third_party/subzero/src/IceLiveness.cpp - SwiftShader - Git at Google

 //===- subzero/src/IceLiveness.cpp - Liveness analysis implementation -----===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Provides some of the support for the Liveness class.

 /// In particular, it handles the sparsity representation of the mapping
 /// between Variables and CfgNodes. The idea is that since most variables are
 /// used only within a single basic block, we can partition the variables into
 /// "local" and "global" sets. Instead of sizing and indexing vectors according
 /// to Variable::Number, we create a mapping such that global variables are
 /// mapped to low indexes that are common across nodes, and local variables are
 /// mapped to a higher index space that is shared across nodes.
 ///
 //===----------------------------------------------------------------------===//

 #include "IceLiveness.h"

 #include "IceCfg.h"
 #include "IceCfgNode.h"
 #include "IceDefs.h"
 #include "IceInst.h"
 #include "IceOperand.h"

 namespace Ice {

 // Initializes the basic liveness-related data structures for full liveness
 // analysis (IsFullInit=true), or for incremental update after phi lowering
 // (IsFullInit=false). In the latter case, FirstNode points to the first node
 // added since starting phi lowering, and FirstVar points to the first Variable
 // added since starting phi lowering.
 void Liveness::initInternal(NodeList::const_iterator FirstNode,
                             VarList::const_iterator FirstVar, bool IsFullInit) {
   // Initialize most of the container sizes.
   SizeT NumVars = Func->getVariables().size();
   SizeT NumNodes = Func->getNumNodes();
   VariablesMetadata *VMetadata = Func->getVMetadata();
   Nodes.resize(NumNodes);
   VarToLiveMap.resize(NumVars);

   // Count the number of globals, and the number of locals for each block.
   SizeT TmpNumGlobals = 0;
   for (auto I = FirstVar, E = Func->getVariables().end(); I != E; ++I) {
     Variable *Var = *I;
     if (VMetadata->isMultiBlock(Var)) {
       ++TmpNumGlobals;
     } else if (VMetadata->isSingleBlock(Var)) {
       SizeT Index = VMetadata->getLocalUseNode(Var)->getIndex();
       ++Nodes[Index].NumLocals;
     }
   }
   if (IsFullInit)
     NumGlobals = TmpNumGlobals;
   else
     assert(TmpNumGlobals == 0);

   // Resize each LivenessNode::LiveToVarMap, and the global LiveToVarMap. Reset
   // the counts to 0.
   for (auto I = FirstNode, E = Func->getNodes().end(); I != E; ++I) {
     LivenessNode &N = Nodes[(*I)->getIndex()];
     N.LiveToVarMap.assign(N.NumLocals, nullptr);
     N.NumLocals = 0;
     N.NumNonDeadPhis = 0;
   }
   if (IsFullInit)
     LiveToVarMap.assign(NumGlobals, nullptr);

   // Initialize the bitmask of which variables to track.
   RangeMask.resize(NumVars);
   RangeMask.set(0, NumVars); // Track all variables by default.

   // Sort each variable into the appropriate LiveToVarMap. Set VarToLiveMap.
   // Set RangeMask correctly for each variable.
   TmpNumGlobals = 0;
   for (auto I = FirstVar, E = Func->getVariables().end(); I != E; ++I) {
     Variable *Var = *I;
     SizeT VarIndex = Var->getIndex();
     SizeT LiveIndex = InvalidLiveIndex;
     if (VMetadata->isMultiBlock(Var)) {
       LiveIndex = TmpNumGlobals++;
       LiveToVarMap[LiveIndex] = Var;
     } else if (VMetadata->isSingleBlock(Var)) {
       SizeT NodeIndex = VMetadata->getLocalUseNode(Var)->getIndex();
       LiveIndex = Nodes[NodeIndex].NumLocals++;
       Nodes[NodeIndex].LiveToVarMap[LiveIndex] = Var;
       LiveIndex += NumGlobals;
     }
     VarToLiveMap[VarIndex] = LiveIndex;
     if (LiveIndex == InvalidLiveIndex || Var->getIgnoreLiveness())
       RangeMask[VarIndex] = false;
   }
   assert(TmpNumGlobals == (IsFullInit ? NumGlobals : 0));

   // Fix up RangeMask for variables before FirstVar.
   for (auto I = Func->getVariables().begin(); I != FirstVar; ++I) {
     Variable *Var = *I;
     SizeT VarIndex = Var->getIndex();
     if (Var->getIgnoreLiveness() ||
         (!IsFullInit && !Var->hasReg() && !Var->mustHaveReg()))
       RangeMask[VarIndex] = false;
   }

   // Process each node.
   MaxLocals = 0;
   for (auto I = FirstNode, E = Func->getNodes().end(); I != E; ++I) {
     LivenessNode &Node = Nodes[(*I)->getIndex()];
     // NumLocals, LiveToVarMap already initialized
     Node.LiveIn.resize(NumGlobals);
     Node.LiveOut.resize(NumGlobals);
     // LiveBegin and LiveEnd are reinitialized before each pass over the block.
     MaxLocals = std::max(MaxLocals, Node.NumLocals);
   }
   ScratchBV.reserve(NumGlobals + MaxLocals);
 }

 void Liveness::init() {
   constexpr bool IsFullInit = true;
   NodeList::const_iterator FirstNode = Func->getNodes().begin();
   VarList::const_iterator FirstVar = Func->getVariables().begin();
   initInternal(FirstNode, FirstVar, IsFullInit);
 }

 void Liveness::initPhiEdgeSplits(NodeList::const_iterator FirstNode,
                                  VarList::const_iterator FirstVar) {
   constexpr bool IsFullInit = false;
   initInternal(FirstNode, FirstVar, IsFullInit);
 }

 Variable *Liveness::getVariable(SizeT LiveIndex, const CfgNode *Node) const {
   if (LiveIndex < NumGlobals)
     return LiveToVarMap[LiveIndex];
   SizeT NodeIndex = Node->getIndex();
   return Nodes[NodeIndex].LiveToVarMap[LiveIndex - NumGlobals];
 }

 } // end of namespace Ice
	//===- subzero/src/IceLiveness.cpp - Liveness analysis implementation -----===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Provides some of the support for the Liveness class.

	/// In particular, it handles the sparsity representation of the mapping
	/// between Variables and CfgNodes. The idea is that since most variables are
	/// used only within a single basic block, we can partition the variables into
	/// "local" and "global" sets. Instead of sizing and indexing vectors according
	/// to Variable::Number, we create a mapping such that global variables are
	/// mapped to low indexes that are common across nodes, and local variables are
	/// mapped to a higher index space that is shared across nodes.
	///
	//===----------------------------------------------------------------------===//

	#include "IceLiveness.h"

	#include "IceCfg.h"
	#include "IceCfgNode.h"
	#include "IceDefs.h"
	#include "IceInst.h"
	#include "IceOperand.h"

	namespace Ice {

	// Initializes the basic liveness-related data structures for full liveness
	// analysis (IsFullInit=true), or for incremental update after phi lowering
	// (IsFullInit=false). In the latter case, FirstNode points to the first node
	// added since starting phi lowering, and FirstVar points to the first Variable
	// added since starting phi lowering.
	void Liveness::initInternal(NodeList::const_iterator FirstNode,
	VarList::const_iterator FirstVar, bool IsFullInit) {
	// Initialize most of the container sizes.
	SizeT NumVars = Func->getVariables().size();
	SizeT NumNodes = Func->getNumNodes();
	VariablesMetadata *VMetadata = Func->getVMetadata();
	Nodes.resize(NumNodes);
	VarToLiveMap.resize(NumVars);

	// Count the number of globals, and the number of locals for each block.
	SizeT TmpNumGlobals = 0;
	for (auto I = FirstVar, E = Func->getVariables().end(); I != E; ++I) {
	Variable Var = I;
	if (VMetadata->isMultiBlock(Var)) {
	++TmpNumGlobals;
	} else if (VMetadata->isSingleBlock(Var)) {
	SizeT Index = VMetadata->getLocalUseNode(Var)->getIndex();
	++Nodes[Index].NumLocals;
	}
	}
	if (IsFullInit)
	NumGlobals = TmpNumGlobals;
	else
	assert(TmpNumGlobals == 0);

	// Resize each LivenessNode::LiveToVarMap, and the global LiveToVarMap. Reset
	// the counts to 0.
	for (auto I = FirstNode, E = Func->getNodes().end(); I != E; ++I) {
	LivenessNode &N = Nodes[(*I)->getIndex()];
	N.LiveToVarMap.assign(N.NumLocals, nullptr);
	N.NumLocals = 0;
	N.NumNonDeadPhis = 0;
	}
	if (IsFullInit)
	LiveToVarMap.assign(NumGlobals, nullptr);

	// Initialize the bitmask of which variables to track.
	RangeMask.resize(NumVars);
	RangeMask.set(0, NumVars); // Track all variables by default.

	// Sort each variable into the appropriate LiveToVarMap. Set VarToLiveMap.
	// Set RangeMask correctly for each variable.
	TmpNumGlobals = 0;
	for (auto I = FirstVar, E = Func->getVariables().end(); I != E; ++I) {
	Variable Var = I;
	SizeT VarIndex = Var->getIndex();
	SizeT LiveIndex = InvalidLiveIndex;
	if (VMetadata->isMultiBlock(Var)) {
	LiveIndex = TmpNumGlobals++;
	LiveToVarMap[LiveIndex] = Var;
	} else if (VMetadata->isSingleBlock(Var)) {
	SizeT NodeIndex = VMetadata->getLocalUseNode(Var)->getIndex();
	LiveIndex = Nodes[NodeIndex].NumLocals++;
	Nodes[NodeIndex].LiveToVarMap[LiveIndex] = Var;
	LiveIndex += NumGlobals;
	}
	VarToLiveMap[VarIndex] = LiveIndex;
	if (LiveIndex == InvalidLiveIndex \|\| Var->getIgnoreLiveness())
	RangeMask[VarIndex] = false;
	}
	assert(TmpNumGlobals == (IsFullInit ? NumGlobals : 0));

	// Fix up RangeMask for variables before FirstVar.
	for (auto I = Func->getVariables().begin(); I != FirstVar; ++I) {
	Variable Var = I;
	SizeT VarIndex = Var->getIndex();
	if (Var->getIgnoreLiveness() \|\|
	(!IsFullInit && !Var->hasReg() && !Var->mustHaveReg()))
	RangeMask[VarIndex] = false;
	}

	// Process each node.
	MaxLocals = 0;
	for (auto I = FirstNode, E = Func->getNodes().end(); I != E; ++I) {
	LivenessNode &Node = Nodes[(*I)->getIndex()];
	// NumLocals, LiveToVarMap already initialized
	Node.LiveIn.resize(NumGlobals);
	Node.LiveOut.resize(NumGlobals);
	// LiveBegin and LiveEnd are reinitialized before each pass over the block.
	MaxLocals = std::max(MaxLocals, Node.NumLocals);
	}
	ScratchBV.reserve(NumGlobals + MaxLocals);
	}

	void Liveness::init() {
	constexpr bool IsFullInit = true;
	NodeList::const_iterator FirstNode = Func->getNodes().begin();
	VarList::const_iterator FirstVar = Func->getVariables().begin();
	initInternal(FirstNode, FirstVar, IsFullInit);
	}

	void Liveness::initPhiEdgeSplits(NodeList::const_iterator FirstNode,
	VarList::const_iterator FirstVar) {
	constexpr bool IsFullInit = false;
	initInternal(FirstNode, FirstVar, IsFullInit);
	}

	Variable Liveness::getVariable(SizeT LiveIndex, const CfgNode Node) const {
	if (LiveIndex < NumGlobals)
	return LiveToVarMap[LiveIndex];
	SizeT NodeIndex = Node->getIndex();
	return Nodes[NodeIndex].LiveToVarMap[LiveIndex - NumGlobals];
	}

	} // end of namespace Ice