Theodosius/Examples/Theodosius-Usermode/asmjit/core/rapass_p.h

// AsmJit - Machine code generation for C++
//
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//
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#ifndef ASMJIT_CORE_RAPASS_P_H_INCLUDED
#define ASMJIT_CORE_RAPASS_P_H_INCLUDED

#include "../core/api-config.h"
#ifndef ASMJIT_NO_COMPILER

#include "../core/compiler.h"
#include "../core/emithelper_p.h"
#include "../core/raassignment_p.h"
#include "../core/radefs_p.h"
#include "../core/rastack_p.h"
#include "../core/support.h"

ASMJIT_BEGIN_NAMESPACE

//! \cond INTERNAL
//! \addtogroup asmjit_ra
//! \{

// ============================================================================
// [asmjit::RABlock]
// ============================================================================

//! Basic block used by register allocator pass.
class RABlock {
public:
  ASMJIT_NONCOPYABLE(RABlock)

  typedef RAAssignment::PhysToWorkMap PhysToWorkMap;
  typedef RAAssignment::WorkToPhysMap WorkToPhysMap;

  enum Id : uint32_t {
    kUnassignedId = 0xFFFFFFFFu
  };

  //! Basic block flags.
  enum Flags : uint32_t {
    //! Block has been constructed from nodes.
    kFlagIsConstructed    = 0x00000001u,
    //! Block is reachable (set by `buildViews()`).
    kFlagIsReachable      = 0x00000002u,
    //! Block is a target (has an associated label or multiple labels).
    kFlagIsTargetable     = 0x00000004u,
    //! Block has been allocated.
    kFlagIsAllocated      = 0x00000008u,
    //! Block is a function-exit.
    kFlagIsFuncExit       = 0x00000010u,

    //! Block has a terminator (jump, conditional jump, ret).
    kFlagHasTerminator    = 0x00000100u,
    //! Block naturally flows to the next block.
    kFlagHasConsecutive   = 0x00000200u,
    //! Block has a jump to a jump-table at the end.
    kFlagHasJumpTable     = 0x00000400u,
    //! Block contains fixed registers (precolored).
    kFlagHasFixedRegs     = 0x00000800u,
    //! Block contains function calls.
    kFlagHasFuncCalls     = 0x00001000u
  };

  //! Register allocator pass.
  BaseRAPass* _ra;

  //! Block id (indexed from zero).
  uint32_t _blockId = kUnassignedId;
  //! Block flags, see `Flags`.
  uint32_t _flags = 0;

  //! First `BaseNode` of this block (inclusive).
  BaseNode* _first = nullptr;
  //! Last `BaseNode` of this block (inclusive).
  BaseNode* _last = nullptr;

  //! Initial position of this block (inclusive).
  uint32_t _firstPosition = 0;
  //! End position of this block (exclusive).
  uint32_t _endPosition = 0;

  //! Weight of this block (default 0, each loop adds one).
  uint32_t _weight = 0;
  //! Post-order view order, used during POV construction.
  uint32_t _povOrder = 0;

  //! Basic statistics about registers.
  RARegsStats _regsStats = RARegsStats();
  //! Maximum live-count per register group.
  RALiveCount _maxLiveCount = RALiveCount();

  //! Timestamp (used by block visitors).
  mutable uint64_t _timestamp = 0;
  //! Immediate dominator of this block.
  RABlock* _idom = nullptr;

  //! Block predecessors.
  RABlocks _predecessors {};
  //! Block successors.
  RABlocks _successors {};

  enum LiveType : uint32_t {
    kLiveIn = 0,
    kLiveOut = 1,
    kLiveGen = 2,
    kLiveKill = 3,
    kLiveCount = 4
  };

  //! Liveness in/out/use/kill.
  ZoneBitVector _liveBits[kLiveCount] {};

  //! Shared assignment it or `Globals::kInvalidId` if this block doesn't
  //! have shared assignment. See `RASharedAssignment` for more details.
  uint32_t _sharedAssignmentId = Globals::kInvalidId;
  //! Scratch registers that cannot be allocated upon block entry.
  uint32_t _entryScratchGpRegs = 0;
  //! Scratch registers used at exit, by a terminator instruction.
  uint32_t _exitScratchGpRegs = 0;

  //! Register assignment (PhysToWork) on entry.
  PhysToWorkMap* _entryPhysToWorkMap = nullptr;
  //! Register assignment (WorkToPhys) on entry.
  WorkToPhysMap* _entryWorkToPhysMap = nullptr;

  //! \name Construction & Destruction
  //! \{

  inline RABlock(BaseRAPass* ra) noexcept
    : _ra(ra) {}

  //! \}

  //! \name Accessors
  //! \{

  inline BaseRAPass* pass() const noexcept { return _ra; }
  inline ZoneAllocator* allocator() const noexcept;

  inline uint32_t blockId() const noexcept { return _blockId; }
  inline uint32_t flags() const noexcept { return _flags; }

  inline bool hasFlag(uint32_t flag) const noexcept { return (_flags & flag) != 0; }
  inline void addFlags(uint32_t flags) noexcept { _flags |= flags; }

  inline bool isAssigned() const noexcept { return _blockId != kUnassignedId; }

  inline bool isConstructed() const noexcept { return hasFlag(kFlagIsConstructed); }
  inline bool isReachable() const noexcept { return hasFlag(kFlagIsReachable); }
  inline bool isTargetable() const noexcept { return hasFlag(kFlagIsTargetable); }
  inline bool isAllocated() const noexcept { return hasFlag(kFlagIsAllocated); }
  inline bool isFuncExit() const noexcept { return hasFlag(kFlagIsFuncExit); }

  inline void makeConstructed(const RARegsStats& regStats) noexcept {
    _flags |= kFlagIsConstructed;
    _regsStats.combineWith(regStats);
  }

  inline void makeReachable() noexcept { _flags |= kFlagIsReachable; }
  inline void makeTargetable() noexcept { _flags |= kFlagIsTargetable; }
  inline void makeAllocated() noexcept { _flags |= kFlagIsAllocated; }

  inline const RARegsStats& regsStats() const noexcept { return _regsStats; }

  inline bool hasTerminator() const noexcept { return hasFlag(kFlagHasTerminator); }
  inline bool hasConsecutive() const noexcept { return hasFlag(kFlagHasConsecutive); }
  inline bool hasJumpTable() const noexcept { return hasFlag(kFlagHasJumpTable); }

  inline bool hasPredecessors() const noexcept { return !_predecessors.empty(); }
  inline bool hasSuccessors() const noexcept { return !_successors.empty(); }

  inline const RABlocks& predecessors() const noexcept { return _predecessors; }
  inline const RABlocks& successors() const noexcept { return _successors; }

  inline BaseNode* first() const noexcept { return _first; }
  inline BaseNode* last() const noexcept { return _last; }

  inline void setFirst(BaseNode* node) noexcept { _first = node; }
  inline void setLast(BaseNode* node) noexcept { _last = node; }

  inline uint32_t firstPosition() const noexcept { return _firstPosition; }
  inline void setFirstPosition(uint32_t position) noexcept { _firstPosition = position; }

  inline uint32_t endPosition() const noexcept { return _endPosition; }
  inline void setEndPosition(uint32_t position) noexcept { _endPosition = position; }

  inline uint32_t povOrder() const noexcept { return _povOrder; }

  inline uint32_t entryScratchGpRegs() const noexcept;
  inline uint32_t exitScratchGpRegs() const noexcept { return _exitScratchGpRegs; }

  inline void addEntryScratchGpRegs(uint32_t regMask) noexcept { _entryScratchGpRegs |= regMask; }
  inline void addExitScratchGpRegs(uint32_t regMask) noexcept { _exitScratchGpRegs |= regMask; }

  inline bool hasSharedAssignmentId() const noexcept { return _sharedAssignmentId != Globals::kInvalidId; }
  inline uint32_t sharedAssignmentId() const noexcept { return _sharedAssignmentId; }
  inline void setSharedAssignmentId(uint32_t id) noexcept { _sharedAssignmentId = id; }

  inline uint64_t timestamp() const noexcept { return _timestamp; }
  inline bool hasTimestamp(uint64_t ts) const noexcept { return _timestamp == ts; }
  inline void setTimestamp(uint64_t ts) const noexcept { _timestamp = ts; }
  inline void resetTimestamp() const noexcept { _timestamp = 0; }

  inline RABlock* consecutive() const noexcept { return hasConsecutive() ? _successors[0] : nullptr; }

  inline RABlock* iDom() noexcept { return _idom; }
  inline const RABlock* iDom() const noexcept { return _idom; }
  inline void setIDom(RABlock* block) noexcept { _idom = block; }

  inline ZoneBitVector& liveIn() noexcept { return _liveBits[kLiveIn]; }
  inline const ZoneBitVector& liveIn() const noexcept { return _liveBits[kLiveIn]; }

  inline ZoneBitVector& liveOut() noexcept { return _liveBits[kLiveOut]; }
  inline const ZoneBitVector& liveOut() const noexcept { return _liveBits[kLiveOut]; }

  inline ZoneBitVector& gen() noexcept { return _liveBits[kLiveGen]; }
  inline const ZoneBitVector& gen() const noexcept { return _liveBits[kLiveGen]; }

  inline ZoneBitVector& kill() noexcept { return _liveBits[kLiveKill]; }
  inline const ZoneBitVector& kill() const noexcept { return _liveBits[kLiveKill]; }

  inline Error resizeLiveBits(uint32_t size) noexcept {
    ASMJIT_PROPAGATE(_liveBits[kLiveIn  ].resize(allocator(), size));
    ASMJIT_PROPAGATE(_liveBits[kLiveOut ].resize(allocator(), size));
    ASMJIT_PROPAGATE(_liveBits[kLiveGen ].resize(allocator(), size));
    ASMJIT_PROPAGATE(_liveBits[kLiveKill].resize(allocator(), size));
    return kErrorOk;
  }

  inline bool hasEntryAssignment() const noexcept { return _entryPhysToWorkMap != nullptr; }
  inline WorkToPhysMap* entryWorkToPhysMap() const noexcept { return _entryWorkToPhysMap; }
  inline PhysToWorkMap* entryPhysToWorkMap() const noexcept { return _entryPhysToWorkMap; }

  inline void setEntryAssignment(PhysToWorkMap* physToWorkMap, WorkToPhysMap* workToPhysMap) noexcept {
    _entryPhysToWorkMap = physToWorkMap;
    _entryWorkToPhysMap = workToPhysMap;
  }

  //! \}

  //! \name Utilities
  //! \{

  //! Adds a successor to this block, and predecessor to `successor`, making
  //! connection on both sides.
  //!
  //! This API must be used to manage successors and predecessors, never manage
  //! it manually.
  Error appendSuccessor(RABlock* successor) noexcept;

  //! Similar to `appendSuccessor()`, but does prepend instead append.
  //!
  //! This function is used to add a natural flow (always first) to the block.
  Error prependSuccessor(RABlock* successor) noexcept;

  //! \}
};

// ============================================================================
// [asmjit::RAInst]
// ============================================================================

//! Register allocator's data associated with each `InstNode`.
class RAInst {
public:
  ASMJIT_NONCOPYABLE(RAInst)

  //! Parent block.
  RABlock* _block;
  //! Instruction flags.
  uint32_t _flags;
  //! Total count of RATiedReg's.
  uint32_t _tiedTotal;
  //! Index of RATiedReg's per register group.
  RARegIndex _tiedIndex;
  //! Count of RATiedReg's per register group.
  RARegCount _tiedCount;
  //! Number of live, and thus interfering VirtReg's at this point.
  RALiveCount _liveCount;
  //! Fixed physical registers used.
  RARegMask _usedRegs;
  //! Clobbered registers (by a function call).
  RARegMask _clobberedRegs;
  //! Tied registers.
  RATiedReg _tiedRegs[1];

  enum Flags : uint32_t {
    kFlagIsTerminator = 0x00000001u
  };

  //! \name Construction & Destruction
  //! \{

  ASMJIT_INLINE RAInst(RABlock* block, uint32_t flags, uint32_t tiedTotal, const RARegMask& clobberedRegs) noexcept {
    _block = block;
    _flags = flags;
    _tiedTotal = tiedTotal;
    _tiedIndex.reset();
    _tiedCount.reset();
    _liveCount.reset();
    _usedRegs.reset();
    _clobberedRegs = clobberedRegs;
  }

  //! \}

  //! \name Accessors
  //! \{

  //! Returns the instruction flags.
  inline uint32_t flags() const noexcept { return _flags; }
  //! Tests whether the instruction has flag `flag`.
  inline bool hasFlag(uint32_t flag) const noexcept { return (_flags & flag) != 0; }
  //! Replaces the existing instruction flags with `flags`.
  inline void setFlags(uint32_t flags) noexcept { _flags = flags; }
  //! Adds instruction `flags` to this RAInst.
  inline void addFlags(uint32_t flags) noexcept { _flags |= flags; }
  //! Clears instruction `flags` from  this RAInst.
  inline void clearFlags(uint32_t flags) noexcept { _flags &= ~flags; }

  //! Returns whether the RAInst represents an instruction that terminates this basic block.
  inline bool isTerminator() const noexcept { return hasFlag(kFlagIsTerminator); }

  //! Returns the associated block with this RAInst.
  inline RABlock* block() const noexcept { return _block; }

  //! Returns tied registers (all).
  inline RATiedReg* tiedRegs() const noexcept { return const_cast<RATiedReg*>(_tiedRegs); }
  //! Returns tied registers for a given `group`.
  inline RATiedReg* tiedRegs(uint32_t group) const noexcept { return const_cast<RATiedReg*>(_tiedRegs) + _tiedIndex.get(group); }

  //! Returns count of all tied registers.
  inline uint32_t tiedCount() const noexcept { return _tiedTotal; }
  //! Returns count of tied registers of a given `group`.
  inline uint32_t tiedCount(uint32_t group) const noexcept { return _tiedCount[group]; }

  //! Returns `RATiedReg` at the given `index`.
  inline RATiedReg* tiedAt(uint32_t index) const noexcept {
    ASMJIT_ASSERT(index < _tiedTotal);
    return tiedRegs() + index;
  }

  //! Returns `RATiedReg` at the given `index` of the given register `group`.
  inline RATiedReg* tiedOf(uint32_t group, uint32_t index) const noexcept {
    ASMJIT_ASSERT(index < _tiedCount._regs[group]);
    return tiedRegs(group) + index;
  }

  inline void setTiedAt(uint32_t index, RATiedReg& tied) noexcept {
    ASMJIT_ASSERT(index < _tiedTotal);
    _tiedRegs[index] = tied;
  }

  //! \name Static Functions
  //! \{

  static inline size_t sizeOf(uint32_t tiedRegCount) noexcept {
    return sizeof(RAInst) - sizeof(RATiedReg) + tiedRegCount * sizeof(RATiedReg);
  }

  //! \}
};

// ============================================================================
// [asmjit::RAInstBuilder]
// ============================================================================

//! A helper class that is used to build an array of RATiedReg items that are
//! then copied to `RAInst`.
class RAInstBuilder {
public:
  ASMJIT_NONCOPYABLE(RAInstBuilder)

  //! Flags combined from all RATiedReg's.
  uint32_t _aggregatedFlags;
  //! Flags that will be cleared before storing the aggregated flags to `RAInst`.
  uint32_t _forbiddenFlags;
  RARegCount _count;
  RARegsStats _stats;

  RARegMask _used;
  RARegMask _clobbered;

  //! Current tied register in `_tiedRegs`.
  RATiedReg* _cur;
  //! Array of temporary tied registers.
  RATiedReg _tiedRegs[128];

  //! \name Construction & Destruction
  //! \{

  inline RAInstBuilder() noexcept { reset(); }

  inline void init() noexcept { reset(); }
  inline void reset() noexcept {
    _aggregatedFlags = 0;
    _forbiddenFlags = 0;
    _count.reset();
    _stats.reset();
    _used.reset();
    _clobbered.reset();
    _cur = _tiedRegs;
  }

  //! \}

  //! \name Accessors
  //! \{

  inline uint32_t aggregatedFlags() const noexcept { return _aggregatedFlags; }
  inline uint32_t forbiddenFlags() const noexcept { return _forbiddenFlags; }

  inline void addAggregatedFlags(uint32_t flags) noexcept { _aggregatedFlags |= flags; }
  inline void addForbiddenFlags(uint32_t flags) noexcept { _forbiddenFlags |= flags; }

  //! Returns the number of tied registers added to the builder.
  inline uint32_t tiedRegCount() const noexcept { return uint32_t((size_t)(_cur - _tiedRegs)); }

  inline RATiedReg* begin() noexcept { return _tiedRegs; }
  inline RATiedReg* end() noexcept { return _cur; }

  inline const RATiedReg* begin() const noexcept { return _tiedRegs; }
  inline const RATiedReg* end() const noexcept { return _cur; }

  //! Returns `RATiedReg` at the given `index`.
  inline RATiedReg* operator[](uint32_t index) noexcept {
    ASMJIT_ASSERT(index < tiedRegCount());
    return &_tiedRegs[index];
  }

  //! Returns `RATiedReg` at the given `index`. (const).
  inline const RATiedReg* operator[](uint32_t index) const noexcept {
    ASMJIT_ASSERT(index < tiedRegCount());
    return &_tiedRegs[index];
  }

  //! \}

  //! \name Utilities
  //! \{

  Error add(RAWorkReg* workReg, uint32_t flags, uint32_t allocable, uint32_t useId, uint32_t useRewriteMask, uint32_t outId, uint32_t outRewriteMask, uint32_t rmSize = 0) noexcept {
    uint32_t group = workReg->group();
    RATiedReg* tiedReg = workReg->tiedReg();

    if (useId != BaseReg::kIdBad) {
      _stats.makeFixed(group);
      _used[group] |= Support::bitMask(useId);
      flags |= RATiedReg::kUseFixed;
    }

    if (outId != BaseReg::kIdBad) {
      _clobbered[group] |= Support::bitMask(outId);
      flags |= RATiedReg::kOutFixed;
    }

    _aggregatedFlags |= flags;
    _stats.makeUsed(group);

    if (!tiedReg) {
      // Could happen when the builder is not reset properly after each instruction.
      ASMJIT_ASSERT(tiedRegCount() < ASMJIT_ARRAY_SIZE(_tiedRegs));

      tiedReg = _cur++;
      tiedReg->init(workReg->workId(), flags, allocable, useId, useRewriteMask, outId, outRewriteMask, rmSize);
      workReg->setTiedReg(tiedReg);

      _count.add(group);
      return kErrorOk;
    }
    else {
      if (useId != BaseReg::kIdBad) {
        if (ASMJIT_UNLIKELY(tiedReg->hasUseId()))
          return DebugUtils::errored(kErrorOverlappedRegs);
        tiedReg->setUseId(useId);
      }

      if (outId != BaseReg::kIdBad) {
        if (ASMJIT_UNLIKELY(tiedReg->hasOutId()))
          return DebugUtils::errored(kErrorOverlappedRegs);
        tiedReg->setOutId(outId);
      }

      tiedReg->addRefCount();
      tiedReg->addFlags(flags);
      tiedReg->_allocableRegs &= allocable;
      tiedReg->_useRewriteMask |= useRewriteMask;
      tiedReg->_outRewriteMask |= outRewriteMask;
      tiedReg->_rmSize = uint8_t(Support::max<uint32_t>(tiedReg->rmSize(), rmSize));
      return kErrorOk;
    }
  }

  Error addCallArg(RAWorkReg* workReg, uint32_t useId) noexcept {
    ASMJIT_ASSERT(useId != BaseReg::kIdBad);

    uint32_t flags = RATiedReg::kUse | RATiedReg::kRead | RATiedReg::kUseFixed;
    uint32_t group = workReg->group();
    uint32_t allocable = Support::bitMask(useId);

    _aggregatedFlags |= flags;
    _used[group] |= allocable;
    _stats.makeFixed(group);
    _stats.makeUsed(group);

    RATiedReg* tiedReg = workReg->tiedReg();
    if (!tiedReg) {
      // Could happen when the builder is not reset properly after each instruction.
      ASMJIT_ASSERT(tiedRegCount() < ASMJIT_ARRAY_SIZE(_tiedRegs));

      tiedReg = _cur++;
      tiedReg->init(workReg->workId(), flags, allocable, useId, 0, BaseReg::kIdBad, 0);
      workReg->setTiedReg(tiedReg);

      _count.add(group);
      return kErrorOk;
    }
    else {
      if (tiedReg->hasUseId()) {
        flags |= RATiedReg::kDuplicate;
        tiedReg->_allocableRegs |= allocable;
      }
      else {
        tiedReg->setUseId(useId);
        tiedReg->_allocableRegs &= allocable;
      }

      tiedReg->addRefCount();
      tiedReg->addFlags(flags);
      return kErrorOk;
    }
  }

  Error addCallRet(RAWorkReg* workReg, uint32_t outId) noexcept {
    ASMJIT_ASSERT(outId != BaseReg::kIdBad);

    uint32_t flags = RATiedReg::kOut | RATiedReg::kWrite | RATiedReg::kOutFixed;
    uint32_t group = workReg->group();
    uint32_t allocable = Support::bitMask(outId);

    _aggregatedFlags |= flags;
    _used[group] |= allocable;
    _stats.makeFixed(group);
    _stats.makeUsed(group);

    RATiedReg* tiedReg = workReg->tiedReg();
    if (!tiedReg) {
      // Could happen when the builder is not reset properly after each instruction.
      ASMJIT_ASSERT(tiedRegCount() < ASMJIT_ARRAY_SIZE(_tiedRegs));

      tiedReg = _cur++;
      tiedReg->init(workReg->workId(), flags, allocable, BaseReg::kIdBad, 0, outId, 0);
      workReg->setTiedReg(tiedReg);

      _count.add(group);
      return kErrorOk;
    }
    else {
      if (tiedReg->hasOutId())
        return DebugUtils::errored(kErrorOverlappedRegs);

      tiedReg->addRefCount();
      tiedReg->addFlags(flags);
      tiedReg->setOutId(outId);
      return kErrorOk;
    }
  }

  //! \}
};

// ============================================================================
// [asmjit::RASharedAssignment]
// ============================================================================

class RASharedAssignment {
public:
  typedef RAAssignment::PhysToWorkMap PhysToWorkMap;
  typedef RAAssignment::WorkToPhysMap WorkToPhysMap;

  //! Bit-mask of registers that cannot be used upon a block entry, for each
  //! block that has this shared assignment. Scratch registers can come from
  //! ISA limits (like jecx/loop instructions on x86) or because the registers
  //! are used by jump/branch instruction that uses registers to perform an
  //! indirect jump.
  uint32_t _entryScratchGpRegs = 0;
  //! Union of all live-in registers.
  ZoneBitVector _liveIn {};
  //! Register assignment (PhysToWork).
  PhysToWorkMap* _physToWorkMap = nullptr;
  //! Register assignment (WorkToPhys).
  WorkToPhysMap* _workToPhysMap = nullptr;

  //! Most likely never called as we initialize a vector of shared assignments to zero.
  inline RASharedAssignment() noexcept {}

  inline uint32_t entryScratchGpRegs() const noexcept { return _entryScratchGpRegs; }
  inline void addEntryScratchGpRegs(uint32_t mask) noexcept { _entryScratchGpRegs |= mask; }

  inline const ZoneBitVector& liveIn() const noexcept { return _liveIn; }

  inline PhysToWorkMap* physToWorkMap() const noexcept { return _physToWorkMap; }
  inline WorkToPhysMap* workToPhysMap() const noexcept { return _workToPhysMap; }

  inline bool empty() const noexcept {
    return _physToWorkMap == nullptr;
  }

  inline void assignMaps(PhysToWorkMap* physToWorkMap, WorkToPhysMap* workToPhysMap) noexcept {
    _physToWorkMap = physToWorkMap;
    _workToPhysMap = workToPhysMap;
  }
};

// ============================================================================
// [asmjit::BaseRAPass]
// ============================================================================

//! Register allocation pass used by `BaseCompiler`.
class BaseRAPass : public FuncPass {
public:
  ASMJIT_NONCOPYABLE(BaseRAPass)
  typedef FuncPass Base;

  enum Weights : uint32_t {
    kCallArgWeight = 80
  };

  typedef RAAssignment::PhysToWorkMap PhysToWorkMap;
  typedef RAAssignment::WorkToPhysMap WorkToPhysMap;

  //! Allocator that uses zone passed to `runOnFunction()`.
  ZoneAllocator _allocator {};
  //! Emit helper.
  BaseEmitHelper* _iEmitHelper = nullptr;

  //! Logger, disabled if null.
  Logger* _logger = nullptr;
  //! Debug logger, non-null only if `kOptionDebugPasses` option is set.
  Logger* _debugLogger = nullptr;
  //! Logger flags.
  uint32_t _loggerFlags = 0;

  //! Function being processed.
  FuncNode* _func = nullptr;
  //! Stop node.
  BaseNode* _stop = nullptr;
  //! Node that is used to insert extra code after the function body.
  BaseNode* _extraBlock = nullptr;

  //! Blocks (first block is the entry, always exists).
  RABlocks _blocks {};
  //! Function exit blocks (usually one, but can contain more).
  RABlocks _exits {};
  //! Post order view (POV).
  RABlocks _pov {};

  //! Number of instruction nodes.
  uint32_t _instructionCount = 0;
  //! Number of created blocks (internal).
  uint32_t _createdBlockCount = 0;

  //! SharedState blocks.
  ZoneVector<RASharedAssignment> _sharedAssignments {};

  //! Timestamp generator (incremental).
  mutable uint64_t _lastTimestamp = 0;

  //! Architecture traits.
  const ArchTraits* _archTraits = nullptr;
  //! Index to physical registers in `RAAssignment::PhysToWorkMap`.
  RARegIndex _physRegIndex = RARegIndex();
  //! Count of physical registers in `RAAssignment::PhysToWorkMap`.
  RARegCount _physRegCount = RARegCount();
  //! Total number of physical registers.
  uint32_t _physRegTotal = 0;
  //! Indexes of a possible scratch registers that can be selected if necessary.
  uint8_t _scratchRegIndexes[2] {};

  //! Registers available for allocation.
  RARegMask _availableRegs = RARegMask();
  //! Count of physical registers per group.
  RARegCount _availableRegCount = RARegCount();
  //! Registers clobbered by the function.
  RARegMask _clobberedRegs = RARegMask();

  //! Work registers (registers used by the function).
  RAWorkRegs _workRegs;
  //! Work registers per register group.
  RAWorkRegs _workRegsOfGroup[BaseReg::kGroupVirt];

  //! Register allocation strategy per register group.
  RAStrategy _strategy[BaseReg::kGroupVirt];
  //! Global max live-count (from all blocks) per register group.
  RALiveCount _globalMaxLiveCount = RALiveCount();
  //! Global live spans per register group.
  LiveRegSpans* _globalLiveSpans[BaseReg::kGroupVirt] {};
  //! Temporary stack slot.
  Operand _temporaryMem = Operand();

  //! Stack pointer.
  BaseReg _sp = BaseReg();
  //! Frame pointer.
  BaseReg _fp = BaseReg();
  //! Stack manager.
  RAStackAllocator _stackAllocator {};
  //! Function arguments assignment.
  FuncArgsAssignment _argsAssignment {};
  //! Some StackArgs have to be assigned to StackSlots.
  uint32_t _numStackArgsToStackSlots = 0;

  //! Maximum name-size computed from all WorkRegs.
  uint32_t _maxWorkRegNameSize = 0;
  //! Temporary string builder used to format comments.
  StringTmp<80> _tmpString;

  //! \name Construction & Reset
  //! \{

  BaseRAPass() noexcept;
  virtual ~BaseRAPass() noexcept;

  //! \}

  //! \name Accessors
  //! \{

  //! Returns \ref Logger passed to \ref runOnFunction().
  inline Logger* logger() const noexcept { return _logger; }
  //! Returns \ref Logger passed to \ref runOnFunction() or null if `kOptionDebugPasses` is not set.
  inline Logger* debugLogger() const noexcept { return _debugLogger; }

  //! Returns \ref Zone passed to \ref runOnFunction().
  inline Zone* zone() const noexcept { return _allocator.zone(); }
  //! Returns \ref ZoneAllocator used by the register allocator.
  inline ZoneAllocator* allocator() const noexcept { return const_cast<ZoneAllocator*>(&_allocator); }

  inline const ZoneVector<RASharedAssignment>& sharedAssignments() const { return _sharedAssignments; }
  inline uint32_t sharedAssignmentCount() const noexcept { return _sharedAssignments.size(); }

  //! Returns the current function node.
  inline FuncNode* func() const noexcept { return _func; }
  //! Returns the stop of the current function.
  inline BaseNode* stop() const noexcept { return _stop; }

  //! Returns an extra block used by the current function being processed.
  inline BaseNode* extraBlock() const noexcept { return _extraBlock; }
  //! Sets an extra block, see `extraBlock()`.
  inline void setExtraBlock(BaseNode* node) noexcept { _extraBlock = node; }

  inline uint32_t endPosition() const noexcept { return _instructionCount * 2; }

  inline const RARegMask& availableRegs() const noexcept { return _availableRegs; }
  inline const RARegMask& cloberredRegs() const noexcept { return _clobberedRegs; }

  //! \}

  //! \name Utilities
  //! \{

  inline void makeUnavailable(uint32_t group, uint32_t regId) noexcept {
    _availableRegs[group] &= ~Support::bitMask(regId);
    _availableRegCount[group]--;
  }

  //! Runs the register allocator for the given `func`.
  Error runOnFunction(Zone* zone, Logger* logger, FuncNode* func) override;

  //! Performs all allocation steps sequentially, called by `runOnFunction()`.
  Error onPerformAllSteps() noexcept;

  //! \}

  //! \name Events
  //! \{

  //! Called by \ref runOnFunction() before the register allocation to initialize
  //! architecture-specific data and constraints.
  virtual void onInit() noexcept = 0;

  //! Called by \ref runOnFunction(` after register allocation to clean everything
  //! up. Called even if the register allocation failed.
  virtual void onDone() noexcept = 0;

  //! \}

  //! \name CFG - Basic-Block Management
  //! \{

  //! Returns the function's entry block.
  inline RABlock* entryBlock() noexcept {
    ASMJIT_ASSERT(!_blocks.empty());
    return _blocks[0];
  }

  //! \overload
  inline const RABlock* entryBlock() const noexcept {
    ASMJIT_ASSERT(!_blocks.empty());
    return _blocks[0];
  }

  //! Returns all basic blocks of this function.
  inline RABlocks& blocks() noexcept { return _blocks; }
  //! \overload
  inline const RABlocks& blocks() const noexcept { return _blocks; }

  //! Returns the count of basic blocks (returns size of `_blocks` array).
  inline uint32_t blockCount() const noexcept { return _blocks.size(); }
  //! Returns the count of reachable basic blocks (returns size of `_pov` array).
  inline uint32_t reachableBlockCount() const noexcept { return _pov.size(); }

  //! Tests whether the CFG has dangling blocks - these were created by `newBlock()`,
  //! but not added to CFG through `addBlocks()`. If `true` is returned and the
  //! CFG is constructed it means that something is missing and it's incomplete.
  //!
  //! \note This is only used to check if the number of created blocks matches
  //! the number of added blocks.
  inline bool hasDanglingBlocks() const noexcept { return _createdBlockCount != blockCount(); }

  //! Gest a next timestamp to be used to mark CFG blocks.
  inline uint64_t nextTimestamp() const noexcept { return ++_lastTimestamp; }

  //! Createss a new `RABlock` instance.
  //!
  //! \note New blocks don't have ID assigned until they are added to the block
  //! array by calling `addBlock()`.
  RABlock* newBlock(BaseNode* initialNode = nullptr) noexcept;

  //! Tries to find a neighboring LabelNode (without going through code) that is
  //! already connected with `RABlock`. If no label is found then a new RABlock
  //! is created and assigned to all possible labels in a backward direction.
  RABlock* newBlockOrExistingAt(LabelNode* cbLabel, BaseNode** stoppedAt = nullptr) noexcept;

  //! Adds the given `block` to the block list and assign it a unique block id.
  Error addBlock(RABlock* block) noexcept;

  inline Error addExitBlock(RABlock* block) noexcept {
    block->addFlags(RABlock::kFlagIsFuncExit);
    return _exits.append(allocator(), block);
  }

  ASMJIT_INLINE RAInst* newRAInst(RABlock* block, uint32_t flags, uint32_t tiedRegCount, const RARegMask& clobberedRegs) noexcept {
    void* p = zone()->alloc(RAInst::sizeOf(tiedRegCount));
    if (ASMJIT_UNLIKELY(!p))
      return nullptr;
    return new(p) RAInst(block, flags, tiedRegCount, clobberedRegs);
  }

  ASMJIT_INLINE Error assignRAInst(BaseNode* node, RABlock* block, RAInstBuilder& ib) noexcept {
    uint32_t tiedRegCount = ib.tiedRegCount();
    RAInst* raInst = newRAInst(block, ib.aggregatedFlags(), tiedRegCount, ib._clobbered);

    if (ASMJIT_UNLIKELY(!raInst))
      return DebugUtils::errored(kErrorOutOfMemory);

    RARegIndex index;
    uint32_t flagsFilter = ~ib.forbiddenFlags();

    index.buildIndexes(ib._count);
    raInst->_tiedIndex = index;
    raInst->_tiedCount = ib._count;

    for (uint32_t i = 0; i < tiedRegCount; i++) {
      RATiedReg* tiedReg = ib[i];
      RAWorkReg* workReg = workRegById(tiedReg->workId());

      workReg->resetTiedReg();
      uint32_t group = workReg->group();

      if (tiedReg->hasUseId()) {
        block->addFlags(RABlock::kFlagHasFixedRegs);
        raInst->_usedRegs[group] |= Support::bitMask(tiedReg->useId());
      }

      if (tiedReg->hasOutId()) {
        block->addFlags(RABlock::kFlagHasFixedRegs);
      }

      RATiedReg& dst = raInst->_tiedRegs[index[group]++];
      dst = *tiedReg;
      dst._flags &= flagsFilter;

      if (!tiedReg->isDuplicate())
        dst._allocableRegs &= ~ib._used[group];
    }

    node->setPassData<RAInst>(raInst);
    return kErrorOk;
  }

  //! \}

  //! \name CFG - Build CFG
  //! \{

  //! Traverse the whole function and do the following:
  //!
  //!   1. Construct CFG (represented by `RABlock`) by populating `_blocks` and
  //!      `_exits`. Blocks describe the control flow of the function and contain
  //!      some additional information that is used by the register allocator.
  //!
  //!   2. Remove unreachable code immediately. This is not strictly necessary
  //!      for BaseCompiler itself as the register allocator cannot reach such
  //!      nodes, but keeping instructions that use virtual registers would fail
  //!      during instruction encoding phase (Assembler).
  //!
  //!   3. `RAInst` is created for each `InstNode` or compatible. It contains
  //!      information that is essential for further analysis and register
  //!      allocation.
  //!
  //! Use `RACFGBuilderT` template that provides the necessary boilerplate.
  virtual Error buildCFG() noexcept = 0;

  //! Called after the CFG is built.
  Error initSharedAssignments(const ZoneVector<uint32_t>& sharedAssignmentsMap) noexcept;

  //! \}

  //! \name CFG - Views Order
  //! \{

  //! Constructs CFG views (only POV at the moment).
  Error buildViews() noexcept;

  //! \}

  //! \name CFG - Dominators
  //! \{

  // Terminology:
  //   - A node `X` dominates a node `Z` if any path from the entry point to
  //     `Z` has to go through `X`.
  //   - A node `Z` post-dominates a node `X` if any path from `X` to the end
  //     of the graph has to go through `Z`.

  //! Constructs a dominator-tree from CFG.
  Error buildDominators() noexcept;

  bool _strictlyDominates(const RABlock* a, const RABlock* b) const noexcept;
  const RABlock* _nearestCommonDominator(const RABlock* a, const RABlock* b) const noexcept;

  //! Tests whether the basic block `a` dominates `b` - non-strict, returns true when `a == b`.
  inline bool dominates(const RABlock* a, const RABlock* b) const noexcept { return a == b ? true : _strictlyDominates(a, b); }
  //! Tests whether the basic block `a` dominates `b` - strict dominance check, returns false when `a == b`.
  inline bool strictlyDominates(const RABlock* a, const RABlock* b) const noexcept { return a == b ? false : _strictlyDominates(a, b); }

  //! Returns a nearest common dominator of `a` and `b`.
  inline RABlock* nearestCommonDominator(RABlock* a, RABlock* b) const noexcept { return const_cast<RABlock*>(_nearestCommonDominator(a, b)); }
  //! Returns a nearest common dominator of `a` and `b` (const).
  inline const RABlock* nearestCommonDominator(const RABlock* a, const RABlock* b) const noexcept { return _nearestCommonDominator(a, b); }

  //! \}

  //! \name CFG - Utilities
  //! \{

  Error removeUnreachableBlocks() noexcept;

  //! Returns `node` or some node after that is ideal for beginning a new block.
  //! This function is mostly used after a conditional or unconditional jump to
  //! select the successor node. In some cases the next node could be a label,
  //! which means it could have assigned some block already.
  BaseNode* findSuccessorStartingAt(BaseNode* node) noexcept;

  //! Returns `true` of the `node` can flow to `target` without reaching code
  //! nor data. It's used to eliminate jumps to labels that are next right to
  //! them.
  bool isNextTo(BaseNode* node, BaseNode* target) noexcept;

  //! \}

  //! \name Virtual Register Management
  //! \{

  //! Returns a native size of the general-purpose register of the target architecture.
  inline uint32_t registerSize() const noexcept { return _sp.size(); }
  inline uint32_t availableRegCount(uint32_t group) const noexcept { return _availableRegCount[group]; }

  inline RAWorkReg* workRegById(uint32_t workId) const noexcept { return _workRegs[workId]; }

  inline RAWorkRegs& workRegs() noexcept { return _workRegs; }
  inline RAWorkRegs& workRegs(uint32_t group) noexcept { return _workRegsOfGroup[group]; }

  inline const RAWorkRegs& workRegs() const noexcept { return _workRegs; }
  inline const RAWorkRegs& workRegs(uint32_t group) const noexcept { return _workRegsOfGroup[group]; }

  inline uint32_t workRegCount() const noexcept { return _workRegs.size(); }
  inline uint32_t workRegCount(uint32_t group) const noexcept { return _workRegsOfGroup[group].size(); }

  inline void _buildPhysIndex() noexcept {
    _physRegIndex.buildIndexes(_physRegCount);
    _physRegTotal = uint32_t(_physRegIndex[BaseReg::kGroupVirt - 1]) +
                    uint32_t(_physRegCount[BaseReg::kGroupVirt - 1]) ;
  }
  inline uint32_t physRegIndex(uint32_t group) const noexcept { return _physRegIndex[group]; }
  inline uint32_t physRegTotal() const noexcept { return _physRegTotal; }

  Error _asWorkReg(VirtReg* vReg, RAWorkReg** out) noexcept;

  //! Creates `RAWorkReg` data for the given `vReg`. The function does nothing
  //! if `vReg` already contains link to `RAWorkReg`. Called by `constructBlocks()`.
  inline Error asWorkReg(VirtReg* vReg, RAWorkReg** out) noexcept {
    *out = vReg->workReg();
    return *out ? kErrorOk : _asWorkReg(vReg, out);
  }

  inline Error virtIndexAsWorkReg(uint32_t vIndex, RAWorkReg** out) noexcept {
    const ZoneVector<VirtReg*>& virtRegs = cc()->virtRegs();
    if (ASMJIT_UNLIKELY(vIndex >= virtRegs.size()))
      return DebugUtils::errored(kErrorInvalidVirtId);
    return asWorkReg(virtRegs[vIndex], out);
  }

  inline RAStackSlot* getOrCreateStackSlot(RAWorkReg* workReg) noexcept {
    RAStackSlot* slot = workReg->stackSlot();

    if (slot)
      return slot;

    slot = _stackAllocator.newSlot(_sp.id(), workReg->virtReg()->virtSize(), workReg->virtReg()->alignment(), RAStackSlot::kFlagRegHome);
    workReg->_stackSlot = slot;
    workReg->markStackUsed();
    return slot;
  }

  inline BaseMem workRegAsMem(RAWorkReg* workReg) noexcept {
    getOrCreateStackSlot(workReg);
    return BaseMem(BaseMem::Decomposed { _sp.type(), workReg->virtId(), BaseReg::kTypeNone, 0, 0, 0, BaseMem::kSignatureMemRegHomeFlag });
  }

  WorkToPhysMap* newWorkToPhysMap() noexcept;
  PhysToWorkMap* newPhysToWorkMap() noexcept;

  inline PhysToWorkMap* clonePhysToWorkMap(const PhysToWorkMap* map) noexcept {
    size_t size = PhysToWorkMap::sizeOf(_physRegTotal);
    return static_cast<PhysToWorkMap*>(zone()->dupAligned(map, size, sizeof(uint32_t)));
  }

  inline WorkToPhysMap* cloneWorkToPhysMap(const WorkToPhysMap* map) noexcept {
    size_t size = WorkToPhysMap::sizeOf(_workRegs.size());
    if (ASMJIT_UNLIKELY(size == 0))
      return const_cast<WorkToPhysMap*>(map);
    return static_cast<WorkToPhysMap*>(zone()->dup(map, size));
  }

  //! \name Liveness Analysis & Statistics
  //! \{

  //! 1. Calculates GEN/KILL/IN/OUT of each block.
  //! 2. Calculates live spans and basic statistics of each work register.
  Error buildLiveness() noexcept;

  //! Assigns argIndex to WorkRegs. Must be called after the liveness analysis
  //! finishes as it checks whether the argument is live upon entry.
  Error assignArgIndexToWorkRegs() noexcept;

  //! \}

  //! \name Register Allocation - Global
  //! \{

  //! Runs a global register allocator.
  Error runGlobalAllocator() noexcept;

  //! Initializes data structures used for global live spans.
  Error initGlobalLiveSpans() noexcept;

  Error binPack(uint32_t group) noexcept;

  //! \}

  //! \name Register Allocation - Local
  //! \{

  //! Runs a local register allocator.
  Error runLocalAllocator() noexcept;
  Error setBlockEntryAssignment(RABlock* block, const RABlock* fromBlock, const RAAssignment& fromAssignment) noexcept;
  Error setSharedAssignment(uint32_t sharedAssignmentId, const RAAssignment& fromAssignment) noexcept;

  //! Called after the RA assignment has been assigned to a block.
  //!
  //! This cannot change the assignment, but can examine it.
  Error blockEntryAssigned(const RAAssignment& as) noexcept;

  //! \}

  //! \name Register Allocation Utilities
  //! \{

  Error useTemporaryMem(BaseMem& out, uint32_t size, uint32_t alignment) noexcept;

  //! \}

  //! \name Function Prolog & Epilog
  //! \{

  virtual Error updateStackFrame() noexcept;
  Error _markStackArgsToKeep() noexcept;
  Error _updateStackArgs() noexcept;
  Error insertPrologEpilog() noexcept;

  //! \}

  //! \name Instruction Rewriter
  //! \{

  Error rewrite() noexcept;
  Error _rewrite(BaseNode* first, BaseNode* stop) noexcept;

  //! \}

#ifndef ASMJIT_NO_LOGGING
  //! \name Logging
  //! \{

  Error annotateCode() noexcept;

  Error _dumpBlockIds(String& sb, const RABlocks& blocks) noexcept;
  Error _dumpBlockLiveness(String& sb, const RABlock* block) noexcept;
  Error _dumpLiveSpans(String& sb) noexcept;

  //! \}
#endif

  //! \name Emit
  //! \{

  virtual Error emitMove(uint32_t workId, uint32_t dstPhysId, uint32_t srcPhysId) noexcept = 0;
  virtual Error emitSwap(uint32_t aWorkId, uint32_t aPhysId, uint32_t bWorkId, uint32_t bPhysId) noexcept = 0;

  virtual Error emitLoad(uint32_t workId, uint32_t dstPhysId) noexcept = 0;
  virtual Error emitSave(uint32_t workId, uint32_t srcPhysId) noexcept = 0;

  virtual Error emitJump(const Label& label) noexcept = 0;
  virtual Error emitPreCall(InvokeNode* invokeNode) noexcept = 0;

  //! \}
};

inline ZoneAllocator* RABlock::allocator() const noexcept { return _ra->allocator(); }

inline uint32_t RABlock::entryScratchGpRegs() const noexcept {
  uint32_t regs = _entryScratchGpRegs;
  if (hasSharedAssignmentId())
    regs = _ra->_sharedAssignments[_sharedAssignmentId].entryScratchGpRegs();
  return regs;
}

//! \}
//! \endcond

ASMJIT_END_NAMESPACE

#endif // !ASMJIT_NO_COMPILER
#endif // ASMJIT_CORE_RAPASS_P_H_INCLUDED