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cobalt / cobalt / 3cd5432aaed8f14f27f66ade1b51aa71df939492 / . / third_party / angle / src / compiler / translator / ConstantUnion.cpp
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//
// Copyright 2016 The ANGLE Project Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
//
// ConstantUnion: Constant folding helper class.
#include "compiler/translator/ConstantUnion.h"
#include "common/mathutil.h"
#include "compiler/translator/Diagnostics.h"
#include "compiler/translator/util.h"
namespace sh
{
namespace
{
float CheckedSum(float lhs, float rhs, TDiagnostics *diag, const TSourceLoc &line)
{
float result = lhs + rhs;
if (gl::isNaN(result) && !gl::isNaN(lhs) && !gl::isNaN(rhs))
{
diag->warning(line, "Constant folded undefined addition generated NaN", "+");
}
else if (gl::isInf(result) && !gl::isInf(lhs) && !gl::isInf(rhs))
{
diag->warning(line, "Constant folded addition overflowed to infinity", "+");
}
return result;
}
float CheckedDiff(float lhs, float rhs, TDiagnostics *diag, const TSourceLoc &line)
{
float result = lhs - rhs;
if (gl::isNaN(result) && !gl::isNaN(lhs) && !gl::isNaN(rhs))
{
diag->warning(line, "Constant folded undefined subtraction generated NaN", "-");
}
else if (gl::isInf(result) && !gl::isInf(lhs) && !gl::isInf(rhs))
{
diag->warning(line, "Constant folded subtraction overflowed to infinity", "-");
}
return result;
}
float CheckedMul(float lhs, float rhs, TDiagnostics *diag, const TSourceLoc &line)
{
float result = lhs * rhs;
if (gl::isNaN(result) && !gl::isNaN(lhs) && !gl::isNaN(rhs))
{
diag->warning(line, "Constant folded undefined multiplication generated NaN", "*");
}
else if (gl::isInf(result) && !gl::isInf(lhs) && !gl::isInf(rhs))
{
diag->warning(line, "Constant folded multiplication overflowed to infinity", "*");
}
return result;
}
bool IsValidShiftOffset(const TConstantUnion &rhs)
{
return (rhs.getType() == EbtInt && (rhs.getIConst() >= 0 && rhs.getIConst() <= 31)) ||
(rhs.getType() == EbtUInt && rhs.getUConst() <= 31u);
}
} // anonymous namespace
TConstantUnion::TConstantUnion()
{
iConst = 0;
type = EbtVoid;
}
int TConstantUnion::getIConst() const
{
ASSERT(type == EbtInt);
return iConst;
}
unsigned int TConstantUnion::getUConst() const
{
ASSERT(type == EbtUInt);
return uConst;
}
float TConstantUnion::getFConst() const
{
switch (type)
{
case EbtInt:
return static_cast<float>(iConst);
case EbtUInt:
return static_cast<float>(uConst);
default:
ASSERT(type == EbtFloat);
return fConst;
}
}
bool TConstantUnion::getBConst() const
{
ASSERT(type == EbtBool);
return bConst;
}
bool TConstantUnion::isZero() const
{
switch (type)
{
case EbtInt:
return getIConst() == 0;
case EbtUInt:
return getUConst() == 0;
case EbtFloat:
return getFConst() == 0.0f;
case EbtBool:
return getBConst() == false;
default:
return false;
}
}
TYuvCscStandardEXT TConstantUnion::getYuvCscStandardEXTConst() const
{
ASSERT(type == EbtYuvCscStandardEXT);
return yuvCscStandardEXTConst;
}
bool TConstantUnion::cast(TBasicType newType, const TConstantUnion &constant)
{
switch (newType)
{
case EbtFloat:
switch (constant.type)
{
case EbtInt:
setFConst(static_cast<float>(constant.getIConst()));
break;
case EbtUInt:
setFConst(static_cast<float>(constant.getUConst()));
break;
case EbtBool:
setFConst(static_cast<float>(constant.getBConst()));
break;
case EbtFloat:
setFConst(static_cast<float>(constant.getFConst()));
break;
default:
return false;
}
break;
case EbtInt:
switch (constant.type)
{
case EbtInt:
setIConst(static_cast<int>(constant.getIConst()));
break;
case EbtUInt:
setIConst(static_cast<int>(constant.getUConst()));
break;
case EbtBool:
setIConst(static_cast<int>(constant.getBConst()));
break;
case EbtFloat:
setIConst(static_cast<int>(constant.getFConst()));
break;
default:
return false;
}
break;
case EbtUInt:
switch (constant.type)
{
case EbtInt:
setUConst(static_cast<unsigned int>(constant.getIConst()));
break;
case EbtUInt:
setUConst(static_cast<unsigned int>(constant.getUConst()));
break;
case EbtBool:
setUConst(static_cast<unsigned int>(constant.getBConst()));
break;
case EbtFloat:
if (constant.getFConst() < 0.0f)
{
// Avoid undefined behavior in C++ by first casting to signed int.
setUConst(
static_cast<unsigned int>(static_cast<int>(constant.getFConst())));
}
else
{
setUConst(static_cast<unsigned int>(constant.getFConst()));
}
break;
default:
return false;
}
break;
case EbtBool:
switch (constant.type)
{
case EbtInt:
setBConst(constant.getIConst() != 0);
break;
case EbtUInt:
setBConst(constant.getUConst() != 0);
break;
case EbtBool:
setBConst(constant.getBConst());
break;
case EbtFloat:
setBConst(constant.getFConst() != 0.0f);
break;
default:
return false;
}
break;
case EbtStruct: // Struct fields don't get cast
switch (constant.type)
{
case EbtInt:
setIConst(constant.getIConst());
break;
case EbtUInt:
setUConst(constant.getUConst());
break;
case EbtBool:
setBConst(constant.getBConst());
break;
case EbtFloat:
setFConst(constant.getFConst());
break;
default:
return false;
}
break;
default:
return false;
}
return true;
}
bool TConstantUnion::operator==(const int i) const
{
switch (type)
{
case EbtFloat:
return static_cast<float>(i) == fConst;
default:
return i == iConst;
}
}
bool TConstantUnion::operator==(const unsigned int u) const
{
switch (type)
{
case EbtFloat:
return static_cast<float>(u) == fConst;
default:
return u == uConst;
}
}
bool TConstantUnion::operator==(const float f) const
{
switch (type)
{
case EbtInt:
return f == static_cast<float>(iConst);
case EbtUInt:
return f == static_cast<float>(uConst);
default:
return f == fConst;
}
}
bool TConstantUnion::operator==(const bool b) const
{
return b == bConst;
}
bool TConstantUnion::operator==(const TYuvCscStandardEXT s) const
{
return s == yuvCscStandardEXTConst;
}
bool TConstantUnion::operator==(const TConstantUnion &constant) const
{
ImplicitTypeConversion conversion = GetConversion(constant.type, type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (type)
{
case EbtInt:
return constant.iConst == iConst;
case EbtUInt:
return constant.uConst == uConst;
case EbtFloat:
return constant.fConst == fConst;
case EbtBool:
return constant.bConst == bConst;
case EbtYuvCscStandardEXT:
return constant.yuvCscStandardEXTConst == yuvCscStandardEXTConst;
default:
return false;
}
}
else if (conversion == ImplicitTypeConversion::Invalid)
{
return false;
}
else
{
return constant.getFConst() == getFConst();
}
}
bool TConstantUnion::operator!=(const int i) const
{
return !operator==(i);
}
bool TConstantUnion::operator!=(const unsigned int u) const
{
return !operator==(u);
}
bool TConstantUnion::operator!=(const float f) const
{
return !operator==(f);
}
bool TConstantUnion::operator!=(const bool b) const
{
return !operator==(b);
}
bool TConstantUnion::operator!=(const TYuvCscStandardEXT s) const
{
return !operator==(s);
}
bool TConstantUnion::operator!=(const TConstantUnion &constant) const
{
return !operator==(constant);
}
bool TConstantUnion::operator>(const TConstantUnion &constant) const
{
ImplicitTypeConversion conversion = GetConversion(constant.type, type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (type)
{
case EbtInt:
return iConst > constant.iConst;
case EbtUInt:
return uConst > constant.uConst;
case EbtFloat:
return fConst > constant.fConst;
default:
return false; // Invalid operation, handled at semantic analysis
}
}
else
{
ASSERT(conversion != ImplicitTypeConversion::Invalid);
return getFConst() > constant.getFConst();
}
}
bool TConstantUnion::operator<(const TConstantUnion &constant) const
{
ImplicitTypeConversion conversion = GetConversion(constant.type, type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (type)
{
case EbtInt:
return iConst < constant.iConst;
case EbtUInt:
return uConst < constant.uConst;
case EbtFloat:
return fConst < constant.fConst;
default:
return false; // Invalid operation, handled at semantic analysis
}
}
else
{
ASSERT(conversion != ImplicitTypeConversion::Invalid);
return getFConst() < constant.getFConst();
}
}
// static
TConstantUnion TConstantUnion::add(const TConstantUnion &lhs,
const TConstantUnion &rhs,
TDiagnostics *diag,
const TSourceLoc &line)
{
TConstantUnion returnValue;
ImplicitTypeConversion conversion = GetConversion(lhs.type, rhs.type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (lhs.type)
{
case EbtInt:
returnValue.setIConst(gl::WrappingSum<int>(lhs.iConst, rhs.iConst));
break;
case EbtUInt:
returnValue.setUConst(gl::WrappingSum<unsigned int>(lhs.uConst, rhs.uConst));
break;
case EbtFloat:
returnValue.setFConst(CheckedSum(lhs.fConst, rhs.fConst, diag, line));
break;
default:
UNREACHABLE();
}
}
else
{
ASSERT(conversion != ImplicitTypeConversion::Invalid);
returnValue.setFConst(CheckedSum(lhs.getFConst(), rhs.getFConst(), diag, line));
}
return returnValue;
}
// static
TConstantUnion TConstantUnion::sub(const TConstantUnion &lhs,
const TConstantUnion &rhs,
TDiagnostics *diag,
const TSourceLoc &line)
{
TConstantUnion returnValue;
ImplicitTypeConversion conversion = GetConversion(lhs.type, rhs.type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (lhs.type)
{
case EbtInt:
returnValue.setIConst(gl::WrappingDiff<int>(lhs.iConst, rhs.iConst));
break;
case EbtUInt:
returnValue.setUConst(gl::WrappingDiff<unsigned int>(lhs.uConst, rhs.uConst));
break;
case EbtFloat:
returnValue.setFConst(CheckedDiff(lhs.fConst, rhs.fConst, diag, line));
break;
default:
UNREACHABLE();
}
}
else
{
ASSERT(conversion != ImplicitTypeConversion::Invalid);
returnValue.setFConst(CheckedDiff(lhs.getFConst(), rhs.getFConst(), diag, line));
}
return returnValue;
}
// static
TConstantUnion TConstantUnion::mul(const TConstantUnion &lhs,
const TConstantUnion &rhs,
TDiagnostics *diag,
const TSourceLoc &line)
{
TConstantUnion returnValue;
ImplicitTypeConversion conversion = GetConversion(lhs.type, rhs.type);
if (conversion == ImplicitTypeConversion::Same)
{
switch (lhs.type)
{
case EbtInt:
returnValue.setIConst(gl::WrappingMul(lhs.iConst, rhs.iConst));
break;
case EbtUInt:
// Unsigned integer math in C++ is defined to be done in modulo 2^n, so we rely
// on that to implement wrapping multiplication.
returnValue.setUConst(lhs.uConst * rhs.uConst);
break;
case EbtFloat:
returnValue.setFConst(CheckedMul(lhs.fConst, rhs.fConst, diag, line));
break;
default:
UNREACHABLE();
}
}
else
{
ASSERT(conversion != ImplicitTypeConversion::Invalid);
returnValue.setFConst(CheckedMul(lhs.getFConst(), rhs.getFConst(), diag, line));
}
return returnValue;
}
TConstantUnion TConstantUnion::operator%(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(type == constant.type);
switch (type)
{
case EbtInt:
returnValue.setIConst(iConst % constant.iConst);
break;
case EbtUInt:
returnValue.setUConst(uConst % constant.uConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
// static
TConstantUnion TConstantUnion::rshift(const TConstantUnion &lhs,
const TConstantUnion &rhs,
TDiagnostics *diag,
const TSourceLoc &line)
{
TConstantUnion returnValue;
ASSERT(lhs.type == EbtInt || lhs.type == EbtUInt);
ASSERT(rhs.type == EbtInt || rhs.type == EbtUInt);
if (!IsValidShiftOffset(rhs))
{
diag->warning(line, "Undefined shift (operand out of range)", ">>");
switch (lhs.type)
{
case EbtInt:
returnValue.setIConst(0);
break;
case EbtUInt:
returnValue.setUConst(0u);
break;
default:
UNREACHABLE();
}
return returnValue;
}
switch (lhs.type)
{
case EbtInt:
{
unsigned int shiftOffset = 0;
switch (rhs.type)
{
case EbtInt:
shiftOffset = static_cast<unsigned int>(rhs.iConst);
break;
case EbtUInt:
shiftOffset = rhs.uConst;
break;
default:
UNREACHABLE();
}
if (shiftOffset > 0)
{
// ESSL 3.00.6 section 5.9: "If E1 is a signed integer, the right-shift will extend
// the sign bit." In C++ shifting negative integers is undefined, so we implement
// extending the sign bit manually.
int lhsSafe = lhs.iConst;
if (lhsSafe == std::numeric_limits<int>::min())
{
// The min integer needs special treatment because only bit it has set is the
// sign bit, which we clear later to implement safe right shift of negative
// numbers.
lhsSafe = -0x40000000;
--shiftOffset;
}
if (shiftOffset > 0)
{
bool extendSignBit = false;
if (lhsSafe < 0)
{
extendSignBit = true;
// Clear the sign bit so that bitshift right is defined in C++.
lhsSafe &= 0x7fffffff;
ASSERT(lhsSafe > 0);
}
returnValue.setIConst(lhsSafe >> shiftOffset);
// Manually fill in the extended sign bit if necessary.
if (extendSignBit)
{
int extendedSignBit = static_cast<int>(0xffffffffu << (31 - shiftOffset));
returnValue.setIConst(returnValue.getIConst() | extendedSignBit);
}
}
else
{
returnValue.setIConst(lhsSafe);
}
}
else
{
returnValue.setIConst(lhs.iConst);
}
break;
}
case EbtUInt:
switch (rhs.type)
{
case EbtInt:
returnValue.setUConst(lhs.uConst >> rhs.iConst);
break;
case EbtUInt:
returnValue.setUConst(lhs.uConst >> rhs.uConst);
break;
default:
UNREACHABLE();
}
break;
default:
UNREACHABLE();
}
return returnValue;
}
// static
TConstantUnion TConstantUnion::lshift(const TConstantUnion &lhs,
const TConstantUnion &rhs,
TDiagnostics *diag,
const TSourceLoc &line)
{
TConstantUnion returnValue;
ASSERT(lhs.type == EbtInt || lhs.type == EbtUInt);
ASSERT(rhs.type == EbtInt || rhs.type == EbtUInt);
if (!IsValidShiftOffset(rhs))
{
diag->warning(line, "Undefined shift (operand out of range)", "<<");
switch (lhs.type)
{
case EbtInt:
returnValue.setIConst(0);
break;
case EbtUInt:
returnValue.setUConst(0u);
break;
default:
UNREACHABLE();
}
return returnValue;
}
switch (lhs.type)
{
case EbtInt:
switch (rhs.type)
{
// Cast to unsigned integer before shifting, since ESSL 3.00.6 section 5.9 says that
// lhs is "interpreted as a bit pattern". This also avoids the possibility of signed
// integer overflow or undefined shift of a negative integer.
case EbtInt:
returnValue.setIConst(
static_cast<int>(static_cast<uint32_t>(lhs.iConst) << rhs.iConst));
break;
case EbtUInt:
returnValue.setIConst(
static_cast<int>(static_cast<uint32_t>(lhs.iConst) << rhs.uConst));
break;
default:
UNREACHABLE();
}
break;
case EbtUInt:
switch (rhs.type)
{
case EbtInt:
returnValue.setUConst(lhs.uConst << rhs.iConst);
break;
case EbtUInt:
returnValue.setUConst(lhs.uConst << rhs.uConst);
break;
default:
UNREACHABLE();
}
break;
default:
UNREACHABLE();
}
return returnValue;
}
TConstantUnion TConstantUnion::operator&(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(constant.type == EbtInt || constant.type == EbtUInt);
switch (type)
{
case EbtInt:
returnValue.setIConst(iConst & constant.iConst);
break;
case EbtUInt:
returnValue.setUConst(uConst & constant.uConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
TConstantUnion TConstantUnion::operator|(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(type == constant.type);
switch (type)
{
case EbtInt:
returnValue.setIConst(iConst | constant.iConst);
break;
case EbtUInt:
returnValue.setUConst(uConst | constant.uConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
TConstantUnion TConstantUnion::operator^(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(type == constant.type);
switch (type)
{
case EbtInt:
returnValue.setIConst(iConst ^ constant.iConst);
break;
case EbtUInt:
returnValue.setUConst(uConst ^ constant.uConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
TConstantUnion TConstantUnion::operator&&(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(type == constant.type);
switch (type)
{
case EbtBool:
returnValue.setBConst(bConst && constant.bConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
TConstantUnion TConstantUnion::operator||(const TConstantUnion &constant) const
{
TConstantUnion returnValue;
ASSERT(type == constant.type);
switch (type)
{
case EbtBool:
returnValue.setBConst(bConst || constant.bConst);
break;
default:
UNREACHABLE();
}
return returnValue;
}
} // namespace sh