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// Copyright 2016 The SwiftShader Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "Nucleus.hpp"
#include "llvm/Support/IRBuilder.h"
#include "llvm/Function.h"
#include "llvm/GlobalVariable.h"
#include "llvm/Module.h"
#include "llvm/LLVMContext.h"
#include "llvm/Constants.h"
#include "llvm/Intrinsics.h"
#include "llvm/PassManager.h"
#include "llvm/Analysis/LoopPass.h"
#include "llvm/Transforms/Scalar.h"
#include "llvm/Target/TargetData.h"
#include "llvm/Target/TargetOptions.h"
#include "llvm/Support/TargetSelect.h"
#include "../lib/ExecutionEngine/JIT/JIT.h"
#include "LLVMRoutine.hpp"
#include "LLVMRoutineManager.hpp"
#include "x86.hpp"
#include "CPUID.hpp"
#include "Thread.hpp"
#include "Memory.hpp"
#include "MutexLock.hpp"
#include <xmmintrin.h>
#include <fstream>
#if defined(__x86_64__) && defined(_WIN32)
extern "C" void X86CompilationCallback()
{
assert(false); // UNIMPLEMENTED
}
#endif
extern "C"
{
bool (*CodeAnalystInitialize)() = 0;
void (*CodeAnalystCompleteJITLog)() = 0;
bool (*CodeAnalystLogJITCode)(const void *jitCodeStartAddr, unsigned int jitCodeSize, const wchar_t *functionName) = 0;
}
namespace llvm
{
extern bool JITEmitDebugInfo;
}
namespace
{
sw::LLVMRoutineManager *routineManager = nullptr;
llvm::ExecutionEngine *executionEngine = nullptr;
llvm::IRBuilder<> *builder = nullptr;
llvm::LLVMContext *context = nullptr;
llvm::Module *module = nullptr;
llvm::Function *function = nullptr;
sw::BackoffLock codegenMutex;
sw::BasicBlock *falseBB = nullptr;
}
namespace sw
{
using namespace llvm;
Optimization optimization[10] = {InstructionCombining, Disabled};
class Type : public llvm::Type {};
class Value : public llvm::Value {};
class BasicBlock : public llvm::BasicBlock {};
inline Type *T(llvm::Type *t)
{
return reinterpret_cast<Type*>(t);
}
inline Value *V(llvm::Value *t)
{
return reinterpret_cast<Value*>(t);
}
inline std::vector<llvm::Type*> &T(std::vector<Type*> &t)
{
return reinterpret_cast<std::vector<llvm::Type*>&>(t);
}
inline BasicBlock *B(llvm::BasicBlock *t)
{
return reinterpret_cast<BasicBlock*>(t);
}
Nucleus::Nucleus()
{
::codegenMutex.lock(); // Reactor and LLVM are currently not thread safe
InitializeNativeTarget();
JITEmitDebugInfo = false;
if(!::context)
{
::context = new LLVMContext();
}
::module = new Module("", *::context);
::routineManager = new LLVMRoutineManager();
#if defined(__x86_64__)
const char *architecture = "x86-64";
#else
const char *architecture = "x86";
#endif
SmallVector<std::string, 1> MAttrs;
MAttrs.push_back(CPUID::supportsMMX() ? "+mmx" : "-mmx");
MAttrs.push_back(CPUID::supportsCMOV() ? "+cmov" : "-cmov");
MAttrs.push_back(CPUID::supportsSSE() ? "+sse" : "-sse");
MAttrs.push_back(CPUID::supportsSSE2() ? "+sse2" : "-sse2");
MAttrs.push_back(CPUID::supportsSSE3() ? "+sse3" : "-sse3");
MAttrs.push_back(CPUID::supportsSSSE3() ? "+ssse3" : "-ssse3");
MAttrs.push_back(CPUID::supportsSSE4_1() ? "+sse41" : "-sse41");
std::string error;
TargetMachine *targetMachine = EngineBuilder::selectTarget(::module, architecture, "", MAttrs, Reloc::Default, CodeModel::JITDefault, &error);
::executionEngine = JIT::createJIT(::module, 0, ::routineManager, CodeGenOpt::Aggressive, true, targetMachine);
if(!::builder)
{
::builder = new IRBuilder<>(*::context);
#if defined(_WIN32)
HMODULE CodeAnalyst = LoadLibrary("CAJitNtfyLib.dll");
if(CodeAnalyst)
{
CodeAnalystInitialize = (bool(*)())GetProcAddress(CodeAnalyst, "CAJIT_Initialize");
CodeAnalystCompleteJITLog = (void(*)())GetProcAddress(CodeAnalyst, "CAJIT_CompleteJITLog");
CodeAnalystLogJITCode = (bool(*)(const void*, unsigned int, const wchar_t*))GetProcAddress(CodeAnalyst, "CAJIT_LogJITCode");
CodeAnalystInitialize();
}
#endif
}
}
Nucleus::~Nucleus()
{
delete ::executionEngine;
::executionEngine = nullptr;
::routineManager = nullptr;
::function = nullptr;
::module = nullptr;
::codegenMutex.unlock();
}
Routine *Nucleus::acquireRoutine(const wchar_t *name, bool runOptimizations)
{
if(::builder->GetInsertBlock()->empty() || !::builder->GetInsertBlock()->back().isTerminator())
{
llvm::Type *type = ::function->getReturnType();
if(type->isVoidTy())
{
createRetVoid();
}
else
{
createRet(V(UndefValue::get(type)));
}
}
if(false)
{
std::string error;
raw_fd_ostream file("llvm-dump-unopt.txt", error);
::module->print(file, 0);
}
if(runOptimizations)
{
optimize();
}
if(false)
{
std::string error;
raw_fd_ostream file("llvm-dump-opt.txt", error);
::module->print(file, 0);
}
void *entry = ::executionEngine->getPointerToFunction(::function);
LLVMRoutine *routine = ::routineManager->acquireRoutine(entry);
if(CodeAnalystLogJITCode)
{
CodeAnalystLogJITCode(routine->getEntry(), routine->getCodeSize(), name);
}
return routine;
}
void Nucleus::optimize()
{
static PassManager *passManager = nullptr;
if(!passManager)
{
passManager = new PassManager();
UnsafeFPMath = true;
// NoInfsFPMath = true;
// NoNaNsFPMath = true;
passManager->add(new TargetData(*::executionEngine->getTargetData()));
passManager->add(createScalarReplAggregatesPass());
for(int pass = 0; pass < 10 && optimization[pass] != Disabled; pass++)
{
switch(optimization[pass])
{
case Disabled: break;
case CFGSimplification: passManager->add(createCFGSimplificationPass()); break;
case LICM: passManager->add(createLICMPass()); break;
case AggressiveDCE: passManager->add(createAggressiveDCEPass()); break;
case GVN: passManager->add(createGVNPass()); break;
case InstructionCombining: passManager->add(createInstructionCombiningPass()); break;
case Reassociate: passManager->add(createReassociatePass()); break;
case DeadStoreElimination: passManager->add(createDeadStoreEliminationPass()); break;
case SCCP: passManager->add(createSCCPPass()); break;
case ScalarReplAggregates: passManager->add(createScalarReplAggregatesPass()); break;
default:
assert(false);
}
}
}
passManager->run(*::module);
}
Value *Nucleus::allocateStackVariable(Type *type, int arraySize)
{
// Need to allocate it in the entry block for mem2reg to work
llvm::BasicBlock &entryBlock = ::function->getEntryBlock();
Instruction *declaration;
if(arraySize)
{
declaration = new AllocaInst(type, Nucleus::createConstantInt(arraySize));
}
else
{
declaration = new AllocaInst(type, (Value*)0);
}
entryBlock.getInstList().push_front(declaration);
return V(declaration);
}
BasicBlock *Nucleus::createBasicBlock()
{
return B(BasicBlock::Create(*::context, "", ::function));
}
BasicBlock *Nucleus::getInsertBlock()
{
return B(::builder->GetInsertBlock());
}
void Nucleus::setInsertBlock(BasicBlock *basicBlock)
{
// assert(::builder->GetInsertBlock()->back().isTerminator());
return ::builder->SetInsertPoint(basicBlock);
}
void Nucleus::createFunction(Type *ReturnType, std::vector<Type*> &Params)
{
llvm::FunctionType *functionType = llvm::FunctionType::get(ReturnType, T(Params), false);
::function = llvm::Function::Create(functionType, llvm::GlobalValue::InternalLinkage, "", ::module);
::function->setCallingConv(llvm::CallingConv::C);
::builder->SetInsertPoint(BasicBlock::Create(*::context, "", ::function));
}
Value *Nucleus::getArgument(unsigned int index)
{
llvm::Function::arg_iterator args = ::function->arg_begin();
while(index)
{
args++;
index--;
}
return V(&*args);
}
void Nucleus::createRetVoid()
{
x86::emms();
::builder->CreateRetVoid();
}
void Nucleus::createRet(Value *v)
{
x86::emms();
::builder->CreateRet(v);
}
void Nucleus::createBr(BasicBlock *dest)
{
::builder->CreateBr(dest);
}
void Nucleus::createCondBr(Value *cond, BasicBlock *ifTrue, BasicBlock *ifFalse)
{
::builder->CreateCondBr(cond, ifTrue, ifFalse);
}
Value *Nucleus::createAdd(Value *lhs, Value *rhs)
{
return V(::builder->CreateAdd(lhs, rhs));
}
Value *Nucleus::createSub(Value *lhs, Value *rhs)
{
return V(::builder->CreateSub(lhs, rhs));
}
Value *Nucleus::createMul(Value *lhs, Value *rhs)
{
return V(::builder->CreateMul(lhs, rhs));
}
Value *Nucleus::createUDiv(Value *lhs, Value *rhs)
{
return V(::builder->CreateUDiv(lhs, rhs));
}
Value *Nucleus::createSDiv(Value *lhs, Value *rhs)
{
return V(::builder->CreateSDiv(lhs, rhs));
}
Value *Nucleus::createFAdd(Value *lhs, Value *rhs)
{
return V(::builder->CreateFAdd(lhs, rhs));
}
Value *Nucleus::createFSub(Value *lhs, Value *rhs)
{
return V(::builder->CreateFSub(lhs, rhs));
}
Value *Nucleus::createFMul(Value *lhs, Value *rhs)
{
return V(::builder->CreateFMul(lhs, rhs));
}
Value *Nucleus::createFDiv(Value *lhs, Value *rhs)
{
return V(::builder->CreateFDiv(lhs, rhs));
}
Value *Nucleus::createURem(Value *lhs, Value *rhs)
{
return V(::builder->CreateURem(lhs, rhs));
}
Value *Nucleus::createSRem(Value *lhs, Value *rhs)
{
return V(::builder->CreateSRem(lhs, rhs));
}
Value *Nucleus::createFRem(Value *lhs, Value *rhs)
{
return V(::builder->CreateFRem(lhs, rhs));
}
Value *Nucleus::createShl(Value *lhs, Value *rhs)
{
return V(::builder->CreateShl(lhs, rhs));
}
Value *Nucleus::createLShr(Value *lhs, Value *rhs)
{
return V(::builder->CreateLShr(lhs, rhs));
}
Value *Nucleus::createAShr(Value *lhs, Value *rhs)
{
return V(::builder->CreateAShr(lhs, rhs));
}
Value *Nucleus::createAnd(Value *lhs, Value *rhs)
{
return V(::builder->CreateAnd(lhs, rhs));
}
Value *Nucleus::createOr(Value *lhs, Value *rhs)
{
return V(::builder->CreateOr(lhs, rhs));
}
Value *Nucleus::createXor(Value *lhs, Value *rhs)
{
return V(::builder->CreateXor(lhs, rhs));
}
Value *Nucleus::createNeg(Value *v)
{
return V(::builder->CreateNeg(v));
}
Value *Nucleus::createFNeg(Value *v)
{
return V(::builder->CreateFNeg(v));
}
Value *Nucleus::createNot(Value *v)
{
return V(::builder->CreateNot(v));
}
Value *Nucleus::createLoad(Value *ptr, Type *type, bool isVolatile, unsigned int align)
{
assert(ptr->getType()->getContainedType(0) == type);
return V(::builder->Insert(new LoadInst(ptr, "", isVolatile, align)));
}
Value *Nucleus::createStore(Value *value, Value *ptr, Type *type, bool isVolatile, unsigned int align)
{
assert(ptr->getType()->getContainedType(0) == type);
::builder->Insert(new StoreInst(value, ptr, isVolatile, align));
return value;
}
Value *Nucleus::createGEP(Value *ptr, Type *type, Value *index)
{
assert(ptr->getType()->getContainedType(0) == type);
return V(::builder->CreateGEP(ptr, index));
}
Value *Nucleus::createAtomicAdd(Value *ptr, Value *value)
{
return V(::builder->CreateAtomicRMW(AtomicRMWInst::Add, ptr, value, SequentiallyConsistent));
}
Value *Nucleus::createTrunc(Value *v, Type *destType)
{
return V(::builder->CreateTrunc(v, destType));
}
Value *Nucleus::createZExt(Value *v, Type *destType)
{
return V(::builder->CreateZExt(v, destType));
}
Value *Nucleus::createSExt(Value *v, Type *destType)
{
return V(::builder->CreateSExt(v, destType));
}
Value *Nucleus::createFPToSI(Value *v, Type *destType)
{
return V(::builder->CreateFPToSI(v, destType));
}
Value *Nucleus::createUIToFP(Value *v, Type *destType)
{
return V(::builder->CreateUIToFP(v, destType));
}
Value *Nucleus::createSIToFP(Value *v, Type *destType)
{
return V(::builder->CreateSIToFP(v, destType));
}
Value *Nucleus::createFPTrunc(Value *v, Type *destType)
{
return V(::builder->CreateFPTrunc(v, destType));
}
Value *Nucleus::createFPExt(Value *v, Type *destType)
{
return V(::builder->CreateFPExt(v, destType));
}
Value *Nucleus::createBitCast(Value *v, Type *destType)
{
return V(::builder->CreateBitCast(v, destType));
}
Value *Nucleus::createIntCast(Value *v, Type *destType, bool isSigned)
{
return V(::builder->CreateIntCast(v, destType, isSigned));
}
Value *Nucleus::createICmpEQ(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpEQ(lhs, rhs));
}
Value *Nucleus::createICmpNE(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpNE(lhs, rhs));
}
Value *Nucleus::createICmpUGT(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpUGT(lhs, rhs));
}
Value *Nucleus::createICmpUGE(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpUGE(lhs, rhs));
}
Value *Nucleus::createICmpULT(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpULT(lhs, rhs));
}
Value *Nucleus::createICmpULE(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpULE(lhs, rhs));
}
Value *Nucleus::createICmpSGT(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpSGT(lhs, rhs));
}
Value *Nucleus::createICmpSGE(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpSGE(lhs, rhs));
}
Value *Nucleus::createICmpSLT(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpSLT(lhs, rhs));
}
Value *Nucleus::createICmpSLE(Value *lhs, Value *rhs)
{
return V(::builder->CreateICmpSLE(lhs, rhs));
}
Value *Nucleus::createFCmpOEQ(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpOEQ(lhs, rhs));
}
Value *Nucleus::createFCmpOGT(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpOGT(lhs, rhs));
}
Value *Nucleus::createFCmpOGE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpOGE(lhs, rhs));
}
Value *Nucleus::createFCmpOLT(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpOLT(lhs, rhs));
}
Value *Nucleus::createFCmpOLE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpOLE(lhs, rhs));
}
Value *Nucleus::createFCmpONE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpONE(lhs, rhs));
}
Value *Nucleus::createFCmpORD(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpORD(lhs, rhs));
}
Value *Nucleus::createFCmpUNO(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpUNO(lhs, rhs));
}
Value *Nucleus::createFCmpUEQ(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpUEQ(lhs, rhs));
}
Value *Nucleus::createFCmpUGT(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpUGT(lhs, rhs));
}
Value *Nucleus::createFCmpUGE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpUGE(lhs, rhs));
}
Value *Nucleus::createFCmpULT(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpULT(lhs, rhs));
}
Value *Nucleus::createFCmpULE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpULE(lhs, rhs));
}
Value *Nucleus::createFCmpUNE(Value *lhs, Value *rhs)
{
return V(::builder->CreateFCmpULE(lhs, rhs));
}
Value *Nucleus::createExtractElement(Value *vector, Type *type, int index)
{
assert(vector->getType()->getContainedType(0) == type);
return V(::builder->CreateExtractElement(vector, createConstantInt(index)));
}
Value *Nucleus::createInsertElement(Value *vector, Value *element, int index)
{
return V(::builder->CreateInsertElement(vector, element, createConstantInt(index)));
}
Value *Nucleus::createShuffleVector(Value *V1, Value *V2, const int *select)
{
int size = llvm::cast<llvm::VectorType>(V1->getType())->getNumElements();
const int maxSize = 16;
llvm::Constant *swizzle[maxSize];
assert(size <= maxSize);
for(int i = 0; i < size; i++)
{
swizzle[i] = llvm::ConstantInt::get(Type::getInt32Ty(*::context), select[i]);
}
llvm::Value *shuffle = llvm::ConstantVector::get(llvm::ArrayRef<llvm::Constant*>(swizzle, size));
return V(::builder->CreateShuffleVector(V1, V2, shuffle));
}
Value *Nucleus::createSelect(Value *C, Value *ifTrue, Value *ifFalse)
{
return V(::builder->CreateSelect(C, ifTrue, ifFalse));
}
Value *Nucleus::createSwitch(Value *v, BasicBlock *Dest, unsigned NumCases)
{
return V(::builder->CreateSwitch(v, Dest, NumCases));
}
void Nucleus::addSwitchCase(Value *Switch, int Case, BasicBlock *Branch)
{
reinterpret_cast<SwitchInst*>(Switch)->addCase(llvm::ConstantInt::get(Type::getInt32Ty(*::context), Case, true), Branch);
}
void Nucleus::createUnreachable()
{
::builder->CreateUnreachable();
}
static Value *createSwizzle4(Value *val, unsigned char select)
{
int swizzle[4] =
{
(select >> 0) & 0x03,
(select >> 2) & 0x03,
(select >> 4) & 0x03,
(select >> 6) & 0x03,
};
return Nucleus::createShuffleVector(val, val, swizzle);
}
static Value *createMask4(Value *lhs, Value *rhs, unsigned char select)
{
bool mask[4] = {false, false, false, false};
mask[(select >> 0) & 0x03] = true;
mask[(select >> 2) & 0x03] = true;
mask[(select >> 4) & 0x03] = true;
mask[(select >> 6) & 0x03] = true;
int swizzle[4] =
{
mask[0] ? 4 : 0,
mask[1] ? 5 : 1,
mask[2] ? 6 : 2,
mask[3] ? 7 : 3,
};
Value *shuffle = Nucleus::createShuffleVector(lhs, rhs, swizzle);
return shuffle;
}
Value *Nucleus::createConstantPointer(const void *address, Type *Ty, unsigned int align)
{
const GlobalValue *existingGlobal = ::executionEngine->getGlobalValueAtAddress(const_cast<void*>(address)); // FIXME: Const
if(existingGlobal)
{
return (Value*)existingGlobal;
}
llvm::GlobalValue *global = new llvm::GlobalVariable(*::module, Ty, true, llvm::GlobalValue::ExternalLinkage, 0, "");
global->setAlignment(align);
::executionEngine->addGlobalMapping(global, const_cast<void*>(address));
return V(global);
}
Type *Nucleus::getPointerType(Type *ElementType)
{
return T(llvm::PointerType::get(ElementType, 0));
}
Value *Nucleus::createNullValue(Type *Ty)
{
return V(llvm::Constant::getNullValue(Ty));
}
Value *Nucleus::createConstantLong(int64_t i)
{
return V(llvm::ConstantInt::get(Type::getInt64Ty(*::context), i, true));
}
Value *Nucleus::createConstantInt(int i)
{
return V(llvm::ConstantInt::get(Type::getInt32Ty(*::context), i, true));
}
Value *Nucleus::createConstantInt(unsigned int i)
{
return V(llvm::ConstantInt::get(Type::getInt32Ty(*::context), i, false));
}
Value *Nucleus::createConstantBool(bool b)
{
return V(llvm::ConstantInt::get(Type::getInt1Ty(*::context), b));
}
Value *Nucleus::createConstantByte(signed char i)
{
return V(llvm::ConstantInt::get(Type::getInt8Ty(*::context), i, true));
}
Value *Nucleus::createConstantByte(unsigned char i)
{
return V(llvm::ConstantInt::get(Type::getInt8Ty(*::context), i, false));
}
Value *Nucleus::createConstantShort(short i)
{
return V(llvm::ConstantInt::get(Type::getInt16Ty(*::context), i, true));
}
Value *Nucleus::createConstantShort(unsigned short i)
{
return V(llvm::ConstantInt::get(Type::getInt16Ty(*::context), i, false));
}
Value *Nucleus::createConstantFloat(float x)
{
return V(llvm::ConstantFP::get(Float::getType(), x));
}
Value *Nucleus::createNullPointer(Type *Ty)
{
return V(llvm::ConstantPointerNull::get(llvm::PointerType::get(Ty, 0)));
}
Value *Nucleus::createConstantVector(const int64_t *constants, Type *type)
{
assert(llvm::isa<VectorType>(type));
const int numConstants = llvm::cast<VectorType>(type)->getNumElements();
assert(numConstants <= 16);
llvm::Constant *constantVector[16];
for(int i = 0; i < numConstants; i++)
{
constantVector[i] = llvm::ConstantInt::get(type->getContainedType(0), constants[i]);
}
return V(llvm::ConstantVector::get(llvm::ArrayRef<llvm::Constant*>(constantVector, numConstants)));
}
Value *Nucleus::createConstantVector(const double *constants, Type *type)
{
assert(llvm::isa<VectorType>(type));
const int numConstants = llvm::cast<VectorType>(type)->getNumElements();
assert(numConstants <= 8);
llvm::Constant *constantVector[8];
for(int i = 0; i < numConstants; i++)
{
constantVector[i] = llvm::ConstantFP::get(type->getContainedType(0), constants[i]);
}
return V(llvm::ConstantVector::get(llvm::ArrayRef<llvm::Constant*>(constantVector, numConstants)));
}
Type *Void::getType()
{
return T(llvm::Type::getVoidTy(*::context));
}
class MMX : public Variable<MMX>
{
public:
static Type *getType();
};
Type *MMX::getType()
{
return T(llvm::Type::getX86_MMXTy(*::context));
}
Bool::Bool(Argument<Bool> argument)
{
storeValue(argument.value);
}
Bool::Bool()
{
}
Bool::Bool(bool x)
{
storeValue(Nucleus::createConstantBool(x));
}
Bool::Bool(RValue<Bool> rhs)
{
storeValue(rhs.value);
}
Bool::Bool(const Bool &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Bool::Bool(const Reference<Bool> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Bool> Bool::operator=(RValue<Bool> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Bool> Bool::operator=(const Bool &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Bool>(value);
}
RValue<Bool> Bool::operator=(const Reference<Bool> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Bool>(value);
}
RValue<Bool> operator!(RValue<Bool> val)
{
return RValue<Bool>(Nucleus::createNot(val.value));
}
RValue<Bool> operator&&(RValue<Bool> lhs, RValue<Bool> rhs)
{
return RValue<Bool>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Bool> operator||(RValue<Bool> lhs, RValue<Bool> rhs)
{
return RValue<Bool>(Nucleus::createOr(lhs.value, rhs.value));
}
Type *Bool::getType()
{
return T(llvm::Type::getInt1Ty(*::context));
}
Byte::Byte(Argument<Byte> argument)
{
storeValue(argument.value);
}
Byte::Byte(RValue<Int> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, Byte::getType());
storeValue(integer);
}
Byte::Byte(RValue<UInt> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, Byte::getType());
storeValue(integer);
}
Byte::Byte(RValue<UShort> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, Byte::getType());
storeValue(integer);
}
Byte::Byte()
{
}
Byte::Byte(int x)
{
storeValue(Nucleus::createConstantByte((unsigned char)x));
}
Byte::Byte(unsigned char x)
{
storeValue(Nucleus::createConstantByte(x));
}
Byte::Byte(RValue<Byte> rhs)
{
storeValue(rhs.value);
}
Byte::Byte(const Byte &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Byte::Byte(const Reference<Byte> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Byte> Byte::operator=(RValue<Byte> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Byte> Byte::operator=(const Byte &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte>(value);
}
RValue<Byte> Byte::operator=(const Reference<Byte> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte>(value);
}
RValue<Byte> operator+(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Byte> operator-(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<Byte> operator*(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<Byte> operator/(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createUDiv(lhs.value, rhs.value));
}
RValue<Byte> operator%(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createURem(lhs.value, rhs.value));
}
RValue<Byte> operator&(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Byte> operator|(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<Byte> operator^(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<Byte> operator<<(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<Byte> operator>>(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Byte>(Nucleus::createLShr(lhs.value, rhs.value));
}
RValue<Byte> operator+=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs + rhs;
}
RValue<Byte> operator-=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs - rhs;
}
RValue<Byte> operator*=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs * rhs;
}
RValue<Byte> operator/=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs / rhs;
}
RValue<Byte> operator%=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs % rhs;
}
RValue<Byte> operator&=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs & rhs;
}
RValue<Byte> operator|=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs | rhs;
}
RValue<Byte> operator^=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Byte> operator<<=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs << rhs;
}
RValue<Byte> operator>>=(const Byte &lhs, RValue<Byte> rhs)
{
return lhs = lhs >> rhs;
}
RValue<Byte> operator+(RValue<Byte> val)
{
return val;
}
RValue<Byte> operator-(RValue<Byte> val)
{
return RValue<Byte>(Nucleus::createNeg(val.value));
}
RValue<Byte> operator~(RValue<Byte> val)
{
return RValue<Byte>(Nucleus::createNot(val.value));
}
RValue<Byte> operator++(const Byte &val, int) // Post-increment
{
RValue<Byte> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantByte((unsigned char)1)));
val.storeValue(inc);
return res;
}
const Byte &operator++(const Byte &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantByte((unsigned char)1)));
val.storeValue(inc);
return val;
}
RValue<Byte> operator--(const Byte &val, int) // Post-decrement
{
RValue<Byte> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantByte((unsigned char)1)));
val.storeValue(inc);
return res;
}
const Byte &operator--(const Byte &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantByte((unsigned char)1)));
val.storeValue(inc);
return val;
}
RValue<Bool> operator<(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpULT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpULE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<Byte> lhs, RValue<Byte> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
Type *Byte::getType()
{
return T(llvm::Type::getInt8Ty(*::context));
}
SByte::SByte(Argument<SByte> argument)
{
storeValue(argument.value);
}
SByte::SByte(RValue<Int> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, SByte::getType());
storeValue(integer);
}
SByte::SByte(RValue<Short> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, SByte::getType());
storeValue(integer);
}
SByte::SByte()
{
}
SByte::SByte(signed char x)
{
storeValue(Nucleus::createConstantByte(x));
}
SByte::SByte(RValue<SByte> rhs)
{
storeValue(rhs.value);
}
SByte::SByte(const SByte &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
SByte::SByte(const Reference<SByte> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<SByte> SByte::operator=(RValue<SByte> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<SByte> SByte::operator=(const SByte &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<SByte>(value);
}
RValue<SByte> SByte::operator=(const Reference<SByte> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<SByte>(value);
}
RValue<SByte> operator+(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<SByte> operator-(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<SByte> operator*(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<SByte> operator/(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createSDiv(lhs.value, rhs.value));
}
RValue<SByte> operator%(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createSRem(lhs.value, rhs.value));
}
RValue<SByte> operator&(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<SByte> operator|(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<SByte> operator^(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<SByte> operator<<(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<SByte> operator>>(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<SByte>(Nucleus::createAShr(lhs.value, rhs.value));
}
RValue<SByte> operator+=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs + rhs;
}
RValue<SByte> operator-=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs - rhs;
}
RValue<SByte> operator*=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs * rhs;
}
RValue<SByte> operator/=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs / rhs;
}
RValue<SByte> operator%=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs % rhs;
}
RValue<SByte> operator&=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs & rhs;
}
RValue<SByte> operator|=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs | rhs;
}
RValue<SByte> operator^=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<SByte> operator<<=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs << rhs;
}
RValue<SByte> operator>>=(const SByte &lhs, RValue<SByte> rhs)
{
return lhs = lhs >> rhs;
}
RValue<SByte> operator+(RValue<SByte> val)
{
return val;
}
RValue<SByte> operator-(RValue<SByte> val)
{
return RValue<SByte>(Nucleus::createNeg(val.value));
}
RValue<SByte> operator~(RValue<SByte> val)
{
return RValue<SByte>(Nucleus::createNot(val.value));
}
RValue<SByte> operator++(const SByte &val, int) // Post-increment
{
RValue<SByte> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantByte((signed char)1)));
val.storeValue(inc);
return res;
}
const SByte &operator++(const SByte &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantByte((signed char)1)));
val.storeValue(inc);
return val;
}
RValue<SByte> operator--(const SByte &val, int) // Post-decrement
{
RValue<SByte> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantByte((signed char)1)));
val.storeValue(inc);
return res;
}
const SByte &operator--(const SByte &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantByte((signed char)1)));
val.storeValue(inc);
return val;
}
RValue<Bool> operator<(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<SByte> lhs, RValue<SByte> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
Type *SByte::getType()
{
return T(llvm::Type::getInt8Ty(*::context));
}
Short::Short(Argument<Short> argument)
{
storeValue(argument.value);
}
Short::Short(RValue<Int> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, Short::getType());
storeValue(integer);
}
Short::Short()
{
}
Short::Short(short x)
{
storeValue(Nucleus::createConstantShort(x));
}
Short::Short(RValue<Short> rhs)
{
storeValue(rhs.value);
}
Short::Short(const Short &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Short::Short(const Reference<Short> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Short> Short::operator=(RValue<Short> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Short> Short::operator=(const Short &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short>(value);
}
RValue<Short> Short::operator=(const Reference<Short> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short>(value);
}
RValue<Short> operator+(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Short> operator-(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<Short> operator*(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<Short> operator/(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createSDiv(lhs.value, rhs.value));
}
RValue<Short> operator%(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createSRem(lhs.value, rhs.value));
}
RValue<Short> operator&(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Short> operator|(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<Short> operator^(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<Short> operator<<(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<Short> operator>>(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Short>(Nucleus::createAShr(lhs.value, rhs.value));
}
RValue<Short> operator+=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs + rhs;
}
RValue<Short> operator-=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs - rhs;
}
RValue<Short> operator*=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs * rhs;
}
RValue<Short> operator/=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs / rhs;
}
RValue<Short> operator%=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs % rhs;
}
RValue<Short> operator&=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs & rhs;
}
RValue<Short> operator|=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs | rhs;
}
RValue<Short> operator^=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Short> operator<<=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs << rhs;
}
RValue<Short> operator>>=(const Short &lhs, RValue<Short> rhs)
{
return lhs = lhs >> rhs;
}
RValue<Short> operator+(RValue<Short> val)
{
return val;
}
RValue<Short> operator-(RValue<Short> val)
{
return RValue<Short>(Nucleus::createNeg(val.value));
}
RValue<Short> operator~(RValue<Short> val)
{
return RValue<Short>(Nucleus::createNot(val.value));
}
RValue<Short> operator++(const Short &val, int) // Post-increment
{
RValue<Short> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantShort((short)1)));
val.storeValue(inc);
return res;
}
const Short &operator++(const Short &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantShort((short)1)));
val.storeValue(inc);
return val;
}
RValue<Short> operator--(const Short &val, int) // Post-decrement
{
RValue<Short> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantShort((short)1)));
val.storeValue(inc);
return res;
}
const Short &operator--(const Short &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantShort((short)1)));
val.storeValue(inc);
return val;
}
RValue<Bool> operator<(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<Short> lhs, RValue<Short> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
Type *Short::getType()
{
return T(llvm::Type::getInt16Ty(*::context));
}
UShort::UShort(Argument<UShort> argument)
{
storeValue(argument.value);
}
UShort::UShort(RValue<UInt> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, UShort::getType());
storeValue(integer);
}
UShort::UShort(RValue<Int> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, UShort::getType());
storeValue(integer);
}
UShort::UShort()
{
}
UShort::UShort(unsigned short x)
{
storeValue(Nucleus::createConstantShort(x));
}
UShort::UShort(RValue<UShort> rhs)
{
storeValue(rhs.value);
}
UShort::UShort(const UShort &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
UShort::UShort(const Reference<UShort> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<UShort> UShort::operator=(RValue<UShort> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UShort> UShort::operator=(const UShort &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort>(value);
}
RValue<UShort> UShort::operator=(const Reference<UShort> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort>(value);
}
RValue<UShort> operator+(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<UShort> operator-(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<UShort> operator*(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<UShort> operator/(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createUDiv(lhs.value, rhs.value));
}
RValue<UShort> operator%(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createURem(lhs.value, rhs.value));
}
RValue<UShort> operator&(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<UShort> operator|(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<UShort> operator^(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<UShort> operator<<(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<UShort> operator>>(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<UShort>(Nucleus::createLShr(lhs.value, rhs.value));
}
RValue<UShort> operator+=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs + rhs;
}
RValue<UShort> operator-=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs - rhs;
}
RValue<UShort> operator*=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs * rhs;
}
RValue<UShort> operator/=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs / rhs;
}
RValue<UShort> operator%=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs % rhs;
}
RValue<UShort> operator&=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs & rhs;
}
RValue<UShort> operator|=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs | rhs;
}
RValue<UShort> operator^=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<UShort> operator<<=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs << rhs;
}
RValue<UShort> operator>>=(const UShort &lhs, RValue<UShort> rhs)
{
return lhs = lhs >> rhs;
}
RValue<UShort> operator+(RValue<UShort> val)
{
return val;
}
RValue<UShort> operator-(RValue<UShort> val)
{
return RValue<UShort>(Nucleus::createNeg(val.value));
}
RValue<UShort> operator~(RValue<UShort> val)
{
return RValue<UShort>(Nucleus::createNot(val.value));
}
RValue<UShort> operator++(const UShort &val, int) // Post-increment
{
RValue<UShort> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantShort((unsigned short)1)));
val.storeValue(inc);
return res;
}
const UShort &operator++(const UShort &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantShort((unsigned short)1)));
val.storeValue(inc);
return val;
}
RValue<UShort> operator--(const UShort &val, int) // Post-decrement
{
RValue<UShort> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantShort((unsigned short)1)));
val.storeValue(inc);
return res;
}
const UShort &operator--(const UShort &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantShort((unsigned short)1)));
val.storeValue(inc);
return val;
}
RValue<Bool> operator<(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpULT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpULE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<UShort> lhs, RValue<UShort> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
Type *UShort::getType()
{
return T(llvm::Type::getInt16Ty(*::context));
}
Byte4::Byte4(RValue<Byte8> cast)
{
// xyzw.parent = this;
storeValue(Nucleus::createTrunc(Nucleus::createBitCast(cast.value, Long::getType()), Int::getType()));
}
Byte4::Byte4(const Reference<Byte4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Type *Byte4::getType()
{
#if 0
return T(VectorType::get(Byte::getType(), 4));
#else
return UInt::getType(); // FIXME: LLVM doesn't manipulate it as one 32-bit block
#endif
}
Type *SByte4::getType()
{
#if 0
return T(VectorType::get(SByte::getType(), 4));
#else
return Int::getType(); // FIXME: LLVM doesn't manipulate it as one 32-bit block
#endif
}
Byte8::Byte8()
{
// xyzw.parent = this;
}
Byte8::Byte8(uint8_t x0, uint8_t x1, uint8_t x2, uint8_t x3, uint8_t x4, uint8_t x5, uint8_t x6, uint8_t x7)
{
// xyzw.parent = this;
int64_t constantVector[8] = {x0, x1, x2, x3, x4, x5, x6, x7};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(Byte::getType(), 8))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
Byte8::Byte8(RValue<Byte8> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Byte8::Byte8(const Byte8 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Byte8::Byte8(const Reference<Byte8> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Byte8> Byte8::operator=(RValue<Byte8> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Byte8> Byte8::operator=(const Byte8 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte8>(value);
}
RValue<Byte8> Byte8::operator=(const Reference<Byte8> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte8>(value);
}
RValue<Byte8> operator+(RValue<Byte8> lhs, RValue<Byte8> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::paddb(lhs, rhs);
}
else
{
return RValue<Byte8>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<Byte8> operator-(RValue<Byte8> lhs, RValue<Byte8> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::psubb(lhs, rhs);
}
else
{
return RValue<Byte8>(Nucleus::createSub(lhs.value, rhs.value));
}
}
// RValue<Byte8> operator*(RValue<Byte8> lhs, RValue<Byte8> rhs)
// {
// return RValue<Byte8>(Nucleus::createMul(lhs.value, rhs.value));
// }
// RValue<Byte8> operator/(RValue<Byte8> lhs, RValue<Byte8> rhs)
// {
// return RValue<Byte8>(Nucleus::createUDiv(lhs.value, rhs.value));
// }
// RValue<Byte8> operator%(RValue<Byte8> lhs, RValue<Byte8> rhs)
// {
// return RValue<Byte8>(Nucleus::createURem(lhs.value, rhs.value));
// }
RValue<Byte8> operator&(RValue<Byte8> lhs, RValue<Byte8> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Byte8>(x86::pand(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Byte8>(Nucleus::createAnd(lhs.value, rhs.value));
}
}
RValue<Byte8> operator|(RValue<Byte8> lhs, RValue<Byte8> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Byte8>(x86::por(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Byte8>(Nucleus::createOr(lhs.value, rhs.value));
}
}
RValue<Byte8> operator^(RValue<Byte8> lhs, RValue<Byte8> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Byte8>(x86::pxor(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Byte8>(Nucleus::createXor(lhs.value, rhs.value));
}
}
// RValue<Byte8> operator<<(RValue<Byte8> lhs, unsigned char rhs)
// {
// return RValue<Byte8>(Nucleus::createShl(lhs.value, rhs.value));
// }
// RValue<Byte8> operator>>(RValue<Byte8> lhs, unsigned char rhs)
// {
// return RValue<Byte8>(Nucleus::createLShr(lhs.value, rhs.value));
// }
RValue<Byte8> operator+=(const Byte8 &lhs, RValue<Byte8> rhs)
{
return lhs = lhs + rhs;
}
RValue<Byte8> operator-=(const Byte8 &lhs, RValue<Byte8> rhs)
{
return lhs = lhs - rhs;
}
// RValue<Byte8> operator*=(const Byte8 &lhs, RValue<Byte8> rhs)
// {
// return lhs = lhs * rhs;
// }
// RValue<Byte8> operator/=(const Byte8 &lhs, RValue<Byte8> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<Byte8> operator%=(const Byte8 &lhs, RValue<Byte8> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<Byte8> operator&=(const Byte8 &lhs, RValue<Byte8> rhs)
{
return lhs = lhs & rhs;
}
RValue<Byte8> operator|=(const Byte8 &lhs, RValue<Byte8> rhs)
{
return lhs = lhs | rhs;
}
RValue<Byte8> operator^=(const Byte8 &lhs, RValue<Byte8> rhs)
{
return lhs = lhs ^ rhs;
}
// RValue<Byte8> operator<<=(const Byte8 &lhs, RValue<Byte8> rhs)
// {
// return lhs = lhs << rhs;
// }
// RValue<Byte8> operator>>=(const Byte8 &lhs, RValue<Byte8> rhs)
// {
// return lhs = lhs >> rhs;
// }
// RValue<Byte8> operator+(RValue<Byte8> val)
// {
// return val;
// }
// RValue<Byte8> operator-(RValue<Byte8> val)
// {
// return RValue<Byte8>(Nucleus::createNeg(val.value));
// }
RValue<Byte8> operator~(RValue<Byte8> val)
{
if(CPUID::supportsMMX2())
{
return val ^ Byte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
}
else
{
return RValue<Byte8>(Nucleus::createNot(val.value));
}
}
RValue<Byte8> AddSat(RValue<Byte8> x, RValue<Byte8> y)
{
return x86::paddusb(x, y);
}
RValue<Byte8> SubSat(RValue<Byte8> x, RValue<Byte8> y)
{
return x86::psubusb(x, y);
}
RValue<Short4> Unpack(RValue<Byte4> x)
{
Value *int2 = Nucleus::createInsertElement(V(UndefValue::get(VectorType::get(Int::getType(), 2))), x.value, 0);
Value *byte8 = Nucleus::createBitCast(int2, Byte8::getType());
return UnpackLow(RValue<Byte8>(byte8), RValue<Byte8>(byte8));
}
RValue<Short4> UnpackLow(RValue<Byte8> x, RValue<Byte8> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpcklbw(x, y);
}
else
{
int shuffle[8] = {0, 8, 1, 9, 2, 10, 3, 11};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Short4>(Nucleus::createBitCast(packed, Short4::getType()));
}
}
RValue<Short4> UnpackHigh(RValue<Byte8> x, RValue<Byte8> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpckhbw(x, y);
}
else
{
int shuffle[8] = {4, 12, 5, 13, 6, 14, 7, 15};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Short4>(Nucleus::createBitCast(packed, Short4::getType()));
}
}
RValue<Int> SignMask(RValue<Byte8> x)
{
return x86::pmovmskb(x);
}
// RValue<Byte8> CmpGT(RValue<Byte8> x, RValue<Byte8> y)
// {
// return x86::pcmpgtb(x, y); // FIXME: Signedness
// }
RValue<Byte8> CmpEQ(RValue<Byte8> x, RValue<Byte8> y)
{
return x86::pcmpeqb(x, y);
}
Type *Byte8::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(Byte::getType(), 8));
}
}
SByte8::SByte8()
{
// xyzw.parent = this;
}
SByte8::SByte8(uint8_t x0, uint8_t x1, uint8_t x2, uint8_t x3, uint8_t x4, uint8_t x5, uint8_t x6, uint8_t x7)
{
// xyzw.parent = this;
int64_t constantVector[8] = {x0, x1, x2, x3, x4, x5, x6, x7};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(SByte::getType(), 8))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
SByte8::SByte8(RValue<SByte8> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
SByte8::SByte8(const SByte8 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
SByte8::SByte8(const Reference<SByte8> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<SByte8> SByte8::operator=(RValue<SByte8> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<SByte8> SByte8::operator=(const SByte8 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<SByte8>(value);
}
RValue<SByte8> SByte8::operator=(const Reference<SByte8> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<SByte8>(value);
}
RValue<SByte8> operator+(RValue<SByte8> lhs, RValue<SByte8> rhs)
{
if(CPUID::supportsMMX2())
{
return As<SByte8>(x86::paddb(As<Byte8>(lhs), As<Byte8>(rhs)));
}
else
{
return RValue<SByte8>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<SByte8> operator-(RValue<SByte8> lhs, RValue<SByte8> rhs)
{
if(CPUID::supportsMMX2())
{
return As<SByte8>(x86::psubb(As<Byte8>(lhs), As<Byte8>(rhs)));
}
else
{
return RValue<SByte8>(Nucleus::createSub(lhs.value, rhs.value));
}
}
// RValue<SByte8> operator*(RValue<SByte8> lhs, RValue<SByte8> rhs)
// {
// return RValue<SByte8>(Nucleus::createMul(lhs.value, rhs.value));
// }
// RValue<SByte8> operator/(RValue<SByte8> lhs, RValue<SByte8> rhs)
// {
// return RValue<SByte8>(Nucleus::createSDiv(lhs.value, rhs.value));
// }
// RValue<SByte8> operator%(RValue<SByte8> lhs, RValue<SByte8> rhs)
// {
// return RValue<SByte8>(Nucleus::createSRem(lhs.value, rhs.value));
// }
RValue<SByte8> operator&(RValue<SByte8> lhs, RValue<SByte8> rhs)
{
return RValue<SByte8>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<SByte8> operator|(RValue<SByte8> lhs, RValue<SByte8> rhs)
{
return RValue<SByte8>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<SByte8> operator^(RValue<SByte8> lhs, RValue<SByte8> rhs)
{
return RValue<SByte8>(Nucleus::createXor(lhs.value, rhs.value));
}
// RValue<SByte8> operator<<(RValue<SByte8> lhs, unsigned char rhs)
// {
// return RValue<SByte8>(Nucleus::createShl(lhs.value, rhs.value));
// }
// RValue<SByte8> operator>>(RValue<SByte8> lhs, unsigned char rhs)
// {
// return RValue<SByte8>(Nucleus::createAShr(lhs.value, rhs.value));
// }
RValue<SByte8> operator+=(const SByte8 &lhs, RValue<SByte8> rhs)
{
return lhs = lhs + rhs;
}
RValue<SByte8> operator-=(const SByte8 &lhs, RValue<SByte8> rhs)
{
return lhs = lhs - rhs;
}
// RValue<SByte8> operator*=(const SByte8 &lhs, RValue<SByte8> rhs)
// {
// return lhs = lhs * rhs;
// }
// RValue<SByte8> operator/=(const SByte8 &lhs, RValue<SByte8> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<SByte8> operator%=(const SByte8 &lhs, RValue<SByte8> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<SByte8> operator&=(const SByte8 &lhs, RValue<SByte8> rhs)
{
return lhs = lhs & rhs;
}
RValue<SByte8> operator|=(const SByte8 &lhs, RValue<SByte8> rhs)
{
return lhs = lhs | rhs;
}
RValue<SByte8> operator^=(const SByte8 &lhs, RValue<SByte8> rhs)
{
return lhs = lhs ^ rhs;
}
// RValue<SByte8> operator<<=(const SByte8 &lhs, RValue<SByte8> rhs)
// {
// return lhs = lhs << rhs;
// }
// RValue<SByte8> operator>>=(const SByte8 &lhs, RValue<SByte8> rhs)
// {
// return lhs = lhs >> rhs;
// }
// RValue<SByte8> operator+(RValue<SByte8> val)
// {
// return val;
// }
// RValue<SByte8> operator-(RValue<SByte8> val)
// {
// return RValue<SByte8>(Nucleus::createNeg(val.value));
// }
RValue<SByte8> operator~(RValue<SByte8> val)
{
if(CPUID::supportsMMX2())
{
return val ^ SByte8(0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
}
else
{
return RValue<SByte8>(Nucleus::createNot(val.value));
}
}
RValue<SByte8> AddSat(RValue<SByte8> x, RValue<SByte8> y)
{
return x86::paddsb(x, y);
}
RValue<SByte8> SubSat(RValue<SByte8> x, RValue<SByte8> y)
{
return x86::psubsb(x, y);
}
RValue<Short4> UnpackLow(RValue<SByte8> x, RValue<SByte8> y)
{
if(CPUID::supportsMMX2())
{
return As<Short4>(x86::punpcklbw(As<Byte8>(x), As<Byte8>(y)));
}
else
{
int shuffle[8] = {0, 8, 1, 9, 2, 10, 3, 11};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Short4>(Nucleus::createBitCast(packed, Short4::getType()));
}
}
RValue<Short4> UnpackHigh(RValue<SByte8> x, RValue<SByte8> y)
{
if(CPUID::supportsMMX2())
{
return As<Short4>(x86::punpckhbw(As<Byte8>(x), As<Byte8>(y)));
}
else
{
int shuffle[8] = {4, 12, 5, 13, 6, 14, 7, 15};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Short4>(Nucleus::createBitCast(packed, Short4::getType()));
}
}
RValue<Int> SignMask(RValue<SByte8> x)
{
return x86::pmovmskb(As<Byte8>(x));
}
RValue<Byte8> CmpGT(RValue<SByte8> x, RValue<SByte8> y)
{
return x86::pcmpgtb(x, y);
}
RValue<Byte8> CmpEQ(RValue<SByte8> x, RValue<SByte8> y)
{
return x86::pcmpeqb(As<Byte8>(x), As<Byte8>(y));
}
Type *SByte8::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(SByte::getType(), 8));
}
}
Byte16::Byte16(RValue<Byte16> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Byte16::Byte16(const Byte16 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Byte16::Byte16(const Reference<Byte16> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Byte16> Byte16::operator=(RValue<Byte16> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Byte16> Byte16::operator=(const Byte16 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte16>(value);
}
RValue<Byte16> Byte16::operator=(const Reference<Byte16> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Byte16>(value);
}
Type *Byte16::getType()
{
return T(VectorType::get(Byte::getType(), 16));
}
Type *SByte16::getType()
{
return T( VectorType::get(SByte::getType(), 16));
}
Short2::Short2(RValue<Short4> cast)
{
storeValue(Nucleus::createTrunc(Nucleus::createBitCast(cast.value, Long::getType()), UInt::getType()));
}
Type *Short2::getType()
{
#if 0
return T(VectorType::get(Short::getType(), 2));
#else
return UInt::getType(); // FIXME: LLVM doesn't manipulate it as one 32-bit block
#endif
}
UShort2::UShort2(RValue<UShort4> cast)
{
storeValue(Nucleus::createTrunc(Nucleus::createBitCast(cast.value, Long::getType()), UInt::getType()));
}
Type *UShort2::getType()
{
#if 0
return T(VectorType::get(UShort::getType(), 2));
#else
return UInt::getType(); // FIXME: LLVM doesn't manipulate it as one 32-bit block
#endif
}
Short4::Short4(RValue<Int> cast)
{
Value *extend = Nucleus::createZExt(cast.value, Long::getType());
Value *swizzle = Swizzle(RValue<Short4>(extend), 0x00).value;
storeValue(swizzle);
}
Short4::Short4(RValue<Int4> cast)
{
Value *short8 = Nucleus::createBitCast(cast.value, Short8::getType());
#if 0 // FIXME: Check codegen (pshuflw phshufhw pshufd)
Constant *pack[8];
pack[0] = Nucleus::createConstantInt(0);
pack[1] = Nucleus::createConstantInt(2);
pack[2] = Nucleus::createConstantInt(4);
pack[3] = Nucleus::createConstantInt(6);
Value *short4 = Nucleus::createShuffleVector(short8, short8, Nucleus::createConstantVector(pack, 4));
#else
Value *packed;
// FIXME: Use Swizzle<Short8>
if(!CPUID::supportsSSSE3())
{
int pshuflw[8] = {0, 2, 0, 2, 4, 5, 6, 7};
int pshufhw[8] = {0, 1, 2, 3, 4, 6, 4, 6};
Value *shuffle1 = Nucleus::createShuffleVector(short8, short8, pshuflw);
Value *shuffle2 = Nucleus::createShuffleVector(shuffle1, shuffle1, pshufhw);
Value *int4 = Nucleus::createBitCast(shuffle2, Int4::getType());
packed = createSwizzle4(int4, 0x88);
}
else
{
int pshufb[16] = {0, 1, 4, 5, 8, 9, 12, 13, 0, 1, 4, 5, 8, 9, 12, 13};
Value *byte16 = Nucleus::createBitCast(cast.value, Byte16::getType());
packed = Nucleus::createShuffleVector(byte16, byte16, pshufb);
}
#if 0 // FIXME: No optimal instruction selection
Value *qword2 = Nucleus::createBitCast(packed, T(VectorType::get(Long::getType(), 2)));
Value *element = Nucleus::createExtractElement(qword2, 0);
Value *short4 = Nucleus::createBitCast(element, Short4::getType());
#else // FIXME: Requires SSE
Value *int2 = RValue<Int2>(Int2(RValue<Int4>(packed))).value;
Value *short4 = Nucleus::createBitCast(int2, Short4::getType());
#endif
#endif
storeValue(short4);
}
// Short4::Short4(RValue<Float> cast)
// {
// }
Short4::Short4(RValue<Float4> cast)
{
Int4 v4i32 = Int4(cast);
v4i32 = As<Int4>(x86::packssdw(v4i32, v4i32));
storeValue(As<Short4>(Int2(v4i32)).value);
}
Short4::Short4()
{
// xyzw.parent = this;
}
Short4::Short4(short xyzw)
{
// xyzw.parent = this;
int64_t constantVector[4] = {xyzw, xyzw, xyzw, xyzw};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(Short::getType(), 4))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
Short4::Short4(short x, short y, short z, short w)
{
// xyzw.parent = this;
int64_t constantVector[4] = {x, y, z, w};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(Short::getType(), 4))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
Short4::Short4(RValue<Short4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Short4::Short4(const Short4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Short4::Short4(const Reference<Short4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Short4::Short4(RValue<UShort4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Short4::Short4(const UShort4 &rhs)
{
// xyzw.parent = this;
storeValue(rhs.loadValue());
}
Short4::Short4(const Reference<UShort4> &rhs)
{
// xyzw.parent = this;
storeValue(rhs.loadValue());
}
RValue<Short4> Short4::operator=(RValue<Short4> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Short4> Short4::operator=(const Short4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short4>(value);
}
RValue<Short4> Short4::operator=(const Reference<Short4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short4>(value);
}
RValue<Short4> Short4::operator=(RValue<UShort4> rhs) const
{
storeValue(rhs.value);
return RValue<Short4>(rhs);
}
RValue<Short4> Short4::operator=(const UShort4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short4>(value);
}
RValue<Short4> Short4::operator=(const Reference<UShort4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Short4>(value);
}
RValue<Short4> operator+(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::paddw(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<Short4> operator-(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::psubw(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createSub(lhs.value, rhs.value));
}
}
RValue<Short4> operator*(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::pmullw(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createMul(lhs.value, rhs.value));
}
}
// RValue<Short4> operator/(RValue<Short4> lhs, RValue<Short4> rhs)
// {
// return RValue<Short4>(Nucleus::createSDiv(lhs.value, rhs.value));
// }
// RValue<Short4> operator%(RValue<Short4> lhs, RValue<Short4> rhs)
// {
// return RValue<Short4>(Nucleus::createSRem(lhs.value, rhs.value));
// }
RValue<Short4> operator&(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::pand(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createAnd(lhs.value, rhs.value));
}
}
RValue<Short4> operator|(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::por(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createOr(lhs.value, rhs.value));
}
}
RValue<Short4> operator^(RValue<Short4> lhs, RValue<Short4> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::pxor(lhs, rhs);
}
else
{
return RValue<Short4>(Nucleus::createXor(lhs.value, rhs.value));
}
}
RValue<Short4> operator<<(RValue<Short4> lhs, unsigned char rhs)
{
// return RValue<Short4>(Nucleus::createShl(lhs.value, rhs.value));
return x86::psllw(lhs, rhs);
}
RValue<Short4> operator>>(RValue<Short4> lhs, unsigned char rhs)
{
// return RValue<Short4>(Nucleus::createAShr(lhs.value, rhs.value));
return x86::psraw(lhs, rhs);
}
RValue<Short4> operator<<(RValue<Short4> lhs, RValue<Long1> rhs)
{
// return RValue<Short4>(Nucleus::createShl(lhs.value, rhs.value));
return x86::psllw(lhs, rhs);
}
RValue<Short4> operator>>(RValue<Short4> lhs, RValue<Long1> rhs)
{
// return RValue<Short4>(Nucleus::createAShr(lhs.value, rhs.value));
return x86::psraw(lhs, rhs);
}
RValue<Short4> operator+=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs + rhs;
}
RValue<Short4> operator-=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs - rhs;
}
RValue<Short4> operator*=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs * rhs;
}
// RValue<Short4> operator/=(const Short4 &lhs, RValue<Short4> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<Short4> operator%=(const Short4 &lhs, RValue<Short4> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<Short4> operator&=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs & rhs;
}
RValue<Short4> operator|=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs | rhs;
}
RValue<Short4> operator^=(const Short4 &lhs, RValue<Short4> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Short4> operator<<=(const Short4 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<Short4> operator>>=(const Short4 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<Short4> operator<<=(const Short4 &lhs, RValue<Long1> rhs)
{
return lhs = lhs << rhs;
}
RValue<Short4> operator>>=(const Short4 &lhs, RValue<Long1> rhs)
{
return lhs = lhs >> rhs;
}
// RValue<Short4> operator+(RValue<Short4> val)
// {
// return val;
// }
RValue<Short4> operator-(RValue<Short4> val)
{
if(CPUID::supportsMMX2())
{
return Short4(0, 0, 0, 0) - val;
}
else
{
return RValue<Short4>(Nucleus::createNeg(val.value));
}
}
RValue<Short4> operator~(RValue<Short4> val)
{
if(CPUID::supportsMMX2())
{
return val ^ Short4(0xFFFFu, 0xFFFFu, 0xFFFFu, 0xFFFFu);
}
else
{
return RValue<Short4>(Nucleus::createNot(val.value));
}
}
RValue<Short4> RoundShort4(RValue<Float4> cast)
{
RValue<Int4> v4i32 = x86::cvtps2dq(cast);
RValue<Short8> v8i16 = x86::packssdw(v4i32, v4i32);
return As<Short4>(Int2(As<Int4>(v8i16)));
}
RValue<Short4> Max(RValue<Short4> x, RValue<Short4> y)
{
return x86::pmaxsw(x, y);
}
RValue<Short4> Min(RValue<Short4> x, RValue<Short4> y)
{
return x86::pminsw(x, y);
}
RValue<Short4> AddSat(RValue<Short4> x, RValue<Short4> y)
{
return x86::paddsw(x, y);
}
RValue<Short4> SubSat(RValue<Short4> x, RValue<Short4> y)
{
return x86::psubsw(x, y);
}
RValue<Short4> MulHigh(RValue<Short4> x, RValue<Short4> y)
{
return x86::pmulhw(x, y);
}
RValue<Int2> MulAdd(RValue<Short4> x, RValue<Short4> y)
{
return x86::pmaddwd(x, y);
}
RValue<SByte8> Pack(RValue<Short4> x, RValue<Short4> y)
{
return x86::packsswb(x, y);
}
RValue<Int2> UnpackLow(RValue<Short4> x, RValue<Short4> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpcklwd(x, y);
}
else
{
int shuffle[4] = {0, 4, 1, 5};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Int2>(Nucleus::createBitCast(packed, Int2::getType()));
}
}
RValue<Int2> UnpackHigh(RValue<Short4> x, RValue<Short4> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpckhwd(x, y);
}
else
{
int shuffle[4] = {2, 6, 3, 7};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Int2>(Nucleus::createBitCast(packed, Int2::getType()));
}
}
RValue<Short4> Swizzle(RValue<Short4> x, unsigned char select)
{
if(CPUID::supportsMMX2())
{
return x86::pshufw(x, select);
}
else
{
return RValue<Short4>(createSwizzle4(x.value, select));
}
}
RValue<Short4> Insert(RValue<Short4> val, RValue<Short> element, int i)
{
if(CPUID::supportsMMX2())
{
return x86::pinsrw(val, Int(element), i);
}
else
{
return RValue<Short4>(Nucleus::createInsertElement(val.value, element.value, i));
}
}
RValue<Short> Extract(RValue<Short4> val, int i)
{
if(CPUID::supportsMMX2())
{
return Short(x86::pextrw(val, i));
}
else
{
return RValue<Short>(Nucleus::createExtractElement(val.value, Short::getType(), i));
}
}
RValue<Short4> CmpGT(RValue<Short4> x, RValue<Short4> y)
{
return x86::pcmpgtw(x, y);
}
RValue<Short4> CmpEQ(RValue<Short4> x, RValue<Short4> y)
{
return x86::pcmpeqw(x, y);
}
Type *Short4::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(Short::getType(), 4));
}
}
UShort4::UShort4(RValue<Int4> cast)
{
*this = Short4(cast);
}
UShort4::UShort4(RValue<Float4> cast, bool saturate)
{
Float4 sat;
if(saturate)
{
if(CPUID::supportsSSE4_1())
{
sat = Min(cast, Float4(0xFFFF)); // packusdw takes care of 0x0000 saturation
}
else
{
sat = Max(Min(cast, Float4(0xFFFF)), Float4(0x0000));
}
}
else
{
sat = cast;
}
Int4 int4(sat);
if(!saturate || !CPUID::supportsSSE4_1())
{
*this = Short4(Int4(int4));
}
else
{
*this = As<Short4>(Int2(As<Int4>(x86::packusdw(As<UInt4>(int4), As<UInt4>(int4)))));
}
}
UShort4::UShort4()
{
// xyzw.parent = this;
}
UShort4::UShort4(unsigned short xyzw)
{
// xyzw.parent = this;
int64_t constantVector[4] = {xyzw, xyzw, xyzw, xyzw};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(UShort::getType(), 4))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
UShort4::UShort4(unsigned short x, unsigned short y, unsigned short z, unsigned short w)
{
// xyzw.parent = this;
int64_t constantVector[4] = {x, y, z, w};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(UShort::getType(), 4))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
UShort4::UShort4(RValue<UShort4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
UShort4::UShort4(const UShort4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UShort4::UShort4(const Reference<UShort4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UShort4::UShort4(RValue<Short4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
UShort4::UShort4(const Short4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UShort4::UShort4(const Reference<Short4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<UShort4> UShort4::operator=(RValue<UShort4> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UShort4> UShort4::operator=(const UShort4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort4>(value);
}
RValue<UShort4> UShort4::operator=(const Reference<UShort4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort4>(value);
}
RValue<UShort4> UShort4::operator=(RValue<Short4> rhs) const
{
storeValue(rhs.value);
return RValue<UShort4>(rhs);
}
RValue<UShort4> UShort4::operator=(const Short4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort4>(value);
}
RValue<UShort4> UShort4::operator=(const Reference<Short4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort4>(value);
}
RValue<UShort4> operator+(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::paddw(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<UShort4> operator-(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::psubw(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createSub(lhs.value, rhs.value));
}
}
RValue<UShort4> operator*(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::pmullw(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createMul(lhs.value, rhs.value));
}
}
RValue<UShort4> operator&(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::pand(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createAnd(lhs.value, rhs.value));
}
}
RValue<UShort4> operator|(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::por(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createOr(lhs.value, rhs.value));
}
}
RValue<UShort4> operator^(RValue<UShort4> lhs, RValue<UShort4> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(x86::pxor(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UShort4>(Nucleus::createXor(lhs.value, rhs.value));
}
}
RValue<UShort4> operator<<(RValue<UShort4> lhs, unsigned char rhs)
{
// return RValue<Short4>(Nucleus::createShl(lhs.value, rhs.value));
return As<UShort4>(x86::psllw(As<Short4>(lhs), rhs));
}
RValue<UShort4> operator>>(RValue<UShort4> lhs, unsigned char rhs)
{
// return RValue<Short4>(Nucleus::createLShr(lhs.value, rhs.value));
return x86::psrlw(lhs, rhs);
}
RValue<UShort4> operator<<(RValue<UShort4> lhs, RValue<Long1> rhs)
{
// return RValue<Short4>(Nucleus::createShl(lhs.value, rhs.value));
return As<UShort4>(x86::psllw(As<Short4>(lhs), rhs));
}
RValue<UShort4> operator>>(RValue<UShort4> lhs, RValue<Long1> rhs)
{
// return RValue<Short4>(Nucleus::createLShr(lhs.value, rhs.value));
return x86::psrlw(lhs, rhs);
}
RValue<UShort4> operator<<=(const UShort4 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<UShort4> operator>>=(const UShort4 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<UShort4> operator<<=(const UShort4 &lhs, RValue<Long1> rhs)
{
return lhs = lhs << rhs;
}
RValue<UShort4> operator>>=(const UShort4 &lhs, RValue<Long1> rhs)
{
return lhs = lhs >> rhs;
}
RValue<UShort4> operator~(RValue<UShort4> val)
{
if(CPUID::supportsMMX2())
{
return As<UShort4>(As<Short4>(val) ^ Short4(0xFFFFu, 0xFFFFu, 0xFFFFu, 0xFFFFu));
}
else
{
return RValue<UShort4>(Nucleus::createNot(val.value));
}
}
RValue<UShort4> Max(RValue<UShort4> x, RValue<UShort4> y)
{
return RValue<UShort4>(Max(As<Short4>(x) - Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u), As<Short4>(y) - Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u)) + Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u));
}
RValue<UShort4> Min(RValue<UShort4> x, RValue<UShort4> y)
{
return RValue<UShort4>(Min(As<Short4>(x) - Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u), As<Short4>(y) - Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u)) + Short4(0x8000u, 0x8000u, 0x8000u, 0x8000u));
}
RValue<UShort4> AddSat(RValue<UShort4> x, RValue<UShort4> y)
{
return x86::paddusw(x, y);
}
RValue<UShort4> SubSat(RValue<UShort4> x, RValue<UShort4> y)
{
return x86::psubusw(x, y);
}
RValue<UShort4> MulHigh(RValue<UShort4> x, RValue<UShort4> y)
{
return x86::pmulhuw(x, y);
}
RValue<UShort4> Average(RValue<UShort4> x, RValue<UShort4> y)
{
return x86::pavgw(x, y);
}
RValue<Byte8> Pack(RValue<UShort4> x, RValue<UShort4> y)
{
return x86::packuswb(x, y);
}
Type *UShort4::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(UShort::getType(), 4));
}
}
Short8::Short8(short c0, short c1, short c2, short c3, short c4, short c5, short c6, short c7)
{
int64_t constantVector[8] = {c0, c1, c2, c3, c4, c5, c6, c7};
storeValue(Nucleus::createConstantVector(constantVector, getType()));
}
Short8::Short8(RValue<Short8> rhs)
{
storeValue(rhs.value);
}
Short8::Short8(const Reference<Short8> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Short8::Short8(RValue<Short4> lo, RValue<Short4> hi)
{
Value *loLong = Nucleus::createBitCast(lo.value, Long::getType());
Value *hiLong = Nucleus::createBitCast(hi.value, Long::getType());
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
long2 = Nucleus::createInsertElement(long2, loLong, 0);
long2 = Nucleus::createInsertElement(long2, hiLong, 1);
Value *short8 = Nucleus::createBitCast(long2, Short8::getType());
storeValue(short8);
}
RValue<Short8> operator+(RValue<Short8> lhs, RValue<Short8> rhs)
{
return RValue<Short8>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Short8> operator&(RValue<Short8> lhs, RValue<Short8> rhs)
{
return RValue<Short8>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Short8> operator<<(RValue<Short8> lhs, unsigned char rhs)
{
return x86::psllw(lhs, rhs); // FIXME: Fallback required
}
RValue<Short8> operator>>(RValue<Short8> lhs, unsigned char rhs)
{
return x86::psraw(lhs, rhs); // FIXME: Fallback required
}
RValue<Int4> MulAdd(RValue<Short8> x, RValue<Short8> y)
{
return x86::pmaddwd(x, y); // FIXME: Fallback required
}
RValue<Int4> Abs(RValue<Int4> x)
{
if(CPUID::supportsSSSE3())
{
return x86::pabsd(x);
}
else
{
Int4 mask = (x >> 31);
return (mask ^ x) - mask;
}
}
RValue<Short8> MulHigh(RValue<Short8> x, RValue<Short8> y)
{
return x86::pmulhw(x, y); // FIXME: Fallback required
}
Type *Short8::getType()
{
return T(VectorType::get(Short::getType(), 8));
}
UShort8::UShort8(unsigned short c0, unsigned short c1, unsigned short c2, unsigned short c3, unsigned short c4, unsigned short c5, unsigned short c6, unsigned short c7)
{
int64_t constantVector[8] = {c0, c1, c2, c3, c4, c5, c6, c7};
storeValue(Nucleus::createConstantVector(constantVector, getType()));
}
UShort8::UShort8(RValue<UShort8> rhs)
{
storeValue(rhs.value);
}
UShort8::UShort8(const Reference<UShort8> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
UShort8::UShort8(RValue<UShort4> lo, RValue<UShort4> hi)
{
Value *loLong = Nucleus::createBitCast(lo.value, Long::getType());
Value *hiLong = Nucleus::createBitCast(hi.value, Long::getType());
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
long2 = Nucleus::createInsertElement(long2, loLong, 0);
long2 = Nucleus::createInsertElement(long2, hiLong, 1);
Value *short8 = Nucleus::createBitCast(long2, Short8::getType());
storeValue(short8);
}
RValue<UShort8> UShort8::operator=(RValue<UShort8> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UShort8> UShort8::operator=(const UShort8 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort8>(value);
}
RValue<UShort8> UShort8::operator=(const Reference<UShort8> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UShort8>(value);
}
RValue<UShort8> operator&(RValue<UShort8> lhs, RValue<UShort8> rhs)
{
return RValue<UShort8>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<UShort8> operator<<(RValue<UShort8> lhs, unsigned char rhs)
{
return As<UShort8>(x86::psllw(As<Short8>(lhs), rhs)); // FIXME: Fallback required
}
RValue<UShort8> operator>>(RValue<UShort8> lhs, unsigned char rhs)
{
return x86::psrlw(lhs, rhs); // FIXME: Fallback required
}
RValue<UShort8> operator+(RValue<UShort8> lhs, RValue<UShort8> rhs)
{
return RValue<UShort8>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<UShort8> operator*(RValue<UShort8> lhs, RValue<UShort8> rhs)
{
return RValue<UShort8>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<UShort8> operator+=(const UShort8 &lhs, RValue<UShort8> rhs)
{
return lhs = lhs + rhs;
}
RValue<UShort8> operator~(RValue<UShort8> val)
{
return RValue<UShort8>(Nucleus::createNot(val.value));
}
RValue<UShort8> Swizzle(RValue<UShort8> x, char select0, char select1, char select2, char select3, char select4, char select5, char select6, char select7)
{
int pshufb[16] =
{
select0 + 0,
select0 + 1,
select1 + 0,
select1 + 1,
select2 + 0,
select2 + 1,
select3 + 0,
select3 + 1,
select4 + 0,
select4 + 1,
select5 + 0,
select5 + 1,
select6 + 0,
select6 + 1,
select7 + 0,
select7 + 1,
};
Value *byte16 = Nucleus::createBitCast(x.value, Byte16::getType());
Value *shuffle = Nucleus::createShuffleVector(byte16, byte16, pshufb);
Value *short8 = Nucleus::createBitCast(shuffle, UShort8::getType());
return RValue<UShort8>(short8);
}
RValue<UShort8> MulHigh(RValue<UShort8> x, RValue<UShort8> y)
{
return x86::pmulhuw(x, y); // FIXME: Fallback required
}
Type *UShort8::getType()
{
return T(VectorType::get(UShort::getType(), 8));
}
Int::Int(Argument<Int> argument)
{
storeValue(argument.value);
}
Int::Int(RValue<Byte> cast)
{
Value *integer = Nucleus::createZExt(cast.value, Int::getType());
storeValue(integer);
}
Int::Int(RValue<SByte> cast)
{
Value *integer = Nucleus::createSExt(cast.value, Int::getType());
storeValue(integer);
}
Int::Int(RValue<Short> cast)
{
Value *integer = Nucleus::createSExt(cast.value, Int::getType());
storeValue(integer);
}
Int::Int(RValue<UShort> cast)
{
Value *integer = Nucleus::createZExt(cast.value, Int::getType());
storeValue(integer);
}
Int::Int(RValue<Int2> cast)
{
*this = Extract(cast, 0);
}
Int::Int(RValue<Long> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, Int::getType());
storeValue(integer);
}
Int::Int(RValue<Float> cast)
{
Value *integer = Nucleus::createFPToSI(cast.value, Int::getType());
storeValue(integer);
}
Int::Int()
{
}
Int::Int(int x)
{
storeValue(Nucleus::createConstantInt(x));
}
Int::Int(RValue<Int> rhs)
{
storeValue(rhs.value);
}
Int::Int(RValue<UInt> rhs)
{
storeValue(rhs.value);
}
Int::Int(const Int &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Int::Int(const Reference<Int> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Int::Int(const UInt &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Int::Int(const Reference<UInt> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Int> Int::operator=(int rhs) const
{
return RValue<Int>(storeValue(Nucleus::createConstantInt(rhs)));
}
RValue<Int> Int::operator=(RValue<Int> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Int> Int::operator=(RValue<UInt> rhs) const
{
storeValue(rhs.value);
return RValue<Int>(rhs);
}
RValue<Int> Int::operator=(const Int &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int>(value);
}
RValue<Int> Int::operator=(const Reference<Int> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int>(value);
}
RValue<Int> Int::operator=(const UInt &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int>(value);
}
RValue<Int> Int::operator=(const Reference<UInt> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int>(value);
}
RValue<Int> operator+(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Int> operator-(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<Int> operator*(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<Int> operator/(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createSDiv(lhs.value, rhs.value));
}
RValue<Int> operator%(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createSRem(lhs.value, rhs.value));
}
RValue<Int> operator&(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Int> operator|(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<Int> operator^(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<Int> operator<<(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<Int> operator>>(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Int>(Nucleus::createAShr(lhs.value, rhs.value));
}
RValue<Int> operator+=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs + rhs;
}
RValue<Int> operator-=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs - rhs;
}
RValue<Int> operator*=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs * rhs;
}
RValue<Int> operator/=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs / rhs;
}
RValue<Int> operator%=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs % rhs;
}
RValue<Int> operator&=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs & rhs;
}
RValue<Int> operator|=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs | rhs;
}
RValue<Int> operator^=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Int> operator<<=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs << rhs;
}
RValue<Int> operator>>=(const Int &lhs, RValue<Int> rhs)
{
return lhs = lhs >> rhs;
}
RValue<Int> operator+(RValue<Int> val)
{
return val;
}
RValue<Int> operator-(RValue<Int> val)
{
return RValue<Int>(Nucleus::createNeg(val.value));
}
RValue<Int> operator~(RValue<Int> val)
{
return RValue<Int>(Nucleus::createNot(val.value));
}
RValue<Int> operator++(const Int &val, int) // Post-increment
{
RValue<Int> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return res;
}
const Int &operator++(const Int &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return val;
}
RValue<Int> operator--(const Int &val, int) // Post-decrement
{
RValue<Int> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return res;
}
const Int &operator--(const Int &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return val;
}
RValue<Bool> operator<(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpSLE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpSGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<Int> lhs, RValue<Int> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
RValue<Int> Max(RValue<Int> x, RValue<Int> y)
{
return IfThenElse(x > y, x, y);
}
RValue<Int> Min(RValue<Int> x, RValue<Int> y)
{
return IfThenElse(x < y, x, y);
}
RValue<Int> Clamp(RValue<Int> x, RValue<Int> min, RValue<Int> max)
{
return Min(Max(x, min), max);
}
RValue<Int> RoundInt(RValue<Float> cast)
{
return x86::cvtss2si(cast);
// return IfThenElse(val > 0.0f, Int(val + 0.5f), Int(val - 0.5f));
}
Type *Int::getType()
{
return T(llvm::Type::getInt32Ty(*::context));
}
Long::Long(RValue<Int> cast)
{
Value *integer = Nucleus::createSExt(cast.value, Long::getType());
storeValue(integer);
}
Long::Long(RValue<UInt> cast)
{
Value *integer = Nucleus::createZExt(cast.value, Long::getType());
storeValue(integer);
}
Long::Long()
{
}
Long::Long(RValue<Long> rhs)
{
storeValue(rhs.value);
}
RValue<Long> Long::operator=(int64_t rhs) const
{
return RValue<Long>(storeValue(Nucleus::createConstantLong(rhs)));
}
RValue<Long> Long::operator=(RValue<Long> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Long> Long::operator=(const Long &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Long>(value);
}
RValue<Long> Long::operator=(const Reference<Long> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Long>(value);
}
RValue<Long> operator+(RValue<Long> lhs, RValue<Long> rhs)
{
return RValue<Long>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Long> operator-(RValue<Long> lhs, RValue<Long> rhs)
{
return RValue<Long>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<Long> operator+=(const Long &lhs, RValue<Long> rhs)
{
return lhs = lhs + rhs;
}
RValue<Long> operator-=(const Long &lhs, RValue<Long> rhs)
{
return lhs = lhs - rhs;
}
RValue<Long> AddAtomic(RValue<Pointer<Long> > x, RValue<Long> y)
{
return RValue<Long>(Nucleus::createAtomicAdd(x.value, y.value));
}
Type *Long::getType()
{
return T(llvm::Type::getInt64Ty(*::context));
}
Long1::Long1(const RValue<UInt> cast)
{
Value *undefCast = Nucleus::createInsertElement(V(UndefValue::get(VectorType::get(Int::getType(), 2))), cast.value, 0);
Value *zeroCast = Nucleus::createInsertElement(undefCast, V(Nucleus::createConstantInt(0)), 1);
storeValue(Nucleus::createBitCast(zeroCast, Long1::getType()));
}
Long1::Long1(RValue<Long1> rhs)
{
storeValue(rhs.value);
}
Type *Long1::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(Long::getType(), 1));
}
}
UInt::UInt(Argument<UInt> argument)
{
storeValue(argument.value);
}
UInt::UInt(RValue<UShort> cast)
{
Value *integer = Nucleus::createZExt(cast.value, UInt::getType());
storeValue(integer);
}
UInt::UInt(RValue<Long> cast)
{
Value *integer = Nucleus::createTrunc(cast.value, UInt::getType());
storeValue(integer);
}
UInt::UInt(RValue<Float> cast)
{
// Note: createFPToUI is broken, must perform conversion using createFPtoSI
// Value *integer = Nucleus::createFPToUI(cast.value, UInt::getType());
// Smallest positive value representable in UInt, but not in Int
const unsigned int ustart = 0x80000000u;
const float ustartf = float(ustart);
// If the value is negative, store 0, otherwise store the result of the conversion
storeValue((~(As<Int>(cast) >> 31) &
// Check if the value can be represented as an Int
IfThenElse(cast >= ustartf,
// If the value is too large, subtract ustart and re-add it after conversion.
As<Int>(As<UInt>(Int(cast - Float(ustartf))) + UInt(ustart)),
// Otherwise, just convert normally
Int(cast))).value);
}
UInt::UInt()
{
}
UInt::UInt(int x)
{
storeValue(Nucleus::createConstantInt(x));
}
UInt::UInt(unsigned int x)
{
storeValue(Nucleus::createConstantInt(x));
}
UInt::UInt(RValue<UInt> rhs)
{
storeValue(rhs.value);
}
UInt::UInt(RValue<Int> rhs)
{
storeValue(rhs.value);
}
UInt::UInt(const UInt &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
UInt::UInt(const Reference<UInt> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
UInt::UInt(const Int &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
UInt::UInt(const Reference<Int> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<UInt> UInt::operator=(unsigned int rhs) const
{
return RValue<UInt>(storeValue(Nucleus::createConstantInt(rhs)));
}
RValue<UInt> UInt::operator=(RValue<UInt> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UInt> UInt::operator=(RValue<Int> rhs) const
{
storeValue(rhs.value);
return RValue<UInt>(rhs);
}
RValue<UInt> UInt::operator=(const UInt &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt>(value);
}
RValue<UInt> UInt::operator=(const Reference<UInt> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt>(value);
}
RValue<UInt> UInt::operator=(const Int &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt>(value);
}
RValue<UInt> UInt::operator=(const Reference<Int> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt>(value);
}
RValue<UInt> operator+(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<UInt> operator-(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<UInt> operator*(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<UInt> operator/(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createUDiv(lhs.value, rhs.value));
}
RValue<UInt> operator%(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createURem(lhs.value, rhs.value));
}
RValue<UInt> operator&(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<UInt> operator|(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<UInt> operator^(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<UInt> operator<<(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<UInt> operator>>(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<UInt>(Nucleus::createLShr(lhs.value, rhs.value));
}
RValue<UInt> operator+=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs + rhs;
}
RValue<UInt> operator-=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs - rhs;
}
RValue<UInt> operator*=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs * rhs;
}
RValue<UInt> operator/=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs / rhs;
}
RValue<UInt> operator%=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs % rhs;
}
RValue<UInt> operator&=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs & rhs;
}
RValue<UInt> operator|=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs | rhs;
}
RValue<UInt> operator^=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<UInt> operator<<=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs << rhs;
}
RValue<UInt> operator>>=(const UInt &lhs, RValue<UInt> rhs)
{
return lhs = lhs >> rhs;
}
RValue<UInt> operator+(RValue<UInt> val)
{
return val;
}
RValue<UInt> operator-(RValue<UInt> val)
{
return RValue<UInt>(Nucleus::createNeg(val.value));
}
RValue<UInt> operator~(RValue<UInt> val)
{
return RValue<UInt>(Nucleus::createNot(val.value));
}
RValue<UInt> operator++(const UInt &val, int) // Post-increment
{
RValue<UInt> res = val;
Value *inc = Nucleus::createAdd(res.value, V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return res;
}
const UInt &operator++(const UInt &val) // Pre-increment
{
Value *inc = Nucleus::createAdd(val.loadValue(), V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return val;
}
RValue<UInt> operator--(const UInt &val, int) // Post-decrement
{
RValue<UInt> res = val;
Value *inc = Nucleus::createSub(res.value, V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return res;
}
const UInt &operator--(const UInt &val) // Pre-decrement
{
Value *inc = Nucleus::createSub(val.loadValue(), V(Nucleus::createConstantInt(1)));
val.storeValue(inc);
return val;
}
RValue<UInt> Max(RValue<UInt> x, RValue<UInt> y)
{
return IfThenElse(x > y, x, y);
}
RValue<UInt> Min(RValue<UInt> x, RValue<UInt> y)
{
return IfThenElse(x < y, x, y);
}
RValue<UInt> Clamp(RValue<UInt> x, RValue<UInt> min, RValue<UInt> max)
{
return Min(Max(x, min), max);
}
RValue<Bool> operator<(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpULT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpULE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpUGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpNE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<UInt> lhs, RValue<UInt> rhs)
{
return RValue<Bool>(Nucleus::createICmpEQ(lhs.value, rhs.value));
}
// RValue<UInt> RoundUInt(RValue<Float> cast)
// {
// return x86::cvtss2si(val); // FIXME: Unsigned
//
// // return IfThenElse(val > 0.0f, Int(val + 0.5f), Int(val - 0.5f));
// }
Type *UInt::getType()
{
return T(llvm::Type::getInt32Ty(*::context));
}
// Int2::Int2(RValue<Int> cast)
// {
// Value *extend = Nucleus::createZExt(cast.value, Long::getType());
// Value *vector = Nucleus::createBitCast(extend, Int2::getType());
//
// int shuffle[2] = {0, 0};
// Value *replicate = Nucleus::createShuffleVector(vector, vector, shuffle);
//
// storeValue(replicate);
// }
Int2::Int2(RValue<Int4> cast)
{
Value *long2 = Nucleus::createBitCast(cast.value, T(VectorType::get(Long::getType(), 2)));
Value *element = Nucleus::createExtractElement(long2, Long::getType(), 0);
Value *int2 = Nucleus::createBitCast(element, Int2::getType());
storeValue(int2);
}
Int2::Int2()
{
// xy.parent = this;
}
Int2::Int2(int x, int y)
{
// xy.parent = this;
int64_t constantVector[2] = {x, y};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(Int::getType(), 2))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
Int2::Int2(RValue<Int2> rhs)
{
// xy.parent = this;
storeValue(rhs.value);
}
Int2::Int2(const Int2 &rhs)
{
// xy.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int2::Int2(const Reference<Int2> &rhs)
{
// xy.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int2::Int2(RValue<Int> lo, RValue<Int> hi)
{
if(CPUID::supportsMMX2())
{
// movd mm0, lo
// movd mm1, hi
// punpckldq mm0, mm1
storeValue(As<Int2>(UnpackLow(As<Int2>(Long1(RValue<UInt>(lo))), As<Int2>(Long1(RValue<UInt>(hi))))).value);
}
else
{
int shuffle[2] = {0, 1};
Value *packed = Nucleus::createShuffleVector(Nucleus::createBitCast(lo.value, T(VectorType::get(Int::getType(), 1))), Nucleus::createBitCast(hi.value, T(VectorType::get(Int::getType(), 1))), shuffle);
storeValue(Nucleus::createBitCast(packed, Int2::getType()));
}
}
RValue<Int2> Int2::operator=(RValue<Int2> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Int2> Int2::operator=(const Int2 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int2>(value);
}
RValue<Int2> Int2::operator=(const Reference<Int2> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int2>(value);
}
RValue<Int2> operator+(RValue<Int2> lhs, RValue<Int2> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::paddd(lhs, rhs);
}
else
{
return RValue<Int2>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<Int2> operator-(RValue<Int2> lhs, RValue<Int2> rhs)
{
if(CPUID::supportsMMX2())
{
return x86::psubd(lhs, rhs);
}
else
{
return RValue<Int2>(Nucleus::createSub(lhs.value, rhs.value));
}
}
// RValue<Int2> operator*(RValue<Int2> lhs, RValue<Int2> rhs)
// {
// return RValue<Int2>(Nucleus::createMul(lhs.value, rhs.value));
// }
// RValue<Int2> operator/(RValue<Int2> lhs, RValue<Int2> rhs)
// {
// return RValue<Int2>(Nucleus::createSDiv(lhs.value, rhs.value));
// }
// RValue<Int2> operator%(RValue<Int2> lhs, RValue<Int2> rhs)
// {
// return RValue<Int2>(Nucleus::createSRem(lhs.value, rhs.value));
// }
RValue<Int2> operator&(RValue<Int2> lhs, RValue<Int2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Int2>(x86::pand(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Int2>(Nucleus::createAnd(lhs.value, rhs.value));
}
}
RValue<Int2> operator|(RValue<Int2> lhs, RValue<Int2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Int2>(x86::por(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Int2>(Nucleus::createOr(lhs.value, rhs.value));
}
}
RValue<Int2> operator^(RValue<Int2> lhs, RValue<Int2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<Int2>(x86::pxor(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<Int2>(Nucleus::createXor(lhs.value, rhs.value));
}
}
RValue<Int2> operator<<(RValue<Int2> lhs, unsigned char rhs)
{
// return RValue<Int2>(Nucleus::createShl(lhs.value, rhs.value));
return x86::pslld(lhs, rhs);
}
RValue<Int2> operator>>(RValue<Int2> lhs, unsigned char rhs)
{
// return RValue<Int2>(Nucleus::createAShr(lhs.value, rhs.value));
return x86::psrad(lhs, rhs);
}
RValue<Int2> operator<<(RValue<Int2> lhs, RValue<Long1> rhs)
{
// return RValue<Int2>(Nucleus::createShl(lhs.value, rhs.value));
return x86::pslld(lhs, rhs);
}
RValue<Int2> operator>>(RValue<Int2> lhs, RValue<Long1> rhs)
{
// return RValue<Int2>(Nucleus::createAShr(lhs.value, rhs.value));
return x86::psrad(lhs, rhs);
}
RValue<Int2> operator+=(const Int2 &lhs, RValue<Int2> rhs)
{
return lhs = lhs + rhs;
}
RValue<Int2> operator-=(const Int2 &lhs, RValue<Int2> rhs)
{
return lhs = lhs - rhs;
}
// RValue<Int2> operator*=(const Int2 &lhs, RValue<Int2> rhs)
// {
// return lhs = lhs * rhs;
// }
// RValue<Int2> operator/=(const Int2 &lhs, RValue<Int2> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<Int2> operator%=(const Int2 &lhs, RValue<Int2> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<Int2> operator&=(const Int2 &lhs, RValue<Int2> rhs)
{
return lhs = lhs & rhs;
}
RValue<Int2> operator|=(const Int2 &lhs, RValue<Int2> rhs)
{
return lhs = lhs | rhs;
}
RValue<Int2> operator^=(const Int2 &lhs, RValue<Int2> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Int2> operator<<=(const Int2 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<Int2> operator>>=(const Int2 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<Int2> operator<<=(const Int2 &lhs, RValue<Long1> rhs)
{
return lhs = lhs << rhs;
}
RValue<Int2> operator>>=(const Int2 &lhs, RValue<Long1> rhs)
{
return lhs = lhs >> rhs;
}
// RValue<Int2> operator+(RValue<Int2> val)
// {
// return val;
// }
// RValue<Int2> operator-(RValue<Int2> val)
// {
// return RValue<Int2>(Nucleus::createNeg(val.value));
// }
RValue<Int2> operator~(RValue<Int2> val)
{
if(CPUID::supportsMMX2())
{
return val ^ Int2(0xFFFFFFFF, 0xFFFFFFFF);
}
else
{
return RValue<Int2>(Nucleus::createNot(val.value));
}
}
RValue<Long1> UnpackLow(RValue<Int2> x, RValue<Int2> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpckldq(x, y);
}
else
{
int shuffle[2] = {0, 2};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Long1>(Nucleus::createBitCast(packed, Long1::getType()));
}
}
RValue<Long1> UnpackHigh(RValue<Int2> x, RValue<Int2> y)
{
if(CPUID::supportsMMX2())
{
return x86::punpckhdq(x, y);
}
else
{
int shuffle[2] = {1, 3};
Value *packed = Nucleus::createShuffleVector(x.value, y.value, shuffle);
return RValue<Long1>(Nucleus::createBitCast(packed, Long1::getType()));
}
}
RValue<Int> Extract(RValue<Int2> val, int i)
{
if(false) // FIXME: LLVM does not generate optimal code
{
return RValue<Int>(Nucleus::createExtractElement(val.value, Int::getType(), i));
}
else
{
if(i == 0)
{
return RValue<Int>(Nucleus::createExtractElement(Nucleus::createBitCast(val.value, T(VectorType::get(Int::getType(), 2))), Int::getType(), 0));
}
else
{
Int2 val2 = As<Int2>(UnpackHigh(val, val));
return Extract(val2, 0);
}
}
}
RValue<Int2> Insert(RValue<Int2> val, RValue<Int> element, int i)
{
return RValue<Int2>(Nucleus::createBitCast(Nucleus::createInsertElement(Nucleus::createBitCast(val.value, T(VectorType::get(Int::getType(), 2))), element.value, i), Int2::getType()));
}
Type *Int2::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(Int::getType(), 2));
}
}
UInt2::UInt2()
{
// xy.parent = this;
}
UInt2::UInt2(unsigned int x, unsigned int y)
{
// xy.parent = this;
int64_t constantVector[2] = {x, y};
Value *vector = V(Nucleus::createConstantVector(constantVector, T(VectorType::get(UInt::getType(), 2))));
storeValue(Nucleus::createBitCast(vector, getType()));
}
UInt2::UInt2(RValue<UInt2> rhs)
{
// xy.parent = this;
storeValue(rhs.value);
}
UInt2::UInt2(const UInt2 &rhs)
{
// xy.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UInt2::UInt2(const Reference<UInt2> &rhs)
{
// xy.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<UInt2> UInt2::operator=(RValue<UInt2> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UInt2> UInt2::operator=(const UInt2 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt2>(value);
}
RValue<UInt2> UInt2::operator=(const Reference<UInt2> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt2>(value);
}
RValue<UInt2> operator+(RValue<UInt2> lhs, RValue<UInt2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UInt2>(x86::paddd(As<Int2>(lhs), As<Int2>(rhs)));
}
else
{
return RValue<UInt2>(Nucleus::createAdd(lhs.value, rhs.value));
}
}
RValue<UInt2> operator-(RValue<UInt2> lhs, RValue<UInt2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UInt2>(x86::psubd(As<Int2>(lhs), As<Int2>(rhs)));
}
else
{
return RValue<UInt2>(Nucleus::createSub(lhs.value, rhs.value));
}
}
// RValue<UInt2> operator*(RValue<UInt2> lhs, RValue<UInt2> rhs)
// {
// return RValue<UInt2>(Nucleus::createMul(lhs.value, rhs.value));
// }
// RValue<UInt2> operator/(RValue<UInt2> lhs, RValue<UInt2> rhs)
// {
// return RValue<UInt2>(Nucleus::createUDiv(lhs.value, rhs.value));
// }
// RValue<UInt2> operator%(RValue<UInt2> lhs, RValue<UInt2> rhs)
// {
// return RValue<UInt2>(Nucleus::createURem(lhs.value, rhs.value));
// }
RValue<UInt2> operator&(RValue<UInt2> lhs, RValue<UInt2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UInt2>(x86::pand(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UInt2>(Nucleus::createAnd(lhs.value, rhs.value));
}
}
RValue<UInt2> operator|(RValue<UInt2> lhs, RValue<UInt2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UInt2>(x86::por(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UInt2>(Nucleus::createOr(lhs.value, rhs.value));
}
}
RValue<UInt2> operator^(RValue<UInt2> lhs, RValue<UInt2> rhs)
{
if(CPUID::supportsMMX2())
{
return As<UInt2>(x86::pxor(As<Short4>(lhs), As<Short4>(rhs)));
}
else
{
return RValue<UInt2>(Nucleus::createXor(lhs.value, rhs.value));
}
}
RValue<UInt2> operator<<(RValue<UInt2> lhs, unsigned char rhs)
{
// return RValue<UInt2>(Nucleus::createShl(lhs.value, rhs.value));
return As<UInt2>(x86::pslld(As<Int2>(lhs), rhs));
}
RValue<UInt2> operator>>(RValue<UInt2> lhs, unsigned char rhs)
{
// return RValue<UInt2>(Nucleus::createLShr(lhs.value, rhs.value));
return x86::psrld(lhs, rhs);
}
RValue<UInt2> operator<<(RValue<UInt2> lhs, RValue<Long1> rhs)
{
// return RValue<UInt2>(Nucleus::createShl(lhs.value, rhs.value));
return As<UInt2>(x86::pslld(As<Int2>(lhs), rhs));
}
RValue<UInt2> operator>>(RValue<UInt2> lhs, RValue<Long1> rhs)
{
// return RValue<UInt2>(Nucleus::createLShr(lhs.value, rhs.value));
return x86::psrld(lhs, rhs);
}
RValue<UInt2> operator+=(const UInt2 &lhs, RValue<UInt2> rhs)
{
return lhs = lhs + rhs;
}
RValue<UInt2> operator-=(const UInt2 &lhs, RValue<UInt2> rhs)
{
return lhs = lhs - rhs;
}
// RValue<UInt2> operator*=(const UInt2 &lhs, RValue<UInt2> rhs)
// {
// return lhs = lhs * rhs;
// }
// RValue<UInt2> operator/=(const UInt2 &lhs, RValue<UInt2> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<UInt2> operator%=(const UInt2 &lhs, RValue<UInt2> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<UInt2> operator&=(const UInt2 &lhs, RValue<UInt2> rhs)
{
return lhs = lhs & rhs;
}
RValue<UInt2> operator|=(const UInt2 &lhs, RValue<UInt2> rhs)
{
return lhs = lhs | rhs;
}
RValue<UInt2> operator^=(const UInt2 &lhs, RValue<UInt2> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<UInt2> operator<<=(const UInt2 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<UInt2> operator>>=(const UInt2 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<UInt2> operator<<=(const UInt2 &lhs, RValue<Long1> rhs)
{
return lhs = lhs << rhs;
}
RValue<UInt2> operator>>=(const UInt2 &lhs, RValue<Long1> rhs)
{
return lhs = lhs >> rhs;
}
// RValue<UInt2> operator+(RValue<UInt2> val)
// {
// return val;
// }
// RValue<UInt2> operator-(RValue<UInt2> val)
// {
// return RValue<UInt2>(Nucleus::createNeg(val.value));
// }
RValue<UInt2> operator~(RValue<UInt2> val)
{
if(CPUID::supportsMMX2())
{
return val ^ UInt2(0xFFFFFFFF, 0xFFFFFFFF);
}
else
{
return RValue<UInt2>(Nucleus::createNot(val.value));
}
}
Type *UInt2::getType()
{
if(CPUID::supportsMMX2())
{
return MMX::getType();
}
else
{
return T(VectorType::get(UInt::getType(), 2));
}
}
Int4::Int4(RValue<Byte4> cast)
{
Value *x = Nucleus::createBitCast(cast.value, Int::getType());
Value *a = Nucleus::createInsertElement(V(UndefValue::get(Int4::getType())), x, 0);
Value *e;
if (CPUID::supportsSSE4_1())
{
e = x86::pmovzxbd(RValue<Int4>(a)).value;
}
else
{
int swizzle[16] = {0, 16, 1, 17, 2, 18, 3, 19, 4, 20, 5, 21, 6, 22, 7, 23};
Value *b = Nucleus::createBitCast(a, Byte16::getType());
Value *c = Nucleus::createShuffleVector(b, V(Nucleus::createNullValue(Byte16::getType())), swizzle);
int swizzle2[8] = {0, 8, 1, 9, 2, 10, 3, 11};
Value *d = Nucleus::createBitCast(c, Short8::getType());
e = Nucleus::createShuffleVector(d, V(Nucleus::createNullValue(Short8::getType())), swizzle2);
}
Value *f = Nucleus::createBitCast(e, Int4::getType());
storeValue(f);
}
Int4::Int4(RValue<SByte4> cast)
{
Value *x = Nucleus::createBitCast(cast.value, Int::getType());
Value *a = Nucleus::createInsertElement(V(UndefValue::get(Int4::getType())), x, 0);
Value *g;
if (CPUID::supportsSSE4_1())
{
g = x86::pmovsxbd(RValue<Int4>(a)).value;
}
else
{
int swizzle[16] = {0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7};
Value *b = Nucleus::createBitCast(a, Byte16::getType());
Value *c = Nucleus::createShuffleVector(b, b, swizzle);
int swizzle2[8] = {0, 0, 1, 1, 2, 2, 3, 3};
Value *d = Nucleus::createBitCast(c, Short8::getType());
Value *e = Nucleus::createShuffleVector(d, d, swizzle2);
Value *f = Nucleus::createBitCast(e, Int4::getType());
// g = Nucleus::createAShr(f, Nucleus::createConstantInt(24));
g = x86::psrad(RValue<Int4>(f), 24).value;
}
storeValue(g);
}
Int4::Int4(RValue<Float4> cast)
{
// xyzw.parent = this;
Value *xyzw = Nucleus::createFPToSI(cast.value, Int4::getType());
storeValue(xyzw);
}
Int4::Int4(RValue<Short4> cast)
{
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
Value *element = Nucleus::createBitCast(cast.value, Long::getType());
long2 = Nucleus::createInsertElement(long2, element, 0);
RValue<Int4> vector = RValue<Int4>(Nucleus::createBitCast(long2, Int4::getType()));
if(CPUID::supportsSSE4_1())
{
storeValue(x86::pmovsxwd(vector).value);
}
else
{
Value *b = Nucleus::createBitCast(vector.value, Short8::getType());
int swizzle[8] = {0, 0, 1, 1, 2, 2, 3, 3};
Value *c = Nucleus::createShuffleVector(b, b, swizzle);
Value *d = Nucleus::createBitCast(c, Int4::getType());
storeValue(d);
// Each Short is packed into each Int in the (Short | Short) format.
// Shifting by 16 will retrieve the original Short value.
// Shitfing an Int will propagate the sign bit, which will work
// for both positive and negative values of a Short.
*this >>= 16;
}
}
Int4::Int4(RValue<UShort4> cast)
{
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
Value *element = Nucleus::createBitCast(cast.value, Long::getType());
long2 = Nucleus::createInsertElement(long2, element, 0);
RValue<Int4> vector = RValue<Int4>(Nucleus::createBitCast(long2, Int4::getType()));
if(CPUID::supportsSSE4_1())
{
storeValue(x86::pmovzxwd(RValue<Int4>(vector)).value);
}
else
{
Value *b = Nucleus::createBitCast(vector.value, Short8::getType());
int swizzle[8] = {0, 8, 1, 9, 2, 10, 3, 11};
Value *c = Nucleus::createShuffleVector(b, V(Nucleus::createNullValue(Short8::getType())), swizzle);
Value *d = Nucleus::createBitCast(c, Int4::getType());
storeValue(d);
}
}
Int4::Int4()
{
// xyzw.parent = this;
}
Int4::Int4(int xyzw)
{
constant(xyzw, xyzw, xyzw, xyzw);
}
Int4::Int4(int x, int yzw)
{
constant(x, yzw, yzw, yzw);
}
Int4::Int4(int x, int y, int zw)
{
constant(x, y, zw, zw);
}
Int4::Int4(int x, int y, int z, int w)
{
constant(x, y, z, w);
}
void Int4::constant(int x, int y, int z, int w)
{
// xyzw.parent = this;
int64_t constantVector[4] = {x, y, z, w};
storeValue(Nucleus::createConstantVector(constantVector, getType()));
}
Int4::Int4(RValue<Int4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Int4::Int4(const Int4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int4::Int4(const Reference<Int4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int4::Int4(RValue<UInt4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
Int4::Int4(const UInt4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int4::Int4(const Reference<UInt4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Int4::Int4(RValue<Int2> lo, RValue<Int2> hi)
{
// xyzw.parent = this;
Value *loLong = Nucleus::createBitCast(lo.value, Long::getType());
Value *hiLong = Nucleus::createBitCast(hi.value, Long::getType());
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
long2 = Nucleus::createInsertElement(long2, loLong, 0);
long2 = Nucleus::createInsertElement(long2, hiLong, 1);
Value *int4 = Nucleus::createBitCast(long2, Int4::getType());
storeValue(int4);
}
Int4::Int4(RValue<Int> rhs)
{
// xyzw.parent = this;
Value *vector = loadValue();
Value *insert = Nucleus::createInsertElement(vector, rhs.value, 0);
int swizzle[4] = {0, 0, 0, 0};
Value *replicate = Nucleus::createShuffleVector(insert, insert, swizzle);
storeValue(replicate);
}
Int4::Int4(const Int &rhs)
{
// xyzw.parent = this;
*this = RValue<Int>(rhs.loadValue());
}
Int4::Int4(const Reference<Int> &rhs)
{
// xyzw.parent = this;
*this = RValue<Int>(rhs.loadValue());
}
RValue<Int4> Int4::operator=(RValue<Int4> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Int4> Int4::operator=(const Int4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int4>(value);
}
RValue<Int4> Int4::operator=(const Reference<Int4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Int4>(value);
}
RValue<Int4> operator+(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<Int4> operator-(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<Int4> operator*(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<Int4> operator/(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createSDiv(lhs.value, rhs.value));
}
RValue<Int4> operator%(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createSRem(lhs.value, rhs.value));
}
RValue<Int4> operator&(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<Int4> operator|(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<Int4> operator^(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<Int4> operator<<(RValue<Int4> lhs, unsigned char rhs)
{
return x86::pslld(lhs, rhs);
}
RValue<Int4> operator>>(RValue<Int4> lhs, unsigned char rhs)
{
return x86::psrad(lhs, rhs);
}
RValue<Int4> operator<<(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<Int4> operator>>(RValue<Int4> lhs, RValue<Int4> rhs)
{
return RValue<Int4>(Nucleus::createAShr(lhs.value, rhs.value));
}
RValue<Int4> operator+=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs + rhs;
}
RValue<Int4> operator-=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs - rhs;
}
RValue<Int4> operator*=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs * rhs;
}
// RValue<Int4> operator/=(const Int4 &lhs, RValue<Int4> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<Int4> operator%=(const Int4 &lhs, RValue<Int4> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<Int4> operator&=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs & rhs;
}
RValue<Int4> operator|=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs | rhs;
}
RValue<Int4> operator^=(const Int4 &lhs, RValue<Int4> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<Int4> operator<<=(const Int4 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<Int4> operator>>=(const Int4 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<Int4> operator+(RValue<Int4> val)
{
return val;
}
RValue<Int4> operator-(RValue<Int4> val)
{
return RValue<Int4>(Nucleus::createNeg(val.value));
}
RValue<Int4> operator~(RValue<Int4> val)
{
return RValue<Int4>(Nucleus::createNot(val.value));
}
RValue<Int4> CmpEQ(RValue<Int4> x, RValue<Int4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpEQ(x.value, y.value), Int4::getType()));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpNE(x.value, y.value), Int4::getType())) ^ Int4(0xFFFFFFFF);
}
RValue<Int4> CmpLT(RValue<Int4> x, RValue<Int4> y)
{
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSLT(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpLE(RValue<Int4> x, RValue<Int4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSLE(x.value, y.value), Int4::getType()));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSGT(x.value, y.value), Int4::getType())) ^ Int4(0xFFFFFFFF);
}
RValue<Int4> CmpNEQ(RValue<Int4> x, RValue<Int4> y)
{
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpNE(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpNLT(RValue<Int4> x, RValue<Int4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSGE(x.value, y.value), Int4::getType()));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSLT(x.value, y.value), Int4::getType())) ^ Int4(0xFFFFFFFF);
}
RValue<Int4> CmpNLE(RValue<Int4> x, RValue<Int4> y)
{
return RValue<Int4>(Nucleus::createSExt(Nucleus::createICmpSGT(x.value, y.value), Int4::getType()));
}
RValue<Int4> Max(RValue<Int4> x, RValue<Int4> y)
{
if(CPUID::supportsSSE4_1())
{
return x86::pmaxsd(x, y);
}
else
{
RValue<Int4> greater = CmpNLE(x, y);
return x & greater | y & ~greater;
}
}
RValue<Int4> Min(RValue<Int4> x, RValue<Int4> y)
{
if(CPUID::supportsSSE4_1())
{
return x86::pminsd(x, y);
}
else
{
RValue<Int4> less = CmpLT(x, y);
return x & less | y & ~less;
}
}
RValue<Int4> RoundInt(RValue<Float4> cast)
{
return x86::cvtps2dq(cast);
}
RValue<Short8> Pack(RValue<Int4> x, RValue<Int4> y)
{
return x86::packssdw(x, y);
}
RValue<Int> Extract(RValue<Int4> x, int i)
{
return RValue<Int>(Nucleus::createExtractElement(x.value, Int::getType(), i));
}
RValue<Int4> Insert(RValue<Int4> x, RValue<Int> element, int i)
{
return RValue<Int4>(Nucleus::createInsertElement(x.value, element.value, i));
}
RValue<Int> SignMask(RValue<Int4> x)
{
return x86::movmskps(As<Float4>(x));
}
RValue<Int4> Swizzle(RValue<Int4> x, unsigned char select)
{
return RValue<Int4>(createSwizzle4(x.value, select));
}
Type *Int4::getType()
{
return T(VectorType::get(Int::getType(), 4));
}
UInt4::UInt4(RValue<Float4> cast)
{
// xyzw.parent = this;
// Note: createFPToUI is broken, must perform conversion using createFPtoSI
// Value *xyzw = Nucleus::createFPToUI(cast.value, UInt4::getType());
// Smallest positive value representable in UInt, but not in Int
const unsigned int ustart = 0x80000000u;
const float ustartf = float(ustart);
// Check if the value can be represented as an Int
Int4 uiValue = CmpNLT(cast, Float4(ustartf));
// If the value is too large, subtract ustart and re-add it after conversion.
uiValue = (uiValue & As<Int4>(As<UInt4>(Int4(cast - Float4(ustartf))) + UInt4(ustart))) |
// Otherwise, just convert normally
(~uiValue & Int4(cast));
// If the value is negative, store 0, otherwise store the result of the conversion
storeValue((~(As<Int4>(cast) >> 31) & uiValue).value);
}
UInt4::UInt4()
{
// xyzw.parent = this;
}
UInt4::UInt4(int xyzw)
{
constant(xyzw, xyzw, xyzw, xyzw);
}
UInt4::UInt4(int x, int yzw)
{
constant(x, yzw, yzw, yzw);
}
UInt4::UInt4(int x, int y, int zw)
{
constant(x, y, zw, zw);
}
UInt4::UInt4(int x, int y, int z, int w)
{
constant(x, y, z, w);
}
void UInt4::constant(int x, int y, int z, int w)
{
// xyzw.parent = this;
int64_t constantVector[4] = {x, y, z, w};
storeValue(Nucleus::createConstantVector(constantVector, getType()));
}
UInt4::UInt4(RValue<UInt4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
UInt4::UInt4(const UInt4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UInt4::UInt4(const Reference<UInt4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UInt4::UInt4(RValue<Int4> rhs)
{
// xyzw.parent = this;
storeValue(rhs.value);
}
UInt4::UInt4(const Int4 &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UInt4::UInt4(const Reference<Int4> &rhs)
{
// xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
UInt4::UInt4(RValue<UInt2> lo, RValue<UInt2> hi)
{
Value *loLong = Nucleus::createBitCast(lo.value, Long::getType());
Value *hiLong = Nucleus::createBitCast(hi.value, Long::getType());
Value *long2 = V(UndefValue::get(VectorType::get(Long::getType(), 2)));
long2 = Nucleus::createInsertElement(long2, loLong, 0);
long2 = Nucleus::createInsertElement(long2, hiLong, 1);
Value *uint4 = Nucleus::createBitCast(long2, Int4::getType());
storeValue(uint4);
}
RValue<UInt4> UInt4::operator=(RValue<UInt4> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<UInt4> UInt4::operator=(const UInt4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt4>(value);
}
RValue<UInt4> UInt4::operator=(const Reference<UInt4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<UInt4>(value);
}
RValue<UInt4> operator+(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createAdd(lhs.value, rhs.value));
}
RValue<UInt4> operator-(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createSub(lhs.value, rhs.value));
}
RValue<UInt4> operator*(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createMul(lhs.value, rhs.value));
}
RValue<UInt4> operator/(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createUDiv(lhs.value, rhs.value));
}
RValue<UInt4> operator%(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createURem(lhs.value, rhs.value));
}
RValue<UInt4> operator&(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createAnd(lhs.value, rhs.value));
}
RValue<UInt4> operator|(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createOr(lhs.value, rhs.value));
}
RValue<UInt4> operator^(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createXor(lhs.value, rhs.value));
}
RValue<UInt4> operator<<(RValue<UInt4> lhs, unsigned char rhs)
{
return As<UInt4>(x86::pslld(As<Int4>(lhs), rhs));
}
RValue<UInt4> operator>>(RValue<UInt4> lhs, unsigned char rhs)
{
return x86::psrld(lhs, rhs);
}
RValue<UInt4> operator<<(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createShl(lhs.value, rhs.value));
}
RValue<UInt4> operator>>(RValue<UInt4> lhs, RValue<UInt4> rhs)
{
return RValue<UInt4>(Nucleus::createLShr(lhs.value, rhs.value));
}
RValue<UInt4> operator+=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs + rhs;
}
RValue<UInt4> operator-=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs - rhs;
}
RValue<UInt4> operator*=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs * rhs;
}
// RValue<UInt4> operator/=(const UInt4 &lhs, RValue<UInt4> rhs)
// {
// return lhs = lhs / rhs;
// }
// RValue<UInt4> operator%=(const UInt4 &lhs, RValue<UInt4> rhs)
// {
// return lhs = lhs % rhs;
// }
RValue<UInt4> operator&=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs & rhs;
}
RValue<UInt4> operator|=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs | rhs;
}
RValue<UInt4> operator^=(const UInt4 &lhs, RValue<UInt4> rhs)
{
return lhs = lhs ^ rhs;
}
RValue<UInt4> operator<<=(const UInt4 &lhs, unsigned char rhs)
{
return lhs = lhs << rhs;
}
RValue<UInt4> operator>>=(const UInt4 &lhs, unsigned char rhs)
{
return lhs = lhs >> rhs;
}
RValue<UInt4> operator+(RValue<UInt4> val)
{
return val;
}
RValue<UInt4> operator-(RValue<UInt4> val)
{
return RValue<UInt4>(Nucleus::createNeg(val.value));
}
RValue<UInt4> operator~(RValue<UInt4> val)
{
return RValue<UInt4>(Nucleus::createNot(val.value));
}
RValue<UInt4> CmpEQ(RValue<UInt4> x, RValue<UInt4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpEQ(x.value, y.value), Int4::getType()));
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpNE(x.value, y.value), Int4::getType())) ^ UInt4(0xFFFFFFFF);
}
RValue<UInt4> CmpLT(RValue<UInt4> x, RValue<UInt4> y)
{
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpULT(x.value, y.value), Int4::getType()));
}
RValue<UInt4> CmpLE(RValue<UInt4> x, RValue<UInt4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpULE(x.value, y.value), Int4::getType()));
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpUGT(x.value, y.value), Int4::getType())) ^ UInt4(0xFFFFFFFF);
}
RValue<UInt4> CmpNEQ(RValue<UInt4> x, RValue<UInt4> y)
{
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpNE(x.value, y.value), Int4::getType()));
}
RValue<UInt4> CmpNLT(RValue<UInt4> x, RValue<UInt4> y)
{
// FIXME: An LLVM bug causes SExt(ICmpCC()) to produce 0 or 1 instead of 0 or ~0
// Restore the following line when LLVM is updated to a version where this issue is fixed.
// return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpUGE(x.value, y.value), Int4::getType()));
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpULT(x.value, y.value), Int4::getType())) ^ UInt4(0xFFFFFFFF);
}
RValue<UInt4> CmpNLE(RValue<UInt4> x, RValue<UInt4> y)
{
return RValue<UInt4>(Nucleus::createSExt(Nucleus::createICmpUGT(x.value, y.value), Int4::getType()));
}
RValue<UInt4> Max(RValue<UInt4> x, RValue<UInt4> y)
{
if(CPUID::supportsSSE4_1())
{
return x86::pmaxud(x, y);
}
else
{
RValue<UInt4> greater = CmpNLE(x, y);
return x & greater | y & ~greater;
}
}
RValue<UInt4> Min(RValue<UInt4> x, RValue<UInt4> y)
{
if(CPUID::supportsSSE4_1())
{
return x86::pminud(x, y);
}
else
{
RValue<UInt4> less = CmpLT(x, y);
return x & less | y & ~less;
}
}
RValue<UShort8> Pack(RValue<UInt4> x, RValue<UInt4> y)
{
return x86::packusdw(x, y); // FIXME: Fallback required
}
Type *UInt4::getType()
{
return T(VectorType::get(UInt::getType(), 4));
}
Float::Float(RValue<Int> cast)
{
Value *integer = Nucleus::createSIToFP(cast.value, Float::getType());
storeValue(integer);
}
Float::Float()
{
}
Float::Float(float x)
{
storeValue(Nucleus::createConstantFloat(x));
}
Float::Float(RValue<Float> rhs)
{
storeValue(rhs.value);
}
Float::Float(const Float &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
Float::Float(const Reference<Float> &rhs)
{
Value *value = rhs.loadValue();
storeValue(value);
}
RValue<Float> Float::operator=(RValue<Float> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Float> Float::operator=(const Float &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Float>(value);
}
RValue<Float> Float::operator=(const Reference<Float> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Float>(value);
}
RValue<Float> operator+(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Float>(Nucleus::createFAdd(lhs.value, rhs.value));
}
RValue<Float> operator-(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Float>(Nucleus::createFSub(lhs.value, rhs.value));
}
RValue<Float> operator*(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Float>(Nucleus::createFMul(lhs.value, rhs.value));
}
RValue<Float> operator/(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Float>(Nucleus::createFDiv(lhs.value, rhs.value));
}
RValue<Float> operator+=(const Float &lhs, RValue<Float> rhs)
{
return lhs = lhs + rhs;
}
RValue<Float> operator-=(const Float &lhs, RValue<Float> rhs)
{
return lhs = lhs - rhs;
}
RValue<Float> operator*=(const Float &lhs, RValue<Float> rhs)
{
return lhs = lhs * rhs;
}
RValue<Float> operator/=(const Float &lhs, RValue<Float> rhs)
{
return lhs = lhs / rhs;
}
RValue<Float> operator+(RValue<Float> val)
{
return val;
}
RValue<Float> operator-(RValue<Float> val)
{
return RValue<Float>(Nucleus::createFNeg(val.value));
}
RValue<Bool> operator<(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpOLT(lhs.value, rhs.value));
}
RValue<Bool> operator<=(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpOLE(lhs.value, rhs.value));
}
RValue<Bool> operator>(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpOGT(lhs.value, rhs.value));
}
RValue<Bool> operator>=(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpOGE(lhs.value, rhs.value));
}
RValue<Bool> operator!=(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpONE(lhs.value, rhs.value));
}
RValue<Bool> operator==(RValue<Float> lhs, RValue<Float> rhs)
{
return RValue<Bool>(Nucleus::createFCmpOEQ(lhs.value, rhs.value));
}
RValue<Float> Abs(RValue<Float> x)
{
return IfThenElse(x > 0.0f, x, -x);
}
RValue<Float> Max(RValue<Float> x, RValue<Float> y)
{
return IfThenElse(x > y, x, y);
}
RValue<Float> Min(RValue<Float> x, RValue<Float> y)
{
return IfThenElse(x < y, x, y);
}
RValue<Float> Rcp_pp(RValue<Float> x, bool exactAtPow2)
{
if(exactAtPow2)
{
// rcpss uses a piecewise-linear approximation which minimizes the relative error
// but is not exact at power-of-two values. Rectify by multiplying by the inverse.
return x86::rcpss(x) * Float(1.0f / _mm_cvtss_f32(_mm_rcp_ss(_mm_set_ps1(1.0f))));
}
else
{
return x86::rcpss(x);
}
}
RValue<Float> RcpSqrt_pp(RValue<Float> x)
{
return x86::rsqrtss(x);
}
RValue<Float> Sqrt(RValue<Float> x)
{
return x86::sqrtss(x);
}
RValue<Float> Round(RValue<Float> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::roundss(x, 0);
}
else
{
return Float4(Round(Float4(x))).x;
}
}
RValue<Float> Trunc(RValue<Float> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::roundss(x, 3);
}
else
{
return Float(Int(x)); // Rounded toward zero
}
}
RValue<Float> Frac(RValue<Float> x)
{
if(CPUID::supportsSSE4_1())
{
return x - x86::floorss(x);
}
else
{
return Float4(Frac(Float4(x))).x;
}
}
RValue<Float> Floor(RValue<Float> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::floorss(x);
}
else
{
return Float4(Floor(Float4(x))).x;
}
}
RValue<Float> Ceil(RValue<Float> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::ceilss(x);
}
else
{
return Float4(Ceil(Float4(x))).x;
}
}
Type *Float::getType()
{
return T(llvm::Type::getFloatTy(*::context));
}
Float2::Float2(RValue<Float4> cast)
{
// xyzw.parent = this;
Value *int64x2 = Nucleus::createBitCast(cast.value, T(VectorType::get(Long::getType(), 2)));
Value *int64 = Nucleus::createExtractElement(int64x2, Long::getType(), 0);
Value *float2 = Nucleus::createBitCast(int64, Float2::getType());
storeValue(float2);
}
Type *Float2::getType()
{
return T(VectorType::get(Float::getType(), 2));
}
Float4::Float4(RValue<Byte4> cast)
{
xyzw.parent = this;
#if 0
Value *xyzw = Nucleus::createUIToFP(cast.value, Float4::getType()); // FIXME: Crashes
#elif 0
Value *vector = loadValue();
Value *i8x = Nucleus::createExtractElement(cast.value, 0);
Value *f32x = Nucleus::createUIToFP(i8x, Float::getType());
Value *x = Nucleus::createInsertElement(vector, f32x, 0);
Value *i8y = Nucleus::createExtractElement(cast.value, V(Nucleus::createConstantInt(1)));
Value *f32y = Nucleus::createUIToFP(i8y, Float::getType());
Value *xy = Nucleus::createInsertElement(x, f32y, V(Nucleus::createConstantInt(1)));
Value *i8z = Nucleus::createExtractElement(cast.value, Nucleus::createConstantInt(2));
Value *f32z = Nucleus::createUIToFP(i8z, Float::getType());
Value *xyz = Nucleus::createInsertElement(xy, f32z, Nucleus::createConstantInt(2));
Value *i8w = Nucleus::createExtractElement(cast.value, Nucleus::createConstantInt(3));
Value *f32w = Nucleus::createUIToFP(i8w, Float::getType());
Value *xyzw = Nucleus::createInsertElement(xyz, f32w, Nucleus::createConstantInt(3));
#else
Value *a = Int4(cast).loadValue();
Value *xyzw = Nucleus::createSIToFP(a, Float4::getType());
#endif
storeValue(xyzw);
}
Float4::Float4(RValue<SByte4> cast)
{
xyzw.parent = this;
#if 0
Value *xyzw = Nucleus::createSIToFP(cast.value, Float4::getType()); // FIXME: Crashes
#elif 0
Value *vector = loadValue();
Value *i8x = Nucleus::createExtractElement(cast.value, 0);
Value *f32x = Nucleus::createSIToFP(i8x, Float::getType());
Value *x = Nucleus::createInsertElement(vector, f32x, 0);
Value *i8y = Nucleus::createExtractElement(cast.value, V(Nucleus::createConstantInt(1)));
Value *f32y = Nucleus::createSIToFP(i8y, Float::getType());
Value *xy = Nucleus::createInsertElement(x, f32y, V(Nucleus::createConstantInt(1)));
Value *i8z = Nucleus::createExtractElement(cast.value, Nucleus::createConstantInt(2));
Value *f32z = Nucleus::createSIToFP(i8z, Float::getType());
Value *xyz = Nucleus::createInsertElement(xy, f32z, Nucleus::createConstantInt(2));
Value *i8w = Nucleus::createExtractElement(cast.value, Nucleus::createConstantInt(3));
Value *f32w = Nucleus::createSIToFP(i8w, Float::getType());
Value *xyzw = Nucleus::createInsertElement(xyz, f32w, Nucleus::createConstantInt(3));
#else
Value *a = Int4(cast).loadValue();
Value *xyzw = Nucleus::createSIToFP(a, Float4::getType());
#endif
storeValue(xyzw);
}
Float4::Float4(RValue<Short4> cast)
{
xyzw.parent = this;
Int4 c(cast);
storeValue(Nucleus::createSIToFP(RValue<Int4>(c).value, Float4::getType()));
}
Float4::Float4(RValue<UShort4> cast)
{
xyzw.parent = this;
Int4 c(cast);
storeValue(Nucleus::createSIToFP(RValue<Int4>(c).value, Float4::getType()));
}
Float4::Float4(RValue<Int4> cast)
{
xyzw.parent = this;
Value *xyzw = Nucleus::createSIToFP(cast.value, Float4::getType());
storeValue(xyzw);
}
Float4::Float4(RValue<UInt4> cast)
{
xyzw.parent = this;
Value *xyzw = Nucleus::createUIToFP(cast.value, Float4::getType());
storeValue(xyzw);
}
Float4::Float4()
{
xyzw.parent = this;
}
Float4::Float4(float xyzw)
{
constant(xyzw, xyzw, xyzw, xyzw);
}
Float4::Float4(float x, float yzw)
{
constant(x, yzw, yzw, yzw);
}
Float4::Float4(float x, float y, float zw)
{
constant(x, y, zw, zw);
}
Float4::Float4(float x, float y, float z, float w)
{
constant(x, y, z, w);
}
void Float4::constant(float x, float y, float z, float w)
{
xyzw.parent = this;
double constantVector[4] = {x, y, z, w};
storeValue(Nucleus::createConstantVector(constantVector, getType()));
}
Float4::Float4(RValue<Float4> rhs)
{
xyzw.parent = this;
storeValue(rhs.value);
}
Float4::Float4(const Float4 &rhs)
{
xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Float4::Float4(const Reference<Float4> &rhs)
{
xyzw.parent = this;
Value *value = rhs.loadValue();
storeValue(value);
}
Float4::Float4(RValue<Float> rhs)
{
xyzw.parent = this;
Value *vector = loadValue();
Value *insert = Nucleus::createInsertElement(vector, rhs.value, 0);
int swizzle[4] = {0, 0, 0, 0};
Value *replicate = Nucleus::createShuffleVector(insert, insert, swizzle);
storeValue(replicate);
}
Float4::Float4(const Float &rhs)
{
xyzw.parent = this;
*this = RValue<Float>(rhs.loadValue());
}
Float4::Float4(const Reference<Float> &rhs)
{
xyzw.parent = this;
*this = RValue<Float>(rhs.loadValue());
}
RValue<Float4> Float4::operator=(float x) const
{
return *this = Float4(x, x, x, x);
}
RValue<Float4> Float4::operator=(RValue<Float4> rhs) const
{
storeValue(rhs.value);
return rhs;
}
RValue<Float4> Float4::operator=(const Float4 &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Float4>(value);
}
RValue<Float4> Float4::operator=(const Reference<Float4> &rhs) const
{
Value *value = rhs.loadValue();
storeValue(value);
return RValue<Float4>(value);
}
RValue<Float4> Float4::operator=(RValue<Float> rhs) const
{
return *this = Float4(rhs);
}
RValue<Float4> Float4::operator=(const Float &rhs) const
{
return *this = Float4(rhs);
}
RValue<Float4> Float4::operator=(const Reference<Float> &rhs) const
{
return *this = Float4(rhs);
}
RValue<Float4> operator+(RValue<Float4> lhs, RValue<Float4> rhs)
{
return RValue<Float4>(Nucleus::createFAdd(lhs.value, rhs.value));
}
RValue<Float4> operator-(RValue<Float4> lhs, RValue<Float4> rhs)
{
return RValue<Float4>(Nucleus::createFSub(lhs.value, rhs.value));
}
RValue<Float4> operator*(RValue<Float4> lhs, RValue<Float4> rhs)
{
return RValue<Float4>(Nucleus::createFMul(lhs.value, rhs.value));
}
RValue<Float4> operator/(RValue<Float4> lhs, RValue<Float4> rhs)
{
return RValue<Float4>(Nucleus::createFDiv(lhs.value, rhs.value));
}
RValue<Float4> operator%(RValue<Float4> lhs, RValue<Float4> rhs)
{
return RValue<Float4>(Nucleus::createFRem(lhs.value, rhs.value));
}
RValue<Float4> operator+=(const Float4 &lhs, RValue<Float4> rhs)
{
return lhs = lhs + rhs;
}
RValue<Float4> operator-=(const Float4 &lhs, RValue<Float4> rhs)
{
return lhs = lhs - rhs;
}
RValue<Float4> operator*=(const Float4 &lhs, RValue<Float4> rhs)
{
return lhs = lhs * rhs;
}
RValue<Float4> operator/=(const Float4 &lhs, RValue<Float4> rhs)
{
return lhs = lhs / rhs;
}
RValue<Float4> operator%=(const Float4 &lhs, RValue<Float4> rhs)
{
return lhs = lhs % rhs;
}
RValue<Float4> operator+(RValue<Float4> val)
{
return val;
}
RValue<Float4> operator-(RValue<Float4> val)
{
return RValue<Float4>(Nucleus::createFNeg(val.value));
}
RValue<Float4> Abs(RValue<Float4> x)
{
Value *vector = Nucleus::createBitCast(x.value, Int4::getType());
int64_t constantVector[4] = {0x7FFFFFFF, 0x7FFFFFFF, 0x7FFFFFFF, 0x7FFFFFFF};
Value *result = Nucleus::createAnd(vector, V(Nucleus::createConstantVector(constantVector, Int4::getType())));
return RValue<Float4>(Nucleus::createBitCast(result, Float4::getType()));
}
RValue<Float4> Max(RValue<Float4> x, RValue<Float4> y)
{
return x86::maxps(x, y);
}
RValue<Float4> Min(RValue<Float4> x, RValue<Float4> y)
{
return x86::minps(x, y);
}
RValue<Float4> Rcp_pp(RValue<Float4> x, bool exactAtPow2)
{
if(exactAtPow2)
{
// rcpps uses a piecewise-linear approximation which minimizes the relative error
// but is not exact at power-of-two values. Rectify by multiplying by the inverse.
return x86::rcpps(x) * Float4(1.0f / _mm_cvtss_f32(_mm_rcp_ss(_mm_set_ps1(1.0f))));
}
else
{
return x86::rcpps(x);
}
}
RValue<Float4> RcpSqrt_pp(RValue<Float4> x)
{
return x86::rsqrtps(x);
}
RValue<Float4> Sqrt(RValue<Float4> x)
{
return x86::sqrtps(x);
}
RValue<Float4> Insert(const Float4 &val, RValue<Float> element, int i)
{
Value *value = val.loadValue();
Value *insert = Nucleus::createInsertElement(value, element.value, i);
val = RValue<Float4>(insert);
return val;
}
RValue<Float> Extract(RValue<Float4> x, int i)
{
return RValue<Float>(Nucleus::createExtractElement(x.value, Float::getType(), i));
}
RValue<Float4> Swizzle(RValue<Float4> x, unsigned char select)
{
return RValue<Float4>(createSwizzle4(x.value, select));
}
RValue<Float4> ShuffleLowHigh(RValue<Float4> x, RValue<Float4> y, unsigned char imm)
{
int shuffle[4] =
{
((imm >> 0) & 0x03) + 0,
((imm >> 2) & 0x03) + 0,
((imm >> 4) & 0x03) + 4,
((imm >> 6) & 0x03) + 4,
};
return RValue<Float4>(Nucleus::createShuffleVector(x.value, y.value, shuffle));
}
RValue<Float4> UnpackLow(RValue<Float4> x, RValue<Float4> y)
{
int shuffle[4] = {0, 4, 1, 5};
return RValue<Float4>(Nucleus::createShuffleVector(x.value, y.value, shuffle));
}
RValue<Float4> UnpackHigh(RValue<Float4> x, RValue<Float4> y)
{
int shuffle[4] = {2, 6, 3, 7};
return RValue<Float4>(Nucleus::createShuffleVector(x.value, y.value, shuffle));
}
RValue<Float4> Mask(Float4 &lhs, RValue<Float4> rhs, unsigned char select)
{
Value *vector = lhs.loadValue();
Value *shuffle = createMask4(vector, rhs.value, select);
lhs.storeValue(shuffle);
return RValue<Float4>(shuffle);
}
RValue<Int> SignMask(RValue<Float4> x)
{
return x86::movmskps(x);
}
RValue<Int4> CmpEQ(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpeqps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpOEQ(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpLT(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpltps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpOLT(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpLE(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpleps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpOLE(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpNEQ(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpneqps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpONE(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpNLT(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpnltps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpOGE(x.value, y.value), Int4::getType()));
}
RValue<Int4> CmpNLE(RValue<Float4> x, RValue<Float4> y)
{
// return As<Int4>(x86::cmpnleps(x, y));
return RValue<Int4>(Nucleus::createSExt(Nucleus::createFCmpOGT(x.value, y.value), Int4::getType()));
}
RValue<Float4> Round(RValue<Float4> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::roundps(x, 0);
}
else
{
return Float4(RoundInt(x));
}
}
RValue<Float4> Trunc(RValue<Float4> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::roundps(x, 3);
}
else
{
return Float4(Int4(x)); // Rounded toward zero
}
}
RValue<Float4> Frac(RValue<Float4> x)
{
if(CPUID::supportsSSE4_1())
{
return x - x86::floorps(x);
}
else
{
Float4 frc = x - Float4(Int4(x)); // Signed fractional part
return frc + As<Float4>(As<Int4>(CmpNLE(Float4(0.0f), frc)) & As<Int4>(Float4(1, 1, 1, 1)));
}
}
RValue<Float4> Floor(RValue<Float4> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::floorps(x);
}
else
{
return x - Frac(x);
}
}
RValue<Float4> Ceil(RValue<Float4> x)
{
if(CPUID::supportsSSE4_1())
{
return x86::ceilps(x);
}
else
{
return -Floor(-x);
}
}
Type *Float4::getType()
{
return T(VectorType::get(Float::getType(), 4));
}
RValue<Pointer<Byte>> operator+(RValue<Pointer<Byte>> lhs, int offset)
{
return RValue<Pointer<Byte>>(Nucleus::createGEP(lhs.value, Byte::getType(), V(Nucleus::createConstantInt(offset))));
}
RValue<Pointer<Byte>> operator+(RValue<Pointer<Byte>> lhs, RValue<Int> offset)
{
return RValue<Pointer<Byte>>(Nucleus::createGEP(lhs.value, Byte::getType(), offset.value));
}
RValue<Pointer<Byte>> operator+(RValue<Pointer<Byte>> lhs, RValue<UInt> offset)
{
return RValue<Pointer<Byte>>(Nucleus::createGEP(lhs.value, Byte::getType(), offset.value));
}
RValue<Pointer<Byte>> operator+=(const Pointer<Byte> &lhs, int offset)
{
return lhs = lhs + offset;
}
RValue<Pointer<Byte>> operator+=(const Pointer<Byte> &lhs, RValue<Int> offset)
{
return lhs = lhs + offset;
}
RValue<Pointer<Byte>> operator+=(const Pointer<Byte> &lhs, RValue<UInt> offset)
{
return lhs = lhs + offset;
}
RValue<Pointer<Byte>> operator-(RValue<Pointer<Byte>> lhs, int offset)
{
return lhs + -offset;
}
RValue<Pointer<Byte>> operator-(RValue<Pointer<Byte>> lhs, RValue<Int> offset)
{
return lhs + -offset;
}
RValue<Pointer<Byte>> operator-(RValue<Pointer<Byte>> lhs, RValue<UInt> offset)
{
return lhs + -offset;
}
RValue<Pointer<Byte>> operator-=(const Pointer<Byte> &lhs, int offset)
{
return lhs = lhs - offset;
}
RValue<Pointer<Byte>> operator-=(const Pointer<Byte> &lhs, RValue<Int> offset)
{
return lhs = lhs - offset;
}
RValue<Pointer<Byte>> operator-=(const Pointer<Byte> &lhs, RValue<UInt> offset)
{
return lhs = lhs - offset;
}
void Return()
{
Nucleus::createRetVoid();
Nucleus::setInsertBlock(Nucleus::createBasicBlock());
Nucleus::createUnreachable();
}
void Return(bool ret)
{
Nucleus::createRet(V(Nucleus::createConstantBool(ret)));
Nucleus::setInsertBlock(Nucleus::createBasicBlock());
Nucleus::createUnreachable();
}
void Return(const Int &ret)
{
Nucleus::createRet(ret.loadValue());
Nucleus::setInsertBlock(Nucleus::createBasicBlock());
Nucleus::createUnreachable();
}
bool branch(RValue<Bool> cmp, BasicBlock *bodyBB, BasicBlock *endBB)
{
Nucleus::createCondBr(cmp.value, bodyBB, endBB);
Nucleus::setInsertBlock(bodyBB);
return true;
}
void endIf(BasicBlock *falseBB)
{
::falseBB = falseBB;
}
bool elseBlock(BasicBlock *falseBB)
{
assert(falseBB && "Else not preceded by If");
falseBB->back().eraseFromParent();
Nucleus::setInsertBlock(falseBB);
return true;
}
BasicBlock *beginElse()
{
BasicBlock *falseBB = ::falseBB;
::falseBB = nullptr;
return falseBB;
}
RValue<Long> Ticks()
{
llvm::Function *rdtsc = Intrinsic::getDeclaration(::module, Intrinsic::readcyclecounter);
return RValue<Long>(V(::builder->CreateCall(rdtsc)));
}
}
namespace sw
{
namespace x86
{
RValue<Int> cvtss2si(RValue<Float> val)
{
llvm::Function *cvtss2si = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_cvtss2si);
Float4 vector;
vector.x = val;
return RValue<Int>(V(::builder->CreateCall(cvtss2si, RValue<Float4>(vector).value)));
}
RValue<Int2> cvtps2pi(RValue<Float4> val)
{
llvm::Function *cvtps2pi = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_cvtps2pi);
return RValue<Int2>(V(::builder->CreateCall(cvtps2pi, val.value)));
}
RValue<Int2> cvttps2pi(RValue<Float4> val)
{
llvm::Function *cvttps2pi = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_cvttps2pi);
return RValue<Int2>(V(::builder->CreateCall(cvttps2pi, val.value)));
}
RValue<Int4> cvtps2dq(RValue<Float4> val)
{
if(CPUID::supportsSSE2())
{
llvm::Function *cvtps2dq = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_cvtps2dq);
return RValue<Int4>(V(::builder->CreateCall(cvtps2dq, val.value)));
}
else
{
Int2 lo = x86::cvtps2pi(val);
Int2 hi = x86::cvtps2pi(Swizzle(val, 0xEE));
return Int4(lo, hi);
}
}
RValue<Float> rcpss(RValue<Float> val)
{
llvm::Function *rcpss = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_rcp_ss);
Value *vector = Nucleus::createInsertElement(V(UndefValue::get(Float4::getType())), val.value, 0);
return RValue<Float>(Nucleus::createExtractElement(V(::builder->CreateCall(rcpss, vector)), Float::getType(), 0));
}
RValue<Float> sqrtss(RValue<Float> val)
{
llvm::Function *sqrtss = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_sqrt_ss);
Value *vector = Nucleus::createInsertElement(V(UndefValue::get(Float4::getType())), val.value, 0);
return RValue<Float>(Nucleus::createExtractElement(V(::builder->CreateCall(sqrtss, vector)), Float::getType(), 0));
}
RValue<Float> rsqrtss(RValue<Float> val)
{
llvm::Function *rsqrtss = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_rsqrt_ss);
Value *vector = Nucleus::createInsertElement(V(UndefValue::get(Float4::getType())), val.value, 0);
return RValue<Float>(Nucleus::createExtractElement(V(::builder->CreateCall(rsqrtss, vector)), Float::getType(), 0));
}
RValue<Float4> rcpps(RValue<Float4> val)
{
llvm::Function *rcpps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_rcp_ps);
return RValue<Float4>(V(::builder->CreateCall(rcpps, val.value)));
}
RValue<Float4> sqrtps(RValue<Float4> val)
{
llvm::Function *sqrtps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_sqrt_ps);
return RValue<Float4>(V(::builder->CreateCall(sqrtps, val.value)));
}
RValue<Float4> rsqrtps(RValue<Float4> val)
{
llvm::Function *rsqrtps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_rsqrt_ps);
return RValue<Float4>(V(::builder->CreateCall(rsqrtps, val.value)));
}
RValue<Float4> maxps(RValue<Float4> x, RValue<Float4> y)
{
llvm::Function *maxps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_max_ps);
return RValue<Float4>(V(::builder->CreateCall2(maxps, x.value, y.value)));
}
RValue<Float4> minps(RValue<Float4> x, RValue<Float4> y)
{
llvm::Function *minps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_min_ps);
return RValue<Float4>(V(::builder->CreateCall2(minps, x.value, y.value)));
}
RValue<Float> roundss(RValue<Float> val, unsigned char imm)
{
llvm::Function *roundss = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_round_ss);
Value *undef = V(UndefValue::get(Float4::getType()));
Value *vector = Nucleus::createInsertElement(undef, val.value, 0);
return RValue<Float>(Nucleus::createExtractElement(V(::builder->CreateCall3(roundss, undef, vector, V(Nucleus::createConstantInt(imm)))), Float::getType(), 0));
}
RValue<Float> floorss(RValue<Float> val)
{
return roundss(val, 1);
}
RValue<Float> ceilss(RValue<Float> val)
{
return roundss(val, 2);
}
RValue<Float4> roundps(RValue<Float4> val, unsigned char imm)
{
llvm::Function *roundps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_round_ps);
return RValue<Float4>(V(::builder->CreateCall2(roundps, val.value, V(Nucleus::createConstantInt(imm)))));
}
RValue<Float4> floorps(RValue<Float4> val)
{
return roundps(val, 1);
}
RValue<Float4> ceilps(RValue<Float4> val)
{
return roundps(val, 2);
}
RValue<Float4> cmpps(RValue<Float4> x, RValue<Float4> y, unsigned char imm)
{
llvm::Function *cmpps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_cmp_ps);
return RValue<Float4>(V(::builder->CreateCall3(cmpps, x.value, y.value, V(Nucleus::createConstantByte(imm)))));
}
RValue<Float4> cmpeqps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 0);
}
RValue<Float4> cmpltps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 1);
}
RValue<Float4> cmpleps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 2);
}
RValue<Float4> cmpunordps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 3);
}
RValue<Float4> cmpneqps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 4);
}
RValue<Float4> cmpnltps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 5);
}
RValue<Float4> cmpnleps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 6);
}
RValue<Float4> cmpordps(RValue<Float4> x, RValue<Float4> y)
{
return cmpps(x, y, 7);
}
RValue<Float> cmpss(RValue<Float> x, RValue<Float> y, unsigned char imm)
{
llvm::Function *cmpss = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_cmp_ss);
Value *vector1 = Nucleus::createInsertElement(V(UndefValue::get(Float4::getType())), x.value, 0);
Value *vector2 = Nucleus::createInsertElement(V(UndefValue::get(Float4::getType())), y.value, 0);
return RValue<Float>(Nucleus::createExtractElement(V(::builder->CreateCall3(cmpss, vector1, vector2, V(Nucleus::createConstantByte(imm)))), Float::getType(), 0));
}
RValue<Float> cmpeqss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 0);
}
RValue<Float> cmpltss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 1);
}
RValue<Float> cmpless(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 2);
}
RValue<Float> cmpunordss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 3);
}
RValue<Float> cmpneqss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 4);
}
RValue<Float> cmpnltss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 5);
}
RValue<Float> cmpnless(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 6);
}
RValue<Float> cmpordss(RValue<Float> x, RValue<Float> y)
{
return cmpss(x, y, 7);
}
RValue<Int4> pabsd(RValue<Int4> x)
{
llvm::Function *pabsd = Intrinsic::getDeclaration(::module, Intrinsic::x86_ssse3_pabs_d_128);
return RValue<Int4>(V(::builder->CreateCall(pabsd, x.value)));
}
RValue<Short4> paddsw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *paddsw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_padds_w);
return As<Short4>(V(::builder->CreateCall2(paddsw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> psubsw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *psubsw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psubs_w);
return As<Short4>(V(::builder->CreateCall2(psubsw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UShort4> paddusw(RValue<UShort4> x, RValue<UShort4> y)
{
llvm::Function *paddusw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_paddus_w);
return As<UShort4>(V(::builder->CreateCall2(paddusw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UShort4> psubusw(RValue<UShort4> x, RValue<UShort4> y)
{
llvm::Function *psubusw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psubus_w);
return As<UShort4>(V(::builder->CreateCall2(psubusw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<SByte8> paddsb(RValue<SByte8> x, RValue<SByte8> y)
{
llvm::Function *paddsb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_padds_b);
return As<SByte8>(V(::builder->CreateCall2(paddsb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<SByte8> psubsb(RValue<SByte8> x, RValue<SByte8> y)
{
llvm::Function *psubsb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psubs_b);
return As<SByte8>(V(::builder->CreateCall2(psubsb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> paddusb(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *paddusb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_paddus_b);
return As<Byte8>(V(::builder->CreateCall2(paddusb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> psubusb(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *psubusb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psubus_b);
return As<Byte8>(V(::builder->CreateCall2(psubusb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> paddw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *paddw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_padd_w);
return As<Short4>(V(::builder->CreateCall2(paddw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> psubw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *psubw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psub_w);
return As<Short4>(V(::builder->CreateCall2(psubw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pmullw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pmullw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmull_w);
return As<Short4>(V(::builder->CreateCall2(pmullw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pand(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pand = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pand);
return As<Short4>(V(::builder->CreateCall2(pand, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> por(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *por = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_por);
return As<Short4>(V(::builder->CreateCall2(por, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pxor(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pxor = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pxor);
return As<Short4>(V(::builder->CreateCall2(pxor, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pshufw(RValue<Short4> x, unsigned char y)
{
llvm::Function *pshufw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_pshuf_w);
return As<Short4>(V(::builder->CreateCall2(pshufw, As<MMX>(x).value, V(Nucleus::createConstantByte(y)))));
}
RValue<Int2> punpcklwd(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *punpcklwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpcklwd);
return As<Int2>(V(::builder->CreateCall2(punpcklwd, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> punpckhwd(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *punpckhwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpckhwd);
return As<Int2>(V(::builder->CreateCall2(punpckhwd, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pinsrw(RValue<Short4> x, RValue<Int> y, unsigned int i)
{
llvm::Function *pinsrw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pinsr_w);
return As<Short4>(V(::builder->CreateCall3(pinsrw, As<MMX>(x).value, y.value, V(Nucleus::createConstantInt(i)))));
}
RValue<Int> pextrw(RValue<Short4> x, unsigned int i)
{
llvm::Function *pextrw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pextr_w);
return RValue<Int>(V(::builder->CreateCall2(pextrw, As<MMX>(x).value, V(Nucleus::createConstantInt(i)))));
}
RValue<Long1> punpckldq(RValue<Int2> x, RValue<Int2> y)
{
llvm::Function *punpckldq = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpckldq);
return As<Long1>(V(::builder->CreateCall2(punpckldq, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Long1> punpckhdq(RValue<Int2> x, RValue<Int2> y)
{
llvm::Function *punpckhdq = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpckhdq);
return As<Long1>(V(::builder->CreateCall2(punpckhdq, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> punpcklbw(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *punpcklbw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpcklbw);
return As<Short4>(V(::builder->CreateCall2(punpcklbw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> punpckhbw(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *punpckhbw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_punpckhbw);
return As<Short4>(V(::builder->CreateCall2(punpckhbw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> paddb(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *paddb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_padd_b);
return As<Byte8>(V(::builder->CreateCall2(paddb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> psubb(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *psubb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psub_b);
return As<Byte8>(V(::builder->CreateCall2(psubb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> paddd(RValue<Int2> x, RValue<Int2> y)
{
llvm::Function *paddd = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_padd_d);
return As<Int2>(V(::builder->CreateCall2(paddd, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> psubd(RValue<Int2> x, RValue<Int2> y)
{
llvm::Function *psubd = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psub_d);
return As<Int2>(V(::builder->CreateCall2(psubd, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UShort4> pavgw(RValue<UShort4> x, RValue<UShort4> y)
{
llvm::Function *pavgw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pavg_w);
return As<UShort4>(V(::builder->CreateCall2(pavgw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pmaxsw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pmaxsw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmaxs_w);
return As<Short4>(V(::builder->CreateCall2(pmaxsw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pminsw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pminsw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmins_w);
return As<Short4>(V(::builder->CreateCall2(pminsw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pcmpgtw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pcmpgtw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pcmpgt_w);
return As<Short4>(V(::builder->CreateCall2(pcmpgtw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> pcmpeqw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pcmpeqw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pcmpeq_w);
return As<Short4>(V(::builder->CreateCall2(pcmpeqw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> pcmpgtb(RValue<SByte8> x, RValue<SByte8> y)
{
llvm::Function *pcmpgtb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pcmpgt_b);
return As<Byte8>(V(::builder->CreateCall2(pcmpgtb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> pcmpeqb(RValue<Byte8> x, RValue<Byte8> y)
{
llvm::Function *pcmpeqb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pcmpeq_b);
return As<Byte8>(V(::builder->CreateCall2(pcmpeqb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> packssdw(RValue<Int2> x, RValue<Int2> y)
{
llvm::Function *packssdw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_packssdw);
return As<Short4>(V(::builder->CreateCall2(packssdw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short8> packssdw(RValue<Int4> x, RValue<Int4> y)
{
if(CPUID::supportsSSE2())
{
llvm::Function *packssdw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_packssdw_128);
return RValue<Short8>(V(::builder->CreateCall2(packssdw, x.value, y.value)));
}
else
{
Int2 loX = Int2(x);
Int2 hiX = Int2(Swizzle(x, 0xEE));
Int2 loY = Int2(y);
Int2 hiY = Int2(Swizzle(y, 0xEE));
Short4 lo = x86::packssdw(loX, hiX);
Short4 hi = x86::packssdw(loY, hiY);
return Short8(lo, hi);
}
}
RValue<SByte8> packsswb(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *packsswb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_packsswb);
return As<SByte8>(V(::builder->CreateCall2(packsswb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Byte8> packuswb(RValue<UShort4> x, RValue<UShort4> y)
{
llvm::Function *packuswb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_packuswb);
return As<Byte8>(V(::builder->CreateCall2(packuswb, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UShort8> packusdw(RValue<UInt4> x, RValue<UInt4> y)
{
if(CPUID::supportsSSE4_1())
{
llvm::Function *packusdw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_packusdw);
return RValue<UShort8>(V(::builder->CreateCall2(packusdw, x.value, y.value)));
}
else
{
// FIXME: Not an exact replacement!
return As<UShort8>(packssdw(As<Int4>(x - UInt4(0x00008000, 0x00008000, 0x00008000, 0x00008000)), As<Int4>(y - UInt4(0x00008000, 0x00008000, 0x00008000, 0x00008000))) + Short8(0x8000u, 0x8000u, 0x8000u, 0x8000u, 0x8000u, 0x8000u, 0x8000u, 0x8000u));
}
}
RValue<UShort4> psrlw(RValue<UShort4> x, unsigned char y)
{
llvm::Function *psrlw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrli_w);
return As<UShort4>(V(::builder->CreateCall2(psrlw, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<UShort8> psrlw(RValue<UShort8> x, unsigned char y)
{
llvm::Function *psrlw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_psrli_w);
return RValue<UShort8>(V(::builder->CreateCall2(psrlw, x.value, V(Nucleus::createConstantInt(y)))));
}
RValue<Short4> psraw(RValue<Short4> x, unsigned char y)
{
llvm::Function *psraw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrai_w);
return As<Short4>(V(::builder->CreateCall2(psraw, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<Short8> psraw(RValue<Short8> x, unsigned char y)
{
llvm::Function *psraw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_psrai_w);
return RValue<Short8>(V(::builder->CreateCall2(psraw, x.value, V(Nucleus::createConstantInt(y)))));
}
RValue<Short4> psllw(RValue<Short4> x, unsigned char y)
{
llvm::Function *psllw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pslli_w);
return As<Short4>(V(::builder->CreateCall2(psllw, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<Short8> psllw(RValue<Short8> x, unsigned char y)
{
llvm::Function *psllw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_pslli_w);
return RValue<Short8>(V(::builder->CreateCall2(psllw, x.value, V(Nucleus::createConstantInt(y)))));
}
RValue<Int2> pslld(RValue<Int2> x, unsigned char y)
{
llvm::Function *pslld = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pslli_d);
return As<Int2>(V(::builder->CreateCall2(pslld, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<Int4> pslld(RValue<Int4> x, unsigned char y)
{
if(CPUID::supportsSSE2())
{
llvm::Function *pslld = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_pslli_d);
return RValue<Int4>(V(::builder->CreateCall2(pslld, x.value, V(Nucleus::createConstantInt(y)))));
}
else
{
Int2 lo = Int2(x);
Int2 hi = Int2(Swizzle(x, 0xEE));
lo = x86::pslld(lo, y);
hi = x86::pslld(hi, y);
return Int4(lo, hi);
}
}
RValue<Int2> psrad(RValue<Int2> x, unsigned char y)
{
llvm::Function *psrad = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrai_d);
return As<Int2>(V(::builder->CreateCall2(psrad, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<Int4> psrad(RValue<Int4> x, unsigned char y)
{
if(CPUID::supportsSSE2())
{
llvm::Function *psrad = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_psrai_d);
return RValue<Int4>(V(::builder->CreateCall2(psrad, x.value, V(Nucleus::createConstantInt(y)))));
}
else
{
Int2 lo = Int2(x);
Int2 hi = Int2(Swizzle(x, 0xEE));
lo = x86::psrad(lo, y);
hi = x86::psrad(hi, y);
return Int4(lo, hi);
}
}
RValue<UInt2> psrld(RValue<UInt2> x, unsigned char y)
{
llvm::Function *psrld = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrli_d);
return As<UInt2>(V(::builder->CreateCall2(psrld, As<MMX>(x).value, V(Nucleus::createConstantInt(y)))));
}
RValue<UInt4> psrld(RValue<UInt4> x, unsigned char y)
{
if(CPUID::supportsSSE2())
{
llvm::Function *psrld = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_psrli_d);
return RValue<UInt4>(V(::builder->CreateCall2(psrld, x.value, V(Nucleus::createConstantInt(y)))));
}
else
{
UInt2 lo = As<UInt2>(Int2(As<Int4>(x)));
UInt2 hi = As<UInt2>(Int2(Swizzle(As<Int4>(x), 0xEE)));
lo = x86::psrld(lo, y);
hi = x86::psrld(hi, y);
return UInt4(lo, hi);
}
}
RValue<UShort4> psrlw(RValue<UShort4> x, RValue<Long1> y)
{
llvm::Function *psrlw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrl_w);
return As<UShort4>(V(::builder->CreateCall2(psrlw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> psraw(RValue<Short4> x, RValue<Long1> y)
{
llvm::Function *psraw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psra_w);
return As<Short4>(V(::builder->CreateCall2(psraw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short4> psllw(RValue<Short4> x, RValue<Long1> y)
{
llvm::Function *psllw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psll_w);
return As<Short4>(V(::builder->CreateCall2(psllw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> pslld(RValue<Int2> x, RValue<Long1> y)
{
llvm::Function *pslld = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psll_d);
return As<Int2>(V(::builder->CreateCall2(pslld, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UInt2> psrld(RValue<UInt2> x, RValue<Long1> y)
{
llvm::Function *psrld = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psrl_d);
return As<UInt2>(V(::builder->CreateCall2(psrld, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> psrad(RValue<Int2> x, RValue<Long1> y)
{
llvm::Function *psrld = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_psra_d);
return As<Int2>(V(::builder->CreateCall2(psrld, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int4> pmaxsd(RValue<Int4> x, RValue<Int4> y)
{
llvm::Function *pmaxsd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmaxsd);
return RValue<Int4>(V(::builder->CreateCall2(pmaxsd, x.value, y.value)));
}
RValue<Int4> pminsd(RValue<Int4> x, RValue<Int4> y)
{
llvm::Function *pminsd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pminsd);
return RValue<Int4>(V(::builder->CreateCall2(pminsd, x.value, y.value)));
}
RValue<UInt4> pmaxud(RValue<UInt4> x, RValue<UInt4> y)
{
llvm::Function *pmaxud = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmaxud);
return RValue<UInt4>(V(::builder->CreateCall2(pmaxud, x.value, y.value)));
}
RValue<UInt4> pminud(RValue<UInt4> x, RValue<UInt4> y)
{
llvm::Function *pminud = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pminud);
return RValue<UInt4>(V(::builder->CreateCall2(pminud, x.value, y.value)));
}
RValue<Short4> pmulhw(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pmulhw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmulh_w);
return As<Short4>(V(::builder->CreateCall2(pmulhw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<UShort4> pmulhuw(RValue<UShort4> x, RValue<UShort4> y)
{
llvm::Function *pmulhuw = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmulhu_w);
return As<UShort4>(V(::builder->CreateCall2(pmulhuw, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Int2> pmaddwd(RValue<Short4> x, RValue<Short4> y)
{
llvm::Function *pmaddwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmadd_wd);
return As<Int2>(V(::builder->CreateCall2(pmaddwd, As<MMX>(x).value, As<MMX>(y).value)));
}
RValue<Short8> pmulhw(RValue<Short8> x, RValue<Short8> y)
{
llvm::Function *pmulhw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_pmulh_w);
return RValue<Short8>(V(::builder->CreateCall2(pmulhw, x.value, y.value)));
}
RValue<UShort8> pmulhuw(RValue<UShort8> x, RValue<UShort8> y)
{
llvm::Function *pmulhuw = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_pmulhu_w);
return RValue<UShort8>(V(::builder->CreateCall2(pmulhuw, x.value, y.value)));
}
RValue<Int4> pmaddwd(RValue<Short8> x, RValue<Short8> y)
{
llvm::Function *pmaddwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse2_pmadd_wd);
return RValue<Int4>(V(::builder->CreateCall2(pmaddwd, x.value, y.value)));
}
RValue<Int> movmskps(RValue<Float4> x)
{
llvm::Function *movmskps = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse_movmsk_ps);
return RValue<Int>(V(::builder->CreateCall(movmskps, x.value)));
}
RValue<Int> pmovmskb(RValue<Byte8> x)
{
llvm::Function *pmovmskb = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_pmovmskb);
return RValue<Int>(V(::builder->CreateCall(pmovmskb, As<MMX>(x).value)));
}
//RValue<Int2> movd(RValue<Pointer<Int>> x)
//{
// Value *element = Nucleus::createLoad(x.value);
//// Value *int2 = UndefValue::get(Int2::getType());
//// int2 = Nucleus::createInsertElement(int2, element, ConstantInt::get(Int::getType(), 0));
// Value *int2 = Nucleus::createBitCast(Nucleus::createZExt(element, Long::getType()), Int2::getType());
// return RValue<Int2>(int2);
//}
//RValue<Int2> movdq2q(RValue<Int4> x)
//{
// Value *long2 = Nucleus::createBitCast(x.value, T(VectorType::get(Long::getType(), 2)));
// Value *element = Nucleus::createExtractElement(long2, ConstantInt::get(Int::getType(), 0));
// return RValue<Int2>(Nucleus::createBitCast(element, Int2::getType()));
//}
RValue<Int4> pmovzxbd(RValue<Int4> x)
{
llvm::Function *pmovzxbd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmovzxbd);
return RValue<Int4>(V(::builder->CreateCall(pmovzxbd, Nucleus::createBitCast(x.value, Byte16::getType()))));
}
RValue<Int4> pmovsxbd(RValue<Int4> x)
{
llvm::Function *pmovsxbd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmovsxbd);
return RValue<Int4>(V(::builder->CreateCall(pmovsxbd, Nucleus::createBitCast(x.value, SByte16::getType()))));
}
RValue<Int4> pmovzxwd(RValue<Int4> x)
{
llvm::Function *pmovzxwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmovzxwd);
return RValue<Int4>(V(::builder->CreateCall(pmovzxwd, Nucleus::createBitCast(x.value, UShort8::getType()))));
}
RValue<Int4> pmovsxwd(RValue<Int4> x)
{
llvm::Function *pmovsxwd = Intrinsic::getDeclaration(::module, Intrinsic::x86_sse41_pmovsxwd);
return RValue<Int4>(V(::builder->CreateCall(pmovsxwd, Nucleus::createBitCast(x.value, Short8::getType()))));
}
void emms()
{
llvm::Function *emms = Intrinsic::getDeclaration(::module, Intrinsic::x86_mmx_emms);
V(::builder->CreateCall(emms));
}
}
}