src/hydrogen-removable-simulates.cc - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2013 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/hydrogen-flow-engine.h"
 #include "src/hydrogen-instructions.h"
 #include "src/hydrogen-removable-simulates.h"

 namespace v8 {
 namespace internal {

 class State : public ZoneObject {
  public:
   explicit State(Zone* zone)
       : zone_(zone), mergelist_(2, zone), first_(true), mode_(NORMAL) { }

   State* Process(HInstruction* instr, Zone* zone) {
     if (FLAG_trace_removable_simulates) {
       PrintF("[%s with state %p in B%d: #%d %s]\n",
              mode_ == NORMAL ? "processing" : "collecting",
              reinterpret_cast<void*>(this), instr->block()->block_id(),
              instr->id(), instr->Mnemonic());
     }
     // Forward-merge "trains" of simulates after an instruction with observable
     // side effects to keep live ranges short.
     if (mode_ == COLLECT_CONSECUTIVE_SIMULATES) {
       if (instr->IsSimulate()) {
         HSimulate* current_simulate = HSimulate::cast(instr);
         if (current_simulate->is_candidate_for_removal() &&
             !current_simulate->ast_id().IsNone()) {
           Remember(current_simulate);
           return this;
         }
       }
       FlushSimulates();
       mode_ = NORMAL;
     }
     // Ensure there's a non-foldable HSimulate before an HEnterInlined to avoid
     // folding across HEnterInlined.
     DCHECK(!(instr->IsEnterInlined() &&
              HSimulate::cast(instr->previous())->is_candidate_for_removal()));
     if (instr->IsLeaveInlined() || instr->IsReturn()) {
       // Never fold simulates from inlined environments into simulates in the
       // outer environment. Simply remove all accumulated simulates without
       // merging. This is safe because simulates after instructions with side
       // effects are never added to the merge list. The same reasoning holds for
       // return instructions.
       RemoveSimulates();
       return this;
     }
     if (instr->IsControlInstruction()) {
       // Merge the accumulated simulates at the end of the block.
       FlushSimulates();
       return this;
     }
     if (instr->IsCapturedObject()) {
       // Do not merge simulates across captured objects - captured objects
       // change environments during environment replay, and such changes
       // would not be reflected in the simulate.
       FlushSimulates();
       return this;
     }
     // Skip the non-simulates and the first simulate.
     if (!instr->IsSimulate()) return this;
     if (first_) {
       first_ = false;
       return this;
     }
     HSimulate* current_simulate = HSimulate::cast(instr);
     if (!current_simulate->is_candidate_for_removal()) {
       Remember(current_simulate);
       FlushSimulates();
     } else if (current_simulate->ast_id().IsNone()) {
       DCHECK(current_simulate->next()->IsEnterInlined());
       FlushSimulates();
     } else if (current_simulate->previous()->HasObservableSideEffects()) {
       Remember(current_simulate);
       mode_ = COLLECT_CONSECUTIVE_SIMULATES;
     } else {
       Remember(current_simulate);
     }

     return this;
   }

   static State* Merge(State* succ_state,
                       HBasicBlock* succ_block,
                       State* pred_state,
                       HBasicBlock* pred_block,
                       Zone* zone) {
     return (succ_state == NULL)
         ? pred_state->Copy(succ_block, pred_block, zone)
         : succ_state->Merge(succ_block, pred_state, pred_block, zone);
   }

   static State* Finish(State* state, HBasicBlock* block, Zone* zone) {
     if (FLAG_trace_removable_simulates) {
       PrintF("[preparing state %p for B%d]\n", reinterpret_cast<void*>(state),
              block->block_id());
     }
     // For our current local analysis, we should not remember simulates across
     // block boundaries.
     DCHECK(!state->HasRememberedSimulates());
     // Nasty heuristic: Never remove the first simulate in a block. This
     // just so happens to have a beneficial effect on register allocation.
     state->first_ = true;
     return state;
   }

  private:
   explicit State(const State& other)
       : zone_(other.zone_),
         mergelist_(other.mergelist_, other.zone_),
         first_(other.first_),
         mode_(other.mode_) { }

   enum Mode { NORMAL, COLLECT_CONSECUTIVE_SIMULATES };

   bool HasRememberedSimulates() const { return !mergelist_.is_empty(); }

   void Remember(HSimulate* sim) {
     mergelist_.Add(sim, zone_);
   }

   void FlushSimulates() {
     if (HasRememberedSimulates()) {
       mergelist_.RemoveLast()->MergeWith(&mergelist_);
     }
   }

   void RemoveSimulates() {
     while (HasRememberedSimulates()) {
       mergelist_.RemoveLast()->DeleteAndReplaceWith(NULL);
     }
   }

   State* Copy(HBasicBlock* succ_block, HBasicBlock* pred_block, Zone* zone) {
     State* copy = new(zone) State(*this);
     if (FLAG_trace_removable_simulates) {
       PrintF("[copy state %p from B%d to new state %p for B%d]\n",
              reinterpret_cast<void*>(this), pred_block->block_id(),
              reinterpret_cast<void*>(copy), succ_block->block_id());
     }
     return copy;
   }

   State* Merge(HBasicBlock* succ_block,
                State* pred_state,
                HBasicBlock* pred_block,
                Zone* zone) {
     // For our current local analysis, we should not remember simulates across
     // block boundaries.
     DCHECK(!pred_state->HasRememberedSimulates());
     DCHECK(!HasRememberedSimulates());
     if (FLAG_trace_removable_simulates) {
       PrintF("[merge state %p from B%d into %p for B%d]\n",
              reinterpret_cast<void*>(pred_state), pred_block->block_id(),
              reinterpret_cast<void*>(this), succ_block->block_id());
     }
     return this;
   }

   Zone* zone_;
   ZoneList<HSimulate*> mergelist_;
   bool first_;
   Mode mode_;
 };


 // We don't use effects here.
 class Effects : public ZoneObject {
  public:
   explicit Effects(Zone* zone) { }
   bool Disabled() { return true; }
   void Process(HInstruction* instr, Zone* zone) { }
   void Apply(State* state) { }
   void Union(Effects* that, Zone* zone) { }
 };


 void HMergeRemovableSimulatesPhase::Run() {
   HFlowEngine<State, Effects> engine(graph(), zone());
   State* state = new(zone()) State(zone());
   engine.AnalyzeDominatedBlocks(graph()->blocks()->at(0), state);
 }

 } }  // namespace v8::internal
	// Copyright 2013 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/hydrogen-flow-engine.h"
	#include "src/hydrogen-instructions.h"
	#include "src/hydrogen-removable-simulates.h"

	namespace v8 {
	namespace internal {

	class State : public ZoneObject {
	public:
	explicit State(Zone* zone)
	: zone_(zone), mergelist_(2, zone), first_(true), mode_(NORMAL) { }

	State* Process(HInstruction* instr, Zone* zone) {
	if (FLAG_trace_removable_simulates) {
	PrintF("[%s with state %p in B%d: #%d %s]\n",
	mode_ == NORMAL ? "processing" : "collecting",
	reinterpret_cast<void*>(this), instr->block()->block_id(),
	instr->id(), instr->Mnemonic());
	}
	// Forward-merge "trains" of simulates after an instruction with observable
	// side effects to keep live ranges short.
	if (mode_ == COLLECT_CONSECUTIVE_SIMULATES) {
	if (instr->IsSimulate()) {
	HSimulate* current_simulate = HSimulate::cast(instr);
	if (current_simulate->is_candidate_for_removal() &&
	!current_simulate->ast_id().IsNone()) {
	Remember(current_simulate);
	return this;
	}
	}
	FlushSimulates();
	mode_ = NORMAL;
	}
	// Ensure there's a non-foldable HSimulate before an HEnterInlined to avoid
	// folding across HEnterInlined.
	DCHECK(!(instr->IsEnterInlined() &&
	HSimulate::cast(instr->previous())->is_candidate_for_removal()));
	if (instr->IsLeaveInlined() \|\| instr->IsReturn()) {
	// Never fold simulates from inlined environments into simulates in the
	// outer environment. Simply remove all accumulated simulates without
	// merging. This is safe because simulates after instructions with side
	// effects are never added to the merge list. The same reasoning holds for
	// return instructions.
	RemoveSimulates();
	return this;
	}
	if (instr->IsControlInstruction()) {
	// Merge the accumulated simulates at the end of the block.
	FlushSimulates();
	return this;
	}
	if (instr->IsCapturedObject()) {
	// Do not merge simulates across captured objects - captured objects
	// change environments during environment replay, and such changes
	// would not be reflected in the simulate.
	FlushSimulates();
	return this;
	}
	// Skip the non-simulates and the first simulate.
	if (!instr->IsSimulate()) return this;
	if (first_) {
	first_ = false;
	return this;
	}
	HSimulate* current_simulate = HSimulate::cast(instr);
	if (!current_simulate->is_candidate_for_removal()) {
	Remember(current_simulate);
	FlushSimulates();
	} else if (current_simulate->ast_id().IsNone()) {
	DCHECK(current_simulate->next()->IsEnterInlined());
	FlushSimulates();
	} else if (current_simulate->previous()->HasObservableSideEffects()) {
	Remember(current_simulate);
	mode_ = COLLECT_CONSECUTIVE_SIMULATES;
	} else {
	Remember(current_simulate);
	}

	return this;
	}

	static State* Merge(State* succ_state,
	HBasicBlock* succ_block,
	State* pred_state,
	HBasicBlock* pred_block,
	Zone* zone) {
	return (succ_state == NULL)
	? pred_state->Copy(succ_block, pred_block, zone)
	: succ_state->Merge(succ_block, pred_state, pred_block, zone);
	}

	static State* Finish(State* state, HBasicBlock* block, Zone* zone) {
	if (FLAG_trace_removable_simulates) {
	PrintF("[preparing state %p for B%d]\n", reinterpret_cast<void*>(state),
	block->block_id());
	}
	// For our current local analysis, we should not remember simulates across
	// block boundaries.
	DCHECK(!state->HasRememberedSimulates());
	// Nasty heuristic: Never remove the first simulate in a block. This
	// just so happens to have a beneficial effect on register allocation.
	state->first_ = true;
	return state;
	}

	private:
	explicit State(const State& other)
	: zone_(other.zone_),
	mergelist_(other.mergelist_, other.zone_),
	first_(other.first_),
	mode_(other.mode_) { }

	enum Mode { NORMAL, COLLECT_CONSECUTIVE_SIMULATES };

	bool HasRememberedSimulates() const { return !mergelist_.is_empty(); }

	void Remember(HSimulate* sim) {
	mergelist_.Add(sim, zone_);
	}

	void FlushSimulates() {
	if (HasRememberedSimulates()) {
	mergelist_.RemoveLast()->MergeWith(&mergelist_);
	}
	}

	void RemoveSimulates() {
	while (HasRememberedSimulates()) {
	mergelist_.RemoveLast()->DeleteAndReplaceWith(NULL);
	}
	}

	State* Copy(HBasicBlock* succ_block, HBasicBlock* pred_block, Zone* zone) {
	State* copy = new(zone) State(*this);
	if (FLAG_trace_removable_simulates) {
	PrintF("[copy state %p from B%d to new state %p for B%d]\n",
	reinterpret_cast<void*>(this), pred_block->block_id(),
	reinterpret_cast<void*>(copy), succ_block->block_id());
	}
	return copy;
	}

	State* Merge(HBasicBlock* succ_block,
	State* pred_state,
	HBasicBlock* pred_block,
	Zone* zone) {
	// For our current local analysis, we should not remember simulates across
	// block boundaries.
	DCHECK(!pred_state->HasRememberedSimulates());
	DCHECK(!HasRememberedSimulates());
	if (FLAG_trace_removable_simulates) {
	PrintF("[merge state %p from B%d into %p for B%d]\n",
	reinterpret_cast<void*>(pred_state), pred_block->block_id(),
	reinterpret_cast<void*>(this), succ_block->block_id());
	}
	return this;
	}

	Zone* zone_;
	ZoneList<HSimulate*> mergelist_;
	bool first_;
	Mode mode_;
	};


	// We don't use effects here.
	class Effects : public ZoneObject {
	public:
	explicit Effects(Zone* zone) { }
	bool Disabled() { return true; }
	void Process(HInstruction* instr, Zone* zone) { }
	void Apply(State* state) { }
	void Union(Effects* that, Zone* zone) { }
	};


	void HMergeRemovableSimulatesPhase::Run() {
	HFlowEngine<State, Effects> engine(graph(), zone());
	State* state = new(zone()) State(zone());
	engine.AnalyzeDominatedBlocks(graph()->blocks()->at(0), state);
	}

	} } // namespace v8::internal