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|
//
// Copyright (c) 2002-2013 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.
//
// mathutil.h: Math and bit manipulation functions.
#ifndef COMMON_MATHUTIL_H_
#define COMMON_MATHUTIL_H_
#include <limits>
#include <algorithm>
#include <math.h>
#include <string.h>
#include <stdint.h>
#include <stdlib.h>
#include <base/numerics/safe_math.h>
#include "common/debug.h"
#include "common/platform.h"
namespace angle
{
using base::CheckedNumeric;
using base::IsValueInRangeForNumericType;
}
namespace gl
{
const unsigned int Float32One = 0x3F800000;
const unsigned short Float16One = 0x3C00;
struct Vector4
{
Vector4() {}
Vector4(float x, float y, float z, float w) : x(x), y(y), z(z), w(w) {}
float x;
float y;
float z;
float w;
};
inline bool isPow2(int x)
{
return (x & (x - 1)) == 0 && (x != 0);
}
inline int log2(int x)
{
int r = 0;
while ((x >> r) > 1) r++;
return r;
}
inline unsigned int ceilPow2(unsigned int x)
{
if (x != 0) x--;
x |= x >> 1;
x |= x >> 2;
x |= x >> 4;
x |= x >> 8;
x |= x >> 16;
x++;
return x;
}
inline int clampToInt(unsigned int x)
{
return static_cast<int>(std::min(x, static_cast<unsigned int>(std::numeric_limits<int>::max())));
}
template <typename DestT, typename SrcT>
inline DestT clampCast(SrcT value)
{
static const DestT destLo = std::numeric_limits<DestT>::min();
static const DestT destHi = std::numeric_limits<DestT>::max();
static const SrcT srcLo = static_cast<SrcT>(destLo);
static const SrcT srcHi = static_cast<SrcT>(destHi);
// When value is outside of or equal to the limits for DestT we use the DestT limit directly.
// This avoids undefined behaviors due to loss of precision when converting from floats to
// integers:
// destHi for ints is 2147483647 but the closest float number is around 2147483648, so when
// doing a conversion from float to int we run into an UB because the float is outside of the
// range representable by the int.
if (value <= srcLo)
{
return destLo;
}
else if (value >= srcHi)
{
return destHi;
}
else
{
return static_cast<DestT>(value);
}
}
template<typename T, typename MIN, typename MAX>
inline T clamp(T x, MIN min, MAX max)
{
// Since NaNs fail all comparison tests, a NaN value will default to min
return x > min ? (x > max ? max : x) : min;
}
inline float clamp01(float x)
{
return clamp(x, 0.0f, 1.0f);
}
template<const int n>
inline unsigned int unorm(float x)
{
const unsigned int max = 0xFFFFFFFF >> (32 - n);
if (x > 1)
{
return max;
}
else if (x < 0)
{
return 0;
}
else
{
return (unsigned int)(max * x + 0.5f);
}
}
inline bool supportsSSE2()
{
#if defined(ANGLE_USE_SSE)
static bool checked = false;
static bool supports = false;
if (checked)
{
return supports;
}
#if defined(ANGLE_PLATFORM_WINDOWS) && !defined(_M_ARM)
{
int info[4];
__cpuid(info, 0);
if (info[0] >= 1)
{
__cpuid(info, 1);
supports = (info[3] >> 26) & 1;
}
}
#endif // defined(ANGLE_PLATFORM_WINDOWS) && !defined(_M_ARM)
checked = true;
return supports;
#else // defined(ANGLE_USE_SSE)
return false;
#endif
}
template <typename destType, typename sourceType>
destType bitCast(const sourceType &source)
{
size_t copySize = std::min(sizeof(destType), sizeof(sourceType));
destType output;
memcpy(&output, &source, copySize);
return output;
}
inline unsigned short float32ToFloat16(float fp32)
{
unsigned int fp32i = bitCast<unsigned int>(fp32);
unsigned int sign = (fp32i & 0x80000000) >> 16;
unsigned int abs = fp32i & 0x7FFFFFFF;
if(abs > 0x47FFEFFF) // Infinity
{
return static_cast<unsigned short>(sign | 0x7FFF);
}
else if(abs < 0x38800000) // Denormal
{
unsigned int mantissa = (abs & 0x007FFFFF) | 0x00800000;
int e = 113 - (abs >> 23);
if(e < 24)
{
abs = mantissa >> e;
}
else
{
abs = 0;
}
return static_cast<unsigned short>(sign | (abs + 0x00000FFF + ((abs >> 13) & 1)) >> 13);
}
else
{
return static_cast<unsigned short>(sign | (abs + 0xC8000000 + 0x00000FFF + ((abs >> 13) & 1)) >> 13);
}
}
float float16ToFloat32(unsigned short h);
unsigned int convertRGBFloatsTo999E5(float red, float green, float blue);
void convert999E5toRGBFloats(unsigned int input, float *red, float *green, float *blue);
inline unsigned short float32ToFloat11(float fp32)
{
const unsigned int float32MantissaMask = 0x7FFFFF;
const unsigned int float32ExponentMask = 0x7F800000;
const unsigned int float32SignMask = 0x80000000;
const unsigned int float32ValueMask = ~float32SignMask;
const unsigned int float32ExponentFirstBit = 23;
const unsigned int float32ExponentBias = 127;
const unsigned short float11Max = 0x7BF;
const unsigned short float11MantissaMask = 0x3F;
const unsigned short float11ExponentMask = 0x7C0;
const unsigned short float11BitMask = 0x7FF;
const unsigned int float11ExponentBias = 14;
const unsigned int float32Maxfloat11 = 0x477E0000;
const unsigned int float32Minfloat11 = 0x38800000;
const unsigned int float32Bits = bitCast<unsigned int>(fp32);
const bool float32Sign = (float32Bits & float32SignMask) == float32SignMask;
unsigned int float32Val = float32Bits & float32ValueMask;
if ((float32Val & float32ExponentMask) == float32ExponentMask)
{
// INF or NAN
if ((float32Val & float32MantissaMask) != 0)
{
return float11ExponentMask | (((float32Val >> 17) | (float32Val >> 11) | (float32Val >> 6) | (float32Val)) & float11MantissaMask);
}
else if (float32Sign)
{
// -INF is clamped to 0 since float11 is positive only
return 0;
}
else
{
return float11ExponentMask;
}
}
else if (float32Sign)
{
// float11 is positive only, so clamp to zero
return 0;
}
else if (float32Val > float32Maxfloat11)
{
// The number is too large to be represented as a float11, set to max
return float11Max;
}
else
{
if (float32Val < float32Minfloat11)
{
// The number is too small to be represented as a normalized float11
// Convert it to a denormalized value.
const unsigned int shift = (float32ExponentBias - float11ExponentBias) - (float32Val >> float32ExponentFirstBit);
float32Val = ((1 << float32ExponentFirstBit) | (float32Val & float32MantissaMask)) >> shift;
}
else
{
// Rebias the exponent to represent the value as a normalized float11
float32Val += 0xC8000000;
}
return ((float32Val + 0xFFFF + ((float32Val >> 17) & 1)) >> 17) & float11BitMask;
}
}
inline unsigned short float32ToFloat10(float fp32)
{
const unsigned int float32MantissaMask = 0x7FFFFF;
const unsigned int float32ExponentMask = 0x7F800000;
const unsigned int float32SignMask = 0x80000000;
const unsigned int float32ValueMask = ~float32SignMask;
const unsigned int float32ExponentFirstBit = 23;
const unsigned int float32ExponentBias = 127;
const unsigned short float10Max = 0x3DF;
const unsigned short float10MantissaMask = 0x1F;
const unsigned short float10ExponentMask = 0x3E0;
const unsigned short float10BitMask = 0x3FF;
const unsigned int float10ExponentBias = 14;
const unsigned int float32Maxfloat10 = 0x477C0000;
const unsigned int float32Minfloat10 = 0x38800000;
const unsigned int float32Bits = bitCast<unsigned int>(fp32);
const bool float32Sign = (float32Bits & float32SignMask) == float32SignMask;
unsigned int float32Val = float32Bits & float32ValueMask;
if ((float32Val & float32ExponentMask) == float32ExponentMask)
{
// INF or NAN
if ((float32Val & float32MantissaMask) != 0)
{
return float10ExponentMask | (((float32Val >> 18) | (float32Val >> 13) | (float32Val >> 3) | (float32Val)) & float10MantissaMask);
}
else if (float32Sign)
{
// -INF is clamped to 0 since float11 is positive only
return 0;
}
else
{
return float10ExponentMask;
}
}
else if (float32Sign)
{
// float10 is positive only, so clamp to zero
return 0;
}
else if (float32Val > float32Maxfloat10)
{
// The number is too large to be represented as a float11, set to max
return float10Max;
}
else
{
if (float32Val < float32Minfloat10)
{
// The number is too small to be represented as a normalized float11
// Convert it to a denormalized value.
const unsigned int shift = (float32ExponentBias - float10ExponentBias) - (float32Val >> float32ExponentFirstBit);
float32Val = ((1 << float32ExponentFirstBit) | (float32Val & float32MantissaMask)) >> shift;
}
else
{
// Rebias the exponent to represent the value as a normalized float11
float32Val += 0xC8000000;
}
return ((float32Val + 0x1FFFF + ((float32Val >> 18) & 1)) >> 18) & float10BitMask;
}
}
inline float float11ToFloat32(unsigned short fp11)
{
unsigned short exponent = (fp11 >> 6) & 0x1F;
unsigned short mantissa = fp11 & 0x3F;
if (exponent == 0x1F)
{
// INF or NAN
return bitCast<float>(0x7f800000 | (mantissa << 17));
}
else
{
if (exponent != 0)
{
// normalized
}
else if (mantissa != 0)
{
// The value is denormalized
exponent = 1;
do
{
exponent--;
mantissa <<= 1;
}
while ((mantissa & 0x40) == 0);
mantissa = mantissa & 0x3F;
}
else // The value is zero
{
exponent = static_cast<unsigned short>(-112);
}
return bitCast<float>(((exponent + 112) << 23) | (mantissa << 17));
}
}
inline float float10ToFloat32(unsigned short fp11)
{
unsigned short exponent = (fp11 >> 5) & 0x1F;
unsigned short mantissa = fp11 & 0x1F;
if (exponent == 0x1F)
{
// INF or NAN
return bitCast<float>(0x7f800000 | (mantissa << 17));
}
else
{
if (exponent != 0)
{
// normalized
}
else if (mantissa != 0)
{
// The value is denormalized
exponent = 1;
do
{
exponent--;
mantissa <<= 1;
}
while ((mantissa & 0x20) == 0);
mantissa = mantissa & 0x1F;
}
else // The value is zero
{
exponent = static_cast<unsigned short>(-112);
}
return bitCast<float>(((exponent + 112) << 23) | (mantissa << 18));
}
}
template <typename T>
inline float normalizedToFloat(T input)
{
static_assert(std::numeric_limits<T>::is_integer, "T must be an integer.");
const float inverseMax = 1.0f / std::numeric_limits<T>::max();
return input * inverseMax;
}
template <unsigned int inputBitCount, typename T>
inline float normalizedToFloat(T input)
{
static_assert(std::numeric_limits<T>::is_integer, "T must be an integer.");
static_assert(inputBitCount < (sizeof(T) * 8), "T must have more bits than inputBitCount.");
const float inverseMax = 1.0f / ((1 << inputBitCount) - 1);
return input * inverseMax;
}
template <typename T>
inline T floatToNormalized(float input)
{
return static_cast<T>(std::numeric_limits<T>::max() * input + 0.5f);
}
template <unsigned int outputBitCount, typename T>
inline T floatToNormalized(float input)
{
static_assert(outputBitCount < (sizeof(T) * 8), "T must have more bits than outputBitCount.");
return static_cast<T>(((1 << outputBitCount) - 1) * input + 0.5f);
}
template <unsigned int inputBitCount, unsigned int inputBitStart, typename T>
inline T getShiftedData(T input)
{
static_assert(inputBitCount + inputBitStart <= (sizeof(T) * 8),
"T must have at least as many bits as inputBitCount + inputBitStart.");
const T mask = (1 << inputBitCount) - 1;
return (input >> inputBitStart) & mask;
}
template <unsigned int inputBitCount, unsigned int inputBitStart, typename T>
inline T shiftData(T input)
{
static_assert(inputBitCount + inputBitStart <= (sizeof(T) * 8),
"T must have at least as many bits as inputBitCount + inputBitStart.");
const T mask = (1 << inputBitCount) - 1;
return (input & mask) << inputBitStart;
}
inline unsigned int CountLeadingZeros(uint32_t x)
{
// Use binary search to find the amount of leading zeros.
unsigned int zeros = 32u;
uint32_t y;
y = x >> 16u;
if (y != 0)
{
zeros = zeros - 16u;
x = y;
}
y = x >> 8u;
if (y != 0)
{
zeros = zeros - 8u;
x = y;
}
y = x >> 4u;
if (y != 0)
{
zeros = zeros - 4u;
x = y;
}
y = x >> 2u;
if (y != 0)
{
zeros = zeros - 2u;
x = y;
}
y = x >> 1u;
if (y != 0)
{
return zeros - 2u;
}
return zeros - x;
}
inline unsigned char average(unsigned char a, unsigned char b)
{
return ((a ^ b) >> 1) + (a & b);
}
inline signed char average(signed char a, signed char b)
{
return ((short)a + (short)b) / 2;
}
inline unsigned short average(unsigned short a, unsigned short b)
{
return ((a ^ b) >> 1) + (a & b);
}
inline signed short average(signed short a, signed short b)
{
return ((int)a + (int)b) / 2;
}
inline unsigned int average(unsigned int a, unsigned int b)
{
return ((a ^ b) >> 1) + (a & b);
}
inline int average(int a, int b)
{
long long average = (static_cast<long long>(a) + static_cast<long long>(b)) / 2ll;
return static_cast<int>(average);
}
inline float average(float a, float b)
{
return (a + b) * 0.5f;
}
inline unsigned short averageHalfFloat(unsigned short a, unsigned short b)
{
return float32ToFloat16((float16ToFloat32(a) + float16ToFloat32(b)) * 0.5f);
}
inline unsigned int averageFloat11(unsigned int a, unsigned int b)
{
return float32ToFloat11((float11ToFloat32(static_cast<unsigned short>(a)) + float11ToFloat32(static_cast<unsigned short>(b))) * 0.5f);
}
inline unsigned int averageFloat10(unsigned int a, unsigned int b)
{
return float32ToFloat10((float10ToFloat32(static_cast<unsigned short>(a)) + float10ToFloat32(static_cast<unsigned short>(b))) * 0.5f);
}
template <typename T>
struct Range
{
Range() {}
Range(T lo, T hi) : start(lo), end(hi) { ASSERT(lo <= hi); }
T start;
T end;
T length() const { return end - start; }
bool intersects(Range<T> other)
{
if (start <= other.start)
{
return other.start < end;
}
else
{
return start < other.end;
}
}
void extend(T value)
{
start = value > start ? value : start;
end = value < end ? value : end;
}
bool empty() const
{
return end <= start;
}
};
typedef Range<int> RangeI;
typedef Range<unsigned int> RangeUI;
struct IndexRange
{
IndexRange() : IndexRange(0, 0, 0) {}
IndexRange(size_t start_, size_t end_, size_t vertexIndexCount_)
: start(start_), end(end_), vertexIndexCount(vertexIndexCount_)
{
ASSERT(start <= end);
}
// Number of vertices in the range.
size_t vertexCount() const { return (end - start) + 1; }
// Inclusive range of indices that are not primitive restart
size_t start;
size_t end;
// Number of non-primitive restart indices
size_t vertexIndexCount;
};
// First, both normalized floating-point values are converted into 16-bit integer values.
// Then, the results are packed into the returned 32-bit unsigned integer.
// The first float value will be written to the least significant bits of the output;
// the last float value will be written to the most significant bits.
// The conversion of each value to fixed point is done as follows :
// packSnorm2x16 : round(clamp(c, -1, +1) * 32767.0)
inline uint32_t packSnorm2x16(float f1, float f2)
{
int16_t leastSignificantBits = static_cast<int16_t>(roundf(clamp(f1, -1.0f, 1.0f) * 32767.0f));
int16_t mostSignificantBits = static_cast<int16_t>(roundf(clamp(f2, -1.0f, 1.0f) * 32767.0f));
return static_cast<uint32_t>(mostSignificantBits) << 16 |
(static_cast<uint32_t>(leastSignificantBits) & 0xFFFF);
}
// First, unpacks a single 32-bit unsigned integer u into a pair of 16-bit unsigned integers. Then, each
// component is converted to a normalized floating-point value to generate the returned two float values.
// The first float value will be extracted from the least significant bits of the input;
// the last float value will be extracted from the most-significant bits.
// The conversion for unpacked fixed-point value to floating point is done as follows:
// unpackSnorm2x16 : clamp(f / 32767.0, -1, +1)
inline void unpackSnorm2x16(uint32_t u, float *f1, float *f2)
{
int16_t leastSignificantBits = static_cast<int16_t>(u & 0xFFFF);
int16_t mostSignificantBits = static_cast<int16_t>(u >> 16);
*f1 = clamp(static_cast<float>(leastSignificantBits) / 32767.0f, -1.0f, 1.0f);
*f2 = clamp(static_cast<float>(mostSignificantBits) / 32767.0f, -1.0f, 1.0f);
}
// First, both normalized floating-point values are converted into 16-bit integer values.
// Then, the results are packed into the returned 32-bit unsigned integer.
// The first float value will be written to the least significant bits of the output;
// the last float value will be written to the most significant bits.
// The conversion of each value to fixed point is done as follows:
// packUnorm2x16 : round(clamp(c, 0, +1) * 65535.0)
inline uint32_t packUnorm2x16(float f1, float f2)
{
uint16_t leastSignificantBits = static_cast<uint16_t>(roundf(clamp(f1, 0.0f, 1.0f) * 65535.0f));
uint16_t mostSignificantBits = static_cast<uint16_t>(roundf(clamp(f2, 0.0f, 1.0f) * 65535.0f));
return static_cast<uint32_t>(mostSignificantBits) << 16 | static_cast<uint32_t>(leastSignificantBits);
}
// First, unpacks a single 32-bit unsigned integer u into a pair of 16-bit unsigned integers. Then, each
// component is converted to a normalized floating-point value to generate the returned two float values.
// The first float value will be extracted from the least significant bits of the input;
// the last float value will be extracted from the most-significant bits.
// The conversion for unpacked fixed-point value to floating point is done as follows:
// unpackUnorm2x16 : f / 65535.0
inline void unpackUnorm2x16(uint32_t u, float *f1, float *f2)
{
uint16_t leastSignificantBits = static_cast<uint16_t>(u & 0xFFFF);
uint16_t mostSignificantBits = static_cast<uint16_t>(u >> 16);
*f1 = static_cast<float>(leastSignificantBits) / 65535.0f;
*f2 = static_cast<float>(mostSignificantBits) / 65535.0f;
}
// Returns an unsigned integer obtained by converting the two floating-point values to the 16-bit
// floating-point representation found in the OpenGL ES Specification, and then packing these
// two 16-bit integers into a 32-bit unsigned integer.
// f1: The 16 least-significant bits of the result;
// f2: The 16 most-significant bits.
inline uint32_t packHalf2x16(float f1, float f2)
{
uint16_t leastSignificantBits = static_cast<uint16_t>(float32ToFloat16(f1));
uint16_t mostSignificantBits = static_cast<uint16_t>(float32ToFloat16(f2));
return static_cast<uint32_t>(mostSignificantBits) << 16 | static_cast<uint32_t>(leastSignificantBits);
}
// Returns two floating-point values obtained by unpacking a 32-bit unsigned integer into a pair of 16-bit values,
// interpreting those values as 16-bit floating-point numbers according to the OpenGL ES Specification,
// and converting them to 32-bit floating-point values.
// The first float value is obtained from the 16 least-significant bits of u;
// the second component is obtained from the 16 most-significant bits of u.
inline void unpackHalf2x16(uint32_t u, float *f1, float *f2)
{
uint16_t leastSignificantBits = static_cast<uint16_t>(u & 0xFFFF);
uint16_t mostSignificantBits = static_cast<uint16_t>(u >> 16);
*f1 = float16ToFloat32(leastSignificantBits);
*f2 = float16ToFloat32(mostSignificantBits);
}
// Returns whether the argument is Not a Number.
// IEEE 754 single precision NaN representation: Exponent(8 bits) - 255, Mantissa(23 bits) - non-zero.
inline bool isNaN(float f)
{
// Exponent mask: ((1u << 8) - 1u) << 23 = 0x7f800000u
// Mantissa mask: ((1u << 23) - 1u) = 0x7fffffu
return ((bitCast<uint32_t>(f) & 0x7f800000u) == 0x7f800000u) && (bitCast<uint32_t>(f) & 0x7fffffu);
}
// Returns whether the argument is infinity.
// IEEE 754 single precision infinity representation: Exponent(8 bits) - 255, Mantissa(23 bits) - zero.
inline bool isInf(float f)
{
// Exponent mask: ((1u << 8) - 1u) << 23 = 0x7f800000u
// Mantissa mask: ((1u << 23) - 1u) = 0x7fffffu
return ((bitCast<uint32_t>(f) & 0x7f800000u) == 0x7f800000u) && !(bitCast<uint32_t>(f) & 0x7fffffu);
}
namespace priv
{
template <unsigned int N, unsigned int R>
struct iSquareRoot
{
static constexpr unsigned int solve()
{
return (R * R > N)
? 0
: ((R * R == N) ? R : static_cast<unsigned int>(iSquareRoot<N, R + 1>::value));
}
enum Result
{
value = iSquareRoot::solve()
};
};
template <unsigned int N>
struct iSquareRoot<N, N>
{
enum result
{
value = N
};
};
} // namespace priv
template <unsigned int N>
constexpr unsigned int iSquareRoot()
{
return priv::iSquareRoot<N, 1>::value;
}
} // namespace gl
namespace rx
{
template <typename T>
T roundUp(const T value, const T alignment)
{
auto temp = value + alignment - static_cast<T>(1);
return temp - temp % alignment;
}
template <typename T>
angle::CheckedNumeric<T> CheckedRoundUp(const T value, const T alignment)
{
angle::CheckedNumeric<T> checkedValue(value);
angle::CheckedNumeric<T> checkedAlignment(alignment);
return roundUp(checkedValue, checkedAlignment);
}
inline unsigned int UnsignedCeilDivide(unsigned int value, unsigned int divisor)
{
unsigned int divided = value / divisor;
return (divided + ((value % divisor == 0) ? 0 : 1));
}
#if defined(_MSC_VER)
#define ANGLE_ROTL(x,y) _rotl(x,y)
#define ANGLE_ROTR16(x,y) _rotr16(x,y)
#else
inline uint32_t RotL(uint32_t x, int8_t r)
{
return (x << r) | (x >> (32 - r));
}
inline uint16_t RotR16(uint16_t x, int8_t r)
{
return (x >> r) | (x << (16 - r));
}
#define ANGLE_ROTL(x, y) ::rx::RotL(x, y)
#define ANGLE_ROTR16(x, y) ::rx::RotR16(x, y)
#endif // namespace rx
}
#endif // COMMON_MATHUTIL_H_
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