lib/CodeGen/InstrSelection/InstrForest.cpp - llvm - Git at Google

 //===-- InstrForest.cpp - Build instruction forest for inst selection -----===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  The key goal is to group instructions into a single
 //  tree if one or more of them might be potentially combined into a single
 //  complex instruction in the target machine.
 //  Since this grouping is completely machine-independent, we do it as
 //  aggressive as possible to exploit any possible target instructions.
 //  In particular, we group two instructions O and I if:
 //      (1) Instruction O computes an operand used by instruction I,
 //  and (2) O and I are part of the same basic block,
 //  and (3) O has only a single use, viz., I.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Constant.h"
 #include "llvm/Function.h"
 #include "llvm/iTerminators.h"
 #include "llvm/iMemory.h"
 #include "llvm/Type.h"
 #include "llvm/CodeGen/InstrForest.h"
 #include "llvm/CodeGen/MachineCodeForInstruction.h"
 #include "llvm/CodeGen/MachineInstr.h"
 #include "Support/STLExtras.h"
 #include "Config/alloca.h"

 //------------------------------------------------------------------------
 // class InstrTreeNode
 //------------------------------------------------------------------------

 void
 InstrTreeNode::dump(int dumpChildren, int indent) const {
   dumpNode(indent);

   if (dumpChildren) {
     if (LeftChild)
       LeftChild->dump(dumpChildren, indent+1);
     if (RightChild)
       RightChild->dump(dumpChildren, indent+1);
   }
 }


 InstructionNode::InstructionNode(Instruction* I)
   : InstrTreeNode(NTInstructionNode, I), codeIsFoldedIntoParent(false)
 {
   opLabel = I->getOpcode();

   // Distinguish special cases of some instructions such as Ret and Br
   //
   if (opLabel == Instruction::Ret && cast<ReturnInst>(I)->getReturnValue()) {
     opLabel = RetValueOp;              	 // ret(value) operation
   }
   else if (opLabel ==Instruction::Br && !cast<BranchInst>(I)->isUnconditional())
   {
     opLabel = BrCondOp;		// br(cond) operation
   } else if (opLabel >= Instruction::SetEQ && opLabel <= Instruction::SetGT) {
     opLabel = SetCCOp;		// common label for all SetCC ops
   } else if (opLabel == Instruction::Alloca && I->getNumOperands() > 0) {
     opLabel = AllocaN;		 // Alloca(ptr, N) operation
   } else if (opLabel == Instruction::GetElementPtr &&
              cast<GetElementPtrInst>(I)->hasIndices()) {
     opLabel = opLabel + 100;		 // getElem with index vector
   } else if (opLabel == Instruction::Xor &&
              BinaryOperator::isNot(I)) {
     opLabel = (I->getType() == Type::BoolTy)?  NotOp  // boolean Not operator
       : BNotOp; // bitwise Not operator
   } else if (opLabel == Instruction::And || opLabel == Instruction::Or ||
              opLabel == Instruction::Xor) {
     // Distinguish bitwise operators from logical operators!
     if (I->getType() != Type::BoolTy)
       opLabel = opLabel + 100;	 // bitwise operator
   } else if (opLabel == Instruction::Cast) {
     const Type *ITy = I->getType();
     switch(ITy->getPrimitiveID())
     {
     case Type::BoolTyID:    opLabel = ToBoolTy;    break;
     case Type::UByteTyID:   opLabel = ToUByteTy;   break;
     case Type::SByteTyID:   opLabel = ToSByteTy;   break;
     case Type::UShortTyID:  opLabel = ToUShortTy;  break;
     case Type::ShortTyID:   opLabel = ToShortTy;   break;
     case Type::UIntTyID:    opLabel = ToUIntTy;    break;
     case Type::IntTyID:     opLabel = ToIntTy;     break;
     case Type::ULongTyID:   opLabel = ToULongTy;   break;
     case Type::LongTyID:    opLabel = ToLongTy;    break;
     case Type::FloatTyID:   opLabel = ToFloatTy;   break;
     case Type::DoubleTyID:  opLabel = ToDoubleTy;  break;
     case Type::ArrayTyID:   opLabel = ToArrayTy;   break;
     case Type::PointerTyID: opLabel = ToPointerTy; break;
     default:
       // Just use `Cast' opcode otherwise. It's probably ignored.
       break;
     }
   }
 }


 void
 InstructionNode::dumpNode(int indent) const {
   for (int i=0; i < indent; i++)
     std::cerr << "    ";
   std::cerr << getInstruction()->getOpcodeName()
             << " [label " << getOpLabel() << "]" << "\n";
 }

 void
 VRegListNode::dumpNode(int indent) const {
   for (int i=0; i < indent; i++)
     std::cerr << "    ";

   std::cerr << "List" << "\n";
 }


 void
 VRegNode::dumpNode(int indent) const {
   for (int i=0; i < indent; i++)
     std::cerr << "    ";

   std::cerr << "VReg " << getValue() << "\t(type "
             << (int) getValue()->getValueType() << ")" << "\n";
 }

 void
 ConstantNode::dumpNode(int indent) const {
   for (int i=0; i < indent; i++)
     std::cerr << "    ";

   std::cerr << "Constant " << getValue() << "\t(type "
             << (int) getValue()->getValueType() << ")" << "\n";
 }

 void LabelNode::dumpNode(int indent) const {
   for (int i=0; i < indent; i++)
     std::cerr << "    ";

   std::cerr << "Label " << getValue() << "\n";
 }

 //------------------------------------------------------------------------
 // class InstrForest
 //
 // A forest of instruction trees, usually for a single method.
 //------------------------------------------------------------------------

 InstrForest::InstrForest(Function *F) {
   for (Function::iterator BB = F->begin(), FE = F->end(); BB != FE; ++BB) {
     for(BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E; ++I)
       buildTreeForInstruction(I);
   }
 }

 InstrForest::~InstrForest() {
   for_each(treeRoots.begin(), treeRoots.end(), deleter<InstructionNode>);
 }

 void InstrForest::dump() const {
   for (const_root_iterator I = roots_begin(); I != roots_end(); ++I)
     (*I)->dump(/*dumpChildren*/ 1, /*indent*/ 0);
 }

 inline void InstrForest::eraseRoot(InstructionNode* node) {
   for (RootSet::reverse_iterator RI=treeRoots.rbegin(), RE=treeRoots.rend();
        RI != RE; ++RI)
     if (*RI == node)
       treeRoots.erase(RI.base()-1);
 }

 inline void InstrForest::noteTreeNodeForInstr(Instruction *instr,
                                               InstructionNode *treeNode) {
   (*this)[instr] = treeNode;
   treeRoots.push_back(treeNode);	// mark node as root of a new tree
 }


 inline void InstrForest::setLeftChild(InstrTreeNode *parent,
                                       InstrTreeNode *child) {
   parent->LeftChild = child;
   child->Parent = parent;
   if (InstructionNode* instrNode = dyn_cast<InstructionNode>(child))
     eraseRoot(instrNode); // no longer a tree root
 }

 inline void InstrForest::setRightChild(InstrTreeNode *parent,
                                        InstrTreeNode *child) {
   parent->RightChild = child;
   child->Parent = parent;
   if (InstructionNode* instrNode = dyn_cast<InstructionNode>(child))
     eraseRoot(instrNode); // no longer a tree root
 }


 InstructionNode* InstrForest::buildTreeForInstruction(Instruction *instr) {
   InstructionNode *treeNode = getTreeNodeForInstr(instr);
   if (treeNode) {
     // treeNode has already been constructed for this instruction
     assert(treeNode->getInstruction() == instr);
     return treeNode;
   }

   // Otherwise, create a new tree node for this instruction.
   //
   treeNode = new InstructionNode(instr);
   noteTreeNodeForInstr(instr, treeNode);

   if (instr->getOpcode() == Instruction::Call) {
     // Operands of call instruction
     return treeNode;
   }

   // If the instruction has more than 2 instruction operands,
   // then we need to create artificial list nodes to hold them.
   // (Note that we only count operands that get tree nodes, and not
   // others such as branch labels for a branch or switch instruction.)
   //
   // To do this efficiently, we'll walk all operands, build treeNodes
   // for all appropriate operands and save them in an array.  We then
   // insert children at the end, creating list nodes where needed.
   // As a performance optimization, allocate a child array only
   // if a fixed array is too small.
   //
   int numChildren = 0;
   InstrTreeNode** childArray = new InstrTreeNode*[instr->getNumOperands()];

   //
   // Walk the operands of the instruction
   //
   for (Instruction::op_iterator O = instr->op_begin(); O!=instr->op_end(); ++O)
     {
       Value* operand = *O;

       // Check if the operand is a data value, not an branch label, type,
       // method or module.  If the operand is an address type (i.e., label
       // or method) that is used in an non-branching operation, e.g., `add'.
       // that should be considered a data value.

       // Check latter condition here just to simplify the next IF.
       bool includeAddressOperand =
 	(isa<BasicBlock>(operand) || isa<Function>(operand))
 	&& !instr->isTerminator();

       if (includeAddressOperand || isa<Instruction>(operand) ||
 	  isa<Constant>(operand) || isa<Argument>(operand) ||
 	  isa<GlobalVariable>(operand))
       {
         // This operand is a data value

         // An instruction that computes the incoming value is added as a
         // child of the current instruction if:
         //   the value has only a single use
         //   AND both instructions are in the same basic block.
         //   AND the current instruction is not a PHI (because the incoming
         //		value is conceptually in a predecessor block,
         //		even though it may be in the same static block)
         //
         // (Note that if the value has only a single use (viz., `instr'),
         //  the def of the value can be safely moved just before instr
         //  and therefore it is safe to combine these two instructions.)
         //
         // In all other cases, the virtual register holding the value
         // is used directly, i.e., made a child of the instruction node.
         //
         InstrTreeNode* opTreeNode;
         if (isa<Instruction>(operand) && operand->hasOneUse() &&
             cast<Instruction>(operand)->getParent() == instr->getParent() &&
             instr->getOpcode() != Instruction::PHI &&
             instr->getOpcode() != Instruction::Call)
         {
           // Recursively create a treeNode for it.
           opTreeNode = buildTreeForInstruction((Instruction*)operand);
         } else if (Constant *CPV = dyn_cast<Constant>(operand)) {
           // Create a leaf node for a constant
           opTreeNode = new ConstantNode(CPV);
         } else {
           // Create a leaf node for the virtual register
           opTreeNode = new VRegNode(operand);
         }

         childArray[numChildren++] = opTreeNode;
       }
     }

   //--------------------------------------------------------------------
   // Add any selected operands as children in the tree.
   // Certain instructions can have more than 2 in some instances (viz.,
   // a CALL or a memory access -- LOAD, STORE, and GetElemPtr -- to an
   // array or struct). Make the operands of every such instruction into
   // a right-leaning binary tree with the operand nodes at the leaves
   // and VRegList nodes as internal nodes.
   //--------------------------------------------------------------------

   InstrTreeNode *parent = treeNode;

   if (numChildren > 2) {
     unsigned instrOpcode = treeNode->getInstruction()->getOpcode();
     assert(instrOpcode == Instruction::PHI ||
            instrOpcode == Instruction::Call ||
            instrOpcode == Instruction::Load ||
            instrOpcode == Instruction::Store ||
            instrOpcode == Instruction::GetElementPtr);
   }

   // Insert the first child as a direct child
   if (numChildren >= 1)
     setLeftChild(parent, childArray[0]);

   int n;

   // Create a list node for children 2 .. N-1, if any
   for (n = numChildren-1; n >= 2; n--) {
     // We have more than two children
     InstrTreeNode *listNode = new VRegListNode();
     setRightChild(parent, listNode);
     setLeftChild(listNode, childArray[numChildren - n]);
     parent = listNode;
   }

   // Now insert the last remaining child (if any).
   if (numChildren >= 2) {
     assert(n == 1);
     setRightChild(parent, childArray[numChildren - 1]);
   }

   delete [] childArray;
   return treeNode;
 }
	//===-- InstrForest.cpp - Build instruction forest for inst selection -----===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// The key goal is to group instructions into a single
	// tree if one or more of them might be potentially combined into a single
	// complex instruction in the target machine.
	// Since this grouping is completely machine-independent, we do it as
	// aggressive as possible to exploit any possible target instructions.
	// In particular, we group two instructions O and I if:
	// (1) Instruction O computes an operand used by instruction I,
	// and (2) O and I are part of the same basic block,
	// and (3) O has only a single use, viz., I.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Constant.h"
	#include "llvm/Function.h"
	#include "llvm/iTerminators.h"
	#include "llvm/iMemory.h"
	#include "llvm/Type.h"
	#include "llvm/CodeGen/InstrForest.h"
	#include "llvm/CodeGen/MachineCodeForInstruction.h"
	#include "llvm/CodeGen/MachineInstr.h"
	#include "Support/STLExtras.h"
	#include "Config/alloca.h"

	//------------------------------------------------------------------------
	// class InstrTreeNode
	//------------------------------------------------------------------------

	void
	InstrTreeNode::dump(int dumpChildren, int indent) const {
	dumpNode(indent);

	if (dumpChildren) {
	if (LeftChild)
	LeftChild->dump(dumpChildren, indent+1);
	if (RightChild)
	RightChild->dump(dumpChildren, indent+1);
	}
	}


	InstructionNode::InstructionNode(Instruction* I)
	: InstrTreeNode(NTInstructionNode, I), codeIsFoldedIntoParent(false)
	{
	opLabel = I->getOpcode();

	// Distinguish special cases of some instructions such as Ret and Br
	//
	if (opLabel == Instruction::Ret && cast<ReturnInst>(I)->getReturnValue()) {
	opLabel = RetValueOp; // ret(value) operation
	}
	else if (opLabel ==Instruction::Br && !cast<BranchInst>(I)->isUnconditional())
	{
	opLabel = BrCondOp; // br(cond) operation
	} else if (opLabel >= Instruction::SetEQ && opLabel <= Instruction::SetGT) {
	opLabel = SetCCOp; // common label for all SetCC ops
	} else if (opLabel == Instruction::Alloca && I->getNumOperands() > 0) {
	opLabel = AllocaN; // Alloca(ptr, N) operation
	} else if (opLabel == Instruction::GetElementPtr &&
	cast<GetElementPtrInst>(I)->hasIndices()) {
	opLabel = opLabel + 100; // getElem with index vector
	} else if (opLabel == Instruction::Xor &&
	BinaryOperator::isNot(I)) {
	opLabel = (I->getType() == Type::BoolTy)? NotOp // boolean Not operator
	: BNotOp; // bitwise Not operator
	} else if (opLabel == Instruction::And \|\| opLabel == Instruction::Or \|\|
	opLabel == Instruction::Xor) {
	// Distinguish bitwise operators from logical operators!
	if (I->getType() != Type::BoolTy)
	opLabel = opLabel + 100; // bitwise operator
	} else if (opLabel == Instruction::Cast) {
	const Type *ITy = I->getType();
	switch(ITy->getPrimitiveID())
	{
	case Type::BoolTyID: opLabel = ToBoolTy; break;
	case Type::UByteTyID: opLabel = ToUByteTy; break;
	case Type::SByteTyID: opLabel = ToSByteTy; break;
	case Type::UShortTyID: opLabel = ToUShortTy; break;
	case Type::ShortTyID: opLabel = ToShortTy; break;
	case Type::UIntTyID: opLabel = ToUIntTy; break;
	case Type::IntTyID: opLabel = ToIntTy; break;
	case Type::ULongTyID: opLabel = ToULongTy; break;
	case Type::LongTyID: opLabel = ToLongTy; break;
	case Type::FloatTyID: opLabel = ToFloatTy; break;
	case Type::DoubleTyID: opLabel = ToDoubleTy; break;
	case Type::ArrayTyID: opLabel = ToArrayTy; break;
	case Type::PointerTyID: opLabel = ToPointerTy; break;
	default:
	// Just use `Cast' opcode otherwise. It's probably ignored.
	break;
	}
	}
	}


	void
	InstructionNode::dumpNode(int indent) const {
	for (int i=0; i < indent; i++)
	std::cerr << " ";
	std::cerr << getInstruction()->getOpcodeName()
	<< " [label " << getOpLabel() << "]" << "\n";
	}

	void
	VRegListNode::dumpNode(int indent) const {
	for (int i=0; i < indent; i++)
	std::cerr << " ";

	std::cerr << "List" << "\n";
	}


	void
	VRegNode::dumpNode(int indent) const {
	for (int i=0; i < indent; i++)
	std::cerr << " ";

	std::cerr << "VReg " << getValue() << "\t(type "
	<< (int) getValue()->getValueType() << ")" << "\n";
	}

	void
	ConstantNode::dumpNode(int indent) const {
	for (int i=0; i < indent; i++)
	std::cerr << " ";

	std::cerr << "Constant " << getValue() << "\t(type "
	<< (int) getValue()->getValueType() << ")" << "\n";
	}

	void LabelNode::dumpNode(int indent) const {
	for (int i=0; i < indent; i++)
	std::cerr << " ";

	std::cerr << "Label " << getValue() << "\n";
	}

	//------------------------------------------------------------------------
	// class InstrForest
	//
	// A forest of instruction trees, usually for a single method.
	//------------------------------------------------------------------------

	InstrForest::InstrForest(Function *F) {
	for (Function::iterator BB = F->begin(), FE = F->end(); BB != FE; ++BB) {
	for(BasicBlock::iterator I = BB->begin(), E = BB->end(); I != E; ++I)
	buildTreeForInstruction(I);
	}
	}

	InstrForest::~InstrForest() {
	for_each(treeRoots.begin(), treeRoots.end(), deleter<InstructionNode>);
	}

	void InstrForest::dump() const {
	for (const_root_iterator I = roots_begin(); I != roots_end(); ++I)
	(I)->dump(/dumpChildren/ 1, /indent*/ 0);
	}

	inline void InstrForest::eraseRoot(InstructionNode* node) {
	for (RootSet::reverse_iterator RI=treeRoots.rbegin(), RE=treeRoots.rend();
	RI != RE; ++RI)
	if (*RI == node)
	treeRoots.erase(RI.base()-1);
	}

	inline void InstrForest::noteTreeNodeForInstr(Instruction *instr,
	InstructionNode *treeNode) {
	(*this)[instr] = treeNode;
	treeRoots.push_back(treeNode); // mark node as root of a new tree
	}


	inline void InstrForest::setLeftChild(InstrTreeNode *parent,
	InstrTreeNode *child) {
	parent->LeftChild = child;
	child->Parent = parent;
	if (InstructionNode* instrNode = dyn_cast<InstructionNode>(child))
	eraseRoot(instrNode); // no longer a tree root
	}

	inline void InstrForest::setRightChild(InstrTreeNode *parent,
	InstrTreeNode *child) {
	parent->RightChild = child;
	child->Parent = parent;
	if (InstructionNode* instrNode = dyn_cast<InstructionNode>(child))
	eraseRoot(instrNode); // no longer a tree root
	}


	InstructionNode* InstrForest::buildTreeForInstruction(Instruction *instr) {
	InstructionNode *treeNode = getTreeNodeForInstr(instr);
	if (treeNode) {
	// treeNode has already been constructed for this instruction
	assert(treeNode->getInstruction() == instr);
	return treeNode;
	}

	// Otherwise, create a new tree node for this instruction.
	//
	treeNode = new InstructionNode(instr);
	noteTreeNodeForInstr(instr, treeNode);

	if (instr->getOpcode() == Instruction::Call) {
	// Operands of call instruction
	return treeNode;
	}

	// If the instruction has more than 2 instruction operands,
	// then we need to create artificial list nodes to hold them.
	// (Note that we only count operands that get tree nodes, and not
	// others such as branch labels for a branch or switch instruction.)
	//
	// To do this efficiently, we'll walk all operands, build treeNodes
	// for all appropriate operands and save them in an array. We then
	// insert children at the end, creating list nodes where needed.
	// As a performance optimization, allocate a child array only
	// if a fixed array is too small.
	//
	int numChildren = 0;
	InstrTreeNode** childArray = new InstrTreeNode*[instr->getNumOperands()];

	//
	// Walk the operands of the instruction
	//
	for (Instruction::op_iterator O = instr->op_begin(); O!=instr->op_end(); ++O)
	{
	Value* operand = *O;

	// Check if the operand is a data value, not an branch label, type,
	// method or module. If the operand is an address type (i.e., label
	// or method) that is used in an non-branching operation, e.g., `add'.
	// that should be considered a data value.

	// Check latter condition here just to simplify the next IF.
	bool includeAddressOperand =
	(isa<BasicBlock>(operand) \|\| isa<Function>(operand))
	&& !instr->isTerminator();

	if (includeAddressOperand \|\| isa<Instruction>(operand) \|\|
	isa<Constant>(operand) \|\| isa<Argument>(operand) \|\|
	isa<GlobalVariable>(operand))
	{
	// This operand is a data value

	// An instruction that computes the incoming value is added as a
	// child of the current instruction if:
	// the value has only a single use
	// AND both instructions are in the same basic block.
	// AND the current instruction is not a PHI (because the incoming
	// value is conceptually in a predecessor block,
	// even though it may be in the same static block)
	//
	// (Note that if the value has only a single use (viz., `instr'),
	// the def of the value can be safely moved just before instr
	// and therefore it is safe to combine these two instructions.)
	//
	// In all other cases, the virtual register holding the value
	// is used directly, i.e., made a child of the instruction node.
	//
	InstrTreeNode* opTreeNode;
	if (isa<Instruction>(operand) && operand->hasOneUse() &&
	cast<Instruction>(operand)->getParent() == instr->getParent() &&
	instr->getOpcode() != Instruction::PHI &&
	instr->getOpcode() != Instruction::Call)
	{
	// Recursively create a treeNode for it.
	opTreeNode = buildTreeForInstruction((Instruction*)operand);
	} else if (Constant *CPV = dyn_cast<Constant>(operand)) {
	// Create a leaf node for a constant
	opTreeNode = new ConstantNode(CPV);
	} else {
	// Create a leaf node for the virtual register
	opTreeNode = new VRegNode(operand);
	}

	childArray[numChildren++] = opTreeNode;
	}
	}

	//--------------------------------------------------------------------
	// Add any selected operands as children in the tree.
	// Certain instructions can have more than 2 in some instances (viz.,
	// a CALL or a memory access -- LOAD, STORE, and GetElemPtr -- to an
	// array or struct). Make the operands of every such instruction into
	// a right-leaning binary tree with the operand nodes at the leaves
	// and VRegList nodes as internal nodes.
	//--------------------------------------------------------------------

	InstrTreeNode *parent = treeNode;

	if (numChildren > 2) {
	unsigned instrOpcode = treeNode->getInstruction()->getOpcode();
	assert(instrOpcode == Instruction::PHI \|\|
	instrOpcode == Instruction::Call \|\|
	instrOpcode == Instruction::Load \|\|
	instrOpcode == Instruction::Store \|\|
	instrOpcode == Instruction::GetElementPtr);
	}

	// Insert the first child as a direct child
	if (numChildren >= 1)
	setLeftChild(parent, childArray[0]);

	int n;

	// Create a list node for children 2 .. N-1, if any
	for (n = numChildren-1; n >= 2; n--) {
	// We have more than two children
	InstrTreeNode *listNode = new VRegListNode();
	setRightChild(parent, listNode);
	setLeftChild(listNode, childArray[numChildren - n]);
	parent = listNode;
	}

	// Now insert the last remaining child (if any).
	if (numChildren >= 2) {
	assert(n == 1);
	setRightChild(parent, childArray[numChildren - 1]);
	}

	delete [] childArray;
	return treeNode;
	}