src/v8/src/compiler/register-allocator-verifier.h - cobalt - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_REGISTER_ALLOCATOR_VERIFIER_H_
 #define V8_REGISTER_ALLOCATOR_VERIFIER_H_

 #include "src/compiler/instruction.h"
 #include "src/zone/zone-containers.h"

 namespace v8 {
 namespace internal {
 namespace compiler {

 class InstructionBlock;
 class InstructionSequence;

 // The register allocator validator traverses instructions in the instruction
 // sequence, and verifies the correctness of machine operand substitutions of
 // virtual registers. It collects the virtual register instruction signatures
 // before register allocation. Then, after the register allocation pipeline
 // completes, it compares the operand substitutions against the pre-allocation
 // data.
 // At a high level, validation works as follows: we iterate through each block,
 // and, in a block, through each instruction; then:
 // - when an operand is the output of an instruction, we associate it to the
 // virtual register that the instruction sequence declares as its output. We
 // use the concept of "FinalAssessment" to model this.
 // - when an operand is used in an instruction, we check that the assessment
 // matches the expectation of the instruction
 // - moves simply copy the assessment over to the new operand
 // - blocks with more than one predecessor associate to each operand a "Pending"
 // assessment. The pending assessment remembers the operand and block where it
 // was created. Then, when the value is used (which may be as a different
 // operand, because of moves), we check that the virtual register at the use
 // site matches the definition of this pending operand: either the phi inputs
 // match, or, if it's not a phi, all the predecessors at the point the pending
 // assessment was defined have that operand assigned to the given virtual
 // register. If all checks out, we record in the assessment that the virtual
 // register is aliased by the specific operand.
 // If a block is a loop header - so one or more of its predecessors are it or
 // below - we still treat uses of operands as above, but we record which operand
 // assessments haven't been made yet, and what virtual register they must
 // correspond to, and verify that when we are done with the respective
 // predecessor blocks.
 // This way, the algorithm always makes a final decision about the operands
 // in an instruction, ensuring convergence.
 // Operand assessments are recorded per block, as the result at the exit from
 // the block. When moving to a new block, we copy assessments from its single
 // predecessor, or, if the block has multiple predecessors, the mechanism was
 // described already.

 enum AssessmentKind { Final, Pending };

 class Assessment : public ZoneObject {
  public:
   AssessmentKind kind() const { return kind_; }

  protected:
   explicit Assessment(AssessmentKind kind) : kind_(kind) {}
   AssessmentKind kind_;

  private:
   DISALLOW_COPY_AND_ASSIGN(Assessment);
 };

 // PendingAssessments are associated to operands coming from the multiple
 // predecessors of a block. We only record the operand and the block, and
 // will determine if the way the operand is defined (from the predecessors)
 // matches a particular use. We allow more than one vreg association with
 // an operand - this handles scenarios where multiple phis are
 // defined with identical operands, and the move optimizer moved down the moves
 // separating the 2 phis in the block defining them.
 class PendingAssessment final : public Assessment {
  public:
   explicit PendingAssessment(Zone* zone, const InstructionBlock* origin,
                              InstructionOperand operand)
       : Assessment(Pending),
         origin_(origin),
         operand_(operand),
         aliases_(zone) {}

   static const PendingAssessment* cast(const Assessment* assessment) {
     CHECK(assessment->kind() == Pending);
     return static_cast<const PendingAssessment*>(assessment);
   }

   static PendingAssessment* cast(Assessment* assessment) {
     CHECK(assessment->kind() == Pending);
     return static_cast<PendingAssessment*>(assessment);
   }

   const InstructionBlock* origin() const { return origin_; }
   InstructionOperand operand() const { return operand_; }
   bool IsAliasOf(int vreg) const { return aliases_.count(vreg) > 0; }
   void AddAlias(int vreg) { aliases_.insert(vreg); }

  private:
   const InstructionBlock* const origin_;
   InstructionOperand operand_;
   ZoneSet<int> aliases_;

   DISALLOW_COPY_AND_ASSIGN(PendingAssessment);
 };

 // FinalAssessments are associated to operands that we know to be a certain
 // virtual register.
 class FinalAssessment final : public Assessment {
  public:
   explicit FinalAssessment(int virtual_register)
       : Assessment(Final), virtual_register_(virtual_register) {}

   int virtual_register() const { return virtual_register_; }
   static const FinalAssessment* cast(const Assessment* assessment) {
     CHECK(assessment->kind() == Final);
     return static_cast<const FinalAssessment*>(assessment);
   }

  private:
   int virtual_register_;

   DISALLOW_COPY_AND_ASSIGN(FinalAssessment);
 };

 struct OperandAsKeyLess {
   bool operator()(const InstructionOperand& a,
                   const InstructionOperand& b) const {
     return a.CompareCanonicalized(b);
   }
 };

 // Assessments associated with a basic block.
 class BlockAssessments : public ZoneObject {
  public:
   typedef ZoneMap<InstructionOperand, Assessment*, OperandAsKeyLess> OperandMap;
   explicit BlockAssessments(Zone* zone)
       : map_(zone), map_for_moves_(zone), zone_(zone) {}
   void Drop(InstructionOperand operand) { map_.erase(operand); }
   void DropRegisters();
   void AddDefinition(InstructionOperand operand, int virtual_register) {
     auto existent = map_.find(operand);
     if (existent != map_.end()) {
       // Drop the assignment
       map_.erase(existent);
     }
     map_.insert(
         std::make_pair(operand, new (zone_) FinalAssessment(virtual_register)));
   }

   void PerformMoves(const Instruction* instruction);
   void PerformParallelMoves(const ParallelMove* moves);
   void CopyFrom(const BlockAssessments* other) {
     CHECK(map_.empty());
     CHECK_NOT_NULL(other);
     map_.insert(other->map_.begin(), other->map_.end());
   }

   OperandMap& map() { return map_; }
   const OperandMap& map() const { return map_; }
   void Print() const;

  private:
   OperandMap map_;
   OperandMap map_for_moves_;
   Zone* zone_;

   DISALLOW_COPY_AND_ASSIGN(BlockAssessments);
 };

 class RegisterAllocatorVerifier final : public ZoneObject {
  public:
   RegisterAllocatorVerifier(Zone* zone, const RegisterConfiguration* config,
                             const InstructionSequence* sequence);

   void VerifyAssignment(const char* caller_info);
   void VerifyGapMoves();

  private:
   enum ConstraintType {
     kConstant,
     kImmediate,
     kRegister,
     kFixedRegister,
     kFPRegister,
     kFixedFPRegister,
     kSlot,
     kFixedSlot,
     kNone,
     kNoneFP,
     kExplicit,
     kSameAsFirst,
     kRegisterAndSlot
   };

   struct OperandConstraint {
     ConstraintType type_;
     // Constant or immediate value, register code, slot index, or slot size
     // when relevant.
     int value_;
     int spilled_slot_;
     int virtual_register_;
   };

   struct InstructionConstraint {
     const Instruction* instruction_;
     size_t operand_constaints_size_;
     OperandConstraint* operand_constraints_;
   };

   typedef ZoneVector<InstructionConstraint> Constraints;

   class DelayedAssessments : public ZoneObject {
    public:
     explicit DelayedAssessments(Zone* zone) : map_(zone) {}

     const ZoneMap<InstructionOperand, int, OperandAsKeyLess>& map() const {
       return map_;
     }

     void AddDelayedAssessment(InstructionOperand op, int vreg) {
       auto it = map_.find(op);
       if (it == map_.end()) {
         map_.insert(std::make_pair(op, vreg));
       } else {
         CHECK_EQ(it->second, vreg);
       }
     }

    private:
     ZoneMap<InstructionOperand, int, OperandAsKeyLess> map_;
   };

   Zone* zone() const { return zone_; }
   const RegisterConfiguration* config() { return config_; }
   const InstructionSequence* sequence() const { return sequence_; }
   Constraints* constraints() { return &constraints_; }

   static void VerifyInput(const OperandConstraint& constraint);
   static void VerifyTemp(const OperandConstraint& constraint);
   static void VerifyOutput(const OperandConstraint& constraint);

   void BuildConstraint(const InstructionOperand* op,
                        OperandConstraint* constraint);
   void CheckConstraint(const InstructionOperand* op,
                        const OperandConstraint* constraint);
   BlockAssessments* CreateForBlock(const InstructionBlock* block);

   // Prove that this operand is an alias of this virtual register in the given
   // block. Update the assessment if that's the case.
   void ValidatePendingAssessment(RpoNumber block_id, InstructionOperand op,
                                  const BlockAssessments* current_assessments,
                                  PendingAssessment* const assessment,
                                  int virtual_register);
   void ValidateUse(RpoNumber block_id, BlockAssessments* current_assessments,
                    InstructionOperand op, int virtual_register);

   Zone* const zone_;
   const RegisterConfiguration* config_;
   const InstructionSequence* const sequence_;
   Constraints constraints_;
   ZoneMap<RpoNumber, BlockAssessments*> assessments_;
   ZoneMap<RpoNumber, DelayedAssessments*> outstanding_assessments_;
   // TODO(chromium:725559): remove after we understand this bug's root cause.
   const char* caller_info_ = nullptr;

   DISALLOW_COPY_AND_ASSIGN(RegisterAllocatorVerifier);
 };

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8

 #endif
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_REGISTER_ALLOCATOR_VERIFIER_H_
	#define V8_REGISTER_ALLOCATOR_VERIFIER_H_

	#include "src/compiler/instruction.h"
	#include "src/zone/zone-containers.h"

	namespace v8 {
	namespace internal {
	namespace compiler {

	class InstructionBlock;
	class InstructionSequence;

	// The register allocator validator traverses instructions in the instruction
	// sequence, and verifies the correctness of machine operand substitutions of
	// virtual registers. It collects the virtual register instruction signatures
	// before register allocation. Then, after the register allocation pipeline
	// completes, it compares the operand substitutions against the pre-allocation
	// data.
	// At a high level, validation works as follows: we iterate through each block,
	// and, in a block, through each instruction; then:
	// - when an operand is the output of an instruction, we associate it to the
	// virtual register that the instruction sequence declares as its output. We
	// use the concept of "FinalAssessment" to model this.
	// - when an operand is used in an instruction, we check that the assessment
	// matches the expectation of the instruction
	// - moves simply copy the assessment over to the new operand
	// - blocks with more than one predecessor associate to each operand a "Pending"
	// assessment. The pending assessment remembers the operand and block where it
	// was created. Then, when the value is used (which may be as a different
	// operand, because of moves), we check that the virtual register at the use
	// site matches the definition of this pending operand: either the phi inputs
	// match, or, if it's not a phi, all the predecessors at the point the pending
	// assessment was defined have that operand assigned to the given virtual
	// register. If all checks out, we record in the assessment that the virtual
	// register is aliased by the specific operand.
	// If a block is a loop header - so one or more of its predecessors are it or
	// below - we still treat uses of operands as above, but we record which operand
	// assessments haven't been made yet, and what virtual register they must
	// correspond to, and verify that when we are done with the respective
	// predecessor blocks.
	// This way, the algorithm always makes a final decision about the operands
	// in an instruction, ensuring convergence.
	// Operand assessments are recorded per block, as the result at the exit from
	// the block. When moving to a new block, we copy assessments from its single
	// predecessor, or, if the block has multiple predecessors, the mechanism was
	// described already.

	enum AssessmentKind { Final, Pending };

	class Assessment : public ZoneObject {
	public:
	AssessmentKind kind() const { return kind_; }

	protected:
	explicit Assessment(AssessmentKind kind) : kind_(kind) {}
	AssessmentKind kind_;

	private:
	DISALLOW_COPY_AND_ASSIGN(Assessment);
	};

	// PendingAssessments are associated to operands coming from the multiple
	// predecessors of a block. We only record the operand and the block, and
	// will determine if the way the operand is defined (from the predecessors)
	// matches a particular use. We allow more than one vreg association with
	// an operand - this handles scenarios where multiple phis are
	// defined with identical operands, and the move optimizer moved down the moves
	// separating the 2 phis in the block defining them.
	class PendingAssessment final : public Assessment {
	public:
	explicit PendingAssessment(Zone* zone, const InstructionBlock* origin,
	InstructionOperand operand)
	: Assessment(Pending),
	origin_(origin),
	operand_(operand),
	aliases_(zone) {}

	static const PendingAssessment* cast(const Assessment* assessment) {
	CHECK(assessment->kind() == Pending);
	return static_cast<const PendingAssessment*>(assessment);
	}

	static PendingAssessment* cast(Assessment* assessment) {
	CHECK(assessment->kind() == Pending);
	return static_cast<PendingAssessment*>(assessment);
	}

	const InstructionBlock* origin() const { return origin_; }
	InstructionOperand operand() const { return operand_; }
	bool IsAliasOf(int vreg) const { return aliases_.count(vreg) > 0; }
	void AddAlias(int vreg) { aliases_.insert(vreg); }

	private:
	const InstructionBlock* const origin_;
	InstructionOperand operand_;
	ZoneSet<int> aliases_;

	DISALLOW_COPY_AND_ASSIGN(PendingAssessment);
	};

	// FinalAssessments are associated to operands that we know to be a certain
	// virtual register.
	class FinalAssessment final : public Assessment {
	public:
	explicit FinalAssessment(int virtual_register)
	: Assessment(Final), virtual_register_(virtual_register) {}

	int virtual_register() const { return virtual_register_; }
	static const FinalAssessment* cast(const Assessment* assessment) {
	CHECK(assessment->kind() == Final);
	return static_cast<const FinalAssessment*>(assessment);
	}

	private:
	int virtual_register_;

	DISALLOW_COPY_AND_ASSIGN(FinalAssessment);
	};

	struct OperandAsKeyLess {
	bool operator()(const InstructionOperand& a,
	const InstructionOperand& b) const {
	return a.CompareCanonicalized(b);
	}
	};

	// Assessments associated with a basic block.
	class BlockAssessments : public ZoneObject {
	public:
	typedef ZoneMap<InstructionOperand, Assessment*, OperandAsKeyLess> OperandMap;
	explicit BlockAssessments(Zone* zone)
	: map_(zone), map_for_moves_(zone), zone_(zone) {}
	void Drop(InstructionOperand operand) { map_.erase(operand); }
	void DropRegisters();
	void AddDefinition(InstructionOperand operand, int virtual_register) {
	auto existent = map_.find(operand);
	if (existent != map_.end()) {
	// Drop the assignment
	map_.erase(existent);
	}
	map_.insert(
	std::make_pair(operand, new (zone_) FinalAssessment(virtual_register)));
	}

	void PerformMoves(const Instruction* instruction);
	void PerformParallelMoves(const ParallelMove* moves);
	void CopyFrom(const BlockAssessments* other) {
	CHECK(map_.empty());
	CHECK_NOT_NULL(other);
	map_.insert(other->map_.begin(), other->map_.end());
	}

	OperandMap& map() { return map_; }
	const OperandMap& map() const { return map_; }
	void Print() const;

	private:
	OperandMap map_;
	OperandMap map_for_moves_;
	Zone* zone_;

	DISALLOW_COPY_AND_ASSIGN(BlockAssessments);
	};

	class RegisterAllocatorVerifier final : public ZoneObject {
	public:
	RegisterAllocatorVerifier(Zone* zone, const RegisterConfiguration* config,
	const InstructionSequence* sequence);

	void VerifyAssignment(const char* caller_info);
	void VerifyGapMoves();

	private:
	enum ConstraintType {
	kConstant,
	kImmediate,
	kRegister,
	kFixedRegister,
	kFPRegister,
	kFixedFPRegister,
	kSlot,
	kFixedSlot,
	kNone,
	kNoneFP,
	kExplicit,
	kSameAsFirst,
	kRegisterAndSlot
	};

	struct OperandConstraint {
	ConstraintType type_;
	// Constant or immediate value, register code, slot index, or slot size
	// when relevant.
	int value_;
	int spilled_slot_;
	int virtual_register_;
	};

	struct InstructionConstraint {
	const Instruction* instruction_;
	size_t operand_constaints_size_;
	OperandConstraint* operand_constraints_;
	};

	typedef ZoneVector<InstructionConstraint> Constraints;

	class DelayedAssessments : public ZoneObject {
	public:
	explicit DelayedAssessments(Zone* zone) : map_(zone) {}

	const ZoneMap<InstructionOperand, int, OperandAsKeyLess>& map() const {
	return map_;
	}

	void AddDelayedAssessment(InstructionOperand op, int vreg) {
	auto it = map_.find(op);
	if (it == map_.end()) {
	map_.insert(std::make_pair(op, vreg));
	} else {
	CHECK_EQ(it->second, vreg);
	}
	}

	private:
	ZoneMap<InstructionOperand, int, OperandAsKeyLess> map_;
	};

	Zone* zone() const { return zone_; }
	const RegisterConfiguration* config() { return config_; }
	const InstructionSequence* sequence() const { return sequence_; }
	Constraints* constraints() { return &constraints_; }

	static void VerifyInput(const OperandConstraint& constraint);
	static void VerifyTemp(const OperandConstraint& constraint);
	static void VerifyOutput(const OperandConstraint& constraint);

	void BuildConstraint(const InstructionOperand* op,
	OperandConstraint* constraint);
	void CheckConstraint(const InstructionOperand* op,
	const OperandConstraint* constraint);
	BlockAssessments* CreateForBlock(const InstructionBlock* block);

	// Prove that this operand is an alias of this virtual register in the given
	// block. Update the assessment if that's the case.
	void ValidatePendingAssessment(RpoNumber block_id, InstructionOperand op,
	const BlockAssessments* current_assessments,
	PendingAssessment* const assessment,
	int virtual_register);
	void ValidateUse(RpoNumber block_id, BlockAssessments* current_assessments,
	InstructionOperand op, int virtual_register);

	Zone* const zone_;
	const RegisterConfiguration* config_;
	const InstructionSequence* const sequence_;
	Constraints constraints_;
	ZoneMap<RpoNumber, BlockAssessments*> assessments_;
	ZoneMap<RpoNumber, DelayedAssessments*> outstanding_assessments_;
	// TODO(chromium:725559): remove after we understand this bug's root cause.
	const char* caller_info_ = nullptr;

	DISALLOW_COPY_AND_ASSIGN(RegisterAllocatorVerifier);
	};

	} // namespace compiler
	} // namespace internal
	} // namespace v8

	#endif