src/hydrogen-load-elimination.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-alias-analysis.h"
 #include "src/hydrogen-load-elimination.h"
 #include "src/hydrogen-instructions.h"
 #include "src/hydrogen-flow-engine.h"

 namespace v8 {
 namespace internal {

 #define GLOBAL true
 #define TRACE(x) if (FLAG_trace_load_elimination) PrintF x

 static const int kMaxTrackedFields = 16;
 static const int kMaxTrackedObjects = 5;

 // An element in the field approximation list.
 class HFieldApproximation : public ZoneObject {
  public:  // Just a data blob.
   HValue* object_;
   HValue* last_value_;
   HFieldApproximation* next_;

   // Recursively copy the entire linked list of field approximations.
   HFieldApproximation* Copy(Zone* zone) {
     HFieldApproximation* copy = new(zone) HFieldApproximation();
     copy->object_ = this->object_;
     copy->last_value_ = this->last_value_;
     copy->next_ = this->next_ == NULL ? NULL : this->next_->Copy(zone);
     return copy;
   }
 };


 // The main datastructure used during load/store elimination. Each in-object
 // field is tracked separately. For each field, store a list of known field
 // values for known objects.
 class HLoadEliminationTable : public ZoneObject {
  public:
   HLoadEliminationTable(Zone* zone, HAliasAnalyzer* aliasing)
     : zone_(zone), fields_(kMaxTrackedFields, zone), aliasing_(aliasing) { }

   // The main processing of instructions.
   HLoadEliminationTable* Process(HInstruction* instr, Zone* zone) {
     switch (instr->opcode()) {
       case HValue::kLoadNamedField: {
         HLoadNamedField* l = HLoadNamedField::cast(instr);
         TRACE((" process L%d field %d (o%d)\n",
                instr->id(),
                FieldOf(l->access()),
                l->object()->ActualValue()->id()));
         HValue* result = load(l);
         if (result != instr && l->CanBeReplacedWith(result)) {
           // The load can be replaced with a previous load or a value.
           TRACE(("  replace L%d -> v%d\n", instr->id(), result->id()));
           instr->DeleteAndReplaceWith(result);
         }
         break;
       }
       case HValue::kStoreNamedField: {
         HStoreNamedField* s = HStoreNamedField::cast(instr);
         TRACE((" process S%d field %d (o%d) = v%d\n",
                instr->id(),
                FieldOf(s->access()),
                s->object()->ActualValue()->id(),
                s->value()->id()));
         HValue* result = store(s);
         if (result == NULL) {
           // The store is redundant. Remove it.
           TRACE(("  remove S%d\n", instr->id()));
           instr->DeleteAndReplaceWith(NULL);
         }
         break;
       }
       case HValue::kTransitionElementsKind: {
         HTransitionElementsKind* t = HTransitionElementsKind::cast(instr);
         HValue* object = t->object()->ActualValue();
         KillFieldInternal(object, FieldOf(JSArray::kElementsOffset), NULL);
         KillFieldInternal(object, FieldOf(JSObject::kMapOffset), NULL);
         break;
       }
       default: {
         if (instr->CheckChangesFlag(kInobjectFields)) {
           TRACE((" kill-all i%d\n", instr->id()));
           Kill();
           break;
         }
         if (instr->CheckChangesFlag(kMaps)) {
           TRACE((" kill-maps i%d\n", instr->id()));
           KillOffset(JSObject::kMapOffset);
         }
         if (instr->CheckChangesFlag(kElementsKind)) {
           TRACE((" kill-elements-kind i%d\n", instr->id()));
           KillOffset(JSObject::kMapOffset);
           KillOffset(JSObject::kElementsOffset);
         }
         if (instr->CheckChangesFlag(kElementsPointer)) {
           TRACE((" kill-elements i%d\n", instr->id()));
           KillOffset(JSObject::kElementsOffset);
         }
         if (instr->CheckChangesFlag(kOsrEntries)) {
           TRACE((" kill-osr i%d\n", instr->id()));
           Kill();
         }
       }
       // Improvements possible:
       // - learn from HCheckMaps for field 0
       // - remove unobservable stores (write-after-write)
       // - track cells
       // - track globals
       // - track roots
     }
     return this;
   }

   // Support for global analysis with HFlowEngine: Merge given state with
   // the other incoming state.
   static HLoadEliminationTable* Merge(HLoadEliminationTable* succ_state,
                                       HBasicBlock* succ_block,
                                       HLoadEliminationTable* pred_state,
                                       HBasicBlock* pred_block,
                                       Zone* zone) {
     ASSERT(pred_state != NULL);
     if (succ_state == NULL) {
       return pred_state->Copy(succ_block, pred_block, zone);
     } else {
       return succ_state->Merge(succ_block, pred_state, pred_block, zone);
     }
   }

   // Support for global analysis with HFlowEngine: Given state merged with all
   // the other incoming states, prepare it for use.
   static HLoadEliminationTable* Finish(HLoadEliminationTable* state,
                                        HBasicBlock* block,
                                        Zone* zone) {
     ASSERT(state != NULL);
     return state;
   }

  private:
   // Copy state to successor block.
   HLoadEliminationTable* Copy(HBasicBlock* succ, HBasicBlock* from_block,
                               Zone* zone) {
     HLoadEliminationTable* copy =
         new(zone) HLoadEliminationTable(zone, aliasing_);
     copy->EnsureFields(fields_.length());
     for (int i = 0; i < fields_.length(); i++) {
       copy->fields_[i] = fields_[i] == NULL ? NULL : fields_[i]->Copy(zone);
     }
     if (FLAG_trace_load_elimination) {
       TRACE((" copy-to B%d\n", succ->block_id()));
       copy->Print();
     }
     return copy;
   }

   // Merge this state with the other incoming state.
   HLoadEliminationTable* Merge(HBasicBlock* succ, HLoadEliminationTable* that,
                                HBasicBlock* that_block, Zone* zone) {
     if (that->fields_.length() < fields_.length()) {
       // Drop fields not in the other table.
       fields_.Rewind(that->fields_.length());
     }
     for (int i = 0; i < fields_.length(); i++) {
       // Merge the field approximations for like fields.
       HFieldApproximation* approx = fields_[i];
       HFieldApproximation* prev = NULL;
       while (approx != NULL) {
         // TODO(titzer): Merging is O(N * M); sort?
         HFieldApproximation* other = that->Find(approx->object_, i);
         if (other == NULL || !Equal(approx->last_value_, other->last_value_)) {
           // Kill an entry that doesn't agree with the other value.
           if (prev != NULL) {
             prev->next_ = approx->next_;
           } else {
             fields_[i] = approx->next_;
           }
           approx = approx->next_;
           continue;
         }
         prev = approx;
         approx = approx->next_;
       }
     }
     if (FLAG_trace_load_elimination) {
       TRACE((" merge-to B%d\n", succ->block_id()));
       Print();
     }
     return this;
   }

   friend class HLoadEliminationEffects;  // Calls Kill() and others.
   friend class HLoadEliminationPhase;

  private:
   // Process a load instruction, updating internal table state. If a previous
   // load or store for this object and field exists, return the new value with
   // which the load should be replaced. Otherwise, return {instr}.
   HValue* load(HLoadNamedField* instr) {
     // There must be no loads from non observable in-object properties.
     ASSERT(!instr->access().IsInobject() ||
            instr->access().existing_inobject_property());

     int field = FieldOf(instr->access());
     if (field < 0) return instr;

     HValue* object = instr->object()->ActualValue();
     HFieldApproximation* approx = FindOrCreate(object, field);

     if (approx->last_value_ == NULL) {
       // Load is not redundant. Fill out a new entry.
       approx->last_value_ = instr;
       return instr;
     } else if (approx->last_value_->block()->EqualToOrDominates(
         instr->block())) {
       // Eliminate the load. Reuse previously stored value or load instruction.
       return approx->last_value_;
     } else {
       return instr;
     }
   }

   // Process a store instruction, updating internal table state. If a previous
   // store to the same object and field makes this store redundant (e.g. because
   // the stored values are the same), return NULL indicating that this store
   // instruction is redundant. Otherwise, return {instr}.
   HValue* store(HStoreNamedField* instr) {
     if (instr->access().IsInobject() &&
         !instr->access().existing_inobject_property()) {
       TRACE(("  skipping non existing property initialization store\n"));
       return instr;
     }

     int field = FieldOf(instr->access());
     if (field < 0) return KillIfMisaligned(instr);

     HValue* object = instr->object()->ActualValue();
     HValue* value = instr->value();

     if (instr->has_transition()) {
       // A transition introduces a new field and alters the map of the object.
       // Since the field in the object is new, it cannot alias existing entries.
       // TODO(titzer): introduce a constant for the new map and remember it.
       KillFieldInternal(object, FieldOf(JSObject::kMapOffset), NULL);
     } else {
       // Kill non-equivalent may-alias entries.
       KillFieldInternal(object, field, value);
     }
     HFieldApproximation* approx = FindOrCreate(object, field);

     if (Equal(approx->last_value_, value)) {
       // The store is redundant because the field already has this value.
       return NULL;
     } else {
       // The store is not redundant. Update the entry.
       approx->last_value_ = value;
       return instr;
     }
   }

   // Kill everything in this table.
   void Kill() {
     fields_.Rewind(0);
   }

   // Kill all entries matching the given offset.
   void KillOffset(int offset) {
     int field = FieldOf(offset);
     if (field >= 0 && field < fields_.length()) {
       fields_[field] = NULL;
     }
   }

   // Kill all entries aliasing the given store.
   void KillStore(HStoreNamedField* s) {
     int field = FieldOf(s->access());
     if (field >= 0) {
       KillFieldInternal(s->object()->ActualValue(), field, s->value());
     } else {
       KillIfMisaligned(s);
     }
   }

   // Kill multiple entries in the case of a misaligned store.
   HValue* KillIfMisaligned(HStoreNamedField* instr) {
     HObjectAccess access = instr->access();
     if (access.IsInobject()) {
       int offset = access.offset();
       if ((offset % kPointerSize) != 0) {
         // Kill the field containing the first word of the access.
         HValue* object = instr->object()->ActualValue();
         int field = offset / kPointerSize;
         KillFieldInternal(object, field, NULL);

         // Kill the next field in case of overlap.
         int size = access.representation().size();
         int next_field = (offset + size - 1) / kPointerSize;
         if (next_field != field) KillFieldInternal(object, next_field, NULL);
       }
     }
     return instr;
   }

   // Find an entry for the given object and field pair.
   HFieldApproximation* Find(HValue* object, int field) {
     // Search for a field approximation for this object.
     HFieldApproximation* approx = fields_[field];
     while (approx != NULL) {
       if (aliasing_->MustAlias(object, approx->object_)) return approx;
       approx = approx->next_;
     }
     return NULL;
   }

   // Find or create an entry for the given object and field pair.
   HFieldApproximation* FindOrCreate(HValue* object, int field) {
     EnsureFields(field + 1);

     // Search for a field approximation for this object.
     HFieldApproximation* approx = fields_[field];
     int count = 0;
     while (approx != NULL) {
       if (aliasing_->MustAlias(object, approx->object_)) return approx;
       count++;
       approx = approx->next_;
     }

     if (count >= kMaxTrackedObjects) {
       // Pull the last entry off the end and repurpose it for this object.
       approx = ReuseLastApproximation(field);
     } else {
       // Allocate a new entry.
       approx = new(zone_) HFieldApproximation();
     }

     // Insert the entry at the head of the list.
     approx->object_ = object;
     approx->last_value_ = NULL;
     approx->next_ = fields_[field];
     fields_[field] = approx;

     return approx;
   }

   // Kill all entries for a given field that _may_ alias the given object
   // and do _not_ have the given value.
   void KillFieldInternal(HValue* object, int field, HValue* value) {
     if (field >= fields_.length()) return;  // Nothing to do.

     HFieldApproximation* approx = fields_[field];
     HFieldApproximation* prev = NULL;
     while (approx != NULL) {
       if (aliasing_->MayAlias(object, approx->object_)) {
         if (!Equal(approx->last_value_, value)) {
           // Kill an aliasing entry that doesn't agree on the value.
           if (prev != NULL) {
             prev->next_ = approx->next_;
           } else {
             fields_[field] = approx->next_;
           }
           approx = approx->next_;
           continue;
         }
       }
       prev = approx;
       approx = approx->next_;
     }
   }

   bool Equal(HValue* a, HValue* b) {
     if (a == b) return true;
     if (a != NULL && b != NULL && a->CheckFlag(HValue::kUseGVN)) {
       return a->Equals(b);
     }
     return false;
   }

   // Remove the last approximation for a field so that it can be reused.
   // We reuse the last entry because it was the first inserted and is thus
   // farthest away from the current instruction.
   HFieldApproximation* ReuseLastApproximation(int field) {
     HFieldApproximation* approx = fields_[field];
     ASSERT(approx != NULL);

     HFieldApproximation* prev = NULL;
     while (approx->next_ != NULL) {
       prev = approx;
       approx = approx->next_;
     }
     if (prev != NULL) prev->next_ = NULL;
     return approx;
   }

   // Compute the field index for the given object access; -1 if not tracked.
   int FieldOf(HObjectAccess access) {
     return access.IsInobject() ? FieldOf(access.offset()) : -1;
   }

   // Compute the field index for the given in-object offset; -1 if not tracked.
   int FieldOf(int offset) {
     if (offset >= kMaxTrackedFields * kPointerSize) return -1;
     // TODO(titzer): track misaligned loads in a separate list?
     if ((offset % kPointerSize) != 0) return -1;  // Ignore misaligned accesses.
     return offset / kPointerSize;
   }

   // Ensure internal storage for the given number of fields.
   void EnsureFields(int num_fields) {
     if (fields_.length() < num_fields) {
       fields_.AddBlock(NULL, num_fields - fields_.length(), zone_);
     }
   }

   // Print this table to stdout.
   void Print() {
     for (int i = 0; i < fields_.length(); i++) {
       PrintF("  field %d: ", i);
       for (HFieldApproximation* a = fields_[i]; a != NULL; a = a->next_) {
         PrintF("[o%d =", a->object_->id());
         if (a->last_value_ != NULL) PrintF(" v%d", a->last_value_->id());
         PrintF("] ");
       }
       PrintF("\n");
     }
   }

   Zone* zone_;
   ZoneList<HFieldApproximation*> fields_;
   HAliasAnalyzer* aliasing_;
 };


 // Support for HFlowEngine: collect store effects within loops.
 class HLoadEliminationEffects : public ZoneObject {
  public:
   explicit HLoadEliminationEffects(Zone* zone)
     : zone_(zone), stores_(5, zone) { }

   inline bool Disabled() {
     return false;  // Effects are _not_ disabled.
   }

   // Process a possibly side-effecting instruction.
   void Process(HInstruction* instr, Zone* zone) {
     if (instr->IsStoreNamedField()) {
       stores_.Add(HStoreNamedField::cast(instr), zone_);
     } else {
       flags_.Add(instr->ChangesFlags());
     }
   }

   // Apply these effects to the given load elimination table.
   void Apply(HLoadEliminationTable* table) {
     // Loads must not be hoisted past the OSR entry, therefore we kill
     // everything if we see an OSR entry.
     if (flags_.Contains(kInobjectFields) || flags_.Contains(kOsrEntries)) {
       table->Kill();
       return;
     }
     if (flags_.Contains(kElementsKind) || flags_.Contains(kMaps)) {
       table->KillOffset(JSObject::kMapOffset);
     }
     if (flags_.Contains(kElementsKind) || flags_.Contains(kElementsPointer)) {
       table->KillOffset(JSObject::kElementsOffset);
     }

     // Kill non-agreeing fields for each store contained in these effects.
     for (int i = 0; i < stores_.length(); i++) {
       table->KillStore(stores_[i]);
     }
   }

   // Union these effects with the other effects.
   void Union(HLoadEliminationEffects* that, Zone* zone) {
     flags_.Add(that->flags_);
     for (int i = 0; i < that->stores_.length(); i++) {
       stores_.Add(that->stores_[i], zone);
     }
   }

  private:
   Zone* zone_;
   GVNFlagSet flags_;
   ZoneList<HStoreNamedField*> stores_;
 };


 // The main routine of the analysis phase. Use the HFlowEngine for either a
 // local or a global analysis.
 void HLoadEliminationPhase::Run() {
   HFlowEngine<HLoadEliminationTable, HLoadEliminationEffects>
     engine(graph(), zone());
   HAliasAnalyzer aliasing;
   HLoadEliminationTable* table =
       new(zone()) HLoadEliminationTable(zone(), &aliasing);

   if (GLOBAL) {
     // Perform a global analysis.
     engine.AnalyzeDominatedBlocks(graph()->blocks()->at(0), table);
   } else {
     // Perform only local analysis.
     for (int i = 0; i < graph()->blocks()->length(); i++) {
       table->Kill();
       engine.AnalyzeOneBlock(graph()->blocks()->at(i), table);
     }
   }
 }

 } }  // 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-alias-analysis.h"
	#include "src/hydrogen-load-elimination.h"
	#include "src/hydrogen-instructions.h"
	#include "src/hydrogen-flow-engine.h"

	namespace v8 {
	namespace internal {

	#define GLOBAL true
	#define TRACE(x) if (FLAG_trace_load_elimination) PrintF x

	static const int kMaxTrackedFields = 16;
	static const int kMaxTrackedObjects = 5;

	// An element in the field approximation list.
	class HFieldApproximation : public ZoneObject {
	public: // Just a data blob.
	HValue* object_;
	HValue* last_value_;
	HFieldApproximation* next_;

	// Recursively copy the entire linked list of field approximations.
	HFieldApproximation* Copy(Zone* zone) {
	HFieldApproximation* copy = new(zone) HFieldApproximation();
	copy->object_ = this->object_;
	copy->last_value_ = this->last_value_;
	copy->next_ = this->next_ == NULL ? NULL : this->next_->Copy(zone);
	return copy;
	}
	};


	// The main datastructure used during load/store elimination. Each in-object
	// field is tracked separately. For each field, store a list of known field
	// values for known objects.
	class HLoadEliminationTable : public ZoneObject {
	public:
	HLoadEliminationTable(Zone* zone, HAliasAnalyzer* aliasing)
	: zone_(zone), fields_(kMaxTrackedFields, zone), aliasing_(aliasing) { }

	// The main processing of instructions.
	HLoadEliminationTable* Process(HInstruction* instr, Zone* zone) {
	switch (instr->opcode()) {
	case HValue::kLoadNamedField: {
	HLoadNamedField* l = HLoadNamedField::cast(instr);
	TRACE((" process L%d field %d (o%d)\n",
	instr->id(),
	FieldOf(l->access()),
	l->object()->ActualValue()->id()));
	HValue* result = load(l);
	if (result != instr && l->CanBeReplacedWith(result)) {
	// The load can be replaced with a previous load or a value.
	TRACE((" replace L%d -> v%d\n", instr->id(), result->id()));
	instr->DeleteAndReplaceWith(result);
	}
	break;
	}
	case HValue::kStoreNamedField: {
	HStoreNamedField* s = HStoreNamedField::cast(instr);
	TRACE((" process S%d field %d (o%d) = v%d\n",
	instr->id(),
	FieldOf(s->access()),
	s->object()->ActualValue()->id(),
	s->value()->id()));
	HValue* result = store(s);
	if (result == NULL) {
	// The store is redundant. Remove it.
	TRACE((" remove S%d\n", instr->id()));
	instr->DeleteAndReplaceWith(NULL);
	}
	break;
	}
	case HValue::kTransitionElementsKind: {
	HTransitionElementsKind* t = HTransitionElementsKind::cast(instr);
	HValue* object = t->object()->ActualValue();
	KillFieldInternal(object, FieldOf(JSArray::kElementsOffset), NULL);
	KillFieldInternal(object, FieldOf(JSObject::kMapOffset), NULL);
	break;
	}
	default: {
	if (instr->CheckChangesFlag(kInobjectFields)) {
	TRACE((" kill-all i%d\n", instr->id()));
	Kill();
	break;
	}
	if (instr->CheckChangesFlag(kMaps)) {
	TRACE((" kill-maps i%d\n", instr->id()));
	KillOffset(JSObject::kMapOffset);
	}
	if (instr->CheckChangesFlag(kElementsKind)) {
	TRACE((" kill-elements-kind i%d\n", instr->id()));
	KillOffset(JSObject::kMapOffset);
	KillOffset(JSObject::kElementsOffset);
	}
	if (instr->CheckChangesFlag(kElementsPointer)) {
	TRACE((" kill-elements i%d\n", instr->id()));
	KillOffset(JSObject::kElementsOffset);
	}
	if (instr->CheckChangesFlag(kOsrEntries)) {
	TRACE((" kill-osr i%d\n", instr->id()));
	Kill();
	}
	}
	// Improvements possible:
	// - learn from HCheckMaps for field 0
	// - remove unobservable stores (write-after-write)
	// - track cells
	// - track globals
	// - track roots
	}
	return this;
	}

	// Support for global analysis with HFlowEngine: Merge given state with
	// the other incoming state.
	static HLoadEliminationTable* Merge(HLoadEliminationTable* succ_state,
	HBasicBlock* succ_block,
	HLoadEliminationTable* pred_state,
	HBasicBlock* pred_block,
	Zone* zone) {
	ASSERT(pred_state != NULL);
	if (succ_state == NULL) {
	return pred_state->Copy(succ_block, pred_block, zone);
	} else {
	return succ_state->Merge(succ_block, pred_state, pred_block, zone);
	}
	}

	// Support for global analysis with HFlowEngine: Given state merged with all
	// the other incoming states, prepare it for use.
	static HLoadEliminationTable* Finish(HLoadEliminationTable* state,
	HBasicBlock* block,
	Zone* zone) {
	ASSERT(state != NULL);
	return state;
	}

	private:
	// Copy state to successor block.
	HLoadEliminationTable* Copy(HBasicBlock* succ, HBasicBlock* from_block,
	Zone* zone) {
	HLoadEliminationTable* copy =
	new(zone) HLoadEliminationTable(zone, aliasing_);
	copy->EnsureFields(fields_.length());
	for (int i = 0; i < fields_.length(); i++) {
	copy->fields_[i] = fields_[i] == NULL ? NULL : fields_[i]->Copy(zone);
	}
	if (FLAG_trace_load_elimination) {
	TRACE((" copy-to B%d\n", succ->block_id()));
	copy->Print();
	}
	return copy;
	}

	// Merge this state with the other incoming state.
	HLoadEliminationTable* Merge(HBasicBlock* succ, HLoadEliminationTable* that,
	HBasicBlock* that_block, Zone* zone) {
	if (that->fields_.length() < fields_.length()) {
	// Drop fields not in the other table.
	fields_.Rewind(that->fields_.length());
	}
	for (int i = 0; i < fields_.length(); i++) {
	// Merge the field approximations for like fields.
	HFieldApproximation* approx = fields_[i];
	HFieldApproximation* prev = NULL;
	while (approx != NULL) {
	// TODO(titzer): Merging is O(N * M); sort?
	HFieldApproximation* other = that->Find(approx->object_, i);
	if (other == NULL \|\| !Equal(approx->last_value_, other->last_value_)) {
	// Kill an entry that doesn't agree with the other value.
	if (prev != NULL) {
	prev->next_ = approx->next_;
	} else {
	fields_[i] = approx->next_;
	}
	approx = approx->next_;
	continue;
	}
	prev = approx;
	approx = approx->next_;
	}
	}
	if (FLAG_trace_load_elimination) {
	TRACE((" merge-to B%d\n", succ->block_id()));
	Print();
	}
	return this;
	}

	friend class HLoadEliminationEffects; // Calls Kill() and others.
	friend class HLoadEliminationPhase;

	private:
	// Process a load instruction, updating internal table state. If a previous
	// load or store for this object and field exists, return the new value with
	// which the load should be replaced. Otherwise, return {instr}.
	HValue* load(HLoadNamedField* instr) {
	// There must be no loads from non observable in-object properties.
	ASSERT(!instr->access().IsInobject() \|\|
	instr->access().existing_inobject_property());

	int field = FieldOf(instr->access());
	if (field < 0) return instr;

	HValue* object = instr->object()->ActualValue();
	HFieldApproximation* approx = FindOrCreate(object, field);

	if (approx->last_value_ == NULL) {
	// Load is not redundant. Fill out a new entry.
	approx->last_value_ = instr;
	return instr;
	} else if (approx->last_value_->block()->EqualToOrDominates(
	instr->block())) {
	// Eliminate the load. Reuse previously stored value or load instruction.
	return approx->last_value_;
	} else {
	return instr;
	}
	}

	// Process a store instruction, updating internal table state. If a previous
	// store to the same object and field makes this store redundant (e.g. because
	// the stored values are the same), return NULL indicating that this store
	// instruction is redundant. Otherwise, return {instr}.
	HValue* store(HStoreNamedField* instr) {
	if (instr->access().IsInobject() &&
	!instr->access().existing_inobject_property()) {
	TRACE((" skipping non existing property initialization store\n"));
	return instr;
	}

	int field = FieldOf(instr->access());
	if (field < 0) return KillIfMisaligned(instr);

	HValue* object = instr->object()->ActualValue();
	HValue* value = instr->value();

	if (instr->has_transition()) {
	// A transition introduces a new field and alters the map of the object.
	// Since the field in the object is new, it cannot alias existing entries.
	// TODO(titzer): introduce a constant for the new map and remember it.
	KillFieldInternal(object, FieldOf(JSObject::kMapOffset), NULL);
	} else {
	// Kill non-equivalent may-alias entries.
	KillFieldInternal(object, field, value);
	}
	HFieldApproximation* approx = FindOrCreate(object, field);

	if (Equal(approx->last_value_, value)) {
	// The store is redundant because the field already has this value.
	return NULL;
	} else {
	// The store is not redundant. Update the entry.
	approx->last_value_ = value;
	return instr;
	}
	}

	// Kill everything in this table.
	void Kill() {
	fields_.Rewind(0);
	}

	// Kill all entries matching the given offset.
	void KillOffset(int offset) {
	int field = FieldOf(offset);
	if (field >= 0 && field < fields_.length()) {
	fields_[field] = NULL;
	}
	}

	// Kill all entries aliasing the given store.
	void KillStore(HStoreNamedField* s) {
	int field = FieldOf(s->access());
	if (field >= 0) {
	KillFieldInternal(s->object()->ActualValue(), field, s->value());
	} else {
	KillIfMisaligned(s);
	}
	}

	// Kill multiple entries in the case of a misaligned store.
	HValue* KillIfMisaligned(HStoreNamedField* instr) {
	HObjectAccess access = instr->access();
	if (access.IsInobject()) {
	int offset = access.offset();
	if ((offset % kPointerSize) != 0) {
	// Kill the field containing the first word of the access.
	HValue* object = instr->object()->ActualValue();
	int field = offset / kPointerSize;
	KillFieldInternal(object, field, NULL);

	// Kill the next field in case of overlap.
	int size = access.representation().size();
	int next_field = (offset + size - 1) / kPointerSize;
	if (next_field != field) KillFieldInternal(object, next_field, NULL);
	}
	}
	return instr;
	}

	// Find an entry for the given object and field pair.
	HFieldApproximation* Find(HValue* object, int field) {
	// Search for a field approximation for this object.
	HFieldApproximation* approx = fields_[field];
	while (approx != NULL) {
	if (aliasing_->MustAlias(object, approx->object_)) return approx;
	approx = approx->next_;
	}
	return NULL;
	}

	// Find or create an entry for the given object and field pair.
	HFieldApproximation* FindOrCreate(HValue* object, int field) {
	EnsureFields(field + 1);

	// Search for a field approximation for this object.
	HFieldApproximation* approx = fields_[field];
	int count = 0;
	while (approx != NULL) {
	if (aliasing_->MustAlias(object, approx->object_)) return approx;
	count++;
	approx = approx->next_;
	}

	if (count >= kMaxTrackedObjects) {
	// Pull the last entry off the end and repurpose it for this object.
	approx = ReuseLastApproximation(field);
	} else {
	// Allocate a new entry.
	approx = new(zone_) HFieldApproximation();
	}

	// Insert the entry at the head of the list.
	approx->object_ = object;
	approx->last_value_ = NULL;
	approx->next_ = fields_[field];
	fields_[field] = approx;

	return approx;
	}

	// Kill all entries for a given field that _may_ alias the given object
	// and do _not_ have the given value.
	void KillFieldInternal(HValue* object, int field, HValue* value) {
	if (field >= fields_.length()) return; // Nothing to do.

	HFieldApproximation* approx = fields_[field];
	HFieldApproximation* prev = NULL;
	while (approx != NULL) {
	if (aliasing_->MayAlias(object, approx->object_)) {
	if (!Equal(approx->last_value_, value)) {
	// Kill an aliasing entry that doesn't agree on the value.
	if (prev != NULL) {
	prev->next_ = approx->next_;
	} else {
	fields_[field] = approx->next_;
	}
	approx = approx->next_;
	continue;
	}
	}
	prev = approx;
	approx = approx->next_;
	}
	}

	bool Equal(HValue* a, HValue* b) {
	if (a == b) return true;
	if (a != NULL && b != NULL && a->CheckFlag(HValue::kUseGVN)) {
	return a->Equals(b);
	}
	return false;
	}

	// Remove the last approximation for a field so that it can be reused.
	// We reuse the last entry because it was the first inserted and is thus
	// farthest away from the current instruction.
	HFieldApproximation* ReuseLastApproximation(int field) {
	HFieldApproximation* approx = fields_[field];
	ASSERT(approx != NULL);

	HFieldApproximation* prev = NULL;
	while (approx->next_ != NULL) {
	prev = approx;
	approx = approx->next_;
	}
	if (prev != NULL) prev->next_ = NULL;
	return approx;
	}

	// Compute the field index for the given object access; -1 if not tracked.
	int FieldOf(HObjectAccess access) {
	return access.IsInobject() ? FieldOf(access.offset()) : -1;
	}

	// Compute the field index for the given in-object offset; -1 if not tracked.
	int FieldOf(int offset) {
	if (offset >= kMaxTrackedFields * kPointerSize) return -1;
	// TODO(titzer): track misaligned loads in a separate list?
	if ((offset % kPointerSize) != 0) return -1; // Ignore misaligned accesses.
	return offset / kPointerSize;
	}

	// Ensure internal storage for the given number of fields.
	void EnsureFields(int num_fields) {
	if (fields_.length() < num_fields) {
	fields_.AddBlock(NULL, num_fields - fields_.length(), zone_);
	}
	}

	// Print this table to stdout.
	void Print() {
	for (int i = 0; i < fields_.length(); i++) {
	PrintF(" field %d: ", i);
	for (HFieldApproximation* a = fields_[i]; a != NULL; a = a->next_) {
	PrintF("[o%d =", a->object_->id());
	if (a->last_value_ != NULL) PrintF(" v%d", a->last_value_->id());
	PrintF("] ");
	}
	PrintF("\n");
	}
	}

	Zone* zone_;
	ZoneList<HFieldApproximation*> fields_;
	HAliasAnalyzer* aliasing_;
	};


	// Support for HFlowEngine: collect store effects within loops.
	class HLoadEliminationEffects : public ZoneObject {
	public:
	explicit HLoadEliminationEffects(Zone* zone)
	: zone_(zone), stores_(5, zone) { }

	inline bool Disabled() {
	return false; // Effects are _not_ disabled.
	}

	// Process a possibly side-effecting instruction.
	void Process(HInstruction* instr, Zone* zone) {
	if (instr->IsStoreNamedField()) {
	stores_.Add(HStoreNamedField::cast(instr), zone_);
	} else {
	flags_.Add(instr->ChangesFlags());
	}
	}

	// Apply these effects to the given load elimination table.
	void Apply(HLoadEliminationTable* table) {
	// Loads must not be hoisted past the OSR entry, therefore we kill
	// everything if we see an OSR entry.
	if (flags_.Contains(kInobjectFields) \|\| flags_.Contains(kOsrEntries)) {
	table->Kill();
	return;
	}
	if (flags_.Contains(kElementsKind) \|\| flags_.Contains(kMaps)) {
	table->KillOffset(JSObject::kMapOffset);
	}
	if (flags_.Contains(kElementsKind) \|\| flags_.Contains(kElementsPointer)) {
	table->KillOffset(JSObject::kElementsOffset);
	}

	// Kill non-agreeing fields for each store contained in these effects.
	for (int i = 0; i < stores_.length(); i++) {
	table->KillStore(stores_[i]);
	}
	}

	// Union these effects with the other effects.
	void Union(HLoadEliminationEffects* that, Zone* zone) {
	flags_.Add(that->flags_);
	for (int i = 0; i < that->stores_.length(); i++) {
	stores_.Add(that->stores_[i], zone);
	}
	}

	private:
	Zone* zone_;
	GVNFlagSet flags_;
	ZoneList<HStoreNamedField*> stores_;
	};


	// The main routine of the analysis phase. Use the HFlowEngine for either a
	// local or a global analysis.
	void HLoadEliminationPhase::Run() {
	HFlowEngine<HLoadEliminationTable, HLoadEliminationEffects>
	engine(graph(), zone());
	HAliasAnalyzer aliasing;
	HLoadEliminationTable* table =
	new(zone()) HLoadEliminationTable(zone(), &aliasing);

	if (GLOBAL) {
	// Perform a global analysis.
	engine.AnalyzeDominatedBlocks(graph()->blocks()->at(0), table);
	} else {
	// Perform only local analysis.
	for (int i = 0; i < graph()->blocks()->length(); i++) {
	table->Kill();
	engine.AnalyzeOneBlock(graph()->blocks()->at(i), table);
	}
	}
	}

	} } // namespace v8::internal