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cobalt / cobalt / b15365272e6489fad522fda39eabf582f874017d / . / src / third_party / angle / src / compiler / translator / util.cpp
blob: c87b72514cfb2dd4989b25daddb9b46848beaec4 [file] [log] [blame]
//
// Copyright (c) 2010 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.
//
#include "compiler/translator/util.h"
#include <limits>
#include "common/utilities.h"
#include "compiler/preprocessor/numeric_lex.h"
#include "compiler/translator/SymbolTable.h"
bool atoi_clamp(const char *str, unsigned int *value)
{
bool success = pp::numeric_lex_int(str, value);
if (!success)
*value = std::numeric_limits<unsigned int>::max();
return success;
}
namespace sh
{
float NumericLexFloat32OutOfRangeToInfinity(const std::string &str)
{
// Parses a decimal string using scientific notation into a floating point number.
// Out-of-range values are converted to infinity. Values that are too small to be
// represented are converted to zero.
// The mantissa in decimal scientific notation. The magnitude of the mantissa integer does not
// matter.
unsigned int decimalMantissa = 0;
size_t i = 0;
bool decimalPointSeen = false;
bool nonZeroSeenInMantissa = false;
// The exponent offset reflects the position of the decimal point.
int exponentOffset = -1;
while (i < str.length())
{
const char c = str[i];
if (c == 'e' || c == 'E')
{
break;
}
if (c == '.')
{
decimalPointSeen = true;
++i;
continue;
}
unsigned int digit = static_cast<unsigned int>(c - '0');
ASSERT(digit < 10u);
if (digit != 0u)
{
nonZeroSeenInMantissa = true;
}
if (nonZeroSeenInMantissa)
{
// Add bits to the mantissa until space runs out in 32-bit int. This should be
// enough precision to make the resulting binary mantissa accurate to 1 ULP.
if (decimalMantissa <= (std::numeric_limits<unsigned int>::max() - 9u) / 10u)
{
decimalMantissa = decimalMantissa * 10u + digit;
}
if (!decimalPointSeen)
{
++exponentOffset;
}
}
else if (decimalPointSeen)
{
--exponentOffset;
}
++i;
}
if (decimalMantissa == 0)
{
return 0.0f;
}
int exponent = 0;
if (i < str.length())
{
ASSERT(str[i] == 'e' || str[i] == 'E');
++i;
bool exponentOutOfRange = false;
bool negativeExponent = false;
if (str[i] == '-')
{
negativeExponent = true;
++i;
}
else if (str[i] == '+')
{
++i;
}
while (i < str.length())
{
const char c = str[i];
unsigned int digit = static_cast<unsigned int>(c - '0');
ASSERT(digit < 10u);
if (exponent <= (std::numeric_limits<int>::max() - 9) / 10)
{
exponent = exponent * 10 + digit;
}
else
{
exponentOutOfRange = true;
}
++i;
}
if (negativeExponent)
{
exponent = -exponent;
}
if (exponentOutOfRange)
{
if (negativeExponent)
{
return 0.0f;
}
else
{
return std::numeric_limits<float>::infinity();
}
}
}
// Do the calculation in 64-bit to avoid overflow.
long long exponentLong =
static_cast<long long>(exponent) + static_cast<long long>(exponentOffset);
if (exponentLong > std::numeric_limits<float>::max_exponent10)
{
return std::numeric_limits<float>::infinity();
}
else if (exponentLong < std::numeric_limits<float>::min_exponent10)
{
return 0.0f;
}
// The exponent is in range, so we need to actually evaluate the float.
exponent = static_cast<int>(exponentLong);
double value = decimalMantissa;
// Calculate the exponent offset to normalize the mantissa.
int normalizationExponentOffset = 0;
while (decimalMantissa >= 10u)
{
--normalizationExponentOffset;
decimalMantissa /= 10u;
}
// Apply the exponent.
value *= std::pow(10.0, static_cast<double>(exponent + normalizationExponentOffset));
if (value > static_cast<double>(std::numeric_limits<float>::max()))
{
return std::numeric_limits<float>::infinity();
}
if (value < static_cast<double>(std::numeric_limits<float>::min()))
{
return 0.0f;
}
return static_cast<float>(value);
}
bool strtof_clamp(const std::string &str, float *value)
{
// Try the standard float parsing path first.
bool success = pp::numeric_lex_float(str, value);
// If the standard path doesn't succeed, take the path that can handle the following corner
// cases:
// 1. The decimal mantissa is very small but the exponent is very large, putting the resulting
// number inside the float range.
// 2. The decimal mantissa is very large but the exponent is very small, putting the resulting
// number inside the float range.
// 3. The value is out-of-range and should be evaluated as infinity.
// 4. The value is too small and should be evaluated as zero.
// See ESSL 3.00.6 section 4.1.4 for the relevant specification.
if (!success)
*value = NumericLexFloat32OutOfRangeToInfinity(str);
return !gl::isInf(*value);
}
GLenum GLVariableType(const TType &type)
{
if (type.getBasicType() == EbtFloat)
{
if (type.isScalar())
{
return GL_FLOAT;
}
else if (type.isVector())
{
switch (type.getNominalSize())
{
case 2:
return GL_FLOAT_VEC2;
case 3:
return GL_FLOAT_VEC3;
case 4:
return GL_FLOAT_VEC4;
default:
UNREACHABLE();
}
}
else if (type.isMatrix())
{
switch (type.getCols())
{
case 2:
switch (type.getRows())
{
case 2:
return GL_FLOAT_MAT2;
case 3:
return GL_FLOAT_MAT2x3;
case 4:
return GL_FLOAT_MAT2x4;
default:
UNREACHABLE();
}
case 3:
switch (type.getRows())
{
case 2:
return GL_FLOAT_MAT3x2;
case 3:
return GL_FLOAT_MAT3;
case 4:
return GL_FLOAT_MAT3x4;
default:
UNREACHABLE();
}
case 4:
switch (type.getRows())
{
case 2:
return GL_FLOAT_MAT4x2;
case 3:
return GL_FLOAT_MAT4x3;
case 4:
return GL_FLOAT_MAT4;
default:
UNREACHABLE();
}
default:
UNREACHABLE();
}
}
else
UNREACHABLE();
}
else if (type.getBasicType() == EbtInt)
{
if (type.isScalar())
{
return GL_INT;
}
else if (type.isVector())
{
switch (type.getNominalSize())
{
case 2:
return GL_INT_VEC2;
case 3:
return GL_INT_VEC3;
case 4:
return GL_INT_VEC4;
default:
UNREACHABLE();
}
}
else
UNREACHABLE();
}
else if (type.getBasicType() == EbtUInt)
{
if (type.isScalar())
{
return GL_UNSIGNED_INT;
}
else if (type.isVector())
{
switch (type.getNominalSize())
{
case 2:
return GL_UNSIGNED_INT_VEC2;
case 3:
return GL_UNSIGNED_INT_VEC3;
case 4:
return GL_UNSIGNED_INT_VEC4;
default:
UNREACHABLE();
}
}
else
UNREACHABLE();
}
else if (type.getBasicType() == EbtBool)
{
if (type.isScalar())
{
return GL_BOOL;
}
else if (type.isVector())
{
switch (type.getNominalSize())
{
case 2:
return GL_BOOL_VEC2;
case 3:
return GL_BOOL_VEC3;
case 4:
return GL_BOOL_VEC4;
default:
UNREACHABLE();
}
}
else
UNREACHABLE();
}
switch (type.getBasicType())
{
case EbtSampler2D:
return GL_SAMPLER_2D;
case EbtSampler3D:
return GL_SAMPLER_3D;
case EbtSamplerCube:
return GL_SAMPLER_CUBE;
case EbtSamplerExternalOES:
return GL_SAMPLER_EXTERNAL_OES;
case EbtSamplerExternal2DY2YEXT:
return GL_SAMPLER_EXTERNAL_2D_Y2Y_EXT;
case EbtSampler2DRect:
return GL_SAMPLER_2D_RECT_ARB;
case EbtSampler2DArray:
return GL_SAMPLER_2D_ARRAY;
case EbtSampler2DMS:
return GL_SAMPLER_2D_MULTISAMPLE;
case EbtISampler2D:
return GL_INT_SAMPLER_2D;
case EbtISampler3D:
return GL_INT_SAMPLER_3D;
case EbtISamplerCube:
return GL_INT_SAMPLER_CUBE;
case EbtISampler2DArray:
return GL_INT_SAMPLER_2D_ARRAY;
case EbtISampler2DMS:
return GL_INT_SAMPLER_2D_MULTISAMPLE;
case EbtUSampler2D:
return GL_UNSIGNED_INT_SAMPLER_2D;
case EbtUSampler3D:
return GL_UNSIGNED_INT_SAMPLER_3D;
case EbtUSamplerCube:
return GL_UNSIGNED_INT_SAMPLER_CUBE;
case EbtUSampler2DArray:
return GL_UNSIGNED_INT_SAMPLER_2D_ARRAY;
case EbtUSampler2DMS:
return GL_UNSIGNED_INT_SAMPLER_2D_MULTISAMPLE;
case EbtSampler2DShadow:
return GL_SAMPLER_2D_SHADOW;
case EbtSamplerCubeShadow:
return GL_SAMPLER_CUBE_SHADOW;
case EbtSampler2DArrayShadow:
return GL_SAMPLER_2D_ARRAY_SHADOW;
case EbtImage2D:
return GL_IMAGE_2D;
case EbtIImage2D:
return GL_INT_IMAGE_2D;
case EbtUImage2D:
return GL_UNSIGNED_INT_IMAGE_2D;
case EbtImage2DArray:
return GL_IMAGE_2D_ARRAY;
case EbtIImage2DArray:
return GL_INT_IMAGE_2D_ARRAY;
case EbtUImage2DArray:
return GL_UNSIGNED_INT_IMAGE_2D_ARRAY;
case EbtImage3D:
return GL_IMAGE_3D;
case EbtIImage3D:
return GL_INT_IMAGE_3D;
case EbtUImage3D:
return GL_UNSIGNED_INT_IMAGE_3D;
case EbtImageCube:
return GL_IMAGE_CUBE;
case EbtIImageCube:
return GL_INT_IMAGE_CUBE;
case EbtUImageCube:
return GL_UNSIGNED_INT_IMAGE_CUBE;
default:
UNREACHABLE();
}
return GL_NONE;
}
GLenum GLVariablePrecision(const TType &type)
{
if (type.getBasicType() == EbtFloat)
{
switch (type.getPrecision())
{
case EbpHigh:
return GL_HIGH_FLOAT;
case EbpMedium:
return GL_MEDIUM_FLOAT;
case EbpLow:
return GL_LOW_FLOAT;
case EbpUndefined:
// Should be defined as the default precision by the parser
default:
UNREACHABLE();
}
}
else if (type.getBasicType() == EbtInt || type.getBasicType() == EbtUInt)
{
switch (type.getPrecision())
{
case EbpHigh:
return GL_HIGH_INT;
case EbpMedium:
return GL_MEDIUM_INT;
case EbpLow:
return GL_LOW_INT;
case EbpUndefined:
// Should be defined as the default precision by the parser
default:
UNREACHABLE();
}
}
// Other types (boolean, sampler) don't have a precision
return GL_NONE;
}
TString ArrayString(const TType &type)
{
if (!type.isArray())
{
return "";
}
return "[" + str(type.getArraySize()) + "]";
}
bool IsVaryingOut(TQualifier qualifier)
{
switch (qualifier)
{
case EvqVaryingOut:
case EvqSmoothOut:
case EvqFlatOut:
case EvqCentroidOut:
case EvqVertexOut:
return true;
default:
break;
}
return false;
}
bool IsVaryingIn(TQualifier qualifier)
{
switch (qualifier)
{
case EvqVaryingIn:
case EvqSmoothIn:
case EvqFlatIn:
case EvqCentroidIn:
case EvqFragmentIn:
return true;
default:
break;
}
return false;
}
bool IsVarying(TQualifier qualifier)
{
return IsVaryingIn(qualifier) || IsVaryingOut(qualifier);
}
InterpolationType GetInterpolationType(TQualifier qualifier)
{
switch (qualifier)
{
case EvqFlatIn:
case EvqFlatOut:
return INTERPOLATION_FLAT;
case EvqSmoothIn:
case EvqSmoothOut:
case EvqVertexOut:
case EvqFragmentIn:
case EvqVaryingIn:
case EvqVaryingOut:
return INTERPOLATION_SMOOTH;
case EvqCentroidIn:
case EvqCentroidOut:
return INTERPOLATION_CENTROID;
default:
UNREACHABLE();
return INTERPOLATION_SMOOTH;
}
}
TType GetShaderVariableBasicType(const sh::ShaderVariable &var)
{
switch (var.type)
{
case GL_BOOL:
return TType(EbtBool);
case GL_BOOL_VEC2:
return TType(EbtBool, 2);
case GL_BOOL_VEC3:
return TType(EbtBool, 3);
case GL_BOOL_VEC4:
return TType(EbtBool, 4);
case GL_FLOAT:
return TType(EbtFloat);
case GL_FLOAT_VEC2:
return TType(EbtFloat, 2);
case GL_FLOAT_VEC3:
return TType(EbtFloat, 3);
case GL_FLOAT_VEC4:
return TType(EbtFloat, 4);
case GL_FLOAT_MAT2:
return TType(EbtFloat, 2, 2);
case GL_FLOAT_MAT3:
return TType(EbtFloat, 3, 3);
case GL_FLOAT_MAT4:
return TType(EbtFloat, 4, 4);
case GL_FLOAT_MAT2x3:
return TType(EbtFloat, 2, 3);
case GL_FLOAT_MAT2x4:
return TType(EbtFloat, 2, 4);
case GL_FLOAT_MAT3x2:
return TType(EbtFloat, 3, 2);
case GL_FLOAT_MAT3x4:
return TType(EbtFloat, 3, 4);
case GL_FLOAT_MAT4x2:
return TType(EbtFloat, 4, 2);
case GL_FLOAT_MAT4x3:
return TType(EbtFloat, 4, 3);
case GL_INT:
return TType(EbtInt);
case GL_INT_VEC2:
return TType(EbtInt, 2);
case GL_INT_VEC3:
return TType(EbtInt, 3);
case GL_INT_VEC4:
return TType(EbtInt, 4);
case GL_UNSIGNED_INT:
return TType(EbtUInt);
case GL_UNSIGNED_INT_VEC2:
return TType(EbtUInt, 2);
case GL_UNSIGNED_INT_VEC3:
return TType(EbtUInt, 3);
case GL_UNSIGNED_INT_VEC4:
return TType(EbtUInt, 4);
default:
UNREACHABLE();
return TType();
}
}
// GLSL ES 1.0.17 4.6.1 The Invariant Qualifier
bool CanBeInvariantESSL1(TQualifier qualifier)
{
return IsVaryingIn(qualifier) || IsVaryingOut(qualifier) ||
IsBuiltinOutputVariable(qualifier) ||
(IsBuiltinFragmentInputVariable(qualifier) && qualifier != EvqFrontFacing);
}
// GLSL ES 3.00 Revision 6, 4.6.1 The Invariant Qualifier
// GLSL ES 3.10 Revision 4, 4.8.1 The Invariant Qualifier
bool CanBeInvariantESSL3OrGreater(TQualifier qualifier)
{
return IsVaryingOut(qualifier) || qualifier == EvqFragmentOut ||
IsBuiltinOutputVariable(qualifier);
}
bool IsBuiltinOutputVariable(TQualifier qualifier)
{
switch (qualifier)
{
case EvqPosition:
case EvqPointSize:
case EvqFragDepth:
case EvqFragDepthEXT:
case EvqFragColor:
case EvqSecondaryFragColorEXT:
case EvqFragData:
case EvqSecondaryFragDataEXT:
return true;
default:
break;
}
return false;
}
bool IsBuiltinFragmentInputVariable(TQualifier qualifier)
{
switch (qualifier)
{
case EvqFragCoord:
case EvqPointCoord:
case EvqFrontFacing:
return true;
default:
break;
}
return false;
}
} // namespace sh