third_party/llvm-7.0/llvm/tools/llvm-exegesis/lib/MCInstrDescView.cpp - platform/external/swiftshader - Git at Google

 //===-- MCInstrDescView.cpp -------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "MCInstrDescView.h"

 #include <iterator>
 #include <map>
 #include <tuple>

 #include "llvm/ADT/STLExtras.h"

 namespace exegesis {

 Instruction::Instruction(const llvm::MCInstrDesc &MCInstrDesc,
                          const RegisterAliasingTrackerCache &RATC)
     : Description(&MCInstrDesc) {
   unsigned OpIndex = 0;
   for (; OpIndex < MCInstrDesc.getNumOperands(); ++OpIndex) {
     const auto &OpInfo = MCInstrDesc.opInfo_begin()[OpIndex];
     Operand Operand;
     Operand.Index = OpIndex;
     Operand.IsDef = (OpIndex < MCInstrDesc.getNumDefs());
     Operand.IsExplicit = true;
     // TODO(gchatelet): Handle isLookupPtrRegClass.
     if (OpInfo.RegClass >= 0)
       Operand.Tracker = &RATC.getRegisterClass(OpInfo.RegClass);
     Operand.TiedToIndex =
         MCInstrDesc.getOperandConstraint(OpIndex, llvm::MCOI::TIED_TO);
     Operand.Info = &OpInfo;
     Operands.push_back(Operand);
   }
   for (const llvm::MCPhysReg *MCPhysReg = MCInstrDesc.getImplicitDefs();
        MCPhysReg && *MCPhysReg; ++MCPhysReg, ++OpIndex) {
     Operand Operand;
     Operand.Index = OpIndex;
     Operand.IsDef = true;
     Operand.IsExplicit = false;
     Operand.Tracker = &RATC.getRegister(*MCPhysReg);
     Operand.ImplicitReg = MCPhysReg;
     Operands.push_back(Operand);
   }
   for (const llvm::MCPhysReg *MCPhysReg = MCInstrDesc.getImplicitUses();
        MCPhysReg && *MCPhysReg; ++MCPhysReg, ++OpIndex) {
     Operand Operand;
     Operand.Index = OpIndex;
     Operand.IsDef = false;
     Operand.IsExplicit = false;
     Operand.Tracker = &RATC.getRegister(*MCPhysReg);
     Operand.ImplicitReg = MCPhysReg;
     Operands.push_back(Operand);
   }
   // Assigning Variables to non tied explicit operands.
   Variables.reserve(Operands.size()); // Variables.size() <= Operands.size()
   for (auto &Op : Operands)
     if (Op.IsExplicit && Op.TiedToIndex < 0) {
       const size_t VariableIndex = Variables.size();
       Op.VariableIndex = VariableIndex;
       Variables.emplace_back();
       Variables.back().Index = VariableIndex;
     }
   // Assigning Variables to tied operands.
   for (auto &Op : Operands)
     if (Op.TiedToIndex >= 0)
       Op.VariableIndex = Operands[Op.TiedToIndex].VariableIndex;
   // Assigning Operands to Variables.
   for (auto &Op : Operands)
     if (Op.VariableIndex >= 0)
       Variables[Op.VariableIndex].TiedOperands.push_back(Op.Index);
   // Processing Aliasing.
   DefRegisters = RATC.emptyRegisters();
   UseRegisters = RATC.emptyRegisters();
   for (const auto &Op : Operands) {
     if (Op.Tracker) {
       auto &Registers = Op.IsDef ? DefRegisters : UseRegisters;
       Registers |= Op.Tracker->aliasedBits();
     }
   }
 }

 InstructionInstance::InstructionInstance(const Instruction &Instr)
     : Instr(Instr), VariableValues(Instr.Variables.size()) {}

 InstructionInstance::InstructionInstance(InstructionInstance &&) = default;

 InstructionInstance &InstructionInstance::
 operator=(InstructionInstance &&) = default;

 unsigned InstructionInstance::getOpcode() const {
   return Instr.Description->getOpcode();
 }

 llvm::MCOperand &InstructionInstance::getValueFor(const Variable &Var) {
   return VariableValues[Var.Index];
 }

 const llvm::MCOperand &
 InstructionInstance::getValueFor(const Variable &Var) const {
   return VariableValues[Var.Index];
 }

 llvm::MCOperand &InstructionInstance::getValueFor(const Operand &Op) {
   assert(Op.VariableIndex >= 0);
   return getValueFor(Instr.Variables[Op.VariableIndex]);
 }

 const llvm::MCOperand &
 InstructionInstance::getValueFor(const Operand &Op) const {
   assert(Op.VariableIndex >= 0);
   return getValueFor(Instr.Variables[Op.VariableIndex]);
 }

 // forward declaration.
 static void randomize(const Instruction &Instr, const Variable &Var,
                       llvm::MCOperand &AssignedValue);

 bool InstructionInstance::hasImmediateVariables() const {
   return llvm::any_of(Instr.Variables, [this](const Variable &Var) {
     assert(!Var.TiedOperands.empty());
     const unsigned OpIndex = Var.TiedOperands[0];
     const Operand &Op = Instr.Operands[OpIndex];
     assert(Op.Info);
     return Op.Info->OperandType == llvm::MCOI::OPERAND_IMMEDIATE;
   });
 }

 void InstructionInstance::randomizeUnsetVariables() {
   for (const Variable &Var : Instr.Variables) {
     llvm::MCOperand &AssignedValue = getValueFor(Var);
     if (!AssignedValue.isValid())
       randomize(Instr, Var, AssignedValue);
   }
 }

 llvm::MCInst InstructionInstance::build() const {
   llvm::MCInst Result;
   Result.setOpcode(Instr.Description->Opcode);
   for (const auto &Op : Instr.Operands)
     if (Op.IsExplicit)
       Result.addOperand(getValueFor(Op));
   return Result;
 }

 SnippetPrototype::SnippetPrototype(SnippetPrototype &&) = default;

 SnippetPrototype &SnippetPrototype::operator=(SnippetPrototype &&) = default;

 bool RegisterOperandAssignment::
 operator==(const RegisterOperandAssignment &Other) const {
   return std::tie(Op, Reg) == std::tie(Other.Op, Other.Reg);
 }

 bool AliasingRegisterOperands::
 operator==(const AliasingRegisterOperands &Other) const {
   return std::tie(Defs, Uses) == std::tie(Other.Defs, Other.Uses);
 }

 static void addOperandIfAlias(
     const llvm::MCPhysReg Reg, bool SelectDef, llvm::ArrayRef<Operand> Operands,
     llvm::SmallVectorImpl<RegisterOperandAssignment> &OperandValues) {
   for (const auto &Op : Operands) {
     if (Op.Tracker && Op.IsDef == SelectDef) {
       const int SourceReg = Op.Tracker->getOrigin(Reg);
       if (SourceReg >= 0)
         OperandValues.emplace_back(&Op, SourceReg);
     }
   }
 }

 bool AliasingRegisterOperands::hasImplicitAliasing() const {
   const auto HasImplicit = [](const RegisterOperandAssignment &ROV) {
     return !ROV.Op->IsExplicit;
   };
   return llvm::any_of(Defs, HasImplicit) && llvm::any_of(Uses, HasImplicit);
 }

 bool AliasingConfigurations::empty() const { return Configurations.empty(); }

 bool AliasingConfigurations::hasImplicitAliasing() const {
   return llvm::any_of(Configurations, [](const AliasingRegisterOperands &ARO) {
     return ARO.hasImplicitAliasing();
   });
 }

 AliasingConfigurations::AliasingConfigurations(
     const Instruction &DefInstruction, const Instruction &UseInstruction)
     : DefInstruction(DefInstruction), UseInstruction(UseInstruction) {
   if (UseInstruction.UseRegisters.anyCommon(DefInstruction.DefRegisters)) {
     auto CommonRegisters = UseInstruction.UseRegisters;
     CommonRegisters &= DefInstruction.DefRegisters;
     for (const llvm::MCPhysReg Reg : CommonRegisters.set_bits()) {
       AliasingRegisterOperands ARO;
       addOperandIfAlias(Reg, true, DefInstruction.Operands, ARO.Defs);
       addOperandIfAlias(Reg, false, UseInstruction.Operands, ARO.Uses);
       if (!ARO.Defs.empty() && !ARO.Uses.empty() &&
           !llvm::is_contained(Configurations, ARO))
         Configurations.push_back(std::move(ARO));
     }
   }
 }

 std::mt19937 &randomGenerator() {
   static std::random_device RandomDevice;
   static std::mt19937 RandomGenerator(RandomDevice());
   return RandomGenerator;
 }

 static size_t randomIndex(size_t Size) {
   assert(Size > 0);
   std::uniform_int_distribution<> Distribution(0, Size - 1);
   return Distribution(randomGenerator());
 }

 template <typename C>
 static auto randomElement(const C &Container) -> decltype(Container[0]) {
   return Container[randomIndex(Container.size())];
 }

 static void randomize(const Instruction &Instr, const Variable &Var,
                       llvm::MCOperand &AssignedValue) {
   assert(!Var.TiedOperands.empty());
   const Operand &Op = Instr.Operands[Var.TiedOperands.front()];
   assert(Op.Info != nullptr);
   const auto &OpInfo = *Op.Info;
   switch (OpInfo.OperandType) {
   case llvm::MCOI::OperandType::OPERAND_IMMEDIATE:
     // FIXME: explore immediate values too.
     AssignedValue = llvm::MCOperand::createImm(1);
     break;
   case llvm::MCOI::OperandType::OPERAND_REGISTER: {
     assert(Op.Tracker);
     const auto &Registers = Op.Tracker->sourceBits();
     AssignedValue = llvm::MCOperand::createReg(randomBit(Registers));
     break;
   }
   default:
     break;
   }
 }

 static void setRegisterOperandValue(const RegisterOperandAssignment &ROV,
                                     InstructionInstance &II) {
   assert(ROV.Op);
   if (ROV.Op->IsExplicit) {
     auto &AssignedValue = II.getValueFor(*ROV.Op);
     if (AssignedValue.isValid()) {
       assert(AssignedValue.isReg() && AssignedValue.getReg() == ROV.Reg);
       return;
     }
     AssignedValue = llvm::MCOperand::createReg(ROV.Reg);
   } else {
     assert(ROV.Op->ImplicitReg != nullptr);
     assert(ROV.Reg == *ROV.Op->ImplicitReg);
   }
 }

 size_t randomBit(const llvm::BitVector &Vector) {
   assert(Vector.any());
   auto Itr = Vector.set_bits_begin();
   for (size_t I = randomIndex(Vector.count()); I != 0; --I)
     ++Itr;
   return *Itr;
 }

 void setRandomAliasing(const AliasingConfigurations &AliasingConfigurations,
                        InstructionInstance &DefII, InstructionInstance &UseII) {
   assert(!AliasingConfigurations.empty());
   assert(!AliasingConfigurations.hasImplicitAliasing());
   const auto &RandomConf = randomElement(AliasingConfigurations.Configurations);
   setRegisterOperandValue(randomElement(RandomConf.Defs), DefII);
   setRegisterOperandValue(randomElement(RandomConf.Uses), UseII);
 }

 void DumpMCOperand(const llvm::MCRegisterInfo &MCRegisterInfo,
                    const llvm::MCOperand &Op, llvm::raw_ostream &OS) {
   if (!Op.isValid())
     OS << "Invalid";
   else if (Op.isReg())
     OS << MCRegisterInfo.getName(Op.getReg());
   else if (Op.isImm())
     OS << Op.getImm();
   else if (Op.isFPImm())
     OS << Op.getFPImm();
   else if (Op.isExpr())
     OS << "Expr";
   else if (Op.isInst())
     OS << "SubInst";
 }

 void DumpMCInst(const llvm::MCRegisterInfo &MCRegisterInfo,
                 const llvm::MCInstrInfo &MCInstrInfo,
                 const llvm::MCInst &MCInst, llvm::raw_ostream &OS) {
   OS << MCInstrInfo.getName(MCInst.getOpcode());
   for (unsigned I = 0, E = MCInst.getNumOperands(); I < E; ++I) {
     if (I > 0)
       OS << ',';
     OS << ' ';
     DumpMCOperand(MCRegisterInfo, MCInst.getOperand(I), OS);
   }
 }

 } // namespace exegesis
	//===-- MCInstrDescView.cpp -------------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "MCInstrDescView.h"

	#include <iterator>
	#include <map>
	#include <tuple>

	#include "llvm/ADT/STLExtras.h"

	namespace exegesis {

	Instruction::Instruction(const llvm::MCInstrDesc &MCInstrDesc,
	const RegisterAliasingTrackerCache &RATC)
	: Description(&MCInstrDesc) {
	unsigned OpIndex = 0;
	for (; OpIndex < MCInstrDesc.getNumOperands(); ++OpIndex) {
	const auto &OpInfo = MCInstrDesc.opInfo_begin()[OpIndex];
	Operand Operand;
	Operand.Index = OpIndex;
	Operand.IsDef = (OpIndex < MCInstrDesc.getNumDefs());
	Operand.IsExplicit = true;
	// TODO(gchatelet): Handle isLookupPtrRegClass.
	if (OpInfo.RegClass >= 0)
	Operand.Tracker = &RATC.getRegisterClass(OpInfo.RegClass);
	Operand.TiedToIndex =
	MCInstrDesc.getOperandConstraint(OpIndex, llvm::MCOI::TIED_TO);
	Operand.Info = &OpInfo;
	Operands.push_back(Operand);
	}
	for (const llvm::MCPhysReg *MCPhysReg = MCInstrDesc.getImplicitDefs();
	MCPhysReg && *MCPhysReg; ++MCPhysReg, ++OpIndex) {
	Operand Operand;
	Operand.Index = OpIndex;
	Operand.IsDef = true;
	Operand.IsExplicit = false;
	Operand.Tracker = &RATC.getRegister(*MCPhysReg);
	Operand.ImplicitReg = MCPhysReg;
	Operands.push_back(Operand);
	}
	for (const llvm::MCPhysReg *MCPhysReg = MCInstrDesc.getImplicitUses();
	MCPhysReg && *MCPhysReg; ++MCPhysReg, ++OpIndex) {
	Operand Operand;
	Operand.Index = OpIndex;
	Operand.IsDef = false;
	Operand.IsExplicit = false;
	Operand.Tracker = &RATC.getRegister(*MCPhysReg);
	Operand.ImplicitReg = MCPhysReg;
	Operands.push_back(Operand);
	}
	// Assigning Variables to non tied explicit operands.
	Variables.reserve(Operands.size()); // Variables.size() <= Operands.size()
	for (auto &Op : Operands)
	if (Op.IsExplicit && Op.TiedToIndex < 0) {
	const size_t VariableIndex = Variables.size();
	Op.VariableIndex = VariableIndex;
	Variables.emplace_back();
	Variables.back().Index = VariableIndex;
	}
	// Assigning Variables to tied operands.
	for (auto &Op : Operands)
	if (Op.TiedToIndex >= 0)
	Op.VariableIndex = Operands[Op.TiedToIndex].VariableIndex;
	// Assigning Operands to Variables.
	for (auto &Op : Operands)
	if (Op.VariableIndex >= 0)
	Variables[Op.VariableIndex].TiedOperands.push_back(Op.Index);
	// Processing Aliasing.
	DefRegisters = RATC.emptyRegisters();
	UseRegisters = RATC.emptyRegisters();
	for (const auto &Op : Operands) {
	if (Op.Tracker) {
	auto &Registers = Op.IsDef ? DefRegisters : UseRegisters;
	Registers \|= Op.Tracker->aliasedBits();
	}
	}
	}

	InstructionInstance::InstructionInstance(const Instruction &Instr)
	: Instr(Instr), VariableValues(Instr.Variables.size()) {}

	InstructionInstance::InstructionInstance(InstructionInstance &&) = default;

	InstructionInstance &InstructionInstance::
	operator=(InstructionInstance &&) = default;

	unsigned InstructionInstance::getOpcode() const {
	return Instr.Description->getOpcode();
	}

	llvm::MCOperand &InstructionInstance::getValueFor(const Variable &Var) {
	return VariableValues[Var.Index];
	}

	const llvm::MCOperand &
	InstructionInstance::getValueFor(const Variable &Var) const {
	return VariableValues[Var.Index];
	}

	llvm::MCOperand &InstructionInstance::getValueFor(const Operand &Op) {
	assert(Op.VariableIndex >= 0);
	return getValueFor(Instr.Variables[Op.VariableIndex]);
	}

	const llvm::MCOperand &
	InstructionInstance::getValueFor(const Operand &Op) const {
	assert(Op.VariableIndex >= 0);
	return getValueFor(Instr.Variables[Op.VariableIndex]);
	}

	// forward declaration.
	static void randomize(const Instruction &Instr, const Variable &Var,
	llvm::MCOperand &AssignedValue);

	bool InstructionInstance::hasImmediateVariables() const {
	return llvm::any_of(Instr.Variables, [this](const Variable &Var) {
	assert(!Var.TiedOperands.empty());
	const unsigned OpIndex = Var.TiedOperands[0];
	const Operand &Op = Instr.Operands[OpIndex];
	assert(Op.Info);
	return Op.Info->OperandType == llvm::MCOI::OPERAND_IMMEDIATE;
	});
	}

	void InstructionInstance::randomizeUnsetVariables() {
	for (const Variable &Var : Instr.Variables) {
	llvm::MCOperand &AssignedValue = getValueFor(Var);
	if (!AssignedValue.isValid())
	randomize(Instr, Var, AssignedValue);
	}
	}

	llvm::MCInst InstructionInstance::build() const {
	llvm::MCInst Result;
	Result.setOpcode(Instr.Description->Opcode);
	for (const auto &Op : Instr.Operands)
	if (Op.IsExplicit)
	Result.addOperand(getValueFor(Op));
	return Result;
	}

	SnippetPrototype::SnippetPrototype(SnippetPrototype &&) = default;

	SnippetPrototype &SnippetPrototype::operator=(SnippetPrototype &&) = default;

	bool RegisterOperandAssignment::
	operator==(const RegisterOperandAssignment &Other) const {
	return std::tie(Op, Reg) == std::tie(Other.Op, Other.Reg);
	}

	bool AliasingRegisterOperands::
	operator==(const AliasingRegisterOperands &Other) const {
	return std::tie(Defs, Uses) == std::tie(Other.Defs, Other.Uses);
	}

	static void addOperandIfAlias(
	const llvm::MCPhysReg Reg, bool SelectDef, llvm::ArrayRef<Operand> Operands,
	llvm::SmallVectorImpl<RegisterOperandAssignment> &OperandValues) {
	for (const auto &Op : Operands) {
	if (Op.Tracker && Op.IsDef == SelectDef) {
	const int SourceReg = Op.Tracker->getOrigin(Reg);
	if (SourceReg >= 0)
	OperandValues.emplace_back(&Op, SourceReg);
	}
	}
	}

	bool AliasingRegisterOperands::hasImplicitAliasing() const {
	const auto HasImplicit = [](const RegisterOperandAssignment &ROV) {
	return !ROV.Op->IsExplicit;
	};
	return llvm::any_of(Defs, HasImplicit) && llvm::any_of(Uses, HasImplicit);
	}

	bool AliasingConfigurations::empty() const { return Configurations.empty(); }

	bool AliasingConfigurations::hasImplicitAliasing() const {
	return llvm::any_of(Configurations, [](const AliasingRegisterOperands &ARO) {
	return ARO.hasImplicitAliasing();
	});
	}

	AliasingConfigurations::AliasingConfigurations(
	const Instruction &DefInstruction, const Instruction &UseInstruction)
	: DefInstruction(DefInstruction), UseInstruction(UseInstruction) {
	if (UseInstruction.UseRegisters.anyCommon(DefInstruction.DefRegisters)) {
	auto CommonRegisters = UseInstruction.UseRegisters;
	CommonRegisters &= DefInstruction.DefRegisters;
	for (const llvm::MCPhysReg Reg : CommonRegisters.set_bits()) {
	AliasingRegisterOperands ARO;
	addOperandIfAlias(Reg, true, DefInstruction.Operands, ARO.Defs);
	addOperandIfAlias(Reg, false, UseInstruction.Operands, ARO.Uses);
	if (!ARO.Defs.empty() && !ARO.Uses.empty() &&
	!llvm::is_contained(Configurations, ARO))
	Configurations.push_back(std::move(ARO));
	}
	}
	}

	std::mt19937 &randomGenerator() {
	static std::random_device RandomDevice;
	static std::mt19937 RandomGenerator(RandomDevice());
	return RandomGenerator;
	}

	static size_t randomIndex(size_t Size) {
	assert(Size > 0);
	std::uniform_int_distribution<> Distribution(0, Size - 1);
	return Distribution(randomGenerator());
	}

	template <typename C>
	static auto randomElement(const C &Container) -> decltype(Container[0]) {
	return Container[randomIndex(Container.size())];
	}

	static void randomize(const Instruction &Instr, const Variable &Var,
	llvm::MCOperand &AssignedValue) {
	assert(!Var.TiedOperands.empty());
	const Operand &Op = Instr.Operands[Var.TiedOperands.front()];
	assert(Op.Info != nullptr);
	const auto &OpInfo = *Op.Info;
	switch (OpInfo.OperandType) {
	case llvm::MCOI::OperandType::OPERAND_IMMEDIATE:
	// FIXME: explore immediate values too.
	AssignedValue = llvm::MCOperand::createImm(1);
	break;
	case llvm::MCOI::OperandType::OPERAND_REGISTER: {
	assert(Op.Tracker);
	const auto &Registers = Op.Tracker->sourceBits();
	AssignedValue = llvm::MCOperand::createReg(randomBit(Registers));
	break;
	}
	default:
	break;
	}
	}

	static void setRegisterOperandValue(const RegisterOperandAssignment &ROV,
	InstructionInstance &II) {
	assert(ROV.Op);
	if (ROV.Op->IsExplicit) {
	auto &AssignedValue = II.getValueFor(*ROV.Op);
	if (AssignedValue.isValid()) {
	assert(AssignedValue.isReg() && AssignedValue.getReg() == ROV.Reg);
	return;
	}
	AssignedValue = llvm::MCOperand::createReg(ROV.Reg);
	} else {
	assert(ROV.Op->ImplicitReg != nullptr);
	assert(ROV.Reg == *ROV.Op->ImplicitReg);
	}
	}

	size_t randomBit(const llvm::BitVector &Vector) {
	assert(Vector.any());
	auto Itr = Vector.set_bits_begin();
	for (size_t I = randomIndex(Vector.count()); I != 0; --I)
	++Itr;
	return *Itr;
	}

	void setRandomAliasing(const AliasingConfigurations &AliasingConfigurations,
	InstructionInstance &DefII, InstructionInstance &UseII) {
	assert(!AliasingConfigurations.empty());
	assert(!AliasingConfigurations.hasImplicitAliasing());
	const auto &RandomConf = randomElement(AliasingConfigurations.Configurations);
	setRegisterOperandValue(randomElement(RandomConf.Defs), DefII);
	setRegisterOperandValue(randomElement(RandomConf.Uses), UseII);
	}

	void DumpMCOperand(const llvm::MCRegisterInfo &MCRegisterInfo,
	const llvm::MCOperand &Op, llvm::raw_ostream &OS) {
	if (!Op.isValid())
	OS << "Invalid";
	else if (Op.isReg())
	OS << MCRegisterInfo.getName(Op.getReg());
	else if (Op.isImm())
	OS << Op.getImm();
	else if (Op.isFPImm())
	OS << Op.getFPImm();
	else if (Op.isExpr())
	OS << "Expr";
	else if (Op.isInst())
	OS << "SubInst";
	}

	void DumpMCInst(const llvm::MCRegisterInfo &MCRegisterInfo,
	const llvm::MCInstrInfo &MCInstrInfo,
	const llvm::MCInst &MCInst, llvm::raw_ostream &OS) {
	OS << MCInstrInfo.getName(MCInst.getOpcode());
	for (unsigned I = 0, E = MCInst.getNumOperands(); I < E; ++I) {
	if (I > 0)
	OS << ',';
	OS << ' ';
	DumpMCOperand(MCRegisterInfo, MCInst.getOperand(I), OS);
	}
	}

	} // namespace exegesis