// 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. #include "src/compiler/backend/register-allocator-verifier.h" #include "src/compiler/backend/instruction.h" #include "src/utils/bit-vector.h" #include "src/utils/ostreams.h" namespace v8 { namespace internal { namespace compiler { namespace { size_t OperandCount(const Instruction* instr) { return instr->InputCount() + instr->OutputCount() + instr->TempCount(); } void VerifyEmptyGaps(const Instruction* instr) { for (int i = Instruction::FIRST_GAP_POSITION; i <= Instruction::LAST_GAP_POSITION; i++) { Instruction::GapPosition inner_pos = static_cast(i); CHECK_NULL(instr->GetParallelMove(inner_pos)); } } void VerifyAllocatedGaps(const Instruction* instr, const char* caller_info) { for (int i = Instruction::FIRST_GAP_POSITION; i <= Instruction::LAST_GAP_POSITION; i++) { Instruction::GapPosition inner_pos = static_cast(i); const ParallelMove* moves = instr->GetParallelMove(inner_pos); if (moves == nullptr) continue; for (const MoveOperands* move : *moves) { if (move->IsRedundant()) continue; CHECK_WITH_MSG( move->source().IsAllocated() || move->source().IsConstant(), caller_info); CHECK_WITH_MSG(move->destination().IsAllocated(), caller_info); } } } } // namespace RegisterAllocatorVerifier::RegisterAllocatorVerifier( Zone* zone, const RegisterConfiguration* config, const InstructionSequence* sequence) : zone_(zone), config_(config), sequence_(sequence), constraints_(zone), assessments_(zone), outstanding_assessments_(zone) { constraints_.reserve(sequence->instructions().size()); // TODO(dcarney): model unique constraints. // Construct OperandConstraints for all InstructionOperands, eliminating // kSameAsFirst along the way. for (const Instruction* instr : sequence->instructions()) { // All gaps should be totally unallocated at this point. VerifyEmptyGaps(instr); const size_t operand_count = OperandCount(instr); OperandConstraint* op_constraints = zone->NewArray(operand_count); size_t count = 0; for (size_t i = 0; i < instr->InputCount(); ++i, ++count) { BuildConstraint(instr->InputAt(i), &op_constraints[count]); VerifyInput(op_constraints[count]); } for (size_t i = 0; i < instr->TempCount(); ++i, ++count) { BuildConstraint(instr->TempAt(i), &op_constraints[count]); VerifyTemp(op_constraints[count]); } for (size_t i = 0; i < instr->OutputCount(); ++i, ++count) { BuildConstraint(instr->OutputAt(i), &op_constraints[count]); if (op_constraints[count].type_ == kSameAsFirst) { CHECK_LT(0, instr->InputCount()); op_constraints[count].type_ = op_constraints[0].type_; op_constraints[count].value_ = op_constraints[0].value_; } VerifyOutput(op_constraints[count]); } InstructionConstraint instr_constraint = {instr, operand_count, op_constraints}; constraints()->push_back(instr_constraint); } } void RegisterAllocatorVerifier::VerifyInput( const OperandConstraint& constraint) { CHECK_NE(kSameAsFirst, constraint.type_); if (constraint.type_ != kImmediate) { CHECK_NE(InstructionOperand::kInvalidVirtualRegister, constraint.virtual_register_); } } void RegisterAllocatorVerifier::VerifyTemp( const OperandConstraint& constraint) { CHECK_NE(kSameAsFirst, constraint.type_); CHECK_NE(kImmediate, constraint.type_); CHECK_NE(kConstant, constraint.type_); } void RegisterAllocatorVerifier::VerifyOutput( const OperandConstraint& constraint) { CHECK_NE(kImmediate, constraint.type_); CHECK_NE(InstructionOperand::kInvalidVirtualRegister, constraint.virtual_register_); } void RegisterAllocatorVerifier::VerifyAssignment(const char* caller_info) { caller_info_ = caller_info; CHECK(sequence()->instructions().size() == constraints()->size()); auto instr_it = sequence()->begin(); for (const auto& instr_constraint : *constraints()) { const Instruction* instr = instr_constraint.instruction_; // All gaps should be totally allocated at this point. VerifyAllocatedGaps(instr, caller_info_); const size_t operand_count = instr_constraint.operand_constaints_size_; const OperandConstraint* op_constraints = instr_constraint.operand_constraints_; CHECK_EQ(instr, *instr_it); CHECK(operand_count == OperandCount(instr)); size_t count = 0; for (size_t i = 0; i < instr->InputCount(); ++i, ++count) { CheckConstraint(instr->InputAt(i), &op_constraints[count]); } for (size_t i = 0; i < instr->TempCount(); ++i, ++count) { CheckConstraint(instr->TempAt(i), &op_constraints[count]); } for (size_t i = 0; i < instr->OutputCount(); ++i, ++count) { CheckConstraint(instr->OutputAt(i), &op_constraints[count]); } ++instr_it; } } void RegisterAllocatorVerifier::BuildConstraint(const InstructionOperand* op, OperandConstraint* constraint) { constraint->value_ = kMinInt; constraint->virtual_register_ = InstructionOperand::kInvalidVirtualRegister; if (op->IsConstant()) { constraint->type_ = kConstant; constraint->value_ = ConstantOperand::cast(op)->virtual_register(); constraint->virtual_register_ = constraint->value_; } else if (op->IsImmediate()) { const ImmediateOperand* imm = ImmediateOperand::cast(op); int value = imm->type() == ImmediateOperand::INLINE ? imm->inline_value() : imm->indexed_value(); constraint->type_ = kImmediate; constraint->value_ = value; } else { CHECK(op->IsUnallocated()); const UnallocatedOperand* unallocated = UnallocatedOperand::cast(op); int vreg = unallocated->virtual_register(); constraint->virtual_register_ = vreg; if (unallocated->basic_policy() == UnallocatedOperand::FIXED_SLOT) { constraint->type_ = kFixedSlot; constraint->value_ = unallocated->fixed_slot_index(); } else { switch (unallocated->extended_policy()) { case UnallocatedOperand::REGISTER_OR_SLOT: case UnallocatedOperand::NONE: if (sequence()->IsFP(vreg)) { constraint->type_ = kRegisterOrSlotFP; } else { constraint->type_ = kRegisterOrSlot; } break; case UnallocatedOperand::REGISTER_OR_SLOT_OR_CONSTANT: DCHECK(!sequence()->IsFP(vreg)); constraint->type_ = kRegisterOrSlotOrConstant; break; case UnallocatedOperand::FIXED_REGISTER: if (unallocated->HasSecondaryStorage()) { constraint->type_ = kRegisterAndSlot; constraint->spilled_slot_ = unallocated->GetSecondaryStorage(); } else { constraint->type_ = kFixedRegister; } constraint->value_ = unallocated->fixed_register_index(); break; case UnallocatedOperand::FIXED_FP_REGISTER: constraint->type_ = kFixedFPRegister; constraint->value_ = unallocated->fixed_register_index(); break; case UnallocatedOperand::MUST_HAVE_REGISTER: if (sequence()->IsFP(vreg)) { constraint->type_ = kFPRegister; } else { constraint->type_ = kRegister; } break; case UnallocatedOperand::MUST_HAVE_SLOT: constraint->type_ = kSlot; constraint->value_ = ElementSizeLog2Of(sequence()->GetRepresentation(vreg)); break; case UnallocatedOperand::SAME_AS_FIRST_INPUT: constraint->type_ = kSameAsFirst; break; } } } } void RegisterAllocatorVerifier::CheckConstraint( const InstructionOperand* op, const OperandConstraint* constraint) { switch (constraint->type_) { case kConstant: CHECK_WITH_MSG(op->IsConstant(), caller_info_); CHECK_EQ(ConstantOperand::cast(op)->virtual_register(), constraint->value_); return; case kImmediate: { CHECK_WITH_MSG(op->IsImmediate(), caller_info_); const ImmediateOperand* imm = ImmediateOperand::cast(op); int value = imm->type() == ImmediateOperand::INLINE ? imm->inline_value() : imm->indexed_value(); CHECK_EQ(value, constraint->value_); return; } case kRegister: CHECK_WITH_MSG(op->IsRegister(), caller_info_); return; case kFPRegister: CHECK_WITH_MSG(op->IsFPRegister(), caller_info_); return; case kFixedRegister: case kRegisterAndSlot: CHECK_WITH_MSG(op->IsRegister(), caller_info_); CHECK_EQ(LocationOperand::cast(op)->register_code(), constraint->value_); return; case kFixedFPRegister: CHECK_WITH_MSG(op->IsFPRegister(), caller_info_); CHECK_EQ(LocationOperand::cast(op)->register_code(), constraint->value_); return; case kFixedSlot: CHECK_WITH_MSG(op->IsStackSlot() || op->IsFPStackSlot(), caller_info_); CHECK_EQ(LocationOperand::cast(op)->index(), constraint->value_); return; case kSlot: CHECK_WITH_MSG(op->IsStackSlot() || op->IsFPStackSlot(), caller_info_); CHECK_EQ(ElementSizeLog2Of(LocationOperand::cast(op)->representation()), constraint->value_); return; case kRegisterOrSlot: CHECK_WITH_MSG(op->IsRegister() || op->IsStackSlot(), caller_info_); return; case kRegisterOrSlotFP: CHECK_WITH_MSG(op->IsFPRegister() || op->IsFPStackSlot(), caller_info_); return; case kRegisterOrSlotOrConstant: CHECK_WITH_MSG(op->IsRegister() || op->IsStackSlot() || op->IsConstant(), caller_info_); return; case kSameAsFirst: CHECK_WITH_MSG(false, caller_info_); return; } } void BlockAssessments::PerformMoves(const Instruction* instruction) { const ParallelMove* first = instruction->GetParallelMove(Instruction::GapPosition::START); PerformParallelMoves(first); const ParallelMove* last = instruction->GetParallelMove(Instruction::GapPosition::END); PerformParallelMoves(last); } void BlockAssessments::PerformParallelMoves(const ParallelMove* moves) { if (moves == nullptr) return; CHECK(map_for_moves_.empty()); for (MoveOperands* move : *moves) { if (move->IsEliminated() || move->IsRedundant()) continue; auto it = map_.find(move->source()); // The RHS of a parallel move should have been already assessed. CHECK(it != map_.end()); // The LHS of a parallel move should not have been assigned in this // parallel move. CHECK(map_for_moves_.find(move->destination()) == map_for_moves_.end()); // Copy the assessment to the destination. map_for_moves_[move->destination()] = it->second; } for (auto pair : map_for_moves_) { map_[pair.first] = pair.second; } map_for_moves_.clear(); } void BlockAssessments::DropRegisters() { for (auto iterator = map().begin(), end = map().end(); iterator != end;) { auto current = iterator; ++iterator; InstructionOperand op = current->first; if (op.IsAnyRegister()) map().erase(current); } } void BlockAssessments::Print() const { StdoutStream os; for (const auto pair : map()) { const InstructionOperand op = pair.first; const Assessment* assessment = pair.second; // Use operator<< so we can write the assessment on the same // line. os << op << " : "; if (assessment->kind() == AssessmentKind::Final) { os << "v" << FinalAssessment::cast(assessment)->virtual_register(); } else { os << "P"; } os << std::endl; } os << std::endl; } BlockAssessments* RegisterAllocatorVerifier::CreateForBlock( const InstructionBlock* block) { RpoNumber current_block_id = block->rpo_number(); BlockAssessments* ret = new (zone()) BlockAssessments(zone()); if (block->PredecessorCount() == 0) { // TODO(mtrofin): the following check should hold, however, in certain // unit tests it is invalidated by the last block. Investigate and // normalize the CFG. // CHECK_EQ(0, current_block_id.ToInt()); // The phi size test below is because we can, technically, have phi // instructions with one argument. Some tests expose that, too. } else if (block->PredecessorCount() == 1 && block->phis().size() == 0) { const BlockAssessments* prev_block = assessments_[block->predecessors()[0]]; ret->CopyFrom(prev_block); } else { for (RpoNumber pred_id : block->predecessors()) { // For every operand coming from any of the predecessors, create an // Unfinalized assessment. auto iterator = assessments_.find(pred_id); if (iterator == assessments_.end()) { // This block is the head of a loop, and this predecessor is the // loopback // arc. // Validate this is a loop case, otherwise the CFG is malformed. CHECK(pred_id >= current_block_id); CHECK(block->IsLoopHeader()); continue; } const BlockAssessments* pred_assessments = iterator->second; CHECK_NOT_NULL(pred_assessments); for (auto pair : pred_assessments->map()) { InstructionOperand operand = pair.first; if (ret->map().find(operand) == ret->map().end()) { ret->map().insert(std::make_pair( operand, new (zone()) PendingAssessment(zone(), block, operand))); } } } } return ret; } void RegisterAllocatorVerifier::ValidatePendingAssessment( RpoNumber block_id, InstructionOperand op, const BlockAssessments* current_assessments, PendingAssessment* const assessment, int virtual_register) { if (assessment->IsAliasOf(virtual_register)) return; // When validating a pending assessment, it is possible some of the // assessments for the original operand (the one where the assessment was // created for first) are also pending. To avoid recursion, we use a work // list. To deal with cycles, we keep a set of seen nodes. Zone local_zone(zone()->allocator(), ZONE_NAME); ZoneQueue> worklist(&local_zone); ZoneSet seen(&local_zone); worklist.push(std::make_pair(assessment, virtual_register)); seen.insert(block_id); while (!worklist.empty()) { auto work = worklist.front(); const PendingAssessment* current_assessment = work.first; int current_virtual_register = work.second; InstructionOperand current_operand = current_assessment->operand(); worklist.pop(); const InstructionBlock* origin = current_assessment->origin(); CHECK(origin->PredecessorCount() > 1 || origin->phis().size() > 0); // Check if the virtual register is a phi first, instead of relying on // the incoming assessments. In particular, this handles the case // v1 = phi v0 v0, which structurally is identical to v0 having been // defined at the top of a diamond, and arriving at the node joining the // diamond's branches. const PhiInstruction* phi = nullptr; for (const PhiInstruction* candidate : origin->phis()) { if (candidate->virtual_register() == current_virtual_register) { phi = candidate; break; } } int op_index = 0; for (RpoNumber pred : origin->predecessors()) { int expected = phi != nullptr ? phi->operands()[op_index] : current_virtual_register; ++op_index; auto pred_assignment = assessments_.find(pred); if (pred_assignment == assessments_.end()) { CHECK(origin->IsLoopHeader()); auto todo_iter = outstanding_assessments_.find(pred); DelayedAssessments* set = nullptr; if (todo_iter == outstanding_assessments_.end()) { set = new (zone()) DelayedAssessments(zone()); outstanding_assessments_.insert(std::make_pair(pred, set)); } else { set = todo_iter->second; } set->AddDelayedAssessment(current_operand, expected); continue; } const BlockAssessments* pred_assessments = pred_assignment->second; auto found_contribution = pred_assessments->map().find(current_operand); CHECK(found_contribution != pred_assessments->map().end()); Assessment* contribution = found_contribution->second; switch (contribution->kind()) { case Final: CHECK_EQ(FinalAssessment::cast(contribution)->virtual_register(), expected); break; case Pending: { // This happens if we have a diamond feeding into another one, and // the inner one never being used - other than for carrying the value. const PendingAssessment* next = PendingAssessment::cast(contribution); if (seen.find(pred) == seen.end()) { worklist.push({next, expected}); seen.insert(pred); } // Note that we do not want to finalize pending assessments at the // beginning of a block - which is the information we'd have // available here. This is because this operand may be reused to // define duplicate phis. break; } } } } assessment->AddAlias(virtual_register); } void RegisterAllocatorVerifier::ValidateUse( RpoNumber block_id, BlockAssessments* current_assessments, InstructionOperand op, int virtual_register) { auto iterator = current_assessments->map().find(op); // We should have seen this operand before. CHECK(iterator != current_assessments->map().end()); Assessment* assessment = iterator->second; switch (assessment->kind()) { case Final: CHECK_EQ(FinalAssessment::cast(assessment)->virtual_register(), virtual_register); break; case Pending: { PendingAssessment* pending = PendingAssessment::cast(assessment); ValidatePendingAssessment(block_id, op, current_assessments, pending, virtual_register); break; } } } void RegisterAllocatorVerifier::VerifyGapMoves() { CHECK(assessments_.empty()); CHECK(outstanding_assessments_.empty()); const size_t block_count = sequence()->instruction_blocks().size(); for (size_t block_index = 0; block_index < block_count; ++block_index) { const InstructionBlock* block = sequence()->instruction_blocks()[block_index]; BlockAssessments* block_assessments = CreateForBlock(block); for (int instr_index = block->code_start(); instr_index < block->code_end(); ++instr_index) { const InstructionConstraint& instr_constraint = constraints_[instr_index]; const Instruction* instr = instr_constraint.instruction_; block_assessments->PerformMoves(instr); const OperandConstraint* op_constraints = instr_constraint.operand_constraints_; size_t count = 0; for (size_t i = 0; i < instr->InputCount(); ++i, ++count) { if (op_constraints[count].type_ == kImmediate) { continue; } int virtual_register = op_constraints[count].virtual_register_; InstructionOperand op = *instr->InputAt(i); ValidateUse(block->rpo_number(), block_assessments, op, virtual_register); } for (size_t i = 0; i < instr->TempCount(); ++i, ++count) { block_assessments->Drop(*instr->TempAt(i)); } if (instr->IsCall()) { block_assessments->DropRegisters(); } for (size_t i = 0; i < instr->OutputCount(); ++i, ++count) { int virtual_register = op_constraints[count].virtual_register_; block_assessments->AddDefinition(*instr->OutputAt(i), virtual_register); if (op_constraints[count].type_ == kRegisterAndSlot) { const AllocatedOperand* reg_op = AllocatedOperand::cast(instr->OutputAt(i)); MachineRepresentation rep = reg_op->representation(); const AllocatedOperand* stack_op = AllocatedOperand::New( zone(), LocationOperand::LocationKind::STACK_SLOT, rep, op_constraints[i].spilled_slot_); block_assessments->AddDefinition(*stack_op, virtual_register); } } } // Now commit the assessments for this block. If there are any delayed // assessments, ValidatePendingAssessment should see this block, too. assessments_[block->rpo_number()] = block_assessments; auto todo_iter = outstanding_assessments_.find(block->rpo_number()); if (todo_iter == outstanding_assessments_.end()) continue; DelayedAssessments* todo = todo_iter->second; for (auto pair : todo->map()) { InstructionOperand op = pair.first; int vreg = pair.second; auto found_op = block_assessments->map().find(op); CHECK(found_op != block_assessments->map().end()); switch (found_op->second->kind()) { case Final: CHECK_EQ(FinalAssessment::cast(found_op->second)->virtual_register(), vreg); break; case Pending: ValidatePendingAssessment(block->rpo_number(), op, block_assessments, PendingAssessment::cast(found_op->second), vreg); break; } } } } } // namespace compiler } // namespace internal } // namespace v8