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|
/****************************************************************************
* Copyright (C) 2014-2015 Intel Corporation. All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*
* @file builder_misc.cpp
*
* @brief Implementation for miscellaneous builder functions
*
* Notes:
*
******************************************************************************/
#include "jit_pch.hpp"
#include "builder.h"
#include "common/rdtsc_buckets.h"
#include <cstdarg>
extern "C" void CallPrint(const char* fmt, ...);
namespace SwrJit
{
//////////////////////////////////////////////////////////////////////////
/// @brief Convert an IEEE 754 32-bit single precision float to an
/// 16 bit float with 5 exponent bits and a variable
/// number of mantissa bits.
/// @param val - 32-bit float
/// @todo Maybe move this outside of this file into a header?
static uint16_t ConvertFloat32ToFloat16(float val)
{
uint32_t sign, exp, mant;
uint32_t roundBits;
// Extract the sign, exponent, and mantissa
uint32_t uf = *(uint32_t*)&val;
sign = (uf & 0x80000000) >> 31;
exp = (uf & 0x7F800000) >> 23;
mant = uf & 0x007FFFFF;
// Check for out of range
if (std::isnan(val))
{
exp = 0x1F;
mant = 0x200;
sign = 1; // set the sign bit for NANs
}
else if (std::isinf(val))
{
exp = 0x1f;
mant = 0x0;
}
else if (exp > (0x70 + 0x1E)) // Too big to represent -> max representable value
{
exp = 0x1E;
mant = 0x3FF;
}
else if ((exp <= 0x70) && (exp >= 0x66)) // It's a denorm
{
mant |= 0x00800000;
for (; exp <= 0x70; mant >>= 1, exp++)
;
exp = 0;
mant = mant >> 13;
}
else if (exp < 0x66) // Too small to represent -> Zero
{
exp = 0;
mant = 0;
}
else
{
// Saves bits that will be shifted off for rounding
roundBits = mant & 0x1FFFu;
// convert exponent and mantissa to 16 bit format
exp = exp - 0x70;
mant = mant >> 13;
// Essentially RTZ, but round up if off by only 1 lsb
if (roundBits == 0x1FFFu)
{
mant++;
// check for overflow
if ((mant & 0xC00u) != 0)
exp++;
// make sure only the needed bits are used
mant &= 0x3FF;
}
}
uint32_t tmpVal = (sign << 15) | (exp << 10) | mant;
return (uint16_t)tmpVal;
}
//////////////////////////////////////////////////////////////////////////
/// @brief Convert an IEEE 754 16-bit float to an 32-bit single precision
/// float
/// @param val - 16-bit float
/// @todo Maybe move this outside of this file into a header?
static float ConvertFloat16ToFloat32(uint32_t val)
{
uint32_t result;
if ((val & 0x7fff) == 0)
{
result = ((uint32_t)(val & 0x8000)) << 16;
}
else if ((val & 0x7c00) == 0x7c00)
{
result = ((val & 0x3ff) == 0) ? 0x7f800000 : 0x7fc00000;
result |= ((uint32_t)val & 0x8000) << 16;
}
else
{
uint32_t sign = (val & 0x8000) << 16;
uint32_t mant = (val & 0x3ff) << 13;
uint32_t exp = (val >> 10) & 0x1f;
if ((exp == 0) && (mant != 0)) // Adjust exponent and mantissa for denormals
{
mant <<= 1;
while (mant < (0x400 << 13))
{
exp--;
mant <<= 1;
}
mant &= (0x3ff << 13);
}
exp = ((exp - 15 + 127) & 0xff) << 23;
result = sign | exp | mant;
}
return *(float*)&result;
}
Constant* Builder::C(bool i) { return ConstantInt::get(IRB()->getInt1Ty(), (i ? 1 : 0)); }
Constant* Builder::C(char i) { return ConstantInt::get(IRB()->getInt8Ty(), i); }
Constant* Builder::C(uint8_t i) { return ConstantInt::get(IRB()->getInt8Ty(), i); }
Constant* Builder::C(int i) { return ConstantInt::get(IRB()->getInt32Ty(), i); }
Constant* Builder::C(int64_t i) { return ConstantInt::get(IRB()->getInt64Ty(), i); }
Constant* Builder::C(uint16_t i) { return ConstantInt::get(mInt16Ty, i); }
Constant* Builder::C(uint32_t i) { return ConstantInt::get(IRB()->getInt32Ty(), i); }
Constant* Builder::C(uint64_t i) { return ConstantInt::get(IRB()->getInt64Ty(), i); }
Constant* Builder::C(float i) { return ConstantFP::get(IRB()->getFloatTy(), i); }
Constant* Builder::PRED(bool pred)
{
return ConstantInt::get(IRB()->getInt1Ty(), (pred ? 1 : 0));
}
Value* Builder::VIMMED1(int i)
{
return ConstantVector::getSplat(mVWidth, cast<ConstantInt>(C(i)));
}
Value* Builder::VIMMED1_16(int i)
{
return ConstantVector::getSplat(mVWidth16, cast<ConstantInt>(C(i)));
}
Value* Builder::VIMMED1(uint32_t i)
{
return ConstantVector::getSplat(mVWidth, cast<ConstantInt>(C(i)));
}
Value* Builder::VIMMED1_16(uint32_t i)
{
return ConstantVector::getSplat(mVWidth16, cast<ConstantInt>(C(i)));
}
Value* Builder::VIMMED1(float i)
{
return ConstantVector::getSplat(mVWidth, cast<ConstantFP>(C(i)));
}
Value* Builder::VIMMED1_16(float i)
{
return ConstantVector::getSplat(mVWidth16, cast<ConstantFP>(C(i)));
}
Value* Builder::VIMMED1(bool i)
{
return ConstantVector::getSplat(mVWidth, cast<ConstantInt>(C(i)));
}
Value* Builder::VIMMED1_16(bool i)
{
return ConstantVector::getSplat(mVWidth16, cast<ConstantInt>(C(i)));
}
Value* Builder::VUNDEF_IPTR() { return UndefValue::get(VectorType::get(mInt32PtrTy, mVWidth)); }
Value* Builder::VUNDEF(Type* t) { return UndefValue::get(VectorType::get(t, mVWidth)); }
Value* Builder::VUNDEF_I() { return UndefValue::get(VectorType::get(mInt32Ty, mVWidth)); }
Value* Builder::VUNDEF_I_16() { return UndefValue::get(VectorType::get(mInt32Ty, mVWidth16)); }
Value* Builder::VUNDEF_F() { return UndefValue::get(VectorType::get(mFP32Ty, mVWidth)); }
Value* Builder::VUNDEF_F_16() { return UndefValue::get(VectorType::get(mFP32Ty, mVWidth16)); }
Value* Builder::VUNDEF(Type* ty, uint32_t size)
{
return UndefValue::get(VectorType::get(ty, size));
}
Value* Builder::VBROADCAST(Value* src, const llvm::Twine& name)
{
// check if src is already a vector
if (src->getType()->isVectorTy())
{
return src;
}
return VECTOR_SPLAT(mVWidth, src, name);
}
Value* Builder::VBROADCAST_16(Value* src)
{
// check if src is already a vector
if (src->getType()->isVectorTy())
{
return src;
}
return VECTOR_SPLAT(mVWidth16, src);
}
uint32_t Builder::IMMED(Value* v)
{
SWR_ASSERT(isa<ConstantInt>(v));
ConstantInt* pValConst = cast<ConstantInt>(v);
return pValConst->getZExtValue();
}
int32_t Builder::S_IMMED(Value* v)
{
SWR_ASSERT(isa<ConstantInt>(v));
ConstantInt* pValConst = cast<ConstantInt>(v);
return pValConst->getSExtValue();
}
CallInst* Builder::CALL(Value* Callee,
const std::initializer_list<Value*>& argsList,
const llvm::Twine& name)
{
std::vector<Value*> args;
for (auto arg : argsList)
args.push_back(arg);
return CALLA(Callee, args, name);
}
CallInst* Builder::CALL(Value* Callee, Value* arg)
{
std::vector<Value*> args;
args.push_back(arg);
return CALLA(Callee, args);
}
CallInst* Builder::CALL2(Value* Callee, Value* arg1, Value* arg2)
{
std::vector<Value*> args;
args.push_back(arg1);
args.push_back(arg2);
return CALLA(Callee, args);
}
CallInst* Builder::CALL3(Value* Callee, Value* arg1, Value* arg2, Value* arg3)
{
std::vector<Value*> args;
args.push_back(arg1);
args.push_back(arg2);
args.push_back(arg3);
return CALLA(Callee, args);
}
Value* Builder::VRCP(Value* va, const llvm::Twine& name)
{
return FDIV(VIMMED1(1.0f), va, name); // 1 / a
}
Value* Builder::VPLANEPS(Value* vA, Value* vB, Value* vC, Value*& vX, Value*& vY)
{
Value* vOut = FMADDPS(vA, vX, vC);
vOut = FMADDPS(vB, vY, vOut);
return vOut;
}
//////////////////////////////////////////////////////////////////////////
/// @brief insert a JIT call to CallPrint
/// - outputs formatted string to both stdout and VS output window
/// - DEBUG builds only
/// Usage example:
/// PRINT("index %d = 0x%p\n",{C(lane), pIndex});
/// where C(lane) creates a constant value to print, and pIndex is the Value*
/// result from a GEP, printing out the pointer to memory
/// @param printStr - constant string to print, which includes format specifiers
/// @param printArgs - initializer list of Value*'s to print to std out
CallInst* Builder::PRINT(const std::string& printStr,
const std::initializer_list<Value*>& printArgs)
{
// push the arguments to CallPrint into a vector
std::vector<Value*> printCallArgs;
// save room for the format string. we still need to modify it for vectors
printCallArgs.resize(1);
// search through the format string for special processing
size_t pos = 0;
std::string tempStr(printStr);
pos = tempStr.find('%', pos);
auto v = printArgs.begin();
while ((pos != std::string::npos) && (v != printArgs.end()))
{
Value* pArg = *v;
Type* pType = pArg->getType();
if (pType->isVectorTy())
{
Type* pContainedType = pType->getContainedType(0);
if (toupper(tempStr[pos + 1]) == 'X')
{
tempStr[pos] = '0';
tempStr[pos + 1] = 'x';
tempStr.insert(pos + 2, "%08X ");
pos += 7;
printCallArgs.push_back(VEXTRACT(pArg, C(0)));
std::string vectorFormatStr;
for (uint32_t i = 1; i < pType->getVectorNumElements(); ++i)
{
vectorFormatStr += "0x%08X ";
printCallArgs.push_back(VEXTRACT(pArg, C(i)));
}
tempStr.insert(pos, vectorFormatStr);
pos += vectorFormatStr.size();
}
else if ((tempStr[pos + 1] == 'f') && (pContainedType->isFloatTy()))
{
uint32_t i = 0;
for (; i < (pArg->getType()->getVectorNumElements()) - 1; i++)
{
tempStr.insert(pos, std::string("%f "));
pos += 3;
printCallArgs.push_back(
FP_EXT(VEXTRACT(pArg, C(i)), Type::getDoubleTy(JM()->mContext)));
}
printCallArgs.push_back(
FP_EXT(VEXTRACT(pArg, C(i)), Type::getDoubleTy(JM()->mContext)));
}
else if ((tempStr[pos + 1] == 'd') && (pContainedType->isIntegerTy()))
{
uint32_t i = 0;
for (; i < (pArg->getType()->getVectorNumElements()) - 1; i++)
{
tempStr.insert(pos, std::string("%d "));
pos += 3;
printCallArgs.push_back(
S_EXT(VEXTRACT(pArg, C(i)), Type::getInt32Ty(JM()->mContext)));
}
printCallArgs.push_back(
S_EXT(VEXTRACT(pArg, C(i)), Type::getInt32Ty(JM()->mContext)));
}
else if ((tempStr[pos + 1] == 'u') && (pContainedType->isIntegerTy()))
{
uint32_t i = 0;
for (; i < (pArg->getType()->getVectorNumElements()) - 1; i++)
{
tempStr.insert(pos, std::string("%d "));
pos += 3;
printCallArgs.push_back(
Z_EXT(VEXTRACT(pArg, C(i)), Type::getInt32Ty(JM()->mContext)));
}
printCallArgs.push_back(
Z_EXT(VEXTRACT(pArg, C(i)), Type::getInt32Ty(JM()->mContext)));
}
}
else
{
if (toupper(tempStr[pos + 1]) == 'X')
{
tempStr[pos] = '0';
tempStr.insert(pos + 1, "x%08");
printCallArgs.push_back(pArg);
pos += 3;
}
// for %f we need to cast float Values to doubles so that they print out correctly
else if ((tempStr[pos + 1] == 'f') && (pType->isFloatTy()))
{
printCallArgs.push_back(FP_EXT(pArg, Type::getDoubleTy(JM()->mContext)));
pos++;
}
else
{
printCallArgs.push_back(pArg);
}
}
// advance to the next arguement
v++;
pos = tempStr.find('%', ++pos);
}
// create global variable constant string
Constant* constString = ConstantDataArray::getString(JM()->mContext, tempStr, true);
GlobalVariable* gvPtr = new GlobalVariable(
constString->getType(), true, GlobalValue::InternalLinkage, constString, "printStr");
JM()->mpCurrentModule->getGlobalList().push_back(gvPtr);
// get a pointer to the first character in the constant string array
std::vector<Constant*> geplist{C(0), C(0)};
Constant* strGEP = ConstantExpr::getGetElementPtr(nullptr, gvPtr, geplist, false);
// insert the pointer to the format string in the argument vector
printCallArgs[0] = strGEP;
// get pointer to CallPrint function and insert decl into the module if needed
std::vector<Type*> args;
args.push_back(PointerType::get(mInt8Ty, 0));
FunctionType* callPrintTy = FunctionType::get(Type::getVoidTy(JM()->mContext), args, true);
Function* callPrintFn =
cast<Function>(JM()->mpCurrentModule->getOrInsertFunction("CallPrint", callPrintTy));
// if we haven't yet added the symbol to the symbol table
if ((sys::DynamicLibrary::SearchForAddressOfSymbol("CallPrint")) == nullptr)
{
sys::DynamicLibrary::AddSymbol("CallPrint", (void*)&CallPrint);
}
// insert a call to CallPrint
return CALLA(callPrintFn, printCallArgs);
}
//////////////////////////////////////////////////////////////////////////
/// @brief Wrapper around PRINT with initializer list.
CallInst* Builder::PRINT(const std::string& printStr) { return PRINT(printStr, {}); }
Value* Builder::EXTRACT_16(Value* x, uint32_t imm)
{
if (imm == 0)
{
return VSHUFFLE(x, UndefValue::get(x->getType()), {0, 1, 2, 3, 4, 5, 6, 7});
}
else
{
return VSHUFFLE(x, UndefValue::get(x->getType()), {8, 9, 10, 11, 12, 13, 14, 15});
}
}
Value* Builder::JOIN_16(Value* a, Value* b)
{
return VSHUFFLE(a, b, {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15});
}
//////////////////////////////////////////////////////////////////////////
/// @brief convert x86 <N x float> mask to llvm <N x i1> mask
Value* Builder::MASK(Value* vmask)
{
Value* src = BITCAST(vmask, mSimdInt32Ty);
return ICMP_SLT(src, VIMMED1(0));
}
Value* Builder::MASK_16(Value* vmask)
{
Value* src = BITCAST(vmask, mSimd16Int32Ty);
return ICMP_SLT(src, VIMMED1_16(0));
}
//////////////////////////////////////////////////////////////////////////
/// @brief convert llvm <N x i1> mask to x86 <N x i32> mask
Value* Builder::VMASK(Value* mask) { return S_EXT(mask, mSimdInt32Ty); }
Value* Builder::VMASK_16(Value* mask) { return S_EXT(mask, mSimd16Int32Ty); }
/// @brief Convert <Nxi1> llvm mask to integer
Value* Builder::VMOVMSK(Value* mask)
{
SWR_ASSERT(mask->getType()->getVectorElementType() == mInt1Ty);
uint32_t numLanes = mask->getType()->getVectorNumElements();
Value* i32Result;
if (numLanes == 8)
{
i32Result = BITCAST(mask, mInt8Ty);
}
else if (numLanes == 16)
{
i32Result = BITCAST(mask, mInt16Ty);
}
else
{
SWR_ASSERT("Unsupported vector width");
i32Result = BITCAST(mask, mInt8Ty);
}
return Z_EXT(i32Result, mInt32Ty);
}
//////////////////////////////////////////////////////////////////////////
/// @brief Generate a VPSHUFB operation in LLVM IR. If not
/// supported on the underlying platform, emulate it
/// @param a - 256bit SIMD(32x8bit) of 8bit integer values
/// @param b - 256bit SIMD(32x8bit) of 8bit integer mask values
/// Byte masks in lower 128 lane of b selects 8 bit values from lower
/// 128bits of a, and vice versa for the upper lanes. If the mask
/// value is negative, '0' is inserted.
Value* Builder::PSHUFB(Value* a, Value* b)
{
Value* res;
// use avx2 pshufb instruction if available
if (JM()->mArch.AVX2())
{
res = VPSHUFB(a, b);
}
else
{
Constant* cB = dyn_cast<Constant>(b);
// number of 8 bit elements in b
uint32_t numElms = cast<VectorType>(cB->getType())->getNumElements();
// output vector
Value* vShuf = UndefValue::get(VectorType::get(mInt8Ty, numElms));
// insert an 8 bit value from the high and low lanes of a per loop iteration
numElms /= 2;
for (uint32_t i = 0; i < numElms; i++)
{
ConstantInt* cLow128b = cast<ConstantInt>(cB->getAggregateElement(i));
ConstantInt* cHigh128b = cast<ConstantInt>(cB->getAggregateElement(i + numElms));
// extract values from constant mask
char valLow128bLane = (char)(cLow128b->getSExtValue());
char valHigh128bLane = (char)(cHigh128b->getSExtValue());
Value* insertValLow128b;
Value* insertValHigh128b;
// if the mask value is negative, insert a '0' in the respective output position
// otherwise, lookup the value at mask position (bits 3..0 of the respective mask
// byte) in a and insert in output vector
insertValLow128b =
(valLow128bLane < 0) ? C((char)0) : VEXTRACT(a, C((valLow128bLane & 0xF)));
insertValHigh128b = (valHigh128bLane < 0)
? C((char)0)
: VEXTRACT(a, C((valHigh128bLane & 0xF) + numElms));
vShuf = VINSERT(vShuf, insertValLow128b, i);
vShuf = VINSERT(vShuf, insertValHigh128b, (i + numElms));
}
res = vShuf;
}
return res;
}
//////////////////////////////////////////////////////////////////////////
/// @brief Generate a VPSHUFB operation (sign extend 8 8bit values to 32
/// bits)in LLVM IR. If not supported on the underlying platform, emulate it
/// @param a - 128bit SIMD lane(16x8bit) of 8bit integer values. Only
/// lower 8 values are used.
Value* Builder::PMOVSXBD(Value* a)
{
// VPMOVSXBD output type
Type* v8x32Ty = VectorType::get(mInt32Ty, 8);
// Extract 8 values from 128bit lane and sign extend
return S_EXT(VSHUFFLE(a, a, C<int>({0, 1, 2, 3, 4, 5, 6, 7})), v8x32Ty);
}
//////////////////////////////////////////////////////////////////////////
/// @brief Generate a VPSHUFB operation (sign extend 8 16bit values to 32
/// bits)in LLVM IR. If not supported on the underlying platform, emulate it
/// @param a - 128bit SIMD lane(8x16bit) of 16bit integer values.
Value* Builder::PMOVSXWD(Value* a)
{
// VPMOVSXWD output type
Type* v8x32Ty = VectorType::get(mInt32Ty, 8);
// Extract 8 values from 128bit lane and sign extend
return S_EXT(VSHUFFLE(a, a, C<int>({0, 1, 2, 3, 4, 5, 6, 7})), v8x32Ty);
}
//////////////////////////////////////////////////////////////////////////
/// @brief Generate a VCVTPH2PS operation (float16->float32 conversion)
/// in LLVM IR. If not supported on the underlying platform, emulate it
/// @param a - 128bit SIMD lane(8x16bit) of float16 in int16 format.
Value* Builder::CVTPH2PS(Value* a, const llvm::Twine& name)
{
if (JM()->mArch.F16C())
{
return VCVTPH2PS(a, name);
}
else
{
FunctionType* pFuncTy = FunctionType::get(mFP32Ty, mInt16Ty);
Function* pCvtPh2Ps = cast<Function>(
JM()->mpCurrentModule->getOrInsertFunction("ConvertFloat16ToFloat32", pFuncTy));
if (sys::DynamicLibrary::SearchForAddressOfSymbol("ConvertFloat16ToFloat32") == nullptr)
{
sys::DynamicLibrary::AddSymbol("ConvertFloat16ToFloat32",
(void*)&ConvertFloat16ToFloat32);
}
Value* pResult = UndefValue::get(mSimdFP32Ty);
for (uint32_t i = 0; i < mVWidth; ++i)
{
Value* pSrc = VEXTRACT(a, C(i));
Value* pConv = CALL(pCvtPh2Ps, std::initializer_list<Value*>{pSrc});
pResult = VINSERT(pResult, pConv, C(i));
}
pResult->setName(name);
return pResult;
}
}
//////////////////////////////////////////////////////////////////////////
/// @brief Generate a VCVTPS2PH operation (float32->float16 conversion)
/// in LLVM IR. If not supported on the underlying platform, emulate it
/// @param a - 128bit SIMD lane(8x16bit) of float16 in int16 format.
Value* Builder::CVTPS2PH(Value* a, Value* rounding)
{
if (JM()->mArch.F16C())
{
return VCVTPS2PH(a, rounding);
}
else
{
// call scalar C function for now
FunctionType* pFuncTy = FunctionType::get(mInt16Ty, mFP32Ty);
Function* pCvtPs2Ph = cast<Function>(
JM()->mpCurrentModule->getOrInsertFunction("ConvertFloat32ToFloat16", pFuncTy));
if (sys::DynamicLibrary::SearchForAddressOfSymbol("ConvertFloat32ToFloat16") == nullptr)
{
sys::DynamicLibrary::AddSymbol("ConvertFloat32ToFloat16",
(void*)&ConvertFloat32ToFloat16);
}
Value* pResult = UndefValue::get(mSimdInt16Ty);
for (uint32_t i = 0; i < mVWidth; ++i)
{
Value* pSrc = VEXTRACT(a, C(i));
Value* pConv = CALL(pCvtPs2Ph, std::initializer_list<Value*>{pSrc});
pResult = VINSERT(pResult, pConv, C(i));
}
return pResult;
}
}
Value* Builder::PMAXSD(Value* a, Value* b)
{
Value* cmp = ICMP_SGT(a, b);
return SELECT(cmp, a, b);
}
Value* Builder::PMINSD(Value* a, Value* b)
{
Value* cmp = ICMP_SLT(a, b);
return SELECT(cmp, a, b);
}
Value* Builder::PMAXUD(Value* a, Value* b)
{
Value* cmp = ICMP_UGT(a, b);
return SELECT(cmp, a, b);
}
Value* Builder::PMINUD(Value* a, Value* b)
{
Value* cmp = ICMP_ULT(a, b);
return SELECT(cmp, a, b);
}
// Helper function to create alloca in entry block of function
Value* Builder::CreateEntryAlloca(Function* pFunc, Type* pType)
{
auto saveIP = IRB()->saveIP();
IRB()->SetInsertPoint(&pFunc->getEntryBlock(), pFunc->getEntryBlock().begin());
Value* pAlloca = ALLOCA(pType);
if (saveIP.isSet())
IRB()->restoreIP(saveIP);
return pAlloca;
}
Value* Builder::CreateEntryAlloca(Function* pFunc, Type* pType, Value* pArraySize)
{
auto saveIP = IRB()->saveIP();
IRB()->SetInsertPoint(&pFunc->getEntryBlock(), pFunc->getEntryBlock().begin());
Value* pAlloca = ALLOCA(pType, pArraySize);
if (saveIP.isSet())
IRB()->restoreIP(saveIP);
return pAlloca;
}
Value* Builder::VABSPS(Value* a)
{
Value* asInt = BITCAST(a, mSimdInt32Ty);
Value* result = BITCAST(AND(asInt, VIMMED1(0x7fffffff)), mSimdFP32Ty);
return result;
}
Value* Builder::ICLAMP(Value* src, Value* low, Value* high, const llvm::Twine& name)
{
Value* lowCmp = ICMP_SLT(src, low);
Value* ret = SELECT(lowCmp, low, src);
Value* highCmp = ICMP_SGT(ret, high);
ret = SELECT(highCmp, high, ret, name);
return ret;
}
Value* Builder::FCLAMP(Value* src, Value* low, Value* high)
{
Value* lowCmp = FCMP_OLT(src, low);
Value* ret = SELECT(lowCmp, low, src);
Value* highCmp = FCMP_OGT(ret, high);
ret = SELECT(highCmp, high, ret);
return ret;
}
Value* Builder::FCLAMP(Value* src, float low, float high)
{
Value* result = VMAXPS(src, VIMMED1(low));
result = VMINPS(result, VIMMED1(high));
return result;
}
Value* Builder::FMADDPS(Value* a, Value* b, Value* c)
{
Value* vOut;
// This maps to LLVM fmuladd intrinsic
vOut = VFMADDPS(a, b, c);
return vOut;
}
//////////////////////////////////////////////////////////////////////////
/// @brief pop count on vector mask (e.g. <8 x i1>)
Value* Builder::VPOPCNT(Value* a) { return POPCNT(VMOVMSK(a)); }
//////////////////////////////////////////////////////////////////////////
/// @brief Float / Fixed-point conversions
//////////////////////////////////////////////////////////////////////////
Value* Builder::VCVT_F32_FIXED_SI(Value* vFloat,
uint32_t numIntBits,
uint32_t numFracBits,
const llvm::Twine& name)
{
SWR_ASSERT((numIntBits + numFracBits) <= 32, "Can only handle 32-bit fixed-point values");
Value* fixed = nullptr;
#if 0
// This doesn't work for negative numbers!!
{
fixed = FP_TO_SI(VROUND(FMUL(vFloat, VIMMED1(float(1 << numFracBits))),
C(_MM_FROUND_TO_NEAREST_INT)),
mSimdInt32Ty);
}
#else
{
// Do round to nearest int on fractional bits first
// Not entirely perfect for negative numbers, but close enough
vFloat = VROUND(FMUL(vFloat, VIMMED1(float(1 << numFracBits))),
C(_MM_FROUND_TO_NEAREST_INT));
vFloat = FMUL(vFloat, VIMMED1(1.0f / float(1 << numFracBits)));
// TODO: Handle INF, NAN, overflow / underflow, etc.
Value* vSgn = FCMP_OLT(vFloat, VIMMED1(0.0f));
Value* vFloatInt = BITCAST(vFloat, mSimdInt32Ty);
Value* vFixed = AND(vFloatInt, VIMMED1((1 << 23) - 1));
vFixed = OR(vFixed, VIMMED1(1 << 23));
vFixed = SELECT(vSgn, NEG(vFixed), vFixed);
Value* vExp = LSHR(SHL(vFloatInt, VIMMED1(1)), VIMMED1(24));
vExp = SUB(vExp, VIMMED1(127));
Value* vExtraBits = SUB(VIMMED1(23 - numFracBits), vExp);
fixed = ASHR(vFixed, vExtraBits, name);
}
#endif
return fixed;
}
Value* Builder::VCVT_FIXED_SI_F32(Value* vFixed,
uint32_t numIntBits,
uint32_t numFracBits,
const llvm::Twine& name)
{
SWR_ASSERT((numIntBits + numFracBits) <= 32, "Can only handle 32-bit fixed-point values");
uint32_t extraBits = 32 - numIntBits - numFracBits;
if (numIntBits && extraBits)
{
// Sign extend
Value* shftAmt = VIMMED1(extraBits);
vFixed = ASHR(SHL(vFixed, shftAmt), shftAmt);
}
Value* fVal = VIMMED1(0.0f);
Value* fFrac = VIMMED1(0.0f);
if (numIntBits)
{
fVal = SI_TO_FP(ASHR(vFixed, VIMMED1(numFracBits)), mSimdFP32Ty, name);
}
if (numFracBits)
{
fFrac = UI_TO_FP(AND(vFixed, VIMMED1((1 << numFracBits) - 1)), mSimdFP32Ty);
fFrac = FDIV(fFrac, VIMMED1(float(1 << numFracBits)), name);
}
return FADD(fVal, fFrac, name);
}
Value* Builder::VCVT_F32_FIXED_UI(Value* vFloat,
uint32_t numIntBits,
uint32_t numFracBits,
const llvm::Twine& name)
{
SWR_ASSERT((numIntBits + numFracBits) <= 32, "Can only handle 32-bit fixed-point values");
Value* fixed = nullptr;
#if 1
// KNOB_SIM_FAST_MATH? Below works correctly from a precision
// standpoint...
{
fixed = FP_TO_UI(VROUND(FMUL(vFloat, VIMMED1(float(1 << numFracBits))),
C(_MM_FROUND_TO_NEAREST_INT)),
mSimdInt32Ty);
}
#else
{
// Do round to nearest int on fractional bits first
vFloat = VROUND(FMUL(vFloat, VIMMED1(float(1 << numFracBits))),
C(_MM_FROUND_TO_NEAREST_INT));
vFloat = FMUL(vFloat, VIMMED1(1.0f / float(1 << numFracBits)));
// TODO: Handle INF, NAN, overflow / underflow, etc.
Value* vSgn = FCMP_OLT(vFloat, VIMMED1(0.0f));
Value* vFloatInt = BITCAST(vFloat, mSimdInt32Ty);
Value* vFixed = AND(vFloatInt, VIMMED1((1 << 23) - 1));
vFixed = OR(vFixed, VIMMED1(1 << 23));
Value* vExp = LSHR(SHL(vFloatInt, VIMMED1(1)), VIMMED1(24));
vExp = SUB(vExp, VIMMED1(127));
Value* vExtraBits = SUB(VIMMED1(23 - numFracBits), vExp);
fixed = LSHR(vFixed, vExtraBits, name);
}
#endif
return fixed;
}
Value* Builder::VCVT_FIXED_UI_F32(Value* vFixed,
uint32_t numIntBits,
uint32_t numFracBits,
const llvm::Twine& name)
{
SWR_ASSERT((numIntBits + numFracBits) <= 32, "Can only handle 32-bit fixed-point values");
uint32_t extraBits = 32 - numIntBits - numFracBits;
if (numIntBits && extraBits)
{
// Sign extend
Value* shftAmt = VIMMED1(extraBits);
vFixed = ASHR(SHL(vFixed, shftAmt), shftAmt);
}
Value* fVal = VIMMED1(0.0f);
Value* fFrac = VIMMED1(0.0f);
if (numIntBits)
{
fVal = UI_TO_FP(LSHR(vFixed, VIMMED1(numFracBits)), mSimdFP32Ty, name);
}
if (numFracBits)
{
fFrac = UI_TO_FP(AND(vFixed, VIMMED1((1 << numFracBits) - 1)), mSimdFP32Ty);
fFrac = FDIV(fFrac, VIMMED1(float(1 << numFracBits)), name);
}
return FADD(fVal, fFrac, name);
}
//////////////////////////////////////////////////////////////////////////
/// @brief C functions called by LLVM IR
//////////////////////////////////////////////////////////////////////////
Value* Builder::VEXTRACTI128(Value* a, Constant* imm8)
{
bool flag = !imm8->isZeroValue();
SmallVector<Constant*, 8> idx;
for (unsigned i = 0; i < mVWidth / 2; i++)
{
idx.push_back(C(flag ? i + mVWidth / 2 : i));
}
return VSHUFFLE(a, VUNDEF_I(), ConstantVector::get(idx));
}
Value* Builder::VINSERTI128(Value* a, Value* b, Constant* imm8)
{
bool flag = !imm8->isZeroValue();
SmallVector<Constant*, 8> idx;
for (unsigned i = 0; i < mVWidth; i++)
{
idx.push_back(C(i));
}
Value* inter = VSHUFFLE(b, VUNDEF_I(), ConstantVector::get(idx));
SmallVector<Constant*, 8> idx2;
for (unsigned i = 0; i < mVWidth / 2; i++)
{
idx2.push_back(C(flag ? i : i + mVWidth));
}
for (unsigned i = mVWidth / 2; i < mVWidth; i++)
{
idx2.push_back(C(flag ? i + mVWidth / 2 : i));
}
return VSHUFFLE(a, inter, ConstantVector::get(idx2));
}
// rdtsc buckets macros
void Builder::RDTSC_START(Value* pBucketMgr, Value* pId)
{
// @todo due to an issue with thread local storage propagation in llvm, we can only safely
// call into buckets framework when single threaded
if (KNOB_SINGLE_THREADED)
{
std::vector<Type*> args{
PointerType::get(mInt32Ty, 0), // pBucketMgr
mInt32Ty // id
};
FunctionType* pFuncTy = FunctionType::get(Type::getVoidTy(JM()->mContext), args, false);
Function* pFunc = cast<Function>(
JM()->mpCurrentModule->getOrInsertFunction("BucketManager_StartBucket", pFuncTy));
if (sys::DynamicLibrary::SearchForAddressOfSymbol("BucketManager_StartBucket") ==
nullptr)
{
sys::DynamicLibrary::AddSymbol("BucketManager_StartBucket",
(void*)&BucketManager_StartBucket);
}
CALL(pFunc, {pBucketMgr, pId});
}
}
void Builder::RDTSC_STOP(Value* pBucketMgr, Value* pId)
{
// @todo due to an issue with thread local storage propagation in llvm, we can only safely
// call into buckets framework when single threaded
if (KNOB_SINGLE_THREADED)
{
std::vector<Type*> args{
PointerType::get(mInt32Ty, 0), // pBucketMgr
mInt32Ty // id
};
FunctionType* pFuncTy = FunctionType::get(Type::getVoidTy(JM()->mContext), args, false);
Function* pFunc = cast<Function>(
JM()->mpCurrentModule->getOrInsertFunction("BucketManager_StopBucket", pFuncTy));
if (sys::DynamicLibrary::SearchForAddressOfSymbol("BucketManager_StopBucket") ==
nullptr)
{
sys::DynamicLibrary::AddSymbol("BucketManager_StopBucket",
(void*)&BucketManager_StopBucket);
}
CALL(pFunc, {pBucketMgr, pId});
}
}
uint32_t Builder::GetTypeSize(Type* pType)
{
if (pType->isStructTy())
{
uint32_t numElems = pType->getStructNumElements();
Type* pElemTy = pType->getStructElementType(0);
return numElems * GetTypeSize(pElemTy);
}
if (pType->isArrayTy())
{
uint32_t numElems = pType->getArrayNumElements();
Type* pElemTy = pType->getArrayElementType();
return numElems * GetTypeSize(pElemTy);
}
if (pType->isIntegerTy())
{
uint32_t bitSize = pType->getIntegerBitWidth();
return bitSize / 8;
}
if (pType->isFloatTy())
{
return 4;
}
if (pType->isHalfTy())
{
return 2;
}
if (pType->isDoubleTy())
{
return 8;
}
SWR_ASSERT(false, "Unimplemented type.");
return 0;
}
} // namespace SwrJit
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