must be used for the VMCS
*
* [Bits 53:50] Report the memory type that should be used for the VMCS, for data structures referenced by pointers in the
* VMCS (I/O bitmaps, virtual-APIC page, MSR areas for VMX transitions), and for the MSEG header. If software needs to
* access these data structures (e.g., to modify the contents of the MSR bitmaps), it can configure the paging structures
* to map them into the linear-address space. If it does so, it should establish mappings that use the memory type reported
* bits 53:50 in this MSR.
* As of this writing, all processors that support VMX operation indicate the write-back type.
*/
UINT64_t memory_type : 4;
#define IA32_VMX_BASIC_MEMORY_TYPE_BIT 50
#define IA32_VMX_BASIC_MEMORY_TYPE_FLAG 0x3C000000000000
#define IA32_VMX_BASIC_MEMORY_TYPE_MASK 0x0F
#define IA32_VMX_BASIC_MEMORY_TYPE(_) (((_) >> 50) & 0x0F)
/**
* @brief Whether the processor provides additional information for exits due to INS/OUTS
*
* [Bit 54] When set to 1, the processor reports information in the VM-exit instruction-information field on VM exits due
* to execution of the INS and OUTS instructions. This reporting is done only if this bit is read as 1.
*
* @see Vol3C[27.2.4(Information for VM Exits Due to Instruction Execution)]
*/
UINT64_t ins_outs_reporting : 1;
#define IA32_VMX_BASIC_INS_OUTS_REPORTING_BIT 54
#define IA32_VMX_BASIC_INS_OUTS_REPORTING_FLAG 0x40000000000000
#define IA32_VMX_BASIC_INS_OUTS_REPORTING_MASK 0x01
#define IA32_VMX_BASIC_INS_OUTS_REPORTING(_) (((_) >> 54) & 0x01)
/**
* @brief Whether default 1 bits in control MSRs (pin/proc/exit/entry) may be cleared to 0 and that 'true' control MSRs are
* supported
*
* [Bit 55] Is read as 1 if any VMX controls that default to 1 may be cleared to 0. It also reports support for the VMX
* capability MSRs IA32_VMX_TRUE_PINBASED_CTLS, IA32_VMX_TRUE_PROCBASED_CTLS, IA32_VMX_TRUE_EXIT_CTLS, and
* IA32_VMX_TRUE_ENTRY_CTLS.
*
* @see Vol3D[A.2(RESERVED CONTROLS AND DEFAULT SETTINGS)]
* @see Vol3D[A.3.1(Pin-Based VM-Execution Controls)]
* @see Vol3D[A.3.2(Primary Processor-Based VM-Execution Controls)]
* @see Vol3D[A.4(VM-EXIT CONTROLS)]
* @see Vol3D[A.5(VM-ENTRY CONTROLS)]
*/
UINT64_t vmx_controls : 1;
#define IA32_VMX_BASIC_VMX_CONTROLS_BIT 55
#define IA32_VMX_BASIC_VMX_CONTROLS_FLAG 0x80000000000000
#define IA32_VMX_BASIC_VMX_CONTROLS_MASK 0x01
#define IA32_VMX_BASIC_VMX_CONTROLS(_) (((_) >> 55) & 0x01)
UINT64_t reserved2 : 8;
};
UINT64_t flags;
} ia32_vmx_basic_register;
/**
* Capability Reporting Register of Pin-Based VM-Execution Controls.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.3.1(Pin-Based VM-Execution Controls)]
* @see Vol3C[24.6.1(Pin-Based VM-Execution Controls)] (reference)
*/
#define IA32_VMX_PINBASED_CTLS 0x00000481
typedef union
{
struct
{
/**
* @brief External interrupts cause VM-exits if set; otherwise dispatched through the guest's IDT
*
* [Bit 0] If this control is 1, external interrupts cause VM exits. Otherwise, they are delivered normally through the
* guest interrupt-descriptor table (IDT). If this control is 1, the value of RFLAGS.IF does not affect interrupt blocking.
*/
UINT64_t external_interrupt_exiting : 1;
#define IA32_VMX_PINBASED_CTLS_EXTERNAL_INTERRUPT_EXITING_BIT 0
#define IA32_VMX_PINBASED_CTLS_EXTERNAL_INTERRUPT_EXITING_FLAG 0x01
#define IA32_VMX_PINBASED_CTLS_EXTERNAL_INTERRUPT_EXITING_MASK 0x01
#define IA32_VMX_PINBASED_CTLS_EXTERNAL_INTERRUPT_EXITING(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 2;
/**
* @brief Non-maskable interrupts cause VM-exits if set; otherwise dispatched through the guest's IDT
*
* [Bit 3] If this control is 1, non-maskable interrupts (NMIs) cause VM exits. Otherwise, they are delivered normally
* using descriptor 2 of the IDT. This control also determines interactions between IRET and blocking by NMI.
*
* @see Vol3C[25.3(CHANGES TO INSTRUCTION BEHAVIOR IN VMX NON-ROOT OPERATION)]
*/
UINT64_t nmi_exiting : 1;
#define IA32_VMX_PINBASED_CTLS_NMI_EXITING_BIT 3
#define IA32_VMX_PINBASED_CTLS_NMI_EXITING_FLAG 0x08
#define IA32_VMX_PINBASED_CTLS_NMI_EXITING_MASK 0x01
#define IA32_VMX_PINBASED_CTLS_NMI_EXITING(_) (((_) >> 3) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief Virtual NMIs
*
* [Bit 5] If this control is 1, NMIs are never blocked and the "blocking by NMI" bit (bit 3) in the interruptibility-state
* field indicates "virtual-NMI blocking". This control also interacts with the "NMI-window exiting" VM-execution control.
*
* @see Vol3C[24.6.2(Processor-Based VM-Execution Controls)]
*/
UINT64_t virtual_nmi : 1;
#define IA32_VMX_PINBASED_CTLS_VIRTUAL_NMI_BIT 5
#define IA32_VMX_PINBASED_CTLS_VIRTUAL_NMI_FLAG 0x20
#define IA32_VMX_PINBASED_CTLS_VIRTUAL_NMI_MASK 0x01
#define IA32_VMX_PINBASED_CTLS_VIRTUAL_NMI(_) (((_) >> 5) & 0x01)
/**
* @brief Activate VMX preemption timer
*
* [Bit 6] If this control is 1, the VMX-preemption timer counts down in VMX non-root operation. A VM exit occurs when the
* timer counts down to zero.
*
* @see Vol3C[25.5.1(VMX-Preemption Timer)]
* @see Vol3C[25.2(OTHER CAUSES OF VM EXITS)]
*/
UINT64_t activate_vmx_preemption_timer : 1;
#define IA32_VMX_PINBASED_CTLS_ACTIVATE_VMX_PREEMPTION_TIMER_BIT 6
#define IA32_VMX_PINBASED_CTLS_ACTIVATE_VMX_PREEMPTION_TIMER_FLAG 0x40
#define IA32_VMX_PINBASED_CTLS_ACTIVATE_VMX_PREEMPTION_TIMER_MASK 0x01
#define IA32_VMX_PINBASED_CTLS_ACTIVATE_VMX_PREEMPTION_TIMER(_) (((_) >> 6) & 0x01)
/**
* @brief Process interrupts with the posted-interrupt notification vector
*
* [Bit 7] If this control is 1, the processor treats interrupts with the posted-interrupt notification vector specially,
* updating the virtual-APIC page with posted-interrupt requests.
*
* @see Vol3C[24.6.8(Controls for APIC Virtualization)]
* @see Vol3C[29.6(POSTED-INTERRUPT PROCESSING)]
*/
UINT64_t process_posted_interrupts : 1;
#define IA32_VMX_PINBASED_CTLS_PROCESS_POSTED_INTERRUPTS_BIT 7
#define IA32_VMX_PINBASED_CTLS_PROCESS_POSTED_INTERRUPTS_FLAG 0x80
#define IA32_VMX_PINBASED_CTLS_PROCESS_POSTED_INTERRUPTS_MASK 0x01
#define IA32_VMX_PINBASED_CTLS_PROCESS_POSTED_INTERRUPTS(_) (((_) >> 7) & 0x01)
UINT64_t reserved3 : 56;
};
UINT64_t flags;
} ia32_vmx_pinbased_ctls_register;
/**
* Capability Reporting Register of Primary Processor-Based VM-Execution Controls.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.3.2(Primary Processor-Based VM-Execution Controls)]
* @see Vol3C[24.6.2(Processor-Based VM-Execution Controls)] (reference)
*/
#define IA32_VMX_PROCBASED_CTLS 0x00000482
typedef union
{
struct
{
UINT64_t reserved1 : 2;
/**
* @brief VM-exit as soon as RFLAGS.IF=1 and no blocking is active
*
* [Bit 2] If this control is 1, a VM exit occurs at the beginning of any instruction if RFLAGS.IF = 1 and there are no
* other blocking of interrupts.
*
* @see Vol3C[24.4.2(Guest Non-Register State)]
*/
UINT64_t interrupt_window_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_INTERRUPT_WINDOW_EXITING_BIT 2
#define IA32_VMX_PROCBASED_CTLS_INTERRUPT_WINDOW_EXITING_FLAG 0x04
#define IA32_VMX_PROCBASED_CTLS_INTERRUPT_WINDOW_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_INTERRUPT_WINDOW_EXITING(_) (((_) >> 2) & 0x01)
/**
* @brief Use timestamp counter offset
*
* [Bit 3] This control determines whether executions of RDTSC, executions of RDTSCP, and executions of RDMSR that read
* from the IA32_TIME_STAMP_COUNTER MSR return a value modified by the TSC offset field.
*
* @see Vol3C[24.6.5(Time-Stamp Counter Offset and Multiplier)]
* @see Vol3C[25.3(CHANGES TO INSTRUCTION BEHAVIOR IN VMX NON-ROOT OPERATION)]
*/
UINT64_t use_tsc_offsetting : 1;
#define IA32_VMX_PROCBASED_CTLS_USE_TSC_OFFSETTING_BIT 3
#define IA32_VMX_PROCBASED_CTLS_USE_TSC_OFFSETTING_FLAG 0x08
#define IA32_VMX_PROCBASED_CTLS_USE_TSC_OFFSETTING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_USE_TSC_OFFSETTING(_) (((_) >> 3) & 0x01)
UINT64_t reserved2 : 3;
/**
* @brief VM-exit when executing the HLT instruction
*
* [Bit 7] This control determines whether executions of HLT cause VM exits.
*/
UINT64_t hlt_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_HLT_EXITING_BIT 7
#define IA32_VMX_PROCBASED_CTLS_HLT_EXITING_FLAG 0x80
#define IA32_VMX_PROCBASED_CTLS_HLT_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_HLT_EXITING(_) (((_) >> 7) & 0x01)
UINT64_t reserved3 : 1;
/**
* @brief VM-exit when executing the INVLPG instruction
*
* [Bit 9] This control determines whether executions of INVLPG cause VM exits.
*/
UINT64_t invlpg_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_INVLPG_EXITING_BIT 9
#define IA32_VMX_PROCBASED_CTLS_INVLPG_EXITING_FLAG 0x200
#define IA32_VMX_PROCBASED_CTLS_INVLPG_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_INVLPG_EXITING(_) (((_) >> 9) & 0x01)
/**
* @brief VM-exit when executing the MWAIT instruction
*
* [Bit 10] This control determines whether executions of MWAIT cause VM exits.
*/
UINT64_t mwait_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_MWAIT_EXITING_BIT 10
#define IA32_VMX_PROCBASED_CTLS_MWAIT_EXITING_FLAG 0x400
#define IA32_VMX_PROCBASED_CTLS_MWAIT_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_MWAIT_EXITING(_) (((_) >> 10) & 0x01)
/**
* @brief VM-exit when executing the RDPMC instruction
*
* [Bit 11] This control determines whether executions of RDPMC cause VM exits.
*/
UINT64_t rdpmc_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_RDPMC_EXITING_BIT 11
#define IA32_VMX_PROCBASED_CTLS_RDPMC_EXITING_FLAG 0x800
#define IA32_VMX_PROCBASED_CTLS_RDPMC_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_RDPMC_EXITING(_) (((_) >> 11) & 0x01)
/**
* @brief VM-exit when executing the RDTSC/RDTSCP instruction
*
* [Bit 12] This control determines whether executions of RDTSC and RDTSCP cause VM exits.
*/
UINT64_t rdtsc_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_RDTSC_EXITING_BIT 12
#define IA32_VMX_PROCBASED_CTLS_RDTSC_EXITING_FLAG 0x1000
#define IA32_VMX_PROCBASED_CTLS_RDTSC_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_RDTSC_EXITING(_) (((_) >> 12) & 0x01)
UINT64_t reserved4 : 2;
/**
* @brief VM-exit when executing the MOV to CR3 instruction (forced to 1 on the 'first' VT-x capable CPUs; this actually
* includes the newest Nehalem CPUs)
*
* [Bit 15] In conjunction with the CR3-target controls, this control determines whether executions of MOV to CR3 cause VM
* exits. The first processors to support the virtual-machine extensions supported only the 1-setting of this control.
*
* @see Vol3C[24.6.7(CR3-Target Controls)]
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
UINT64_t cr3_load_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_CR3_LOAD_EXITING_BIT 15
#define IA32_VMX_PROCBASED_CTLS_CR3_LOAD_EXITING_FLAG 0x8000
#define IA32_VMX_PROCBASED_CTLS_CR3_LOAD_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_CR3_LOAD_EXITING(_) (((_) >> 15) & 0x01)
/**
* @brief VM-exit when executing the MOV from CR3 instruction (forced to 1 on the 'first' VT-x capable CPUs; this actually
* includes the newest Nehalem CPUs)
*
* [Bit 16] This control determines whether executions of MOV from CR3 cause VM exits. The first processors to support the
* virtual-machine extensions supported only the 1-setting of this control.
*/
UINT64_t cr3_store_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_CR3_STORE_EXITING_BIT 16
#define IA32_VMX_PROCBASED_CTLS_CR3_STORE_EXITING_FLAG 0x10000
#define IA32_VMX_PROCBASED_CTLS_CR3_STORE_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_CR3_STORE_EXITING(_) (((_) >> 16) & 0x01)
UINT64_t reserved5 : 2;
/**
* @brief VM-exit on CR8 loads
*
* [Bit 19] This control determines whether executions of MOV to CR8 cause VM exits.
*/
UINT64_t cr8_load_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_CR8_LOAD_EXITING_BIT 19
#define IA32_VMX_PROCBASED_CTLS_CR8_LOAD_EXITING_FLAG 0x80000
#define IA32_VMX_PROCBASED_CTLS_CR8_LOAD_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_CR8_LOAD_EXITING(_) (((_) >> 19) & 0x01)
/**
* @brief VM-exit on CR8 stores
*
* [Bit 20] This control determines whether executions of MOV from CR8 cause VM exits.
*/
UINT64_t cr8_store_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_CR8_STORE_EXITING_BIT 20
#define IA32_VMX_PROCBASED_CTLS_CR8_STORE_EXITING_FLAG 0x100000
#define IA32_VMX_PROCBASED_CTLS_CR8_STORE_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_CR8_STORE_EXITING(_) (((_) >> 20) & 0x01)
/**
* @brief Use TPR shadow
*
* [Bit 21] Setting this control to 1 enables TPR virtualization and other APIC-virtualization features.
*
* @see Vol3C[29(APIC VIRTUALIZATION AND VIRTUAL INTERRUPTS)]
*/
UINT64_t use_tpr_shadow : 1;
#define IA32_VMX_PROCBASED_CTLS_USE_TPR_SHADOW_BIT 21
#define IA32_VMX_PROCBASED_CTLS_USE_TPR_SHADOW_FLAG 0x200000
#define IA32_VMX_PROCBASED_CTLS_USE_TPR_SHADOW_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_USE_TPR_SHADOW(_) (((_) >> 21) & 0x01)
/**
* @brief VM-exit when virtual NMI blocking is disabled
*
* [Bit 22] If this control is 1, a VM exit occurs at the beginning of any instruction if there is no virtual-NMI blocking.
*
* @see Vol3C[24.4.2(Guest Non-Register State)]
*/
UINT64_t nmi_window_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_NMI_WINDOW_EXITING_BIT 22
#define IA32_VMX_PROCBASED_CTLS_NMI_WINDOW_EXITING_FLAG 0x400000
#define IA32_VMX_PROCBASED_CTLS_NMI_WINDOW_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_NMI_WINDOW_EXITING(_) (((_) >> 22) & 0x01)
/**
* @brief VM-exit when executing a MOV DRx instruction
*
* [Bit 23] This control determines whether executions of MOV DR cause VM exits.
*/
UINT64_t mov_dr_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_MOV_DR_EXITING_BIT 23
#define IA32_VMX_PROCBASED_CTLS_MOV_DR_EXITING_FLAG 0x800000
#define IA32_VMX_PROCBASED_CTLS_MOV_DR_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_MOV_DR_EXITING(_) (((_) >> 23) & 0x01)
/**
* @brief VM-exit when executing IO instructions
*
* [Bit 24] This control determines whether executions of I/O instructions (IN, INS/INSB/INSW/INSD, OUT, and
* OUTS/OUTSB/OUTSW/OUTSD) cause VM exits.
*/
UINT64_t unconditional_io_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_UNCONDITIONAL_IO_EXITING_BIT 24
#define IA32_VMX_PROCBASED_CTLS_UNCONDITIONAL_IO_EXITING_FLAG 0x1000000
#define IA32_VMX_PROCBASED_CTLS_UNCONDITIONAL_IO_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_UNCONDITIONAL_IO_EXITING(_) (((_) >> 24) & 0x01)
/**
* @brief Use IO bitmaps
*
* [Bit 25] This control determines whether I/O bitmaps are used to restrict executions of I/O instructions For this
* control, "0" means "do not use I/O bitmaps" and "1" means "use I/O bitmaps." If the I/O bitmaps are used, the setting of
* the "unconditional I/O exiting" control is ignored.
*
* @see Vol3C[24.6.4(I/O-Bitmap Addresses)]
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
UINT64_t use_io_bitmaps : 1;
#define IA32_VMX_PROCBASED_CTLS_USE_IO_BITMAPS_BIT 25
#define IA32_VMX_PROCBASED_CTLS_USE_IO_BITMAPS_FLAG 0x2000000
#define IA32_VMX_PROCBASED_CTLS_USE_IO_BITMAPS_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_USE_IO_BITMAPS(_) (((_) >> 25) & 0x01)
UINT64_t reserved6 : 1;
/**
* @brief Monitor trap flag
*
* [Bit 27] If this control is 1, the monitor trap flag debugging feature is enabled.
*
* @see Vol3C[25.5.2(Monitor Trap Flag)]
*/
UINT64_t monitor_trap_flag : 1;
#define IA32_VMX_PROCBASED_CTLS_MONITOR_TRAP_FLAG_BIT 27
#define IA32_VMX_PROCBASED_CTLS_MONITOR_TRAP_FLAG_FLAG 0x8000000
#define IA32_VMX_PROCBASED_CTLS_MONITOR_TRAP_FLAG_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_MONITOR_TRAP_FLAG(_) (((_) >> 27) & 0x01)
/**
* @brief Use MSR bitmaps
*
* [Bit 28] This control determines whether MSR bitmaps are used to control execution of the RDMSR and WRMSR instructions.
* For this control, "0" means "do not use MSR bitmaps" and "1" means "use MSR bitmaps." If the MSR bitmaps are not used,
* all executions of the RDMSR and WRMSR instructions cause VM exits.
*
* @see Vol3C[24.6.9(MSR-Bitmap Address)]
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
UINT64_t use_msr_bitmaps : 1;
#define IA32_VMX_PROCBASED_CTLS_USE_MSR_BITMAPS_BIT 28
#define IA32_VMX_PROCBASED_CTLS_USE_MSR_BITMAPS_FLAG 0x10000000
#define IA32_VMX_PROCBASED_CTLS_USE_MSR_BITMAPS_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_USE_MSR_BITMAPS(_) (((_) >> 28) & 0x01)
/**
* @brief VM-exit when executing the MONITOR instruction
*
* [Bit 29] This control determines whether executions of MONITOR cause VM exits.
*/
UINT64_t monitor_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_MONITOR_EXITING_BIT 29
#define IA32_VMX_PROCBASED_CTLS_MONITOR_EXITING_FLAG 0x20000000
#define IA32_VMX_PROCBASED_CTLS_MONITOR_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_MONITOR_EXITING(_) (((_) >> 29) & 0x01)
/**
* @brief VM-exit when executing the PAUSE instruction
*
* [Bit 30] This control determines whether executions of PAUSE cause VM exits.
*/
UINT64_t pause_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS_PAUSE_EXITING_BIT 30
#define IA32_VMX_PROCBASED_CTLS_PAUSE_EXITING_FLAG 0x40000000
#define IA32_VMX_PROCBASED_CTLS_PAUSE_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_PAUSE_EXITING(_) (((_) >> 30) & 0x01)
/**
* @brief Determines whether the secondary processor based VM-execution controls are used
*
* [Bit 31] This control determines whether the secondary processor-based VM-execution controls are used. If this control
* is 0, the logical processor operates as if all the secondary processor-based VM-execution controls were also 0.
*/
UINT64_t activate_secondary_controls : 1;
#define IA32_VMX_PROCBASED_CTLS_ACTIVATE_SECONDARY_CONTROLS_BIT 31
#define IA32_VMX_PROCBASED_CTLS_ACTIVATE_SECONDARY_CONTROLS_FLAG 0x80000000
#define IA32_VMX_PROCBASED_CTLS_ACTIVATE_SECONDARY_CONTROLS_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS_ACTIVATE_SECONDARY_CONTROLS(_) (((_) >> 31) & 0x01)
UINT64_t reserved7 : 32;
};
UINT64_t flags;
} ia32_vmx_procbased_ctls_register;
/**
* Capability Reporting Register of VM-Exit Controls.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.4(VM-EXIT CONTROLS)]
* @see Vol3C[24.7.1(VM-Exit Controls)] (reference)
*/
#define IA32_VMX_EXIT_CTLS 0x00000483
typedef union
{
struct
{
UINT64_t reserved1 : 2;
/**
* @brief Save guest debug controls (dr7 & IA32_DEBUGCTL_MSR) (forced to 1 on the 'first' VT-x capable CPUs; this actually
* includes the newest Nehalem CPUs)
*
* [Bit 2] This control determines whether DR7 and the IA32_DEBUGCTL MSR are saved on VM exit. The first processors to
* support the virtual-machine extensions supported only the 1-setting of this control.
*/
UINT64_t save_debug_controls : 1;
#define IA32_VMX_EXIT_CTLS_SAVE_DEBUG_CONTROLS_BIT 2
#define IA32_VMX_EXIT_CTLS_SAVE_DEBUG_CONTROLS_FLAG 0x04
#define IA32_VMX_EXIT_CTLS_SAVE_DEBUG_CONTROLS_MASK 0x01
#define IA32_VMX_EXIT_CTLS_SAVE_DEBUG_CONTROLS(_) (((_) >> 2) & 0x01)
UINT64_t reserved2 : 6;
/**
* @brief Return to long mode after a VM-exit
*
* [Bit 9] On processors that support Intel 64 architecture, this control determines whether a logical processor is in
* 64-bit mode after the next VM exit. Its value is loaded into CS.L, IA32_EFER.LME, and IA32_EFER.LMA on every VM exit.1
* This control must be 0 on processors that do not support Intel 64 architecture.
*/
UINT64_t host_address_space_size : 1;
#define IA32_VMX_EXIT_CTLS_HOST_ADDRESS_SPACE_SIZE_BIT 9
#define IA32_VMX_EXIT_CTLS_HOST_ADDRESS_SPACE_SIZE_FLAG 0x200
#define IA32_VMX_EXIT_CTLS_HOST_ADDRESS_SPACE_SIZE_MASK 0x01
#define IA32_VMX_EXIT_CTLS_HOST_ADDRESS_SPACE_SIZE(_) (((_) >> 9) & 0x01)
UINT64_t reserved3 : 2;
/**
* @brief Whether the IA32_PERF_GLOBAL_CTRL MSR is loaded on VM-exit
*
* [Bit 12] This control determines whether the IA32_PERF_GLOBAL_CTRL MSR is loaded on VM exit.
*/
UINT64_t load_ia32_perf_global_ctrl : 1;
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_BIT 12
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_FLAG 0x1000
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_MASK 0x01
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL(_) (((_) >> 12) & 0x01)
UINT64_t reserved4 : 2;
/**
* @brief Acknowledge external interrupts with the irq controller if one caused a VM-exit
*
* [Bit 15] This control affects VM exits due to external interrupts:
* - If such a VM exit occurs and this control is 1, the logical processor acknowledges the interrupt controller, acquiring
* the interrupt's vector. The vector is stored in the VM-exit interruption-information field, which is marked valid.
* - If such a VM exit occurs and this control is 0, the interrupt is not acknowledged and the VM-exit
* interruption-information field is marked invalid.
*/
UINT64_t acknowledge_interrupt_on_exit : 1;
#define IA32_VMX_EXIT_CTLS_ACKNOWLEDGE_INTERRUPT_ON_EXIT_BIT 15
#define IA32_VMX_EXIT_CTLS_ACKNOWLEDGE_INTERRUPT_ON_EXIT_FLAG 0x8000
#define IA32_VMX_EXIT_CTLS_ACKNOWLEDGE_INTERRUPT_ON_EXIT_MASK 0x01
#define IA32_VMX_EXIT_CTLS_ACKNOWLEDGE_INTERRUPT_ON_EXIT(_) (((_) >> 15) & 0x01)
UINT64_t reserved5 : 2;
/**
* @brief Whether the guest IA32_PAT MSR is saved on VM-exit
*
* [Bit 18] This control determines whether the IA32_PAT MSR is saved on VM exit.
*/
UINT64_t save_ia32_pat : 1;
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_PAT_BIT 18
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_PAT_FLAG 0x40000
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_PAT_MASK 0x01
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_PAT(_) (((_) >> 18) & 0x01)
/**
* @brief Whether the host IA32_PAT MSR is loaded on VM-exit
*
* [Bit 19] This control determines whether the IA32_PAT MSR is loaded on VM exit.
*/
UINT64_t load_ia32_pat : 1;
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PAT_BIT 19
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PAT_FLAG 0x80000
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PAT_MASK 0x01
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_PAT(_) (((_) >> 19) & 0x01)
/**
* @brief Whether the guest IA32_EFER MSR is saved on VM-exit
*
* [Bit 20] This control determines whether the IA32_EFER MSR is saved on VM exit.
*/
UINT64_t save_ia32_efer : 1;
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_EFER_BIT 20
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_EFER_FLAG 0x100000
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_EFER_MASK 0x01
#define IA32_VMX_EXIT_CTLS_SAVE_IA32_EFER(_) (((_) >> 20) & 0x01)
/**
* @brief Whether the host IA32_EFER MSR is loaded on VM-exit
*
* [Bit 21] This control determines whether the IA32_EFER MSR is loaded on VM exit.
*/
UINT64_t load_ia32_efer : 1;
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_EFER_BIT 21
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_EFER_FLAG 0x200000
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_EFER_MASK 0x01
#define IA32_VMX_EXIT_CTLS_LOAD_IA32_EFER(_) (((_) >> 21) & 0x01)
/**
* @brief Whether the value of the VMX preemption timer is saved on every VM-exit
*
* [Bit 22] This control determines whether the value of the VMX-preemption timer is saved on VM exit.
*/
UINT64_t save_vmx_preemption_timer_value : 1;
#define IA32_VMX_EXIT_CTLS_SAVE_VMX_PREEMPTION_TIMER_VALUE_BIT 22
#define IA32_VMX_EXIT_CTLS_SAVE_VMX_PREEMPTION_TIMER_VALUE_FLAG 0x400000
#define IA32_VMX_EXIT_CTLS_SAVE_VMX_PREEMPTION_TIMER_VALUE_MASK 0x01
#define IA32_VMX_EXIT_CTLS_SAVE_VMX_PREEMPTION_TIMER_VALUE(_) (((_) >> 22) & 0x01)
/**
* [Bit 23] This control determines whether the IA32_BNDCFGS MSR is cleared on VM exit.
*/
UINT64_t clear_ia32_bndcfgs : 1;
#define IA32_VMX_EXIT_CTLS_CLEAR_IA32_BNDCFGS_BIT 23
#define IA32_VMX_EXIT_CTLS_CLEAR_IA32_BNDCFGS_FLAG 0x800000
#define IA32_VMX_EXIT_CTLS_CLEAR_IA32_BNDCFGS_MASK 0x01
#define IA32_VMX_EXIT_CTLS_CLEAR_IA32_BNDCFGS(_) (((_) >> 23) & 0x01)
/**
* [Bit 24] If this control is 1, Intel Processor Trace does not produce a paging information packet (PIP) on a VM exit or
* a VMCS packet on an SMM VM exit.
*
* @see Vol3C[35(INTEL(R) PROCESSOR TRACE)]
*/
UINT64_t conceal_vmx_from_pt : 1;
#define IA32_VMX_EXIT_CTLS_CONCEAL_VMX_FROM_PT_BIT 24
#define IA32_VMX_EXIT_CTLS_CONCEAL_VMX_FROM_PT_FLAG 0x1000000
#define IA32_VMX_EXIT_CTLS_CONCEAL_VMX_FROM_PT_MASK 0x01
#define IA32_VMX_EXIT_CTLS_CONCEAL_VMX_FROM_PT(_) (((_) >> 24) & 0x01)
UINT64_t reserved6 : 39;
};
UINT64_t flags;
} ia32_vmx_exit_ctls_register;
/**
* Capability Reporting Register of VM-Entry Controls.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.5(VM-ENTRY CONTROLS)]
* @see Vol3D[24.8.1(VM-Entry Controls)] (reference)
*/
#define IA32_VMX_ENTRY_CTLS 0x00000484
typedef union
{
struct
{
UINT64_t reserved1 : 2;
/**
* @brief Load guest debug controls (dr7 & IA32_DEBUGCTL_MSR) (forced to 1 on the 'first' VT-x capable CPUs; this actually
* includes the newest Nehalem CPUs)
*
* [Bit 2] This control determines whether DR7 and the IA32_DEBUGCTL MSR are loaded on VM entry. The first processors to
* support the virtual-machine extensions supported only the 1-setting of this control.
*/
UINT64_t load_debug_controls : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_DEBUG_CONTROLS_BIT 2
#define IA32_VMX_ENTRY_CTLS_LOAD_DEBUG_CONTROLS_FLAG 0x04
#define IA32_VMX_ENTRY_CTLS_LOAD_DEBUG_CONTROLS_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_DEBUG_CONTROLS(_) (((_) >> 2) & 0x01)
UINT64_t reserved2 : 6;
/**
* @brief 64 bits guest mode. Must be 0 for CPUs that don't support AMD64
*
* [Bit 9] On processors that support Intel 64 architecture, this control determines whether the logical processor is in
* IA-32e mode after VM entry. Its value is loaded into IA32_EFER.LMA as part of VM entry. This control must be 0 on
* processors that do not support Intel 64 architecture.
*/
UINT64_t ia32e_mode_guest : 1;
#define IA32_VMX_ENTRY_CTLS_IA32E_MODE_GUEST_BIT 9
#define IA32_VMX_ENTRY_CTLS_IA32E_MODE_GUEST_FLAG 0x200
#define IA32_VMX_ENTRY_CTLS_IA32E_MODE_GUEST_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_IA32E_MODE_GUEST(_) (((_) >> 9) & 0x01)
/**
* @brief In SMM mode after VM-entry
*
* [Bit 10] This control determines whether the logical processor is in system-management mode (SMM) after VM entry. This
* control must be 0 for any VM entry from outside SMM.
*/
UINT64_t entry_to_smm : 1;
#define IA32_VMX_ENTRY_CTLS_ENTRY_TO_SMM_BIT 10
#define IA32_VMX_ENTRY_CTLS_ENTRY_TO_SMM_FLAG 0x400
#define IA32_VMX_ENTRY_CTLS_ENTRY_TO_SMM_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_ENTRY_TO_SMM(_) (((_) >> 10) & 0x01)
/**
* @brief Disable dual treatment of SMI and SMM; must be zero for VM-entry outside of SMM
*
* [Bit 11] If set to 1, the default treatment of SMIs and SMM is in effect after the VM entry. This control must be 0 for
* any VM entry from outside SMM
*
* @see Vol3C[34.15.7(Deactivating the Dual-Monitor Treatment)]
*/
UINT64_t deactivate_dual_monitor_treatment : 1;
#define IA32_VMX_ENTRY_CTLS_DEACTIVATE_DUAL_MONITOR_TREATMENT_BIT 11
#define IA32_VMX_ENTRY_CTLS_DEACTIVATE_DUAL_MONITOR_TREATMENT_FLAG 0x800
#define IA32_VMX_ENTRY_CTLS_DEACTIVATE_DUAL_MONITOR_TREATMENT_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_DEACTIVATE_DUAL_MONITOR_TREATMENT(_) (((_) >> 11) & 0x01)
UINT64_t reserved3 : 1;
/**
* @brief Whether the guest IA32_PERF_GLOBAL_CTRL MSR is loaded on VM-entry
*
* [Bit 13] This control determines whether the IA32_PERF_GLOBAL_CTRL MSR is loaded on VM entry.
*/
UINT64_t load_ia32_perf_global_ctrl : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_BIT 13
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_FLAG 0x2000
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PERF_GLOBAL_CTRL(_) (((_) >> 13) & 0x01)
/**
* @brief Whether the guest IA32_PAT MSR is loaded on VM-entry
*
* [Bit 14] This control determines whether the IA32_PAT MSR is loaded on VM entry.
*/
UINT64_t load_ia32_pat : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PAT_BIT 14
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PAT_FLAG 0x4000
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PAT_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_PAT(_) (((_) >> 14) & 0x01)
/**
* @brief Whether the guest IA32_EFER MSR is loaded on VM-entry
*
* [Bit 15] This control determines whether the IA32_EFER MSR is loaded on VM entry.
*/
UINT64_t load_ia32_efer : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_EFER_BIT 15
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_EFER_FLAG 0x8000
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_EFER_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_EFER(_) (((_) >> 15) & 0x01)
/**
* [Bit 16] This control determines whether the IA32_BNDCFGS MSR is loaded on VM entry.
*/
UINT64_t load_ia32_bndcfgs : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_BNDCFGS_BIT 16
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_BNDCFGS_FLAG 0x10000
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_BNDCFGS_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_BNDCFGS(_) (((_) >> 16) & 0x01)
/**
* [Bit 17] If this control is 1, Intel Processor Trace does not produce a paging information packet (PIP) on a VM entry or
* a VMCS packet on a VM entry that returns from SMM.
*
* @see Vol3C[35(INTEL(R) PROCESSOR TRACE)]
*/
UINT64_t conceal_vmx_from_pt : 1;
#define IA32_VMX_ENTRY_CTLS_CONCEAL_VMX_FROM_PT_BIT 17
#define IA32_VMX_ENTRY_CTLS_CONCEAL_VMX_FROM_PT_FLAG 0x20000
#define IA32_VMX_ENTRY_CTLS_CONCEAL_VMX_FROM_PT_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_CONCEAL_VMX_FROM_PT(_) (((_) >> 17) & 0x01)
/**
* [Bit 18] This control determines whether the IA32_RTIT_CTL MSR is loaded on VM entry.
*/
UINT64_t load_ia32_rtit_ctl : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_RTIT_CTL_BIT 18
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_RTIT_CTL_FLAG 0x40000
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_RTIT_CTL_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_IA32_RTIT_CTL(_) (((_) >> 18) & 0x01)
UINT64_t reserved4 : 1;
/**
* [Bit 20] This control determines whether CET-related MSRs and SPP are loaded on VM entry.
*/
UINT64_t load_cet_state : 1;
#define IA32_VMX_ENTRY_CTLS_LOAD_CET_STATE_BIT 20
#define IA32_VMX_ENTRY_CTLS_LOAD_CET_STATE_FLAG 0x100000
#define IA32_VMX_ENTRY_CTLS_LOAD_CET_STATE_MASK 0x01
#define IA32_VMX_ENTRY_CTLS_LOAD_CET_STATE(_) (((_) >> 20) & 0x01)
UINT64_t reserved5 : 43;
};
UINT64_t flags;
} ia32_vmx_entry_ctls_register;
/**
* Reporting Register of Miscellaneous VMX Capabilities.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.6(MISCELLANEOUS DATA)]
* @see Vol3D[A.6(Miscellaneous Data)] (reference)
*/
#define IA32_VMX_MISC 0x00000485
typedef union
{
struct
{
/**
* @brief Relationship between the preemption timer and tsc; count down every time bit x of the tsc changes
*
* [Bits 4:0] Report a value X that specifies the relationship between the rate of the VMX-preemption timer and that of the
* timestamp counter (TSC). Specifically, the VMX-preemption timer (if it is active) counts down by 1 every time bit X in
* the TSC changes due to a TSC increment.
*/
UINT64_t preemption_timer_tsc_relationship : 5;
#define IA32_VMX_MISC_PREEMPTION_TIMER_TSC_RELATIONSHIP_BIT 0
#define IA32_VMX_MISC_PREEMPTION_TIMER_TSC_RELATIONSHIP_FLAG 0x1F
#define IA32_VMX_MISC_PREEMPTION_TIMER_TSC_RELATIONSHIP_MASK 0x1F
#define IA32_VMX_MISC_PREEMPTION_TIMER_TSC_RELATIONSHIP(_) (((_) >> 0) & 0x1F)
/**
* @brief Whether VM-exit stores EFER.LMA into the "IA32e mode guest" field
*
* [Bit 5] When set to 1, VM exits store the value of IA32_EFER.LMA into the "IA-32e mode guest" VM-entry control. This bit
* is read as 1 on any logical processor that supports the 1-setting of the "unrestricted guest" VM-execution control.
*
* @see Vol3C[27.2(RECORDING VM-EXIT INFORMATION AND UPDATING VM-ENTRY CONTROL FIELDS)]
*/
UINT64_t store_efer_lma_on_vmexit : 1;
#define IA32_VMX_MISC_STORE_EFER_LMA_ON_VMEXIT_BIT 5
#define IA32_VMX_MISC_STORE_EFER_LMA_ON_VMEXIT_FLAG 0x20
#define IA32_VMX_MISC_STORE_EFER_LMA_ON_VMEXIT_MASK 0x01
#define IA32_VMX_MISC_STORE_EFER_LMA_ON_VMEXIT(_) (((_) >> 5) & 0x01)
/**
* @brief Activity states supported by the implementation
*
* [Bits 8:6] Report, as a bitmap, the activity states supported by the implementation:
* - Bit 6 reports (if set) the support for activity state 1 (HLT).
* - Bit 7 reports (if set) the support for activity state 2 (shutdown).
* - Bit 8 reports (if set) the support for activity state 3 (wait-for-SIPI).
* If an activity state is not supported, the implementation causes a VM entry to fail if it attempts to establish that
* activity state. All implementations support VM entry to activity state 0 (active).
*/
UINT64_t activity_states : 3;
#define IA32_VMX_MISC_ACTIVITY_STATES_BIT 6
#define IA32_VMX_MISC_ACTIVITY_STATES_FLAG 0x1C0
#define IA32_VMX_MISC_ACTIVITY_STATES_MASK 0x07
#define IA32_VMX_MISC_ACTIVITY_STATES(_) (((_) >> 6) & 0x07)
UINT64_t reserved1 : 5;
/**
* @brief Intel Processor Trace (Intel PT) can be used in VMX operation
*
* [Bit 14] When set to 1, Intel(R) Processor Trace (Intel PT) can be used in VMX operation. If the processor supports Intel
* PT but does not allow it to be used in VMX operation, execution of VMXON clears IA32_RTIT_CTL.TraceEn; any attempt to
* write IA32_RTIT_CTL while in VMX operation (including VMX root operation) causes a general-protection exception.
*
* @see Vol3C[30.3(VMX INSTRUCTIONS | VMXON-Enter VMX Operation)]
*/
UINT64_t intel_pt_available_in_vmx : 1;
#define IA32_VMX_MISC_INTEL_PT_AVAILABLE_IN_VMX_BIT 14
#define IA32_VMX_MISC_INTEL_PT_AVAILABLE_IN_VMX_FLAG 0x4000
#define IA32_VMX_MISC_INTEL_PT_AVAILABLE_IN_VMX_MASK 0x01
#define IA32_VMX_MISC_INTEL_PT_AVAILABLE_IN_VMX(_) (((_) >> 14) & 0x01)
/**
* @brief Whether RDMSR can be used to read IA32_SMBASE_MSR in SMM
*
* [Bit 15] When set to 1, the RDMSR instruction can be used in system-management mode (SMM) to read the IA32_SMBASE MSR
* (MSR address 9EH).
*
* @see Vol3C[34.15.6.3(Saving Guest State)]
*/
UINT64_t rdmsr_can_read_ia32_smbase_msr_in_smm : 1;
#define IA32_VMX_MISC_RDMSR_CAN_READ_IA32_SMBASE_MSR_IN_SMM_BIT 15
#define IA32_VMX_MISC_RDMSR_CAN_READ_IA32_SMBASE_MSR_IN_SMM_FLAG 0x8000
#define IA32_VMX_MISC_RDMSR_CAN_READ_IA32_SMBASE_MSR_IN_SMM_MASK 0x01
#define IA32_VMX_MISC_RDMSR_CAN_READ_IA32_SMBASE_MSR_IN_SMM(_) (((_) >> 15) & 0x01)
/**
* @brief Number of CR3 target values supported by the processor (0-256)
*
* [Bits 24:16] Indicate the number of CR3-target values supported by the processor. This number is a value between 0 and
* 256, inclusive (bit 24 is set if and only if bits 23:16 are clear).
*/
UINT64_t cr3_target_count : 9;
#define IA32_VMX_MISC_CR3_TARGET_COUNT_BIT 16
#define IA32_VMX_MISC_CR3_TARGET_COUNT_FLAG 0x1FF0000
#define IA32_VMX_MISC_CR3_TARGET_COUNT_MASK 0x1FF
#define IA32_VMX_MISC_CR3_TARGET_COUNT(_) (((_) >> 16) & 0x1FF)
/**
* @brief Maximum number of MSRs in the VMCS. (N+1)*512
*
* [Bits 27:25] Used to compute the recommended maximum number of MSRs that should appear in the VM-exit MSR-store list,
* the VM-exit MSR-load list, or the VM-entry MSR-load list. Specifically, if the value bits 27:25 of IA32_VMX_MISC is N,
* then 512 * (N + 1) is the recommended maximum number of MSRs to be included in each list. If the limit is exceeded,
* undefined processor behavior may result (including a machine check during the VMX transition).
*/
UINT64_t max_number_of_msr : 3;
#define IA32_VMX_MISC_MAX_NUMBER_OF_MSR_BIT 25
#define IA32_VMX_MISC_MAX_NUMBER_OF_MSR_FLAG 0xE000000
#define IA32_VMX_MISC_MAX_NUMBER_OF_MSR_MASK 0x07
#define IA32_VMX_MISC_MAX_NUMBER_OF_MSR(_) (((_) >> 25) & 0x07)
/**
* @brief Whether bit 2 of IA32_SMM_MONITOR_CTL can be set to 1
*
* [Bit 28] When set to 1, bit 2 of the IA32_SMM_MONITOR_CTL can be set to 1. VMXOFF unblocks SMIs unless
* IA32_SMM_MONITOR_CTL[bit 2] is 1.
*
* @see Vol3C[34.14.4(VMXOFF and SMI Unblocking)]
*/
UINT64_t smm_monitor_ctl_b2 : 1;
#define IA32_VMX_MISC_SMM_MONITOR_CTL_B2_BIT 28
#define IA32_VMX_MISC_SMM_MONITOR_CTL_B2_FLAG 0x10000000
#define IA32_VMX_MISC_SMM_MONITOR_CTL_B2_MASK 0x01
#define IA32_VMX_MISC_SMM_MONITOR_CTL_B2(_) (((_) >> 28) & 0x01)
/**
* @brief Whether VMWRITE can be used to write VM-exit information fields
*
* [Bit 29] When set to 1, software can use VMWRITE to write to any supported field in the VMCS; otherwise, VMWRITE cannot
* be used to modify VM-exit information fields.
*/
UINT64_t vmwrite_vmexit_info : 1;
#define IA32_VMX_MISC_VMWRITE_VMEXIT_INFO_BIT 29
#define IA32_VMX_MISC_VMWRITE_VMEXIT_INFO_FLAG 0x20000000
#define IA32_VMX_MISC_VMWRITE_VMEXIT_INFO_MASK 0x01
#define IA32_VMX_MISC_VMWRITE_VMEXIT_INFO(_) (((_) >> 29) & 0x01)
/**
* [Bit 30] When set to 1, VM entry allows injection of a software interrupt, software exception, or privileged software
* exception with an instruction length of 0.
*/
UINT64_t zero_length_instruction_vmentry_injection : 1;
#define IA32_VMX_MISC_ZERO_LENGTH_INSTRUCTION_VMENTRY_INJECTION_BIT 30
#define IA32_VMX_MISC_ZERO_LENGTH_INSTRUCTION_VMENTRY_INJECTION_FLAG 0x40000000
#define IA32_VMX_MISC_ZERO_LENGTH_INSTRUCTION_VMENTRY_INJECTION_MASK 0x01
#define IA32_VMX_MISC_ZERO_LENGTH_INSTRUCTION_VMENTRY_INJECTION(_) (((_) >> 30) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief MSEG revision identifier used by the processor
*
* [Bits 63:32] Report the 32-bit MSEG revision identifier used by the processor.
*/
UINT64_t mseg_id : 32;
#define IA32_VMX_MISC_MSEG_ID_BIT 32
#define IA32_VMX_MISC_MSEG_ID_FLAG 0xFFFFFFFF00000000
#define IA32_VMX_MISC_MSEG_ID_MASK 0xFFFFFFFF
#define IA32_VMX_MISC_MSEG_ID(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_vmx_misc_register;
/**
* Capability Reporting Register of CR0 Bits Fixed to 0.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.7(VMX-FIXED BITS IN CR0)]
* @see Vol3D[A.7(VMX-Fixed Bits in CR0)] (reference)
*/
#define IA32_VMX_CR0_FIXED0 0x00000486
/**
* Capability Reporting Register of CR0 Bits Fixed to 1.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.7(VMX-FIXED BITS IN CR0)]
* @see Vol3D[A.7(VMX-Fixed Bits in CR0)] (reference)
*/
#define IA32_VMX_CR0_FIXED1 0x00000487
/**
* Capability Reporting Register of CR4 Bits Fixed to 0.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.8(VMX-FIXED BITS IN CR4)]
* @see Vol3D[A.8(VMX-Fixed Bits in CR4)] (reference)
*/
#define IA32_VMX_CR4_FIXED0 0x00000488
/**
* Capability Reporting Register of CR4 Bits Fixed to 1.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.8(VMX-FIXED BITS IN CR4)]
* @see Vol3D[A.8(VMX-Fixed Bits in CR4)] (reference)
*/
#define IA32_VMX_CR4_FIXED1 0x00000489
/**
* Capability Reporting Register of VMCS Field Enumeration.
*
* @remarks If CPUID.01H:ECX.[5] = 1
* @see Vol3D[A.9(VMCS ENUMERATION)]
* @see Vol3D[A.9(VMCS Enumeration)] (reference)
*/
#define IA32_VMX_VMCS_ENUM 0x0000048A
typedef union
{
struct
{
/**
* [Bit 0] Indicates access type.
*/
UINT64_t access_type : 1;
#define IA32_VMX_VMCS_ENUM_ACCESS_TYPE_BIT 0
#define IA32_VMX_VMCS_ENUM_ACCESS_TYPE_FLAG 0x01
#define IA32_VMX_VMCS_ENUM_ACCESS_TYPE_MASK 0x01
#define IA32_VMX_VMCS_ENUM_ACCESS_TYPE(_) (((_) >> 0) & 0x01)
/**
* [Bits 9:1] Highest index value used for any VMCS encoding.
*/
UINT64_t highest_index_value : 9;
#define IA32_VMX_VMCS_ENUM_HIGHEST_INDEX_VALUE_BIT 1
#define IA32_VMX_VMCS_ENUM_HIGHEST_INDEX_VALUE_FLAG 0x3FE
#define IA32_VMX_VMCS_ENUM_HIGHEST_INDEX_VALUE_MASK 0x1FF
#define IA32_VMX_VMCS_ENUM_HIGHEST_INDEX_VALUE(_) (((_) >> 1) & 0x1FF)
/**
* [Bits 11:10] Indicate the field's type.
*/
UINT64_t field_type : 2;
#define IA32_VMX_VMCS_ENUM_FIELD_TYPE_BIT 10
#define IA32_VMX_VMCS_ENUM_FIELD_TYPE_FLAG 0xC00
#define IA32_VMX_VMCS_ENUM_FIELD_TYPE_MASK 0x03
#define IA32_VMX_VMCS_ENUM_FIELD_TYPE(_) (((_) >> 10) & 0x03)
UINT64_t reserved1 : 1;
/**
* [Bits 14:13] Indicate the field's width.
*/
UINT64_t field_width : 2;
#define IA32_VMX_VMCS_ENUM_FIELD_WIDTH_BIT 13
#define IA32_VMX_VMCS_ENUM_FIELD_WIDTH_FLAG 0x6000
#define IA32_VMX_VMCS_ENUM_FIELD_WIDTH_MASK 0x03
#define IA32_VMX_VMCS_ENUM_FIELD_WIDTH(_) (((_) >> 13) & 0x03)
UINT64_t reserved2 : 49;
};
UINT64_t flags;
} ia32_vmx_vmcs_enum_register;
/**
* Capability Reporting Register of Secondary Processor-Based VM-Execution Controls.
*
* @remarks If ( CPUID.01H:ECX.[5] && IA32_VMX_PROCBASED_CTLS[63] )
* @see Vol3D[A.3.3(Secondary Processor-Based VM-Execution Controls)]
* @see Vol3D[24.6.2(Processor-Based VM-Execution Controls)] (reference)
*/
#define IA32_VMX_PROCBASED_CTLS2 0x0000048B
typedef union
{
struct
{
/**
* @brief Virtualize APIC access
*
* [Bit 0] If this control is 1, the logical processor treats specially accesses to the page with the APICaccess address.
*
* @see Vol3C[29.4(VIRTUALIZING MEMORY-MAPPED APIC ACCESSES)]
*/
UINT64_t virtualize_apic_accesses : 1;
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_APIC_ACCESSES_BIT 0
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_APIC_ACCESSES_FLAG 0x01
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_APIC_ACCESSES_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_APIC_ACCESSES(_) (((_) >> 0) & 0x01)
/**
* @brief EPT supported/enabled
*
* [Bit 1] If this control is 1, extended page tables (EPT) are enabled.
*
* @see Vol3C[28.2(THE EXTENDED PAGE TABLE MECHANISM (EPT))]
*/
UINT64_t enable_ept : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_EPT_BIT 1
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_EPT_FLAG 0x02
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_EPT_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_EPT(_) (((_) >> 1) & 0x01)
/**
* @brief Descriptor table instructions cause VM-exits
*
* [Bit 2] This control determines whether executions of LGDT, LIDT, LLDT, LTR, SGDT, SIDT, SLDT, and STR cause VM exits.
*/
UINT64_t descriptor_table_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_DESCRIPTOR_TABLE_EXITING_BIT 2
#define IA32_VMX_PROCBASED_CTLS2_DESCRIPTOR_TABLE_EXITING_FLAG 0x04
#define IA32_VMX_PROCBASED_CTLS2_DESCRIPTOR_TABLE_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_DESCRIPTOR_TABLE_EXITING(_) (((_) >> 2) & 0x01)
/**
* @brief RDTSCP supported/enabled
*
* [Bit 3] If this control is 0, any execution of RDTSCP causes an invalid-opcode exception (\#UD).
*/
UINT64_t enable_rdtscp : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_RDTSCP_BIT 3
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_RDTSCP_FLAG 0x08
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_RDTSCP_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_RDTSCP(_) (((_) >> 3) & 0x01)
/**
* @brief Virtualize x2APIC mode
*
* [Bit 4] If this control is 1, the logical processor treats specially RDMSR and WRMSR to APIC MSRs (in the range
* 800H-8FFH).
*
* @see Vol3C[29.5(VIRTUALIZING MSR-BASED APIC ACCESSES)]
*/
UINT64_t virtualize_x2apic_mode : 1;
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_X2APIC_MODE_BIT 4
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_X2APIC_MODE_FLAG 0x10
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_X2APIC_MODE_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_VIRTUALIZE_X2APIC_MODE(_) (((_) >> 4) & 0x01)
/**
* @brief VPID supported/enabled
*
* [Bit 5] If this control is 1, cached translations of linear addresses are associated with a virtualprocessor identifier
* (VPID).
*
* @see Vol3C[28.1(VIRTUAL PROCESSOR IDENTIFIERS (VPIDS))]
*/
UINT64_t enable_vpid : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VPID_BIT 5
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VPID_FLAG 0x20
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VPID_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VPID(_) (((_) >> 5) & 0x01)
/**
* @brief VM-exit when executing the WBINVD instruction
*
* [Bit 6] This control determines whether executions of WBINVD cause VM exits.
*/
UINT64_t wbinvd_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_WBINVD_EXITING_BIT 6
#define IA32_VMX_PROCBASED_CTLS2_WBINVD_EXITING_FLAG 0x40
#define IA32_VMX_PROCBASED_CTLS2_WBINVD_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_WBINVD_EXITING(_) (((_) >> 6) & 0x01)
/**
* @brief Unrestricted guest execution
*
* [Bit 7] This control determines whether guest software may run in unpaged protected mode or in realaddress mode.
*/
UINT64_t unrestricted_guest : 1;
#define IA32_VMX_PROCBASED_CTLS2_UNRESTRICTED_GUEST_BIT 7
#define IA32_VMX_PROCBASED_CTLS2_UNRESTRICTED_GUEST_FLAG 0x80
#define IA32_VMX_PROCBASED_CTLS2_UNRESTRICTED_GUEST_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_UNRESTRICTED_GUEST(_) (((_) >> 7) & 0x01)
/**
* @brief APIC register virtualization
*
* [Bit 8] If this control is 1, the logical processor virtualizes certain APIC accesses.
*
* @see Vol3C[29.4(VIRTUALIZING MEMORY-MAPPED APIC ACCESSES)]
* @see Vol3C[29.5(VIRTUALIZING MSR-BASED APIC ACCESSES)]
*/
UINT64_t apic_register_virtualization : 1;
#define IA32_VMX_PROCBASED_CTLS2_APIC_REGISTER_VIRTUALIZATION_BIT 8
#define IA32_VMX_PROCBASED_CTLS2_APIC_REGISTER_VIRTUALIZATION_FLAG 0x100
#define IA32_VMX_PROCBASED_CTLS2_APIC_REGISTER_VIRTUALIZATION_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_APIC_REGISTER_VIRTUALIZATION(_) (((_) >> 8) & 0x01)
/**
* @brief Virtual-interrupt delivery
*
* [Bit 9] This controls enables the evaluation and delivery of pending virtual interrupts as well as the emulation of
* writes to the APIC registers that control interrupt prioritization.
*/
UINT64_t virtual_interrupt_delivery : 1;
#define IA32_VMX_PROCBASED_CTLS2_VIRTUAL_INTERRUPT_DELIVERY_BIT 9
#define IA32_VMX_PROCBASED_CTLS2_VIRTUAL_INTERRUPT_DELIVERY_FLAG 0x200
#define IA32_VMX_PROCBASED_CTLS2_VIRTUAL_INTERRUPT_DELIVERY_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_VIRTUAL_INTERRUPT_DELIVERY(_) (((_) >> 9) & 0x01)
/**
* @brief A specified number of pause loops cause a VM-exit
*
* [Bit 10] This control determines whether a series of executions of PAUSE can cause a VM exit.
*
* @see Vol3C[24.6.13(Controls for PAUSE-Loop Exiting)]
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
UINT64_t pause_loop_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_PAUSE_LOOP_EXITING_BIT 10
#define IA32_VMX_PROCBASED_CTLS2_PAUSE_LOOP_EXITING_FLAG 0x400
#define IA32_VMX_PROCBASED_CTLS2_PAUSE_LOOP_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_PAUSE_LOOP_EXITING(_) (((_) >> 10) & 0x01)
/**
* @brief VM-exit when executing RDRAND instructions
*
* [Bit 11] This control determines whether executions of RDRAND cause VM exits.
*/
UINT64_t rdrand_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_RDRAND_EXITING_BIT 11
#define IA32_VMX_PROCBASED_CTLS2_RDRAND_EXITING_FLAG 0x800
#define IA32_VMX_PROCBASED_CTLS2_RDRAND_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_RDRAND_EXITING(_) (((_) >> 11) & 0x01)
/**
* @brief Enables INVPCID instructions
*
* [Bit 12] If this control is 0, any execution of INVPCID causes a \#UD.
*/
UINT64_t enable_invpcid : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_INVPCID_BIT 12
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_INVPCID_FLAG 0x1000
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_INVPCID_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_INVPCID(_) (((_) >> 12) & 0x01)
/**
* @brief Enables VMFUNC instructions
*
* [Bit 13] Setting this control to 1 enables use of the VMFUNC instruction in VMX non-root operation.
*
* @see Vol3C[25.5.5(VM Functions)]
*/
UINT64_t enable_vm_functions : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VM_FUNCTIONS_BIT 13
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VM_FUNCTIONS_FLAG 0x2000
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VM_FUNCTIONS_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_VM_FUNCTIONS(_) (((_) >> 13) & 0x01)
/**
* @brief Enables VMCS shadowing
*
* [Bit 14] If this control is 1, executions of VMREAD and VMWRITE in VMX non-root operation may access a shadow VMCS
* (instead of causing VM exits).
*
* @see {'Vol3C[24.10(VMCS TYPES': 'ORDINARY AND SHADOW)]'}
* @see Vol3C[30.3(VMX INSTRUCTIONS)]
*/
UINT64_t vmcs_shadowing : 1;
#define IA32_VMX_PROCBASED_CTLS2_VMCS_SHADOWING_BIT 14
#define IA32_VMX_PROCBASED_CTLS2_VMCS_SHADOWING_FLAG 0x4000
#define IA32_VMX_PROCBASED_CTLS2_VMCS_SHADOWING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_VMCS_SHADOWING(_) (((_) >> 14) & 0x01)
/**
* @brief Enables ENCLS VM-exits
*
* [Bit 15] If this control is 1, executions of ENCLS consult the ENCLS-exiting bitmap to determine whether the instruction
* causes a VM exit.
*
* @see Vol3C[24.6.16(ENCLS-Exiting Bitmap)]
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
UINT64_t enable_encls_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_ENCLS_EXITING_BIT 15
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_ENCLS_EXITING_FLAG 0x8000
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_ENCLS_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_ENCLS_EXITING(_) (((_) >> 15) & 0x01)
/**
* @brief VM-exit when executing RDSEED
*
* [Bit 16] This control determines whether executions of RDSEED cause VM exits.
*/
UINT64_t rdseed_exiting : 1;
#define IA32_VMX_PROCBASED_CTLS2_RDSEED_EXITING_BIT 16
#define IA32_VMX_PROCBASED_CTLS2_RDSEED_EXITING_FLAG 0x10000
#define IA32_VMX_PROCBASED_CTLS2_RDSEED_EXITING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_RDSEED_EXITING(_) (((_) >> 16) & 0x01)
/**
* @brief Enables page-modification logging
*
* [Bit 17] If this control is 1, an access to a guest-physical address that sets an EPT dirty bit first adds an entry to
* the page-modification log.
*
* @see Vol3C[28.2.5(Page-Modification Logging)]
*/
UINT64_t enable_pml : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_PML_BIT 17
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_PML_FLAG 0x20000
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_PML_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_PML(_) (((_) >> 17) & 0x01)
/**
* @brief Controls whether EPT-violations may cause
*
* [Bit 18] If this control is 1, EPT violations may cause virtualization exceptions (\#VE) instead of VM exits.
*
* @see Vol3C[25.5.6(Virtualization Exceptions)]
*/
UINT64_t ept_violation : 1;
#define IA32_VMX_PROCBASED_CTLS2_EPT_VIOLATION_BIT 18
#define IA32_VMX_PROCBASED_CTLS2_EPT_VIOLATION_FLAG 0x40000
#define IA32_VMX_PROCBASED_CTLS2_EPT_VIOLATION_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_EPT_VIOLATION(_) (((_) >> 18) & 0x01)
/**
* @brief Conceal VMX non-root operation from Intel processor trace (PT)
*
* [Bit 19] If this control is 1, Intel Processor Trace suppresses from PIPs an indication that the processor was in VMX
* non-root operation and omits a VMCS packet from any PSB+ produced in VMX nonroot operation.
*
* @see Vol3C[35(INTEL(R) PROCESSOR TRACE)]
*/
UINT64_t conceal_vmx_from_pt : 1;
#define IA32_VMX_PROCBASED_CTLS2_CONCEAL_VMX_FROM_PT_BIT 19
#define IA32_VMX_PROCBASED_CTLS2_CONCEAL_VMX_FROM_PT_FLAG 0x80000
#define IA32_VMX_PROCBASED_CTLS2_CONCEAL_VMX_FROM_PT_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_CONCEAL_VMX_FROM_PT(_) (((_) >> 19) & 0x01)
/**
* @brief Enables XSAVES/XRSTORS instructions
*
* [Bit 20] If this control is 0, any execution of XSAVES or XRSTORS causes a \#UD.
*/
UINT64_t enable_xsaves : 1;
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_XSAVES_BIT 20
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_XSAVES_FLAG 0x100000
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_XSAVES_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_ENABLE_XSAVES(_) (((_) >> 20) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 22] If this control is 1, EPT execute permissions are based on whether the linear address being accessed is
* supervisor mode or user mode.
*
* @see Vol3C[28(VMX SUPPORT FOR ADDRESS TRANSLATION)]
*/
UINT64_t mode_based_execute_control_for_ept : 1;
#define IA32_VMX_PROCBASED_CTLS2_MODE_BASED_EXECUTE_CONTROL_FOR_EPT_BIT 22
#define IA32_VMX_PROCBASED_CTLS2_MODE_BASED_EXECUTE_CONTROL_FOR_EPT_FLAG 0x400000
#define IA32_VMX_PROCBASED_CTLS2_MODE_BASED_EXECUTE_CONTROL_FOR_EPT_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_MODE_BASED_EXECUTE_CONTROL_FOR_EPT(_) (((_) >> 22) & 0x01)
UINT64_t reserved2 : 2;
/**
* @brief Use TSC scaling
*
* [Bit 25] This control determines whether executions of RDTSC, executions of RDTSCP, and executions of RDMSR that read
* from the IA32_TIME_STAMP_COUNTER MSR return a value modified by the TSC multiplier field.
*
* @see Vol3C[24.6.5(Time-Stamp Counter Offset and Multiplier)]
* @see Vol3C[25.3(CHANGES TO INSTRUCTION BEHAVIOR IN VMX NON-ROOT OPERATION)]
*/
UINT64_t use_tsc_scaling : 1;
#define IA32_VMX_PROCBASED_CTLS2_USE_TSC_SCALING_BIT 25
#define IA32_VMX_PROCBASED_CTLS2_USE_TSC_SCALING_FLAG 0x2000000
#define IA32_VMX_PROCBASED_CTLS2_USE_TSC_SCALING_MASK 0x01
#define IA32_VMX_PROCBASED_CTLS2_USE_TSC_SCALING(_) (((_) >> 25) & 0x01)
UINT64_t reserved3 : 38;
};
UINT64_t flags;
} ia32_vmx_procbased_ctls2_register;
/**
* Capability Reporting Register of EPT and VPID.
*
* @remarks If ( CPUID.01H:ECX.[5] && IA32_VMX_PROCBASED_CTLS[63] && (IA32_VMX_PROCBASED_CTLS2[33] ||
* IA32_VMX_PROCBASED_CTLS2[37]) )
* @see Vol3D[A.10(VPID AND EPT CAPABILITIES)]
* @see Vol3D[A.10(VPID and EPT Capabilities)] (reference)
*/
#define IA32_VMX_EPT_VPID_CAP 0x0000048C
typedef union
{
struct
{
/**
* [Bit 0] When set to 1, the processor supports execute-only translations by EPT. This support allows software to
* configure EPT paging-structure entries in which bits 1:0 are clear (indicating that data accesses are not allowed) and
* bit 2 is set (indicating that instruction fetches are allowed).
*/
UINT64_t execute_only_pages : 1;
#define IA32_VMX_EPT_VPID_CAP_EXECUTE_ONLY_PAGES_BIT 0
#define IA32_VMX_EPT_VPID_CAP_EXECUTE_ONLY_PAGES_FLAG 0x01
#define IA32_VMX_EPT_VPID_CAP_EXECUTE_ONLY_PAGES_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_EXECUTE_ONLY_PAGES(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 5;
/**
* [Bit 6] Indicates support for a page-walk length of 4.
*/
UINT64_t page_walk_length_4 : 1;
#define IA32_VMX_EPT_VPID_CAP_PAGE_WALK_LENGTH_4_BIT 6
#define IA32_VMX_EPT_VPID_CAP_PAGE_WALK_LENGTH_4_FLAG 0x40
#define IA32_VMX_EPT_VPID_CAP_PAGE_WALK_LENGTH_4_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_PAGE_WALK_LENGTH_4(_) (((_) >> 6) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 8] When set to 1, the logical processor allows software to configure the EPT paging-structure memory type to be
* uncacheable (UC).
*
* @see Vol3C[24.6.11(Extended-Page-Table Pointer (EPTP))]
*/
UINT64_t memory_type_uncacheable : 1;
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_UNCACHEABLE_BIT 8
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_UNCACHEABLE_FLAG 0x100
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_UNCACHEABLE_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_UNCACHEABLE(_) (((_) >> 8) & 0x01)
UINT64_t reserved3 : 5;
/**
* [Bit 14] When set to 1, the logical processor allows software to configure the EPT paging-structure memory type to be
* write-back (WB).
*/
UINT64_t memory_type_write_back : 1;
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_WRITE_BACK_BIT 14
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_WRITE_BACK_FLAG 0x4000
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_WRITE_BACK_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_MEMORY_TYPE_WRITE_BACK(_) (((_) >> 14) & 0x01)
UINT64_t reserved4 : 1;
/**
* [Bit 16] When set to 1, the logical processor allows software to configure a EPT PDE to map a 2-Mbyte page (by setting
* bit 7 in the EPT PDE).
*/
UINT64_t pde_2mb_pages : 1;
#define IA32_VMX_EPT_VPID_CAP_PDE_2MB_PAGES_BIT 16
#define IA32_VMX_EPT_VPID_CAP_PDE_2MB_PAGES_FLAG 0x10000
#define IA32_VMX_EPT_VPID_CAP_PDE_2MB_PAGES_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_PDE_2MB_PAGES(_) (((_) >> 16) & 0x01)
/**
* [Bit 17] When set to 1, the logical processor allows software to configure a EPT PDPTE to map a 1-Gbyte page (by setting
* bit 7 in the EPT PDPTE).
*/
UINT64_t pdpte_1gb_pages : 1;
#define IA32_VMX_EPT_VPID_CAP_PDPTE_1GB_PAGES_BIT 17
#define IA32_VMX_EPT_VPID_CAP_PDPTE_1GB_PAGES_FLAG 0x20000
#define IA32_VMX_EPT_VPID_CAP_PDPTE_1GB_PAGES_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_PDPTE_1GB_PAGES(_) (((_) >> 17) & 0x01)
UINT64_t reserved5 : 2;
/**
* [Bit 20] If bit 20 is read as 1, the INVEPT instruction is supported.
*
* @see Vol3C[30(VMX INSTRUCTION REFERENCE)]
* @see Vol3C[28.3.3.1(Operations that Invalidate Cached Mappings)]
*/
UINT64_t invept : 1;
#define IA32_VMX_EPT_VPID_CAP_INVEPT_BIT 20
#define IA32_VMX_EPT_VPID_CAP_INVEPT_FLAG 0x100000
#define IA32_VMX_EPT_VPID_CAP_INVEPT_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVEPT(_) (((_) >> 20) & 0x01)
/**
* [Bit 21] When set to 1, accessed and dirty flags for EPT are supported.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t ept_accessed_and_dirty_flags : 1;
#define IA32_VMX_EPT_VPID_CAP_EPT_ACCESSED_AND_DIRTY_FLAGS_BIT 21
#define IA32_VMX_EPT_VPID_CAP_EPT_ACCESSED_AND_DIRTY_FLAGS_FLAG 0x200000
#define IA32_VMX_EPT_VPID_CAP_EPT_ACCESSED_AND_DIRTY_FLAGS_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_EPT_ACCESSED_AND_DIRTY_FLAGS(_) (((_) >> 21) & 0x01)
/**
* [Bit 22] When set to 1, the processor reports advanced VM-exit information for EPT violations. This reporting is done
* only if this bit is read as 1.
*
* @see Vol3C[27.2.1(Basic VM-Exit Information)]
*/
UINT64_t advanced_vmexit_ept_violations_information : 1;
#define IA32_VMX_EPT_VPID_CAP_ADVANCED_VMEXIT_EPT_VIOLATIONS_INFORMATION_BIT 22
#define IA32_VMX_EPT_VPID_CAP_ADVANCED_VMEXIT_EPT_VIOLATIONS_INFORMATION_FLAG 0x400000
#define IA32_VMX_EPT_VPID_CAP_ADVANCED_VMEXIT_EPT_VIOLATIONS_INFORMATION_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_ADVANCED_VMEXIT_EPT_VIOLATIONS_INFORMATION(_) (((_) >> 22) & 0x01)
UINT64_t reserved6 : 2;
/**
* [Bit 25] When set to 1, the single-context INVEPT type is supported.
*
* @see Vol3C[30(VMX INSTRUCTION REFERENCE)]
* @see Vol3C[28.3.3.1(Operations that Invalidate Cached Mappings)]
*/
UINT64_t invept_single_context : 1;
#define IA32_VMX_EPT_VPID_CAP_INVEPT_SINGLE_CONTEXT_BIT 25
#define IA32_VMX_EPT_VPID_CAP_INVEPT_SINGLE_CONTEXT_FLAG 0x2000000
#define IA32_VMX_EPT_VPID_CAP_INVEPT_SINGLE_CONTEXT_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVEPT_SINGLE_CONTEXT(_) (((_) >> 25) & 0x01)
/**
* [Bit 26] When set to 1, the all-context INVEPT type is supported.
*
* @see Vol3C[30(VMX INSTRUCTION REFERENCE)]
* @see Vol3C[28.3.3.1(Operations that Invalidate Cached Mappings)]
*/
UINT64_t invept_all_contexts : 1;
#define IA32_VMX_EPT_VPID_CAP_INVEPT_ALL_CONTEXTS_BIT 26
#define IA32_VMX_EPT_VPID_CAP_INVEPT_ALL_CONTEXTS_FLAG 0x4000000
#define IA32_VMX_EPT_VPID_CAP_INVEPT_ALL_CONTEXTS_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVEPT_ALL_CONTEXTS(_) (((_) >> 26) & 0x01)
UINT64_t reserved7 : 5;
/**
* [Bit 32] When set to 1, the INVVPID instruction is supported.
*/
UINT64_t invvpid : 1;
#define IA32_VMX_EPT_VPID_CAP_INVVPID_BIT 32
#define IA32_VMX_EPT_VPID_CAP_INVVPID_FLAG 0x100000000
#define IA32_VMX_EPT_VPID_CAP_INVVPID_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVVPID(_) (((_) >> 32) & 0x01)
UINT64_t reserved8 : 7;
/**
* [Bit 40] When set to 1, the individual-address INVVPID type is supported.
*/
UINT64_t invvpid_individual_address : 1;
#define IA32_VMX_EPT_VPID_CAP_INVVPID_INDIVIDUAL_ADDRESS_BIT 40
#define IA32_VMX_EPT_VPID_CAP_INVVPID_INDIVIDUAL_ADDRESS_FLAG 0x10000000000
#define IA32_VMX_EPT_VPID_CAP_INVVPID_INDIVIDUAL_ADDRESS_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVVPID_INDIVIDUAL_ADDRESS(_) (((_) >> 40) & 0x01)
/**
* [Bit 41] When set to 1, the single-context INVVPID type is supported.
*/
UINT64_t invvpid_single_context : 1;
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_BIT 41
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_FLAG 0x20000000000
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT(_) (((_) >> 41) & 0x01)
/**
* [Bit 42] When set to 1, the all-context INVVPID type is supported.
*/
UINT64_t invvpid_all_contexts : 1;
#define IA32_VMX_EPT_VPID_CAP_INVVPID_ALL_CONTEXTS_BIT 42
#define IA32_VMX_EPT_VPID_CAP_INVVPID_ALL_CONTEXTS_FLAG 0x40000000000
#define IA32_VMX_EPT_VPID_CAP_INVVPID_ALL_CONTEXTS_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVVPID_ALL_CONTEXTS(_) (((_) >> 42) & 0x01)
/**
* [Bit 43] When set to 1, the single-context-retaining-globals INVVPID type is supported.
*/
UINT64_t invvpid_single_context_retain_globals : 1;
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_RETAIN_GLOBALS_BIT 43
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_RETAIN_GLOBALS_FLAG 0x80000000000
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_RETAIN_GLOBALS_MASK 0x01
#define IA32_VMX_EPT_VPID_CAP_INVVPID_SINGLE_CONTEXT_RETAIN_GLOBALS(_) (((_) >> 43) & 0x01)
UINT64_t reserved9 : 20;
};
UINT64_t flags;
} ia32_vmx_ept_vpid_cap_register;
/**
* @defgroup ia32_vmx_true_ctls \
* IA32_VMX_TRUE_(x)_CTLS
*
* Capability Reporting Register of Pin-Based VM-Execution Flex Controls, Primary Processor-Based VM-Execution Flex
* Controls, VM-Exit Flex Controls and VM-Entry Flex Controls.
*
* @remarks If ( CPUID.01H:ECX.[5] = 1 && IA32_VMX_BASIC[55] )
* @see Vol3D[A.3.1(Pin-Based VM-Execution Controls)]
* @see Vol3D[A.3.2(Primary Processor-Based VM-Execution Controls)]
* @see Vol3D[A.4(VM-EXIT CONTROLS)]
* @see Vol3D[A.5(VM-ENTRY CONTROLS)]
* @see Vol3D[A.3.1(Pin-Based VMExecution Controls)] (reference)
* @see Vol3D[A.3.2(Primary Processor-Based VM-Execution Controls)] (reference)
* @see Vol3D[A.4(VM-Exit Controls)] (reference)
* @see Vol3D[A.5(VM-Entry Controls)] (reference)
* @{
*/
#define IA32_VMX_TRUE_PINBASED_CTLS 0x0000048D
#define IA32_VMX_TRUE_PROCBASED_CTLS 0x0000048E
#define IA32_VMX_TRUE_EXIT_CTLS 0x0000048F
#define IA32_VMX_TRUE_ENTRY_CTLS 0x00000490
typedef union
{
struct
{
/**
* [Bits 31:0] Indicate the allowed 0-settings of these controls. VM entry allows control X to be 0 if bit X in the MSR is
* cleared to 0; if bit X in the MSR is set to 1, VM entry fails if control X is 0.
*/
UINT64_t allowed_0_settings : 32;
#define IA32_VMX_TRUE_CTLS_ALLOWED_0_SETTINGS_BIT 0
#define IA32_VMX_TRUE_CTLS_ALLOWED_0_SETTINGS_FLAG 0xFFFFFFFF
#define IA32_VMX_TRUE_CTLS_ALLOWED_0_SETTINGS_MASK 0xFFFFFFFF
#define IA32_VMX_TRUE_CTLS_ALLOWED_0_SETTINGS(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* [Bits 63:32] Indicate the allowed 1-settings of these controls. VM entry allows control X to be 1 if bit 32+X in the MSR
* is set to 1; if bit 32+X in the MSR is cleared to 0, VM entry fails if control X is 1.
*/
UINT64_t allowed_1_settings : 32;
#define IA32_VMX_TRUE_CTLS_ALLOWED_1_SETTINGS_BIT 32
#define IA32_VMX_TRUE_CTLS_ALLOWED_1_SETTINGS_FLAG 0xFFFFFFFF00000000
#define IA32_VMX_TRUE_CTLS_ALLOWED_1_SETTINGS_MASK 0xFFFFFFFF
#define IA32_VMX_TRUE_CTLS_ALLOWED_1_SETTINGS(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_vmx_true_ctls_register;
/**
* @}
*/
/**
* Capability Reporting Register of VMFunction Controls.
*
* @remarks If ( CPUID.01H:ECX.[5] = 1 && IA32_VMX_BASIC[55] )
* @see Vol3D[A.11(VM FUNCTIONS)]
* @see Vol3D[24.6.14(VM-Function Controls)] (reference)
*/
#define IA32_VMX_VMFUNC 0x00000491
typedef union
{
struct
{
/**
* [Bit 0] The EPTP-switching VM function changes the EPT pointer to a value chosen from the EPTP list.
*
* @see Vol3C[25.5.5.3(EPTP Switching)]
*/
UINT64_t eptp_switching : 1;
#define IA32_VMX_VMFUNC_EPTP_SWITCHING_BIT 0
#define IA32_VMX_VMFUNC_EPTP_SWITCHING_FLAG 0x01
#define IA32_VMX_VMFUNC_EPTP_SWITCHING_MASK 0x01
#define IA32_VMX_VMFUNC_EPTP_SWITCHING(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_vmx_vmfunc_register;
/**
* @defgroup ia32_a_pmc \
* IA32_A_PMC(n)
*
* Full Width Writable IA32_PMC(n) Alias.
*
* @remarks (If CPUID.0AH: EAX[15:8] > 0) && IA32_PERF_CAPABILITIES[13] = 1
* @{
*/
#define IA32_A_PMC0 0x000004C1
#define IA32_A_PMC1 0x000004C2
#define IA32_A_PMC2 0x000004C3
#define IA32_A_PMC3 0x000004C4
#define IA32_A_PMC4 0x000004C5
#define IA32_A_PMC5 0x000004C6
#define IA32_A_PMC6 0x000004C7
#define IA32_A_PMC7 0x000004C8
/**
* @}
*/
/**
* Allows software to signal some MCEs to only a single logical processor in the system.
*
* @remarks If IA32_MCG_CAP.LMCE_P = 1
* @see Vol3B[15.3.1.4(IA32_MCG_EXT_CTL MSR)]
*/
#define IA32_MCG_EXT_CTL 0x000004D0
typedef union
{
struct
{
UINT64_t lmce_en : 1;
#define IA32_MCG_EXT_CTL_LMCE_EN_BIT 0
#define IA32_MCG_EXT_CTL_LMCE_EN_FLAG 0x01
#define IA32_MCG_EXT_CTL_LMCE_EN_MASK 0x01
#define IA32_MCG_EXT_CTL_LMCE_EN(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_mcg_ext_ctl_register;
/**
* @brief Status and SVN Threshold of SGX Support for ACM <b>(RO)</b>
*
* Intel SGX only allows launching ACMs with an Intel SGX SVN that is at the same level or higher than the expected Intel
* SGX SVN. The expected Intel SGX SVN is specified by BIOS and locked down by the processor on the first successful
* execution of an Intel SGX instruction that doesn't return an error code. Intel SGX provides interfaces for system
* software to discover whether a non faulting Intel SGX instruction has been executed, and evaluate the suitability of the
* Intel SGX SVN value of any ACM that is expected to be launched by the OS or the VMM.
*
* @remarks If CPUID.(EAX=07H, ECX=0H): EBX[2] = 1
* @see Vol3D[41.11.3(Interactions with Authenticated Code Modules (ACMs))] (reference)
*/
#define IA32_SGX_SVN_STATUS 0x00000500
typedef union
{
struct
{
/**
* [Bit 0] - If 1, indicates that a non-faulting Intel SGX instruction has been executed, consequently, launching a
* properly signed ACM but with Intel SGX SVN value less than the BIOS specified Intel SGX SVN threshold would lead to an
* TXT shutdown.
* - If 0, indicates that the processor will allow a properly signed ACM to launch irrespective of the Intel SGX SVN value
* of the ACM.
*
* @see Vol3D[41.11.3(Interactions with Authenticated Code Modules (ACMs))]
*/
UINT64_t lock : 1;
#define IA32_SGX_SVN_STATUS_LOCK_BIT 0
#define IA32_SGX_SVN_STATUS_LOCK_FLAG 0x01
#define IA32_SGX_SVN_STATUS_LOCK_MASK 0x01
#define IA32_SGX_SVN_STATUS_LOCK(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 15;
/**
* @brief Reflects the expected threshold of Intel SGX SVN for the SINIT ACM
*
* [Bits 23:16] - If CPUID.01H:ECX.SMX = 1, this field reflects the expected threshold of Intel SGX SVN for the SINIT ACM.
* - If CPUID.01H:ECX.SMX = 0, this field is reserved (0).
*
* @see Vol3D[41.11.3(Interactions with Authenticated Code Modules (ACMs))]
*/
UINT64_t sgx_svn_sinit : 8;
#define IA32_SGX_SVN_STATUS_SGX_SVN_SINIT_BIT 16
#define IA32_SGX_SVN_STATUS_SGX_SVN_SINIT_FLAG 0xFF0000
#define IA32_SGX_SVN_STATUS_SGX_SVN_SINIT_MASK 0xFF
#define IA32_SGX_SVN_STATUS_SGX_SVN_SINIT(_) (((_) >> 16) & 0xFF)
UINT64_t reserved2 : 40;
};
UINT64_t flags;
} ia32_sgx_svn_status_register;
/**
* Trace Output Base Register.
*
* @remarks If ( (CPUID.(EAX=07H, ECX=0):EBX[25] = 1) && ( (CPUID.(EAX=14H,ECX=0): ECX[0] = 1) ||
* (CPUID.(EAX=14H,ECX=0):ECX[2] = 1) ) )
* @see Vol3C[35.2.7.7(IA32_RTIT_OUTPUT_BASE MSR)] (reference)
*/
#define IA32_RTIT_OUTPUT_BASE 0x00000560
typedef union
{
struct
{
UINT64_t reserved1 : 7;
/**
* @brief Base physical address
*
* [Bits 47:7] The base physical address. How this address is used depends on the value of IA32_RTIT_CTL.ToPA:
* - 0: This is the base physical address of a single, contiguous physical output region. This could be mapped to DRAM or
* to MMIO, depending on the value. The base address should be aligned with the size of the region, such that none of the
* 1s in the mask value overlap with 1s in the base address. If the base is not aligned, an operational error will result.
* - 1: The base physical address of the current ToPA table. The address must be 4K aligned. Writing an address in which
* bits 11:7 are non-zero will not cause a \#GP, but an operational error will be signaled once TraceEn is set.
*
* @see Vol3C[35.2.7.8(IA32_RTIT_OUTPUT_MASK_PTRS MSR)]
* @see Vol3C[35.3.9(Operational Errors)]
* @see Vol3C[35.2.6.2(Table of Physical Addresses (ToPA))]
*/
UINT64_t base_physical_address : 41;
#define IA32_RTIT_OUTPUT_BASE_BASE_PHYSICAL_ADDRESS_BIT 7
#define IA32_RTIT_OUTPUT_BASE_BASE_PHYSICAL_ADDRESS_FLAG 0xFFFFFFFFFF80
#define IA32_RTIT_OUTPUT_BASE_BASE_PHYSICAL_ADDRESS_MASK 0x1FFFFFFFFFF
#define IA32_RTIT_OUTPUT_BASE_BASE_PHYSICAL_ADDRESS(_) (((_) >> 7) & 0x1FFFFFFFFFF)
UINT64_t reserved2 : 16;
};
UINT64_t flags;
} ia32_rtit_output_base_register;
/**
* Trace Output Mask Pointers Register.
*
* @remarks If ( (CPUID.(EAX=07H, ECX=0):EBX[25] = 1) && ( (CPUID.(EAX=14H,ECX=0):ECX[0] = 1) ||
* (CPUID.(EAX=14H,ECX=0):ECX[2] = 1) ) )
* @see Vol3C[35.2.7.8(IA32_RTIT_OUTPUT_MASK_PTRS MSR)] (reference)
*/
#define IA32_RTIT_OUTPUT_MASK_PTRS 0x00000561
typedef union
{
struct
{
/**
* [Bits 6:0] Forced to 1, writes are ignored.
*/
UINT64_t lower_mask : 7;
#define IA32_RTIT_OUTPUT_MASK_PTRS_LOWER_MASK_BIT 0
#define IA32_RTIT_OUTPUT_MASK_PTRS_LOWER_MASK_FLAG 0x7F
#define IA32_RTIT_OUTPUT_MASK_PTRS_LOWER_MASK_MASK 0x7F
#define IA32_RTIT_OUTPUT_MASK_PTRS_LOWER_MASK(_) (((_) >> 0) & 0x7F)
/**
* @brief MaskOrTableOffset
*
* [Bits 31:7] The use of this field depends on the value of IA32_RTIT_CTL.ToPA:
* - 0: This field holds bits 31:7 of the mask value for the single, contiguous physical output region. The size of this
* field indicates that regions can be of size 128B up to 4GB. This value (combined with the lower 7 bits, which are
* reserved to 1) will be ANDed with the OutputOffset field to determine the next write address. All 1s in this field
* should be consecutive and starting at bit 7, otherwise the region will not be contiguous, and an operational error will
* be signaled when TraceEn is set.
* - 1: This field holds bits 27:3 of the offset pointer into the current ToPA table. This value can be added to the
* IA32_RTIT_OUTPUT_BASE value to produce a pointer to the current ToPA table entry, which itself is a pointer to the
* current output region. In this scenario, the lower 7 reserved bits are ignored. This field supports tables up to 256
* MBytes in size.
*
* @see Vol3C[35.3.9(Operational Errors)]
*/
UINT64_t mask_or_table_offset : 25;
#define IA32_RTIT_OUTPUT_MASK_PTRS_MASK_OR_TABLE_OFFSET_BIT 7
#define IA32_RTIT_OUTPUT_MASK_PTRS_MASK_OR_TABLE_OFFSET_FLAG 0xFFFFFF80
#define IA32_RTIT_OUTPUT_MASK_PTRS_MASK_OR_TABLE_OFFSET_MASK 0x1FFFFFF
#define IA32_RTIT_OUTPUT_MASK_PTRS_MASK_OR_TABLE_OFFSET(_) (((_) >> 7) & 0x1FFFFFF)
/**
* @brief Output Offset
*
* [Bits 63:32] The use of this field depends on the value of IA32_RTIT_CTL.ToPA:
* - 0: This is bits 31:0 of the offset pointer into the single, contiguous physical output region. This value will be
* added to the IA32_RTIT_OUTPUT_BASE value to form the physical address at which the next byte of packet output data will
* be written. This value must be less than or equal to the MaskOrTableOffset field, otherwise an operational error will be
* signaled when TraceEn is set.
* - 1: This field holds bits 31:0 of the offset pointer into the current ToPA output region. This value will be added to
* the output region base field, found in the current ToPA table entry, to form the physical address at which the next byte
* of trace output data will be written. This value must be less than the ToPA entry size, otherwise an operational error
* will be signaled when TraceEn is set.
*
* @see Vol3C[35.3.9(Operational Errors)]
*/
UINT64_t output_offset : 32;
#define IA32_RTIT_OUTPUT_MASK_PTRS_OUTPUT_OFFSET_BIT 32
#define IA32_RTIT_OUTPUT_MASK_PTRS_OUTPUT_OFFSET_FLAG 0xFFFFFFFF00000000
#define IA32_RTIT_OUTPUT_MASK_PTRS_OUTPUT_OFFSET_MASK 0xFFFFFFFF
#define IA32_RTIT_OUTPUT_MASK_PTRS_OUTPUT_OFFSET(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_rtit_output_mask_ptrs_register;
/**
* Trace Control Register.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[25] = 1)
* @see Vol3C[35.2.7.2(IA32_RTIT_CTL MSR)] (reference)
*/
#define IA32_RTIT_CTL 0x00000570
typedef union
{
struct
{
/**
* @brief TraceEn
*
* [Bit 0] If 1, enables tracing; else tracing is disabled.
* When this bit transitions from 1 to 0, all buffered packets are flushed out of internal buffers. A further store, fence,
* or architecturally serializing instruction may be required to ensure that packet data can be observed at the trace
* endpoint.
* Note that the processor will clear this bit on \#SMI (Section) and warm reset. Other MSR bits of IA32_RTIT_CTL (and
* other trace configuration MSRs) are not impacted by these events.
*
* @see Vol3C[35.2.7.3(Enabling and Disabling Packet Generation with TraceEn)]
*/
UINT64_t trace_enabled : 1;
#define IA32_RTIT_CTL_TRACE_ENABLED_BIT 0
#define IA32_RTIT_CTL_TRACE_ENABLED_FLAG 0x01
#define IA32_RTIT_CTL_TRACE_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_TRACE_ENABLED(_) (((_) >> 0) & 0x01)
/**
* @brief CYCEn
*
* [Bit 1] - 0: Disables CYC Packet.
* - 1: Enables CYC Packet.
*
* @remarks If CPUID.(EAX=14H, ECX=0):EBX.CPSB_CAM[bit 1] = 0
* @see Vol3C[35.4.2.14(Cycle Count (CYC) Packet)]
*/
UINT64_t cyc_enabled : 1;
#define IA32_RTIT_CTL_CYC_ENABLED_BIT 1
#define IA32_RTIT_CTL_CYC_ENABLED_FLAG 0x02
#define IA32_RTIT_CTL_CYC_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_CYC_ENABLED(_) (((_) >> 1) & 0x01)
/**
* @brief OS
*
* [Bit 2] - 0: Packet generation is disabled when CPL = 0.
* - 1: Packet generation may be enabled when CPL = 0.
*/
UINT64_t os : 1;
#define IA32_RTIT_CTL_OS_BIT 2
#define IA32_RTIT_CTL_OS_FLAG 0x04
#define IA32_RTIT_CTL_OS_MASK 0x01
#define IA32_RTIT_CTL_OS(_) (((_) >> 2) & 0x01)
/**
* @brief User
*
* [Bit 3] - 0: Packet generation is disabled when CPL > 0.
* - 1: Packet generation may be enabled when CPL > 0.
*/
UINT64_t user : 1;
#define IA32_RTIT_CTL_USER_BIT 3
#define IA32_RTIT_CTL_USER_FLAG 0x08
#define IA32_RTIT_CTL_USER_MASK 0x01
#define IA32_RTIT_CTL_USER(_) (((_) >> 3) & 0x01)
/**
* @brief PwrEvtEn
*
* [Bit 4] - 0: Power Event Trace packets are disabled.
* - 1: Power Event Trace packets are enabled.
*
* @see Vol3C[35.2.3(Power Event Tracing)]
*/
UINT64_t power_event_trace_enabled : 1;
#define IA32_RTIT_CTL_POWER_EVENT_TRACE_ENABLED_BIT 4
#define IA32_RTIT_CTL_POWER_EVENT_TRACE_ENABLED_FLAG 0x10
#define IA32_RTIT_CTL_POWER_EVENT_TRACE_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_POWER_EVENT_TRACE_ENABLED(_) (((_) >> 4) & 0x01)
/**
* @brief FUPonPTW
*
* [Bit 5] - 0: PTW packets are not followed by FUPs.
* - 1: PTW packets are followed by FUPs.
*/
UINT64_t fup_on_ptw : 1;
#define IA32_RTIT_CTL_FUP_ON_PTW_BIT 5
#define IA32_RTIT_CTL_FUP_ON_PTW_FLAG 0x20
#define IA32_RTIT_CTL_FUP_ON_PTW_MASK 0x01
#define IA32_RTIT_CTL_FUP_ON_PTW(_) (((_) >> 5) & 0x01)
/**
* @brief FabricEn
*
* [Bit 6] - 0: Trace output is directed to the memory subsystem, mechanism depends on IA32_RTIT_CTL.ToPA.
* - 1: Trace output is directed to the trace transport subsystem, IA32_RTIT_CTL.ToPA is ignored.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):ECX[3] = 1) Reserved if CPUID.(EAX=14H, ECX=0):ECX[bit 3] = 0
*/
UINT64_t fabric_enabled : 1;
#define IA32_RTIT_CTL_FABRIC_ENABLED_BIT 6
#define IA32_RTIT_CTL_FABRIC_ENABLED_FLAG 0x40
#define IA32_RTIT_CTL_FABRIC_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_FABRIC_ENABLED(_) (((_) >> 6) & 0x01)
/**
* @brief CR3 filter
*
* [Bit 7] - 0: Disables CR3 filtering.
* - 1: Enables CR3 filtering.
*/
UINT64_t cr3_filter : 1;
#define IA32_RTIT_CTL_CR3_FILTER_BIT 7
#define IA32_RTIT_CTL_CR3_FILTER_FLAG 0x80
#define IA32_RTIT_CTL_CR3_FILTER_MASK 0x01
#define IA32_RTIT_CTL_CR3_FILTER(_) (((_) >> 7) & 0x01)
/**
* @brief ToPA
*
* [Bit 8] - 0: Single-range output scheme enabled.
* - 1: ToPA output scheme enabled.
*
* @remarks 0: If CPUID.(EAX=14H, ECX=0):ECX.SNGLRGNOUT[bit 2] = 1 and IA32_RTIT_CTL.FabricEn=0 1: If CPUID.(EAX=14H,
* ECX=0):ECX.TOPA[bit 0] = 1, and IA32_RTIT_CTL.FabricEn=0
* WRMSR to IA32_RTIT_CTL that sets TraceEn but clears this bit and FabricEn would cause \#GP: If CPUID.(EAX=14H,
* ECX=0):ECX.SNGLRGNOUT[bit 2] = 0 WRMSR to IA32_RTIT_CTL that sets this bit causes \#GP: If CPUID.(EAX=14H,
* ECX=0):ECX.TOPA[bit 0] = 0
* @see Vol3C[35.2.6.2(Table of Physical Addresses (ToPA))]
*/
UINT64_t topa : 1;
#define IA32_RTIT_CTL_TOPA_BIT 8
#define IA32_RTIT_CTL_TOPA_FLAG 0x100
#define IA32_RTIT_CTL_TOPA_MASK 0x01
#define IA32_RTIT_CTL_TOPA(_) (((_) >> 8) & 0x01)
/**
* @brief MTCEn
*
* [Bit 9] - 0: Disables MTC Packet.
* - 1: Enables MTC Packet.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[3] = 1) Reserved if CPUID.(EAX=14H, ECX=0):EBX.MTC[bit 3] = 0
* @see Vol3C[35.4.2.16(Overflow (OVF) Packet)]
*/
UINT64_t mtc_enabled : 1;
#define IA32_RTIT_CTL_MTC_ENABLED_BIT 9
#define IA32_RTIT_CTL_MTC_ENABLED_FLAG 0x200
#define IA32_RTIT_CTL_MTC_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_MTC_ENABLED(_) (((_) >> 9) & 0x01)
/**
* @brief TSCEn
*
* [Bit 10] - 0: Disable TSC packets.
* - 1: Enable TSC packets.
*
* @see Vol3C[35.4.2.11(Timestamp Counter (TSC) Packet)]
*/
UINT64_t tsc_enabled : 1;
#define IA32_RTIT_CTL_TSC_ENABLED_BIT 10
#define IA32_RTIT_CTL_TSC_ENABLED_FLAG 0x400
#define IA32_RTIT_CTL_TSC_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_TSC_ENABLED(_) (((_) >> 10) & 0x01)
/**
* @brief DisRETC
*
* [Bit 11] - 0: Enable RET compression.
* - 1: Disable RET compression.
*
* @see Vol3C[35.2.1.2(Indirect Transfer COFI)]
*/
UINT64_t ret_compression_disabled : 1;
#define IA32_RTIT_CTL_RET_COMPRESSION_DISABLED_BIT 11
#define IA32_RTIT_CTL_RET_COMPRESSION_DISABLED_FLAG 0x800
#define IA32_RTIT_CTL_RET_COMPRESSION_DISABLED_MASK 0x01
#define IA32_RTIT_CTL_RET_COMPRESSION_DISABLED(_) (((_) >> 11) & 0x01)
/**
* @brief PTWEn
*
* [Bit 12] - 0: PTWRITE packet generation disabled.
* - 1: PTWRITE packet generation enabled.
*/
UINT64_t ptw_enabled : 1;
#define IA32_RTIT_CTL_PTW_ENABLED_BIT 12
#define IA32_RTIT_CTL_PTW_ENABLED_FLAG 0x1000
#define IA32_RTIT_CTL_PTW_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_PTW_ENABLED(_) (((_) >> 12) & 0x01)
/**
* @brief BranchEn
*
* [Bit 13] - 0: Disable COFI-based packets.
* - 1: Enable COFI-based packets: FUP, TIP, TIP.PGE, TIP.PGD, TNT, MODE.Exec, MODE.TSX.
*
* @see Vol3C[35.2.5.4(Branch Enable (BranchEn))]
*/
UINT64_t branch_enabled : 1;
#define IA32_RTIT_CTL_BRANCH_ENABLED_BIT 13
#define IA32_RTIT_CTL_BRANCH_ENABLED_FLAG 0x2000
#define IA32_RTIT_CTL_BRANCH_ENABLED_MASK 0x01
#define IA32_RTIT_CTL_BRANCH_ENABLED(_) (((_) >> 13) & 0x01)
/**
* @brief MTCFreq
*
* [Bits 17:14] Defines MTC packet Frequency, which is based on the core crystal clock, or Always Running Timer (ART). MTC
* will be sent each time the selected ART bit toggles. The following Encodings are defined:
* 0: ART(0), 1: ART(1), 2: ART(2), 3: ART(3), 4: ART(4), 5: ART(5), 6: ART(6), 7: ART(7), 8: ART(8), 9: ART(9), 10:
* ART(10), 11: ART(11), 12: ART(12), 13: ART(13), 14: ART(14), 15: ART(15)
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[3] = 1) Reserved if CPUID.(EAX=14H, ECX=0):EBX.MTC[bit 3] = 0
* @see Vol3C[35.3.1(Detection of Intel Processor Trace and Capability Enumeration)]
*/
UINT64_t mtc_frequency : 4;
#define IA32_RTIT_CTL_MTC_FREQUENCY_BIT 14
#define IA32_RTIT_CTL_MTC_FREQUENCY_FLAG 0x3C000
#define IA32_RTIT_CTL_MTC_FREQUENCY_MASK 0x0F
#define IA32_RTIT_CTL_MTC_FREQUENCY(_) (((_) >> 14) & 0x0F)
UINT64_t reserved1 : 1;
/**
* @brief CYCThresh
*
* [Bits 22:19] CYC packet threshold. CYC packets will be sent with the first eligible packet after N cycles have passed
* since the last CYC packet. If CycThresh is 0 then N=0, otherwise N is defined as 2(CycThresh-1). The following Encodings
* are defined:
* 0: 0, 1: 1, 2: 2, 3: 4, 4: 8, 5: 16, 6: 32, 7: 64, 8: 128, 9: 256, 10: 512, 11: 1024, 12: 2048, 13: 4096, 14: 8192, 15:
* 16384
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[1] = 1) Reserved if CPUID.(EAX=14H, ECX=0):EBX.CPSB_CAM[bit 1] = 0
* @see Vol3C[35.3.6(Cycle-Accurate Mode)]
* @see Vol3C[35.3.1(Detection of Intel Processor Trace and Capability Enumeration)]
*/
UINT64_t cyc_threshold : 4;
#define IA32_RTIT_CTL_CYC_THRESHOLD_BIT 19
#define IA32_RTIT_CTL_CYC_THRESHOLD_FLAG 0x780000
#define IA32_RTIT_CTL_CYC_THRESHOLD_MASK 0x0F
#define IA32_RTIT_CTL_CYC_THRESHOLD(_) (((_) >> 19) & 0x0F)
UINT64_t reserved2 : 1;
/**
* @brief PSBFreq
*
* [Bits 27:24] Indicates the frequency of PSB packets. PSB packet frequency is based on the number of Intel PT packet
* bytes output, so this field allows the user to determine the increment of IA32_IA32_RTIT_STATUS.PacketByteCnt that
* should cause a PSB to be generated. Note that PSB insertion is not precise, but the average output bytes per PSB should
* approximate the SW selected period. The following Encodings are defined:
* 0: 2K, 1: 4K, 2: 8K, 3: 16K, 4: 32K, 5: 64K, 6: 128K, 7: 256K, 8: 512K, 9: 1M, 10: 2M, 11: 4M, 12: 8M, 13: 16M, 14: 32M,
* 15: 64M
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[1] = 1) Reserved if CPUID.(EAX=14H, ECX=0):EBX.CPSB_CAM[bit 1] = 0
* @see Vol3C[35.3.1(Detection of Intel Processor Trace and Capability Enumeration)]
*/
UINT64_t psb_frequency : 4;
#define IA32_RTIT_CTL_PSB_FREQUENCY_BIT 24
#define IA32_RTIT_CTL_PSB_FREQUENCY_FLAG 0xF000000
#define IA32_RTIT_CTL_PSB_FREQUENCY_MASK 0x0F
#define IA32_RTIT_CTL_PSB_FREQUENCY(_) (((_) >> 24) & 0x0F)
UINT64_t reserved3 : 4;
/**
* @brief ADDR0_CFG
*
* [Bits 35:32] Configures the base/limit register pair IA32_RTIT_ADDR0_A/B based on the following encodings:
* - 0: ADDR0 range unused.
* - 1: The [IA32_RTIT_ADDR0_A..IA32_RTIT_ADDR0_B] range defines a FilterEn range. FilterEn will only be set when the IP is
* within this range, though other FilterEn ranges can additionally be used.
* - 2: The [IA32_RTIT_ADDR0_A..IA32_RTIT_ADDR0_B] range defines a TraceStop range. TraceStop will be asserted if code
* branches into this range.
* - 3..15: Reserved (\#GP).
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > 0) Reserved if CPUID.(EAX=14H, ECX=1):EBX.RANGECNT[2:0] >= 0
* @see Vol3C[35.2.4.3(Filtering by IP)]
* @see Vol3C[35.4.2.10(Core:Bus Ratio (CBR) Packet)]
*/
UINT64_t addr0_cfg : 4;
#define IA32_RTIT_CTL_ADDR0_CFG_BIT 32
#define IA32_RTIT_CTL_ADDR0_CFG_FLAG 0xF00000000
#define IA32_RTIT_CTL_ADDR0_CFG_MASK 0x0F
#define IA32_RTIT_CTL_ADDR0_CFG(_) (((_) >> 32) & 0x0F)
/**
* @brief ADDR1_CFG
*
* [Bits 39:36] Configures the base/limit register pair IA32_RTIT_ADDR1_A/B based on the following encodings:
* - 0: ADDR1 range unused.
* - 1: The [IA32_RTIT_ADDR1_A..IA32_RTIT_ADDR1_B] range defines a FilterEn range. FilterEn will only be set when the IP is
* within this range, though other FilterEn ranges can additionally be used.
* - 2: The [IA32_RTIT_ADDR1_A..IA32_RTIT_ADDR1_B] range defines a TraceStop range. TraceStop will be asserted if code
* branches into this range.
* - 3..15: Reserved (\#GP).
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > 1) Reserved if CPUID.(EAX=14H, ECX=1):EBX.RANGECNT[2:0] < 2
* @see Vol3C[35.2.4.3(Filtering by IP)]
* @see Vol3C[35.4.2.10(Core:Bus Ratio (CBR) Packet)]
*/
UINT64_t addr1_cfg : 4;
#define IA32_RTIT_CTL_ADDR1_CFG_BIT 36
#define IA32_RTIT_CTL_ADDR1_CFG_FLAG 0xF000000000
#define IA32_RTIT_CTL_ADDR1_CFG_MASK 0x0F
#define IA32_RTIT_CTL_ADDR1_CFG(_) (((_) >> 36) & 0x0F)
/**
* @brief ADDR2_CFG
*
* [Bits 43:40] Configures the base/limit register pair IA32_RTIT_ADDR2_A/B based on the following encodings:
* - 0: ADDR2 range unused.
* - 1: The [IA32_RTIT_ADDR2_A..IA32_RTIT_ADDR2_B] range defines a FilterEn range. FilterEn will only be set when the IP is
* within this range, though other FilterEn ranges can additionally be used.
* - 2: The [IA32_RTIT_ADDR2_A..IA32_RTIT_ADDR2_B] range defines a TraceStop range. TraceStop will be asserted if code
* branches into this range.
* - 3..15: Reserved (\#GP).
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > 2) Reserved if CPUID.(EAX=14H, ECX=1):EBX.RANGECNT[2:0] < 3
* @see Vol3C[35.2.4.3(Filtering by IP)]
* @see Vol3C[35.4.2.10(Core:Bus Ratio (CBR) Packet)]
*/
UINT64_t addr2_cfg : 4;
#define IA32_RTIT_CTL_ADDR2_CFG_BIT 40
#define IA32_RTIT_CTL_ADDR2_CFG_FLAG 0xF0000000000
#define IA32_RTIT_CTL_ADDR2_CFG_MASK 0x0F
#define IA32_RTIT_CTL_ADDR2_CFG(_) (((_) >> 40) & 0x0F)
/**
* @brief ADDR3_CFG
*
* [Bits 47:44] Configures the base/limit register pair IA32_RTIT_ADDR3_A/B based on the following encodings:
* - 0: ADDR3 range unused.
* - 1: The [IA32_RTIT_ADDR3_A..IA32_RTIT_ADDR3_B] range defines a FilterEn range. FilterEn will only be set when the IP is
* within this range, though other FilterEn ranges can additionally be used.
* - 2: The [IA32_RTIT_ADDR3_A..IA32_RTIT_ADDR3_B] range defines a TraceStop range. TraceStop will be asserted if code
* branches into this range.
* - 3..15: Reserved (\#GP).
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > 3) Reserved if CPUID.(EAX=14H, ECX=1):EBX.RANGECNT[2:0] < 4
* @see Vol3C[35.2.4.3(Filtering by IP)]
* @see Vol3C[35.4.2.10(Core:Bus Ratio (CBR) Packet)]
*/
UINT64_t addr3_cfg : 4;
#define IA32_RTIT_CTL_ADDR3_CFG_BIT 44
#define IA32_RTIT_CTL_ADDR3_CFG_FLAG 0xF00000000000
#define IA32_RTIT_CTL_ADDR3_CFG_MASK 0x0F
#define IA32_RTIT_CTL_ADDR3_CFG(_) (((_) >> 44) & 0x0F)
UINT64_t reserved4 : 8;
/**
* @brief InjectPsbPmiOnEnable
*
* [Bit 56] - 1: Enables use of IA32_RTIT_STATUS bits PendPSB[6] and PendTopaPMI[7].
* - 0: IA32_RTIT_STATUS bits 6 and 7 are ignored.
*
* @remarks Reserved if CPUID.(EAX=14H, ECX=0):EBX.INJECTPSBPMI[6] = 0
* @see Vol3C[35.2.7.4(IA32_RTIT_STATUS MSR)]
*/
UINT64_t inject_psb_pmi_on_enable : 1;
#define IA32_RTIT_CTL_INJECT_PSB_PMI_ON_ENABLE_BIT 56
#define IA32_RTIT_CTL_INJECT_PSB_PMI_ON_ENABLE_FLAG 0x100000000000000
#define IA32_RTIT_CTL_INJECT_PSB_PMI_ON_ENABLE_MASK 0x01
#define IA32_RTIT_CTL_INJECT_PSB_PMI_ON_ENABLE(_) (((_) >> 56) & 0x01)
UINT64_t reserved5 : 7;
};
UINT64_t flags;
} ia32_rtit_ctl_register;
/**
* Tracing Status Register.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[25] = 1)
*/
#define IA32_RTIT_STATUS 0x00000571
typedef union
{
struct
{
/**
* @brief FilterEn (writes ignored)
*
* [Bit 0] This bit is written by the processor, and indicates that tracing is allowed for the current IP. Writes are
* ignored.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[2] = 1)
* @see Vol3C[35.2.5.5(Filter Enable (FilterEn))]
*/
UINT64_t filter_enabled : 1;
#define IA32_RTIT_STATUS_FILTER_ENABLED_BIT 0
#define IA32_RTIT_STATUS_FILTER_ENABLED_FLAG 0x01
#define IA32_RTIT_STATUS_FILTER_ENABLED_MASK 0x01
#define IA32_RTIT_STATUS_FILTER_ENABLED(_) (((_) >> 0) & 0x01)
/**
* @brief ContexEn (writes ignored)
*
* [Bit 1] The processor sets this bit to indicate that tracing is allowed for the current context. Writes are ignored.
*
* @see Vol3C[35.2.5.3(Context Enable (ContextEn))]
*/
UINT64_t context_enabled : 1;
#define IA32_RTIT_STATUS_CONTEXT_ENABLED_BIT 1
#define IA32_RTIT_STATUS_CONTEXT_ENABLED_FLAG 0x02
#define IA32_RTIT_STATUS_CONTEXT_ENABLED_MASK 0x01
#define IA32_RTIT_STATUS_CONTEXT_ENABLED(_) (((_) >> 1) & 0x01)
/**
* @brief TriggerEn (writes ignored)
*
* [Bit 2] The processor sets this bit to indicate that tracing is enabled. Writes are ignored.
*
* @see Vol3C[35.2.5.2(Trigger Enable (TriggerEn))]
*/
UINT64_t trigger_enabled : 1;
#define IA32_RTIT_STATUS_TRIGGER_ENABLED_BIT 2
#define IA32_RTIT_STATUS_TRIGGER_ENABLED_FLAG 0x04
#define IA32_RTIT_STATUS_TRIGGER_ENABLED_MASK 0x01
#define IA32_RTIT_STATUS_TRIGGER_ENABLED(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief Error
*
* [Bit 4] The processor sets this bit to indicate that an operational error has been encountered. When this bit is set,
* TriggerEn is cleared to 0 and packet generation is disabled.
* When TraceEn is cleared, software can write this bit. Once it is set, only software can clear it. It is not recommended
* that software ever set this bit, except in cases where it is restoring a prior saved state.
*
* @see Vol3C[35.2.6.2(Table of Physical Addresses (ToPA) | ToPA Errors)]
*/
UINT64_t error : 1;
#define IA32_RTIT_STATUS_ERROR_BIT 4
#define IA32_RTIT_STATUS_ERROR_FLAG 0x10
#define IA32_RTIT_STATUS_ERROR_MASK 0x01
#define IA32_RTIT_STATUS_ERROR(_) (((_) >> 4) & 0x01)
/**
* @brief Stopped
*
* [Bit 5] The processor sets this bit to indicate that a ToPA Stop condition has been encountered. When this bit is set,
* TriggerEn is cleared to 0 and packet generation is disabled.
* When TraceEn is cleared, software can write this bit. Once it is set, only software can clear it. It is not recommended
* that software ever set this bit, except in cases where it is restoring a prior saved state.
*
* @see Vol3C[35.2.6.2(Table of Physical Addresses (ToPA) | ToPA STOP)]
*/
UINT64_t stopped : 1;
#define IA32_RTIT_STATUS_STOPPED_BIT 5
#define IA32_RTIT_STATUS_STOPPED_FLAG 0x20
#define IA32_RTIT_STATUS_STOPPED_MASK 0x01
#define IA32_RTIT_STATUS_STOPPED(_) (((_) >> 5) & 0x01)
/**
* @brief Pend PSB
*
* [Bit 6] If IA32_RTIT_CTL.InjectPsbPmiOnEnable[56] = 1, the processor sets this bit when the threshold for a PSB+ to be
* inserted has been reached. The processor will clear this bit when the PSB+ has been inserted into the trace. If PendPSB
* = 1 and InjectPsbPmiOnEnable = 1 when IA32_RTIT_CTL.TraceEn[0] transitions from 0 to 1, a PSB+ will be inserted into the
* trace.
*
* @remarks If CPUID.(EAX=14H, ECX=0):EBX.INJECTPSBPMI[6] = 1
*/
UINT64_t pend_psb : 1;
#define IA32_RTIT_STATUS_PEND_PSB_BIT 6
#define IA32_RTIT_STATUS_PEND_PSB_FLAG 0x40
#define IA32_RTIT_STATUS_PEND_PSB_MASK 0x01
#define IA32_RTIT_STATUS_PEND_PSB(_) (((_) >> 6) & 0x01)
/**
* @brief Pend ToPA PMI
*
* [Bit 7] If IA32_RTIT_CTL.InjectPsbPmiOnEnable[56] = 1, the processor sets this bit when the threshold for a ToPA PMI to
* be inserted has been reached. Software should clear this bit once the ToPA PMI has been handled. If PendTopaPMI = 1 and
* InjectPsbPmiOnEnable = 1 when IA32_RTIT_CTL.TraceEn[0] transitions from 0 to 1, a PMI will be pended.
*
* @remarks If CPUID.(EAX=14H, ECX=0):EBX.INJECTPSBPMI[6] = 1
* @see Vol3C[35.2.6.2(Table of Physical Addresses (ToPA) | ToPA PMI)]
*/
UINT64_t pend_topa_pmi : 1;
#define IA32_RTIT_STATUS_PEND_TOPA_PMI_BIT 7
#define IA32_RTIT_STATUS_PEND_TOPA_PMI_FLAG 0x80
#define IA32_RTIT_STATUS_PEND_TOPA_PMI_MASK 0x01
#define IA32_RTIT_STATUS_PEND_TOPA_PMI(_) (((_) >> 7) & 0x01)
UINT64_t reserved2 : 24;
/**
* @brief PacketByteCnt
*
* [Bits 48:32] This field is written by the processor, and holds a count of packet bytes that have been sent out. The
* processor also uses this field to determine when the next PSB packet should be inserted. Note that the processor may
* clear or modify this field at any time while IA32_RTIT_CTL.TraceEn=1. It will have a stable value when
* IA32_RTIT_CTL.TraceEn=0.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[1] > 3)
* @see Vol3C[35.4.2.17(Packet Stream Boundary (PSB) Packet)]
*/
UINT64_t packetUINT8_count : 17;
#define IA32_RTIT_STATUS_PACKETUINT8_COUNT_BIT 32
#define IA32_RTIT_STATUS_PACKETUINT8_COUNT_FLAG 0x1FFFF00000000
#define IA32_RTIT_STATUS_PACKETUINT8_COUNT_MASK 0x1FFFF
#define IA32_RTIT_STATUS_PACKETUINT8_COUNT(_) (((_) >> 32) & 0x1FFFF)
UINT64_t reserved3 : 15;
};
UINT64_t flags;
} ia32_rtit_status_register;
/**
* @brief Trace Filter CR3 Match Register <b>(R/W)</b>
*
* The IA32_RTIT_CR3_MATCH register is compared against CR3 when IA32_RTIT_CTL.CR3Filter is 1. Bits 63:5 hold the CR3
* address value to match, bits 4:0 are reserved to 0.
*
* @remarks If (CPUID.(EAX=07H, ECX=0):EBX[25] = 1)
* @see Vol3C[35.2.4.2(Filtering by CR3)]
* @see Vol3C[35.2.7.6(IA32_RTIT_CR3_MATCH MSR)] (reference)
*/
#define IA32_RTIT_CR3_MATCH 0x00000572
typedef union
{
struct
{
UINT64_t reserved1 : 5;
/**
* [Bits 63:5] CR3[63:5] value to match.
*/
UINT64_t cr3_value_to_match : 59;
#define IA32_RTIT_CR3_MATCH_CR3_VALUE_TO_MATCH_BIT 5
#define IA32_RTIT_CR3_MATCH_CR3_VALUE_TO_MATCH_FLAG 0xFFFFFFFFFFFFFFE0
#define IA32_RTIT_CR3_MATCH_CR3_VALUE_TO_MATCH_MASK 0x7FFFFFFFFFFFFFF
#define IA32_RTIT_CR3_MATCH_CR3_VALUE_TO_MATCH(_) (((_) >> 5) & 0x7FFFFFFFFFFFFFF)
};
UINT64_t flags;
} ia32_rtit_cr3_match_register;
/**
* @defgroup ia32_rtit_addr \
* IA32_RTIT_ADDR(x)
*
* The role of the IA32_RTIT_ADDRn_A/B register pairs, for each n, is determined by the corresponding ADDRn_CFG fields in
* IA32_RTIT_CTL. The number of these register pairs is enumerated by CPUID.(EAX=14H, ECX=1):EAX.RANGECNT[2:0].
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > n)
* @see Vol3C[35.2.7.2(IA32_RTIT_CTL MSR)]
* @see Vol3C[35.2.7.5(IA32_RTIT_ADDRn_A and IA32_RTIT_ADDRn_B MSRs)] (reference)
* @{
*/
/**
* @defgroup ia32_rtit_addr_a \
* IA32_RTIT_ADDR(n)_A
*
* Region n Start Address.
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > n)
* @{
*/
#define IA32_RTIT_ADDR0_A 0x00000580
#define IA32_RTIT_ADDR1_A 0x00000582
#define IA32_RTIT_ADDR2_A 0x00000584
#define IA32_RTIT_ADDR3_A 0x00000586
/**
* @}
*/
/**
* @defgroup ia32_rtit_addr_b \
* IA32_RTIT_ADDR(n)_B
*
* Region n End Address.
*
* @remarks If (CPUID.(EAX=07H, ECX=1):EAX[2:0] > n)
* @{
*/
#define IA32_RTIT_ADDR0_B 0x00000581
#define IA32_RTIT_ADDR1_B 0x00000583
#define IA32_RTIT_ADDR2_B 0x00000585
#define IA32_RTIT_ADDR3_B 0x00000587
/**
* @}
*/
typedef union
{
struct
{
/**
* [Bits 47:0] Virtual Address.
*/
UINT64_t virtual_address : 48;
#define IA32_RTIT_ADDR_VIRTUAL_ADDRESS_BIT 0
#define IA32_RTIT_ADDR_VIRTUAL_ADDRESS_FLAG 0xFFFFFFFFFFFF
#define IA32_RTIT_ADDR_VIRTUAL_ADDRESS_MASK 0xFFFFFFFFFFFF
#define IA32_RTIT_ADDR_VIRTUAL_ADDRESS(_) (((_) >> 0) & 0xFFFFFFFFFFFF)
/**
* [Bits 63:48] SignExt_VA.
*/
UINT64_t sign_ext_va : 16;
#define IA32_RTIT_ADDR_SIGN_EXT_VA_BIT 48
#define IA32_RTIT_ADDR_SIGN_EXT_VA_FLAG 0xFFFF000000000000
#define IA32_RTIT_ADDR_SIGN_EXT_VA_MASK 0xFFFF
#define IA32_RTIT_ADDR_SIGN_EXT_VA(_) (((_) >> 48) & 0xFFFF)
};
UINT64_t flags;
} ia32_rtit_addr_register;
/**
* @}
*/
/**
* DS Save Area. Points to the linear address of the first byte of the DS buffer management area, which is used to manage
* the BTS and PEBS buffers.
* Returns:
* - [63:0] The linear address of the first byte of the DS buffer management area, if IA-32e mode is active.
* - [31:0] The linear address of the first byte of the DS buffer management area, if not in IA-32e mode.
* - [63:32] Reserved if not in IA-32e mode.
*
* @remarks If CPUID.01H:EDX.DS[21] = 1
* @see Vol3B[18.6.3.4(Debug Store (DS) Mechanism)]
*/
#define IA32_DS_AREA 0x00000600
/**
* TSC Target of Local APIC's TSC Deadline Mode.
*
* @remarks If CPUID.01H:ECX.[24] = 1
*/
#define IA32_TSC_DEADLINE 0x000006E0
/**
* Enable/disable HWP.
*
* @remarks If CPUID.06H:EAX.[7] = 1
*/
#define IA32_PM_ENABLE 0x00000770
typedef union
{
struct
{
/**
* [Bit 0] HWP_ENABLE.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.2(Enabling HWP)]
*/
UINT64_t hwp_enable : 1;
#define IA32_PM_ENABLE_HWP_ENABLE_BIT 0
#define IA32_PM_ENABLE_HWP_ENABLE_FLAG 0x01
#define IA32_PM_ENABLE_HWP_ENABLE_MASK 0x01
#define IA32_PM_ENABLE_HWP_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_pm_enable_register;
/**
* HWP Performance Range Enumeration.
*
* @remarks If CPUID.06H:EAX.[7] = 1
*/
#define IA32_HWP_CAPABILITIES 0x00000771
typedef union
{
struct
{
/**
* [Bits 7:0] Highest_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.3(HWP Performance Range and Dynamic Capabilities)]
*/
UINT64_t highest_performance : 8;
#define IA32_HWP_CAPABILITIES_HIGHEST_PERFORMANCE_BIT 0
#define IA32_HWP_CAPABILITIES_HIGHEST_PERFORMANCE_FLAG 0xFF
#define IA32_HWP_CAPABILITIES_HIGHEST_PERFORMANCE_MASK 0xFF
#define IA32_HWP_CAPABILITIES_HIGHEST_PERFORMANCE(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Guaranteed_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.3(HWP Performance Range and Dynamic Capabilities)]
*/
UINT64_t guaranteed_performance : 8;
#define IA32_HWP_CAPABILITIES_GUARANTEED_PERFORMANCE_BIT 8
#define IA32_HWP_CAPABILITIES_GUARANTEED_PERFORMANCE_FLAG 0xFF00
#define IA32_HWP_CAPABILITIES_GUARANTEED_PERFORMANCE_MASK 0xFF
#define IA32_HWP_CAPABILITIES_GUARANTEED_PERFORMANCE(_) (((_) >> 8) & 0xFF)
/**
* [Bits 23:16] Most_Efficient_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.3(HWP Performance Range and Dynamic Capabilities)]
*/
UINT64_t most_efficient_performance : 8;
#define IA32_HWP_CAPABILITIES_MOST_EFFICIENT_PERFORMANCE_BIT 16
#define IA32_HWP_CAPABILITIES_MOST_EFFICIENT_PERFORMANCE_FLAG 0xFF0000
#define IA32_HWP_CAPABILITIES_MOST_EFFICIENT_PERFORMANCE_MASK 0xFF
#define IA32_HWP_CAPABILITIES_MOST_EFFICIENT_PERFORMANCE(_) (((_) >> 16) & 0xFF)
/**
* [Bits 31:24] Lowest_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.3(HWP Performance Range and Dynamic Capabilities)]
*/
UINT64_t lowest_performance : 8;
#define IA32_HWP_CAPABILITIES_LOWEST_PERFORMANCE_BIT 24
#define IA32_HWP_CAPABILITIES_LOWEST_PERFORMANCE_FLAG 0xFF000000
#define IA32_HWP_CAPABILITIES_LOWEST_PERFORMANCE_MASK 0xFF
#define IA32_HWP_CAPABILITIES_LOWEST_PERFORMANCE(_) (((_) >> 24) & 0xFF)
UINT64_t reserved1 : 32;
};
UINT64_t flags;
} ia32_hwp_capabilities_register;
/**
* Power Management Control Hints for All Logical Processors in a Package.
*
* @remarks If CPUID.06H:EAX.[11] = 1
*/
#define IA32_HWP_REQUEST_PKG 0x00000772
typedef union
{
struct
{
/**
* [Bits 7:0] Minimum_Performance.
*
* @remarks If CPUID.06H:EAX.[11] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t minimum_performance : 8;
#define IA32_HWP_REQUEST_PKG_MINIMUM_PERFORMANCE_BIT 0
#define IA32_HWP_REQUEST_PKG_MINIMUM_PERFORMANCE_FLAG 0xFF
#define IA32_HWP_REQUEST_PKG_MINIMUM_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_PKG_MINIMUM_PERFORMANCE(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Maximum_Performance.
*
* @remarks If CPUID.06H:EAX.[11] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t maximum_performance : 8;
#define IA32_HWP_REQUEST_PKG_MAXIMUM_PERFORMANCE_BIT 8
#define IA32_HWP_REQUEST_PKG_MAXIMUM_PERFORMANCE_FLAG 0xFF00
#define IA32_HWP_REQUEST_PKG_MAXIMUM_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_PKG_MAXIMUM_PERFORMANCE(_) (((_) >> 8) & 0xFF)
/**
* [Bits 23:16] Desired_Performance.
*
* @remarks If CPUID.06H:EAX.[11] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t desired_performance : 8;
#define IA32_HWP_REQUEST_PKG_DESIRED_PERFORMANCE_BIT 16
#define IA32_HWP_REQUEST_PKG_DESIRED_PERFORMANCE_FLAG 0xFF0000
#define IA32_HWP_REQUEST_PKG_DESIRED_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_PKG_DESIRED_PERFORMANCE(_) (((_) >> 16) & 0xFF)
/**
* [Bits 31:24] Energy_Performance_Preference.
*
* @remarks If CPUID.06H:EAX.[11] = 1 && CPUID.06H:EAX.[10] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t energy_performance_preference : 8;
#define IA32_HWP_REQUEST_PKG_ENERGY_PERFORMANCE_PREFERENCE_BIT 24
#define IA32_HWP_REQUEST_PKG_ENERGY_PERFORMANCE_PREFERENCE_FLAG 0xFF000000
#define IA32_HWP_REQUEST_PKG_ENERGY_PERFORMANCE_PREFERENCE_MASK 0xFF
#define IA32_HWP_REQUEST_PKG_ENERGY_PERFORMANCE_PREFERENCE(_) (((_) >> 24) & 0xFF)
/**
* [Bits 41:32] Activity_Window.
*
* @remarks If CPUID.06H:EAX.[11] = 1 && CPUID.06H:EAX.[9] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t activity_window : 10;
#define IA32_HWP_REQUEST_PKG_ACTIVITY_WINDOW_BIT 32
#define IA32_HWP_REQUEST_PKG_ACTIVITY_WINDOW_FLAG 0x3FF00000000
#define IA32_HWP_REQUEST_PKG_ACTIVITY_WINDOW_MASK 0x3FF
#define IA32_HWP_REQUEST_PKG_ACTIVITY_WINDOW(_) (((_) >> 32) & 0x3FF)
UINT64_t reserved1 : 22;
};
UINT64_t flags;
} ia32_hwp_request_pkg_register;
/**
* Control HWP Native Interrupts.
*
* @remarks If CPUID.06H:EAX.[8] = 1
*/
#define IA32_HWP_INTERRUPT 0x00000773
typedef union
{
struct
{
/**
* [Bit 0] EN_Guaranteed_Performance_Change.
*
* @remarks If CPUID.06H:EAX.[8] = 1
* @see Vol3B[14.4.6(HWP Notifications)]
*/
UINT64_t en_guaranteed_performance_change : 1;
#define IA32_HWP_INTERRUPT_EN_GUARANTEED_PERFORMANCE_CHANGE_BIT 0
#define IA32_HWP_INTERRUPT_EN_GUARANTEED_PERFORMANCE_CHANGE_FLAG 0x01
#define IA32_HWP_INTERRUPT_EN_GUARANTEED_PERFORMANCE_CHANGE_MASK 0x01
#define IA32_HWP_INTERRUPT_EN_GUARANTEED_PERFORMANCE_CHANGE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] EN_Excursion_Minimum.
*
* @remarks If CPUID.06H:EAX.[8] = 1
* @see Vol3B[14.4.6(HWP Notifications)]
*/
UINT64_t en_excursion_minimum : 1;
#define IA32_HWP_INTERRUPT_EN_EXCURSION_MINIMUM_BIT 1
#define IA32_HWP_INTERRUPT_EN_EXCURSION_MINIMUM_FLAG 0x02
#define IA32_HWP_INTERRUPT_EN_EXCURSION_MINIMUM_MASK 0x01
#define IA32_HWP_INTERRUPT_EN_EXCURSION_MINIMUM(_) (((_) >> 1) & 0x01)
UINT64_t reserved1 : 62;
};
UINT64_t flags;
} ia32_hwp_interrupt_register;
/**
* Power Management Control Hints to a Logical Processor.
*
* @remarks If CPUID.06H:EAX.[7] = 1
*/
#define IA32_HWP_REQUEST 0x00000774
typedef union
{
struct
{
/**
* [Bits 7:0] Minimum_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t minimum_performance : 8;
#define IA32_HWP_REQUEST_MINIMUM_PERFORMANCE_BIT 0
#define IA32_HWP_REQUEST_MINIMUM_PERFORMANCE_FLAG 0xFF
#define IA32_HWP_REQUEST_MINIMUM_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_MINIMUM_PERFORMANCE(_) (((_) >> 0) & 0xFF)
/**
* [Bits 15:8] Maximum_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t maximum_performance : 8;
#define IA32_HWP_REQUEST_MAXIMUM_PERFORMANCE_BIT 8
#define IA32_HWP_REQUEST_MAXIMUM_PERFORMANCE_FLAG 0xFF00
#define IA32_HWP_REQUEST_MAXIMUM_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_MAXIMUM_PERFORMANCE(_) (((_) >> 8) & 0xFF)
/**
* [Bits 23:16] Desired_Performance.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t desired_performance : 8;
#define IA32_HWP_REQUEST_DESIRED_PERFORMANCE_BIT 16
#define IA32_HWP_REQUEST_DESIRED_PERFORMANCE_FLAG 0xFF0000
#define IA32_HWP_REQUEST_DESIRED_PERFORMANCE_MASK 0xFF
#define IA32_HWP_REQUEST_DESIRED_PERFORMANCE(_) (((_) >> 16) & 0xFF)
/**
* [Bits 31:24] Energy_Performance_Preference.
*
* @remarks If CPUID.06H:EAX.[7] = 1 && CPUID.06H:EAX.[10] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t energy_performance_preference : 8;
#define IA32_HWP_REQUEST_ENERGY_PERFORMANCE_PREFERENCE_BIT 24
#define IA32_HWP_REQUEST_ENERGY_PERFORMANCE_PREFERENCE_FLAG 0xFF000000
#define IA32_HWP_REQUEST_ENERGY_PERFORMANCE_PREFERENCE_MASK 0xFF
#define IA32_HWP_REQUEST_ENERGY_PERFORMANCE_PREFERENCE(_) (((_) >> 24) & 0xFF)
/**
* [Bits 41:32] Activity_Window.
*
* @remarks If CPUID.06H:EAX.[7] = 1 && CPUID.06H:EAX.[9] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t activity_window : 10;
#define IA32_HWP_REQUEST_ACTIVITY_WINDOW_BIT 32
#define IA32_HWP_REQUEST_ACTIVITY_WINDOW_FLAG 0x3FF00000000
#define IA32_HWP_REQUEST_ACTIVITY_WINDOW_MASK 0x3FF
#define IA32_HWP_REQUEST_ACTIVITY_WINDOW(_) (((_) >> 32) & 0x3FF)
/**
* [Bit 42] Package_Control.
*
* @remarks If CPUID.06H:EAX.[7] = 1 && CPUID.06H:EAX.[11] = 1
* @see Vol3B[14.4.4(Managing HWP)]
*/
UINT64_t package_control : 1;
#define IA32_HWP_REQUEST_PACKAGE_CONTROL_BIT 42
#define IA32_HWP_REQUEST_PACKAGE_CONTROL_FLAG 0x40000000000
#define IA32_HWP_REQUEST_PACKAGE_CONTROL_MASK 0x01
#define IA32_HWP_REQUEST_PACKAGE_CONTROL(_) (((_) >> 42) & 0x01)
UINT64_t reserved1 : 21;
};
UINT64_t flags;
} ia32_hwp_request_register;
/**
* Log bits indicating changes to Guaranteed & excursions to Minimum.
*
* @remarks If CPUID.06H:EAX.[7] = 1
*/
#define IA32_HWP_STATUS 0x00000777
typedef union
{
struct
{
/**
* [Bit 0] Guaranteed_Performance_Change.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.5(HWP Feedback)]
*/
UINT64_t guaranteed_performance_change : 1;
#define IA32_HWP_STATUS_GUARANTEED_PERFORMANCE_CHANGE_BIT 0
#define IA32_HWP_STATUS_GUARANTEED_PERFORMANCE_CHANGE_FLAG 0x01
#define IA32_HWP_STATUS_GUARANTEED_PERFORMANCE_CHANGE_MASK 0x01
#define IA32_HWP_STATUS_GUARANTEED_PERFORMANCE_CHANGE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 2] Excursion_To_Minimum.
*
* @remarks If CPUID.06H:EAX.[7] = 1
* @see Vol3B[14.4.5(HWP Feedback)]
*/
UINT64_t excursion_to_minimum : 1;
#define IA32_HWP_STATUS_EXCURSION_TO_MINIMUM_BIT 2
#define IA32_HWP_STATUS_EXCURSION_TO_MINIMUM_FLAG 0x04
#define IA32_HWP_STATUS_EXCURSION_TO_MINIMUM_MASK 0x01
#define IA32_HWP_STATUS_EXCURSION_TO_MINIMUM(_) (((_) >> 2) & 0x01)
UINT64_t reserved2 : 61;
};
UINT64_t flags;
} ia32_hwp_status_register;
/**
* x2APIC ID Register.
*
* @remarks If CPUID.01H:ECX[21] = 1 && IA32_APIC_BASE.[10] = 1
* @see Vol3A[10.12(EXTENDED XAPIC (X2APIC))]
*/
#define IA32_X2APIC_APICID 0x00000802
/**
* x2APIC Version Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_VERSION 0x00000803
/**
* x2APIC Task Priority Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_TPR 0x00000808
/**
* x2APIC Processor Priority Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_PPR 0x0000080A
/**
* x2APIC EOI Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_EOI 0x0000080B
/**
* x2APIC Logical Destination Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LDR 0x0000080D
/**
* x2APIC Spurious Interrupt Vector Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_SIVR 0x0000080F
/**
* @defgroup ia32_x2apic_isr \
* IA32_X2APIC_ISR(n)
*
* x2APIC In-Service Register Bits (n * 32 + 31):(n * 32).
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
* @{
*/
#define IA32_X2APIC_ISR0 0x00000810
#define IA32_X2APIC_ISR1 0x00000811
#define IA32_X2APIC_ISR2 0x00000812
#define IA32_X2APIC_ISR3 0x00000813
#define IA32_X2APIC_ISR4 0x00000814
#define IA32_X2APIC_ISR5 0x00000815
#define IA32_X2APIC_ISR6 0x00000816
#define IA32_X2APIC_ISR7 0x00000817
/**
* @}
*/
/**
* @defgroup ia32_x2apic_tmr \
* IA32_X2APIC_TMR(n)
*
* x2APIC Trigger Mode Register Bits (n * 32 + 31):(n * 32).
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
* @{
*/
#define IA32_X2APIC_TMR0 0x00000818
#define IA32_X2APIC_TMR1 0x00000819
#define IA32_X2APIC_TMR2 0x0000081A
#define IA32_X2APIC_TMR3 0x0000081B
#define IA32_X2APIC_TMR4 0x0000081C
#define IA32_X2APIC_TMR5 0x0000081D
#define IA32_X2APIC_TMR6 0x0000081E
#define IA32_X2APIC_TMR7 0x0000081F
/**
* @}
*/
/**
* @defgroup ia32_x2apic_irr \
* IA32_X2APIC_IRR(n)
*
* x2APIC Interrupt Request Register Bits (n * 32 + 31):(n * 32).
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
* @{
*/
#define IA32_X2APIC_IRR0 0x00000820
#define IA32_X2APIC_IRR1 0x00000821
#define IA32_X2APIC_IRR2 0x00000822
#define IA32_X2APIC_IRR3 0x00000823
#define IA32_X2APIC_IRR4 0x00000824
#define IA32_X2APIC_IRR5 0x00000825
#define IA32_X2APIC_IRR6 0x00000826
#define IA32_X2APIC_IRR7 0x00000827
/**
* @}
*/
/**
* x2APIC Error Status Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_ESR 0x00000828
/**
* x2APIC LVT Corrected Machine Check Interrupt Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_CMCI 0x0000082F
/**
* x2APIC Interrupt Command Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_ICR 0x00000830
/**
* x2APIC LVT Timer Interrupt Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_TIMER 0x00000832
/**
* x2APIC LVT Thermal Sensor Interrupt Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_THERMAL 0x00000833
/**
* x2APIC LVT Performance Monitor Interrupt Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_PMI 0x00000834
/**
* x2APIC LVT LINT0 Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_LINT0 0x00000835
/**
* x2APIC LVT LINT1 Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_LINT1 0x00000836
/**
* x2APIC LVT Error Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_LVT_ERROR 0x00000837
/**
* x2APIC Initial Count Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_INIT_COUNT 0x00000838
/**
* x2APIC Current Count Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_CUR_COUNT 0x00000839
/**
* x2APIC Divide Configuration Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_DIV_CONF 0x0000083E
/**
* x2APIC Self IPI Register.
*
* @remarks If CPUID.01H:ECX.[21] = 1 && IA32_APIC_BASE.[10] = 1
*/
#define IA32_X2APIC_SELF_IPI 0x0000083F
/**
* Silicon Debug Feature Control.
*
* @remarks If CPUID.01H:ECX.[11] = 1
*/
#define IA32_DEBUG_INTERFACE 0x00000C80
typedef union
{
struct
{
/**
* @brief Enable <b>(R/W)</b>
*
* [Bit 0] BIOS set 1 to enable Silicon debug features. Default is 0.
*
* @remarks If CPUID.01H:ECX.[11] = 1
*/
UINT64_t enable : 1;
#define IA32_DEBUG_INTERFACE_ENABLE_BIT 0
#define IA32_DEBUG_INTERFACE_ENABLE_FLAG 0x01
#define IA32_DEBUG_INTERFACE_ENABLE_MASK 0x01
#define IA32_DEBUG_INTERFACE_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 29;
/**
* @brief Lock <b>(R/W)</b>
*
* [Bit 30] If 1, locks any further change to the MSR. The lock bit is set automatically on the first SMI assertion even if
* not explicitly set by BIOS. Default is 0.
*
* @remarks If CPUID.01H:ECX.[11] = 1
*/
UINT64_t lock : 1;
#define IA32_DEBUG_INTERFACE_LOCK_BIT 30
#define IA32_DEBUG_INTERFACE_LOCK_FLAG 0x40000000
#define IA32_DEBUG_INTERFACE_LOCK_MASK 0x01
#define IA32_DEBUG_INTERFACE_LOCK(_) (((_) >> 30) & 0x01)
/**
* @brief Debug Occurred <b>(R/O)</b>
*
* [Bit 31] This "sticky bit" is set by hardware to indicate the status of bit 0. Default is 0.
*
* @remarks If CPUID.01H:ECX.[11] = 1
*/
UINT64_t debug_occurred : 1;
#define IA32_DEBUG_INTERFACE_DEBUG_OCCURRED_BIT 31
#define IA32_DEBUG_INTERFACE_DEBUG_OCCURRED_FLAG 0x80000000
#define IA32_DEBUG_INTERFACE_DEBUG_OCCURRED_MASK 0x01
#define IA32_DEBUG_INTERFACE_DEBUG_OCCURRED(_) (((_) >> 31) & 0x01)
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} ia32_debug_interface_register;
/**
* L3 QOS Configuration.
*
* @remarks If ( CPUID.(EAX=10H, ECX=1):ECX.[2] = 1 )
*/
#define IA32_L3_QOS_CFG 0x00000C81
typedef union
{
struct
{
/**
* @brief Enable <b>(R/W)</b>
*
* [Bit 0] Set 1 to enable L3 CAT masks and COS to operate in Code and Data Prioritization (CDP) mode.
*/
UINT64_t enable : 1;
#define IA32_L3_QOS_CFG_ENABLE_BIT 0
#define IA32_L3_QOS_CFG_ENABLE_FLAG 0x01
#define IA32_L3_QOS_CFG_ENABLE_MASK 0x01
#define IA32_L3_QOS_CFG_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_l3_qos_cfg_register;
/**
* L2 QOS Configuration.
*
* @remarks If ( CPUID.(EAX=10H, ECX=2):ECX.[2] = 1 )
*/
#define IA32_L2_QOS_CFG 0x00000C82
typedef union
{
struct
{
/**
* @brief Enable <b>(R/W)</b>
*
* [Bit 0] Set 1 to enable L2 CAT masks and COS to operate in Code and Data Prioritization (CDP) mode.
*/
UINT64_t enable : 1;
#define IA32_L2_QOS_CFG_ENABLE_BIT 0
#define IA32_L2_QOS_CFG_ENABLE_FLAG 0x01
#define IA32_L2_QOS_CFG_ENABLE_MASK 0x01
#define IA32_L2_QOS_CFG_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_l2_qos_cfg_register;
/**
* Monitoring Event Select Register.
*
* @remarks If ( CPUID.(EAX=07H, ECX=0):EBX.[12] = 1 )
*/
#define IA32_QM_EVTSEL 0x00000C8D
typedef union
{
struct
{
/**
* @brief Event ID
*
* [Bits 7:0] ID of a supported monitoring event to report via IA32_QM_CTR.
*/
UINT64_t event_id : 8;
#define IA32_QM_EVTSEL_EVENT_ID_BIT 0
#define IA32_QM_EVTSEL_EVENT_ID_FLAG 0xFF
#define IA32_QM_EVTSEL_EVENT_ID_MASK 0xFF
#define IA32_QM_EVTSEL_EVENT_ID(_) (((_) >> 0) & 0xFF)
UINT64_t reserved1 : 24;
/**
* @brief Resource Monitoring ID
*
* [Bits 63:32] ID for monitoring hardware to report monitored data via IA32_QM_CTR.
*
* @remarks Bits [N+31:32] N = Ceil (Log2 (CPUID.(EAX= 0FH,ECX=0H).EBX[31:0] + 1))
*/
UINT64_t resource_monitoring_id : 32;
#define IA32_QM_EVTSEL_RESOURCE_MONITORING_ID_BIT 32
#define IA32_QM_EVTSEL_RESOURCE_MONITORING_ID_FLAG 0xFFFFFFFF00000000
#define IA32_QM_EVTSEL_RESOURCE_MONITORING_ID_MASK 0xFFFFFFFF
#define IA32_QM_EVTSEL_RESOURCE_MONITORING_ID(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_qm_evtsel_register;
/**
* Monitoring Counter Register.
*
* @remarks If ( CPUID.(EAX=07H, ECX=0):EBX.[12] = 1 )
*/
#define IA32_QM_CTR 0x00000C8E
typedef union
{
struct
{
/**
* [Bits 61:0] Resource Monitored Data.
*/
UINT64_t resource_monitored_data : 62;
#define IA32_QM_CTR_RESOURCE_MONITORED_DATA_BIT 0
#define IA32_QM_CTR_RESOURCE_MONITORED_DATA_FLAG 0x3FFFFFFFFFFFFFFF
#define IA32_QM_CTR_RESOURCE_MONITORED_DATA_MASK 0x3FFFFFFFFFFFFFFF
#define IA32_QM_CTR_RESOURCE_MONITORED_DATA(_) (((_) >> 0) & 0x3FFFFFFFFFFFFFFF)
/**
* @brief Unavailable
*
* [Bit 62] If 1, indicates data for this RMID is not available or not monitored for this resource or RMID.
*/
UINT64_t unavailable : 1;
#define IA32_QM_CTR_UNAVAILABLE_BIT 62
#define IA32_QM_CTR_UNAVAILABLE_FLAG 0x4000000000000000
#define IA32_QM_CTR_UNAVAILABLE_MASK 0x01
#define IA32_QM_CTR_UNAVAILABLE(_) (((_) >> 62) & 0x01)
/**
* @brief Error
*
* [Bit 63] If 1, indicates an unsupported RMID or event type was written to IA32_PQR_QM_EVTSEL.
*/
UINT64_t error : 1;
#define IA32_QM_CTR_ERROR_BIT 63
#define IA32_QM_CTR_ERROR_FLAG 0x8000000000000000
#define IA32_QM_CTR_ERROR_MASK 0x01
#define IA32_QM_CTR_ERROR(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} ia32_qm_ctr_register;
/**
* Resource Association Register.
*
* @remarks If ( (CPUID.(EAX=07H, ECX=0):EBX[12] = 1) or (CPUID.(EAX=07H, ECX=0):EBX[15] = 1 ) )
*/
#define IA32_PQR_ASSOC 0x00000C8F
typedef union
{
struct
{
/**
* @brief Resource Monitoring ID <b>(R/W)</b>
*
* [Bits 31:0] ID for monitoring hardware to track internal operation, e.g., memory access.
*
* @remarks Bits [N-1:0] N = Ceil (Log2 (CPUID.(EAX= 0FH, ECX=0H).EBX[31:0] +1)) 31:N Reserved
*/
UINT64_t resource_monitoring_id : 32;
#define IA32_PQR_ASSOC_RESOURCE_MONITORING_ID_BIT 0
#define IA32_PQR_ASSOC_RESOURCE_MONITORING_ID_FLAG 0xFFFFFFFF
#define IA32_PQR_ASSOC_RESOURCE_MONITORING_ID_MASK 0xFFFFFFFF
#define IA32_PQR_ASSOC_RESOURCE_MONITORING_ID(_) (((_) >> 0) & 0xFFFFFFFF)
/**
* @brief COS <b>(R/W)</b>
*
* [Bits 63:32] The class of service (COS) to enforce (on writes); returns the current COS when read.
*
* @remarks If ( CPUID.(EAX=07H, ECX=0):EBX.[15] = 1 )
*/
UINT64_t cos : 32;
#define IA32_PQR_ASSOC_COS_BIT 32
#define IA32_PQR_ASSOC_COS_FLAG 0xFFFFFFFF00000000
#define IA32_PQR_ASSOC_COS_MASK 0xFFFFFFFF
#define IA32_PQR_ASSOC_COS(_) (((_) >> 32) & 0xFFFFFFFF)
};
UINT64_t flags;
} ia32_pqr_assoc_register;
/**
* Supervisor State of MPX Configuration.
*
* @remarks If (CPUID.(EAX=07H, ECX=0H):EBX[14] = 1)
*/
#define IA32_BNDCFGS 0x00000D90
typedef union
{
struct
{
/**
* [Bit 0] Enable Intel MPX in supervisor mode.
*/
UINT64_t enable : 1;
#define IA32_BNDCFGS_ENABLE_BIT 0
#define IA32_BNDCFGS_ENABLE_FLAG 0x01
#define IA32_BNDCFGS_ENABLE_MASK 0x01
#define IA32_BNDCFGS_ENABLE(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Preserve the bounds registers for near branch instructions in the absence of the BND prefix.
*/
UINT64_t bnd_preserve : 1;
#define IA32_BNDCFGS_BND_PRESERVE_BIT 1
#define IA32_BNDCFGS_BND_PRESERVE_FLAG 0x02
#define IA32_BNDCFGS_BND_PRESERVE_MASK 0x01
#define IA32_BNDCFGS_BND_PRESERVE(_) (((_) >> 1) & 0x01)
UINT64_t reserved1 : 10;
/**
* [Bits 63:12] Base Address of Bound Directory.
*/
UINT64_t bound_directory_base_address : 52;
#define IA32_BNDCFGS_BOUND_DIRECTORY_BASE_ADDRESS_BIT 12
#define IA32_BNDCFGS_BOUND_DIRECTORY_BASE_ADDRESS_FLAG 0xFFFFFFFFFFFFF000
#define IA32_BNDCFGS_BOUND_DIRECTORY_BASE_ADDRESS_MASK 0xFFFFFFFFFFFFF
#define IA32_BNDCFGS_BOUND_DIRECTORY_BASE_ADDRESS(_) (((_) >> 12) & 0xFFFFFFFFFFFFF)
};
UINT64_t flags;
} ia32_bndcfgs_register;
/**
* Extended Supervisor State Mask.
*
* @remarks If ( CPUID.(0DH, 1):EAX.[3] = 1
*/
#define IA32_XSS 0x00000DA0
typedef union
{
struct
{
UINT64_t reserved1 : 8;
/**
* [Bit 8] Trace Packet Configuration State.
*/
UINT64_t trace_packet_configuration_state : 1;
#define IA32_XSS_TRACE_PACKET_CONFIGURATION_STATE_BIT 8
#define IA32_XSS_TRACE_PACKET_CONFIGURATION_STATE_FLAG 0x100
#define IA32_XSS_TRACE_PACKET_CONFIGURATION_STATE_MASK 0x01
#define IA32_XSS_TRACE_PACKET_CONFIGURATION_STATE(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 55;
};
UINT64_t flags;
} ia32_xss_register;
/**
* Package Level Enable/disable HDC.
*
* @remarks If CPUID.06H:EAX.[13] = 1
*/
#define IA32_PKG_HDC_CTL 0x00000DB0
typedef union
{
struct
{
/**
* @brief HDC_Pkg_Enable <b>(R/W)</b>
*
* [Bit 0] Force HDC idling or wake up HDC-idled logical processors in the package.
*
* @remarks If CPUID.06H:EAX.[13] = 1
* @see Vol3B[14.5.2(Package level Enabling HDC)]
*/
UINT64_t hdc_pkg_enable : 1;
#define IA32_PKG_HDC_CTL_HDC_PKG_ENABLE_BIT 0
#define IA32_PKG_HDC_CTL_HDC_PKG_ENABLE_FLAG 0x01
#define IA32_PKG_HDC_CTL_HDC_PKG_ENABLE_MASK 0x01
#define IA32_PKG_HDC_CTL_HDC_PKG_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_pkg_hdc_ctl_register;
/**
* Enable/disable HWP.
*
* @remarks If CPUID.06H:EAX.[13] = 1
*/
#define IA32_PM_CTL1 0x00000DB1
typedef union
{
struct
{
/**
* @brief HDC_Allow_Block <b>(R/W)</b>
*
* [Bit 0] Allow/Block this logical processor for package level HDC control.
*
* @remarks If CPUID.06H:EAX.[13] = 1
* @see Vol3B[14.5.3(Logical-Processor Level HDC Control)]
*/
UINT64_t hdc_allow_block : 1;
#define IA32_PM_CTL1_HDC_ALLOW_BLOCK_BIT 0
#define IA32_PM_CTL1_HDC_ALLOW_BLOCK_FLAG 0x01
#define IA32_PM_CTL1_HDC_ALLOW_BLOCK_MASK 0x01
#define IA32_PM_CTL1_HDC_ALLOW_BLOCK(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 63;
};
UINT64_t flags;
} ia32_pm_ctl1_register;
/**
* Per-Logical_Processor HDC Idle Residency.
*
* @remarks If CPUID.06H:EAX.[13] = 1
*/
#define IA32_THREAD_STALL 0x00000DB2
typedef struct
{
/**
* @brief Stall_Cycle_Cnt <b>(R/W)</b>
*
* Stalled cycles due to HDC forced idle on this logical processor.
*
* @remarks If CPUID.06H:EAX.[13] = 1
* @see Vol3B[14.5.4.1(IA32_THREAD_STALL)]
*/
UINT64_t stall_cycle_count;
} ia32_thread_stall_register;
/**
* Extended Feature Enables.
*
* @remarks If CPUID.06H:EAX.[13] = 1
*/
#define IA32_EFER 0xC0000080
typedef union
{
struct
{
/**
* @brief SYSCALL Enable <b>(R/W)</b>
*
* [Bit 0] Enables SYSCALL/SYSRET instructions in 64-bit mode.
*/
UINT64_t syscall_enable : 1;
#define IA32_EFER_SYSCALL_ENABLE_BIT 0
#define IA32_EFER_SYSCALL_ENABLE_FLAG 0x01
#define IA32_EFER_SYSCALL_ENABLE_MASK 0x01
#define IA32_EFER_SYSCALL_ENABLE(_) (((_) >> 0) & 0x01)
UINT64_t reserved1 : 7;
/**
* @brief IA-32e Mode Enable <b>(R/W)</b>
*
* [Bit 8] Enables IA-32e mode operation.
*/
UINT64_t ia32e_mode_enable : 1;
#define IA32_EFER_IA32E_MODE_ENABLE_BIT 8
#define IA32_EFER_IA32E_MODE_ENABLE_FLAG 0x100
#define IA32_EFER_IA32E_MODE_ENABLE_MASK 0x01
#define IA32_EFER_IA32E_MODE_ENABLE(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief IA-32e Mode Active <b>(R)</b>
*
* [Bit 10] Indicates IA-32e mode is active when set.
*/
UINT64_t ia32e_mode_active : 1;
#define IA32_EFER_IA32E_MODE_ACTIVE_BIT 10
#define IA32_EFER_IA32E_MODE_ACTIVE_FLAG 0x400
#define IA32_EFER_IA32E_MODE_ACTIVE_MASK 0x01
#define IA32_EFER_IA32E_MODE_ACTIVE(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] Execute Disable Bit Enable.
*/
UINT64_t execute_disable_bit_enable : 1;
#define IA32_EFER_EXECUTE_DISABLE_BIT_ENABLE_BIT 11
#define IA32_EFER_EXECUTE_DISABLE_BIT_ENABLE_FLAG 0x800
#define IA32_EFER_EXECUTE_DISABLE_BIT_ENABLE_MASK 0x01
#define IA32_EFER_EXECUTE_DISABLE_BIT_ENABLE(_) (((_) >> 11) & 0x01)
UINT64_t reserved3 : 52;
};
UINT64_t flags;
} ia32_efer_register;
/**
* System Call Target Address.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_STAR 0xC0000081
/**
* @brief IA-32e Mode System Call Target Address <b>(R/W)</b>
*
* Target RIP for the called procedure when SYSCALL is executed in 64-bit mode.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_LSTAR 0xC0000082
/**
* @brief IA-32e Mode System Call Target Address <b>(R/W)</b>
*
* Not used, as the SYSCALL instruction is not recognized in compatibility mode.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_CSTAR 0xC0000083
/**
* System Call Flag Mask.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_FMASK 0xC0000084
/**
* Map of BASE Address of FS.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_FS_BASE 0xC0000100
/**
* Map of BASE Address of GS.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_GS_BASE 0xC0000101
/**
* Swap Target of BASE Address of GS.
*
* @remarks If CPUID.80000001:EDX.[29] = 1
*/
#define IA32_KERNEL_GS_BASE 0xC0000102
/**
* Auxiliary TSC.
*
* @remarks If CPUID.80000001H: EDX[27] = 1 or CPUID.(EAX=7,ECX=0):ECX[bit 22] = 1
*/
#define IA32_TSC_AUX 0xC0000103
typedef union
{
struct
{
/**
* [Bits 31:0] AUX. Auxiliary signature of TSC.
*/
UINT64_t tsc_auxiliary_signature : 32;
#define IA32_TSC_AUX_TSC_AUXILIARY_SIGNATURE_BIT 0
#define IA32_TSC_AUX_TSC_AUXILIARY_SIGNATURE_FLAG 0xFFFFFFFF
#define IA32_TSC_AUX_TSC_AUXILIARY_SIGNATURE_MASK 0xFFFFFFFF
#define IA32_TSC_AUX_TSC_AUXILIARY_SIGNATURE(_) (((_) >> 0) & 0xFFFFFFFF)
UINT64_t reserved1 : 32;
};
UINT64_t flags;
} ia32_tsc_aux_register;
/**
* @}
*/
/**
* @defgroup paging \
* Paging
* @{
*/
/**
* @defgroup paging_32 \
* 32-Bit Paging
*
* A logical processor uses 32-bit paging if CR0.PG = 1 and CR4.PAE = 0. 32-bit paging translates 32-bit linear addresses
* to 40-bit physical addresses. Although 40 bits corresponds to 1 TByte, linear addresses are limited to 32 bits; at most
* 4 GBytes of linear-address space may be accessed at any given time.
* 32-bit paging uses a hierarchy of paging structures to produce a translation for a linear address. CR3 is used to locate
* the first paging-structure, the page directory. 32-bit paging may map linear addresses to either 4-KByte pages or
* 4-MByte pages.
*
* @see Vol3A[4.5(4-LEVEL PAGING)] (reference)
* @{
*/
/**
* @brief Format of a 32-Bit Page-Directory Entry that Maps a 4-MByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to map a 4-MByte page.
*/
UINT32_t present : 1;
#define PDE_4MB_32_PRESENT_BIT 0
#define PDE_4MB_32_PRESENT_FLAG 0x01
#define PDE_4MB_32_PRESENT_MASK 0x01
#define PDE_4MB_32_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 4-MByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t write : 1;
#define PDE_4MB_32_WRITE_BIT 1
#define PDE_4MB_32_WRITE_FLAG 0x02
#define PDE_4MB_32_WRITE_MASK 0x01
#define PDE_4MB_32_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 4-MByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t supervisor : 1;
#define PDE_4MB_32_SUPERVISOR_BIT 2
#define PDE_4MB_32_SUPERVISOR_FLAG 0x04
#define PDE_4MB_32_SUPERVISOR_MASK 0x01
#define PDE_4MB_32_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the 4-MByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_write_through : 1;
#define PDE_4MB_32_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDE_4MB_32_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDE_4MB_32_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDE_4MB_32_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the 4-MByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_cache_disable : 1;
#define PDE_4MB_32_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDE_4MB_32_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDE_4MB_32_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDE_4MB_32_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether software has accessed the 4-MByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT32_t accessed : 1;
#define PDE_4MB_32_ACCESSED_BIT 5
#define PDE_4MB_32_ACCESSED_FLAG 0x20
#define PDE_4MB_32_ACCESSED_MASK 0x01
#define PDE_4MB_32_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Dirty; indicates whether software has written to the 4-MByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT32_t dirty : 1;
#define PDE_4MB_32_DIRTY_BIT 6
#define PDE_4MB_32_DIRTY_FLAG 0x40
#define PDE_4MB_32_DIRTY_MASK 0x01
#define PDE_4MB_32_DIRTY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Page size; must be 1 (otherwise, this entry references a page table).
*/
UINT32_t large_page : 1;
#define PDE_4MB_32_LARGE_PAGE_BIT 7
#define PDE_4MB_32_LARGE_PAGE_FLAG 0x80
#define PDE_4MB_32_LARGE_PAGE_MASK 0x01
#define PDE_4MB_32_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Global; if CR4.PGE = 1, determines whether the translation is global; ignored otherwise.
*
* @see Vol3A[4.10(Caching Translation Information)]
*/
UINT32_t global : 1;
#define PDE_4MB_32_GLOBAL_BIT 8
#define PDE_4MB_32_GLOBAL_FLAG 0x100
#define PDE_4MB_32_GLOBAL_MASK 0x01
#define PDE_4MB_32_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT32_t ignored_1 : 3;
#define PDE_4MB_32_IGNORED_1_BIT 9
#define PDE_4MB_32_IGNORED_1_FLAG 0xE00
#define PDE_4MB_32_IGNORED_1_MASK 0x07
#define PDE_4MB_32_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bit 12] Indirectly determines the memory type used to access the 4-MByte page referenced by this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t pat : 1;
#define PDE_4MB_32_PAT_BIT 12
#define PDE_4MB_32_PAT_FLAG 0x1000
#define PDE_4MB_32_PAT_MASK 0x01
#define PDE_4MB_32_PAT(_) (((_) >> 12) & 0x01)
/**
* [Bits 20:13] Bits (M-1):32 of physical address of the 4-MByte page referenced by this entry.
*/
UINT32_t page_frame_number_low : 8;
#define PDE_4MB_32_PAGE_FRAME_NUMBER_LOW_BIT 13
#define PDE_4MB_32_PAGE_FRAME_NUMBER_LOW_FLAG 0x1FE000
#define PDE_4MB_32_PAGE_FRAME_NUMBER_LOW_MASK 0xFF
#define PDE_4MB_32_PAGE_FRAME_NUMBER_LOW(_) (((_) >> 13) & 0xFF)
UINT32_t reserved1 : 1;
/**
* [Bits 31:22] Bits 31:22 of physical address of the 4-MByte page referenced by this entry.
*/
UINT32_t page_frame_number_high : 10;
#define PDE_4MB_32_PAGE_FRAME_NUMBER_HIGH_BIT 22
#define PDE_4MB_32_PAGE_FRAME_NUMBER_HIGH_FLAG 0xFFC00000
#define PDE_4MB_32_PAGE_FRAME_NUMBER_HIGH_MASK 0x3FF
#define PDE_4MB_32_PAGE_FRAME_NUMBER_HIGH(_) (((_) >> 22) & 0x3FF)
};
UINT32_t flags;
} pde_4mb_32;
/**
* @brief Format of a 32-Bit Page-Directory Entry that References a Page Table
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to reference a page table.
*/
UINT32_t present : 1;
#define PDE_32_PRESENT_BIT 0
#define PDE_32_PRESENT_FLAG 0x01
#define PDE_32_PRESENT_MASK 0x01
#define PDE_32_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 4-MByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t write : 1;
#define PDE_32_WRITE_BIT 1
#define PDE_32_WRITE_FLAG 0x02
#define PDE_32_WRITE_MASK 0x01
#define PDE_32_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 4-MByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t supervisor : 1;
#define PDE_32_SUPERVISOR_BIT 2
#define PDE_32_SUPERVISOR_FLAG 0x04
#define PDE_32_SUPERVISOR_MASK 0x01
#define PDE_32_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the page table referenced by this
* entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_write_through : 1;
#define PDE_32_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDE_32_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDE_32_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDE_32_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the page table referenced by this
* entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_cache_disable : 1;
#define PDE_32_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDE_32_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDE_32_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDE_32_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether this entry has been used for linear-address translation.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT32_t accessed : 1;
#define PDE_32_ACCESSED_BIT 5
#define PDE_32_ACCESSED_FLAG 0x20
#define PDE_32_ACCESSED_MASK 0x01
#define PDE_32_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Ignored.
*/
UINT32_t ignored_1 : 1;
#define PDE_32_IGNORED_1_BIT 6
#define PDE_32_IGNORED_1_FLAG 0x40
#define PDE_32_IGNORED_1_MASK 0x01
#define PDE_32_IGNORED_1(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] If CR4.PSE = 1, must be 0 (otherwise, this entry maps a 4-MByte page); otherwise, ignored.
*/
UINT32_t large_page : 1;
#define PDE_32_LARGE_PAGE_BIT 7
#define PDE_32_LARGE_PAGE_FLAG 0x80
#define PDE_32_LARGE_PAGE_MASK 0x01
#define PDE_32_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bits 11:8] Ignored.
*/
UINT32_t ignored_2 : 4;
#define PDE_32_IGNORED_2_BIT 8
#define PDE_32_IGNORED_2_FLAG 0xF00
#define PDE_32_IGNORED_2_MASK 0x0F
#define PDE_32_IGNORED_2(_) (((_) >> 8) & 0x0F)
/**
* [Bits 31:12] Physical address of 4-KByte aligned page table referenced by this entry.
*/
UINT32_t page_frame_number : 20;
#define PDE_32_PAGE_FRAME_NUMBER_BIT 12
#define PDE_32_PAGE_FRAME_NUMBER_FLAG 0xFFFFF000
#define PDE_32_PAGE_FRAME_NUMBER_MASK 0xFFFFF
#define PDE_32_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFF)
};
UINT32_t flags;
} pde_32;
/**
* @brief Format of a 32-Bit Page-Table Entry that Maps a 4-KByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to map a 4-KByte page.
*/
UINT32_t present : 1;
#define PTE_32_PRESENT_BIT 0
#define PTE_32_PRESENT_FLAG 0x01
#define PTE_32_PRESENT_MASK 0x01
#define PTE_32_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t write : 1;
#define PTE_32_WRITE_BIT 1
#define PTE_32_WRITE_FLAG 0x02
#define PTE_32_WRITE_MASK 0x01
#define PTE_32_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT32_t supervisor : 1;
#define PTE_32_SUPERVISOR_BIT 2
#define PTE_32_SUPERVISOR_FLAG 0x04
#define PTE_32_SUPERVISOR_MASK 0x01
#define PTE_32_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the 4-KByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_write_through : 1;
#define PTE_32_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PTE_32_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PTE_32_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PTE_32_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the 4-KByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t page_level_cache_disable : 1;
#define PTE_32_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PTE_32_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PTE_32_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PTE_32_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether software has accessed the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT32_t accessed : 1;
#define PTE_32_ACCESSED_BIT 5
#define PTE_32_ACCESSED_FLAG 0x20
#define PTE_32_ACCESSED_MASK 0x01
#define PTE_32_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Dirty; indicates whether software has written to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT32_t dirty : 1;
#define PTE_32_DIRTY_BIT 6
#define PTE_32_DIRTY_FLAG 0x40
#define PTE_32_DIRTY_MASK 0x01
#define PTE_32_DIRTY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Indirectly determines the memory type used to access the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT32_t pat : 1;
#define PTE_32_PAT_BIT 7
#define PTE_32_PAT_FLAG 0x80
#define PTE_32_PAT_MASK 0x01
#define PTE_32_PAT(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Global; if CR4.PGE = 1, determines whether the translation is global; ignored otherwise.
*
* @see Vol3A[4.10(Caching Translation Information)]
*/
UINT32_t global : 1;
#define PTE_32_GLOBAL_BIT 8
#define PTE_32_GLOBAL_FLAG 0x100
#define PTE_32_GLOBAL_MASK 0x01
#define PTE_32_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT32_t ignored_1 : 3;
#define PTE_32_IGNORED_1_BIT 9
#define PTE_32_IGNORED_1_FLAG 0xE00
#define PTE_32_IGNORED_1_MASK 0x07
#define PTE_32_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bits 31:12] Physical address of 4-KByte aligned page table referenced by this entry.
*/
UINT32_t page_frame_number : 20;
#define PTE_32_PAGE_FRAME_NUMBER_BIT 12
#define PTE_32_PAGE_FRAME_NUMBER_FLAG 0xFFFFF000
#define PTE_32_PAGE_FRAME_NUMBER_MASK 0xFFFFF
#define PTE_32_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFF)
};
UINT32_t flags;
} pte_32;
/**
* @brief Format of a common Page-Table Entry
*/
typedef union
{
struct
{
UINT32_t present : 1;
#define PT_ENTRY_32_PRESENT_BIT 0
#define PT_ENTRY_32_PRESENT_FLAG 0x01
#define PT_ENTRY_32_PRESENT_MASK 0x01
#define PT_ENTRY_32_PRESENT(_) (((_) >> 0) & 0x01)
UINT32_t write : 1;
#define PT_ENTRY_32_WRITE_BIT 1
#define PT_ENTRY_32_WRITE_FLAG 0x02
#define PT_ENTRY_32_WRITE_MASK 0x01
#define PT_ENTRY_32_WRITE(_) (((_) >> 1) & 0x01)
UINT32_t supervisor : 1;
#define PT_ENTRY_32_SUPERVISOR_BIT 2
#define PT_ENTRY_32_SUPERVISOR_FLAG 0x04
#define PT_ENTRY_32_SUPERVISOR_MASK 0x01
#define PT_ENTRY_32_SUPERVISOR(_) (((_) >> 2) & 0x01)
UINT32_t page_level_write_through : 1;
#define PT_ENTRY_32_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PT_ENTRY_32_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PT_ENTRY_32_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PT_ENTRY_32_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
UINT32_t page_level_cache_disable : 1;
#define PT_ENTRY_32_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PT_ENTRY_32_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PT_ENTRY_32_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PT_ENTRY_32_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
UINT32_t accessed : 1;
#define PT_ENTRY_32_ACCESSED_BIT 5
#define PT_ENTRY_32_ACCESSED_FLAG 0x20
#define PT_ENTRY_32_ACCESSED_MASK 0x01
#define PT_ENTRY_32_ACCESSED(_) (((_) >> 5) & 0x01)
UINT32_t dirty : 1;
#define PT_ENTRY_32_DIRTY_BIT 6
#define PT_ENTRY_32_DIRTY_FLAG 0x40
#define PT_ENTRY_32_DIRTY_MASK 0x01
#define PT_ENTRY_32_DIRTY(_) (((_) >> 6) & 0x01)
UINT32_t large_page : 1;
#define PT_ENTRY_32_LARGE_PAGE_BIT 7
#define PT_ENTRY_32_LARGE_PAGE_FLAG 0x80
#define PT_ENTRY_32_LARGE_PAGE_MASK 0x01
#define PT_ENTRY_32_LARGE_PAGE(_) (((_) >> 7) & 0x01)
UINT32_t global : 1;
#define PT_ENTRY_32_GLOBAL_BIT 8
#define PT_ENTRY_32_GLOBAL_FLAG 0x100
#define PT_ENTRY_32_GLOBAL_MASK 0x01
#define PT_ENTRY_32_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT32_t ignored_1 : 3;
#define PT_ENTRY_32_IGNORED_1_BIT 9
#define PT_ENTRY_32_IGNORED_1_FLAG 0xE00
#define PT_ENTRY_32_IGNORED_1_MASK 0x07
#define PT_ENTRY_32_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bits 31:12] Physical address of the 4-KByte page referenced by this entry.
*/
UINT32_t page_frame_number : 20;
#define PT_ENTRY_32_PAGE_FRAME_NUMBER_BIT 12
#define PT_ENTRY_32_PAGE_FRAME_NUMBER_FLAG 0xFFFFF000
#define PT_ENTRY_32_PAGE_FRAME_NUMBER_MASK 0xFFFFF
#define PT_ENTRY_32_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFF)
};
UINT32_t flags;
} pt_entry_32;
/**
* @defgroup paging_structures_entry_count_32 \
* Paging structures entry counts
*
* Paging structures entry counts.
* @{
*/
#define PDE_ENTRY_COUNT_32 0x00000400
#define PTE_ENTRY_COUNT_32 0x00000400
/**
* @}
*/
/**
* @}
*/
/**
* @defgroup paging_64 \
* 64-Bit (4-Level) Paging
*
* A logical processor uses 4-level paging if CR0.PG = 1, CR4.PAE = 1, and IA32_EFER.LME = 1. With 4-level paging, linear
* address are translated using a hierarchy of in-memory paging structures located using the contents of CR3. 4-level
* paging translates 48-bit linear addresses to 52-bit physical addresses. Although 52 bits corresponds to 4 PBytes, linear
* addresses are limited to 48 bits; at most 256 TBytes of linear-address space may be accessed at any given time.
* 4-level paging uses a hierarchy of paging structures to produce a translation for a linear address. CR3 is used to
* locate the first paging-structure, the PML4 table. Use of CR3 with 4-level paging depends on whether processcontext
* identifiers (PCIDs) have been enabled by setting CR4.PCIDE.
*
* @see Vol3A[4.5(4-LEVEL PAGING)] (reference)
* @{
*/
/**
* @brief Format of a 4-Level PML4 Entry (PML4E) that References a Page-Directory-Pointer Table
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to reference a page-directory-pointer table.
*/
UINT64_t present : 1;
#define PML4E_64_PRESENT_BIT 0
#define PML4E_64_PRESENT_FLAG 0x01
#define PML4E_64_PRESENT_MASK 0x01
#define PML4E_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 512-GByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PML4E_64_WRITE_BIT 1
#define PML4E_64_WRITE_FLAG 0x02
#define PML4E_64_WRITE_MASK 0x01
#define PML4E_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 512-GByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PML4E_64_SUPERVISOR_BIT 2
#define PML4E_64_SUPERVISOR_FLAG 0x04
#define PML4E_64_SUPERVISOR_MASK 0x01
#define PML4E_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the page-directory-pointer table
* referenced by this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PML4E_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PML4E_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PML4E_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PML4E_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the page-directory-pointer table
* referenced by this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PML4E_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PML4E_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PML4E_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PML4E_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether this entry has been used for linear-address translation.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PML4E_64_ACCESSED_BIT 5
#define PML4E_64_ACCESSED_FLAG 0x20
#define PML4E_64_ACCESSED_MASK 0x01
#define PML4E_64_ACCESSED(_) (((_) >> 5) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 7] Reserved (must be 0).
*/
UINT64_t must_be_zero : 1;
#define PML4E_64_MUST_BE_ZERO_BIT 7
#define PML4E_64_MUST_BE_ZERO_FLAG 0x80
#define PML4E_64_MUST_BE_ZERO_MASK 0x01
#define PML4E_64_MUST_BE_ZERO(_) (((_) >> 7) & 0x01)
/**
* [Bits 11:8] Ignored.
*/
UINT64_t ignored_1 : 4;
#define PML4E_64_IGNORED_1_BIT 8
#define PML4E_64_IGNORED_1_FLAG 0xF00
#define PML4E_64_IGNORED_1_MASK 0x0F
#define PML4E_64_IGNORED_1(_) (((_) >> 8) & 0x0F)
/**
* [Bits 47:12] Physical address of 4-KByte aligned page-directory-pointer table referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define PML4E_64_PAGE_FRAME_NUMBER_BIT 12
#define PML4E_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define PML4E_64_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define PML4E_64_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 4;
/**
* [Bits 62:52] Ignored.
*/
UINT64_t ignored_2 : 11;
#define PML4E_64_IGNORED_2_BIT 52
#define PML4E_64_IGNORED_2_FLAG 0x7FF0000000000000
#define PML4E_64_IGNORED_2_MASK 0x7FF
#define PML4E_64_IGNORED_2(_) (((_) >> 52) & 0x7FF)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 512-GByte region
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PML4E_64_EXECUTE_DISABLE_BIT 63
#define PML4E_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PML4E_64_EXECUTE_DISABLE_MASK 0x01
#define PML4E_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pml4e_64;
/**
* @brief Format of a 4-Level Page-Directory-Pointer-Table Entry (PDPTE) that Maps a 1-GByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to map a 1-GByte page.
*/
UINT64_t present : 1;
#define PDPTE_1GB_64_PRESENT_BIT 0
#define PDPTE_1GB_64_PRESENT_FLAG 0x01
#define PDPTE_1GB_64_PRESENT_MASK 0x01
#define PDPTE_1GB_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 1-GByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PDPTE_1GB_64_WRITE_BIT 1
#define PDPTE_1GB_64_WRITE_FLAG 0x02
#define PDPTE_1GB_64_WRITE_MASK 0x01
#define PDPTE_1GB_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 1-GByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PDPTE_1GB_64_SUPERVISOR_BIT 2
#define PDPTE_1GB_64_SUPERVISOR_FLAG 0x04
#define PDPTE_1GB_64_SUPERVISOR_MASK 0x01
#define PDPTE_1GB_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the 1-GByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PDPTE_1GB_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDPTE_1GB_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDPTE_1GB_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDPTE_1GB_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the 1-GByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PDPTE_1GB_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDPTE_1GB_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDPTE_1GB_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDPTE_1GB_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether software has accessed the 1-GByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PDPTE_1GB_64_ACCESSED_BIT 5
#define PDPTE_1GB_64_ACCESSED_FLAG 0x20
#define PDPTE_1GB_64_ACCESSED_MASK 0x01
#define PDPTE_1GB_64_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Dirty; indicates whether software has written to the 1-GByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t dirty : 1;
#define PDPTE_1GB_64_DIRTY_BIT 6
#define PDPTE_1GB_64_DIRTY_FLAG 0x40
#define PDPTE_1GB_64_DIRTY_MASK 0x01
#define PDPTE_1GB_64_DIRTY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Page size; must be 1 (otherwise, this entry references a page directory).
*/
UINT64_t large_page : 1;
#define PDPTE_1GB_64_LARGE_PAGE_BIT 7
#define PDPTE_1GB_64_LARGE_PAGE_FLAG 0x80
#define PDPTE_1GB_64_LARGE_PAGE_MASK 0x01
#define PDPTE_1GB_64_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Global; if CR4.PGE = 1, determines whether the translation is global; ignored otherwise.
*
* @see Vol3A[4.10(Caching Translation Information)]
*/
UINT64_t global : 1;
#define PDPTE_1GB_64_GLOBAL_BIT 8
#define PDPTE_1GB_64_GLOBAL_FLAG 0x100
#define PDPTE_1GB_64_GLOBAL_MASK 0x01
#define PDPTE_1GB_64_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT64_t ignored_1 : 3;
#define PDPTE_1GB_64_IGNORED_1_BIT 9
#define PDPTE_1GB_64_IGNORED_1_FLAG 0xE00
#define PDPTE_1GB_64_IGNORED_1_MASK 0x07
#define PDPTE_1GB_64_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bit 12] Indirectly determines the memory type used to access the 1-GByte page referenced by this entry.
*
* @note The PAT is supported on all processors that support 4-level paging.
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t pat : 1;
#define PDPTE_1GB_64_PAT_BIT 12
#define PDPTE_1GB_64_PAT_FLAG 0x1000
#define PDPTE_1GB_64_PAT_MASK 0x01
#define PDPTE_1GB_64_PAT(_) (((_) >> 12) & 0x01)
UINT64_t reserved1 : 17;
/**
* [Bits 47:30] Physical address of the 1-GByte page referenced by this entry.
*/
UINT64_t page_frame_number : 18;
#define PDPTE_1GB_64_PAGE_FRAME_NUMBER_BIT 30
#define PDPTE_1GB_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFC0000000
#define PDPTE_1GB_64_PAGE_FRAME_NUMBER_MASK 0x3FFFF
#define PDPTE_1GB_64_PAGE_FRAME_NUMBER(_) (((_) >> 30) & 0x3FFFF)
UINT64_t reserved2 : 4;
/**
* [Bits 58:52] Ignored.
*/
UINT64_t ignored_2 : 7;
#define PDPTE_1GB_64_IGNORED_2_BIT 52
#define PDPTE_1GB_64_IGNORED_2_FLAG 0x7F0000000000000
#define PDPTE_1GB_64_IGNORED_2_MASK 0x7F
#define PDPTE_1GB_64_IGNORED_2(_) (((_) >> 52) & 0x7F)
/**
* [Bits 62:59] Protection key; if CR4.PKE = 1, determines the protection key of the page; ignored otherwise.
*
* @see Vol3A[4.6.2(Protection Keys)]
*/
UINT64_t protection_key : 4;
#define PDPTE_1GB_64_PROTECTION_KEY_BIT 59
#define PDPTE_1GB_64_PROTECTION_KEY_FLAG 0x7800000000000000
#define PDPTE_1GB_64_PROTECTION_KEY_MASK 0x0F
#define PDPTE_1GB_64_PROTECTION_KEY(_) (((_) >> 59) & 0x0F)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 1-GByte page
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PDPTE_1GB_64_EXECUTE_DISABLE_BIT 63
#define PDPTE_1GB_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PDPTE_1GB_64_EXECUTE_DISABLE_MASK 0x01
#define PDPTE_1GB_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pdpte_1gb_64;
/**
* @brief Format of a 4-Level Page-Directory-Pointer-Table Entry (PDPTE) that References a Page Directory
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to reference a page directory.
*/
UINT64_t present : 1;
#define PDPTE_64_PRESENT_BIT 0
#define PDPTE_64_PRESENT_FLAG 0x01
#define PDPTE_64_PRESENT_MASK 0x01
#define PDPTE_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 1-GByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PDPTE_64_WRITE_BIT 1
#define PDPTE_64_WRITE_FLAG 0x02
#define PDPTE_64_WRITE_MASK 0x01
#define PDPTE_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 1-GByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PDPTE_64_SUPERVISOR_BIT 2
#define PDPTE_64_SUPERVISOR_FLAG 0x04
#define PDPTE_64_SUPERVISOR_MASK 0x01
#define PDPTE_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the page directory referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PDPTE_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDPTE_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDPTE_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDPTE_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the page directory referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PDPTE_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDPTE_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDPTE_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDPTE_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether this entry has been used for linear-address translation.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PDPTE_64_ACCESSED_BIT 5
#define PDPTE_64_ACCESSED_FLAG 0x20
#define PDPTE_64_ACCESSED_MASK 0x01
#define PDPTE_64_ACCESSED(_) (((_) >> 5) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 7] Page size; must be 0 (otherwise, this entry maps a 1-GByte page).
*/
UINT64_t large_page : 1;
#define PDPTE_64_LARGE_PAGE_BIT 7
#define PDPTE_64_LARGE_PAGE_FLAG 0x80
#define PDPTE_64_LARGE_PAGE_MASK 0x01
#define PDPTE_64_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bits 11:8] Ignored.
*/
UINT64_t ignored_1 : 4;
#define PDPTE_64_IGNORED_1_BIT 8
#define PDPTE_64_IGNORED_1_FLAG 0xF00
#define PDPTE_64_IGNORED_1_MASK 0x0F
#define PDPTE_64_IGNORED_1(_) (((_) >> 8) & 0x0F)
/**
* [Bits 47:12] Physical address of 4-KByte aligned page directory referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define PDPTE_64_PAGE_FRAME_NUMBER_BIT 12
#define PDPTE_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define PDPTE_64_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define PDPTE_64_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 4;
/**
* [Bits 62:52] Ignored.
*/
UINT64_t ignored_2 : 11;
#define PDPTE_64_IGNORED_2_BIT 52
#define PDPTE_64_IGNORED_2_FLAG 0x7FF0000000000000
#define PDPTE_64_IGNORED_2_MASK 0x7FF
#define PDPTE_64_IGNORED_2(_) (((_) >> 52) & 0x7FF)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 1-GByte region
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PDPTE_64_EXECUTE_DISABLE_BIT 63
#define PDPTE_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PDPTE_64_EXECUTE_DISABLE_MASK 0x01
#define PDPTE_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pdpte_64;
/**
* @brief Format of a 4-Level Page-Directory Entry that Maps a 2-MByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to map a 2-MByte page.
*/
UINT64_t present : 1;
#define PDE_2MB_64_PRESENT_BIT 0
#define PDE_2MB_64_PRESENT_FLAG 0x01
#define PDE_2MB_64_PRESENT_MASK 0x01
#define PDE_2MB_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 2-MByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PDE_2MB_64_WRITE_BIT 1
#define PDE_2MB_64_WRITE_FLAG 0x02
#define PDE_2MB_64_WRITE_MASK 0x01
#define PDE_2MB_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 2-MByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PDE_2MB_64_SUPERVISOR_BIT 2
#define PDE_2MB_64_SUPERVISOR_FLAG 0x04
#define PDE_2MB_64_SUPERVISOR_MASK 0x01
#define PDE_2MB_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the 2-MByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PDE_2MB_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDE_2MB_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDE_2MB_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDE_2MB_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the 2-MByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PDE_2MB_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDE_2MB_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDE_2MB_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDE_2MB_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether software has accessed the 2-MByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PDE_2MB_64_ACCESSED_BIT 5
#define PDE_2MB_64_ACCESSED_FLAG 0x20
#define PDE_2MB_64_ACCESSED_MASK 0x01
#define PDE_2MB_64_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Dirty; indicates whether software has written to the 2-MByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t dirty : 1;
#define PDE_2MB_64_DIRTY_BIT 6
#define PDE_2MB_64_DIRTY_FLAG 0x40
#define PDE_2MB_64_DIRTY_MASK 0x01
#define PDE_2MB_64_DIRTY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Page size; must be 1 (otherwise, this entry references a page directory).
*/
UINT64_t large_page : 1;
#define PDE_2MB_64_LARGE_PAGE_BIT 7
#define PDE_2MB_64_LARGE_PAGE_FLAG 0x80
#define PDE_2MB_64_LARGE_PAGE_MASK 0x01
#define PDE_2MB_64_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Global; if CR4.PGE = 1, determines whether the translation is global; ignored otherwise.
*
* @see Vol3A[4.10(Caching Translation Information)]
*/
UINT64_t global : 1;
#define PDE_2MB_64_GLOBAL_BIT 8
#define PDE_2MB_64_GLOBAL_FLAG 0x100
#define PDE_2MB_64_GLOBAL_MASK 0x01
#define PDE_2MB_64_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT64_t ignored_1 : 3;
#define PDE_2MB_64_IGNORED_1_BIT 9
#define PDE_2MB_64_IGNORED_1_FLAG 0xE00
#define PDE_2MB_64_IGNORED_1_MASK 0x07
#define PDE_2MB_64_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bit 12] Indirectly determines the memory type used to access the 2-MByte page referenced by this entry.
*
* @note The PAT is supported on all processors that support 4-level paging.
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t pat : 1;
#define PDE_2MB_64_PAT_BIT 12
#define PDE_2MB_64_PAT_FLAG 0x1000
#define PDE_2MB_64_PAT_MASK 0x01
#define PDE_2MB_64_PAT(_) (((_) >> 12) & 0x01)
UINT64_t reserved1 : 8;
/**
* [Bits 47:21] Physical address of the 2-MByte page referenced by this entry.
*/
UINT64_t page_frame_number : 27;
#define PDE_2MB_64_PAGE_FRAME_NUMBER_BIT 21
#define PDE_2MB_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFE00000
#define PDE_2MB_64_PAGE_FRAME_NUMBER_MASK 0x7FFFFFF
#define PDE_2MB_64_PAGE_FRAME_NUMBER(_) (((_) >> 21) & 0x7FFFFFF)
UINT64_t reserved2 : 4;
/**
* [Bits 58:52] Ignored.
*/
UINT64_t ignored_2 : 7;
#define PDE_2MB_64_IGNORED_2_BIT 52
#define PDE_2MB_64_IGNORED_2_FLAG 0x7F0000000000000
#define PDE_2MB_64_IGNORED_2_MASK 0x7F
#define PDE_2MB_64_IGNORED_2(_) (((_) >> 52) & 0x7F)
/**
* [Bits 62:59] Protection key; if CR4.PKE = 1, determines the protection key of the page; ignored otherwise.
*
* @see Vol3A[4.6.2(Protection Keys)]
*/
UINT64_t protection_key : 4;
#define PDE_2MB_64_PROTECTION_KEY_BIT 59
#define PDE_2MB_64_PROTECTION_KEY_FLAG 0x7800000000000000
#define PDE_2MB_64_PROTECTION_KEY_MASK 0x0F
#define PDE_2MB_64_PROTECTION_KEY(_) (((_) >> 59) & 0x0F)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 2-MByte page
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PDE_2MB_64_EXECUTE_DISABLE_BIT 63
#define PDE_2MB_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PDE_2MB_64_EXECUTE_DISABLE_MASK 0x01
#define PDE_2MB_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pde_2mb_64;
/**
* @brief Format of a 4-Level Page-Directory Entry that References a Page Table
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to reference a page table.
*/
UINT64_t present : 1;
#define PDE_64_PRESENT_BIT 0
#define PDE_64_PRESENT_FLAG 0x01
#define PDE_64_PRESENT_MASK 0x01
#define PDE_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 2-MByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PDE_64_WRITE_BIT 1
#define PDE_64_WRITE_FLAG 0x02
#define PDE_64_WRITE_MASK 0x01
#define PDE_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 2-MByte region controlled by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PDE_64_SUPERVISOR_BIT 2
#define PDE_64_SUPERVISOR_FLAG 0x04
#define PDE_64_SUPERVISOR_MASK 0x01
#define PDE_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the page table referenced by this
* entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PDE_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PDE_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PDE_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PDE_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the page table referenced by this
* entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PDE_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PDE_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PDE_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PDE_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether this entry has been used for linear-address translation.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PDE_64_ACCESSED_BIT 5
#define PDE_64_ACCESSED_FLAG 0x20
#define PDE_64_ACCESSED_MASK 0x01
#define PDE_64_ACCESSED(_) (((_) >> 5) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 7] Page size; must be 0 (otherwise, this entry maps a 2-MByte page).
*/
UINT64_t large_page : 1;
#define PDE_64_LARGE_PAGE_BIT 7
#define PDE_64_LARGE_PAGE_FLAG 0x80
#define PDE_64_LARGE_PAGE_MASK 0x01
#define PDE_64_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bits 11:8] Ignored.
*/
UINT64_t ignored_1 : 4;
#define PDE_64_IGNORED_1_BIT 8
#define PDE_64_IGNORED_1_FLAG 0xF00
#define PDE_64_IGNORED_1_MASK 0x0F
#define PDE_64_IGNORED_1(_) (((_) >> 8) & 0x0F)
/**
* [Bits 47:12] Physical address of 4-KByte aligned page table referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define PDE_64_PAGE_FRAME_NUMBER_BIT 12
#define PDE_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define PDE_64_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define PDE_64_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 4;
/**
* [Bits 62:52] Ignored.
*/
UINT64_t ignored_2 : 11;
#define PDE_64_IGNORED_2_BIT 52
#define PDE_64_IGNORED_2_FLAG 0x7FF0000000000000
#define PDE_64_IGNORED_2_MASK 0x7FF
#define PDE_64_IGNORED_2(_) (((_) >> 52) & 0x7FF)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 2-MByte region
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PDE_64_EXECUTE_DISABLE_BIT 63
#define PDE_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PDE_64_EXECUTE_DISABLE_MASK 0x01
#define PDE_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pde_64;
/**
* @brief Format of a 4-Level Page-Table Entry that Maps a 4-KByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Present; must be 1 to map a 4-KByte page.
*/
UINT64_t present : 1;
#define PTE_64_PRESENT_BIT 0
#define PTE_64_PRESENT_FLAG 0x01
#define PTE_64_PRESENT_MASK 0x01
#define PTE_64_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Read/write; if 0, writes may not be allowed to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t write : 1;
#define PTE_64_WRITE_BIT 1
#define PTE_64_WRITE_FLAG 0x02
#define PTE_64_WRITE_MASK 0x01
#define PTE_64_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] User/supervisor; if 0, user-mode accesses are not allowed to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t supervisor : 1;
#define PTE_64_SUPERVISOR_BIT 2
#define PTE_64_SUPERVISOR_FLAG 0x04
#define PTE_64_SUPERVISOR_MASK 0x01
#define PTE_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Page-level write-through; indirectly determines the memory type used to access the 4-KByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_write_through : 1;
#define PTE_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PTE_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PTE_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PTE_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] Page-level cache disable; indirectly determines the memory type used to access the 4-KByte page referenced by
* this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t page_level_cache_disable : 1;
#define PTE_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PTE_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PTE_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PTE_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] Accessed; indicates whether software has accessed the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t accessed : 1;
#define PTE_64_ACCESSED_BIT 5
#define PTE_64_ACCESSED_FLAG 0x20
#define PTE_64_ACCESSED_MASK 0x01
#define PTE_64_ACCESSED(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] Dirty; indicates whether software has written to the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.8(Accessed and Dirty Flags)]
*/
UINT64_t dirty : 1;
#define PTE_64_DIRTY_BIT 6
#define PTE_64_DIRTY_FLAG 0x40
#define PTE_64_DIRTY_MASK 0x01
#define PTE_64_DIRTY(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Indirectly determines the memory type used to access the 4-KByte page referenced by this entry.
*
* @see Vol3A[4.9.2(Paging and Memory Typing When the PAT is Supported (Pentium III and More Recent Processor Families))]
*/
UINT64_t pat : 1;
#define PTE_64_PAT_BIT 7
#define PTE_64_PAT_FLAG 0x80
#define PTE_64_PAT_MASK 0x01
#define PTE_64_PAT(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] Global; if CR4.PGE = 1, determines whether the translation is global; ignored otherwise.
*
* @see Vol3A[4.10(Caching Translation Information)]
*/
UINT64_t global : 1;
#define PTE_64_GLOBAL_BIT 8
#define PTE_64_GLOBAL_FLAG 0x100
#define PTE_64_GLOBAL_MASK 0x01
#define PTE_64_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT64_t ignored_1 : 3;
#define PTE_64_IGNORED_1_BIT 9
#define PTE_64_IGNORED_1_FLAG 0xE00
#define PTE_64_IGNORED_1_MASK 0x07
#define PTE_64_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bits 47:12] Physical address of the 4-KByte page referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define PTE_64_PAGE_FRAME_NUMBER_BIT 12
#define PTE_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define PTE_64_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define PTE_64_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved1 : 4;
/**
* [Bits 58:52] Ignored.
*/
UINT64_t ignored_2 : 7;
#define PTE_64_IGNORED_2_BIT 52
#define PTE_64_IGNORED_2_FLAG 0x7F0000000000000
#define PTE_64_IGNORED_2_MASK 0x7F
#define PTE_64_IGNORED_2(_) (((_) >> 52) & 0x7F)
/**
* [Bits 62:59] Protection key; if CR4.PKE = 1, determines the protection key of the page; ignored otherwise.
*
* @see Vol3A[4.6.2(Protection Keys)]
*/
UINT64_t protection_key : 4;
#define PTE_64_PROTECTION_KEY_BIT 59
#define PTE_64_PROTECTION_KEY_FLAG 0x7800000000000000
#define PTE_64_PROTECTION_KEY_MASK 0x0F
#define PTE_64_PROTECTION_KEY(_) (((_) >> 59) & 0x0F)
/**
* [Bit 63] If IA32_EFER.NXE = 1, execute-disable (if 1, instruction fetches are not allowed from the 1-GByte page
* controlled by this entry); otherwise, reserved (must be 0).
*
* @see Vol3A[4.6(Access Rights)]
*/
UINT64_t execute_disable : 1;
#define PTE_64_EXECUTE_DISABLE_BIT 63
#define PTE_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PTE_64_EXECUTE_DISABLE_MASK 0x01
#define PTE_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pte_64;
/**
* @brief Format of a common Page-Table Entry
*/
typedef union
{
struct
{
UINT64_t present : 1;
#define PT_ENTRY_64_PRESENT_BIT 0
#define PT_ENTRY_64_PRESENT_FLAG 0x01
#define PT_ENTRY_64_PRESENT_MASK 0x01
#define PT_ENTRY_64_PRESENT(_) (((_) >> 0) & 0x01)
UINT64_t write : 1;
#define PT_ENTRY_64_WRITE_BIT 1
#define PT_ENTRY_64_WRITE_FLAG 0x02
#define PT_ENTRY_64_WRITE_MASK 0x01
#define PT_ENTRY_64_WRITE(_) (((_) >> 1) & 0x01)
UINT64_t supervisor : 1;
#define PT_ENTRY_64_SUPERVISOR_BIT 2
#define PT_ENTRY_64_SUPERVISOR_FLAG 0x04
#define PT_ENTRY_64_SUPERVISOR_MASK 0x01
#define PT_ENTRY_64_SUPERVISOR(_) (((_) >> 2) & 0x01)
UINT64_t page_level_write_through : 1;
#define PT_ENTRY_64_PAGE_LEVEL_WRITE_THROUGH_BIT 3
#define PT_ENTRY_64_PAGE_LEVEL_WRITE_THROUGH_FLAG 0x08
#define PT_ENTRY_64_PAGE_LEVEL_WRITE_THROUGH_MASK 0x01
#define PT_ENTRY_64_PAGE_LEVEL_WRITE_THROUGH(_) (((_) >> 3) & 0x01)
UINT64_t page_level_cache_disable : 1;
#define PT_ENTRY_64_PAGE_LEVEL_CACHE_DISABLE_BIT 4
#define PT_ENTRY_64_PAGE_LEVEL_CACHE_DISABLE_FLAG 0x10
#define PT_ENTRY_64_PAGE_LEVEL_CACHE_DISABLE_MASK 0x01
#define PT_ENTRY_64_PAGE_LEVEL_CACHE_DISABLE(_) (((_) >> 4) & 0x01)
UINT64_t accessed : 1;
#define PT_ENTRY_64_ACCESSED_BIT 5
#define PT_ENTRY_64_ACCESSED_FLAG 0x20
#define PT_ENTRY_64_ACCESSED_MASK 0x01
#define PT_ENTRY_64_ACCESSED(_) (((_) >> 5) & 0x01)
UINT64_t dirty : 1;
#define PT_ENTRY_64_DIRTY_BIT 6
#define PT_ENTRY_64_DIRTY_FLAG 0x40
#define PT_ENTRY_64_DIRTY_MASK 0x01
#define PT_ENTRY_64_DIRTY(_) (((_) >> 6) & 0x01)
UINT64_t large_page : 1;
#define PT_ENTRY_64_LARGE_PAGE_BIT 7
#define PT_ENTRY_64_LARGE_PAGE_FLAG 0x80
#define PT_ENTRY_64_LARGE_PAGE_MASK 0x01
#define PT_ENTRY_64_LARGE_PAGE(_) (((_) >> 7) & 0x01)
UINT64_t global : 1;
#define PT_ENTRY_64_GLOBAL_BIT 8
#define PT_ENTRY_64_GLOBAL_FLAG 0x100
#define PT_ENTRY_64_GLOBAL_MASK 0x01
#define PT_ENTRY_64_GLOBAL(_) (((_) >> 8) & 0x01)
/**
* [Bits 11:9] Ignored.
*/
UINT64_t ignored_1 : 3;
#define PT_ENTRY_64_IGNORED_1_BIT 9
#define PT_ENTRY_64_IGNORED_1_FLAG 0xE00
#define PT_ENTRY_64_IGNORED_1_MASK 0x07
#define PT_ENTRY_64_IGNORED_1(_) (((_) >> 9) & 0x07)
/**
* [Bits 47:12] Physical address of the 4-KByte page referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define PT_ENTRY_64_PAGE_FRAME_NUMBER_BIT 12
#define PT_ENTRY_64_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define PT_ENTRY_64_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define PT_ENTRY_64_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved1 : 4;
/**
* [Bits 58:52] Ignored.
*/
UINT64_t ignored_2 : 7;
#define PT_ENTRY_64_IGNORED_2_BIT 52
#define PT_ENTRY_64_IGNORED_2_FLAG 0x7F0000000000000
#define PT_ENTRY_64_IGNORED_2_MASK 0x7F
#define PT_ENTRY_64_IGNORED_2(_) (((_) >> 52) & 0x7F)
UINT64_t protection_key : 4;
#define PT_ENTRY_64_PROTECTION_KEY_BIT 59
#define PT_ENTRY_64_PROTECTION_KEY_FLAG 0x7800000000000000
#define PT_ENTRY_64_PROTECTION_KEY_MASK 0x0F
#define PT_ENTRY_64_PROTECTION_KEY(_) (((_) >> 59) & 0x0F)
UINT64_t execute_disable : 1;
#define PT_ENTRY_64_EXECUTE_DISABLE_BIT 63
#define PT_ENTRY_64_EXECUTE_DISABLE_FLAG 0x8000000000000000
#define PT_ENTRY_64_EXECUTE_DISABLE_MASK 0x01
#define PT_ENTRY_64_EXECUTE_DISABLE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} pt_entry_64;
/**
* @defgroup paging_structures_entry_count_64 \
* Paging structures entry counts
*
* Paging structures entry counts.
* @{
*/
#define PML4E_ENTRY_COUNT_64 0x00000200
#define PDPTE_ENTRY_COUNT_64 0x00000200
#define PDE_ENTRY_COUNT_64 0x00000200
#define PTE_ENTRY_COUNT_64 0x00000200
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @defgroup segment_descriptors \
* Segment descriptors
* @{
*/
/**
* @brief Pseudo-Descriptor Format (32-bit)
*
* @see Vol3A[3.5.1(Segment Descriptor Tables)] (reference)
*/
#pragma pack(push, 1)
typedef struct
{
/**
* Limit.
*/
UINT16_t limit;
/**
* Base Address.
*/
UINT32_t base_address;
} segment_descriptor_register_32;
#pragma pack(pop)
/**
* @brief Pseudo-Descriptor Format (64-bit)
*
* @see Vol3A[3.5.1(Segment Descriptor Tables)] (reference)
*/
#pragma pack(push, 1)
typedef struct
{
/**
* Limit.
*/
UINT16_t limit;
/**
* Base Address.
*/
UINT64_t base_address;
} segment_descriptor_register_64;
#pragma pack(pop)
/**
* @brief Segment access rights
*
* @see Vol2A[3.2(Instructions (A-L) | LAR-Load Access Rights Byte)] (reference)
*/
typedef union
{
struct
{
UINT32_t reserved1 : 8;
/**
* @brief Type field
*
* [Bits 11:8] Indicates the segment or gate type and specifies the kinds of access that can be made to the segment and the
* direction of growth. The interpretation of this field depends on whether the descriptor type flag specifies an
* application (code or data) descriptor or a system descriptor. The encoding of the type field is different for code,
* data, and system descriptors.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)]
*/
UINT32_t type : 4;
#define SEGMENT_ACCESS_RIGHTS_TYPE_BIT 8
#define SEGMENT_ACCESS_RIGHTS_TYPE_FLAG 0xF00
#define SEGMENT_ACCESS_RIGHTS_TYPE_MASK 0x0F
#define SEGMENT_ACCESS_RIGHTS_TYPE(_) (((_) >> 8) & 0x0F)
/**
* @brief S (descriptor type) flag
*
* [Bit 12] Specifies whether the segment descriptor is for a system segment (S flag is clear) or a code or data segment (S
* flag is set).
*/
UINT32_t descriptor_type : 1;
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_BIT 12
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_FLAG 0x1000
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE(_) (((_) >> 12) & 0x01)
/**
* @brief DPL (descriptor privilege level) field
*
* [Bits 14:13] Specifies the privilege level of the segment. The privilege level can range from 0 to 3, with 0 being the
* most privileged level. The DPL is used to control access to the segment. See Section 5.5, "Privilege Levels", for a
* description of the relationship of the DPL to the CPL of the executing code segment and the RPL of a segment selector.
*/
UINT32_t descriptor_privilege_level : 2;
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_BIT 13
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_FLAG 0x6000
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_MASK 0x03
#define SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL(_) (((_) >> 13) & 0x03)
/**
* @brief P (segment-present) flag
*
* [Bit 15] Indicates whether the segment is present in memory (set) or not present (clear). If this flag is clear, the
* processor generates a segment-not-present exception (\#NP) when a segment selector that points to the segment descriptor
* is loaded into a segment register. Memory management software can use this flag to control which segments are actually
* loaded into physical memory at a given time. It offers a control in addition to paging for managing virtual memory.
*/
UINT32_t present : 1;
#define SEGMENT_ACCESS_RIGHTS_PRESENT_BIT 15
#define SEGMENT_ACCESS_RIGHTS_PRESENT_FLAG 0x8000
#define SEGMENT_ACCESS_RIGHTS_PRESENT_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_PRESENT(_) (((_) >> 15) & 0x01)
UINT32_t reserved2 : 4;
/**
* @brief Available bit
*
* [Bit 20] Bit 20 of the second doubleword of the segment descriptor is available for use by system software.
*/
UINT32_t system : 1;
#define SEGMENT_ACCESS_RIGHTS_SYSTEM_BIT 20
#define SEGMENT_ACCESS_RIGHTS_SYSTEM_FLAG 0x100000
#define SEGMENT_ACCESS_RIGHTS_SYSTEM_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_SYSTEM(_) (((_) >> 20) & 0x01)
/**
* @brief L (64-bit code segment) flag
*
* [Bit 21] In IA-32e mode, bit 21 of the second doubleword of the segment descriptor indicates whether a code segment
* contains native 64-bit code. A value of 1 indicates instructions in this code segment are executed in 64-bit mode. A
* value of 0 indicates the instructions in this code segment are executed in compatibility mode. If L-bit is set, then
* D-bit must be cleared. When not in IA-32e mode or for non-code segments, bit 21 is reserved and should always be set to
* 0.
*/
UINT32_t long_mode : 1;
#define SEGMENT_ACCESS_RIGHTS_LONG_MODE_BIT 21
#define SEGMENT_ACCESS_RIGHTS_LONG_MODE_FLAG 0x200000
#define SEGMENT_ACCESS_RIGHTS_LONG_MODE_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_LONG_MODE(_) (((_) >> 21) & 0x01)
/**
* @brief D/B (default operation size/default stack pointer size and/or upper bound) flag
*
* [Bit 22] Performs different functions depending on whether the segment descriptor is an executable code segment, an
* expand-down data segment, or a stack segment. (This flag should always be set to 1 for 32-bit code and data segments and
* to 0 for 16-bit code and data segments.)
* - Executable code segment. The flag is called the D flag and it indicates the default length for effective addresses and
* operands referenced by instructions in the segment. If the flag is set, 32-bit addresses and 32-bit or 8-bit operands
* are assumed; if it is clear, 16-bit addresses and 16-bit or 8-bit operands are assumed. The instruction prefix 66H can
* be used to select an operand size other than the default, and the prefix 67H can be used select an address size other
* than the default.
* - Stack segment (data segment pointed to by the SS register). The flag is called the B (big) flag and it specifies the
* size of the stack pointer used for implicit stack operations (such as pushes, pops, and calls). If the flag is set, a
* 32-bit stack pointer is used, which is stored in the 32-bit ESP register; if the flag is clear, a 16-bit stack pointer
* is used, which is stored in the 16- bit SP register. If the stack segment is set up to be an expand-down data segment
* (described in the next paragraph), the B flag also specifies the upper bound of the stack segment.
* - Expand-down data segment. The flag is called the B flag and it specifies the upper bound of the segment. If the flag
* is set, the upper bound is FFFFFFFFH (4 GBytes); if the flag is clear, the upper bound is FFFFH (64 KBytes).
*/
UINT32_t default_big : 1;
#define SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_BIT 22
#define SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_FLAG 0x400000
#define SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG(_) (((_) >> 22) & 0x01)
/**
* @brief G (granularity) flag
*
* [Bit 23] Determines the scaling of the segment limit field. When the granularity flag is clear, the segment limit is
* interpreted in byte units; when flag is set, the segment limit is interpreted in 4-KByte units. (This flag does not
* affect the granularity of the base address; it is always byte granular.) When the granularity flag is set, the twelve
* least significant bits of an offset are not tested when checking the offset against the segment limit. For example, when
* the granularity flag is set, a limit of 0 results in valid offsets from 0 to 4095.
*/
UINT32_t granularity : 1;
#define SEGMENT_ACCESS_RIGHTS_GRANULARITY_BIT 23
#define SEGMENT_ACCESS_RIGHTS_GRANULARITY_FLAG 0x800000
#define SEGMENT_ACCESS_RIGHTS_GRANULARITY_MASK 0x01
#define SEGMENT_ACCESS_RIGHTS_GRANULARITY(_) (((_) >> 23) & 0x01)
UINT32_t reserved3 : 8;
};
UINT32_t flags;
} segment_access_rights;
/**
* @brief General Segment Descriptor (32-bit)
*
* A segment descriptor is a data structure in a GDT or LDT that provides the processor with the size and location of a
* segment, as well as access control and status information. Segment descriptors are typically created by compilers,
* linkers, loaders, or the operating system or executive, but not application programs.
*
* @see Vol3A[5.2(FIELDS AND FLAGS USED FOR SEGMENT-LEVEL AND PAGE-LEVEL PROTECTION)]
* @see Vol3A[5.2.1(Code-Segment Descriptor in 64-bit Mode)]
* @see Vol3A[5.8.3(Call Gates)]
* @see Vol3A[6.11(IDT DESCRIPTORS)]
* @see Vol3A[6.14.1(64-Bit Mode IDT)]
* @see Vol3A[7.2.2(TSS Descriptor)]
* @see Vol3A[7.2.3(TSS Descriptor in 64-bit mode)]
* @see Vol3A[7.2.5(Task-Gate Descriptor)]
* @see Vol3A[3.4.5(Segment Descriptors)] (reference)
*/
typedef struct
{
/**
* @brief Segment limit field (15:00)
*
* Specifies the size of the segment. The processor puts together the two segment limit fields to form a 20-bit value. The
* processor interprets the segment limit in one of two ways, depending on the setting of the G (granularity) flag:
* - If the granularity flag is clear, the segment size can range from 1 byte to 1 MByte, in byte increments.
* - If the granularity flag is set, the segment size can range from 4 KBytes to 4 GBytes, in 4-KByte increments.
* The processor uses the segment limit in two different ways, depending on whether the segment is an expand-up or an
* expand-down segment. For expand-up segments, the offset in a logical address can range from 0 to the segment limit.
* Offsets greater than the segment limit generate general-protection exceptions (\#GP, for all segments other than SS) or
* stack-fault exceptions (\#SS for the SS segment). For expand-down segments, the segment limit has the reverse function;
* the offset can range from the segment limit plus 1 to FFFFFFFFH or FFFFH, depending on the setting of the B flag.
* Offsets less than or equal to the segment limit generate general-protection exceptions or stack-fault exceptions.
* Decreasing the value in the segment limit field for an expanddown segment allocates new memory at the bottom of the
* segment's address space, rather than at the top. IA-32 architecture stacks always grow downwards, making this mechanism
* convenient for expandable stacks.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)]
*/
UINT16_t segment_limit_low;
/**
* @brief Base address field (15:00)
*
* Defines the location of byte 0 of the segment within the 4-GByte linear address space. The processor puts together the
* three base address fields to form a single 32-bit value. Segment base addresses should be aligned to 16-byte boundaries.
* Although 16-byte alignment is not required, this alignment allows programs to maximize performance by aligning code and
* data on 16-byte boundaries.
*/
UINT16_t base_address_low;
/**
* @brief Segment descriptor fields
*/
union
{
struct
{
/**
* [Bits 7:0] Base address field (23:16); see description of $BASE_LOW for more details.
*/
UINT32_t base_address_middle : 8;
#define SEGMENT__BASE_ADDRESS_MIDDLE_BIT 0
#define SEGMENT__BASE_ADDRESS_MIDDLE_FLAG 0xFF
#define SEGMENT__BASE_ADDRESS_MIDDLE_MASK 0xFF
#define SEGMENT__BASE_ADDRESS_MIDDLE(_) (((_) >> 0) & 0xFF)
/**
* @brief Type field
*
* [Bits 11:8] Indicates the segment or gate type and specifies the kinds of access that can be made to the segment and the
* direction of growth. The interpretation of this field depends on whether the descriptor type flag specifies an
* application (code or data) descriptor or a system descriptor. The encoding of the type field is different for code,
* data, and system descriptors.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)]
*/
UINT32_t type : 4;
#define SEGMENT__TYPE_BIT 8
#define SEGMENT__TYPE_FLAG 0xF00
#define SEGMENT__TYPE_MASK 0x0F
#define SEGMENT__TYPE(_) (((_) >> 8) & 0x0F)
/**
* @brief S (descriptor type) flag
*
* [Bit 12] Specifies whether the segment descriptor is for a system segment (S flag is clear) or a code or data segment (S
* flag is set).
*/
UINT32_t descriptor_type : 1;
#define SEGMENT__DESCRIPTOR_TYPE_BIT 12
#define SEGMENT__DESCRIPTOR_TYPE_FLAG 0x1000
#define SEGMENT__DESCRIPTOR_TYPE_MASK 0x01
#define SEGMENT__DESCRIPTOR_TYPE(_) (((_) >> 12) & 0x01)
/**
* @brief DPL (descriptor privilege level) field
*
* [Bits 14:13] Specifies the privilege level of the segment. The privilege level can range from 0 to 3, with 0 being the
* most privileged level. The DPL is used to control access to the segment. See Section 5.5, "Privilege Levels", for a
* description of the relationship of the DPL to the CPL of the executing code segment and the RPL of a segment selector.
*/
UINT32_t descriptor_privilege_level : 2;
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_BIT 13
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_FLAG 0x6000
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_MASK 0x03
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL(_) (((_) >> 13) & 0x03)
/**
* @brief P (segment-present) flag
*
* [Bit 15] Indicates whether the segment is present in memory (set) or not present (clear). If this flag is clear, the
* processor generates a segment-not-present exception (\#NP) when a segment selector that points to the segment descriptor
* is loaded into a segment register. Memory management software can use this flag to control which segments are actually
* loaded into physical memory at a given time. It offers a control in addition to paging for managing virtual memory.
*/
UINT32_t present : 1;
#define SEGMENT__PRESENT_BIT 15
#define SEGMENT__PRESENT_FLAG 0x8000
#define SEGMENT__PRESENT_MASK 0x01
#define SEGMENT__PRESENT(_) (((_) >> 15) & 0x01)
/**
* [Bits 19:16] Segment limit field (19:16); see description of $LIMIT_LOW for more details.
*/
UINT32_t segment_limit_high : 4;
#define SEGMENT__SEGMENT_LIMIT_HIGH_BIT 16
#define SEGMENT__SEGMENT_LIMIT_HIGH_FLAG 0xF0000
#define SEGMENT__SEGMENT_LIMIT_HIGH_MASK 0x0F
#define SEGMENT__SEGMENT_LIMIT_HIGH(_) (((_) >> 16) & 0x0F)
/**
* @brief Available bit
*
* [Bit 20] Bit 20 of the second doubleword of the segment descriptor is available for use by system software.
*/
UINT32_t system : 1;
#define SEGMENT__SYSTEM_BIT 20
#define SEGMENT__SYSTEM_FLAG 0x100000
#define SEGMENT__SYSTEM_MASK 0x01
#define SEGMENT__SYSTEM(_) (((_) >> 20) & 0x01)
/**
* @brief L (64-bit code segment) flag
*
* [Bit 21] In IA-32e mode, bit 21 of the second doubleword of the segment descriptor indicates whether a code segment
* contains native 64-bit code. A value of 1 indicates instructions in this code segment are executed in 64-bit mode. A
* value of 0 indicates the instructions in this code segment are executed in compatibility mode. If L-bit is set, then
* D-bit must be cleared. When not in IA-32e mode or for non-code segments, bit 21 is reserved and should always be set to
* 0.
*/
UINT32_t long_mode : 1;
#define SEGMENT__LONG_MODE_BIT 21
#define SEGMENT__LONG_MODE_FLAG 0x200000
#define SEGMENT__LONG_MODE_MASK 0x01
#define SEGMENT__LONG_MODE(_) (((_) >> 21) & 0x01)
/**
* @brief D/B (default operation size/default stack pointer size and/or upper bound) flag
*
* [Bit 22] Performs different functions depending on whether the segment descriptor is an executable code segment, an
* expand-down data segment, or a stack segment. (This flag should always be set to 1 for 32-bit code and data segments and
* to 0 for 16-bit code and data segments.)
* - Executable code segment. The flag is called the D flag and it indicates the default length for effective addresses and
* operands referenced by instructions in the segment. If the flag is set, 32-bit addresses and 32-bit or 8-bit operands
* are assumed; if it is clear, 16-bit addresses and 16-bit or 8-bit operands are assumed. The instruction prefix 66H can
* be used to select an operand size other than the default, and the prefix 67H can be used select an address size other
* than the default.
* - Stack segment (data segment pointed to by the SS register). The flag is called the B (big) flag and it specifies the
* size of the stack pointer used for implicit stack operations (such as pushes, pops, and calls). If the flag is set, a
* 32-bit stack pointer is used, which is stored in the 32-bit ESP register; if the flag is clear, a 16-bit stack pointer
* is used, which is stored in the 16- bit SP register. If the stack segment is set up to be an expand-down data segment
* (described in the next paragraph), the B flag also specifies the upper bound of the stack segment.
* - Expand-down data segment. The flag is called the B flag and it specifies the upper bound of the segment. If the flag
* is set, the upper bound is FFFFFFFFH (4 GBytes); if the flag is clear, the upper bound is FFFFH (64 KBytes).
*/
UINT32_t default_big : 1;
#define SEGMENT__DEFAULT_BIG_BIT 22
#define SEGMENT__DEFAULT_BIG_FLAG 0x400000
#define SEGMENT__DEFAULT_BIG_MASK 0x01
#define SEGMENT__DEFAULT_BIG(_) (((_) >> 22) & 0x01)
/**
* @brief G (granularity) flag
*
* [Bit 23] Determines the scaling of the segment limit field. When the granularity flag is clear, the segment limit is
* interpreted in byte units; when flag is set, the segment limit is interpreted in 4-KByte units. (This flag does not
* affect the granularity of the base address; it is always byte granular.) When the granularity flag is set, the twelve
* least significant bits of an offset are not tested when checking the offset against the segment limit. For example, when
* the granularity flag is set, a limit of 0 results in valid offsets from 0 to 4095.
*/
UINT32_t granularity : 1;
#define SEGMENT__GRANULARITY_BIT 23
#define SEGMENT__GRANULARITY_FLAG 0x800000
#define SEGMENT__GRANULARITY_MASK 0x01
#define SEGMENT__GRANULARITY(_) (((_) >> 23) & 0x01)
/**
* [Bits 31:24] Base address field (31:24); see description of $BASE_LOW for more details.
*/
UINT32_t base_address_high : 8;
#define SEGMENT__BASE_ADDRESS_HIGH_BIT 24
#define SEGMENT__BASE_ADDRESS_HIGH_FLAG 0xFF000000
#define SEGMENT__BASE_ADDRESS_HIGH_MASK 0xFF
#define SEGMENT__BASE_ADDRESS_HIGH(_) (((_) >> 24) & 0xFF)
};
UINT32_t flags;
};
} segment_descriptor_32;
/**
* @brief General Segment Descriptor (64-bit)
*
* A segment descriptor is a data structure in a GDT or LDT that provides the processor with the size and location of a
* segment, as well as access control and status information. Segment descriptors are typically created by compilers,
* linkers, loaders, or the operating system or executive, but not application programs.
*
* @see Vol3A[3.4.5(Segment Descriptors)] (reference)
*/
typedef struct
{
/**
* @brief Segment limit field (15:00)
*
* Specifies the size of the segment. The processor puts together the two segment limit fields to form a 20-bit value. The
* processor interprets the segment limit in one of two ways, depending on the setting of the G (granularity) flag:
* - If the granularity flag is clear, the segment size can range from 1 byte to 1 MByte, in byte increments.
* - If the granularity flag is set, the segment size can range from 4 KBytes to 4 GBytes, in 4-KByte increments.
* The processor uses the segment limit in two different ways, depending on whether the segment is an expand-up or an
* expand-down segment. For expand-up segments, the offset in a logical address can range from 0 to the segment limit.
* Offsets greater than the segment limit generate general-protection exceptions (\#GP, for all segments other than SS) or
* stack-fault exceptions (\#SS for the SS segment). For expand-down segments, the segment limit has the reverse function;
* the offset can range from the segment limit plus 1 to FFFFFFFFH or FFFFH, depending on the setting of the B flag.
* Offsets less than or equal to the segment limit generate general-protection exceptions or stack-fault exceptions.
* Decreasing the value in the segment limit field for an expanddown segment allocates new memory at the bottom of the
* segment's address space, rather than at the top. IA-32 architecture stacks always grow downwards, making this mechanism
* convenient for expandable stacks.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)]
*/
UINT16_t segment_limit_low;
/**
* @brief Base address field (15:00)
*
* Defines the location of byte 0 of the segment within the 4-GByte linear address space. The processor puts together the
* three base address fields to form a single 32-bit value. Segment base addresses should be aligned to 16-byte boundaries.
* Although 16-byte alignment is not required, this alignment allows programs to maximize performance by aligning code and
* data on 16-byte boundaries.
*/
UINT16_t base_address_low;
/**
* @brief Segment descriptor fields
*/
union
{
struct
{
/**
* [Bits 7:0] Base address field (23:16); see description of $BASE_LOW for more details.
*/
UINT32_t base_address_middle : 8;
#define SEGMENT__BASE_ADDRESS_MIDDLE_BIT 0
#define SEGMENT__BASE_ADDRESS_MIDDLE_FLAG 0xFF
#define SEGMENT__BASE_ADDRESS_MIDDLE_MASK 0xFF
#define SEGMENT__BASE_ADDRESS_MIDDLE(_) (((_) >> 0) & 0xFF)
/**
* @brief Type field
*
* [Bits 11:8] Indicates the segment or gate type and specifies the kinds of access that can be made to the segment and the
* direction of growth. The interpretation of this field depends on whether the descriptor type flag specifies an
* application (code or data) descriptor or a system descriptor. The encoding of the type field is different for code,
* data, and system descriptors.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)]
*/
UINT32_t type : 4;
#define SEGMENT__TYPE_BIT 8
#define SEGMENT__TYPE_FLAG 0xF00
#define SEGMENT__TYPE_MASK 0x0F
#define SEGMENT__TYPE(_) (((_) >> 8) & 0x0F)
/**
* @brief S (descriptor type) flag
*
* [Bit 12] Specifies whether the segment descriptor is for a system segment (S flag is clear) or a code or data segment (S
* flag is set).
*/
UINT32_t descriptor_type : 1;
#define SEGMENT__DESCRIPTOR_TYPE_BIT 12
#define SEGMENT__DESCRIPTOR_TYPE_FLAG 0x1000
#define SEGMENT__DESCRIPTOR_TYPE_MASK 0x01
#define SEGMENT__DESCRIPTOR_TYPE(_) (((_) >> 12) & 0x01)
/**
* @brief DPL (descriptor privilege level) field
*
* [Bits 14:13] Specifies the privilege level of the segment. The privilege level can range from 0 to 3, with 0 being the
* most privileged level. The DPL is used to control access to the segment. See Section 5.5, "Privilege Levels", for a
* description of the relationship of the DPL to the CPL of the executing code segment and the RPL of a segment selector.
*/
UINT32_t descriptor_privilege_level : 2;
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_BIT 13
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_FLAG 0x6000
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL_MASK 0x03
#define SEGMENT__DESCRIPTOR_PRIVILEGE_LEVEL(_) (((_) >> 13) & 0x03)
/**
* @brief P (segment-present) flag
*
* [Bit 15] Indicates whether the segment is present in memory (set) or not present (clear). If this flag is clear, the
* processor generates a segment-not-present exception (\#NP) when a segment selector that points to the segment descriptor
* is loaded into a segment register. Memory management software can use this flag to control which segments are actually
* loaded into physical memory at a given time. It offers a control in addition to paging for managing virtual memory.
*/
UINT32_t present : 1;
#define SEGMENT__PRESENT_BIT 15
#define SEGMENT__PRESENT_FLAG 0x8000
#define SEGMENT__PRESENT_MASK 0x01
#define SEGMENT__PRESENT(_) (((_) >> 15) & 0x01)
/**
* [Bits 19:16] Segment limit field (19:16); see description of $LIMIT_LOW for more details.
*/
UINT32_t segment_limit_high : 4;
#define SEGMENT__SEGMENT_LIMIT_HIGH_BIT 16
#define SEGMENT__SEGMENT_LIMIT_HIGH_FLAG 0xF0000
#define SEGMENT__SEGMENT_LIMIT_HIGH_MASK 0x0F
#define SEGMENT__SEGMENT_LIMIT_HIGH(_) (((_) >> 16) & 0x0F)
/**
* @brief Available bit
*
* [Bit 20] Bit 20 of the second doubleword of the segment descriptor is available for use by system software.
*/
UINT32_t system : 1;
#define SEGMENT__SYSTEM_BIT 20
#define SEGMENT__SYSTEM_FLAG 0x100000
#define SEGMENT__SYSTEM_MASK 0x01
#define SEGMENT__SYSTEM(_) (((_) >> 20) & 0x01)
/**
* @brief L (64-bit code segment) flag
*
* [Bit 21] In IA-32e mode, bit 21 of the second doubleword of the segment descriptor indicates whether a code segment
* contains native 64-bit code. A value of 1 indicates instructions in this code segment are executed in 64-bit mode. A
* value of 0 indicates the instructions in this code segment are executed in compatibility mode. If L-bit is set, then
* D-bit must be cleared. When not in IA-32e mode or for non-code segments, bit 21 is reserved and should always be set to
* 0.
*/
UINT32_t long_mode : 1;
#define SEGMENT__LONG_MODE_BIT 21
#define SEGMENT__LONG_MODE_FLAG 0x200000
#define SEGMENT__LONG_MODE_MASK 0x01
#define SEGMENT__LONG_MODE(_) (((_) >> 21) & 0x01)
/**
* @brief D/B (default operation size/default stack pointer size and/or upper bound) flag
*
* [Bit 22] Performs different functions depending on whether the segment descriptor is an executable code segment, an
* expand-down data segment, or a stack segment. (This flag should always be set to 1 for 32-bit code and data segments and
* to 0 for 16-bit code and data segments.)
* - Executable code segment. The flag is called the D flag and it indicates the default length for effective addresses and
* operands referenced by instructions in the segment. If the flag is set, 32-bit addresses and 32-bit or 8-bit operands
* are assumed; if it is clear, 16-bit addresses and 16-bit or 8-bit operands are assumed. The instruction prefix 66H can
* be used to select an operand size other than the default, and the prefix 67H can be used select an address size other
* than the default.
* - Stack segment (data segment pointed to by the SS register). The flag is called the B (big) flag and it specifies the
* size of the stack pointer used for implicit stack operations (such as pushes, pops, and calls). If the flag is set, a
* 32-bit stack pointer is used, which is stored in the 32-bit ESP register; if the flag is clear, a 16-bit stack pointer
* is used, which is stored in the 16- bit SP register. If the stack segment is set up to be an expand-down data segment
* (described in the next paragraph), the B flag also specifies the upper bound of the stack segment.
* - Expand-down data segment. The flag is called the B flag and it specifies the upper bound of the segment. If the flag
* is set, the upper bound is FFFFFFFFH (4 GBytes); if the flag is clear, the upper bound is FFFFH (64 KBytes).
*/
UINT32_t default_big : 1;
#define SEGMENT__DEFAULT_BIG_BIT 22
#define SEGMENT__DEFAULT_BIG_FLAG 0x400000
#define SEGMENT__DEFAULT_BIG_MASK 0x01
#define SEGMENT__DEFAULT_BIG(_) (((_) >> 22) & 0x01)
/**
* @brief G (granularity) flag
*
* [Bit 23] Determines the scaling of the segment limit field. When the granularity flag is clear, the segment limit is
* interpreted in byte units; when flag is set, the segment limit is interpreted in 4-KByte units. (This flag does not
* affect the granularity of the base address; it is always byte granular.) When the granularity flag is set, the twelve
* least significant bits of an offset are not tested when checking the offset against the segment limit. For example, when
* the granularity flag is set, a limit of 0 results in valid offsets from 0 to 4095.
*/
UINT32_t granularity : 1;
#define SEGMENT__GRANULARITY_BIT 23
#define SEGMENT__GRANULARITY_FLAG 0x800000
#define SEGMENT__GRANULARITY_MASK 0x01
#define SEGMENT__GRANULARITY(_) (((_) >> 23) & 0x01)
/**
* [Bits 31:24] Base address field (31:24); see description of $BASE_LOW for more details.
*/
UINT32_t base_address_high : 8;
#define SEGMENT__BASE_ADDRESS_HIGH_BIT 24
#define SEGMENT__BASE_ADDRESS_HIGH_FLAG 0xFF000000
#define SEGMENT__BASE_ADDRESS_HIGH_MASK 0xFF
#define SEGMENT__BASE_ADDRESS_HIGH(_) (((_) >> 24) & 0xFF)
};
UINT32_t flags;
};
/**
* Base address field (32:63); see description of $BASE_LOW for more details.
*/
UINT32_t base_address_upper;
/**
* Base address field (32:63); see description of $BASE_LOW for more details.
*/
UINT32_t must_be_zero;
} segment_descriptor_64;
#define SEGMENT_DESCRIPTOR_TYPE_SYSTEM 0x00000000
#define SEGMENT_DESCRIPTOR_TYPE_CODE_OR_DATA 0x00000001
/**
* @defgroup segment_descriptor_code_and_data_type \
* Code- and Data-Segment Descriptor Types
*
* When the S (descriptor type) flag in a segment descriptor is set, the descriptor is for either a code or a data segment.
* The highest order bit of the type field (bit 11 of the second double word of the segment descriptor) then determines
* whether the descriptor is for a data segment (clear) or a code segment (set). For data segments, the three low-order
* bits of the type field (bits 8, 9, and 10) are interpreted as accessed (A), write-enable (W), and expansion-direction
* (E). See Table 3-1 for a description of the encoding of the bits in the type field for code and data segments. Data
* segments can be read-only or read/write segments, depending on the setting of the write-enable bit.
*
* @see Vol3A[3.4.5.1(Code- and Data-Segment Descriptor Types)] (reference)
* @{
*/
/**
* Read-Only.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_ONLY 0x00000000
/**
* Data Read-Only, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_ONLY_ACCESSED 0x00000001
/**
* Data Read/Write.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_WRITE 0x00000002
/**
* Data Read/Write, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_WRITE_ACCESSED 0x00000003
/**
* Data Read-Only, expand-down.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_ONLY_EXPAND_DOWN 0x00000004
/**
* Data Read-Only, expand-down, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_ONLY_EXPAND_DOWN_ACCESSED 0x00000005
/**
* Data Read/Write, expand-down.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_WRITE_EXPAND_DOWN 0x00000006
/**
* Data Read/Write, expand-down, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_DATA_READ_WRITE_EXPAND_DOWN_ACCESSED 0x00000007
/**
* Code Execute-Only.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_ONLY 0x00000008
/**
* Code Execute-Only, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_ONLY_ACCESSED 0x00000009
/**
* Code Execute/Read.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_READ 0x0000000A
/**
* Code Execute/Read, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_READ_ACCESSED 0x0000000B
/**
* Code Execute-Only, conforming.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_ONLY_CONFORMING 0x0000000C
/**
* Code Execute-Only, conforming, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_ONLY_CONFORMING_ACCESSED 0x0000000D
/**
* Code Execute/Read, conforming.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_READ_CONFORMING 0x0000000E
/**
* Code Execute/Read, conforming, accessed.
*/
#define SEGMENT_DESCRIPTOR_TYPE_CODE_EXECUTE_READ_CONFORMING_ACCESSED 0x0000000F
/**
* @}
*/
/**
* @defgroup segment_descriptor_system_type \
* System Descriptor Types
*
* When the S (descriptor type) flag in a segment descriptor is clear, the descriptor type is a system descriptor. The
* processor recognizes the following types of system descriptors:
* - Local descriptor-table (LDT) segment descriptor.
* - Task-state segment (TSS) descriptor.
* - Call-gate descriptor.
* - Interrupt-gate descriptor.
* - Trap-gate descriptor.
* - Task-gate descriptor.
* These descriptor types fall into two categories: system-segment descriptors and gate descriptors. Systemsegment
* descriptors point to system segments (LDT and TSS segments). Gate descriptors are in themselves "gates," which hold
* pointers to procedure entry points in code segments (call, interrupt, and trap gates) or which hold segment selectors
* for TSS's (task gates).
*
* @see Vol3A[3.5(SYSTEM DESCRIPTOR TYPES)] (reference)
* @{
*/
/**
* - 32-Bit Mode: Reserved
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_RESERVED_1 0x00000000
/**
* - 32-Bit Mode: 16-bit TSS (Available)
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_TSS_16_AVAILABLE 0x00000001
/**
* - 32-Bit Mode: LDT
* - IA-32e Mode: LDT
*/
#define SEGMENT_DESCRIPTOR_TYPE_LDT 0x00000002
/**
* - 32-Bit Mode: 16-bit TSS (Busy)
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_TSS_16_BUSY 0x00000003
/**
* - 32-Bit Mode: 16-bit Call Gate
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_CALL_GATE_16 0x00000004
/**
* - 32-Bit Mode: Task Gate
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_TASK_GATE 0x00000005
/**
* - 32-Bit Mode: 16-bit Interrupt Gate
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_INTERRUPT_GATE_16 0x00000006
/**
* - 32-Bit Mode: 16-bit Trap Gate
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_TRAP_GATE_16 0x00000007
/**
* - 32-Bit Mode: Reserved
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_RESERVED_2 0x00000008
/**
* - 32-Bit Mode: 32-bit TSS (Available)
* - IA-32e Mode: 64-bit TSS (Available)
*/
#define SEGMENT_DESCRIPTOR_TYPE_TSS_AVAILABLE 0x00000009
/**
* - 32-Bit Mode: Reserved
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_RESERVED_3 0x0000000A
/**
* - 32-Bit Mode: 32-bit TSS (Busy)
* - IA-32e Mode: 64-bit TSS (Busy)
*/
#define SEGMENT_DESCRIPTOR_TYPE_TSS_BUSY 0x0000000B
/**
* - 32-Bit Mode: 32-bit Call Gate
* - IA-32e Mode: 64-bit Call Gate
*/
#define SEGMENT_DESCRIPTOR_TYPE_CALL_GATE 0x0000000C
/**
* - 32-Bit Mode: Reserved
* - IA-32e Mode: Reserved
*/
#define SEGMENT_DESCRIPTOR_TYPE_RESERVED_4 0x0000000D
/**
* - 32-Bit Mode: 32-bit Interrupt Gate
* - IA-32e Mode: 64-bit Interrupt Gate
*/
#define SEGMENT_DESCRIPTOR_TYPE_INTERRUPT_GATE 0x0000000E
/**
* - 32-Bit Mode: 32-bit Trap Gate
* - IA-32e Mode: 64-bit Trap Gate
*/
#define SEGMENT_DESCRIPTOR_TYPE_TRAP_GATE 0x0000000F
/**
* @}
*/
/**
* @brief A segment selector is a 16-bit identifier for a segment. It does not point directly to the segment, but instead
* points to the segment descriptor that defines the segment
*
* @see Vol3A[3.4.2(Segment Selectors)] (reference)
*/
typedef union
{
struct
{
/**
* [Bits 1:0] Specifies the privilege level of the selector. The privilege level can range from 0 to 3, with 0 being the
* most privileged level.
*
* @see Vol3A[5.5(Privilege Levels)]
*/
UINT16_t request_privilege_level : 2;
#define SEGMENT_SELECTOR_REQUEST_PRIVILEGE_LEVEL_BIT 0
#define SEGMENT_SELECTOR_REQUEST_PRIVILEGE_LEVEL_FLAG 0x03
#define SEGMENT_SELECTOR_REQUEST_PRIVILEGE_LEVEL_MASK 0x03
#define SEGMENT_SELECTOR_REQUEST_PRIVILEGE_LEVEL(_) (((_) >> 0) & 0x03)
/**
* [Bit 2] Specifies the descriptor table to use: clearing this flag selects the GDT; setting this flag selects the current
* LDT.
*/
UINT16_t table : 1;
#define SEGMENT_SELECTOR_TABLE_BIT 2
#define SEGMENT_SELECTOR_TABLE_FLAG 0x04
#define SEGMENT_SELECTOR_TABLE_MASK 0x01
#define SEGMENT_SELECTOR_TABLE(_) (((_) >> 2) & 0x01)
/**
* [Bits 15:3] Selects one of 8192 descriptors in the GDT or LDT. The processor multiplies the index value by 8 (the number
* of bytes in a segment descriptor) and adds the result to the base address of the GDT or LDT (from the GDTR or LDTR
* register, respectively).
*/
UINT16_t index : 13;
#define SEGMENT_SELECTOR_INDEX_BIT 3
#define SEGMENT_SELECTOR_INDEX_FLAG 0xFFF8
#define SEGMENT_SELECTOR_INDEX_MASK 0x1FFF
#define SEGMENT_SELECTOR_INDEX(_) (((_) >> 3) & 0x1FFF)
};
UINT16_t flags;
} segment_selector;
/**
* @}
*/
/**
* @defgroup vmx \
* VMX
* @{
*/
/**
* @{
*/
/**
* @defgroup vmx_basic_exit_reasons \
* VMX Basic Exit Reasons
*
* VMX Basic Exit Reasons.
*
* @see Vol3D[C(VMX BASIC EXIT REASONS)] (reference)
* @{
*/
/**
* @brief Exception or non-maskable interrupt (NMI)
*
* Either:
* -# Guest software caused an exception and the bit in the exception bitmap associated with exception's vector was 1. This
* case includes executions of BOUND that cause \#BR, executions of INT1 (they cause \#DB), executions of INT3 (they cause
* \#BP), executions of INTO that cause \#OF, and executions of UD0, UD1, and UD2 (they cause \#UD).
* -# An NMI was delivered to the logical processor and the "NMI exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXCEPTION_OR_NMI 0x00000000
/**
* @brief External interrupt
*
* An external interrupt arrived and the "external-interrupt exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXTERNAL_INTERRUPT 0x00000001
/**
* @brief Triple fault
*
* The logical processor encountered an exception while attempting to call the double-fault handler and that exception did
* not itself cause a VM exit due to the exception bitmap.
*/
#define VMX_EXIT_REASON_TRIPLE_FAULT 0x00000002
/**
* @brief INIT signal
*
* An INIT signal arrived.
*/
#define VMX_EXIT_REASON_INIT_SIGNAL 0x00000003
/**
* @brief Start-up IPI (SIPI)
*
* A SIPI arrived while the logical processor was in the "wait-for-SIPI" state.
*/
#define VMX_EXIT_REASON_STARTUP_IPI 0x00000004
/**
* @brief I/O system-management interrupt (SMI)
*
* An SMI arrived immediately after retirement of an I/O instruction and caused an SMM VM exit.
*
* @see Vol3C[34.15.2(SMM VM Exits)]
*/
#define VMX_EXIT_REASON_IO_SMI 0x00000005
/**
* @brief Other SMI
*
* An SMI arrived and caused an SMM VM exit but not immediately after retirement of an I/O instruction.
*
* @see Vol3C[34.15.2(SMM VM Exits)]
*/
#define VMX_EXIT_REASON_SMI 0x00000006
/**
* @brief Interrupt window exiting
*
* At the beginning of an instruction, RFLAGS.IF was 1; events were not blocked by STI or by MOV SS; and the
* "interrupt-window exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_INTERRUPT_WINDOW 0x00000007
/**
* @brief NMI window exiting
*
* At the beginning of an instruction, there was no virtual-NMI blocking; events were not blocked by MOV SS; and the
* "NMI-window exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_NMI_WINDOW 0x00000008
/**
* @brief Task switch
*
* Guest software attempted a task switch.
*/
#define VMX_EXIT_REASON_TASK_SWITCH 0x00000009
/**
* @brief CPUID
*
* Guest software attempted to execute CPUID.
*/
#define VMX_EXIT_REASON_EXECUTE_CPUID 0x0000000A
/**
* @brief GETSEC
*
* Guest software attempted to execute GETSEC.
*/
#define VMX_EXIT_REASON_EXECUTE_GETSEC 0x0000000B
/**
* @brief HLT
*
* Guest software attempted to execute HLT and the "HLT exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_HLT 0x0000000C
/**
* @brief INVD
*
* Guest software attempted to execute INVD.
*/
#define VMX_EXIT_REASON_EXECUTE_INVD 0x0000000D
/**
* @brief INVLPG
*
* Guest software attempted to execute INVLPG and the "INVLPG exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_INVLPG 0x0000000E
/**
* @brief RDPMC
*
* Guest software attempted to execute RDPMC and the "RDPMC exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_RDPMC 0x0000000F
/**
* @brief RDTSC
*
* Guest software attempted to execute RDTSC and the "RDTSC exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_RDTSC 0x00000010
/**
* @brief RSM in SMM
*
* Guest software attempted to execute RSM in SMM.
*/
#define VMX_EXIT_REASON_EXECUTE_RSM_IN_SMM 0x00000011
/**
* @brief VMCALL
*
* VMCALL was executed either by guest software (causing an ordinary VM exit) or by the executive monitor (causing an SMM
* VM exit).
*
* @see Vol3C[34.15.2(SMM VM Exits)]
*/
#define VMX_EXIT_REASON_EXECUTE_VMCALL 0x00000012
/**
* @brief VMCLEAR
*
* Guest software attempted to execute VMCLEAR.
*/
#define VMX_EXIT_REASON_EXECUTE_VMCLEAR 0x00000013
/**
* @brief VMLAUNCH
*
* Guest software attempted to execute VMLAUNCH.
*/
#define VMX_EXIT_REASON_EXECUTE_VMLAUNCH 0x00000014
/**
* @brief VMPTRLD
*
* Guest software attempted to execute VMPTRLD.
*/
#define VMX_EXIT_REASON_EXECUTE_VMPTRLD 0x00000015
/**
* @brief VMPTRST
*
* Guest software attempted to execute VMPTRST.
*/
#define VMX_EXIT_REASON_EXECUTE_VMPTRST 0x00000016
/**
* @brief VMREAD
*
* Guest software attempted to execute VMREAD.
*/
#define VMX_EXIT_REASON_EXECUTE_VMREAD 0x00000017
/**
* @brief VMRESUME
*
* Guest software attempted to execute VMRESUME.
*/
#define VMX_EXIT_REASON_EXECUTE_VMRESUME 0x00000018
/**
* @brief VMWRITE
*
* Guest software attempted to execute VMWRITE.
*/
#define VMX_EXIT_REASON_EXECUTE_VMWRITE 0x00000019
/**
* @brief VMXOFF
*
* Guest software attempted to execute VMXOFF.
*/
#define VMX_EXIT_REASON_EXECUTE_VMXOFF 0x0000001A
/**
* @brief VMXON
*
* Guest software attempted to execute VMXON.
*/
#define VMX_EXIT_REASON_EXECUTE_VMXON 0x0000001B
/**
* @brief Control-register accesses
*
* Guest software attempted to access CR0, CR3, CR4, or CR8 using CLTS, LMSW, or MOV CR and the VM-execution control fields
* indicate that a VM exit should occur. This basic exit reason is not used for trap-like VM exits following executions of
* the MOV to CR8 instruction when the "use TPR shadow" VM-execution control is 1. Such VM exits instead use basic exit
* reason 43.
*
* @see Vol3C[25.1(INSTRUCTIONS THAT CAUSE VM EXITS)]
*/
#define VMX_EXIT_REASON_MOV_CR 0x0000001C
/**
* @brief Debug-register accesses
*
* Guest software attempted a MOV to or from a debug register and the "MOV-DR exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_MOV_DR 0x0000001D
/**
* @brief I/O instruction
*
* Guest software attempted to execute an I/O instruction and either:
* -# The "use I/O bitmaps" VM-execution control was 0 and the "unconditional I/O exiting" VM-execution control was 1.
* -# The "use I/O bitmaps" VM-execution control was 1 and a bit in the I/O bitmap associated with one of the ports
* accessed by the I/O instruction was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_IO_INSTRUCTION 0x0000001E
/**
* @brief RDMSR
*
* Guest software attempted to execute RDMSR and either:
* -# The "use MSR bitmaps" VM-execution control was 0.
* -# The value of RCX is neither in the range 00000000H - 00001FFFH nor in the range C0000000H - C0001FFFH.
* -# The value of RCX was in the range 00000000H - 00001FFFH and the nth bit in read bitmap for low MSRs is 1, where n was
* the value of RCX.
* -# The value of RCX is in the range C0000000H - C0001FFFH and the nth bit in read bitmap for high MSRs is 1, where n is
* the value of RCX & 00001FFFH.
*/
#define VMX_EXIT_REASON_EXECUTE_RDMSR 0x0000001F
/**
* @brief WRMSR
*
* Guest software attempted to execute WRMSR and either:
* -# The "use MSR bitmaps" VM-execution control was 0.
* -# The value of RCX is neither in the range 00000000H - 00001FFFH nor in the range C0000000H - C0001FFFH.
* -# The value of RCX was in the range 00000000H - 00001FFFH and the nth bit in write bitmap for low MSRs is 1, where n
* was the value of RCX.
* -# The value of RCX is in the range C0000000H - C0001FFFH and the nth bit in write bitmap for high MSRs is 1, where n is
* the value of RCX & 00001FFFH.
*/
#define VMX_EXIT_REASON_EXECUTE_WRMSR 0x00000020
/**
* @brief VM-entry failure due to invalid guest state
*
* A VM entry failed one of the checks identified in Section 26.3.1.
*/
#define VMX_EXIT_REASON_ERROR_INVALID_GUEST_STATE 0x00000021
/**
* @brief VM-entry failure due to MSR loading
*
* A VM entry failed in an attempt to load MSRs. See Section 26.4.
*/
#define VMX_EXIT_REASON_ERROR_MSR_LOAD 0x00000022
/**
* @brief Guest software executed MWAIT
*
* Guest software attempted to execute MWAIT and the "MWAIT exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_MWAIT 0x00000024
/**
* @brief VM-exit due to monitor trap flag
*
* A VM entry occurred due to the 1-setting of the "monitor trap flag" VM-execution control and injection of an MTF VM exit
* as part of VM entry.
*
* @see Vol3C[25.5.2(Monitor Trap Flag)]
*/
#define VMX_EXIT_REASON_MONITOR_TRAP_FLAG 0x00000025
/**
* @brief Guest software attempted to execute MONITOR
*
* Guest software attempted to execute MONITOR and the "MONITOR exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_MONITOR 0x00000027
/**
* @brief Guest software attempted to execute PAUSE
*
* Either guest software attempted to execute PAUSE and the "PAUSE exiting" VM-execution control was 1 or the "PAUSE-loop
* exiting" VM-execution control was 1 and guest software executed a PAUSE loop with execution time exceeding PLE_Window.
*
* @see Vol3C[25.1.3(Instructions That Cause VM Exits Conditionally)]
*/
#define VMX_EXIT_REASON_EXECUTE_PAUSE 0x00000028
/**
* @brief VM-entry failure due to machine-check
*
* A machine-check event occurred during VM entry.
*
* @see Vol3C[26.8(MACHINE-CHECK EVENTS DURING VM ENTRY)]
*/
#define VMX_EXIT_REASON_ERROR_MACHINE_CHECK 0x00000029
/**
* @brief TPR below threshold
*
* The logical processor determined that the value of bits 7:4 of the byte at offset 080H on the virtual-APIC page was
* below that of the TPR threshold VM-execution control field while the "use TPR shadow" VMexecution control was 1 either
* as part of TPR virtualization or VM entry.
*
* @see Vol3C[29.1.2(TPR Virtualization)]
* @see Vol3C[26.6.7(VM Exits Induced by the TPR Threshold)]
*/
#define VMX_EXIT_REASON_TPR_BELOW_THRESHOLD 0x0000002B
/**
* @brief APIC access
*
* Guest software attempted to access memory at a physical address on the APIC-access page and the "virtualize APIC
* accesses" VM-execution control was 1.
*
* @see Vol3C[29.4(VIRTUALIZING MEMORY-MAPPED APIC ACCESSES)]
*/
#define VMX_EXIT_REASON_APIC_ACCESS 0x0000002C
/**
* @brief Virtualized EOI
*
* EOI virtualization was performed for a virtual interrupt whose vector indexed a bit set in the EOIexit bitmap.
*/
#define VMX_EXIT_REASON_VIRTUALIZED_EOI 0x0000002D
/**
* @brief Access to GDTR or IDTR
*
* Guest software attempted to execute LGDT, LIDT, SGDT, or SIDT and the "descriptor-table exiting" VM-execution control
* was 1.
*/
#define VMX_EXIT_REASON_GDTR_IDTR_ACCESS 0x0000002E
/**
* @brief Access to LDTR or TR
*
* Guest software attempted to execute LLDT, LTR, SLDT, or STR and the "descriptor-table exiting" VM-execution control was
* 1.
*/
#define VMX_EXIT_REASON_LDTR_TR_ACCESS 0x0000002F
/**
* @brief EPT violation
*
* An attempt to access memory with a guest-physical address was disallowed by the configuration of the EPT paging
* structures.
*/
#define VMX_EXIT_REASON_EPT_VIOLATION 0x00000030
/**
* @brief EPT misconfiguration
*
* An attempt to access memory with a guest-physical address encountered a misconfigured EPT paging-structure entry.
*/
#define VMX_EXIT_REASON_EPT_MISCONFIGURATION 0x00000031
/**
* @brief INVEPT
*
* Guest software attempted to execute INVEPT.
*/
#define VMX_EXIT_REASON_EXECUTE_INVEPT 0x00000032
/**
* @brief RDTSCP
*
* Guest software attempted to execute RDTSCP and the "enable RDTSCP" and "RDTSC exiting" VM-execution controls were both
* 1.
*/
#define VMX_EXIT_REASON_EXECUTE_RDTSCP 0x00000033
/**
* @brief VMX-preemption timer expired
*
* The preemption timer counted down to zero.
*/
#define VMX_EXIT_REASON_VMX_PREEMPTION_TIMER_EXPIRED 0x00000034
/**
* @brief INVVPID
*
* Guest software attempted to execute INVVPID.
*/
#define VMX_EXIT_REASON_EXECUTE_INVVPID 0x00000035
/**
* @brief WBINVD
*
* Guest software attempted to execute WBINVD and the "WBINVD exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_WBINVD 0x00000036
/**
* @brief XSETBV - Guest software attempted to execute XSETBV
*
* Guest software attempted to execute XSETBV.
*/
#define VMX_EXIT_REASON_EXECUTE_XSETBV 0x00000037
/**
* @brief APIC write
*
* Guest software completed a write to the virtual-APIC page that must be virtualized by VMM software.
*
* @see Vol3C[29.4.3.3(APIC-Write VM Exits)]
*/
#define VMX_EXIT_REASON_APIC_WRITE 0x00000038
/**
* @brief RDRAND
*
* Guest software attempted to execute RDRAND and the "RDRAND exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_RDRAND 0x00000039
/**
* @brief INVPCID
*
* Guest software attempted to execute INVPCID and the "enable INVPCID" and "INVLPG exiting" VM-execution controls were
* both 1.
*/
#define VMX_EXIT_REASON_EXECUTE_INVPCID 0x0000003A
/**
* @brief VMFUNC
*
* Guest software invoked a VM function with the VMFUNC instruction and the VM function either was not enabled or generated
* a function-specific condition causing a VM exit.
*/
#define VMX_EXIT_REASON_EXECUTE_VMFUNC 0x0000003B
/**
* @brief ENCLS
*
* Guest software attempted to execute ENCLS and "enable ENCLS exiting" VM-execution control was 1 and either:
* -# EAX < 63 and the corresponding bit in the ENCLS-exiting bitmap is 1; or
* -# EAX >= 63 and bit 63 in the ENCLS-exiting bitmap is 1.
*/
#define VMX_EXIT_REASON_EXECUTE_ENCLS 0x0000003C
/**
* @brief RDSEED
*
* Guest software attempted to execute RDSEED and the "RDSEED exiting" VM-execution control was 1.
*/
#define VMX_EXIT_REASON_EXECUTE_RDSEED 0x0000003D
/**
* @brief Page-modification log full
*
* The processor attempted to create a page-modification log entry and the value of the PML index was not in the range
* 0-511.
*/
#define VMX_EXIT_REASON_PAGE_MODIFICATION_LOG_FULL 0x0000003E
/**
* @brief XSAVES
*
* Guest software attempted to execute XSAVES, the "enable XSAVES/XRSTORS" was 1, and a bit was set in the logical-AND of
* the following three values: EDX:EAX, the IA32_XSS MSR, and the XSS-exiting bitmap.
*/
#define VMX_EXIT_REASON_EXECUTE_XSAVES 0x0000003F
/**
* @brief XRSTORS
*
* Guest software attempted to execute XRSTORS, the "enable XSAVES/XRSTORS" was 1, and a bit was set in the logical-AND of
* the following three values: EDX:EAX, the IA32_XSS MSR, and the XSS-exiting bitmap.
*/
#define VMX_EXIT_REASON_EXECUTE_XRSTORS 0x00000040
/**
* @}
*/
/**
* @defgroup vmx_instruction_error_numbers \
* VM-Instruction Error Numbers
*
* VM-Instruction Error Numbers.
*
* @see Vol3C[30.4(VM INSTRUCTION ERROR NUMBERS)] (reference)
* @{
*/
/**
* VMCALL executed in VMX root operation.
*/
#define VMX_ERROR_VMCALL_IN_VMX_ROOT_OPERATION 0x00000001
/**
* VMCLEAR with invalid physical address.
*/
#define VMX_ERROR_VMCLEAR_INVALID_PHYSICAL_ADDRESS 0x00000002
/**
* VMCLEAR with VMXON pointer.
*/
#define VMX_ERROR_VMCLEAR_INVALID_VMXON_POINTER 0x00000003
/**
* VMLAUNCH with non-clear VMCS.
*/
#define VMX_ERROR_VMLAUCH_NON_CLEAR_VMCS 0x00000004
/**
* VMRESUME with non-launched VMCS.
*/
#define VMX_ERROR_VMRESUME_NON_LAUNCHED_VMCS 0x00000005
/**
* VMRESUME after VMXOFF (VMXOFF and VMXON between VMLAUNCH and VMRESUME).
*/
#define VMX_ERROR_VMRESUME_AFTER_VMXOFF 0x00000006
/**
* VM entry with invalid control field(s).
*/
#define VMX_ERROR_VMENTRY_INVALID_CONTROL_FIELDS 0x00000007
/**
* VM entry with invalid host-state field(s).
*/
#define VMX_ERROR_VMENTRY_INVALID_HOST_STATE 0x00000008
/**
* VMPTRLD with invalid physical address.
*/
#define VMX_ERROR_VMPTRLD_INVALID_PHYSICAL_ADDRESS 0x00000009
/**
* VMPTRLD with VMXON pointer.
*/
#define VMX_ERROR_VMPTRLD_VMXON_POINTER 0x0000000A
/**
* VMPTRLD with incorrect VMCS revision identifier.
*/
#define VMX_ERROR_VMPTRLD_INCORRECT_VMCS_REVISION_ID 0x0000000B
/**
* VMREAD/VMWRITE from/to unsupported VMCS component.
*/
#define VMX_ERROR_VMREAD_VMWRITE_INVALID_COMPONENT 0x0000000C
/**
* VMWRITE to read-only VMCS component.
*/
#define VMX_ERROR_VMWRITE_READONLY_COMPONENT 0x0000000D
/**
* VMXON executed in VMX root operation.
*/
#define VMX_ERROR_VMXON_IN_VMX_ROOT_OP 0x0000000F
/**
* VM entry with invalid executive-VMCS pointer.
*/
#define VMX_ERROR_VMENTRY_INVALID_VMCS_EXECUTIVE_POINTER 0x00000010
/**
* VM entry with non-launched executive VMCS.
*/
#define VMX_ERROR_VMENTRY_NON_LAUNCHED_EXECUTIVE_VMCS 0x00000011
/**
* VM entry with executive-VMCS pointer not VMXON pointer (when attempting to deactivate the dual-monitor treatment of SMIs
* and SMM).
*/
#define VMX_ERROR_VMENTRY_EXECUTIVE_VMCS_PTR 0x00000012
/**
* VMCALL with non-clear VMCS (when attempting to activate the dual-monitor treatment of SMIs and SMM).
*/
#define VMX_ERROR_VMCALL_NON_CLEAR_VMCS 0x00000013
/**
* VMCALL with invalid VM-exit control fields.
*/
#define VMX_ERROR_VMCALL_INVALID_VMEXIT_FIELDS 0x00000014
/**
* VMCALL with incorrect MSEG revision identifier (when attempting to activate the dual-monitor treatment of SMIs and SMM).
*/
#define VMX_ERROR_VMCALL_INVALID_MSEG_REVISION_ID 0x00000016
/**
* VMXOFF under dual-monitor treatment of SMIs and SMM.
*/
#define VMX_ERROR_VMXOFF_DUAL_MONITOR 0x00000017
/**
* VMCALL with invalid SMM-monitor features (when attempting to activate the dual-monitor treatment of SMIs and SMM).
*/
#define VMX_ERROR_VMCALL_INVALID_SMM_MONITOR 0x00000018
/**
* VM entry with invalid VM-execution control fields in executive VMCS (when attempting to return from SMM).
*/
#define VMX_ERROR_VMENTRY_INVALID_VM_EXECUTION_CONTROL 0x00000019
/**
* VM entry with events blocked by MOV SS.
*/
#define VMX_ERROR_VMENTRY_MOV_SS 0x0000001A
/**
* Invalid operand to INVEPT/INVVPID.
*/
#define VMX_ERROR_INVEPT_INVVPID_INVALID_OPERAND 0x0000001C
/**
* @}
*/
/**
* @defgroup vmx_exceptions \
* Virtualization Exceptions
*
* Virtualization Exceptions.
*
* @see Vol3C[25.5.6(Virtualization Exceptions)] (reference)
* @{
*/
typedef struct
{
/**
* The 32-bit value that would have been saved into the VMCS as an exit reason had a VM exit occurred instead of the
* virtualization exception. For EPT violations, this value is 48 (00000030H).
*/
UINT32_t reason;
/**
* FFFFFFFFH
*/
UINT32_t exception_mask;
/**
* The 64-bit value that would have been saved into the VMCS as an exit qualification had a VM exit occurred instead of the
* virtualization exception.
*/
UINT64_t exit;
/**
* The 64-bit value that would have been saved into the VMCS as a guest-linear address had a VM exit occurred instead of
* the virtualization exception.
*/
UINT64_t guest_linear_address;
/**
* The 64-bit value that would have been saved into the VMCS as a guest-physical address had a VM exit occurred instead of
* the virtualization exception.
*/
UINT64_t guest_physical_address;
/**
* The current 16-bit value of the EPTP index VM-execution control.
*
* @see Vol3C[24.6.18(Controls for Virtualization Exceptions)]
* @see Vol3C[25.5.5.3(EPTP Switching)]
*/
UINT16_t current_eptp_index;
} vmx_virtualization_exception_information;
/**
* @}
*/
/**
* @defgroup vmx_basic_exit_information \
* Basic VM-Exit Information
*
* Basic VM-Exit Information.
*
* @see Vol3C[27.2.1(Basic VM-Exit Information)] (reference)
* @{
*/
/**
* @brief Exit Qualification for Debug Exceptions
*/
typedef union
{
struct
{
/**
* @brief B0 - B3
*
* [Bits 3:0] When set, each of these bits indicates that the corresponding breakpoint condition was met. Any of these bits
* may be set even if its corresponding enabling bit in DR7 is not set.
*/
UINT64_t breakpoint_condition : 4;
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_BREAKPOINT_CONDITION_BIT 0
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_BREAKPOINT_CONDITION_FLAG 0x0F
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_BREAKPOINT_CONDITION_MASK 0x0F
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_BREAKPOINT_CONDITION(_) (((_) >> 0) & 0x0F)
UINT64_t reserved1 : 9;
/**
* @brief BD
*
* [Bit 13] When set, this bit indicates that the cause of the debug exception is "debug register access detected."
*/
UINT64_t debug_register_access_detected : 1;
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_DEBUG_REGISTER_ACCESS_DETECTED_BIT 13
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_DEBUG_REGISTER_ACCESS_DETECTED_FLAG 0x2000
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_DEBUG_REGISTER_ACCESS_DETECTED_MASK 0x01
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_DEBUG_REGISTER_ACCESS_DETECTED(_) (((_) >> 13) & 0x01)
/**
* @brief BS
*
* [Bit 14] When set, this bit indicates that the cause of the debug exception is either the execution of a single
* instruction (if RFLAGS.TF = 1 and IA32_DEBUGCTL.BTF = 0) or a taken branch (if RFLAGS.TF = DEBUGCTL.BTF = 1).
*/
UINT64_t single_instruction : 1;
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_SINGLE_INSTRUCTION_BIT 14
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_SINGLE_INSTRUCTION_FLAG 0x4000
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_SINGLE_INSTRUCTION_MASK 0x01
#define VMX_EXIT_QUALIFICATION_DEBUG_EXCEPTION_SINGLE_INSTRUCTION(_) (((_) >> 14) & 0x01)
UINT64_t reserved2 : 49;
};
UINT64_t flags;
} vmx_exit_qualification_debug_exception;
/**
* @brief Exit Qualification for Task Switch
*/
typedef union
{
struct
{
/**
* [Bits 15:0] Selector of task-state segment (TSS) to which the guest attempted to switch.
*/
UINT64_t selector : 16;
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SELECTOR_BIT 0
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SELECTOR_FLAG 0xFFFF
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SELECTOR_MASK 0xFFFF
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SELECTOR(_) (((_) >> 0) & 0xFFFF)
UINT64_t reserved1 : 14;
/**
* [Bits 31:30] Source of task switch initiation.
*/
UINT64_t source : 2;
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SOURCE_BIT 30
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SOURCE_FLAG 0xC0000000
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SOURCE_MASK 0x03
#define VMX_EXIT_QUALIFICATION_TASK_SWITCH_SOURCE(_) (((_) >> 30) & 0x03)
#define VMX_EXIT_QUALIFICATION_TYPE_CALL_INSTRUCTION 0x00000000
#define VMX_EXIT_QUALIFICATION_TYPE_IRET_INSTRUCTION 0x00000001
#define VMX_EXIT_QUALIFICATION_TYPE_JMP_INSTRUCTION 0x00000002
#define VMX_EXIT_QUALIFICATION_TYPE_TASK_GATE_IN_IDT 0x00000003
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} vmx_exit_qualification_task_switch;
/**
* @brief Exit Qualification for Control-Register Accesses
*/
typedef union
{
struct
{
/**
* [Bits 3:0] Number of control register (0 for CLTS and LMSW). Bit 3 is always 0 on processors that do not support Intel
* 64 architecture as they do not support CR8.
*/
UINT64_t control_register : 4;
#define VMX_EXIT_QUALIFICATION_MOV_CR_CONTROL_REGISTER_BIT 0
#define VMX_EXIT_QUALIFICATION_MOV_CR_CONTROL_REGISTER_FLAG 0x0F
#define VMX_EXIT_QUALIFICATION_MOV_CR_CONTROL_REGISTER_MASK 0x0F
#define VMX_EXIT_QUALIFICATION_MOV_CR_CONTROL_REGISTER(_) (((_) >> 0) & 0x0F)
#define VMX_EXIT_QUALIFICATION_REGISTER_CR0 0x00000000
#define VMX_EXIT_QUALIFICATION_REGISTER_CR2 0x00000002
#define VMX_EXIT_QUALIFICATION_REGISTER_CR3 0x00000003
#define VMX_EXIT_QUALIFICATION_REGISTER_CR4 0x00000004
#define VMX_EXIT_QUALIFICATION_REGISTER_CR8 0x00000008
/**
* [Bits 5:4] Access type.
*/
UINT64_t access_type : 2;
#define VMX_EXIT_QUALIFICATION_MOV_CR_ACCESS_TYPE_BIT 4
#define VMX_EXIT_QUALIFICATION_MOV_CR_ACCESS_TYPE_FLAG 0x30
#define VMX_EXIT_QUALIFICATION_MOV_CR_ACCESS_TYPE_MASK 0x03
#define VMX_EXIT_QUALIFICATION_MOV_CR_ACCESS_TYPE(_) (((_) >> 4) & 0x03)
#define VMX_EXIT_QUALIFICATION_ACCESS_MOV_TO_CR 0x00000000
#define VMX_EXIT_QUALIFICATION_ACCESS_MOV_FROM_CR 0x00000001
#define VMX_EXIT_QUALIFICATION_ACCESS_CLTS 0x00000002
#define VMX_EXIT_QUALIFICATION_ACCESS_LMSW 0x00000003
/**
* [Bit 6] LMSW operand type. For CLTS and MOV CR, cleared to 0.
*/
UINT64_t lmsw_operand_type : 1;
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_OPERAND_TYPE_BIT 6
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_OPERAND_TYPE_FLAG 0x40
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_OPERAND_TYPE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_OPERAND_TYPE(_) (((_) >> 6) & 0x01)
#define VMX_EXIT_QUALIFICATION_LMSW_OP_REGISTER 0x00000000
#define VMX_EXIT_QUALIFICATION_LMSW_OP_MEMORY 0x00000001
UINT64_t reserved1 : 1;
/**
* [Bits 11:8] For MOV CR, the general-purpose register.
*/
UINT64_t general_purpose_register : 4;
#define VMX_EXIT_QUALIFICATION_MOV_CR_GENERAL_PURPOSE_REGISTER_BIT 8
#define VMX_EXIT_QUALIFICATION_MOV_CR_GENERAL_PURPOSE_REGISTER_FLAG 0xF00
#define VMX_EXIT_QUALIFICATION_MOV_CR_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_EXIT_QUALIFICATION_MOV_CR_GENERAL_PURPOSE_REGISTER(_) (((_) >> 8) & 0x0F)
#define VMX_EXIT_QUALIFICATION_GENREG_RAX 0x00000000
#define VMX_EXIT_QUALIFICATION_GENREG_RCX 0x00000001
#define VMX_EXIT_QUALIFICATION_GENREG_RDX 0x00000002
#define VMX_EXIT_QUALIFICATION_GENREG_RBX 0x00000003
#define VMX_EXIT_QUALIFICATION_GENREG_RSP 0x00000004
#define VMX_EXIT_QUALIFICATION_GENREG_RBP 0x00000005
#define VMX_EXIT_QUALIFICATION_GENREG_RSI 0x00000006
#define VMX_EXIT_QUALIFICATION_GENREG_RDI 0x00000007
#define VMX_EXIT_QUALIFICATION_GENREG_R8 0x00000008
#define VMX_EXIT_QUALIFICATION_GENREG_R9 0x00000009
#define VMX_EXIT_QUALIFICATION_GENREG_R10 0x0000000A
#define VMX_EXIT_QUALIFICATION_GENREG_R11 0x0000000B
#define VMX_EXIT_QUALIFICATION_GENREG_R12 0x0000000C
#define VMX_EXIT_QUALIFICATION_GENREG_R13 0x0000000D
#define VMX_EXIT_QUALIFICATION_GENREG_R14 0x0000000E
#define VMX_EXIT_QUALIFICATION_GENREG_R15 0x0000000F
UINT64_t reserved2 : 4;
/**
* [Bits 31:16] For LMSW, the LMSW source data. For CLTS and MOV CR, cleared to 0.
*/
UINT64_t lmsw_source_data : 16;
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_SOURCE_DATA_BIT 16
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_SOURCE_DATA_FLAG 0xFFFF0000
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_SOURCE_DATA_MASK 0xFFFF
#define VMX_EXIT_QUALIFICATION_MOV_CR_LMSW_SOURCE_DATA(_) (((_) >> 16) & 0xFFFF)
UINT64_t reserved3 : 32;
};
UINT64_t flags;
} vmx_exit_qualification_mov_cr;
/**
* @brief Exit Qualification for MOV DR
*/
typedef union
{
struct
{
/**
* [Bits 2:0] Number of debug register.
*/
UINT64_t debug_register : 3;
#define VMX_EXIT_QUALIFICATION_MOV_DR_DEBUG_REGISTER_BIT 0
#define VMX_EXIT_QUALIFICATION_MOV_DR_DEBUG_REGISTER_FLAG 0x07
#define VMX_EXIT_QUALIFICATION_MOV_DR_DEBUG_REGISTER_MASK 0x07
#define VMX_EXIT_QUALIFICATION_MOV_DR_DEBUG_REGISTER(_) (((_) >> 0) & 0x07)
#define VMX_EXIT_QUALIFICATION_REGISTER_DR0 0x00000000
#define VMX_EXIT_QUALIFICATION_REGISTER_DR1 0x00000001
#define VMX_EXIT_QUALIFICATION_REGISTER_DR2 0x00000002
#define VMX_EXIT_QUALIFICATION_REGISTER_DR3 0x00000003
#define VMX_EXIT_QUALIFICATION_REGISTER_DR6 0x00000006
#define VMX_EXIT_QUALIFICATION_REGISTER_DR7 0x00000007
UINT64_t reserved1 : 1;
/**
* [Bit 4] Direction of access (0 = MOV to DR; 1 = MOV from DR).
*/
UINT64_t direction_of_access : 1;
#define VMX_EXIT_QUALIFICATION_MOV_DR_DIRECTION_OF_ACCESS_BIT 4
#define VMX_EXIT_QUALIFICATION_MOV_DR_DIRECTION_OF_ACCESS_FLAG 0x10
#define VMX_EXIT_QUALIFICATION_MOV_DR_DIRECTION_OF_ACCESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_MOV_DR_DIRECTION_OF_ACCESS(_) (((_) >> 4) & 0x01)
#define VMX_EXIT_QUALIFICATION_DIRECTION_MOV_TO_DR 0x00000000
#define VMX_EXIT_QUALIFICATION_DIRECTION_MOV_FROM_DR 0x00000001
UINT64_t reserved2 : 3;
/**
* [Bits 11:8] General-purpose register.
*/
UINT64_t general_purpose_register : 4;
#define VMX_EXIT_QUALIFICATION_MOV_DR_GENERAL_PURPOSE_REGISTER_BIT 8
#define VMX_EXIT_QUALIFICATION_MOV_DR_GENERAL_PURPOSE_REGISTER_FLAG 0xF00
#define VMX_EXIT_QUALIFICATION_MOV_DR_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_EXIT_QUALIFICATION_MOV_DR_GENERAL_PURPOSE_REGISTER(_) (((_) >> 8) & 0x0F)
UINT64_t reserved3 : 52;
};
UINT64_t flags;
} vmx_exit_qualification_mov_dr;
/**
* @brief Exit Qualification for I/O Instructions
*/
typedef union
{
struct
{
/**
* [Bits 2:0] Size of access.
*/
UINT64_t size_of_access : 3;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_SIZE_OF_ACCESS_BIT 0
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_SIZE_OF_ACCESS_FLAG 0x07
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_SIZE_OF_ACCESS_MASK 0x07
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_SIZE_OF_ACCESS(_) (((_) >> 0) & 0x07)
#define VMX_EXIT_QUALIFICATION_WIDTH_1UINT8 0x00000000
#define VMX_EXIT_QUALIFICATION_WIDTH_2UINT8 0x00000001
#define VMX_EXIT_QUALIFICATION_WIDTH_4UINT8 0x00000003
/**
* [Bit 3] Direction of the attempted access (0 = OUT, 1 = IN).
*/
UINT64_t direction_of_access : 1;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_DIRECTION_OF_ACCESS_BIT 3
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_DIRECTION_OF_ACCESS_FLAG 0x08
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_DIRECTION_OF_ACCESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_DIRECTION_OF_ACCESS(_) (((_) >> 3) & 0x01)
#define VMX_EXIT_QUALIFICATION_DIRECTION_OUT 0x00000000
#define VMX_EXIT_QUALIFICATION_DIRECTION_IN 0x00000001
/**
* [Bit 4] String instruction (0 = not string; 1 = string).
*/
UINT64_t string_instruction : 1;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_STRING_INSTRUCTION_BIT 4
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_STRING_INSTRUCTION_FLAG 0x10
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_STRING_INSTRUCTION_MASK 0x01
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_STRING_INSTRUCTION(_) (((_) >> 4) & 0x01)
#define VMX_EXIT_QUALIFICATION_IS_STRING_NOT_STRING 0x00000000
#define VMX_EXIT_QUALIFICATION_IS_STRING_STRING 0x00000001
/**
* [Bit 5] REP prefixed (0 = not REP; 1 = REP).
*/
UINT64_t rep_prefixed : 1;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_REP_PREFIXED_BIT 5
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_REP_PREFIXED_FLAG 0x20
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_REP_PREFIXED_MASK 0x01
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_REP_PREFIXED(_) (((_) >> 5) & 0x01)
#define VMX_EXIT_QUALIFICATION_IS_REP_NOT_REP 0x00000000
#define VMX_EXIT_QUALIFICATION_IS_REP_REP 0x00000001
/**
* [Bit 6] Operand encoding (0 = DX, 1 = immediate).
*/
UINT64_t operand_encoding : 1;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_OPERAND_ENCODING_BIT 6
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_OPERAND_ENCODING_FLAG 0x40
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_OPERAND_ENCODING_MASK 0x01
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_OPERAND_ENCODING(_) (((_) >> 6) & 0x01)
#define VMX_EXIT_QUALIFICATION_ENCODING_DX 0x00000000
#define VMX_EXIT_QUALIFICATION_ENCODING_IMMEDIATE 0x00000001
UINT64_t reserved1 : 9;
/**
* [Bits 31:16] Port number (as specified in DX or in an immediate operand).
*/
UINT64_t port_number : 16;
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_PORT_NUMBER_BIT 16
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_PORT_NUMBER_FLAG 0xFFFF0000
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_PORT_NUMBER_MASK 0xFFFF
#define VMX_EXIT_QUALIFICATION_IO_INSTRUCTION_PORT_NUMBER(_) (((_) >> 16) & 0xFFFF)
UINT64_t reserved2 : 32;
};
UINT64_t flags;
} vmx_exit_qualification_io_instruction;
/**
* @brief Exit Qualification for APIC-Access VM Exits from Linear Accesses and Guest-Physical Accesses
*/
typedef union
{
struct
{
/**
* [Bits 11:0] - If the APIC-access VM exit is due to a linear access, the offset of access within the APIC page.
* - Undefined if the APIC-access VM exit is due a guest-physical access.
*/
UINT64_t page_offset : 12;
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_PAGE_OFFSET_BIT 0
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_PAGE_OFFSET_FLAG 0xFFF
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_PAGE_OFFSET_MASK 0xFFF
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_PAGE_OFFSET(_) (((_) >> 0) & 0xFFF)
/**
* [Bits 15:12] Access type.
*/
UINT64_t access_type : 4;
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_ACCESS_TYPE_BIT 12
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_ACCESS_TYPE_FLAG 0xF000
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_ACCESS_TYPE_MASK 0x0F
#define VMX_EXIT_QUALIFICATION_APIC_ACCESS_ACCESS_TYPE(_) (((_) >> 12) & 0x0F)
/**
* Linear access for a data read during instruction execution.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_LINEAR_READ 0x00000000
/**
* Linear access for a data write during instruction execution.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_LINEAR_WRITE 0x00000001
/**
* Linear access for an instruction fetch.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_LINEAR_INSTRUCTION_FETCH 0x00000002
/**
* Linear access (read or write) during event delivery.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_LINEAR_EVENT_DELIVERY 0x00000003
/**
* Guest-physical access during event delivery.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_PHYSICAL_EVENT_DELIVERY 0x0000000A
/**
* Guest-physical access for an instruction fetch or during instruction execution.
*/
#define VMX_EXIT_QUALIFICATION_TYPE_PHYSICAL_INSTRUCTION_FETCH 0x0000000F
UINT64_t reserved1 : 48;
};
UINT64_t flags;
} vmx_exit_qualification_apic_access;
/**
* @brief Exit Qualification for EPT Violations
*/
typedef union
{
struct
{
/**
* [Bit 0] Set if the access causing the EPT violation was a data read.
*/
UINT64_t read_access : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READ_ACCESS_BIT 0
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READ_ACCESS_FLAG 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READ_ACCESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Set if the access causing the EPT violation was a data write.
*/
UINT64_t write_access : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_WRITE_ACCESS_BIT 1
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_WRITE_ACCESS_FLAG 0x02
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_WRITE_ACCESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Set if the access causing the EPT violation was an instruction fetch.
*/
UINT64_t execute_access : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_ACCESS_BIT 2
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_ACCESS_FLAG 0x04
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_ACCESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] The logical-AND of bit 0 in the EPT paging-structure entries used to translate the guest-physical address of the
* access causing the EPT violation (indicates whether the guest-physical address was readable).
*/
UINT64_t ept_readable : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_READABLE_BIT 3
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_READABLE_FLAG 0x08
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_READABLE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_READABLE(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] The logical-AND of bit 1 in the EPT paging-structure entries used to translate the guest-physical address of the
* access causing the EPT violation (indicates whether the guest-physical address was writeable).
*/
UINT64_t ept_writeable : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_WRITEABLE_BIT 4
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_WRITEABLE_FLAG 0x10
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_WRITEABLE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_WRITEABLE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] The logical-AND of bit 2 in the EPT paging-structure entries used to translate the guest-physical address of the
* access causing the EPT violation.
* If the "mode-based execute control for EPT" VM-execution control is 0, this indicates whether the guest-physical address
* was executable. If that control is 1, this indicates whether the guest-physical address was executable for
* supervisor-mode linear addresses.
*/
UINT64_t ept_executable : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_BIT 5
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_FLAG 0x20
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE(_) (((_) >> 5) & 0x01)
/**
* [Bit 6] If the "mode-based execute control" VM-execution control is 0, the value of this bit is undefined. If that
* control is 1, this bit is the logical-AND of bit 10 in the EPT paging-structures entries used to translate the
* guest-physical address of the access causing the EPT violation. In this case, it indicates whether the guest-physical
* address was executable for user-mode linear addresses.
*/
UINT64_t ept_executable_for_user_mode : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_FOR_USER_MODE_BIT 6
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_FOR_USER_MODE_FLAG 0x40
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_FOR_USER_MODE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EPT_EXECUTABLE_FOR_USER_MODE(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Set if the guest linear-address field is valid. The guest linear-address field is valid for all EPT violations
* except those resulting from an attempt to load the guest PDPTEs as part of the execution of the MOV CR instruction.
*/
UINT64_t valid_guest_linear_address : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_VALID_GUEST_LINEAR_ADDRESS_BIT 7
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_VALID_GUEST_LINEAR_ADDRESS_FLAG 0x80
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_VALID_GUEST_LINEAR_ADDRESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_VALID_GUEST_LINEAR_ADDRESS(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] If bit 7 is 1:
* - Set if the access causing the EPT violation is to a guest-physical address that is the translation of a linear
* address.
* - Clear if the access causing the EPT violation is to a paging-structure entry as part of a page walk or the update of
* an accessed or dirty bit.
* Reserved if bit 7 is 0 (cleared to 0).
*/
UINT64_t caused_by_translation : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_CAUSED_BY_TRANSLATION_BIT 8
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_CAUSED_BY_TRANSLATION_FLAG 0x100
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_CAUSED_BY_TRANSLATION_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_CAUSED_BY_TRANSLATION(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] This bit is 0 if the linear address is a supervisor-mode linear address and 1 if it is a user-mode linear
* address. Otherwise, this bit is undefined.
*
* @remarks If bit 7 is 1, bit 8 is 1, and the processor supports advanced VM-exit information for EPT violations. (If
* CR0.PG = 0, the translation of every linear address is a user-mode linear address and thus this bit will be 1.)
*/
UINT64_t user_mode_linear_address : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_USER_MODE_LINEAR_ADDRESS_BIT 9
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_USER_MODE_LINEAR_ADDRESS_FLAG 0x200
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_USER_MODE_LINEAR_ADDRESS_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_USER_MODE_LINEAR_ADDRESS(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] This bit is 0 if paging translates the linear address to a read-only page and 1 if it translates to a
* read/write page. Otherwise, this bit is undefined
*
* @remarks If bit 7 is 1, bit 8 is 1, and the processor supports advanced VM-exit information for EPT violations. (If
* CR0.PG = 0, every linear address is read/write and thus this bit will be 1.)
*/
UINT64_t readable_writable_page : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READABLE_WRITABLE_PAGE_BIT 10
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READABLE_WRITABLE_PAGE_FLAG 0x400
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READABLE_WRITABLE_PAGE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_READABLE_WRITABLE_PAGE(_) (((_) >> 10) & 0x01)
/**
* [Bit 11] This bit is 0 if paging translates the linear address to an executable page and 1 if it translates to an
* execute-disable page. Otherwise, this bit is undefined.
*
* @remarks If bit 7 is 1, bit 8 is 1, and the processor supports advanced VM-exit information for EPT violations. (If
* CR0.PG = 0, CR4.PAE = 0, or IA32_EFER.NXE = 0, every linear address is executable and thus this bit will be 0.)
*/
UINT64_t execute_disable_page : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_DISABLE_PAGE_BIT 11
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_DISABLE_PAGE_FLAG 0x800
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_DISABLE_PAGE_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_EXECUTE_DISABLE_PAGE(_) (((_) >> 11) & 0x01)
/**
* [Bit 12] NMI unblocking due to IRET.
*/
UINT64_t nmi_unblocking : 1;
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_NMI_UNBLOCKING_BIT 12
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_NMI_UNBLOCKING_FLAG 0x1000
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_NMI_UNBLOCKING_MASK 0x01
#define VMX_EXIT_QUALIFICATION_EPT_VIOLATION_NMI_UNBLOCKING(_) (((_) >> 12) & 0x01)
UINT64_t reserved1 : 51;
};
UINT64_t flags;
} vmx_exit_qualification_ept_violation;
/**
* @}
*/
/**
* @defgroup vmx_vmexit_instruction_information \
* Information for VM Exits Due to Instruction Execution
*
* Information for VM Exits Due to Instruction Execution.
*
* @see Vol3C[27.2.4(Information for VM Exits Due to Instruction Execution)] (reference)
* @{
*/
/**
* @brief VM-Exit Instruction-Information Field as Used for INS and OUTS
*/
typedef union
{
struct
{
UINT64_t reserved1 : 7;
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used.
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
UINT64_t reserved2 : 5;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used. Undefined for VM exits due to execution of INS.
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_INS_OUTS_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
UINT64_t reserved3 : 46;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_ins_outs;
/**
* @brief VM-Exit Instruction-Information Field as Used for INVEPT, INVPCID, and INVVPID
*/
typedef union
{
struct
{
/**
* @brief Scaling
*
* [Bits 1:0] 0: no scaling
* 1: scale by 2
* 2: scale by 4
* 3: scale by 8 (used only on processors that support Intel 64 architecture)
* Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t scaling : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SCALING_BIT 0
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SCALING_FLAG 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SCALING_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SCALING(_) (((_) >> 0) & 0x03)
UINT64_t reserved1 : 5;
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used.
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
UINT64_t reserved2 : 5;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used. Undefined for VM exits due to execution of INS.
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
/**
* [Bits 21:18] General-purpose register. Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t general_purpose_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_BIT 18
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_FLAG 0x3C0000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER(_) (((_) >> 18) & 0x0F)
/**
* [Bit 22] IndexReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t general_purpose_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_INVALID_BIT 22
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_INVALID_FLAG 0x400000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_GENERAL_PURPOSE_REGISTER_INVALID(_) (((_) >> 22) & 0x01)
/**
* [Bits 26:23] BaseReg (encoded as IndexReg above). Undefined for memory instructions with no base register (bit 27 is
* set).
*/
UINT64_t base_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_BIT 23
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_FLAG 0x7800000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER(_) (((_) >> 23) & 0x0F)
/**
* [Bit 27] BaseReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t base_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_INVALID_BIT 27
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_INVALID_FLAG 0x8000000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_BASE_REGISTER_INVALID(_) (((_) >> 27) & 0x01)
/**
* [Bits 31:28] Reg2 (same encoding as IndexReg above).
*/
UINT64_t register_2 : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_REGISTER_2_BIT 28
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_REGISTER_2_FLAG 0xF0000000
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_REGISTER_2_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_INVALIDATE_REGISTER_2(_) (((_) >> 28) & 0x0F)
UINT64_t reserved3 : 32;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_invalidate;
/**
* @brief VM-Exit Instruction-Information Field as Used for LIDT, LGDT, SIDT, or SGDT
*/
typedef union
{
struct
{
/**
* @brief Scaling
*
* [Bits 1:0] 0: no scaling
* 1: scale by 2
* 2: scale by 4
* 3: scale by 8 (used only on processors that support Intel 64 architecture)
* Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t scaling : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SCALING_BIT 0
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SCALING_FLAG 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SCALING_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SCALING(_) (((_) >> 0) & 0x03)
UINT64_t reserved1 : 5;
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used.
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
UINT64_t reserved2 : 1;
/**
* @brief Operand size
*
* [Bit 11] 0: 16-bit
* 1: 32-bit
* Undefined for VM exits from 64-bit mode.
*/
UINT64_t operand_size : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_OPERAND_SIZE_BIT 11
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_OPERAND_SIZE_FLAG 0x800
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_OPERAND_SIZE_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_OPERAND_SIZE(_) (((_) >> 11) & 0x01)
UINT64_t reserved3 : 3;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used.
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
/**
* [Bits 21:18] General-purpose register. Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t general_purpose_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_BIT 18
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_FLAG 0x3C0000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER(_) (((_) >> 18) & 0x0F)
/**
* [Bit 22] IndexReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t general_purpose_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_BIT 22
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_FLAG 0x400000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID(_) (((_) >> 22) & 0x01)
/**
* [Bits 26:23] BaseReg (encoded as IndexReg above). Undefined for memory instructions with no base register (bit 27 is
* set).
*/
UINT64_t base_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_BIT 23
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_FLAG 0x7800000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER(_) (((_) >> 23) & 0x0F)
/**
* [Bit 27] BaseReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t base_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_INVALID_BIT 27
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_INVALID_FLAG 0x8000000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_BASE_REGISTER_INVALID(_) (((_) >> 27) & 0x01)
/**
* @brief Instruction identity
*
* [Bits 29:28] 0: SGDT
* 1: SIDT
* 2: LGDT
* 3: LIDT
*/
UINT64_t instruction : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_INSTRUCTION_BIT 28
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_INSTRUCTION_FLAG 0x30000000
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_INSTRUCTION_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_GDTR_IDTR_ACCESS_INSTRUCTION(_) (((_) >> 28) & 0x03)
UINT64_t reserved4 : 34;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_gdtr_idtr_access;
/**
* @brief VM-Exit Instruction-Information Field as Used for LLDT, LTR, SLDT, and STR
*/
typedef union
{
struct
{
/**
* @brief Scaling
*
* [Bits 1:0] 0: no scaling
* 1: scale by 2
* 2: scale by 4
* 3: scale by 8 (used only on processors that support Intel 64 architecture)
* Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t scaling : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SCALING_BIT 0
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SCALING_FLAG 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SCALING_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SCALING(_) (((_) >> 0) & 0x03)
UINT64_t reserved1 : 1;
/**
* [Bits 6:3] Reg1. Undefined for memory instructions (bit 10 is clear).
*/
UINT64_t reg_1 : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_REG_1_BIT 3
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_REG_1_FLAG 0x78
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_REG_1_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_REG_1(_) (((_) >> 3) & 0x0F)
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used. Undefined for register instructions (bit 10 is set).
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
/**
* [Bit 10] Mem/Reg (0 = memory; 1 = register).
*/
UINT64_t memory_register : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_MEMORY_REGISTER_BIT 10
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_MEMORY_REGISTER_FLAG 0x400
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_MEMORY_REGISTER_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_MEMORY_REGISTER(_) (((_) >> 10) & 0x01)
UINT64_t reserved2 : 4;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used. Undefined for register instructions (bit 10 is set).
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
/**
* [Bits 21:18] General-purpose register. Undefined for register instructions (bit 10 is set) and for memory instructions
* with no index register (bit 10 is clear and bit 22 is set).
*/
UINT64_t general_purpose_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_BIT 18
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_FLAG 0x3C0000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER(_) (((_) >> 18) & 0x0F)
/**
* [Bit 22] IndexReg invalid (0 = valid; 1 = invalid). Undefined for register instructions (bit 10 is set).
*/
UINT64_t general_purpose_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_BIT 22
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_FLAG 0x400000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_GENERAL_PURPOSE_REGISTER_INVALID(_) (((_) >> 22) & 0x01)
/**
* [Bits 26:23] BaseReg (encoded as IndexReg above). Undefined for register instructions (bit 10 is set) and for memory
* instructions with no base register (bit 10 is clear and bit 27 is set).
*/
UINT64_t base_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_BIT 23
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_FLAG 0x7800000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER(_) (((_) >> 23) & 0x0F)
/**
* [Bit 27] BaseReg invalid (0 = valid; 1 = invalid). Undefined for register instructions (bit 10 is set).
*/
UINT64_t base_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_INVALID_BIT 27
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_INVALID_FLAG 0x8000000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_BASE_REGISTER_INVALID(_) (((_) >> 27) & 0x01)
/**
* @brief Instruction identity
*
* [Bits 29:28] 0: SLDT
* 1: STR
* 2: LLDT
* 3: LTR
*/
UINT64_t instruction : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_INSTRUCTION_BIT 28
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_INSTRUCTION_FLAG 0x30000000
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_INSTRUCTION_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_LDTR_TR_ACCESS_INSTRUCTION(_) (((_) >> 28) & 0x03)
UINT64_t reserved3 : 34;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_ldtr_tr_access;
/**
* @brief VM-Exit Instruction-Information Field as Used for RDRAND and RDSEED
*/
typedef union
{
struct
{
UINT64_t reserved1 : 3;
/**
* [Bits 6:3] Destination register.
*/
UINT64_t destination_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_DESTINATION_REGISTER_BIT 3
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_DESTINATION_REGISTER_FLAG 0x78
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_DESTINATION_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_DESTINATION_REGISTER(_) (((_) >> 3) & 0x0F)
UINT64_t reserved2 : 4;
/**
* @brief Operand size
*
* [Bits 12:11] 0: 16-bit
* 1: 32-bit
* 2: 64-bit
* The value 3 is not used.
*/
UINT64_t operand_size : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_OPERAND_SIZE_BIT 11
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_OPERAND_SIZE_FLAG 0x1800
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_OPERAND_SIZE_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_RDRAND_RDSEED_OPERAND_SIZE(_) (((_) >> 11) & 0x03)
UINT64_t reserved3 : 51;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_rdrand_rdseed;
/**
* @brief VM-Exit Instruction-Information Field as Used for VMCLEAR, VMPTRLD, VMPTRST, VMXON, XRSTORS, and XSAVES
*/
typedef union
{
struct
{
/**
* @brief Scaling
*
* [Bits 1:0] 0: no scaling
* 1: scale by 2
* 2: scale by 4
* 3: scale by 8 (used only on processors that support Intel 64 architecture)
* Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t scaling : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SCALING_BIT 0
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SCALING_FLAG 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SCALING_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SCALING(_) (((_) >> 0) & 0x03)
UINT64_t reserved1 : 5;
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used.
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
UINT64_t reserved2 : 5;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used.
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
/**
* [Bits 21:18] General-purpose register. Undefined for instructions with no index register (bit 22 is set).
*/
UINT64_t general_purpose_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_BIT 18
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_FLAG 0x3C0000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER(_) (((_) >> 18) & 0x0F)
/**
* [Bit 22] IndexReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t general_purpose_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_INVALID_BIT 22
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_INVALID_FLAG 0x400000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_GENERAL_PURPOSE_REGISTER_INVALID(_) (((_) >> 22) & 0x01)
/**
* [Bits 26:23] BaseReg (encoded as IndexReg above). Undefined for memory instructions with no base register (bit 27 is
* set).
*/
UINT64_t base_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_BIT 23
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_FLAG 0x7800000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER(_) (((_) >> 23) & 0x0F)
/**
* [Bit 27] BaseReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t base_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_INVALID_BIT 27
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_INVALID_FLAG 0x8000000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_VMX_AND_XSAVES_BASE_REGISTER_INVALID(_) (((_) >> 27) & 0x01)
UINT64_t reserved3 : 36;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_vmx_and_xsaves;
/**
* @brief VM-Exit Instruction-Information Field as Used for VMREAD and VMWRITE
*/
typedef union
{
struct
{
/**
* @brief Scaling
*
* [Bits 1:0] 0: no scaling
* 1: scale by 2
* 2: scale by 4
* 3: scale by 8 (used only on processors that support Intel 64 architecture)
* Undefined for register instructions (bit 10 is set) and for memory instructions with no index register (bit 10 is clear
* and bit 22 is set).
*/
UINT64_t scaling : 2;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SCALING_BIT 0
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SCALING_FLAG 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SCALING_MASK 0x03
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SCALING(_) (((_) >> 0) & 0x03)
UINT64_t reserved1 : 1;
/**
* [Bits 6:3] Reg1. Undefined for memory instructions (bit 10 is clear).
*/
UINT64_t register_1 : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_1_BIT 3
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_1_FLAG 0x78
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_1_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_1(_) (((_) >> 3) & 0x0F)
/**
* @brief Address size
*
* [Bits 9:7] 0: 16-bit
* 1: 32-bit
* 2: 64-bit (used only on processors that support Intel 64 architecture)
* Other values not used. Undefined for register instructions (bit 10 is set).
*/
UINT64_t address_size : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_ADDRESS_SIZE_BIT 7
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_ADDRESS_SIZE_FLAG 0x380
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_ADDRESS_SIZE_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_ADDRESS_SIZE(_) (((_) >> 7) & 0x07)
/**
* [Bit 10] Mem/Reg (0 = memory; 1 = register).
*/
UINT64_t memory_register : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_MEMORY_REGISTER_BIT 10
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_MEMORY_REGISTER_FLAG 0x400
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_MEMORY_REGISTER_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_MEMORY_REGISTER(_) (((_) >> 10) & 0x01)
UINT64_t reserved2 : 4;
/**
* @brief Segment register
*
* [Bits 17:15] 0: ES
* 1: CS
* 2: SS
* 3: DS
* 4: FS
* 5: GS
* Other values not used. Undefined for register instructions (bit 10 is set).
*/
UINT64_t segment_register : 3;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SEGMENT_REGISTER_BIT 15
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SEGMENT_REGISTER_FLAG 0x38000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SEGMENT_REGISTER_MASK 0x07
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_SEGMENT_REGISTER(_) (((_) >> 15) & 0x07)
/**
* [Bits 21:18] General-purpose register. Undefined for register instructions (bit 10 is set) and for memory instructions
* with no index register (bit 10 is clear and bit 22 is set).
*/
UINT64_t general_purpose_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_BIT 18
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_FLAG 0x3C0000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER(_) (((_) >> 18) & 0x0F)
/**
* [Bit 22] IndexReg invalid (0 = valid; 1 = invalid). Undefined for register instructions (bit 10 is set).
*/
UINT64_t general_purpose_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_INVALID_BIT 22
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_INVALID_FLAG 0x400000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_GENERAL_PURPOSE_REGISTER_INVALID(_) (((_) >> 22) & 0x01)
/**
* [Bits 26:23] BaseReg (encoded as Reg1 above). Undefined for register instructions (bit 10 is set) and for memory
* instructions with no base register (bit 10 is clear and bit 27 is set).
*/
UINT64_t base_register : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_BIT 23
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_FLAG 0x7800000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER(_) (((_) >> 23) & 0x0F)
/**
* [Bit 27] BaseReg invalid (0 = valid; 1 = invalid).
*/
UINT64_t base_register_invalid : 1;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_INVALID_BIT 27
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_INVALID_FLAG 0x8000000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_INVALID_MASK 0x01
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_BASE_REGISTER_INVALID(_) (((_) >> 27) & 0x01)
/**
* [Bits 31:28] Reg2 (same encoding as IndexReg above).
*/
UINT64_t register_2 : 4;
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_2_BIT 28
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_2_FLAG 0xF0000000
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_2_MASK 0x0F
#define VMX_VMEXIT_INSTRUCTION_INFO_VMREAD_VMWRITE_REGISTER_2(_) (((_) >> 28) & 0x0F)
UINT64_t reserved3 : 32;
};
UINT64_t flags;
} vmx_vmexit_instruction_info_vmread_vmwrite;
/**
* @}
*/
/**
* @brief - The low 16 bits correspond to bits 23:8 of the upper 32 bits of a 64-bit segment descriptor. While bits 19:16
* of code-segment and data-segment descriptors correspond to the upper 4 bits of the segment limit, the corresponding bits
* (bits 11:8) are reserved in this VMCS field.
* - Bit 16 indicates an unusable segment. Attempts to use such a segment fault except in 64-bit mode. In general, a
* segment register is unusable if it has been loaded with a null selector.
* - Bits 31:17 are reserved
*
* @note There are a few exceptions to this statement. For example, a segment with a non-null selector may be unusable
* following a task switch that fails after its commit point. In contrast, the TR register is usable after processor reset
* despite having a null selector
* @see SEGMENT_DESCRIPTOR_32
* @see SEGMENT_DESCRIPTOR_64
* @see XXX_ACCESS_RIGHTS fields of 32_BIT_GUEST_STATE_FIELDS
* @see Vol3C[24.4.2(Guest Non-Register State)] (reference)
*/
typedef union
{
struct
{
/**
* [Bits 3:0] Segment type.
*/
UINT32_t type : 4;
#define VMX_SEGMENT_ACCESS_RIGHTS_TYPE_BIT 0
#define VMX_SEGMENT_ACCESS_RIGHTS_TYPE_FLAG 0x0F
#define VMX_SEGMENT_ACCESS_RIGHTS_TYPE_MASK 0x0F
#define VMX_SEGMENT_ACCESS_RIGHTS_TYPE(_) (((_) >> 0) & 0x0F)
/**
* [Bit 4] S - Descriptor type (0 = system; 1 = code or data).
*/
UINT32_t descriptor_type : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_BIT 4
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_FLAG 0x10
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_TYPE(_) (((_) >> 4) & 0x01)
/**
* [Bits 6:5] DPL - Descriptor privilege level.
*/
UINT32_t descriptor_privilege_level : 2;
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_BIT 5
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_FLAG 0x60
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL_MASK 0x03
#define VMX_SEGMENT_ACCESS_RIGHTS_DESCRIPTOR_PRIVILEGE_LEVEL(_) (((_) >> 5) & 0x03)
/**
* [Bit 7] P - Segment present.
*/
UINT32_t present : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_PRESENT_BIT 7
#define VMX_SEGMENT_ACCESS_RIGHTS_PRESENT_FLAG 0x80
#define VMX_SEGMENT_ACCESS_RIGHTS_PRESENT_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_PRESENT(_) (((_) >> 7) & 0x01)
UINT32_t reserved1 : 4;
/**
* [Bit 12] AVL - Available for use by system software.
*/
UINT32_t available_bit : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_AVAILABLE_BIT_BIT 12
#define VMX_SEGMENT_ACCESS_RIGHTS_AVAILABLE_BIT_FLAG 0x1000
#define VMX_SEGMENT_ACCESS_RIGHTS_AVAILABLE_BIT_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_AVAILABLE_BIT(_) (((_) >> 12) & 0x01)
/**
* [Bit 13] Reserved (except for CS). L - 64-bit mode active (for CS only).
*/
UINT32_t long_mode : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_LONG_MODE_BIT 13
#define VMX_SEGMENT_ACCESS_RIGHTS_LONG_MODE_FLAG 0x2000
#define VMX_SEGMENT_ACCESS_RIGHTS_LONG_MODE_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_LONG_MODE(_) (((_) >> 13) & 0x01)
/**
* [Bit 14] D/B - Default operation size (0 = 16-bit segment; 1 = 32-bit segment).
*/
UINT32_t default_big : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_BIT 14
#define VMX_SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_FLAG 0x4000
#define VMX_SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_DEFAULT_BIG(_) (((_) >> 14) & 0x01)
/**
* [Bit 15] G - Granularity.
*/
UINT32_t granularity : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_GRANULARITY_BIT 15
#define VMX_SEGMENT_ACCESS_RIGHTS_GRANULARITY_FLAG 0x8000
#define VMX_SEGMENT_ACCESS_RIGHTS_GRANULARITY_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_GRANULARITY(_) (((_) >> 15) & 0x01)
/**
* [Bit 16] Segment unusable (0 = usable; 1 = unusable).
*/
UINT32_t unusable : 1;
#define VMX_SEGMENT_ACCESS_RIGHTS_UNUSABLE_BIT 16
#define VMX_SEGMENT_ACCESS_RIGHTS_UNUSABLE_FLAG 0x10000
#define VMX_SEGMENT_ACCESS_RIGHTS_UNUSABLE_MASK 0x01
#define VMX_SEGMENT_ACCESS_RIGHTS_UNUSABLE(_) (((_) >> 16) & 0x01)
UINT32_t reserved2 : 15;
};
UINT32_t flags;
} vmx_segment_access_rights;
/**
* @brief The IA-32 architecture includes features that permit certain events to be blocked for a period of time. This
* field contains information about such blocking
*
* @see INTERRUPTIBILITY_STATE of 32_BIT_GUEST_STATE_FIELDS
* @see Vol3C[24.4.2(Guest Non-Register State)] (reference)
*/
typedef union
{
struct
{
/**
* [Bit 0] Execution of STI with RFLAGS.IF = 0 blocks maskable interrupts on the instruction boundary following its
* execution.1 Setting this bit indicates that this blocking is in effect.
*
* @see Vol2B[4(STI-Set Interrupt Flag)]
*/
UINT32_t blocking_by_sti : 1;
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_STI_BIT 0
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_STI_FLAG 0x01
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_STI_MASK 0x01
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_STI(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Execution of a MOV to SS or a POP to SS blocks or suppresses certain debug exceptions as well as interrupts
* (maskable and nonmaskable) on the instruction boundary following its execution. Setting this bit indicates that this
* blocking is in effect. This document uses the term "blocking by MOV SS," but it applies equally to POP SS.
*
* @see Vol3A[6.8.3(Masking Exceptions and Interrupts When Switching Stacks)]
*/
UINT32_t blocking_by_mov_ss : 1;
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_MOV_SS_BIT 1
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_MOV_SS_FLAG 0x02
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_MOV_SS_MASK 0x01
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_MOV_SS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] System-management interrupts (SMIs) are disabled while the processor is in system-management mode (SMM). Setting
* this bit indicates that blocking of SMIs is in effect.
*
* @see Vol3C[34.2(System Management Interrupt (SMI))]
*/
UINT32_t blocking_by_smi : 1;
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_SMI_BIT 2
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_SMI_FLAG 0x04
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_SMI_MASK 0x01
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_SMI(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] Delivery of a non-maskable interrupt (NMI) or a system-management interrupt (SMI) blocks subsequent NMIs until
* the next execution of IRET. Setting this bit indicates that blocking of NMIs is in effect. Clearing this bit does not
* imply that NMIs are not (temporarily) blocked for other reasons. If the "virtual NMIs" VM-execution control is 1, this
* bit does not control the blocking of NMIs. Instead, it refers to "virtual-NMI blocking" (the fact that guest software is
* not ready for an NMI).
*
* @see Vol3C[6.7.1(Handling Multiple NMIs)]
* @see Vol3C[25.3(CHANGES TO INSTRUCTION BEHAVIOR IN VMX NON-ROOT OPERATION)]
* @see Vol3C[24.6.1(Pin-Based VM-Execution Controls)]
*/
UINT32_t blocking_by_nmi : 1;
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_NMI_BIT 3
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_NMI_FLAG 0x08
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_NMI_MASK 0x01
#define VMX_INTERRUPTIBILITY_STATE_BLOCKING_BY_NMI(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] A VM exit saves this bit as 1 to indicate that the VM exit was incident to enclave mode.
*/
UINT32_t enclave_interruption : 1;
#define VMX_INTERRUPTIBILITY_STATE_ENCLAVE_INTERRUPTION_BIT 4
#define VMX_INTERRUPTIBILITY_STATE_ENCLAVE_INTERRUPTION_FLAG 0x10
#define VMX_INTERRUPTIBILITY_STATE_ENCLAVE_INTERRUPTION_MASK 0x01
#define VMX_INTERRUPTIBILITY_STATE_ENCLAVE_INTERRUPTION(_) (((_) >> 4) & 0x01)
UINT32_t reserved1 : 27;
};
UINT32_t flags;
} vmx_interruptibility_state;
typedef enum
{
/**
* The logical processor is executing instructions normally.
*/
vmx_active = 0x00000000,
/**
* The logical processor is inactive because it executed the HLT instruction.
*/
vmx_hlt = 0x00000001,
/**
* The logical processor is inactive because it incurred a triple fault1 or some other serious error.
*/
vmx_shutdown = 0x00000002,
/**
* The logical processor is inactive because it is waiting for a startup-IPI (SIPI).
*/
vmx_wait_for_sipi = 0x00000003,
} vmx_guest_activity_state;
/**
* @}
*/
/**
* @brief Format of Exit Reason
*
* Exit reason (32 bits). This field encodes the reason for the VM exit and has the structure.
*
* @see Vol3C[24.9.1(Basic VM-Exit Information)] (reference)
*/
typedef union
{
struct
{
/**
* [Bits 15:0] Provides basic information about the cause of the VM exit (if bit 31 is clear) or of the VM-entry failure
* (if bit 31 is set).
*/
UINT32_t basic_exit_reason : 16;
#define VMX_VMEXIT_REASON_BASIC_EXIT_REASON_BIT 0
#define VMX_VMEXIT_REASON_BASIC_EXIT_REASON_FLAG 0xFFFF
#define VMX_VMEXIT_REASON_BASIC_EXIT_REASON_MASK 0xFFFF
#define VMX_VMEXIT_REASON_BASIC_EXIT_REASON(_) (((_) >> 0) & 0xFFFF)
/**
* [Bit 16] Always cleared to 0.
*/
UINT32_t always0 : 1;
#define VMX_VMEXIT_REASON_ALWAYS0_BIT 16
#define VMX_VMEXIT_REASON_ALWAYS0_FLAG 0x10000
#define VMX_VMEXIT_REASON_ALWAYS0_MASK 0x01
#define VMX_VMEXIT_REASON_ALWAYS0(_) (((_) >> 16) & 0x01)
UINT32_t reserved1 : 10;
#define VMX_VMEXIT_REASON_RESERVED1_BIT 17
#define VMX_VMEXIT_REASON_RESERVED1_FLAG 0x7FE0000
#define VMX_VMEXIT_REASON_RESERVED1_MASK 0x3FF
#define VMX_VMEXIT_REASON_RESERVED1(_) (((_) >> 17) & 0x3FF)
/**
* [Bit 27] A VM exit saves this bit as 1 to indicate that the VM exit was incident to enclave mode.
*/
UINT32_t enclave_mode : 1;
#define VMX_VMEXIT_REASON_ENCLAVE_MODE_BIT 27
#define VMX_VMEXIT_REASON_ENCLAVE_MODE_FLAG 0x8000000
#define VMX_VMEXIT_REASON_ENCLAVE_MODE_MASK 0x01
#define VMX_VMEXIT_REASON_ENCLAVE_MODE(_) (((_) >> 27) & 0x01)
/**
* [Bit 28] Pending MTF VM exit.
*/
UINT32_t pending_mtf_vm_exit : 1;
#define VMX_VMEXIT_REASON_PENDING_MTF_VM_EXIT_BIT 28
#define VMX_VMEXIT_REASON_PENDING_MTF_VM_EXIT_FLAG 0x10000000
#define VMX_VMEXIT_REASON_PENDING_MTF_VM_EXIT_MASK 0x01
#define VMX_VMEXIT_REASON_PENDING_MTF_VM_EXIT(_) (((_) >> 28) & 0x01)
/**
* [Bit 29] VM exit from VMX root operation.
*/
UINT32_t vm_exit_from_vmx_roor : 1;
#define VMX_VMEXIT_REASON_VM_EXIT_FROM_VMX_ROOR_BIT 29
#define VMX_VMEXIT_REASON_VM_EXIT_FROM_VMX_ROOR_FLAG 0x20000000
#define VMX_VMEXIT_REASON_VM_EXIT_FROM_VMX_ROOR_MASK 0x01
#define VMX_VMEXIT_REASON_VM_EXIT_FROM_VMX_ROOR(_) (((_) >> 29) & 0x01)
UINT32_t reserved2 : 1;
#define VMX_VMEXIT_REASON_RESERVED2_BIT 30
#define VMX_VMEXIT_REASON_RESERVED2_FLAG 0x40000000
#define VMX_VMEXIT_REASON_RESERVED2_MASK 0x01
#define VMX_VMEXIT_REASON_RESERVED2(_) (((_) >> 30) & 0x01)
/**
* [Bit 31] VM-entry failure:
* - 0 = true VM exit
* - 1 = VM-entry failure
*/
UINT32_t vm_entry_failure : 1;
#define VMX_VMEXIT_REASON_VM_ENTRY_FAILURE_BIT 31
#define VMX_VMEXIT_REASON_VM_ENTRY_FAILURE_FLAG 0x80000000
#define VMX_VMEXIT_REASON_VM_ENTRY_FAILURE_MASK 0x01
#define VMX_VMEXIT_REASON_VM_ENTRY_FAILURE(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} vmx_vmexit_reason;
typedef struct
{
#define IO_BITMAP_A_MIN 0x00000000
#define IO_BITMAP_A_MAX 0x00007FFF
#define IO_BITMAP_B_MIN 0x00008000
#define IO_BITMAP_B_MAX 0x0000FFFF
UINT8_t io_a[4096];
UINT8_t io_b[4096];
} vmx_io_bitmap;
typedef struct
{
#define MSR_ID_LOW_MIN 0x00000000
#define MSR_ID_LOW_MAX 0x00001FFF
#define MSR_ID_HIGH_MIN 0xC0000000
#define MSR_ID_HIGH_MAX 0xC0001FFF
UINT8_t rdmsr_low[1024];
UINT8_t rdmsr_high[1024];
UINT8_t wrmsr_low[1024];
UINT8_t wrmsr_high[1024];
} vmx_msr_bitmap;
/**
* @defgroup ept \
* The extended page-table mechanism
*
* The extended page-table mechanism (EPT) is a feature that can be used to support the virtualization of physical memory.
* When EPT is in use, certain addresses that would normally be treated as physical addresses (and used to access memory)
* are instead treated as guest-physical addresses. Guest-physical addresses are translated by traversing a set of EPT
* paging structures to produce physical addresses that are used to access memory.
*
* @see Vol3C[28.2(THE EXTENDED PAGE TABLE MECHANISM (EPT))] (reference)
* @{
*/
/**
* @brief Extended-Page-Table Pointer (EPTP)
*
* The extended-page-table pointer (EPTP) contains the address of the base of EPT PML4 table, as well as other EPT
* configuration information.
*
* @see Vol3C[28.2.2(EPT Translation Mechanism]
* @see Vol3C[24.6.11(Extended-Page-Table Pointer (EPTP)] (reference)
*/
typedef union
{
struct
{
/**
* [Bits 2:0] EPT paging-structure memory type:
* - 0 = Uncacheable (UC)
* - 6 = Write-back (WB)
* Other values are reserved.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t memory_type : 3;
#define EPT_POINTER_MEMORY_TYPE_BIT 0
#define EPT_POINTER_MEMORY_TYPE_FLAG 0x07
#define EPT_POINTER_MEMORY_TYPE_MASK 0x07
#define EPT_POINTER_MEMORY_TYPE(_) (((_) >> 0) & 0x07)
/**
* [Bits 5:3] This value is 1 less than the EPT page-walk length.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t page_walk_length : 3;
#define EPT_POINTER_PAGE_WALK_LENGTH_BIT 3
#define EPT_POINTER_PAGE_WALK_LENGTH_FLAG 0x38
#define EPT_POINTER_PAGE_WALK_LENGTH_MASK 0x07
#define EPT_POINTER_PAGE_WALK_LENGTH(_) (((_) >> 3) & 0x07)
#define EPT_PAGE_WALK_LENGTH_4 0x00000003
/**
* [Bit 6] Setting this control to 1 enables accessed and dirty flags for EPT.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t enable_access_and_dirty_flags : 1;
#define EPT_POINTER_ENABLE_ACCESS_AND_DIRTY_FLAGS_BIT 6
#define EPT_POINTER_ENABLE_ACCESS_AND_DIRTY_FLAGS_FLAG 0x40
#define EPT_POINTER_ENABLE_ACCESS_AND_DIRTY_FLAGS_MASK 0x01
#define EPT_POINTER_ENABLE_ACCESS_AND_DIRTY_FLAGS(_) (((_) >> 6) & 0x01)
UINT64_t reserved1 : 5;
/**
* [Bits 47:12] Bits N-1:12 of the physical address of the 4-KByte aligned EPT PML4 table.
*/
UINT64_t page_frame_number : 36;
#define EPT_POINTER_PAGE_FRAME_NUMBER_BIT 12
#define EPT_POINTER_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPT_POINTER_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPT_POINTER_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 16;
};
UINT64_t flags;
} ept_pointer;
/**
* @brief Format of an EPT PML4 Entry (PML4E) that References an EPT Page-Directory-Pointer Table
*
* A 4-KByte naturally aligned EPT PML4 table is located at the physical address specified in bits 51:12 of the
* extended-page-table pointer (EPTP), a VM-execution control field. An EPT PML4 table comprises 512 64-bit entries (EPT
* PML4Es). An EPT PML4E is selected using the physical address defined as follows:
* - Bits 63:52 are all 0.
* - Bits 51:12 are from the EPTP.
* - Bits 11:3 are bits 47:39 of the guest-physical address.
* - Bits 2:0 are all 0.
* Because an EPT PML4E is identified using bits 47:39 of the guest-physical address, it controls access to a 512- GByte
* region of the guest-physical-address space.
*
* @see Vol3C[24.6.11(Extended-Page-Table Pointer (EPTP)]
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 512-GByte region controlled by this entry.
*/
UINT64_t read_access : 1;
#define EPT_PML4_READ_ACCESS_BIT 0
#define EPT_PML4_READ_ACCESS_FLAG 0x01
#define EPT_PML4_READ_ACCESS_MASK 0x01
#define EPT_PML4_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 512-GByte region controlled by this entry.
*/
UINT64_t write_access : 1;
#define EPT_PML4_WRITE_ACCESS_BIT 1
#define EPT_PML4_WRITE_ACCESS_FLAG 0x02
#define EPT_PML4_WRITE_ACCESS_MASK 0x01
#define EPT_PML4_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 512-GByte region controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 512-GByte region controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPT_PML4_EXECUTE_ACCESS_BIT 2
#define EPT_PML4_EXECUTE_ACCESS_FLAG 0x04
#define EPT_PML4_EXECUTE_ACCESS_MASK 0x01
#define EPT_PML4_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 5;
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 512-GByte region
* controlled by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPT_PML4_ACCESSED_BIT 8
#define EPT_PML4_ACCESSED_FLAG 0x100
#define EPT_PML4_ACCESSED_MASK 0x01
#define EPT_PML4_ACCESSED(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 512-GByte region
* controlled by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPT_PML4_USER_MODE_EXECUTE_BIT 10
#define EPT_PML4_USER_MODE_EXECUTE_FLAG 0x400
#define EPT_PML4_USER_MODE_EXECUTE_MASK 0x01
#define EPT_PML4_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved3 : 1;
/**
* [Bits 47:12] Physical address of 4-KByte aligned EPT page-directory-pointer table referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define EPT_PML4_PAGE_FRAME_NUMBER_BIT 12
#define EPT_PML4_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPT_PML4_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPT_PML4_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved4 : 16;
};
UINT64_t flags;
} ept_pml4;
/**
* @brief Format of an EPT Page-Directory-Pointer-Table Entry (PDPTE) that Maps a 1-GByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 1-GByte page referenced by this entry.
*/
UINT64_t read_access : 1;
#define EPDPTE_1GB_READ_ACCESS_BIT 0
#define EPDPTE_1GB_READ_ACCESS_FLAG 0x01
#define EPDPTE_1GB_READ_ACCESS_MASK 0x01
#define EPDPTE_1GB_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 1-GByte page referenced by this entry.
*/
UINT64_t write_access : 1;
#define EPDPTE_1GB_WRITE_ACCESS_BIT 1
#define EPDPTE_1GB_WRITE_ACCESS_FLAG 0x02
#define EPDPTE_1GB_WRITE_ACCESS_MASK 0x01
#define EPDPTE_1GB_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 1-GByte page controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 1-GByte page controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPDPTE_1GB_EXECUTE_ACCESS_BIT 2
#define EPDPTE_1GB_EXECUTE_ACCESS_FLAG 0x04
#define EPDPTE_1GB_EXECUTE_ACCESS_MASK 0x01
#define EPDPTE_1GB_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
/**
* [Bits 5:3] EPT memory type for this 1-GByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t memory_type : 3;
#define EPDPTE_1GB_MEMORY_TYPE_BIT 3
#define EPDPTE_1GB_MEMORY_TYPE_FLAG 0x38
#define EPDPTE_1GB_MEMORY_TYPE_MASK 0x07
#define EPDPTE_1GB_MEMORY_TYPE(_) (((_) >> 3) & 0x07)
/**
* [Bit 6] Ignore PAT memory type for this 1-GByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t ignore_pat : 1;
#define EPDPTE_1GB_IGNORE_PAT_BIT 6
#define EPDPTE_1GB_IGNORE_PAT_FLAG 0x40
#define EPDPTE_1GB_IGNORE_PAT_MASK 0x01
#define EPDPTE_1GB_IGNORE_PAT(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Must be 1 (otherwise, this entry references an EPT page directory).
*/
UINT64_t large_page : 1;
#define EPDPTE_1GB_LARGE_PAGE_BIT 7
#define EPDPTE_1GB_LARGE_PAGE_FLAG 0x80
#define EPDPTE_1GB_LARGE_PAGE_MASK 0x01
#define EPDPTE_1GB_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 1-GByte page
* referenced by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPDPTE_1GB_ACCESSED_BIT 8
#define EPDPTE_1GB_ACCESSED_FLAG 0x100
#define EPDPTE_1GB_ACCESSED_MASK 0x01
#define EPDPTE_1GB_ACCESSED(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] If bit 6 of EPTP is 1, dirty flag for EPT; indicates whether software has written to the 1-GByte page referenced
* by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t dirty : 1;
#define EPDPTE_1GB_DIRTY_BIT 9
#define EPDPTE_1GB_DIRTY_FLAG 0x200
#define EPDPTE_1GB_DIRTY_MASK 0x01
#define EPDPTE_1GB_DIRTY(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 1-GByte page controlled
* by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPDPTE_1GB_USER_MODE_EXECUTE_BIT 10
#define EPDPTE_1GB_USER_MODE_EXECUTE_FLAG 0x400
#define EPDPTE_1GB_USER_MODE_EXECUTE_MASK 0x01
#define EPDPTE_1GB_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved1 : 19;
/**
* [Bits 47:30] Physical address of 4-KByte aligned EPT page-directory-pointer table referenced by this entry.
*/
UINT64_t page_frame_number : 18;
#define EPDPTE_1GB_PAGE_FRAME_NUMBER_BIT 30
#define EPDPTE_1GB_PAGE_FRAME_NUMBER_FLAG 0xFFFFC0000000
#define EPDPTE_1GB_PAGE_FRAME_NUMBER_MASK 0x3FFFF
#define EPDPTE_1GB_PAGE_FRAME_NUMBER(_) (((_) >> 30) & 0x3FFFF)
UINT64_t reserved2 : 15;
/**
* [Bit 63] Suppress \#VE. If the "EPT-violation \#VE" VM-execution control is 1, EPT violations caused by accesses to this
* page are convertible to virtualization exceptions only if this bit is 0. If "EPT-violation \#VE" VMexecution control is
* 0, this bit is ignored.
*
* @see Vol3C[25.5.6.1(Convertible EPT Violations)]
*/
UINT64_t suppress_ve : 1;
#define EPDPTE_1GB_SUPPRESS_VE_BIT 63
#define EPDPTE_1GB_SUPPRESS_VE_FLAG 0x8000000000000000
#define EPDPTE_1GB_SUPPRESS_VE_MASK 0x01
#define EPDPTE_1GB_SUPPRESS_VE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} epdpte_1gb;
/**
* @brief Format of an EPT Page-Directory-Pointer-Table Entry (PDPTE) that References an EPT Page Directory
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 1-GByte region controlled by this entry.
*/
UINT64_t read_access : 1;
#define EPDPTE_READ_ACCESS_BIT 0
#define EPDPTE_READ_ACCESS_FLAG 0x01
#define EPDPTE_READ_ACCESS_MASK 0x01
#define EPDPTE_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 1-GByte region controlled by this entry.
*/
UINT64_t write_access : 1;
#define EPDPTE_WRITE_ACCESS_BIT 1
#define EPDPTE_WRITE_ACCESS_FLAG 0x02
#define EPDPTE_WRITE_ACCESS_MASK 0x01
#define EPDPTE_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 1-GByte region controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 1-GByte region controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPDPTE_EXECUTE_ACCESS_BIT 2
#define EPDPTE_EXECUTE_ACCESS_FLAG 0x04
#define EPDPTE_EXECUTE_ACCESS_MASK 0x01
#define EPDPTE_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 5;
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 1-GByte region
* controlled by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPDPTE_ACCESSED_BIT 8
#define EPDPTE_ACCESSED_FLAG 0x100
#define EPDPTE_ACCESSED_MASK 0x01
#define EPDPTE_ACCESSED(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 1-GByte region controlled
* by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPDPTE_USER_MODE_EXECUTE_BIT 10
#define EPDPTE_USER_MODE_EXECUTE_FLAG 0x400
#define EPDPTE_USER_MODE_EXECUTE_MASK 0x01
#define EPDPTE_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved3 : 1;
/**
* [Bits 47:12] Physical address of 4-KByte aligned EPT page-directory-pointer table referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define EPDPTE_PAGE_FRAME_NUMBER_BIT 12
#define EPDPTE_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPDPTE_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPDPTE_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved4 : 16;
};
UINT64_t flags;
} epdpte;
/**
* @brief Format of an EPT Page-Directory Entry (PDE) that Maps a 2-MByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 2-MByte page referenced by this entry.
*/
UINT64_t read_access : 1;
#define EPDE_2MB_READ_ACCESS_BIT 0
#define EPDE_2MB_READ_ACCESS_FLAG 0x01
#define EPDE_2MB_READ_ACCESS_MASK 0x01
#define EPDE_2MB_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 2-MByte page referenced by this entry.
*/
UINT64_t write_access : 1;
#define EPDE_2MB_WRITE_ACCESS_BIT 1
#define EPDE_2MB_WRITE_ACCESS_FLAG 0x02
#define EPDE_2MB_WRITE_ACCESS_MASK 0x01
#define EPDE_2MB_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 2-MByte page controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 2-MByte page controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPDE_2MB_EXECUTE_ACCESS_BIT 2
#define EPDE_2MB_EXECUTE_ACCESS_FLAG 0x04
#define EPDE_2MB_EXECUTE_ACCESS_MASK 0x01
#define EPDE_2MB_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
/**
* [Bits 5:3] EPT memory type for this 2-MByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t memory_type : 3;
#define EPDE_2MB_MEMORY_TYPE_BIT 3
#define EPDE_2MB_MEMORY_TYPE_FLAG 0x38
#define EPDE_2MB_MEMORY_TYPE_MASK 0x07
#define EPDE_2MB_MEMORY_TYPE(_) (((_) >> 3) & 0x07)
/**
* [Bit 6] Ignore PAT memory type for this 2-MByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t ignore_pat : 1;
#define EPDE_2MB_IGNORE_PAT_BIT 6
#define EPDE_2MB_IGNORE_PAT_FLAG 0x40
#define EPDE_2MB_IGNORE_PAT_MASK 0x01
#define EPDE_2MB_IGNORE_PAT(_) (((_) >> 6) & 0x01)
/**
* [Bit 7] Must be 1 (otherwise, this entry references an EPT page table).
*/
UINT64_t large_page : 1;
#define EPDE_2MB_LARGE_PAGE_BIT 7
#define EPDE_2MB_LARGE_PAGE_FLAG 0x80
#define EPDE_2MB_LARGE_PAGE_MASK 0x01
#define EPDE_2MB_LARGE_PAGE(_) (((_) >> 7) & 0x01)
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 2-MByte page
* referenced by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPDE_2MB_ACCESSED_BIT 8
#define EPDE_2MB_ACCESSED_FLAG 0x100
#define EPDE_2MB_ACCESSED_MASK 0x01
#define EPDE_2MB_ACCESSED(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] If bit 6 of EPTP is 1, dirty flag for EPT; indicates whether software has written to the 2-MByte page referenced
* by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t dirty : 1;
#define EPDE_2MB_DIRTY_BIT 9
#define EPDE_2MB_DIRTY_FLAG 0x200
#define EPDE_2MB_DIRTY_MASK 0x01
#define EPDE_2MB_DIRTY(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 2-MByte page controlled
* by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPDE_2MB_USER_MODE_EXECUTE_BIT 10
#define EPDE_2MB_USER_MODE_EXECUTE_FLAG 0x400
#define EPDE_2MB_USER_MODE_EXECUTE_MASK 0x01
#define EPDE_2MB_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved1 : 10;
/**
* [Bits 47:21] Physical address of 4-KByte aligned EPT page-directory-pointer table referenced by this entry.
*/
UINT64_t page_frame_number : 27;
#define EPDE_2MB_PAGE_FRAME_NUMBER_BIT 21
#define EPDE_2MB_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFE00000
#define EPDE_2MB_PAGE_FRAME_NUMBER_MASK 0x7FFFFFF
#define EPDE_2MB_PAGE_FRAME_NUMBER(_) (((_) >> 21) & 0x7FFFFFF)
UINT64_t reserved2 : 15;
/**
* [Bit 63] Suppress \#VE. If the "EPT-violation \#VE" VM-execution control is 1, EPT violations caused by accesses to this
* page are convertible to virtualization exceptions only if this bit is 0. If "EPT-violation \#VE" VMexecution control is
* 0, this bit is ignored.
*
* @see Vol3C[25.5.6.1(Convertible EPT Violations)]
*/
UINT64_t suppress_ve : 1;
#define EPDE_2MB_SUPPRESS_VE_BIT 63
#define EPDE_2MB_SUPPRESS_VE_FLAG 0x8000000000000000
#define EPDE_2MB_SUPPRESS_VE_MASK 0x01
#define EPDE_2MB_SUPPRESS_VE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} epde_2mb;
/**
* @brief Format of an EPT Page-Directory Entry (PDE) that References an EPT Page Table
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 2-MByte region controlled by this entry.
*/
UINT64_t read_access : 1;
#define EPDE_READ_ACCESS_BIT 0
#define EPDE_READ_ACCESS_FLAG 0x01
#define EPDE_READ_ACCESS_MASK 0x01
#define EPDE_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 2-MByte region controlled by this entry.
*/
UINT64_t write_access : 1;
#define EPDE_WRITE_ACCESS_BIT 1
#define EPDE_WRITE_ACCESS_FLAG 0x02
#define EPDE_WRITE_ACCESS_MASK 0x01
#define EPDE_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 2-MByte region controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 2-MByte region controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPDE_EXECUTE_ACCESS_BIT 2
#define EPDE_EXECUTE_ACCESS_FLAG 0x04
#define EPDE_EXECUTE_ACCESS_MASK 0x01
#define EPDE_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 5;
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 2-MByte region
* controlled by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPDE_ACCESSED_BIT 8
#define EPDE_ACCESSED_FLAG 0x100
#define EPDE_ACCESSED_MASK 0x01
#define EPDE_ACCESSED(_) (((_) >> 8) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 2-MByte region controlled
* by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPDE_USER_MODE_EXECUTE_BIT 10
#define EPDE_USER_MODE_EXECUTE_FLAG 0x400
#define EPDE_USER_MODE_EXECUTE_MASK 0x01
#define EPDE_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved3 : 1;
/**
* [Bits 47:12] Physical address of 4-KByte aligned EPT page table referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define EPDE_PAGE_FRAME_NUMBER_BIT 12
#define EPDE_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPDE_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPDE_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved4 : 16;
};
UINT64_t flags;
} epde;
/**
* @brief Format of an EPT Page-Table Entry that Maps a 4-KByte Page
*/
typedef union
{
struct
{
/**
* [Bit 0] Read access; indicates whether reads are allowed from the 4-KByte page referenced by this entry.
*/
UINT64_t read_access : 1;
#define EPTE_READ_ACCESS_BIT 0
#define EPTE_READ_ACCESS_FLAG 0x01
#define EPTE_READ_ACCESS_MASK 0x01
#define EPTE_READ_ACCESS(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Write access; indicates whether writes are allowed from the 4-KByte page referenced by this entry.
*/
UINT64_t write_access : 1;
#define EPTE_WRITE_ACCESS_BIT 1
#define EPTE_WRITE_ACCESS_FLAG 0x02
#define EPTE_WRITE_ACCESS_MASK 0x01
#define EPTE_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If the "mode-based execute control for EPT" VM-execution control is 0, execute access; indicates whether
* instruction fetches are allowed from the 4-KByte page controlled by this entry.
* If that control is 1, execute access for supervisor-mode linear addresses; indicates whether instruction fetches are
* allowed from supervisor-mode linear addresses in the 4-KByte page controlled by this entry.
*/
UINT64_t execute_access : 1;
#define EPTE_EXECUTE_ACCESS_BIT 2
#define EPTE_EXECUTE_ACCESS_FLAG 0x04
#define EPTE_EXECUTE_ACCESS_MASK 0x01
#define EPTE_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
/**
* [Bits 5:3] EPT memory type for this 4-KByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t memory_type : 3;
#define EPTE_MEMORY_TYPE_BIT 3
#define EPTE_MEMORY_TYPE_FLAG 0x38
#define EPTE_MEMORY_TYPE_MASK 0x07
#define EPTE_MEMORY_TYPE(_) (((_) >> 3) & 0x07)
/**
* [Bit 6] Ignore PAT memory type for this 4-KByte page.
*
* @see Vol3C[28.2.6(EPT and memory Typing)]
*/
UINT64_t ignore_pat : 1;
#define EPTE_IGNORE_PAT_BIT 6
#define EPTE_IGNORE_PAT_FLAG 0x40
#define EPTE_IGNORE_PAT_MASK 0x01
#define EPTE_IGNORE_PAT(_) (((_) >> 6) & 0x01)
UINT64_t reserved1 : 1;
/**
* [Bit 8] If bit 6 of EPTP is 1, accessed flag for EPT; indicates whether software has accessed the 4-KByte page
* referenced by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t accessed : 1;
#define EPTE_ACCESSED_BIT 8
#define EPTE_ACCESSED_FLAG 0x100
#define EPTE_ACCESSED_MASK 0x01
#define EPTE_ACCESSED(_) (((_) >> 8) & 0x01)
/**
* [Bit 9] If bit 6 of EPTP is 1, dirty flag for EPT; indicates whether software has written to the 4-KByte page referenced
* by this entry. Ignored if bit 6 of EPTP is 0.
*
* @see Vol3C[28.2.4(Accessed and Dirty Flags for EPT)]
*/
UINT64_t dirty : 1;
#define EPTE_DIRTY_BIT 9
#define EPTE_DIRTY_FLAG 0x200
#define EPTE_DIRTY_MASK 0x01
#define EPTE_DIRTY(_) (((_) >> 9) & 0x01)
/**
* [Bit 10] Execute access for user-mode linear addresses. If the "mode-based execute control for EPT" VM-execution control
* is 1, indicates whether instruction fetches are allowed from user-mode linear addresses in the 4-KByte page controlled
* by this entry. If that control is 0, this bit is ignored.
*/
UINT64_t user_mode_execute : 1;
#define EPTE_USER_MODE_EXECUTE_BIT 10
#define EPTE_USER_MODE_EXECUTE_FLAG 0x400
#define EPTE_USER_MODE_EXECUTE_MASK 0x01
#define EPTE_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved2 : 1;
/**
* [Bits 47:12] Physical address of the 4-KByte page referenced by this entry.
*/
UINT64_t page_frame_number : 36;
#define EPTE_PAGE_FRAME_NUMBER_BIT 12
#define EPTE_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPTE_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPTE_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved3 : 15;
/**
* [Bit 63] Suppress \#VE. If the "EPT-violation \#VE" VM-execution control is 1, EPT violations caused by accesses to this
* page are convertible to virtualization exceptions only if this bit is 0. If "EPT-violation \#VE" VMexecution control is
* 0, this bit is ignored.
*
* @see Vol3C[25.5.6.1(Convertible EPT Violations)]
*/
UINT64_t suppress_ve : 1;
#define EPTE_SUPPRESS_VE_BIT 63
#define EPTE_SUPPRESS_VE_FLAG 0x8000000000000000
#define EPTE_SUPPRESS_VE_MASK 0x01
#define EPTE_SUPPRESS_VE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} epte;
/**
* @brief Format of a common EPT Entry
*/
typedef union
{
struct
{
UINT64_t read_access : 1;
#define EPT_ENTRY_READ_ACCESS_BIT 0
#define EPT_ENTRY_READ_ACCESS_FLAG 0x01
#define EPT_ENTRY_READ_ACCESS_MASK 0x01
#define EPT_ENTRY_READ_ACCESS(_) (((_) >> 0) & 0x01)
UINT64_t write_access : 1;
#define EPT_ENTRY_WRITE_ACCESS_BIT 1
#define EPT_ENTRY_WRITE_ACCESS_FLAG 0x02
#define EPT_ENTRY_WRITE_ACCESS_MASK 0x01
#define EPT_ENTRY_WRITE_ACCESS(_) (((_) >> 1) & 0x01)
UINT64_t execute_access : 1;
#define EPT_ENTRY_EXECUTE_ACCESS_BIT 2
#define EPT_ENTRY_EXECUTE_ACCESS_FLAG 0x04
#define EPT_ENTRY_EXECUTE_ACCESS_MASK 0x01
#define EPT_ENTRY_EXECUTE_ACCESS(_) (((_) >> 2) & 0x01)
UINT64_t memory_type : 3;
#define EPT_ENTRY_MEMORY_TYPE_BIT 3
#define EPT_ENTRY_MEMORY_TYPE_FLAG 0x38
#define EPT_ENTRY_MEMORY_TYPE_MASK 0x07
#define EPT_ENTRY_MEMORY_TYPE(_) (((_) >> 3) & 0x07)
UINT64_t ignore_pat : 1;
#define EPT_ENTRY_IGNORE_PAT_BIT 6
#define EPT_ENTRY_IGNORE_PAT_FLAG 0x40
#define EPT_ENTRY_IGNORE_PAT_MASK 0x01
#define EPT_ENTRY_IGNORE_PAT(_) (((_) >> 6) & 0x01)
UINT64_t large_page : 1;
#define EPT_ENTRY_LARGE_PAGE_BIT 7
#define EPT_ENTRY_LARGE_PAGE_FLAG 0x80
#define EPT_ENTRY_LARGE_PAGE_MASK 0x01
#define EPT_ENTRY_LARGE_PAGE(_) (((_) >> 7) & 0x01)
UINT64_t accessed : 1;
#define EPT_ENTRY_ACCESSED_BIT 8
#define EPT_ENTRY_ACCESSED_FLAG 0x100
#define EPT_ENTRY_ACCESSED_MASK 0x01
#define EPT_ENTRY_ACCESSED(_) (((_) >> 8) & 0x01)
UINT64_t dirty : 1;
#define EPT_ENTRY_DIRTY_BIT 9
#define EPT_ENTRY_DIRTY_FLAG 0x200
#define EPT_ENTRY_DIRTY_MASK 0x01
#define EPT_ENTRY_DIRTY(_) (((_) >> 9) & 0x01)
UINT64_t user_mode_execute : 1;
#define EPT_ENTRY_USER_MODE_EXECUTE_BIT 10
#define EPT_ENTRY_USER_MODE_EXECUTE_FLAG 0x400
#define EPT_ENTRY_USER_MODE_EXECUTE_MASK 0x01
#define EPT_ENTRY_USER_MODE_EXECUTE(_) (((_) >> 10) & 0x01)
UINT64_t reserved1 : 1;
UINT64_t page_frame_number : 36;
#define EPT_ENTRY_PAGE_FRAME_NUMBER_BIT 12
#define EPT_ENTRY_PAGE_FRAME_NUMBER_FLAG 0xFFFFFFFFF000
#define EPT_ENTRY_PAGE_FRAME_NUMBER_MASK 0xFFFFFFFFF
#define EPT_ENTRY_PAGE_FRAME_NUMBER(_) (((_) >> 12) & 0xFFFFFFFFF)
UINT64_t reserved2 : 15;
UINT64_t suppress_ve : 1;
#define EPT_ENTRY_SUPPRESS_VE_BIT 63
#define EPT_ENTRY_SUPPRESS_VE_FLAG 0x8000000000000000
#define EPT_ENTRY_SUPPRESS_VE_MASK 0x01
#define EPT_ENTRY_SUPPRESS_VE(_) (((_) >> 63) & 0x01)
};
UINT64_t flags;
} ept_entry;
/**
* @defgroup ept_table_level \
* EPT Table level numbers
*
* EPT Table level numbers.
* @{
*/
#define EPT_LEVEL_PML4E 0x00000003
#define EPT_LEVEL_PDPTE 0x00000002
#define EPT_LEVEL_PDE 0x00000001
#define EPT_LEVEL_PTE 0x00000000
/**
* @}
*/
/**
* @defgroup ept_entry_count \
* EPT Entry counts
*
* EPT Entry counts.
* @{
*/
#define EPT_PML4E_ENTRY_COUNT 0x00000200
#define EPT_PDPTE_ENTRY_COUNT 0x00000200
#define EPT_PDE_ENTRY_COUNT 0x00000200
#define EPT_PTE_ENTRY_COUNT 0x00000200
/**
* @}
*/
/**
* @}
*/
typedef enum
{
/**
* If the INVEPT type is 1, the logical processor invalidates all guest-physical mappings and combined mappings associated
* with the EP4TA specified in the INVEPT descriptor. Combined mappings for that EP4TA are invalidated for all VPIDs and
* all PCIDs. (The instruction may invalidate mappings associated with other EP4TAs.)
*/
invept_single_context = 0x00000001,
/**
* If the INVEPT type is 2, the logical processor invalidates guest-physical mappings and combined mappings associated with
* all EP4TAs (and, for combined mappings, for all VPIDs and PCIDs).
*/
invept_all_context = 0x00000002,
} invept_type;
typedef enum
{
/**
* If the INVVPID type is 0, the logical processor invalidates linear mappings and combined mappings associated with the
* VPID specified in the INVVPID descriptor and that would be used to translate the linear address specified in of the
* INVVPID descriptor. Linear mappings and combined mappings for that VPID and linear address are invalidated for all PCIDs
* and, for combined mappings, all EP4TAs. (The instruction may also invalidate mappings associated with other VPIDs and
* for other linear addresses).
*/
invvpid_individual_address = 0x00000000,
/**
* If the INVVPID type is 1, the logical processor invalidates all linear mappings and combined mappings associated with
* the VPID specified in the INVVPID descriptor. Linear mappings and combined mappings for that VPID are invalidated for
* all PCIDs and, for combined mappings, all EP4TAs. (The instruction may also invalidate mappings associated with other
* VPIDs).
*/
invvpid_single_context = 0x00000001,
/**
* If the INVVPID type is 2, the logical processor invalidates linear mappings and combined mappings associated with all
* VPIDs except VPID 0000H and with all PCIDs. (The instruction may also invalidate linear mappings with VPID 0000H.)
* Combined mappings are invalidated for all EP4TAs.
*/
invvpid_all_context = 0x00000002,
/**
* If the INVVPID type is 3, the logical processor invalidates linear mappings and combined mappings associated with the
* VPID specified in the INVVPID descriptor. Linear mappings and combined mappings for that VPID are invalidated for all
* PCIDs and, for combined mappings, all EP4TAs. The logical processor is not required to invalidate information that was
* used for global translations (although it may do so). (The instruction may also invalidate mappings associated with
* other VPIDs).
*
* @see Vol3C[4.10(Caching Translation Information)]
*/
invvpid_single_context_retaining_globals = 0x00000003,
} invvpid_type;
typedef struct
{
UINT64_t ept_pointer;
/**
* Must be zero.
*/
UINT64_t reserved;
} invept_descriptor;
typedef struct
{
UINT16_t vpid;
/**
* Must be zero.
*/
UINT16_t reserved1;
/**
* Must be zero.
*/
UINT32_t reserved2;
UINT64_t linear_address;
} invvpid_descriptor;
/**
* @brief Format of the VMCS Region
*
* A logical processor uses virtual-machine control data structures (VMCSs) while it is in VMX operation. These manage
* transitions into and out of VMX non-root operation (VM entries and VM exits) as well as processor behavior in VMX
* non-root operation. This structure is manipulated by the new instructions VMCLEAR, VMPTRLD, VMREAD, and VMWRITE.
* A VMCS region comprises up to 4-KBytes. The exact size is implementation specific and can be determined by consulting
* the VMX capability MSR IA32_VMX_BASIC.
*
* @see Vol3C[24.2(FORMAT OF THE VMCS REGION)] (reference)
*/
typedef struct
{
struct
{
/**
* @brief VMCS revision identifier
*
* [Bits 30:0] Processors that maintain VMCS data in different formats (see below) use different VMCS revision identifiers.
* These identifiers enable software to avoid using a VMCS region formatted for one processor on a processor that uses a
* different format.
* Software should write the VMCS revision identifier to the VMCS region before using that region for a VMCS. The VMCS
* revision identifier is never written by the processor; VMPTRLD fails if its operand references a VMCS region whose VMCS
* revision identifier differs from that used by the processor.
* Software can discover the VMCS revision identifier that a processor uses by reading the VMX capability MSR
* IA32_VMX_BASIC.
*
* @see Vol3C[24.6.2(Processor-Based VM-Execution Controls)]
* @see Vol3D[A.1(BASIC VMX INFORMATION)]
*/
UINT32_t revision_id : 31;
/**
* @brief Shadow-VMCS indicator
*
* [Bit 31] Software should clear or set the shadow-VMCS indicator depending on whether the VMCS is to be an ordinary VMCS
* or a shadow VMCS. VMPTRLD fails if the shadow-VMCS indicator is set and the processor does not support the 1-setting of
* the "VMCS shadowing" VM-execution control. Software can discover support for this setting by reading the VMX capability
* MSR IA32_VMX_PROCBASED_CTLS2.
*
* @see Vol3C[24.10(VMCS TYPES ORDINARY AND SHADOW)]
*/
UINT32_t shadow_vmcs_indicator : 1;
};
/**
* @brief VMX-abort indicator
*
* The contents of these bits do not control processor operation in any way. A logical processor writes a non-zero value
* into these bits if a VMX abort occurs. Software may also write into this field.
*
* @see Vol3D[27.7(VMX Aborts)]
*/
UINT32_t abort_indicator;
/**
* @brief VMCS data (implementation-specific format)
*
* These parts of the VMCS control VMX non-root operation and the VMX transitions.
* The format of these data is implementation-specific. To ensure proper behavior in VMX operation, software should
* maintain the VMCS region and related structures in writeback cacheable memory. Future implementations may allow or
* require a different memory type. Software should consult the VMX capability MSR IA32_VMX_BASIC.
*
* @see Vol3C[24.11.4(Software Access to Related Structures)]
* @see Vol3D[A.1(BASIC VMX INFORMATION)]
*/
UINT8_t data[4088];
} vmcs;
/**
* @brief Format of the VMXON Region
*
* Before executing VMXON, software allocates a region of memory that the logical processor uses to support VMX operation.
* This region is called the VMXON region.
* A VMXON region comprises up to 4-KBytes. The exact size is implementation specific and can be determined by consulting
* the VMX capability MSR IA32_VMX_BASIC.
*
* @see Vol3C[24.11.5(VMXON Region)] (reference)
*/
typedef struct
{
struct
{
/**
* @brief VMCS revision identifier
*
* [Bits 30:0] Before executing VMXON, software should write the VMCS revision identifier to the VMXON region.
* (Specifically, it should write the 31-bit VMCS revision identifier to bits 30:0 of the first 4 bytes of the VMXON
* region; bit 31 should be cleared to 0.)
*
* @see VMCS
* @see Vol3C[24.2(FORMAT OF THE VMCS REGION)]
* @see Vol3C[24.11.5(VMXON Region)]
*/
UINT32_t revision_id : 31;
/**
* [Bit 31] Bit 31 is always 0.
*/
UINT32_t must_be_zero : 1;
};
/**
* @brief VMXON data (implementation-specific format)
*
* The format of these data is implementation-specific. To ensure proper behavior in VMX operation, software should not
* access or modify the VMXON region of a logical processor between execution of VMXON and VMXOFF on that logical
* processor. Doing otherwise may lead to unpredictable behavior.
*
* @see Vol3C[24.11.4(Software Access to Related Structures)]
* @see Vol3D[A.1(BASIC VMX INFORMATION)]
*/
UINT8_t data[4092];
} vmxon;
/**
* @defgroup vmcs_fields \
* VMCS (VM Control Structure)
*
* Every component of the VMCS is encoded by a 32-bit field that can be used by VMREAD and VMWRITE. This enumerates all
* fields in the VMCS and their encodings. Fields are grouped by width (16-bit, 32-bit, etc.) and type (guest-state,
* host-state, etc.).
*
* @see Vol3D[B(APPENDIX B FIELD ENCODING IN VMCS)] (reference)
* @{
*/
typedef union
{
struct
{
/**
* [Bit 0] Access type (0 = full; 1 = high); must be full for 16-bit, 32-bit, and natural-width fields.
*/
UINT16_t access_type : 1;
#define VMCS_COMPONENT_ENCODING_ACCESS_TYPE_BIT 0
#define VMCS_COMPONENT_ENCODING_ACCESS_TYPE_FLAG 0x01
#define VMCS_COMPONENT_ENCODING_ACCESS_TYPE_MASK 0x01
#define VMCS_COMPONENT_ENCODING_ACCESS_TYPE(_) (((_) >> 0) & 0x01)
/**
* [Bits 9:1] Index.
*/
UINT16_t index : 9;
#define VMCS_COMPONENT_ENCODING_INDEX_BIT 1
#define VMCS_COMPONENT_ENCODING_INDEX_FLAG 0x3FE
#define VMCS_COMPONENT_ENCODING_INDEX_MASK 0x1FF
#define VMCS_COMPONENT_ENCODING_INDEX(_) (((_) >> 1) & 0x1FF)
/**
* [Bits 11:10] Type:
* 0: control
* 1: VM-exit information
* 2: guest state
* 3: host state
*/
UINT16_t type : 2;
#define VMCS_COMPONENT_ENCODING_TYPE_BIT 10
#define VMCS_COMPONENT_ENCODING_TYPE_FLAG 0xC00
#define VMCS_COMPONENT_ENCODING_TYPE_MASK 0x03
#define VMCS_COMPONENT_ENCODING_TYPE(_) (((_) >> 10) & 0x03)
/**
* [Bit 12] Reserved (must be 0).
*/
UINT16_t must_be_zero : 1;
#define VMCS_COMPONENT_ENCODING_MUST_BE_ZERO_BIT 12
#define VMCS_COMPONENT_ENCODING_MUST_BE_ZERO_FLAG 0x1000
#define VMCS_COMPONENT_ENCODING_MUST_BE_ZERO_MASK 0x01
#define VMCS_COMPONENT_ENCODING_MUST_BE_ZERO(_) (((_) >> 12) & 0x01)
/**
* [Bits 14:13] Width:
* 0: 16-bit
* 1: 64-bit
* 2: 32-bit
* 3: natural-width
*/
UINT16_t width : 2;
#define VMCS_COMPONENT_ENCODING_WIDTH_BIT 13
#define VMCS_COMPONENT_ENCODING_WIDTH_FLAG 0x6000
#define VMCS_COMPONENT_ENCODING_WIDTH_MASK 0x03
#define VMCS_COMPONENT_ENCODING_WIDTH(_) (((_) >> 13) & 0x03)
UINT16_t reserved1 : 1;
};
UINT16_t flags;
} vmcs_component_encoding;
/**
* @defgroup vmcs_16_bit \
* 16-Bit Fields
*
* 16-Bit Fields.
*
* @see Vol3D[B.1(16-BIT FIELDS)] (reference)
* @{
*/
/**
* @defgroup vmcs_16_bit_control_fields \
* 16-Bit Control Fields
*
* 16-Bit Control Fields.
* @{
*/
/**
* Virtual-processor identifier (VPID).
*
* @remarks This field exists only on processors that support the 1-setting of the "enable VPID" VM-execution control.
*/
#define VMCS_CTRL_VIRTUAL_PROCESSOR_IDENTIFIER 0x00000000
/**
* Posted-interrupt notification vector.
*
* @remarks This field exists only on processors that support the 1-setting of the "process posted interrupts" VM-execution
* control.
*/
#define VMCS_CTRL_POSTED_INTERRUPT_NOTIFICATION_VECTOR 0x00000002
/**
* EPTP index.
*
* @remarks This field exists only on processors that support the 1-setting of the "EPT-violation \#VE" VM-execution
* control.
*/
#define VMCS_CTRL_EPTP_INDEX 0x00000004
/**
* @}
*/
/**
* @defgroup vmcs_16_bit_guest_state_fields \
* 16-Bit Guest-State Fields
*
* 16-Bit Guest-State Fields.
* @{
*/
/**
* Guest ES selector.
*/
#define VMCS_GUEST_ES_SELECTOR 0x00000800
/**
* Guest CS selector.
*/
#define VMCS_GUEST_CS_SELECTOR 0x00000802
/**
* Guest SS selector.
*/
#define VMCS_GUEST_SS_SELECTOR 0x00000804
/**
* Guest DS selector.
*/
#define VMCS_GUEST_DS_SELECTOR 0x00000806
/**
* Guest FS selector.
*/
#define VMCS_GUEST_FS_SELECTOR 0x00000808
/**
* Guest GS selector.
*/
#define VMCS_GUEST_GS_SELECTOR 0x0000080A
/**
* Guest LDTR selector.
*/
#define VMCS_GUEST_LDTR_SELECTOR 0x0000080C
/**
* Guest TR selector.
*/
#define VMCS_GUEST_TR_SELECTOR 0x0000080E
/**
* Guest interrupt status.
*
* @remarks This field exists only on processors that support the 1-setting of the "virtual-interrupt delivery"
* VM-execution control.
*/
#define VMCS_GUEST_INTERRUPT_STATUS 0x00000810
/**
* PML index.
*
* @remarks This field exists only on processors that support the 1-setting of the "enable PML" VM-execution control.
*/
#define VMCS_GUEST_PML_INDEX 0x00000812
/**
* @}
*/
/**
* @defgroup vmcs_16_bit_host_state_fields \
* 16-Bit Host-State Fields
*
* 16-Bit Host-State Fields.
* @{
*/
/**
* Host ES selector.
*/
#define VMCS_HOST_ES_SELECTOR 0x00000C00
/**
* Host CS selector.
*/
#define VMCS_HOST_CS_SELECTOR 0x00000C02
/**
* Host SS selector.
*/
#define VMCS_HOST_SS_SELECTOR 0x00000C04
/**
* Host DS selector.
*/
#define VMCS_HOST_DS_SELECTOR 0x00000C06
/**
* Host FS selector.
*/
#define VMCS_HOST_FS_SELECTOR 0x00000C08
/**
* Host GS selector.
*/
#define VMCS_HOST_GS_SELECTOR 0x00000C0A
/**
* Host TR selector.
*/
#define VMCS_HOST_TR_SELECTOR 0x00000C0C
/**
* @}
*/
/**
* @}
*/
/**
* @defgroup vmcs_64_bit \
* 64-Bit Fields
*
* 64-Bit Fields.
*
* @see Vol3D[B.2(64-BIT FIELDS)] (reference)
* @{
*/
/**
* @defgroup vmcs_64_bit_control_fields \
* 64-Bit Control Fields
*
* 64-Bit Control Fields.
* @{
*/
/**
* Address of I/O bitmap A.
*/
#define VMCS_CTRL_IO_BITMAP_A_ADDRESS 0x00002000
/**
* Address of I/O bitmap B.
*/
#define VMCS_CTRL_IO_BITMAP_B_ADDRESS 0x00002002
/**
* Address of MSR bitmaps.
*/
#define VMCS_CTRL_MSR_BITMAP_ADDRESS 0x00002004
/**
* VM-exit MSR-store address.
*/
#define VMCS_CTRL_VMEXIT_MSR_STORE_ADDRESS 0x00002006
/**
* VM-exit MSR-load address.
*/
#define VMCS_CTRL_VMEXIT_MSR_LOAD_ADDRESS 0x00002008
/**
* VM-entry MSR-load address.
*/
#define VMCS_CTRL_VMENTRY_MSR_LOAD_ADDRESS 0x0000200A
/**
* Executive-VMCS pointer.
*/
#define VMCS_CTRL_EXECUTIVE_VMCS_POINTER 0x0000200C
/**
* PML address.
*/
#define VMCS_CTRL_PML_ADDRESS 0x0000200E
/**
* TSC offset.
*/
#define VMCS_CTRL_TSC_OFFSET 0x00002010
/**
* Virtual-APIC address.
*/
#define VMCS_CTRL_VIRTUAL_APIC_ADDRESS 0x00002012
/**
* APIC-access address.
*/
#define VMCS_CTRL_APIC_ACCESS_ADDRESS 0x00002014
/**
* Posted-interrupt descriptor address
*/
#define VMCS_CTRL_POSTED_INTERRUPT_DESCRIPTOR_ADDRESS 0x00002016
/**
* VM-function controls.
*/
#define VMCS_CTRL_VMFUNC_CONTROLS 0x00002018
/**
* EPT pointer.
*/
#define VMCS_CTRL_EPT_POINTER 0x0000201A
/**
* EOI-exit bitmap 0.
*/
#define VMCS_CTRL_EOI_EXIT_BITMAP_0 0x0000201C
/**
* EOI-exit bitmap 1.
*/
#define VMCS_CTRL_EOI_EXIT_BITMAP_1 0x0000201E
/**
* EOI-exit bitmap 2.
*/
#define VMCS_CTRL_EOI_EXIT_BITMAP_2 0x00002020
/**
* EOI-exit bitmap 3.
*/
#define VMCS_CTRL_EOI_EXIT_BITMAP_3 0x00002022
/**
* EPTP-list address.
*/
#define VMCS_CTRL_EPT_POINTER_LIST_ADDRESS 0x00002024
/**
* VMREAD-bitmap address.
*/
#define VMCS_CTRL_VMREAD_BITMAP_ADDRESS 0x00002026
/**
* VMWRITE-bitmap address.
*/
#define VMCS_CTRL_VMWRITE_BITMAP_ADDRESS 0x00002028
/**
* Virtualization-exception information address.
*/
#define VMCS_CTRL_VIRTUALIZATION_EXCEPTION_INFORMATION_ADDRESS 0x0000202A
/**
* XSS-exiting bitmap.
*/
#define VMCS_CTRL_XSS_EXITING_BITMAP 0x0000202C
/**
* ENCLS-exiting bitmap.
*/
#define VMCS_CTRL_ENCLS_EXITING_BITMAP 0x0000202E
/**
* TSC multiplier.
*/
#define VMCS_CTRL_TSC_MULTIPLIER 0x00002032
/**
* @}
*/
/**
* @defgroup vmcs_64_bit_read_only_data_fields \
* 64-Bit Read-Only Data Field
*
* 64-Bit Read-Only Data Field.
* @{
*/
/**
* Guest-physical address.
*/
#define VMCS_GUEST_PHYSICAL_ADDRESS 0x00002400
/**
* @}
*/
/**
* @defgroup vmcs_64_bit_guest_state_fields \
* 64-Bit Guest-State Fields
*
* 64-Bit Guest-State Fields.
* @{
*/
/**
* VMCS link pointer.
*/
#define VMCS_GUEST_VMCS_LINK_POINTER 0x00002800
/**
* Guest IA32_DEBUGCTL.
*/
#define VMCS_GUEST_DEBUGCTL 0x00002802
/**
* Guest IA32_PAT.
*/
#define VMCS_GUEST_PAT 0x00002804
/**
* Guest IA32_EFER.
*/
#define VMCS_GUEST_EFER 0x00002806
/**
* Guest IA32_PERF_GLOBAL_CTRL.
*/
#define VMCS_GUEST_PERF_GLOBAL_CTRL 0x00002808
/**
* Guest PDPTE0.
*/
#define VMCS_GUEST_PDPTE0 0x0000280A
/**
* Guest PDPTE1.
*/
#define VMCS_GUEST_PDPTE1 0x0000280C
/**
* Guest PDPTE2.
*/
#define VMCS_GUEST_PDPTE2 0x0000280E
/**
* Guest PDPTE3.
*/
#define VMCS_GUEST_PDPTE3 0x00002810
/**
* Guest IA32_BNDCFGS.
*/
#define VMCS_GUEST_BNDCFGS 0x00002812
/**
* Guest IA32_RTIT_CTL.
*/
#define VMCS_GUEST_RTIT_CTL 0x00002814
/**
* @}
*/
/**
* @defgroup vmcs_64_bit_host_state_fields \
* 64-Bit Host-State Fields
*
* 64-Bit Host-State Fields.
* @{
*/
/**
* Host IA32_PAT.
*/
#define VMCS_HOST_PAT 0x00002C00
/**
* Host IA32_EFER.
*/
#define VMCS_HOST_EFER 0x00002C02
/**
* Host IA32_PERF_GLOBAL_CTRL.
*/
#define VMCS_HOST_PERF_GLOBAL_CTRL 0x00002C04
/**
* @}
*/
/**
* @}
*/
/**
* @defgroup vmcs_32_bit \
* 32-Bit Fields
*
* 32-Bit Fields.
*
* @see Vol3D[B.3(32-BIT FIELDS)] (reference)
* @{
*/
/**
* @defgroup vmcs_32_bit_control_fields \
* 32-Bit Control Fields
*
* 32-Bit Control Fields.
* @{
*/
/**
* Pin-based VM-execution controls.
*/
#define VMCS_CTRL_PIN_BASED_VM_EXECUTION_CONTROLS 0x00004000
/**
* Primary processor-based VM-execution controls.
*/
#define VMCS_CTRL_PROCESSOR_BASED_VM_EXECUTION_CONTROLS 0x00004002
/**
* Exception bitmap.
*/
#define VMCS_CTRL_EXCEPTION_BITMAP 0x00004004
/**
* Page-fault error-code mask.
*/
#define VMCS_CTRL_PAGEFAULT_ERROR_CODE_MASK 0x00004006
/**
* Page-fault error-code match.
*/
#define VMCS_CTRL_PAGEFAULT_ERROR_CODE_MATCH 0x00004008
/**
* CR3-target count.
*/
#define VMCS_CTRL_CR3_TARGET_COUNT 0x0000400A
/**
* VM-exit controls.
*/
#define VMCS_CTRL_VMEXIT_CONTROLS 0x0000400C
/**
* VM-exit MSR-store count.
*/
#define VMCS_CTRL_VMEXIT_MSR_STORE_COUNT 0x0000400E
/**
* VM-exit MSR-load count.
*/
#define VMCS_CTRL_VMEXIT_MSR_LOAD_COUNT 0x00004010
/**
* VM-entry controls.
*/
#define VMCS_CTRL_VMENTRY_CONTROLS 0x00004012
/**
* VM-entry MSR-load count.
*/
#define VMCS_CTRL_VMENTRY_MSR_LOAD_COUNT 0x00004014
/**
* VM-entry interruption-information field.
*/
#define VMCS_CTRL_VMENTRY_INTERRUPTION_INFORMATION_FIELD 0x00004016
/**
* VM-entry exception error code.
*/
#define VMCS_CTRL_VMENTRY_EXCEPTION_ERROR_CODE 0x00004018
/**
* VM-entry instruction length.
*/
#define VMCS_CTRL_VMENTRY_INSTRUCTION_LENGTH 0x0000401A
/**
* TPR threshold.
*/
#define VMCS_CTRL_TPR_THRESHOLD 0x0000401C
/**
* Secondary processor-based VM-execution controls.
*/
#define VMCS_CTRL_SECONDARY_PROCESSOR_BASED_VM_EXECUTION_CONTROLS 0x0000401E
/**
* PLE_Gap.
*/
#define VMCS_CTRL_PLE_GAP 0x00004020
/**
* PLE_Window.
*/
#define VMCS_CTRL_PLE_WINDOW 0x00004022
/**
* @}
*/
/**
* @defgroup vmcs_32_bit_read_only_data_fields \
* 32-Bit Read-Only Data Fields
*
* 32-Bit Read-Only Data Fields.
* @{
*/
/**
* VM-instruction error.
*/
#define VMCS_VM_INSTRUCTION_ERROR 0x00004400
/**
* Exit reason.
*/
#define VMCS_EXIT_REASON 0x00004402
/**
* VM-exit interruption information.
*/
#define VMCS_VMEXIT_INTERRUPTION_INFORMATION 0x00004404
/**
* VM-exit interruption error code.
*/
#define VMCS_VMEXIT_INTERRUPTION_ERROR_CODE 0x00004406
/**
* IDT-vectoring information field.
*/
#define VMCS_IDT_VECTORING_INFORMATION 0x00004408
/**
* IDT-vectoring error code.
*/
#define VMCS_IDT_VECTORING_ERROR_CODE 0x0000440A
/**
* VM-exit instruction length.
*/
#define VMCS_VMEXIT_INSTRUCTION_LENGTH 0x0000440C
/**
* VM-exit instruction information.
*/
#define VMCS_VMEXIT_INSTRUCTION_INFO 0x0000440E
/**
* @}
*/
/**
* @defgroup vmcs_32_bit_guest_state_fields \
* 32-Bit Guest-State Fields
*
* 32-Bit Guest-State Fields.
* @{
*/
/**
* Guest ES limit.
*/
#define VMCS_GUEST_ES_LIMIT 0x00004800
/**
* Guest CS limit.
*/
#define VMCS_GUEST_CS_LIMIT 0x00004802
/**
* Guest SS limit.
*/
#define VMCS_GUEST_SS_LIMIT 0x00004804
/**
* Guest DS limit.
*/
#define VMCS_GUEST_DS_LIMIT 0x00004806
/**
* Guest FS limit.
*/
#define VMCS_GUEST_FS_LIMIT 0x00004808
/**
* Guest GS limit.
*/
#define VMCS_GUEST_GS_LIMIT 0x0000480A
/**
* Guest LDTR limit.
*/
#define VMCS_GUEST_LDTR_LIMIT 0x0000480C
/**
* Guest TR limit.
*/
#define VMCS_GUEST_TR_LIMIT 0x0000480E
/**
* Guest GDTR limit.
*/
#define VMCS_GUEST_GDTR_LIMIT 0x00004810
/**
* Guest IDTR limit.
*/
#define VMCS_GUEST_IDTR_LIMIT 0x00004812
/**
* Guest ES access rights.
*/
#define VMCS_GUEST_ES_ACCESS_RIGHTS 0x00004814
/**
* Guest CS access rights.
*/
#define VMCS_GUEST_CS_ACCESS_RIGHTS 0x00004816
/**
* Guest SS access rights.
*/
#define VMCS_GUEST_SS_ACCESS_RIGHTS 0x00004818
/**
* Guest DS access rights.
*/
#define VMCS_GUEST_DS_ACCESS_RIGHTS 0x0000481A
/**
* Guest FS access rights.
*/
#define VMCS_GUEST_FS_ACCESS_RIGHTS 0x0000481C
/**
* Guest GS access rights.
*/
#define VMCS_GUEST_GS_ACCESS_RIGHTS 0x0000481E
/**
* Guest LDTR access rights.
*/
#define VMCS_GUEST_LDTR_ACCESS_RIGHTS 0x00004820
/**
* Guest TR access rights.
*/
#define VMCS_GUEST_TR_ACCESS_RIGHTS 0x00004822
/**
* Guest interruptibility state.
*/
#define VMCS_GUEST_INTERRUPTIBILITY_STATE 0x00004824
/**
* Guest activity state.
*/
#define VMCS_GUEST_ACTIVITY_STATE 0x00004826
/**
* Guest SMBASE.
*/
#define VMCS_GUEST_SMBASE 0x00004828
/**
* Guest IA32_SYSENTER_CS.
*/
#define VMCS_GUEST_SYSENTER_CS 0x0000482A
/**
* VMX-preemption timer value.
*/
#define VMCS_GUEST_VMX_PREEMPTION_TIMER_VALUE 0x0000482E
/**
* @}
*/
/**
* @defgroup vmcs_32_bit_host_state_fields \
* 32-Bit Host-State Field
*
* 32-Bit Host-State Field.
* @{
*/
/**
* Host IA32_SYSENTER_CS.
*/
#define VMCS_HOST_SYSENTER_CS 0x00004C00
/**
* @}
*/
/**
* @}
*/
/**
* @defgroup vmcs_natural_width \
* Natural-Width Fields
*
* Natural-Width Fields.
*
* @see Vol3D[B.4(NATURAL-WIDTH FIELDS)] (reference)
* @{
*/
/**
* @defgroup vmcs_natural_width_control_fields \
* Natural-Width Control Fields
*
* Natural-Width Control Fields
* @{
*/
/**
* CR0 guest/host mask.
*/
#define VMCS_CTRL_CR0_GUEST_HOST_MASK 0x00006000
/**
* CR4 guest/host mask.
*/
#define VMCS_CTRL_CR4_GUEST_HOST_MASK 0x00006002
/**
* CR0 read shadow.
*/
#define VMCS_CTRL_CR0_READ_SHADOW 0x00006004
/**
* CR4 read shadow.
*/
#define VMCS_CTRL_CR4_READ_SHADOW 0x00006006
/**
* CR3-target value 0.
*/
#define VMCS_CTRL_CR3_TARGET_VALUE_0 0x00006008
/**
* CR3-target value 1.
*/
#define VMCS_CTRL_CR3_TARGET_VALUE_1 0x0000600A
/**
* CR3-target value 2.
*/
#define VMCS_CTRL_CR3_TARGET_VALUE_2 0x0000600C
/**
* CR3-target value 3.
*/
#define VMCS_CTRL_CR3_TARGET_VALUE_3 0x0000600E
/**
* @}
*/
/**
* @defgroup vmcs_natural_width_read_only_data_fields \
* Natural-Width Read-Only Data Fields
*
* Natural-Width Read-Only Data Fields.
* @{
*/
/**
* Exit qualification.
*/
#define VMCS_EXIT_QUALIFICATION 0x00006400
/**
* I/O RCX.
*/
#define VMCS_IO_RCX 0x00006402
/**
* I/O RSI.
*/
#define VMCS_IO_RSX 0x00006404
/**
* I/O RDI.
*/
#define VMCS_IO_RDI 0x00006406
/**
* I/O RIP.
*/
#define VMCS_IO_RIP 0x00006408
/**
* Guest-linear address.
*/
#define VMCS_EXIT_GUEST_LINEAR_ADDRESS 0x0000640A
/**
* @}
*/
/**
* @defgroup vmcs_natural_width_guest_state_fields \
* Natural-Width Guest-State Fields
*
* Natural-Width Guest-State Fields.
* @{
*/
/**
* Guest CR0.
*/
#define VMCS_GUEST_CR0 0x00006800
/**
* Guest CR3.
*/
#define VMCS_GUEST_CR3 0x00006802
/**
* Guest CR4.
*/
#define VMCS_GUEST_CR4 0x00006804
/**
* Guest ES base.
*/
#define VMCS_GUEST_ES_BASE 0x00006806
/**
* Guest CS base.
*/
#define VMCS_GUEST_CS_BASE 0x00006808
/**
* Guest SS base.
*/
#define VMCS_GUEST_SS_BASE 0x0000680A
/**
* Guest DS base.
*/
#define VMCS_GUEST_DS_BASE 0x0000680C
/**
* Guest FS base.
*/
#define VMCS_GUEST_FS_BASE 0x0000680E
/**
* Guest GS base.
*/
#define VMCS_GUEST_GS_BASE 0x00006810
/**
* Guest LDTR base.
*/
#define VMCS_GUEST_LDTR_BASE 0x00006812
/**
* Guest TR base.
*/
#define VMCS_GUEST_TR_BASE 0x00006814
/**
* Guest GDTR base.
*/
#define VMCS_GUEST_GDTR_BASE 0x00006816
/**
* Guest IDTR base.
*/
#define VMCS_GUEST_IDTR_BASE 0x00006818
/**
* Guest DR7.
*/
#define VMCS_GUEST_DR7 0x0000681A
/**
* Guest RSP.
*/
#define VMCS_GUEST_RSP 0x0000681C
/**
* Guest RIP.
*/
#define VMCS_GUEST_RIP 0x0000681E
/**
* Guest RFLAGS.
*/
#define VMCS_GUEST_RFLAGS 0x00006820
/**
* Guest pending debug exceptions.
*/
#define VMCS_GUEST_PENDING_DEBUG_EXCEPTIONS 0x00006822
/**
* Guest IA32_SYSENTER_ESP.
*/
#define VMCS_GUEST_SYSENTER_ESP 0x00006824
/**
* Guest IA32_SYSENTER_EIP.
*/
#define VMCS_GUEST_SYSENTER_EIP 0x00006826
/**
* Guest IA32_S_CET.
*/
#define VMCS_GUEST_S_CET 0x00006C28
/**
* Guest SSP.
*/
#define VMCS_GUEST_SSP 0x00006C2A
/**
* Guest IA32_INTERRUPT_SSP_TABLE_ADDR.
*/
#define VMCS_GUEST_INTERRUPT_SSP_TABLE_ADDR 0x00006C2C
/**
* @}
*/
/**
* @defgroup vmcs_natural_width_host_state_fields \
* Natural-Width Host-State Fields
*
* Natural-Width Host-State Fields.
* @{
*/
/**
* Host CR0.
*/
#define VMCS_HOST_CR0 0x00006C00
/**
* Host CR3.
*/
#define VMCS_HOST_CR3 0x00006C02
/**
* Host CR4.
*/
#define VMCS_HOST_CR4 0x00006C04
/**
* Host FS base.
*/
#define VMCS_HOST_FS_BASE 0x00006C06
/**
* Host GS base.
*/
#define VMCS_HOST_GS_BASE 0x00006C08
/**
* Host TR base.
*/
#define VMCS_HOST_TR_BASE 0x00006C0A
/**
* Host GDTR base.
*/
#define VMCS_HOST_GDTR_BASE 0x00006C0C
/**
* Host IDTR base.
*/
#define VMCS_HOST_IDTR_BASE 0x00006C0E
/**
* Host IA32_SYSENTER_ESP.
*/
#define VMCS_HOST_SYSENTER_ESP 0x00006C10
/**
* Host IA32_SYSENTER_EIP.
*/
#define VMCS_HOST_SYSENTER_EIP 0x00006C12
/**
* Host RSP.
*/
#define VMCS_HOST_RSP 0x00006C14
/**
* Host RIP.
*/
#define VMCS_HOST_RIP 0x00006C16
/**
* Host IA32_S_CET.
*/
#define VMCS_HOST_S_CET 0x00006C18
/**
* Host SSP.
*/
#define VMCS_HOST_SSP 0x00006C1A
/**
* Host IA32_INTERRUPT_SSP_TABLE_ADDR.
*/
#define VMCS_HOST_INTERRUPT_SSP_TABLE_ADDR 0x00006C1C
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @brief Valid interruption types
*/
typedef enum
{
/**
* External interrupt.
*/
external_interrupt = 0x00000000,
/**
* Non-maskable interrupt (NMI).
*/
non_maskable_interrupt = 0x00000002,
/**
* Hardware exception (e.g,. \#PF).
*/
hardware_exception = 0x00000003,
/**
* Software interrupt (INT n).
*/
software_interrupt = 0x00000004,
/**
* Privileged software exception (INT1).
*/
privileged_software_exception = 0x00000005,
/**
* Software exception (INT3 or INTO).
*/
software_exception = 0x00000006,
/**
* Other event. This type is used for injection of events that are not delivered through the IDT.
*/
other_event = 0x00000007,
} interruption_type;
/**
* @brief VM entry can be configured to conclude by delivering an event through the IDT (after all guest state and MSRs
* have been loaded). This process is called event injection and is controlled by these VM-entry control fields
*
* @see Vol3A[24.8.3(VM-Entry Controls for Event Injection)] (reference)
*/
typedef union
{
struct
{
/**
* @brief Vector of interrupt or exception
*
* [Bits 7:0] Determines which entry in the IDT is used or which other event is injected.
*/
UINT32_t vector : 8;
#define VMENTRY_INTERRUPT_INFORMATION_VECTOR_BIT 0
#define VMENTRY_INTERRUPT_INFORMATION_VECTOR_FLAG 0xFF
#define VMENTRY_INTERRUPT_INFORMATION_VECTOR_MASK 0xFF
#define VMENTRY_INTERRUPT_INFORMATION_VECTOR(_) (((_) >> 0) & 0xFF)
/**
* @brief Interruption type
*
* [Bits 10:8] Determines details of how the injection is performed.
*/
UINT32_t interruption_type : 3;
#define VMENTRY_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_BIT 8
#define VMENTRY_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_FLAG 0x700
#define VMENTRY_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_MASK 0x07
#define VMENTRY_INTERRUPT_INFORMATION_INTERRUPTION_TYPE(_) (((_) >> 8) & 0x07)
/**
* @brief Deliver error code (0 = do not deliver; 1 = deliver)
*
* [Bit 11] Determines whether delivery pushes an error code on the guest stack.
*/
UINT32_t deliver_error_code : 1;
#define VMENTRY_INTERRUPT_INFORMATION_DELIVER_ERROR_CODE_BIT 11
#define VMENTRY_INTERRUPT_INFORMATION_DELIVER_ERROR_CODE_FLAG 0x800
#define VMENTRY_INTERRUPT_INFORMATION_DELIVER_ERROR_CODE_MASK 0x01
#define VMENTRY_INTERRUPT_INFORMATION_DELIVER_ERROR_CODE(_) (((_) >> 11) & 0x01)
UINT32_t reserved1 : 19;
/**
* @brief Valid
*
* [Bit 31] VM entry injects an event if and only if the valid bit is 1. The valid bit in this field is cleared on every VM
* exit.
*/
UINT32_t valid : 1;
#define VMENTRY_INTERRUPT_INFORMATION_VALID_BIT 31
#define VMENTRY_INTERRUPT_INFORMATION_VALID_FLAG 0x80000000
#define VMENTRY_INTERRUPT_INFORMATION_VALID_MASK 0x01
#define VMENTRY_INTERRUPT_INFORMATION_VALID(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} vmentry_interrupt_information;
/**
* @brief VM entry can be configured to conclude by delivering an event through the IDT (after all guest state and MSRs
* have been loaded). This process is called event injection and is controlled by these VM-entry control fields
*
* @see Vol3A[24.9.2(Information for VM Exits Due to Vectored Events)] (reference)
*/
typedef union
{
struct
{
/**
* [Bits 7:0] Vector of interrupt or exception.
*/
UINT32_t vector : 8;
#define VMEXIT_INTERRUPT_INFORMATION_VECTOR_BIT 0
#define VMEXIT_INTERRUPT_INFORMATION_VECTOR_FLAG 0xFF
#define VMEXIT_INTERRUPT_INFORMATION_VECTOR_MASK 0xFF
#define VMEXIT_INTERRUPT_INFORMATION_VECTOR(_) (((_) >> 0) & 0xFF)
/**
* [Bits 10:8] Interruption type.
*/
UINT32_t interruption_type : 3;
#define VMEXIT_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_BIT 8
#define VMEXIT_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_FLAG 0x700
#define VMEXIT_INTERRUPT_INFORMATION_INTERRUPTION_TYPE_MASK 0x07
#define VMEXIT_INTERRUPT_INFORMATION_INTERRUPTION_TYPE(_) (((_) >> 8) & 0x07)
/**
* [Bit 11] Deliver error code (0 = do not deliver; 1 = deliver).
*/
UINT32_t error_code_valid : 1;
#define VMEXIT_INTERRUPT_INFORMATION_ERROR_CODE_VALID_BIT 11
#define VMEXIT_INTERRUPT_INFORMATION_ERROR_CODE_VALID_FLAG 0x800
#define VMEXIT_INTERRUPT_INFORMATION_ERROR_CODE_VALID_MASK 0x01
#define VMEXIT_INTERRUPT_INFORMATION_ERROR_CODE_VALID(_) (((_) >> 11) & 0x01)
/**
* [Bit 12] NMI unblocking due to IRET.
*/
UINT32_t nmi_unblocking : 1;
#define VMEXIT_INTERRUPT_INFORMATION_NMI_UNBLOCKING_BIT 12
#define VMEXIT_INTERRUPT_INFORMATION_NMI_UNBLOCKING_FLAG 0x1000
#define VMEXIT_INTERRUPT_INFORMATION_NMI_UNBLOCKING_MASK 0x01
#define VMEXIT_INTERRUPT_INFORMATION_NMI_UNBLOCKING(_) (((_) >> 12) & 0x01)
UINT32_t reserved1 : 18;
/**
* [Bit 31] Valid.
*/
UINT32_t valid : 1;
#define VMEXIT_INTERRUPT_INFORMATION_VALID_BIT 31
#define VMEXIT_INTERRUPT_INFORMATION_VALID_FLAG 0x80000000
#define VMEXIT_INTERRUPT_INFORMATION_VALID_MASK 0x01
#define VMEXIT_INTERRUPT_INFORMATION_VALID(_) (((_) >> 31) & 0x01)
};
UINT32_t flags;
} vmexit_interrupt_information;
/**
* @}
*/
/**
* @defgroup apic \
* Advanced Programmable Interrupt Controller (APIC)
*
* Software interacts with the local APIC by reading and writing its registers. APIC registers are memory-mapped to a
* 4-KByte region of the processor's physical address space with an initial starting address of FEE00000H. For correct APIC
* operation, this address space must be mapped to an area of memory that has been designated as strong uncacheable (UC).
*
* @remarks Registers are 32 bits, 64 bits, or 256 bits in width; all are aligned on 128-bit boundaries. All 32-bit
* registers should be accessed using 128-bit aligned 32-bit loads or stores. Some processors may support loads and stores
* of less than 32 bits to some of the APIC registers. This is model specific behavior and is not guaranteed to work on all
* processors. Any FP/MMX/SSE access to an APIC register, or any access that touches bytes 4 through 15 of an APIC register
* may cause undefined behavior and must not be executed. This undefined behavior could include hangs, incorrect results or
* unexpected exceptions, including machine checks, and may vary between implementations. Wider registers (64-bit or
* 256-bit) must be accessed using multiple 32-bit loads or stores, with all accesses being 128-bit aligned.
* @see Vol3A[10.4.1(The Local APIC Block Diagram)] (reference)
* @{
*/
/**
* Local APIC Base Address.
*
* @remarks Reserved.
*/
#define APIC_BASE_ADDRESS 0xFEE00000
/**
* Local APIC ID Register.
*/
#define APIC_ID 0x00000020
/**
* Local APIC Version Register.
*/
#define APIC_VERSION 0x00000030
/**
* Task Priority Register (TPR).
*/
#define APIC_TASK_PRIORITY 0x00000080
/**
* Arbitration Priority Register (APR).
*/
#define APIC_ARBITRATION_PRIORITY 0x00000090
/**
* Processor Priority Register (PPR).
*/
#define APIC_PROCESSOR_PRIORITY 0x000000A0
/**
* EOI Register.
*/
#define APIC_EOI 0x000000B0
/**
* Remote Read Register (RRD).
*/
#define APIC_REMOTE_READ 0x000000C0
/**
* Logical Destination Register.
*/
#define APIC_LOGICAL_DESTINATION 0x000000D0
/**
* Destination Format Register.
*
* @see Vol3A[10.6.2.2(Logical Destination Mode)]
*/
#define APIC_DESTINATION_FORMAT 0x000000E0
/**
* Spurious Interrupt Vector Register.
*
* @see Vol3A[10.9(SPURIOUS INTERRUPT)]
*/
#define APIC_SPURIOUS_INTERRUPT_VECTOR 0x000000F0
/**
* In-Service Register (ISR); bits 31:0.
*/
#define APIC_IN_SERVICE_BITS_31_0 0x00000100
/**
* In-Service Register (ISR); bits 63:32.
*/
#define APIC_IN_SERVICE_BITS_63_32 0x00000110
/**
* In-Service Register (ISR); bits 95:64.
*/
#define APIC_IN_SERVICE_BITS_95_64 0x00000120
/**
* In-Service Register (ISR); bits 127:96.
*/
#define APIC_IN_SERVICE_BITS_127_96 0x00000130
/**
* In-Service Register (ISR); bits 159:128.
*/
#define APIC_IN_SERVICE_BITS_159_128 0x00000140
/**
* In-Service Register (ISR); bits 191:160.
*/
#define APIC_IN_SERVICE_BITS_191_160 0x00000150
/**
* In-Service Register (ISR); bits 223:192.
*/
#define APIC_IN_SERVICE_BITS_223_192 0x00000160
/**
* In-Service Register (ISR); bits 255:224.
*/
#define APIC_IN_SERVICE_BITS_255_224 0x00000170
/**
* Trigger Mode Register (TMR); bits 31:0.
*/
#define APIC_TRIGGER_MODE_BITS_31_0 0x00000180
/**
* Trigger Mode Register (TMR); bits 63:32.
*/
#define APIC_TRIGGER_MODE_BITS_63_32 0x00000190
/**
* Trigger Mode Register (TMR); bits 95:64.
*/
#define APIC_TRIGGER_MODE_BITS_95_64 0x000001A0
/**
* Trigger Mode Register (TMR); bits 127:96.
*/
#define APIC_TRIGGER_MODE_BITS_127_96 0x000001B0
/**
* Trigger Mode Register (TMR); bits 159:128.
*/
#define APIC_TRIGGER_MODE_BITS_159_128 0x000001C0
/**
* Trigger Mode Register (TMR); bits 191:160.
*/
#define APIC_TRIGGER_MODE_BITS_191_160 0x000001D0
/**
* Trigger Mode Register (TMR); bits 223:192.
*/
#define APIC_TRIGGER_MODE_BITS_223_192 0x000001E0
/**
* Trigger Mode Register (TMR); bits 255:224.
*/
#define APIC_TRIGGER_MODE_BITS_255_224 0x000001F0
/**
* Interrupt Request Register (IRR); bits 31:0.
*/
#define APIC_INTERRUPT_REQUEST_BITS_31_0 0x00000200
/**
* Interrupt Request Register (IRR); bits 63:32.
*/
#define APIC_INTERRUPT_REQUEST_BITS_63_32 0x00000210
/**
* Interrupt Request Register (IRR); bits 95:64.
*/
#define APIC_INTERRUPT_REQUEST_BITS_95_64 0x00000220
/**
* Interrupt Request Register (IRR); bits 127:96.
*/
#define APIC_INTERRUPT_REQUEST_BITS_127_96 0x00000230
/**
* Interrupt Request Register (IRR); bits 159:128.
*/
#define APIC_INTERRUPT_REQUEST_BITS_159_128 0x00000240
/**
* Interrupt Request Register (IRR); bits 191:160.
*/
#define APIC_INTERRUPT_REQUEST_BITS_191_160 0x00000250
/**
* Interrupt Request Register (IRR); bits 223:192.
*/
#define APIC_INTERRUPT_REQUEST_BITS_223_192 0x00000260
/**
* Interrupt Request Register (IRR); bits 255:224.
*/
#define APIC_INTERRUPT_REQUEST_BITS_255_224 0x00000270
/**
* Error Status Register.
*/
#define APIC_ERROR_STATUS 0x00000280
/**
* LVT Corrected Machine Check Interrupt (CMCI) Register.
*/
#define APIC_LVT_CORRECTED_MACHINE_CHECK_INTERRUPT 0x000002F0
/**
* Interrupt Command Register (ICR); bits 0-31.
*/
#define APIC_INTERRUPT_COMMAND_BITS_0_31 0x00000300
/**
* Interrupt Command Register (ICR); bits 32-63.
*/
#define APIC_INTERRUPT_COMMAND_BITS_32_63 0x00000310
/**
* LVT Timer Register.
*/
#define APIC_LVT_TIMER 0x00000320
/**
* LVT Thermal Sensor Register.
*/
#define APIC_LVT_THERMAL_SENSOR 0x00000330
/**
* LVT Performance Monitoring Counters Register.
*/
#define APIC_LVT_PERFORMANCE_MONITORING_COUNTERS 0x00000340
/**
* LVT LINT0 Register.
*/
#define APIC_LVT_LINT0 0x00000350
/**
* LVT LINT1 Register.
*/
#define APIC_LVT_LINT1 0x00000360
/**
* LVT Error Register.
*/
#define APIC_LVT_ERROR 0x00000370
/**
* Initial Count Register (for Timer).
*/
#define APIC_INITIAL_COUNT 0x00000380
/**
* Current Count Register (for Timer).
*/
#define APIC_CURRENT_COUNT 0x00000390
/**
* Divide Configuration Register (for Timer).
*/
#define APIC_DIVIDE_CONFIGURATION 0x000003E0
/**
* @}
*/
/**
* The 32-bit EFLAGS register contains a group of status flags, a control flag, and a group of system flags. The status
* flags (bits 0, 2, 4, 6, 7, and 11) of the EFLAGS register indicate the results of arithmetic instructions, such as the
* ADD, SUB, MUL, and DIV instructions.
* The system flags and IOPL field in the EFLAGS register control operating-system or executive operations.
*
* @see Vol1[3.4.3(EFLAGS)] (reference)
*/
typedef union
{
struct
{
/**
* @brief Carry flag
*
* [Bit 0] Set if an arithmetic operation generates a carry or a borrow out of the mostsignificant bit of the result;
* cleared otherwise. This flag indicates an overflow condition for unsigned-integer arithmetic. It is also used in
* multiple-precision arithmetic.
*/
UINT32_t carry_flag : 1;
#define EFLAGS_CARRY_FLAG_BIT 0
#define EFLAGS_CARRY_FLAG_FLAG 0x01
#define EFLAGS_CARRY_FLAG_MASK 0x01
#define EFLAGS_CARRY_FLAG(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Reserved - always 1
*/
UINT32_t read_as_1 : 1;
#define EFLAGS_READ_AS_1_BIT 1
#define EFLAGS_READ_AS_1_FLAG 0x02
#define EFLAGS_READ_AS_1_MASK 0x01
#define EFLAGS_READ_AS_1(_) (((_) >> 1) & 0x01)
/**
* @brief Parity flag
*
* [Bit 2] Set if the least-significant byte of the result contains an even number of 1 bits; cleared otherwise.
*/
UINT32_t parity_flag : 1;
#define EFLAGS_PARITY_FLAG_BIT 2
#define EFLAGS_PARITY_FLAG_FLAG 0x04
#define EFLAGS_PARITY_FLAG_MASK 0x01
#define EFLAGS_PARITY_FLAG(_) (((_) >> 2) & 0x01)
UINT32_t reserved1 : 1;
/**
* @brief Auxiliary Carry flag
*
* [Bit 4] Set if an arithmetic operation generates a carry or a borrow out of bit 3 of the result; cleared otherwise. This
* flag is used in binary-coded decimal (BCD) arithmetic.
*/
UINT32_t auxiliary_carry_flag : 1;
#define EFLAGS_AUXILIARY_CARRY_FLAG_BIT 4
#define EFLAGS_AUXILIARY_CARRY_FLAG_FLAG 0x10
#define EFLAGS_AUXILIARY_CARRY_FLAG_MASK 0x01
#define EFLAGS_AUXILIARY_CARRY_FLAG(_) (((_) >> 4) & 0x01)
UINT32_t reserved2 : 1;
/**
* @brief Zero flag
*
* [Bit 6] Set if the result is zero; cleared otherwise.
*/
UINT32_t zero_flag : 1;
#define EFLAGS_ZERO_FLAG_BIT 6
#define EFLAGS_ZERO_FLAG_FLAG 0x40
#define EFLAGS_ZERO_FLAG_MASK 0x01
#define EFLAGS_ZERO_FLAG(_) (((_) >> 6) & 0x01)
/**
* @brief Sign flag
*
* [Bit 7] Set equal to the most-significant bit of the result, which is the sign bit of a signed integer. (0 indicates a
* positive value and 1 indicates a negative value.)
*/
UINT32_t sign_flag : 1;
#define EFLAGS_SIGN_FLAG_BIT 7
#define EFLAGS_SIGN_FLAG_FLAG 0x80
#define EFLAGS_SIGN_FLAG_MASK 0x01
#define EFLAGS_SIGN_FLAG(_) (((_) >> 7) & 0x01)
/**
* @brief Trap flag
*
* [Bit 8] Set to enable single-step mode for debugging; clear to disable single-step mode.
*/
UINT32_t trap_flag : 1;
#define EFLAGS_TRAP_FLAG_BIT 8
#define EFLAGS_TRAP_FLAG_FLAG 0x100
#define EFLAGS_TRAP_FLAG_MASK 0x01
#define EFLAGS_TRAP_FLAG(_) (((_) >> 8) & 0x01)
/**
* @brief Interrupt enable flag
*
* [Bit 9] Controls the response of the processor to maskable interrupt requests. Set to respond to maskable interrupts;
* cleared to inhibit maskable interrupts.
*/
UINT32_t interrupt_enable_flag : 1;
#define EFLAGS_INTERRUPT_ENABLE_FLAG_BIT 9
#define EFLAGS_INTERRUPT_ENABLE_FLAG_FLAG 0x200
#define EFLAGS_INTERRUPT_ENABLE_FLAG_MASK 0x01
#define EFLAGS_INTERRUPT_ENABLE_FLAG(_) (((_) >> 9) & 0x01)
/**
* @brief Direction flag
*
* [Bit 10] Controls string instructions (MOVS, CMPS, SCAS, LODS, and STOS). Setting the DF flag causes the string
* instructions to auto-decrement (to process strings from high addresses to low addresses). Clearing the DF flag causes
* the string instructions to auto-increment (process strings from low addresses to high addresses).
*/
UINT32_t direction_flag : 1;
#define EFLAGS_DIRECTION_FLAG_BIT 10
#define EFLAGS_DIRECTION_FLAG_FLAG 0x400
#define EFLAGS_DIRECTION_FLAG_MASK 0x01
#define EFLAGS_DIRECTION_FLAG(_) (((_) >> 10) & 0x01)
/**
* @brief Overflow flag
*
* [Bit 11] Set if the integer result is too large a positive number or too small a negative number (excluding the
* sign-bit) to fit in the destination operand; cleared otherwise. This flag indicates an overflow condition for
* signed-integer (two's complement) arithmetic.
*/
UINT32_t overflow_flag : 1;
#define EFLAGS_OVERFLOW_FLAG_BIT 11
#define EFLAGS_OVERFLOW_FLAG_FLAG 0x800
#define EFLAGS_OVERFLOW_FLAG_MASK 0x01
#define EFLAGS_OVERFLOW_FLAG(_) (((_) >> 11) & 0x01)
/**
* @brief I/O privilege level field
*
* [Bits 13:12] Indicates the I/O privilege level of the currently running program or task. The current privilege level
* (CPL) of the currently running program or task must be less than or equal to the I/O privilege level to access the I/O
* address space. The POPF and IRET instructions can modify this field only when operating at a CPL of 0.
*/
UINT32_t io_privilege_level : 2;
#define EFLAGS_IO_PRIVILEGE_LEVEL_BIT 12
#define EFLAGS_IO_PRIVILEGE_LEVEL_FLAG 0x3000
#define EFLAGS_IO_PRIVILEGE_LEVEL_MASK 0x03
#define EFLAGS_IO_PRIVILEGE_LEVEL(_) (((_) >> 12) & 0x03)
/**
* @brief Nested task flag
*
* [Bit 14] Controls the chaining of interrupted and called tasks. Set when the current task is linked to the previously
* executed task; cleared when the current task is not linked to another task.
*/
UINT32_t nested_task_flag : 1;
#define EFLAGS_NESTED_TASK_FLAG_BIT 14
#define EFLAGS_NESTED_TASK_FLAG_FLAG 0x4000
#define EFLAGS_NESTED_TASK_FLAG_MASK 0x01
#define EFLAGS_NESTED_TASK_FLAG(_) (((_) >> 14) & 0x01)
UINT32_t reserved3 : 1;
/**
* @brief Resume flag
*
* [Bit 16] Controls the processor's response to debug exceptions.
*/
UINT32_t resume_flag : 1;
#define EFLAGS_RESUME_FLAG_BIT 16
#define EFLAGS_RESUME_FLAG_FLAG 0x10000
#define EFLAGS_RESUME_FLAG_MASK 0x01
#define EFLAGS_RESUME_FLAG(_) (((_) >> 16) & 0x01)
/**
* @brief Virtual-8086 mode flag
*
* [Bit 17] Set to enable virtual-8086 mode; clear to return to protected mode without virtual-8086 mode semantics.
*/
UINT32_t virtual_8086_mode_flag : 1;
#define EFLAGS_VIRTUAL_8086_MODE_FLAG_BIT 17
#define EFLAGS_VIRTUAL_8086_MODE_FLAG_FLAG 0x20000
#define EFLAGS_VIRTUAL_8086_MODE_FLAG_MASK 0x01
#define EFLAGS_VIRTUAL_8086_MODE_FLAG(_) (((_) >> 17) & 0x01)
/**
* @brief Alignment check (or access control) flag
*
* [Bit 18] If the AM bit is set in the CR0 register, alignment checking of user-mode data accesses is enabled if and only
* if this flag is 1. If the SMAP bit is set in the CR4 register, explicit supervisor-mode data accesses to user-mode pages
* are allowed if and only if this bit is 1.
*
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT32_t alignment_check_flag : 1;
#define EFLAGS_ALIGNMENT_CHECK_FLAG_BIT 18
#define EFLAGS_ALIGNMENT_CHECK_FLAG_FLAG 0x40000
#define EFLAGS_ALIGNMENT_CHECK_FLAG_MASK 0x01
#define EFLAGS_ALIGNMENT_CHECK_FLAG(_) (((_) >> 18) & 0x01)
/**
* @brief Virtual interrupt flag
*
* [Bit 19] Virtual image of the IF flag. Used in conjunction with the VIP flag. (To use this flag and the VIP flag the
* virtual mode extensions are enabled by setting the VME flag in control register CR4.)
*/
UINT32_t virtual_interrupt_flag : 1;
#define EFLAGS_VIRTUAL_INTERRUPT_FLAG_BIT 19
#define EFLAGS_VIRTUAL_INTERRUPT_FLAG_FLAG 0x80000
#define EFLAGS_VIRTUAL_INTERRUPT_FLAG_MASK 0x01
#define EFLAGS_VIRTUAL_INTERRUPT_FLAG(_) (((_) >> 19) & 0x01)
/**
* @brief Virtual interrupt pending flag
*
* [Bit 20] Set to indicate that an interrupt is pending; clear when no interrupt is pending. (Software sets and clears
* this flag; the processor only reads it.) Used in conjunction with the VIF flag.
*/
UINT32_t virtual_interrupt_pending_flag : 1;
#define EFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_BIT 20
#define EFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_FLAG 0x100000
#define EFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_MASK 0x01
#define EFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG(_) (((_) >> 20) & 0x01)
/**
* @brief Identification flag
*
* [Bit 21] The ability of a program to set or clear this flag indicates support for the CPUID instruction.
*/
UINT32_t identification_flag : 1;
#define EFLAGS_IDENTIFICATION_FLAG_BIT 21
#define EFLAGS_IDENTIFICATION_FLAG_FLAG 0x200000
#define EFLAGS_IDENTIFICATION_FLAG_MASK 0x01
#define EFLAGS_IDENTIFICATION_FLAG(_) (((_) >> 21) & 0x01)
UINT32_t reserved4 : 10;
};
UINT32_t flags;
} eflags;
/**
* The 64-bit RFLAGS register contains a group of status flags, a control flag, and a group of system flags in 64-bit mode.
* The upper 32 bits of RFLAGS register is reserved. The lower 32 bits of RFLAGS is the same as EFLAGS.
*
* @see EFLAGS
* @see Vol1[3.4.3.4(RFLAGS Register in 64-Bit Mode)] (reference)
*/
typedef union
{
struct
{
/**
* @brief Carry flag
*
* [Bit 0] See the description in EFLAGS.
*/
UINT64_t carry_flag : 1;
#define RFLAGS_CARRY_FLAG_BIT 0
#define RFLAGS_CARRY_FLAG_FLAG 0x01
#define RFLAGS_CARRY_FLAG_MASK 0x01
#define RFLAGS_CARRY_FLAG(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] Reserved - always 1
*/
UINT64_t read_as_1 : 1;
#define RFLAGS_READ_AS_1_BIT 1
#define RFLAGS_READ_AS_1_FLAG 0x02
#define RFLAGS_READ_AS_1_MASK 0x01
#define RFLAGS_READ_AS_1(_) (((_) >> 1) & 0x01)
/**
* @brief Parity flag
*
* [Bit 2] See the description in EFLAGS.
*/
UINT64_t parity_flag : 1;
#define RFLAGS_PARITY_FLAG_BIT 2
#define RFLAGS_PARITY_FLAG_FLAG 0x04
#define RFLAGS_PARITY_FLAG_MASK 0x01
#define RFLAGS_PARITY_FLAG(_) (((_) >> 2) & 0x01)
UINT64_t reserved1 : 1;
/**
* @brief Auxiliary Carry flag
*
* [Bit 4] See the description in EFLAGS.
*/
UINT64_t auxiliary_carry_flag : 1;
#define RFLAGS_AUXILIARY_CARRY_FLAG_BIT 4
#define RFLAGS_AUXILIARY_CARRY_FLAG_FLAG 0x10
#define RFLAGS_AUXILIARY_CARRY_FLAG_MASK 0x01
#define RFLAGS_AUXILIARY_CARRY_FLAG(_) (((_) >> 4) & 0x01)
UINT64_t reserved2 : 1;
/**
* @brief Zero flag
*
* [Bit 6] See the description in EFLAGS.
*/
UINT64_t zero_flag : 1;
#define RFLAGS_ZERO_FLAG_BIT 6
#define RFLAGS_ZERO_FLAG_FLAG 0x40
#define RFLAGS_ZERO_FLAG_MASK 0x01
#define RFLAGS_ZERO_FLAG(_) (((_) >> 6) & 0x01)
/**
* @brief Sign flag
*
* [Bit 7] See the description in EFLAGS.
*/
UINT64_t sign_flag : 1;
#define RFLAGS_SIGN_FLAG_BIT 7
#define RFLAGS_SIGN_FLAG_FLAG 0x80
#define RFLAGS_SIGN_FLAG_MASK 0x01
#define RFLAGS_SIGN_FLAG(_) (((_) >> 7) & 0x01)
/**
* @brief Trap flag
*
* [Bit 8] See the description in EFLAGS.
*/
UINT64_t trap_flag : 1;
#define RFLAGS_TRAP_FLAG_BIT 8
#define RFLAGS_TRAP_FLAG_FLAG 0x100
#define RFLAGS_TRAP_FLAG_MASK 0x01
#define RFLAGS_TRAP_FLAG(_) (((_) >> 8) & 0x01)
/**
* @brief Interrupt enable flag
*
* [Bit 9] See the description in EFLAGS.
*/
UINT64_t interrupt_enable_flag : 1;
#define RFLAGS_INTERRUPT_ENABLE_FLAG_BIT 9
#define RFLAGS_INTERRUPT_ENABLE_FLAG_FLAG 0x200
#define RFLAGS_INTERRUPT_ENABLE_FLAG_MASK 0x01
#define RFLAGS_INTERRUPT_ENABLE_FLAG(_) (((_) >> 9) & 0x01)
/**
* @brief Direction flag
*
* [Bit 10] See the description in EFLAGS.
*/
UINT64_t direction_flag : 1;
#define RFLAGS_DIRECTION_FLAG_BIT 10
#define RFLAGS_DIRECTION_FLAG_FLAG 0x400
#define RFLAGS_DIRECTION_FLAG_MASK 0x01
#define RFLAGS_DIRECTION_FLAG(_) (((_) >> 10) & 0x01)
/**
* @brief Overflow flag
*
* [Bit 11] See the description in EFLAGS.
*/
UINT64_t overflow_flag : 1;
#define RFLAGS_OVERFLOW_FLAG_BIT 11
#define RFLAGS_OVERFLOW_FLAG_FLAG 0x800
#define RFLAGS_OVERFLOW_FLAG_MASK 0x01
#define RFLAGS_OVERFLOW_FLAG(_) (((_) >> 11) & 0x01)
/**
* @brief I/O privilege level field
*
* [Bits 13:12] See the description in EFLAGS.
*/
UINT64_t io_privilege_level : 2;
#define RFLAGS_IO_PRIVILEGE_LEVEL_BIT 12
#define RFLAGS_IO_PRIVILEGE_LEVEL_FLAG 0x3000
#define RFLAGS_IO_PRIVILEGE_LEVEL_MASK 0x03
#define RFLAGS_IO_PRIVILEGE_LEVEL(_) (((_) >> 12) & 0x03)
/**
* @brief Nested task flag
*
* [Bit 14] See the description in EFLAGS.
*/
UINT64_t nested_task_flag : 1;
#define RFLAGS_NESTED_TASK_FLAG_BIT 14
#define RFLAGS_NESTED_TASK_FLAG_FLAG 0x4000
#define RFLAGS_NESTED_TASK_FLAG_MASK 0x01
#define RFLAGS_NESTED_TASK_FLAG(_) (((_) >> 14) & 0x01)
UINT64_t reserved3 : 1;
/**
* @brief Resume flag
*
* [Bit 16] See the description in EFLAGS.
*/
UINT64_t resume_flag : 1;
#define RFLAGS_RESUME_FLAG_BIT 16
#define RFLAGS_RESUME_FLAG_FLAG 0x10000
#define RFLAGS_RESUME_FLAG_MASK 0x01
#define RFLAGS_RESUME_FLAG(_) (((_) >> 16) & 0x01)
/**
* @brief Virtual-8086 mode flag
*
* [Bit 17] See the description in EFLAGS.
*/
UINT64_t virtual_8086_mode_flag : 1;
#define RFLAGS_VIRTUAL_8086_MODE_FLAG_BIT 17
#define RFLAGS_VIRTUAL_8086_MODE_FLAG_FLAG 0x20000
#define RFLAGS_VIRTUAL_8086_MODE_FLAG_MASK 0x01
#define RFLAGS_VIRTUAL_8086_MODE_FLAG(_) (((_) >> 17) & 0x01)
/**
* @brief Alignment check (or access control) flag
*
* [Bit 18] See the description in EFLAGS.
*
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT64_t alignment_check_flag : 1;
#define RFLAGS_ALIGNMENT_CHECK_FLAG_BIT 18
#define RFLAGS_ALIGNMENT_CHECK_FLAG_FLAG 0x40000
#define RFLAGS_ALIGNMENT_CHECK_FLAG_MASK 0x01
#define RFLAGS_ALIGNMENT_CHECK_FLAG(_) (((_) >> 18) & 0x01)
/**
* @brief Virtual interrupt flag
*
* [Bit 19] See the description in EFLAGS.
*/
UINT64_t virtual_interrupt_flag : 1;
#define RFLAGS_VIRTUAL_INTERRUPT_FLAG_BIT 19
#define RFLAGS_VIRTUAL_INTERRUPT_FLAG_FLAG 0x80000
#define RFLAGS_VIRTUAL_INTERRUPT_FLAG_MASK 0x01
#define RFLAGS_VIRTUAL_INTERRUPT_FLAG(_) (((_) >> 19) & 0x01)
/**
* @brief Virtual interrupt pending flag
*
* [Bit 20] See the description in EFLAGS.
*/
UINT64_t virtual_interrupt_pending_flag : 1;
#define RFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_BIT 20
#define RFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_FLAG 0x100000
#define RFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG_MASK 0x01
#define RFLAGS_VIRTUAL_INTERRUPT_PENDING_FLAG(_) (((_) >> 20) & 0x01)
/**
* @brief Identification flag
*
* [Bit 21] See the description in EFLAGS.
*/
UINT64_t identification_flag : 1;
#define RFLAGS_IDENTIFICATION_FLAG_BIT 21
#define RFLAGS_IDENTIFICATION_FLAG_FLAG 0x200000
#define RFLAGS_IDENTIFICATION_FLAG_MASK 0x01
#define RFLAGS_IDENTIFICATION_FLAG(_) (((_) >> 21) & 0x01)
UINT64_t reserved4 : 42;
};
UINT64_t flags;
} rflags;
/**
* @defgroup exceptions \
* Exceptions
* @{
*/
/**
* @brief Exceptions that can occur when the instruction is executed in protected mode.
* Each exception is given a mnemonic that consists of a pound sign (\#) followed by two letters and an optional error code
* in parentheses. For example, \#GP(0) denotes a general protection exception with an error code of 0
*
* @see Vol2A[3.1.1.13(Protected Mode Exceptions Section)] (reference)
* @see Vol3A[6.3.1(External Interrupts)] (reference)
*/
typedef enum
{
/**
* #DE - Divide Error.
* Source: DIV and IDIV instructions.
* Error Code: No.
*/
divide_error = 0x00000000,
/**
* #DB - Debug.
* Source: Any code or data reference.
* Error Code: No.
*/
debug = 0x00000001,
/**
* Nonmaskable Interrupt.
* Source: Generated externally by asserting the processor's NMI pin or
* through an NMI request set by the I/O APIC to the local APIC.
* Error Code: No.
*/
nmi = 0x00000002,
/**
* #BP - Breakpoint.
* Source: INT3 instruction.
* Error Code: No.
*/
breakpoint = 0x00000003,
/**
* #OF - Overflow.
* Source: INTO instruction.
* Error Code: No.
*/
overflow = 0x00000004,
/**
* #BR - BOUND Range Exceeded.
* Source: BOUND instruction.
* Error Code: No.
*/
bound_range_exceeded = 0x00000005,
/**
* #UD - Invalid Opcode (Undefined Opcode).
* Source: UD instruction or reserved opcode.
* Error Code: No.
*/
invalid_opcode = 0x00000006,
/**
* #NM - Device Not Available (No Math Coprocessor).
* Source: Floating-point or WAIT/FWAIT instruction.
* Error Code: No.
*/
device_not_available = 0x00000007,
/**
* #DF - Double Fault.
* Source: Any instruction that can generate an exception, an NMI, or an INTR.
* Error Code: Yes (zero).
*/
double_fault = 0x00000008,
/**
* #\## - Coprocessor Segment Overrun (reserved).
* Source: Floating-point instruction.
* Error Code: No.
*
* @note Processors after the Intel386 processor do not generate this exception.
*/
coprocessor_segment_overrun = 0x00000009,
/**
* #TS - Invalid TSS.
* Source: Task switch or TSS access.
* Error Code: Yes.
*/
invalid_tss = 0x0000000A,
/**
* #NP - Segment Not Present.
* Source: Loading segment registers or accessing system segments.
* Error Code: Yes.
*/
segment_not_present = 0x0000000B,
/**
* #SS - Stack Segment Fault.
* Source: Stack operations and SS register loads.
* Error Code: Yes.
*/
stack_segment_fault = 0x0000000C,
/**
* #GP - General Protection.
* Source: Any memory reference and other protection checks.
* Error Code: Yes.
*/
general_protection = 0x0000000D,
/**
* #PF - Page Fault.
* Source: Any memory reference.
* Error Code: Yes.
*/
page_fault = 0x0000000E,
/**
* #MF - Floating-Point Error (Math Fault).
* Source: Floating-point or WAIT/FWAIT instruction.
* Error Code: No.
*/
x87_floating_point_error = 0x00000010,
/**
* #AC - Alignment Check.
* Source: Any data reference in memory.
* Error Code: Yes.
*/
alignment_check = 0x00000011,
/**
* #MC - Machine Check.
* Source: Model dependent machine check errors.
* Error Code: No.
*/
machine_check = 0x00000012,
/**
* #XM - SIMD Floating-Point Numeric Error.
* Source: SSE/SSE2/SSE3 floating-point instructions.
* Error Code: No.
*/
simd_floating_point_error = 0x00000013,
/**
* #VE - Virtualization Exception.
* Source: EPT violations.
* Error Code: No.
*/
virtualization_exception = 0x00000014,
} exception_vector;
/**
* @brief When an exception condition is related to a specific segment selector or IDT vector, the processor pushes an
* error code onto the stack of the exception handler (whether it is a procedure or task). The error code resembles a
* segment selector; however, instead of a TI flag and RPL field, the error code contains 3 different flags
*
* @see Vol3A[6.13(ERROR CODE)] (reference)
*/
typedef union
{
struct
{
/**
* [Bit 0] When set, indicates that the exception occurred during delivery of an event external to the program, such as an
* interrupt or an earlier exception. The bit is cleared if the exception occurred during delivery of a software interrupt
* (INT n, INT3, or INTO).
*/
UINT32_t external_event : 1;
#define EXCEPTION_ERROR_CODE_EXTERNAL_EVENT_BIT 0
#define EXCEPTION_ERROR_CODE_EXTERNAL_EVENT_FLAG 0x01
#define EXCEPTION_ERROR_CODE_EXTERNAL_EVENT_MASK 0x01
#define EXCEPTION_ERROR_CODE_EXTERNAL_EVENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] When set, indicates that the index portion of the error code refers to a gate descriptor in the IDT; when clear,
* indicates that the index refers to a descriptor in the GDT or the current LDT.
*/
UINT32_t descriptor_location : 1;
#define EXCEPTION_ERROR_CODE_DESCRIPTOR_LOCATION_BIT 1
#define EXCEPTION_ERROR_CODE_DESCRIPTOR_LOCATION_FLAG 0x02
#define EXCEPTION_ERROR_CODE_DESCRIPTOR_LOCATION_MASK 0x01
#define EXCEPTION_ERROR_CODE_DESCRIPTOR_LOCATION(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] Only used when the IDT flag is clear. When set, the TI flag indicates that the index portion of the error code
* refers to a segment or gate descriptor in the LDT; when clear, it indicates that the index refers to a descriptor in the
* current GDT.
*/
UINT32_t gdt_ldt : 1;
#define EXCEPTION_ERROR_CODE_GDT_LDT_BIT 2
#define EXCEPTION_ERROR_CODE_GDT_LDT_FLAG 0x04
#define EXCEPTION_ERROR_CODE_GDT_LDT_MASK 0x01
#define EXCEPTION_ERROR_CODE_GDT_LDT(_) (((_) >> 2) & 0x01)
/**
* [Bits 15:3] The segment selector index field provides an index into the IDT, GDT, or current LDT to the segment or gate
* selector being referenced by the error code. In some cases the error code is null (all bits are clear except possibly
* EXT). A null error code indicates that the error was not caused by a reference to a specific segment or that a null
* segment selector was referenced in an operation.
*
* @note The format of the error code is different for page-fault exceptions (#PF).
*/
UINT32_t index : 13;
#define EXCEPTION_ERROR_CODE_INDEX_BIT 3
#define EXCEPTION_ERROR_CODE_INDEX_FLAG 0xFFF8
#define EXCEPTION_ERROR_CODE_INDEX_MASK 0x1FFF
#define EXCEPTION_ERROR_CODE_INDEX(_) (((_) >> 3) & 0x1FFF)
UINT32_t reserved1 : 16;
};
UINT32_t flags;
} exception_error_code;
/**
* @brief Page fault exception
*
* @see Vol3A[4.7(PAGE-FAULT EXCEPTIONS)] (reference)
*/
typedef union
{
struct
{
/**
* [Bit 0] This flag is 0 if there is no translation for the linear address because the P flag was 0 in one of the
* pagingstructure entries used to translate that address.
*/
UINT32_t present : 1;
#define PAGE_FAULT_EXCEPTION_PRESENT_BIT 0
#define PAGE_FAULT_EXCEPTION_PRESENT_FLAG 0x01
#define PAGE_FAULT_EXCEPTION_PRESENT_MASK 0x01
#define PAGE_FAULT_EXCEPTION_PRESENT(_) (((_) >> 0) & 0x01)
/**
* [Bit 1] If the access causing the page-fault exception was a write, this flag is 1; otherwise, it is 0. This flag
* describes the access causing the page-fault exception, not the access rights specified by paging.
*/
UINT32_t write : 1;
#define PAGE_FAULT_EXCEPTION_WRITE_BIT 1
#define PAGE_FAULT_EXCEPTION_WRITE_FLAG 0x02
#define PAGE_FAULT_EXCEPTION_WRITE_MASK 0x01
#define PAGE_FAULT_EXCEPTION_WRITE(_) (((_) >> 1) & 0x01)
/**
* [Bit 2] If a user-mode access caused the page-fault exception, this flag is 1; it is 0 if a supervisor-mode access did
* so. This flag describes the access causing the page-fault exception, not the access rights specified by paging.
*
* @see Vol3A[4.6(ACCESS RIGHTS)]
*/
UINT32_t user_mode_access : 1;
#define PAGE_FAULT_EXCEPTION_USER_MODE_ACCESS_BIT 2
#define PAGE_FAULT_EXCEPTION_USER_MODE_ACCESS_FLAG 0x04
#define PAGE_FAULT_EXCEPTION_USER_MODE_ACCESS_MASK 0x01
#define PAGE_FAULT_EXCEPTION_USER_MODE_ACCESS(_) (((_) >> 2) & 0x01)
/**
* [Bit 3] This flag is 1 if there is no translation for the linear address because a reserved bit was set in one of the
* pagingstructure entries used to translate that address. (Because reserved bits are not checked in a paging-structure
* entry whose P flag is 0, bit 3 of the error code can be set only if bit 0 is also set). Bits reserved in the
* paging-structure entries are reserved for future functionality. Software developers should be aware that such bits may
* be used in the future and that a paging-structure entry that causes a page-fault exception on one processor might not do
* so in the future.
*/
UINT32_t reserved_bit_violation : 1;
#define PAGE_FAULT_EXCEPTION_RESERVED_BIT_VIOLATION_BIT 3
#define PAGE_FAULT_EXCEPTION_RESERVED_BIT_VIOLATION_FLAG 0x08
#define PAGE_FAULT_EXCEPTION_RESERVED_BIT_VIOLATION_MASK 0x01
#define PAGE_FAULT_EXCEPTION_RESERVED_BIT_VIOLATION(_) (((_) >> 3) & 0x01)
/**
* [Bit 4] This flag is 1 if (1) the access causing the page-fault exception was an instruction fetch; and (2) either (a)
* CR4.SMEP = 1; or (b) both (i) CR4.PAE = 1 (either PAE paging or 4-level paging is in use); and (ii) IA32_EFER.NXE = 1.
* Otherwise, the flag is 0. This flag describes the access causing the page-fault exception, not the access rights
* specified by paging.
*/
UINT32_t execute : 1;
#define PAGE_FAULT_EXCEPTION_EXECUTE_BIT 4
#define PAGE_FAULT_EXCEPTION_EXECUTE_FLAG 0x10
#define PAGE_FAULT_EXCEPTION_EXECUTE_MASK 0x01
#define PAGE_FAULT_EXCEPTION_EXECUTE(_) (((_) >> 4) & 0x01)
/**
* [Bit 5] This flag is 1 if (1) IA32_EFER.LMA = CR4.PKE = 1; (2) the access causing the page-fault exception was a data
* access; (3) the linear address was a user-mode address with protection key i; and (5) the PKRU register is such that
* either (a) ADi = 1; or (b) the following all hold: (i) WDi = 1; (ii) the access is a write access; and (iii) either
* CR0.WP = 1 or the access causing the page-fault exception was a user-mode access.
*
* @see Vol3A[4.6.2(Protection Keys)]
*/
UINT32_t protection_key_violation : 1;
#define PAGE_FAULT_EXCEPTION_PROTECTION_KEY_VIOLATION_BIT 5
#define PAGE_FAULT_EXCEPTION_PROTECTION_KEY_VIOLATION_FLAG 0x20
#define PAGE_FAULT_EXCEPTION_PROTECTION_KEY_VIOLATION_MASK 0x01
#define PAGE_FAULT_EXCEPTION_PROTECTION_KEY_VIOLATION(_) (((_) >> 5) & 0x01)
UINT32_t reserved1 : 9;
/**
* [Bit 15] This flag is 1 if the exception is unrelated to paging and resulted from violation of SGX-specific
* access-control requirements. Because such a violation can occur only if there is no ordinary page fault, this flag is
* set only if the P flag (bit 0) is 1 and the RSVD flag (bit 3) and the PK flag (bit 5) are both 0.
*/
UINT32_t sgx : 1;
#define PAGE_FAULT_EXCEPTION_SGX_BIT 15
#define PAGE_FAULT_EXCEPTION_SGX_FLAG 0x8000
#define PAGE_FAULT_EXCEPTION_SGX_MASK 0x01
#define PAGE_FAULT_EXCEPTION_SGX(_) (((_) >> 15) & 0x01)
UINT32_t reserved2 : 16;
};
UINT32_t flags;
} page_fault_exception;
/**
* @}
*/
/**
* @defgroup memory_type \
* Memory caching type
*
* The processor allows any area of system memory to be cached in the L1, L2, and L3 caches. In individual pages or regions
* of system memory, it allows the type of caching (also called memory type) to be specified.
*
* @see Vol3A[11.11(MEMORY TYPE RANGE REGISTERS (MTRRS))]
* @see Vol3A[11.5(CACHE CONTROL)]
* @see Vol3A[11.3(METHODS OF CACHING AVAILABLE)] (reference)
* @{
*/
/**
* @brief Strong Uncacheable (UC)
*
* System memory locations are not cached. All reads and writes appear on the system bus and are executed in program order
* without reordering. No speculative memory accesses, pagetable walks, or prefetches of speculated branch targets are
* made. This type of cache-control is useful for memory-mapped I/O devices. When used with normal RAM, it greatly reduces
* processor performance.
*/
#define MEMORY_TYPE_UNCACHEABLE 0x00000000
/**
* @brief Write Combining (WC)
*
* System memory locations are not cached (as with uncacheable memory) and coherency is not enforced by the processor's bus
* coherency protocol. Speculative reads are allowed. Writes may be delayed and combined in the write combining buffer (WC
* buffer) to reduce memory accesses. If the WC buffer is partially filled, the writes may be delayed until the next
* occurrence of a serializing event; such as, an SFENCE or MFENCE instruction, CPUID execution, a read or write to
* uncached memory, an interrupt occurrence, or a LOCK instruction execution. This type of cache-control is appropriate for
* video frame buffers, where the order of writes is unimportant as long as the writes update memory so they can be seen on
* the graphics display. This memory type is available in the Pentium Pro and Pentium II processors by programming the
* MTRRs; or in processor families starting from the Pentium III processors by programming the MTRRs or by selecting it
* through the PAT.
*
* @see Vol3A[11.3.1(Buffering of Write Combining Memory Locations)]
*/
#define MEMORY_TYPE_WRITE_COMBINING 0x00000001
/**
* @brief Write-through (WT)
*
* Writes and reads to and from system memory are cached. Reads come from cache lines on cache hits; read misses cause
* cache fills. Speculative reads are allowed. All writes are written to a cache line (when possible) and through to system
* memory. When writing through to memory, invalid cache lines are never filled, and valid cache lines are either filled or
* invalidated. Write combining is allowed. This type of cache-control is appropriate for frame buffers or when there are
* devices on the system bus that access system memory, but do not perform snooping of memory accesses. It enforces
* coherency between caches in the processors and system memory.
*/
#define MEMORY_TYPE_WRITE_THROUGH 0x00000004
/**
* @brief Write protected (WP)
*
* Reads come from cache lines when possible, and read misses cause cache fills. Writes are propagated to the system bus
* and cause corresponding cache lines on all processors on the bus to be invalidated. Speculative reads are allowed. This
* memory type is available in processor families starting from the P6 family processors by programming the MTRRs.
*/
#define MEMORY_TYPE_WRITE_PROTECTED 0x00000005
/**
* @brief Write-back (WB)
*
* Writes and reads to and from system memory are cached. Reads come from cache lines on cache hits; read misses cause
* cache fills. Speculative reads are allowed. Write misses cause cache line fills (in processor families starting with the
* P6 family processors), and writes are performed entirely in the cache, when possible. Write combining is allowed. The
* write-back memory type reduces bus traffic by eliminating many unnecessary writes to system memory. Writes to a cache
* line are not immediately forwarded to system memory; instead, they are accumulated in the cache. The modified cache
* lines are written to system memory later, when a write-back operation is performed. Write-back operations are triggered
* when cache lines need to be deallocated, such as when new cache lines are being allocated in a cache that is already
* full. They also are triggered by the mechanisms used to maintain cache consistency. This type of cache-control provides
* the best performance, but it requires that all devices that access system memory on the system bus be able to snoop
* memory accesses to insure system memory and cache coherency.
*/
#define MEMORY_TYPE_WRITE_BACK 0x00000006
/**
* @brief Uncacheable (UC-)
*
* Has same characteristics as the strong uncacheable (UC) memory type, except that this memory type can be overridden by
* programming the MTRRs for the WC memory type. This memory type is available in processor families starting from the
* Pentium III processors and can only be selected through the PAT.
*/
#define MEMORY_TYPE_UNCACHEABLE_MINUS 0x00000007
#define MEMORY_TYPE_INVALID 0x000000FF
/**
* @}
*/
/**
* @}
*/