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Theodosius/Examples/Theodosius-Usermode/asmjit/x86/x86compiler.h

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// AsmJit - Machine code generation for C++
//
// * Official AsmJit Home Page: https://asmjit.com
// * Official Github Repository: https://github.com/asmjit/asmjit
//
// Copyright (c) 2008-2020 The AsmJit Authors
//
// This software is provided 'as-is', without any express or implied
// warranty. In no event will the authors be held liable for any damages
// arising from the use of this software.
//
// Permission is granted to anyone to use this software for any purpose,
// including commercial applications, and to alter it and redistribute it
// freely, subject to the following restrictions:
//
// 1. The origin of this software must not be misrepresented; you must not
// claim that you wrote the original software. If you use this software
// in a product, an acknowledgment in the product documentation would be
// appreciated but is not required.
// 2. Altered source versions must be plainly marked as such, and must not be
// misrepresented as being the original software.
// 3. This notice may not be removed or altered from any source distribution.
#ifndef ASMJIT_X86_X86COMPILER_H_INCLUDED
#define ASMJIT_X86_X86COMPILER_H_INCLUDED
#include "../core/api-config.h"
#ifndef ASMJIT_NO_COMPILER
#include "../core/compiler.h"
#include "../core/datatypes.h"
#include "../core/type.h"
#include "../x86/x86emitter.h"
ASMJIT_BEGIN_SUB_NAMESPACE(x86)
//! \addtogroup asmjit_x86
//! \{
// ============================================================================
// [asmjit::x86::Compiler]
// ============================================================================
//! X86/X64 compiler implementation.
//!
//! ### Compiler Basics
//!
//! The first \ref x86::Compiler example shows how to generate a function that
//! simply returns an integer value. It's an analogy to the first Assembler example:
//!
//! ```
//! #include <asmjit/x86.h>
//! #include <stdio.h>
//!
//! using namespace asmjit;
//!
//! // Signature of the generated function.
//! typedef int (*Func)(void);
//!
//! int main() {
//! JitRuntime rt; // Runtime specialized for JIT code execution.
//! CodeHolder code; // Holds code and relocation information.
//!
//! code.init(rt.environment()); // Initialize code to match the JIT environment.
//! x86::Compiler cc(&code); // Create and attach x86::Compiler to code.
//!
//! cc.addFunc(FuncSignatureT<int>());// Begin a function of `int fn(void)` signature.
//!
//! x86::Gp vReg = cc.newGpd(); // Create a 32-bit general purpose register.
//! cc.mov(vReg, 1); // Move one to our virtual register `vReg`.
//! cc.ret(vReg); // Return `vReg` from the function.
//!
//! cc.endFunc(); // End of the function body.
//! cc.finalize(); // Translate and assemble the whole 'cc' content.
//! // ----> x86::Compiler is no longer needed from here and can be destroyed <----
//!
//! Func fn;
//! Error err = rt.add(&fn, &code); // Add the generated code to the runtime.
//! if (err) return 1; // Handle a possible error returned by AsmJit.
//! // ----> CodeHolder is no longer needed from here and can be destroyed <----
//!
//! int result = fn(); // Execute the generated code.
//! printf("%d\n", result); // Print the resulting "1".
//!
//! rt.release(fn); // Explicitly remove the function from the runtime.
//! return 0;
//! }
//! ```
//!
//! The \ref BaseCompiler::addFunc() and \ref BaseCompiler::endFunc() functions
//! are used to define the function and its end. Both must be called per function,
//! but the body doesn't have to be generated in sequence. An example of generating
//! two functions will be shown later. The next example shows more complicated code
//! that contain a loop and generates a simple memory copy function that uses
//! `uint32_t` items:
//!
//! ```
//! #include <asmjit/x86.h>
//! #include <stdio.h>
//!
//! using namespace asmjit;
//!
//! // Signature of the generated function.
//! typedef void (*MemCpy32)(uint32_t* dst, const uint32_t* src, size_t count);
//!
//! int main() {
//! JitRuntime rt; // Runtime specialized for JIT code execution.
//! CodeHolder code; // Holds code and relocation information.
//!
//! code.init(rt.environment()); // Initialize code to match the JIT environment.
//! x86::Compiler cc(&code); // Create and attach x86::Compiler to code.
//!
//! cc.addFunc( // Begin the function of the following signature:
//! FuncSignatureT<void, // Return value - void (no return value).
//! uint32_t*, // 1st argument - uint32_t* (machine reg-size).
//! const uint32_t*, // 2nd argument - uint32_t* (machine reg-size).
//! size_t>()); // 3rd argument - size_t (machine reg-size).
//!
//! Label L_Loop = cc.newLabel(); // Start of the loop.
//! Label L_Exit = cc.newLabel(); // Used to exit early.
//!
//! x86::Gp dst = cc.newIntPtr("dst");// Create `dst` register (destination pointer).
//! x86::Gp src = cc.newIntPtr("src");// Create `src` register (source pointer).
//! x86::Gp i = cc.newUIntPtr("i"); // Create `i` register (loop counter).
//!
//! cc.setArg(0, dst); // Assign `dst` argument.
//! cc.setArg(1, src); // Assign `src` argument.
//! cc.setArg(2, i); // Assign `i` argument.
//!
//! cc.test(i, i); // Early exit if length is zero.
//! cc.jz(L_Exit);
//!
//! cc.bind(L_Loop); // Bind the beginning of the loop here.
//!
//! x86::Gp tmp = cc.newInt32("tmp"); // Copy a single dword (4 bytes).
//! cc.mov(tmp, x86::dword_ptr(src)); // Load DWORD from [src] address.
//! cc.mov(x86::dword_ptr(dst), tmp); // Store DWORD to [dst] address.
//!
//! cc.add(src, 4); // Increment `src`.
//! cc.add(dst, 4); // Increment `dst`.
//!
//! cc.dec(i); // Loop until `i` is non-zero.
//! cc.jnz(L_Loop);
//!
//! cc.bind(L_Exit); // Label used by early exit.
//! cc.endFunc(); // End of the function body.
//!
//! cc.finalize(); // Translate and assemble the whole 'cc' content.
//! // ----> x86::Compiler is no longer needed from here and can be destroyed <----
//!
//! // Add the generated code to the runtime.
//! MemCpy32 memcpy32;
//! Error err = rt.add(&memcpy32, &code);
//!
//! // Handle a possible error returned by AsmJit.
//! if (err)
//! return 1;
//! // ----> CodeHolder is no longer needed from here and can be destroyed <----
//!
//! // Test the generated code.
//! uint32_t input[6] = { 1, 2, 3, 5, 8, 13 };
//! uint32_t output[6];
//! memcpy32(output, input, 6);
//!
//! for (uint32_t i = 0; i < 6; i++)
//! printf("%d\n", output[i]);
//!
//! rt.release(memcpy32);
//! return 0;
//! }
//! ```
//!
//! ### Recursive Functions
//!
//! It's possible to create more functions by using the same \ref x86::Compiler
//! instance and make links between them. In such case it's important to keep
//! the pointer to \ref FuncNode.
//!
//! The example below creates a simple Fibonacci function that calls itself recursively:
//!
//! ```
//! #include <asmjit/x86.h>
//! #include <stdio.h>
//!
//! using namespace asmjit;
//!
//! // Signature of the generated function.
//! typedef uint32_t (*Fibonacci)(uint32_t x);
//!
//! int main() {
//! JitRuntime rt; // Runtime specialized for JIT code execution.
//! CodeHolder code; // Holds code and relocation information.
//!
//! code.init(rt.environment()); // Initialize code to match the JIT environment.
//! x86::Compiler cc(&code); // Create and attach x86::Compiler to code.
//!
//! FuncNode* func = cc.addFunc( // Begin of the Fibonacci function, addFunc()
//! FuncSignatureT<int, int>()); // Returns a pointer to the FuncNode node.
//!
//! Label L_Exit = cc.newLabel() // Exit label.
//! x86::Gp x = cc.newU32(); // Function x argument.
//! x86::Gp y = cc.newU32(); // Temporary.
//!
//! cc.setArg(0, x);
//!
//! cc.cmp(x, 3); // Return x if less than 3.
//! cc.jb(L_Exit);
//!
//! cc.mov(y, x); // Make copy of the original x.
//! cc.dec(x); // Decrease x.
//!
//! InvokeNode* invokeNode; // Function invocation:
//! cc.invoke(&invokeNode, // - InvokeNode (output).
//! func->label(), // - Function address or Label.
//! FuncSignatureT<int, int>()); // - Function signature.
//!
//! invokeNode->setArg(0, x); // Assign x as the first argument.
//! invokeNode->setRet(0, x); // Assign x as a return value as well.
//!
//! cc.add(x, y); // Combine the return value with y.
//!
//! cc.bind(L_Exit);
//! cc.ret(x); // Return x.
//! cc.endFunc(); // End of the function body.
//!
//! cc.finalize(); // Translate and assemble the whole 'cc' content.
//! // ----> x86::Compiler is no longer needed from here and can be destroyed <----
//!
//! Fibonacci fib;
//! Error err = rt.add(&fib, &code); // Add the generated code to the runtime.
//! if (err) return 1; // Handle a possible error returned by AsmJit.
//! // ----> CodeHolder is no longer needed from here and can be destroyed <----
//!
//! // Test the generated code.
//! printf("Fib(%u) -> %u\n", 8, fib(8));
//!
//! rt.release(fib);
//! return 0;
//! }
//! ```
//!
//! ### Stack Management
//!
//! Function's stack-frame is managed automatically, which is used by the register allocator to spill virtual registers. It also provides an interface to allocate user-defined block of the stack, which can be used as a temporary storage by the generated function. In the following example a stack of 256 bytes size is allocated, filled by bytes starting from 0 to 255 and then iterated again to sum all the values.
//!
//! ```
//! #include <asmjit/x86.h>
//! #include <stdio.h>
//!
//! using namespace asmjit;
//!
//! // Signature of the generated function.
//! typedef int (*Func)(void);
//!
//! int main() {
//! JitRuntime rt; // Runtime specialized for JIT code execution.
//! CodeHolder code; // Holds code and relocation information.
//!
//! code.init(rt.environment()); // Initialize code to match the JIT environment.
//! x86::Compiler cc(&code); // Create and attach x86::Compiler to code.
//!
//! cc.addFunc(FuncSignatureT<int>());// Create a function that returns int.
//!
//! x86::Gp p = cc.newIntPtr("p");
//! x86::Gp i = cc.newIntPtr("i");
//!
//! // Allocate 256 bytes on the stack aligned to 4 bytes.
//! x86::Mem stack = cc.newStack(256, 4);
//!
//! x86::Mem stackIdx(stack); // Copy of stack with i added.
//! stackIdx.setIndex(i); // stackIdx <- stack[i].
//! stackIdx.setSize(1); // stackIdx <- byte ptr stack[i].
//!
//! // Load a stack address to `p`. This step is purely optional and shows
//! // that `lea` is useful to load a memory operands address (even absolute)
//! // to a general purpose register.
//! cc.lea(p, stack);
//!
//! // Clear i (xor is a C++ keyword, hence 'xor_' is used instead).
//! cc.xor_(i, i);
//!
//! Label L1 = cc.newLabel();
//! Label L2 = cc.newLabel();
//!
//! cc.bind(L1); // First loop, fill the stack.
//! cc.mov(stackIdx, i.r8()); // stack[i] = uint8_t(i).
//!
//! cc.inc(i); // i++;
//! cc.cmp(i, 256); // if (i < 256)
//! cc.jb(L1); // goto L1;
//!
//! // Second loop, sum all bytes stored in `stack`.
//! x86::Gp sum = cc.newI32("sum");
//! x86::Gp val = cc.newI32("val");
//!
//! cc.xor_(i, i);
//! cc.xor_(sum, sum);
//!
//! cc.bind(L2);
//!
//! cc.movzx(val, stackIdx); // val = uint32_t(stack[i]);
//! cc.add(sum, val); // sum += val;
//!
//! cc.inc(i); // i++;
//! cc.cmp(i, 256); // if (i < 256)
//! cc.jb(L2); // goto L2;
//!
//! cc.ret(sum); // Return the `sum` of all values.
//! cc.endFunc(); // End of the function body.
//!
//! cc.finalize(); // Translate and assemble the whole 'cc' content.
//! // ----> x86::Compiler is no longer needed from here and can be destroyed <----
//!
//! Func func;
//! Error err = rt.add(&func, &code); // Add the generated code to the runtime.
//! if (err) return 1; // Handle a possible error returned by AsmJit.
//! // ----> CodeHolder is no longer needed from here and can be destroyed <----
//!
//! printf("Func() -> %d\n", func()); // Test the generated code.
//!
//! rt.release(func);
//! return 0;
//! }
//! ```
//!
//! ### Constant Pool
//!
//! Compiler provides two constant pools for a general purpose code generation:
//!
//! - Local constant pool - Part of \ref FuncNode, can be only used by a
//! single function and added after the function epilog sequence (after
//! `ret` instruction).
//!
//! - Global constant pool - Part of \ref BaseCompiler, flushed at the end
//! of the generated code by \ref BaseEmitter::finalize().
//!
//! The example below illustrates how a built-in constant pool can be used:
//!
//! ```
//! #include <asmjit/x86.h>
//!
//! using namespace asmjit;
//!
//! static void exampleUseOfConstPool(x86::Compiler& cc) {
//! cc.addFunc(FuncSignatureT<int>());
//!
//! x86::Gp v0 = cc.newGpd("v0");
//! x86::Gp v1 = cc.newGpd("v1");
//!
//! x86::Mem c0 = cc.newInt32Const(ConstPool::kScopeLocal, 200);
//! x86::Mem c1 = cc.newInt32Const(ConstPool::kScopeLocal, 33);
//!
//! cc.mov(v0, c0);
//! cc.mov(v1, c1);
//! cc.add(v0, v1);
//!
//! cc.ret(v0);
//! cc.endFunc();
//! }
//! ```
//!
//! ### Jump Tables
//!
//! x86::Compiler supports `jmp` instruction with reg/mem operand, which is a
//! commonly used pattern to implement indirect jumps within a function, for
//! example to implement `switch()` statement in a programming languages. By
//! default AsmJit assumes that every basic block can be a possible jump
//! target as it's unable to deduce targets from instruction's operands. This
//! is a very pessimistic default that should be avoided if possible as it's
//! costly and very unfriendly to liveness analysis and register allocation.
//!
//! Instead of relying on such pessimistic default behavior, let's use \ref
//! JumpAnnotation to annotate a jump where all targets are known:
//!
//! ```
//! #include <asmjit/x86.h>
//!
//! using namespace asmjit;
//!
//! static void exampleUseOfIndirectJump(x86::Compiler& cc) {
//! cc.addFunc(FuncSignatureT<float, float, float, uint32_t>(CallConv::kIdHost));
//!
//! // Function arguments
//! x86::Xmm a = cc.newXmmSs("a");
//! x86::Xmm b = cc.newXmmSs("b");
//! x86::Gp op = cc.newUInt32("op");
//!
//! x86::Gp target = cc.newIntPtr("target");
//! x86::Gp offset = cc.newIntPtr("offset");
//!
//! Label L_Table = cc.newLabel();
//! Label L_Add = cc.newLabel();
//! Label L_Sub = cc.newLabel();
//! Label L_Mul = cc.newLabel();
//! Label L_Div = cc.newLabel();
//! Label L_End = cc.newLabel();
//!
//! cc.setArg(0, a);
//! cc.setArg(1, b);
//! cc.setArg(2, op);
//!
//! // Jump annotation is a building block that allows to annotate all
//! // possible targets where `jmp()` can jump. It then drives the CFG
//! // contruction and liveness analysis, which impacts register allocation.
//! JumpAnnotation* annotation = cc.newJumpAnnotation();
//! annotation->addLabel(L_Add);
//! annotation->addLabel(L_Sub);
//! annotation->addLabel(L_Mul);
//! annotation->addLabel(L_Div);
//!
//! // Most likely not the common indirect jump approach, but it
//! // doesn't really matter how final address is calculated. The
//! // most important path using JumpAnnotation with `jmp()`.
//! cc.lea(offset, x86::ptr(L_Table));
//! if (cc.is64Bit())
//! cc.movsxd(target, x86::dword_ptr(offset, op.cloneAs(offset), 2));
//! else
//! cc.mov(target, x86::dword_ptr(offset, op.cloneAs(offset), 2));
//! cc.add(target, offset);
//! cc.jmp(target, annotation);
//!
//! // Acts like a switch() statement in C.
//! cc.bind(L_Add);
//! cc.addss(a, b);
//! cc.jmp(L_End);
//!
//! cc.bind(L_Sub);
//! cc.subss(a, b);
//! cc.jmp(L_End);
//!
//! cc.bind(L_Mul);
//! cc.mulss(a, b);
//! cc.jmp(L_End);
//!
//! cc.bind(L_Div);
//! cc.divss(a, b);
//!
//! cc.bind(L_End);
//! cc.ret(a);
//!
//! cc.endFunc();
//!
//! // Relative int32_t offsets of `L_XXX - L_Table`.
//! cc.bind(L_Table);
//! cc.embedLabelDelta(L_Add, L_Table, 4);
//! cc.embedLabelDelta(L_Sub, L_Table, 4);
//! cc.embedLabelDelta(L_Mul, L_Table, 4);
//! cc.embedLabelDelta(L_Div, L_Table, 4);
//! }
//! ```
class ASMJIT_VIRTAPI Compiler
: public BaseCompiler,
public EmitterExplicitT<Compiler> {
public:
ASMJIT_NONCOPYABLE(Compiler)
typedef BaseCompiler Base;
//! \name Construction & Destruction
//! \{
ASMJIT_API explicit Compiler(CodeHolder* code = nullptr) noexcept;
ASMJIT_API virtual ~Compiler() noexcept;
//! \}
//! \name Virtual Registers
//! \{
#ifndef ASMJIT_NO_LOGGING
# define ASMJIT_NEW_REG_FMT(OUT, PARAM, FORMAT, ARGS) \
_newRegFmt(&OUT, PARAM, FORMAT, ARGS)
#else
# define ASMJIT_NEW_REG_FMT(OUT, PARAM, FORMAT, ARGS) \
DebugUtils::unused(FORMAT); \
DebugUtils::unused(std::forward<Args>(args)...); \
_newReg(&OUT, PARAM)
#endif
#define ASMJIT_NEW_REG_CUSTOM(FUNC, REG) \
inline REG FUNC(uint32_t typeId) { \
REG reg(Globals::NoInit); \
_newReg(&reg, typeId); \
return reg; \
} \
\
template<typename... Args> \
inline REG FUNC(uint32_t typeId, const char* fmt, Args&&... args) { \
REG reg(Globals::NoInit); \
ASMJIT_NEW_REG_FMT(reg, typeId, fmt, std::forward<Args>(args)...); \
return reg; \
}
#define ASMJIT_NEW_REG_TYPED(FUNC, REG, TYPE_ID) \
inline REG FUNC() { \
REG reg(Globals::NoInit); \
_newReg(&reg, TYPE_ID); \
return reg; \
} \
\
template<typename... Args> \
inline REG FUNC(const char* fmt, Args&&... args) { \
REG reg(Globals::NoInit); \
ASMJIT_NEW_REG_FMT(reg, TYPE_ID, fmt, std::forward<Args>(args)...); \
return reg; \
}
template<typename RegT>
inline RegT newSimilarReg(const RegT& ref) {
RegT reg(Globals::NoInit);
_newReg(reg, ref);
return reg;
}
template<typename RegT, typename... Args>
inline RegT newSimilarReg(const RegT& ref, const char* fmt, Args&&... args) {
RegT reg(Globals::NoInit);
ASMJIT_NEW_REG_FMT(reg, ref, fmt, std::forward<Args>(args)...);
return reg;
}
ASMJIT_NEW_REG_CUSTOM(newReg , Reg )
ASMJIT_NEW_REG_CUSTOM(newGp , Gp )
ASMJIT_NEW_REG_CUSTOM(newVec , Vec )
ASMJIT_NEW_REG_CUSTOM(newK , KReg)
ASMJIT_NEW_REG_TYPED(newI8 , Gp , Type::kIdI8 )
ASMJIT_NEW_REG_TYPED(newU8 , Gp , Type::kIdU8 )
ASMJIT_NEW_REG_TYPED(newI16 , Gp , Type::kIdI16 )
ASMJIT_NEW_REG_TYPED(newU16 , Gp , Type::kIdU16 )
ASMJIT_NEW_REG_TYPED(newI32 , Gp , Type::kIdI32 )
ASMJIT_NEW_REG_TYPED(newU32 , Gp , Type::kIdU32 )
ASMJIT_NEW_REG_TYPED(newI64 , Gp , Type::kIdI64 )
ASMJIT_NEW_REG_TYPED(newU64 , Gp , Type::kIdU64 )
ASMJIT_NEW_REG_TYPED(newInt8 , Gp , Type::kIdI8 )
ASMJIT_NEW_REG_TYPED(newUInt8 , Gp , Type::kIdU8 )
ASMJIT_NEW_REG_TYPED(newInt16 , Gp , Type::kIdI16 )
ASMJIT_NEW_REG_TYPED(newUInt16 , Gp , Type::kIdU16 )
ASMJIT_NEW_REG_TYPED(newInt32 , Gp , Type::kIdI32 )
ASMJIT_NEW_REG_TYPED(newUInt32 , Gp , Type::kIdU32 )
ASMJIT_NEW_REG_TYPED(newInt64 , Gp , Type::kIdI64 )
ASMJIT_NEW_REG_TYPED(newUInt64 , Gp , Type::kIdU64 )
ASMJIT_NEW_REG_TYPED(newIntPtr , Gp , Type::kIdIntPtr )
ASMJIT_NEW_REG_TYPED(newUIntPtr, Gp , Type::kIdUIntPtr)
ASMJIT_NEW_REG_TYPED(newGpb , Gp , Type::kIdU8 )
ASMJIT_NEW_REG_TYPED(newGpw , Gp , Type::kIdU16 )
ASMJIT_NEW_REG_TYPED(newGpd , Gp , Type::kIdU32 )
ASMJIT_NEW_REG_TYPED(newGpq , Gp , Type::kIdU64 )
ASMJIT_NEW_REG_TYPED(newGpz , Gp , Type::kIdUIntPtr)
ASMJIT_NEW_REG_TYPED(newXmm , Xmm , Type::kIdI32x4 )
ASMJIT_NEW_REG_TYPED(newXmmSs , Xmm , Type::kIdF32x1 )
ASMJIT_NEW_REG_TYPED(newXmmSd , Xmm , Type::kIdF64x1 )
ASMJIT_NEW_REG_TYPED(newXmmPs , Xmm , Type::kIdF32x4 )
ASMJIT_NEW_REG_TYPED(newXmmPd , Xmm , Type::kIdF64x2 )
ASMJIT_NEW_REG_TYPED(newYmm , Ymm , Type::kIdI32x8 )
ASMJIT_NEW_REG_TYPED(newYmmPs , Ymm , Type::kIdF32x8 )
ASMJIT_NEW_REG_TYPED(newYmmPd , Ymm , Type::kIdF64x4 )
ASMJIT_NEW_REG_TYPED(newZmm , Zmm , Type::kIdI32x16 )
ASMJIT_NEW_REG_TYPED(newZmmPs , Zmm , Type::kIdF32x16 )
ASMJIT_NEW_REG_TYPED(newZmmPd , Zmm , Type::kIdF64x8 )
ASMJIT_NEW_REG_TYPED(newMm , Mm , Type::kIdMmx64 )
ASMJIT_NEW_REG_TYPED(newKb , KReg, Type::kIdMask8 )
ASMJIT_NEW_REG_TYPED(newKw , KReg, Type::kIdMask16 )
ASMJIT_NEW_REG_TYPED(newKd , KReg, Type::kIdMask32 )
ASMJIT_NEW_REG_TYPED(newKq , KReg, Type::kIdMask64 )
#undef ASMJIT_NEW_REG_TYPED
#undef ASMJIT_NEW_REG_CUSTOM
#undef ASMJIT_NEW_REG_FMT
//! \}
//! \name Stack
//! \{
//! Creates a new memory chunk allocated on the current function's stack.
inline Mem newStack(uint32_t size, uint32_t alignment, const char* name = nullptr) {
Mem m(Globals::NoInit);
_newStack(&m, size, alignment, name);
return m;
}
//! \}
//! \name Constants
//! \{
//! Put data to a constant-pool and get a memory reference to it.
inline Mem newConst(uint32_t scope, const void* data, size_t size) {
Mem m(Globals::NoInit);
_newConst(&m, scope, data, size);
return m;
}
//! Put a BYTE `val` to a constant-pool.
inline Mem newByteConst(uint32_t scope, uint8_t val) noexcept { return newConst(scope, &val, 1); }
//! Put a WORD `val` to a constant-pool.
inline Mem newWordConst(uint32_t scope, uint16_t val) noexcept { return newConst(scope, &val, 2); }
//! Put a DWORD `val` to a constant-pool.
inline Mem newDWordConst(uint32_t scope, uint32_t val) noexcept { return newConst(scope, &val, 4); }
//! Put a QWORD `val` to a constant-pool.
inline Mem newQWordConst(uint32_t scope, uint64_t val) noexcept { return newConst(scope, &val, 8); }
//! Put a WORD `val` to a constant-pool.
inline Mem newInt16Const(uint32_t scope, int16_t val) noexcept { return newConst(scope, &val, 2); }
//! Put a WORD `val` to a constant-pool.
inline Mem newUInt16Const(uint32_t scope, uint16_t val) noexcept { return newConst(scope, &val, 2); }
//! Put a DWORD `val` to a constant-pool.
inline Mem newInt32Const(uint32_t scope, int32_t val) noexcept { return newConst(scope, &val, 4); }
//! Put a DWORD `val` to a constant-pool.
inline Mem newUInt32Const(uint32_t scope, uint32_t val) noexcept { return newConst(scope, &val, 4); }
//! Put a QWORD `val` to a constant-pool.
inline Mem newInt64Const(uint32_t scope, int64_t val) noexcept { return newConst(scope, &val, 8); }
//! Put a QWORD `val` to a constant-pool.
inline Mem newUInt64Const(uint32_t scope, uint64_t val) noexcept { return newConst(scope, &val, 8); }
//! Put a SP-FP `val` to a constant-pool.
inline Mem newFloatConst(uint32_t scope, float val) noexcept { return newConst(scope, &val, 4); }
//! Put a DP-FP `val` to a constant-pool.
inline Mem newDoubleConst(uint32_t scope, double val) noexcept { return newConst(scope, &val, 8); }
#ifndef ASMJIT_NO_DEPRECATED
ASMJIT_DEPRECATED("newMmConst() uses a deprecated Data64, use newConst() with your own data instead")
inline Mem newMmConst(uint32_t scope, const Data64& val) noexcept { return newConst(scope, &val, 8); }
ASMJIT_DEPRECATED("newXmmConst() uses a deprecated Data128, use newConst() with your own data instead")
inline Mem newXmmConst(uint32_t scope, const Data128& val) noexcept { return newConst(scope, &val, 16); }
ASMJIT_DEPRECATED("newYmmConst() uses a deprecated Data256, use newConst() with your own data instead")
inline Mem newYmmConst(uint32_t scope, const Data256& val) noexcept { return newConst(scope, &val, 32); }
#endif // !ASMJIT_NO_DEPRECATED
//! \}
//! \name Instruction Options
//! \{
//! Force the compiler to not follow the conditional or unconditional jump.
inline Compiler& unfollow() noexcept { _instOptions |= Inst::kOptionUnfollow; return *this; }
//! Tell the compiler that the destination variable will be overwritten.
inline Compiler& overwrite() noexcept { _instOptions |= Inst::kOptionOverwrite; return *this; }
//! \}
//! \name Function Call & Ret Intrinsics
//! \{
//! Invoke a function call without `target` type enforcement.
inline Error invoke_(InvokeNode** out, const Operand_& target, const FuncSignature& signature) {
return _addInvokeNode(out, Inst::kIdCall, target, signature);
}
//! Invoke a function call of the given `target` and `signature` and store
//! the added node to `out`.
//!
//! Creates a new \ref InvokeNode, initializes all the necessary members to
//! match the given function `signature`, adds the node to the compiler, and
//! stores its pointer to `out`. The operation is atomic, if anything fails
//! nullptr is stored in `out` and error code is returned.
inline Error invoke(InvokeNode** out, const Gp& target, const FuncSignature& signature) { return invoke_(out, target, signature); }
//! \overload
inline Error invoke(InvokeNode** out, const Mem& target, const FuncSignature& signature) { return invoke_(out, target, signature); }
//! \overload
inline Error invoke(InvokeNode** out, const Label& target, const FuncSignature& signature) { return invoke_(out, target, signature); }
//! \overload
inline Error invoke(InvokeNode** out, const Imm& target, const FuncSignature& signature) { return invoke_(out, target, signature); }
//! \overload
inline Error invoke(InvokeNode** out, uint64_t target, const FuncSignature& signature) { return invoke_(out, Imm(int64_t(target)), signature); }
#ifndef _DOXYGEN
template<typename Target>
ASMJIT_DEPRECATED("Use invoke() instead of call()")
inline InvokeNode* call(const Target& target, const FuncSignature& signature) {
InvokeNode* invokeNode;
invoke(&invokeNode, target, signature);
return invokeNode;
}
#endif
//! Return.
inline FuncRetNode* ret() { return addRet(Operand(), Operand()); }
//! \overload
inline FuncRetNode* ret(const BaseReg& o0) { return addRet(o0, Operand()); }
//! \overload
inline FuncRetNode* ret(const BaseReg& o0, const BaseReg& o1) { return addRet(o0, o1); }
//! \}
//! \name Jump Tables Support
//! \{
using EmitterExplicitT<Compiler>::jmp;
//! Adds a jump to the given `target` with the provided jump `annotation`.
inline Error jmp(const BaseReg& target, JumpAnnotation* annotation) { return emitAnnotatedJump(Inst::kIdJmp, target, annotation); }
//! \overload
inline Error jmp(const BaseMem& target, JumpAnnotation* annotation) { return emitAnnotatedJump(Inst::kIdJmp, target, annotation); }
//! \}
//! \name Finalize
//! \{
ASMJIT_API Error finalize() override;
//! \}
//! \name Events
//! \{
ASMJIT_API Error onAttach(CodeHolder* code) noexcept override;
//! \}
};
//! \}
ASMJIT_END_SUB_NAMESPACE
#endif // !ASMJIT_NO_COMPILER
#endif // ASMJIT_X86_X86COMPILER_H_INCLUDED
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