src/crankshaft/hydrogen-representation-changes.cc - v8/v8.git - 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/crankshaft/hydrogen-representation-changes.h"

 namespace v8 {
 namespace internal {

 void HRepresentationChangesPhase::InsertRepresentationChangeForUse(
     HValue* value, HValue* use_value, int use_index, Representation to) {
   // Insert the representation change right before its use. For phi-uses we
   // insert at the end of the corresponding predecessor.
   HInstruction* next = NULL;
   if (use_value->IsPhi()) {
     next = use_value->block()->predecessors()->at(use_index)->end();
   } else {
     next = HInstruction::cast(use_value);
   }
   // For constants we try to make the representation change at compile
   // time. When a representation change is not possible without loss of
   // information we treat constants like normal instructions and insert the
   // change instructions for them.
   HInstruction* new_value = NULL;
   bool is_truncating_to_smi = use_value->CheckFlag(HValue::kTruncatingToSmi);
   bool is_truncating_to_int = use_value->CheckFlag(HValue::kTruncatingToInt32);
   if (value->IsConstant()) {
     HConstant* constant = HConstant::cast(value);
     // Try to create a new copy of the constant with the new representation.
     if (is_truncating_to_int && to.IsInteger32()) {
       Maybe<HConstant*> res = constant->CopyToTruncatedInt32(graph()->zone());
       if (res.IsJust()) new_value = res.FromJust();
     } else {
       new_value = constant->CopyToRepresentation(to, graph()->zone());
     }
   }

   if (new_value == NULL) {
     new_value = new(graph()->zone()) HChange(
         value, to, is_truncating_to_smi, is_truncating_to_int);
     if (!use_value->operand_position(use_index).IsUnknown()) {
       new_value->set_position(use_value->operand_position(use_index));
     } else {
       DCHECK(!FLAG_hydrogen_track_positions ||
              !graph()->info()->IsOptimizing());
     }
   }

   new_value->InsertBefore(next);
   use_value->SetOperandAt(use_index, new_value);
 }


 static bool IsNonDeoptingIntToSmiChange(HChange* change) {
   Representation from_rep = change->from();
   Representation to_rep = change->to();
   // Flags indicating Uint32 operations are set in a later Hydrogen phase.
   DCHECK(!change->CheckFlag(HValue::kUint32));
   return from_rep.IsInteger32() && to_rep.IsSmi() && SmiValuesAre32Bits();
 }


 void HRepresentationChangesPhase::InsertRepresentationChangesForValue(
     HValue* value) {
   Representation r = value->representation();
   if (r.IsNone()) {
 #ifdef DEBUG
     for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
       HValue* use_value = it.value();
       int use_index = it.index();
       Representation req = use_value->RequiredInputRepresentation(use_index);
       DCHECK(req.IsNone());
     }
 #endif
     return;
   }
   if (value->HasNoUses()) {
     if (value->IsForceRepresentation()) value->DeleteAndReplaceWith(NULL);
     return;
   }

   for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
     HValue* use_value = it.value();
     int use_index = it.index();
     Representation req = use_value->RequiredInputRepresentation(use_index);
     if (req.IsNone() || req.Equals(r)) continue;

     // If this is an HForceRepresentation instruction, and an HChange has been
     // inserted above it, examine the input representation of the HChange. If
     // that's int32, and this HForceRepresentation use is int32, and int32 to
     // smi changes can't cause deoptimisation, set the input of the use to the
     // input of the HChange.
     if (value->IsForceRepresentation()) {
       HValue* input = HForceRepresentation::cast(value)->value();
       if (input->IsChange()) {
         HChange* change = HChange::cast(input);
         if (change->from().Equals(req) && IsNonDeoptingIntToSmiChange(change)) {
           use_value->SetOperandAt(use_index, change->value());
           continue;
         }
       }
     }
     InsertRepresentationChangeForUse(value, use_value, use_index, req);
   }
   if (value->HasNoUses()) {
     DCHECK(value->IsConstant() || value->IsForceRepresentation());
     value->DeleteAndReplaceWith(NULL);
   } else {
     // The only purpose of a HForceRepresentation is to represent the value
     // after the (possible) HChange instruction.  We make it disappear.
     if (value->IsForceRepresentation()) {
       value->DeleteAndReplaceWith(HForceRepresentation::cast(value)->value());
     }
   }
 }


 void HRepresentationChangesPhase::Run() {
   // Compute truncation flag for phis: Initially assume that all
   // int32-phis allow truncation and iteratively remove the ones that
   // are used in an operation that does not allow a truncating
   // conversion.
   ZoneList<HPhi*> int_worklist(8, zone());
   ZoneList<HPhi*> smi_worklist(8, zone());

   const ZoneList<HPhi*>* phi_list(graph()->phi_list());
   for (int i = 0; i < phi_list->length(); i++) {
     HPhi* phi = phi_list->at(i);
     if (phi->representation().IsInteger32()) {
       phi->SetFlag(HValue::kTruncatingToInt32);
     } else if (phi->representation().IsSmi()) {
       phi->SetFlag(HValue::kTruncatingToSmi);
       phi->SetFlag(HValue::kTruncatingToInt32);
     }
   }

   for (int i = 0; i < phi_list->length(); i++) {
     HPhi* phi = phi_list->at(i);
     HValue* value = NULL;
     if (phi->representation().IsSmiOrInteger32() &&
         !phi->CheckUsesForFlag(HValue::kTruncatingToInt32, &value)) {
       int_worklist.Add(phi, zone());
       phi->ClearFlag(HValue::kTruncatingToInt32);
       if (FLAG_trace_representation) {
         PrintF("#%d Phi is not truncating Int32 because of #%d %s\n",
                phi->id(), value->id(), value->Mnemonic());
       }
     }

     if (phi->representation().IsSmi() &&
         !phi->CheckUsesForFlag(HValue::kTruncatingToSmi, &value)) {
       smi_worklist.Add(phi, zone());
       phi->ClearFlag(HValue::kTruncatingToSmi);
       if (FLAG_trace_representation) {
         PrintF("#%d Phi is not truncating Smi because of #%d %s\n",
                phi->id(), value->id(), value->Mnemonic());
       }
     }
   }

   while (!int_worklist.is_empty()) {
     HPhi* current = int_worklist.RemoveLast();
     for (int i = 0; i < current->OperandCount(); ++i) {
       HValue* input = current->OperandAt(i);
       if (input->IsPhi() &&
           input->representation().IsSmiOrInteger32() &&
           input->CheckFlag(HValue::kTruncatingToInt32)) {
         if (FLAG_trace_representation) {
           PrintF("#%d Phi is not truncating Int32 because of #%d %s\n",
                  input->id(), current->id(), current->Mnemonic());
         }
         input->ClearFlag(HValue::kTruncatingToInt32);
         int_worklist.Add(HPhi::cast(input), zone());
       }
     }
   }

   while (!smi_worklist.is_empty()) {
     HPhi* current = smi_worklist.RemoveLast();
     for (int i = 0; i < current->OperandCount(); ++i) {
       HValue* input = current->OperandAt(i);
       if (input->IsPhi() &&
           input->representation().IsSmi() &&
           input->CheckFlag(HValue::kTruncatingToSmi)) {
         if (FLAG_trace_representation) {
           PrintF("#%d Phi is not truncating Smi because of #%d %s\n",
                  input->id(), current->id(), current->Mnemonic());
         }
         input->ClearFlag(HValue::kTruncatingToSmi);
         smi_worklist.Add(HPhi::cast(input), zone());
       }
     }
   }

   const ZoneList<HBasicBlock*>* blocks(graph()->blocks());
   for (int i = 0; i < blocks->length(); ++i) {
     // Process phi instructions first.
     const HBasicBlock* block(blocks->at(i));
     const ZoneList<HPhi*>* phis = block->phis();
     for (int j = 0; j < phis->length(); j++) {
       InsertRepresentationChangesForValue(phis->at(j));
     }

     // Process normal instructions.
     for (HInstruction* current = block->first(); current != NULL; ) {
       HInstruction* next = current->next();
       InsertRepresentationChangesForValue(current);
       current = next;
     }
   }
 }

 }  // namespace internal
 }  // namespace v8
	// 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/crankshaft/hydrogen-representation-changes.h"

	namespace v8 {
	namespace internal {

	void HRepresentationChangesPhase::InsertRepresentationChangeForUse(
	HValue* value, HValue* use_value, int use_index, Representation to) {
	// Insert the representation change right before its use. For phi-uses we
	// insert at the end of the corresponding predecessor.
	HInstruction* next = NULL;
	if (use_value->IsPhi()) {
	next = use_value->block()->predecessors()->at(use_index)->end();
	} else {
	next = HInstruction::cast(use_value);
	}
	// For constants we try to make the representation change at compile
	// time. When a representation change is not possible without loss of
	// information we treat constants like normal instructions and insert the
	// change instructions for them.
	HInstruction* new_value = NULL;
	bool is_truncating_to_smi = use_value->CheckFlag(HValue::kTruncatingToSmi);
	bool is_truncating_to_int = use_value->CheckFlag(HValue::kTruncatingToInt32);
	if (value->IsConstant()) {
	HConstant* constant = HConstant::cast(value);
	// Try to create a new copy of the constant with the new representation.
	if (is_truncating_to_int && to.IsInteger32()) {
	Maybe<HConstant*> res = constant->CopyToTruncatedInt32(graph()->zone());
	if (res.IsJust()) new_value = res.FromJust();
	} else {
	new_value = constant->CopyToRepresentation(to, graph()->zone());
	}
	}

	if (new_value == NULL) {
	new_value = new(graph()->zone()) HChange(
	value, to, is_truncating_to_smi, is_truncating_to_int);
	if (!use_value->operand_position(use_index).IsUnknown()) {
	new_value->set_position(use_value->operand_position(use_index));
	} else {
	DCHECK(!FLAG_hydrogen_track_positions \|\|
	!graph()->info()->IsOptimizing());
	}
	}

	new_value->InsertBefore(next);
	use_value->SetOperandAt(use_index, new_value);
	}


	static bool IsNonDeoptingIntToSmiChange(HChange* change) {
	Representation from_rep = change->from();
	Representation to_rep = change->to();
	// Flags indicating Uint32 operations are set in a later Hydrogen phase.
	DCHECK(!change->CheckFlag(HValue::kUint32));
	return from_rep.IsInteger32() && to_rep.IsSmi() && SmiValuesAre32Bits();
	}


	void HRepresentationChangesPhase::InsertRepresentationChangesForValue(
	HValue* value) {
	Representation r = value->representation();
	if (r.IsNone()) {
	#ifdef DEBUG
	for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
	HValue* use_value = it.value();
	int use_index = it.index();
	Representation req = use_value->RequiredInputRepresentation(use_index);
	DCHECK(req.IsNone());
	}
	#endif
	return;
	}
	if (value->HasNoUses()) {
	if (value->IsForceRepresentation()) value->DeleteAndReplaceWith(NULL);
	return;
	}

	for (HUseIterator it(value->uses()); !it.Done(); it.Advance()) {
	HValue* use_value = it.value();
	int use_index = it.index();
	Representation req = use_value->RequiredInputRepresentation(use_index);
	if (req.IsNone() \|\| req.Equals(r)) continue;

	// If this is an HForceRepresentation instruction, and an HChange has been
	// inserted above it, examine the input representation of the HChange. If
	// that's int32, and this HForceRepresentation use is int32, and int32 to
	// smi changes can't cause deoptimisation, set the input of the use to the
	// input of the HChange.
	if (value->IsForceRepresentation()) {
	HValue* input = HForceRepresentation::cast(value)->value();
	if (input->IsChange()) {
	HChange* change = HChange::cast(input);
	if (change->from().Equals(req) && IsNonDeoptingIntToSmiChange(change)) {
	use_value->SetOperandAt(use_index, change->value());
	continue;
	}
	}
	}
	InsertRepresentationChangeForUse(value, use_value, use_index, req);
	}
	if (value->HasNoUses()) {
	DCHECK(value->IsConstant() \|\| value->IsForceRepresentation());
	value->DeleteAndReplaceWith(NULL);
	} else {
	// The only purpose of a HForceRepresentation is to represent the value
	// after the (possible) HChange instruction. We make it disappear.
	if (value->IsForceRepresentation()) {
	value->DeleteAndReplaceWith(HForceRepresentation::cast(value)->value());
	}
	}
	}


	void HRepresentationChangesPhase::Run() {
	// Compute truncation flag for phis: Initially assume that all
	// int32-phis allow truncation and iteratively remove the ones that
	// are used in an operation that does not allow a truncating
	// conversion.
	ZoneList<HPhi*> int_worklist(8, zone());
	ZoneList<HPhi*> smi_worklist(8, zone());

	const ZoneList<HPhi> phi_list(graph()->phi_list());
	for (int i = 0; i < phi_list->length(); i++) {
	HPhi* phi = phi_list->at(i);
	if (phi->representation().IsInteger32()) {
	phi->SetFlag(HValue::kTruncatingToInt32);
	} else if (phi->representation().IsSmi()) {
	phi->SetFlag(HValue::kTruncatingToSmi);
	phi->SetFlag(HValue::kTruncatingToInt32);
	}
	}

	for (int i = 0; i < phi_list->length(); i++) {
	HPhi* phi = phi_list->at(i);
	HValue* value = NULL;
	if (phi->representation().IsSmiOrInteger32() &&
	!phi->CheckUsesForFlag(HValue::kTruncatingToInt32, &value)) {
	int_worklist.Add(phi, zone());
	phi->ClearFlag(HValue::kTruncatingToInt32);
	if (FLAG_trace_representation) {
	PrintF("#%d Phi is not truncating Int32 because of #%d %s\n",
	phi->id(), value->id(), value->Mnemonic());
	}
	}

	if (phi->representation().IsSmi() &&
	!phi->CheckUsesForFlag(HValue::kTruncatingToSmi, &value)) {
	smi_worklist.Add(phi, zone());
	phi->ClearFlag(HValue::kTruncatingToSmi);
	if (FLAG_trace_representation) {
	PrintF("#%d Phi is not truncating Smi because of #%d %s\n",
	phi->id(), value->id(), value->Mnemonic());
	}
	}
	}

	while (!int_worklist.is_empty()) {
	HPhi* current = int_worklist.RemoveLast();
	for (int i = 0; i < current->OperandCount(); ++i) {
	HValue* input = current->OperandAt(i);
	if (input->IsPhi() &&
	input->representation().IsSmiOrInteger32() &&
	input->CheckFlag(HValue::kTruncatingToInt32)) {
	if (FLAG_trace_representation) {
	PrintF("#%d Phi is not truncating Int32 because of #%d %s\n",
	input->id(), current->id(), current->Mnemonic());
	}
	input->ClearFlag(HValue::kTruncatingToInt32);
	int_worklist.Add(HPhi::cast(input), zone());
	}
	}
	}

	while (!smi_worklist.is_empty()) {
	HPhi* current = smi_worklist.RemoveLast();
	for (int i = 0; i < current->OperandCount(); ++i) {
	HValue* input = current->OperandAt(i);
	if (input->IsPhi() &&
	input->representation().IsSmi() &&
	input->CheckFlag(HValue::kTruncatingToSmi)) {
	if (FLAG_trace_representation) {
	PrintF("#%d Phi is not truncating Smi because of #%d %s\n",
	input->id(), current->id(), current->Mnemonic());
	}
	input->ClearFlag(HValue::kTruncatingToSmi);
	smi_worklist.Add(HPhi::cast(input), zone());
	}
	}
	}

	const ZoneList<HBasicBlock> blocks(graph()->blocks());
	for (int i = 0; i < blocks->length(); ++i) {
	// Process phi instructions first.
	const HBasicBlock* block(blocks->at(i));
	const ZoneList<HPhi> phis = block->phis();
	for (int j = 0; j < phis->length(); j++) {
	InsertRepresentationChangesForValue(phis->at(j));
	}

	// Process normal instructions.
	for (HInstruction* current = block->first(); current != NULL; ) {
	HInstruction* next = current->next();
	InsertRepresentationChangesForValue(current);
	current = next;
	}
	}
	}

	} // namespace internal
	} // namespace v8