src/v8/src/compiler/control-equivalence.cc - cobalt - Git at Google

 // Copyright 2015 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.

 #if defined(V8_OS_STARBOARD)
 #include "starboard/system.h"
 #define __builtin_abort SbSystemBreakIntoDebugger
 #endif

 #include "src/compiler/control-equivalence.h"
 #include "src/compiler/node-properties.h"

 #define TRACE(...)                                 \
   do {                                             \
     if (FLAG_trace_turbo_ceq) PrintF(__VA_ARGS__); \
   } while (false)

 namespace v8 {
 namespace internal {
 namespace compiler {

 void ControlEquivalence::Run(Node* exit) {
   if (!Participates(exit) || GetClass(exit) == kInvalidClass) {
     DetermineParticipation(exit);
     RunUndirectedDFS(exit);
   }
 }


 // static
 STATIC_CONST_MEMBER_DEFINITION const size_t ControlEquivalence::kInvalidClass;


 void ControlEquivalence::VisitPre(Node* node) {
   TRACE("CEQ: Pre-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
 }


 void ControlEquivalence::VisitMid(Node* node, DFSDirection direction) {
   TRACE("CEQ: Mid-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
   BracketList& blist = GetBracketList(node);

   // Remove brackets pointing to this node [line:19].
   BracketListDelete(blist, node, direction);

   // Potentially introduce artificial dependency from start to end.
   if (blist.empty()) {
     DCHECK_EQ(kInputDirection, direction);
     VisitBackedge(node, graph_->end(), kInputDirection);
   }

   // Potentially start a new equivalence class [line:37].
   BracketListTRACE(blist);
   Bracket* recent = &blist.back();
   if (recent->recent_size != blist.size()) {
     recent->recent_size = blist.size();
     recent->recent_class = NewClassNumber();
   }

   // Assign equivalence class to node.
   SetClass(node, recent->recent_class);
   TRACE("  Assigned class number is %zu\n", GetClass(node));
 }


 void ControlEquivalence::VisitPost(Node* node, Node* parent_node,
                                    DFSDirection direction) {
   TRACE("CEQ: Post-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
   BracketList& blist = GetBracketList(node);

   // Remove brackets pointing to this node [line:19].
   BracketListDelete(blist, node, direction);

   // Propagate bracket list up the DFS tree [line:13].
   if (parent_node != nullptr) {
     BracketList& parent_blist = GetBracketList(parent_node);
     parent_blist.splice(parent_blist.end(), blist);
   }
 }


 void ControlEquivalence::VisitBackedge(Node* from, Node* to,
                                        DFSDirection direction) {
   TRACE("CEQ: Backedge from #%d:%s to #%d:%s\n", from->id(),
         from->op()->mnemonic(), to->id(), to->op()->mnemonic());

   // Push backedge onto the bracket list [line:25].
   Bracket bracket = {direction, kInvalidClass, 0, from, to};
   GetBracketList(from).push_back(bracket);
 }


 void ControlEquivalence::RunUndirectedDFS(Node* exit) {
   ZoneStack<DFSStackEntry> stack(zone_);
   DFSPush(stack, exit, nullptr, kInputDirection);
   VisitPre(exit);

   while (!stack.empty()) {  // Undirected depth-first backwards traversal.
     DFSStackEntry& entry = stack.top();
     Node* node = entry.node;

     if (entry.direction == kInputDirection) {
       if (entry.input != node->input_edges().end()) {
         Edge edge = *entry.input;
         Node* input = edge.to();
         ++(entry.input);
         if (NodeProperties::IsControlEdge(edge)) {
           // Visit next control input.
           if (!Participates(input)) continue;
           if (GetData(input)->visited) continue;
           if (GetData(input)->on_stack) {
             // Found backedge if input is on stack.
             if (input != entry.parent_node) {
               VisitBackedge(node, input, kInputDirection);
             }
           } else {
             // Push input onto stack.
             DFSPush(stack, input, node, kInputDirection);
             VisitPre(input);
           }
         }
         continue;
       }
       if (entry.use != node->use_edges().end()) {
         // Switch direction to uses.
         entry.direction = kUseDirection;
         VisitMid(node, kInputDirection);
         continue;
       }
     }

     if (entry.direction == kUseDirection) {
       if (entry.use != node->use_edges().end()) {
         Edge edge = *entry.use;
         Node* use = edge.from();
         ++(entry.use);
         if (NodeProperties::IsControlEdge(edge)) {
           // Visit next control use.
           if (!Participates(use)) continue;
           if (GetData(use)->visited) continue;
           if (GetData(use)->on_stack) {
             // Found backedge if use is on stack.
             if (use != entry.parent_node) {
               VisitBackedge(node, use, kUseDirection);
             }
           } else {
             // Push use onto stack.
             DFSPush(stack, use, node, kUseDirection);
             VisitPre(use);
           }
         }
         continue;
       }
       if (entry.input != node->input_edges().end()) {
         // Switch direction to inputs.
         entry.direction = kInputDirection;
         VisitMid(node, kUseDirection);
         continue;
       }
     }

     // Pop node from stack when done with all inputs and uses.
     DCHECK(entry.input == node->input_edges().end());
     DCHECK(entry.use == node->use_edges().end());
     DFSPop(stack, node);
     VisitPost(node, entry.parent_node, entry.direction);
   }
 }

 void ControlEquivalence::DetermineParticipationEnqueue(ZoneQueue<Node*>& queue,
                                                        Node* node) {
   if (!Participates(node)) {
     AllocateData(node);
     queue.push(node);
   }
 }


 void ControlEquivalence::DetermineParticipation(Node* exit) {
   ZoneQueue<Node*> queue(zone_);
   DetermineParticipationEnqueue(queue, exit);
   while (!queue.empty()) {  // Breadth-first backwards traversal.
     Node* node = queue.front();
     queue.pop();
     int max = NodeProperties::PastControlIndex(node);
     for (int i = NodeProperties::FirstControlIndex(node); i < max; i++) {
       DetermineParticipationEnqueue(queue, node->InputAt(i));
     }
   }
 }


 void ControlEquivalence::DFSPush(DFSStack& stack, Node* node, Node* from,
                                  DFSDirection dir) {
   DCHECK(Participates(node));
   DCHECK(!GetData(node)->visited);
   GetData(node)->on_stack = true;
   Node::InputEdges::iterator input = node->input_edges().begin();
   Node::UseEdges::iterator use = node->use_edges().begin();
   stack.push({dir, input, use, from, node});
 }


 void ControlEquivalence::DFSPop(DFSStack& stack, Node* node) {
   DCHECK_EQ(stack.top().node, node);
   GetData(node)->on_stack = false;
   GetData(node)->visited = true;
   stack.pop();
 }


 void ControlEquivalence::BracketListDelete(BracketList& blist, Node* to,
                                            DFSDirection direction) {
   // TODO(mstarzinger): Optimize this to avoid linear search.
   for (BracketList::iterator i = blist.begin(); i != blist.end(); /*nop*/) {
     if (i->to == to && i->direction != direction) {
       TRACE("  BList erased: {%d->%d}\n", i->from->id(), i->to->id());
       i = blist.erase(i);
     } else {
       ++i;
     }
   }
 }


 void ControlEquivalence::BracketListTRACE(BracketList& blist) {
   if (FLAG_trace_turbo_ceq) {
     TRACE("  BList: ");
     for (Bracket bracket : blist) {
       TRACE("{%d->%d} ", bracket.from->id(), bracket.to->id());
     }
     TRACE("\n");
   }
 }

 #undef TRACE

 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// Copyright 2015 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.

	#if defined(V8_OS_STARBOARD)
	#include "starboard/system.h"
	#define __builtin_abort SbSystemBreakIntoDebugger
	#endif

	#include "src/compiler/control-equivalence.h"
	#include "src/compiler/node-properties.h"

	#define TRACE(...) \
	do { \
	if (FLAG_trace_turbo_ceq) PrintF(__VA_ARGS__); \
	} while (false)

	namespace v8 {
	namespace internal {
	namespace compiler {

	void ControlEquivalence::Run(Node* exit) {
	if (!Participates(exit) \|\| GetClass(exit) == kInvalidClass) {
	DetermineParticipation(exit);
	RunUndirectedDFS(exit);
	}
	}


	// static
	STATIC_CONST_MEMBER_DEFINITION const size_t ControlEquivalence::kInvalidClass;


	void ControlEquivalence::VisitPre(Node* node) {
	TRACE("CEQ: Pre-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
	}


	void ControlEquivalence::VisitMid(Node* node, DFSDirection direction) {
	TRACE("CEQ: Mid-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
	BracketList& blist = GetBracketList(node);

	// Remove brackets pointing to this node [line:19].
	BracketListDelete(blist, node, direction);

	// Potentially introduce artificial dependency from start to end.
	if (blist.empty()) {
	DCHECK_EQ(kInputDirection, direction);
	VisitBackedge(node, graph_->end(), kInputDirection);
	}

	// Potentially start a new equivalence class [line:37].
	BracketListTRACE(blist);
	Bracket* recent = &blist.back();
	if (recent->recent_size != blist.size()) {
	recent->recent_size = blist.size();
	recent->recent_class = NewClassNumber();
	}

	// Assign equivalence class to node.
	SetClass(node, recent->recent_class);
	TRACE(" Assigned class number is %zu\n", GetClass(node));
	}


	void ControlEquivalence::VisitPost(Node* node, Node* parent_node,
	DFSDirection direction) {
	TRACE("CEQ: Post-visit of #%d:%s\n", node->id(), node->op()->mnemonic());
	BracketList& blist = GetBracketList(node);

	// Remove brackets pointing to this node [line:19].
	BracketListDelete(blist, node, direction);

	// Propagate bracket list up the DFS tree [line:13].
	if (parent_node != nullptr) {
	BracketList& parent_blist = GetBracketList(parent_node);
	parent_blist.splice(parent_blist.end(), blist);
	}
	}


	void ControlEquivalence::VisitBackedge(Node* from, Node* to,
	DFSDirection direction) {
	TRACE("CEQ: Backedge from #%d:%s to #%d:%s\n", from->id(),
	from->op()->mnemonic(), to->id(), to->op()->mnemonic());

	// Push backedge onto the bracket list [line:25].
	Bracket bracket = {direction, kInvalidClass, 0, from, to};
	GetBracketList(from).push_back(bracket);
	}


	void ControlEquivalence::RunUndirectedDFS(Node* exit) {
	ZoneStack<DFSStackEntry> stack(zone_);
	DFSPush(stack, exit, nullptr, kInputDirection);
	VisitPre(exit);

	while (!stack.empty()) { // Undirected depth-first backwards traversal.
	DFSStackEntry& entry = stack.top();
	Node* node = entry.node;

	if (entry.direction == kInputDirection) {
	if (entry.input != node->input_edges().end()) {
	Edge edge = *entry.input;
	Node* input = edge.to();
	++(entry.input);
	if (NodeProperties::IsControlEdge(edge)) {
	// Visit next control input.
	if (!Participates(input)) continue;
	if (GetData(input)->visited) continue;
	if (GetData(input)->on_stack) {
	// Found backedge if input is on stack.
	if (input != entry.parent_node) {
	VisitBackedge(node, input, kInputDirection);
	}
	} else {
	// Push input onto stack.
	DFSPush(stack, input, node, kInputDirection);
	VisitPre(input);
	}
	}
	continue;
	}
	if (entry.use != node->use_edges().end()) {
	// Switch direction to uses.
	entry.direction = kUseDirection;
	VisitMid(node, kInputDirection);
	continue;
	}
	}

	if (entry.direction == kUseDirection) {
	if (entry.use != node->use_edges().end()) {
	Edge edge = *entry.use;
	Node* use = edge.from();
	++(entry.use);
	if (NodeProperties::IsControlEdge(edge)) {
	// Visit next control use.
	if (!Participates(use)) continue;
	if (GetData(use)->visited) continue;
	if (GetData(use)->on_stack) {
	// Found backedge if use is on stack.
	if (use != entry.parent_node) {
	VisitBackedge(node, use, kUseDirection);
	}
	} else {
	// Push use onto stack.
	DFSPush(stack, use, node, kUseDirection);
	VisitPre(use);
	}
	}
	continue;
	}
	if (entry.input != node->input_edges().end()) {
	// Switch direction to inputs.
	entry.direction = kInputDirection;
	VisitMid(node, kUseDirection);
	continue;
	}
	}

	// Pop node from stack when done with all inputs and uses.
	DCHECK(entry.input == node->input_edges().end());
	DCHECK(entry.use == node->use_edges().end());
	DFSPop(stack, node);
	VisitPost(node, entry.parent_node, entry.direction);
	}
	}

	void ControlEquivalence::DetermineParticipationEnqueue(ZoneQueue<Node*>& queue,
	Node* node) {
	if (!Participates(node)) {
	AllocateData(node);
	queue.push(node);
	}
	}


	void ControlEquivalence::DetermineParticipation(Node* exit) {
	ZoneQueue<Node*> queue(zone_);
	DetermineParticipationEnqueue(queue, exit);
	while (!queue.empty()) { // Breadth-first backwards traversal.
	Node* node = queue.front();
	queue.pop();
	int max = NodeProperties::PastControlIndex(node);
	for (int i = NodeProperties::FirstControlIndex(node); i < max; i++) {
	DetermineParticipationEnqueue(queue, node->InputAt(i));
	}
	}
	}


	void ControlEquivalence::DFSPush(DFSStack& stack, Node* node, Node* from,
	DFSDirection dir) {
	DCHECK(Participates(node));
	DCHECK(!GetData(node)->visited);
	GetData(node)->on_stack = true;
	Node::InputEdges::iterator input = node->input_edges().begin();
	Node::UseEdges::iterator use = node->use_edges().begin();
	stack.push({dir, input, use, from, node});
	}


	void ControlEquivalence::DFSPop(DFSStack& stack, Node* node) {
	DCHECK_EQ(stack.top().node, node);
	GetData(node)->on_stack = false;
	GetData(node)->visited = true;
	stack.pop();
	}


	void ControlEquivalence::BracketListDelete(BracketList& blist, Node* to,
	DFSDirection direction) {
	// TODO(mstarzinger): Optimize this to avoid linear search.
	for (BracketList::iterator i = blist.begin(); i != blist.end(); /nop/) {
	if (i->to == to && i->direction != direction) {
	TRACE(" BList erased: {%d->%d}\n", i->from->id(), i->to->id());
	i = blist.erase(i);
	} else {
	++i;
	}
	}
	}


	void ControlEquivalence::BracketListTRACE(BracketList& blist) {
	if (FLAG_trace_turbo_ceq) {
	TRACE(" BList: ");
	for (Bracket bracket : blist) {
	TRACE("{%d->%d} ", bracket.from->id(), bracket.to->id());
	}
	TRACE("\n");
	}
	}

	#undef TRACE

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