virtualx-engine/thirdparty/astcenc/astcenc_vecmathlib_none_4.h

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// SPDX-License-Identifier: Apache-2.0
// ----------------------------------------------------------------------------
// Copyright 2019-2023 Arm Limited
//
// 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.
// ----------------------------------------------------------------------------
/**
* @brief 4x32-bit vectors, implemented using plain C++.
*
* This module implements 4-wide 32-bit float, int, and mask vectors. This
* module provides a scalar fallback for VLA code, primarily useful for
* debugging VLA algorithms without the complexity of handling SIMD. Only the
* baseline level of functionality needed to support VLA is provided.
*
* Note that the vector conditional operators implemented by this module are
* designed to behave like SIMD conditional operators that generate lane masks.
* Rather than returning 0/1 booleans like normal C++ code they will return
* 0/-1 to give a full lane-width bitmask.
*
* Note that the documentation for this module still talks about "vectors" to
* help developers think about the implied VLA behavior when writing optimized
* paths.
*/
#ifndef ASTC_VECMATHLIB_NONE_4_H_INCLUDED
#define ASTC_VECMATHLIB_NONE_4_H_INCLUDED
#ifndef ASTCENC_SIMD_INLINE
#error "Include astcenc_vecmathlib.h, do not include directly"
#endif
#include <algorithm>
#include <cstdio>
#include <cstring>
#include <cfenv>
// ============================================================================
// vfloat4 data type
// ============================================================================
/**
* @brief Data type for 4-wide floats.
*/
struct vfloat4
{
/**
* @brief Construct from zero-initialized value.
*/
ASTCENC_SIMD_INLINE vfloat4() = default;
/**
* @brief Construct from 4 values loaded from an unaligned address.
*
* Consider using loada() which is better with wider VLA vectors if data is
* aligned to vector length.
*/
ASTCENC_SIMD_INLINE explicit vfloat4(const float* p)
{
m[0] = p[0];
m[1] = p[1];
m[2] = p[2];
m[3] = p[3];
}
/**
* @brief Construct from 4 scalar values replicated across all lanes.
*
* Consider using zero() for constexpr zeros.
*/
ASTCENC_SIMD_INLINE explicit vfloat4(float a)
{
m[0] = a;
m[1] = a;
m[2] = a;
m[3] = a;
}
/**
* @brief Construct from 4 scalar values.
*
* The value of @c a is stored to lane 0 (LSB) in the SIMD register.
*/
ASTCENC_SIMD_INLINE explicit vfloat4(float a, float b, float c, float d)
{
m[0] = a;
m[1] = b;
m[2] = c;
m[3] = d;
}
/**
* @brief Get the scalar value of a single lane.
*/
template <int l> ASTCENC_SIMD_INLINE float lane() const
{
return m[l];
}
/**
* @brief Set the scalar value of a single lane.
*/
template <int l> ASTCENC_SIMD_INLINE void set_lane(float a)
{
m[l] = a;
}
/**
* @brief Factory that returns a vector of zeros.
*/
static ASTCENC_SIMD_INLINE vfloat4 zero()
{
return vfloat4(0.0f);
}
/**
* @brief Factory that returns a replicated scalar loaded from memory.
*/
static ASTCENC_SIMD_INLINE vfloat4 load1(const float* p)
{
return vfloat4(*p);
}
/**
* @brief Factory that returns a vector loaded from aligned memory.
*/
static ASTCENC_SIMD_INLINE vfloat4 loada(const float* p)
{
return vfloat4(p);
}
/**
* @brief Factory that returns a vector containing the lane IDs.
*/
static ASTCENC_SIMD_INLINE vfloat4 lane_id()
{
return vfloat4(0.0f, 1.0f, 2.0f, 3.0f);
}
/**
* @brief Return a swizzled float 2.
*/
template <int l0, int l1> ASTCENC_SIMD_INLINE vfloat4 swz() const
{
return vfloat4(lane<l0>(), lane<l1>(), 0.0f, 0.0f);
}
/**
* @brief Return a swizzled float 3.
*/
template <int l0, int l1, int l2> ASTCENC_SIMD_INLINE vfloat4 swz() const
{
return vfloat4(lane<l0>(), lane<l1>(), lane<l2>(), 0.0f);
}
/**
* @brief Return a swizzled float 4.
*/
template <int l0, int l1, int l2, int l3> ASTCENC_SIMD_INLINE vfloat4 swz() const
{
return vfloat4(lane<l0>(), lane<l1>(), lane<l2>(), lane<l3>());
}
/**
* @brief The vector ...
*/
float m[4];
};
// ============================================================================
// vint4 data type
// ============================================================================
/**
* @brief Data type for 4-wide ints.
*/
struct vint4
{
/**
* @brief Construct from zero-initialized value.
*/
ASTCENC_SIMD_INLINE vint4() = default;
/**
* @brief Construct from 4 values loaded from an unaligned address.
*
* Consider using vint4::loada() which is better with wider VLA vectors
* if data is aligned.
*/
ASTCENC_SIMD_INLINE explicit vint4(const int* p)
{
m[0] = p[0];
m[1] = p[1];
m[2] = p[2];
m[3] = p[3];
}
/**
* @brief Construct from 4 uint8_t loaded from an unaligned address.
*/
ASTCENC_SIMD_INLINE explicit vint4(const uint8_t *p)
{
m[0] = p[0];
m[1] = p[1];
m[2] = p[2];
m[3] = p[3];
}
/**
* @brief Construct from 4 scalar values.
*
* The value of @c a is stored to lane 0 (LSB) in the SIMD register.
*/
ASTCENC_SIMD_INLINE explicit vint4(int a, int b, int c, int d)
{
m[0] = a;
m[1] = b;
m[2] = c;
m[3] = d;
}
/**
* @brief Construct from 4 scalar values replicated across all lanes.
*
* Consider using vint4::zero() for constexpr zeros.
*/
ASTCENC_SIMD_INLINE explicit vint4(int a)
{
m[0] = a;
m[1] = a;
m[2] = a;
m[3] = a;
}
/**
* @brief Get the scalar value of a single lane.
*/
template <int l> ASTCENC_SIMD_INLINE int lane() const
{
return m[l];
}
/**
* @brief Set the scalar value of a single lane.
*/
template <int l> ASTCENC_SIMD_INLINE void set_lane(int a)
{
m[l] = a;
}
/**
* @brief Factory that returns a vector of zeros.
*/
static ASTCENC_SIMD_INLINE vint4 zero()
{
return vint4(0);
}
/**
* @brief Factory that returns a replicated scalar loaded from memory.
*/
static ASTCENC_SIMD_INLINE vint4 load1(const int* p)
{
return vint4(*p);
}
/**
* @brief Factory that returns a vector loaded from unaligned memory.
*/
static ASTCENC_SIMD_INLINE vint4 load(const uint8_t* p)
{
vint4 data;
std::memcpy(&data.m, p, 4 * sizeof(int));
return data;
}
/**
* @brief Factory that returns a vector loaded from 16B aligned memory.
*/
static ASTCENC_SIMD_INLINE vint4 loada(const int* p)
{
return vint4(p);
}
/**
* @brief Factory that returns a vector containing the lane IDs.
*/
static ASTCENC_SIMD_INLINE vint4 lane_id()
{
return vint4(0, 1, 2, 3);
}
/**
* @brief The vector ...
*/
int m[4];
};
// ============================================================================
// vmask4 data type
// ============================================================================
/**
* @brief Data type for 4-wide control plane masks.
*/
struct vmask4
{
/**
* @brief Construct from an existing mask value.
*/
ASTCENC_SIMD_INLINE explicit vmask4(int* p)
{
m[0] = p[0];
m[1] = p[1];
m[2] = p[2];
m[3] = p[3];
}
/**
* @brief Construct from 1 scalar value.
*/
ASTCENC_SIMD_INLINE explicit vmask4(bool a)
{
m[0] = a == false ? 0 : -1;
m[1] = a == false ? 0 : -1;
m[2] = a == false ? 0 : -1;
m[3] = a == false ? 0 : -1;
}
/**
* @brief Construct from 4 scalar values.
*
* The value of @c a is stored to lane 0 (LSB) in the SIMD register.
*/
ASTCENC_SIMD_INLINE explicit vmask4(bool a, bool b, bool c, bool d)
{
m[0] = a == false ? 0 : -1;
m[1] = b == false ? 0 : -1;
m[2] = c == false ? 0 : -1;
m[3] = d == false ? 0 : -1;
}
/**
* @brief Get the scalar value of a single lane.
*/
template <int l> ASTCENC_SIMD_INLINE float lane() const
{
return m[l] != 0;
}
/**
* @brief The vector ...
*/
int m[4];
};
// ============================================================================
// vmask4 operators and functions
// ============================================================================
/**
* @brief Overload: mask union (or).
*/
ASTCENC_SIMD_INLINE vmask4 operator|(vmask4 a, vmask4 b)
{
return vmask4(a.m[0] | b.m[0],
a.m[1] | b.m[1],
a.m[2] | b.m[2],
a.m[3] | b.m[3]);
}
/**
* @brief Overload: mask intersect (and).
*/
ASTCENC_SIMD_INLINE vmask4 operator&(vmask4 a, vmask4 b)
{
return vmask4(a.m[0] & b.m[0],
a.m[1] & b.m[1],
a.m[2] & b.m[2],
a.m[3] & b.m[3]);
}
/**
* @brief Overload: mask difference (xor).
*/
ASTCENC_SIMD_INLINE vmask4 operator^(vmask4 a, vmask4 b)
{
return vmask4(a.m[0] ^ b.m[0],
a.m[1] ^ b.m[1],
a.m[2] ^ b.m[2],
a.m[3] ^ b.m[3]);
}
/**
* @brief Overload: mask invert (not).
*/
ASTCENC_SIMD_INLINE vmask4 operator~(vmask4 a)
{
return vmask4(~a.m[0],
~a.m[1],
~a.m[2],
~a.m[3]);
}
/**
* @brief Return a 1-bit mask code indicating mask status.
*
* bit0 = lane 0
*/
ASTCENC_SIMD_INLINE unsigned int mask(vmask4 a)
{
return ((a.m[0] >> 31) & 0x1) |
((a.m[1] >> 30) & 0x2) |
((a.m[2] >> 29) & 0x4) |
((a.m[3] >> 28) & 0x8);
}
// ============================================================================
// vint4 operators and functions
// ============================================================================
/**
* @brief Overload: vector by vector addition.
*/
ASTCENC_SIMD_INLINE vint4 operator+(vint4 a, vint4 b)
{
return vint4(a.m[0] + b.m[0],
a.m[1] + b.m[1],
a.m[2] + b.m[2],
a.m[3] + b.m[3]);
}
/**
* @brief Overload: vector by vector subtraction.
*/
ASTCENC_SIMD_INLINE vint4 operator-(vint4 a, vint4 b)
{
return vint4(a.m[0] - b.m[0],
a.m[1] - b.m[1],
a.m[2] - b.m[2],
a.m[3] - b.m[3]);
}
/**
* @brief Overload: vector by vector multiplication.
*/
ASTCENC_SIMD_INLINE vint4 operator*(vint4 a, vint4 b)
{
return vint4(a.m[0] * b.m[0],
a.m[1] * b.m[1],
a.m[2] * b.m[2],
a.m[3] * b.m[3]);
}
/**
* @brief Overload: vector bit invert.
*/
ASTCENC_SIMD_INLINE vint4 operator~(vint4 a)
{
return vint4(~a.m[0],
~a.m[1],
~a.m[2],
~a.m[3]);
}
/**
* @brief Overload: vector by vector bitwise or.
*/
ASTCENC_SIMD_INLINE vint4 operator|(vint4 a, vint4 b)
{
return vint4(a.m[0] | b.m[0],
a.m[1] | b.m[1],
a.m[2] | b.m[2],
a.m[3] | b.m[3]);
}
/**
* @brief Overload: vector by vector bitwise and.
*/
ASTCENC_SIMD_INLINE vint4 operator&(vint4 a, vint4 b)
{
return vint4(a.m[0] & b.m[0],
a.m[1] & b.m[1],
a.m[2] & b.m[2],
a.m[3] & b.m[3]);
}
/**
* @brief Overload: vector by vector bitwise xor.
*/
ASTCENC_SIMD_INLINE vint4 operator^(vint4 a, vint4 b)
{
return vint4(a.m[0] ^ b.m[0],
a.m[1] ^ b.m[1],
a.m[2] ^ b.m[2],
a.m[3] ^ b.m[3]);
}
/**
* @brief Overload: vector by vector equality.
*/
ASTCENC_SIMD_INLINE vmask4 operator==(vint4 a, vint4 b)
{
return vmask4(a.m[0] == b.m[0],
a.m[1] == b.m[1],
a.m[2] == b.m[2],
a.m[3] == b.m[3]);
}
/**
* @brief Overload: vector by vector inequality.
*/
ASTCENC_SIMD_INLINE vmask4 operator!=(vint4 a, vint4 b)
{
return vmask4(a.m[0] != b.m[0],
a.m[1] != b.m[1],
a.m[2] != b.m[2],
a.m[3] != b.m[3]);
}
/**
* @brief Overload: vector by vector less than.
*/
ASTCENC_SIMD_INLINE vmask4 operator<(vint4 a, vint4 b)
{
return vmask4(a.m[0] < b.m[0],
a.m[1] < b.m[1],
a.m[2] < b.m[2],
a.m[3] < b.m[3]);
}
/**
* @brief Overload: vector by vector greater than.
*/
ASTCENC_SIMD_INLINE vmask4 operator>(vint4 a, vint4 b)
{
return vmask4(a.m[0] > b.m[0],
a.m[1] > b.m[1],
a.m[2] > b.m[2],
a.m[3] > b.m[3]);
}
/**
* @brief Logical shift left.
*/
template <int s> ASTCENC_SIMD_INLINE vint4 lsl(vint4 a)
{
return vint4(a.m[0] << s,
a.m[1] << s,
a.m[2] << s,
a.m[3] << s);
}
/**
* @brief Logical shift right.
*/
template <int s> ASTCENC_SIMD_INLINE vint4 lsr(vint4 a)
{
unsigned int as0 = static_cast<unsigned int>(a.m[0]) >> s;
unsigned int as1 = static_cast<unsigned int>(a.m[1]) >> s;
unsigned int as2 = static_cast<unsigned int>(a.m[2]) >> s;
unsigned int as3 = static_cast<unsigned int>(a.m[3]) >> s;
return vint4(static_cast<int>(as0),
static_cast<int>(as1),
static_cast<int>(as2),
static_cast<int>(as3));
}
/**
* @brief Arithmetic shift right.
*/
template <int s> ASTCENC_SIMD_INLINE vint4 asr(vint4 a)
{
return vint4(a.m[0] >> s,
a.m[1] >> s,
a.m[2] >> s,
a.m[3] >> s);
}
/**
* @brief Return the min vector of two vectors.
*/
ASTCENC_SIMD_INLINE vint4 min(vint4 a, vint4 b)
{
return vint4(a.m[0] < b.m[0] ? a.m[0] : b.m[0],
a.m[1] < b.m[1] ? a.m[1] : b.m[1],
a.m[2] < b.m[2] ? a.m[2] : b.m[2],
a.m[3] < b.m[3] ? a.m[3] : b.m[3]);
}
/**
* @brief Return the min vector of two vectors.
*/
ASTCENC_SIMD_INLINE vint4 max(vint4 a, vint4 b)
{
return vint4(a.m[0] > b.m[0] ? a.m[0] : b.m[0],
a.m[1] > b.m[1] ? a.m[1] : b.m[1],
a.m[2] > b.m[2] ? a.m[2] : b.m[2],
a.m[3] > b.m[3] ? a.m[3] : b.m[3]);
}
/**
* @brief Return the horizontal minimum of a single vector.
*/
ASTCENC_SIMD_INLINE vint4 hmin(vint4 a)
{
int b = std::min(a.m[0], a.m[1]);
int c = std::min(a.m[2], a.m[3]);
return vint4(std::min(b, c));
}
/**
* @brief Return the horizontal maximum of a single vector.
*/
ASTCENC_SIMD_INLINE vint4 hmax(vint4 a)
{
int b = std::max(a.m[0], a.m[1]);
int c = std::max(a.m[2], a.m[3]);
return vint4(std::max(b, c));
}
/**
* @brief Return the horizontal sum of vector lanes as a scalar.
*/
ASTCENC_SIMD_INLINE int hadd_s(vint4 a)
{
return a.m[0] + a.m[1] + a.m[2] + a.m[3];
}
/**
* @brief Store a vector to an aligned memory address.
*/
ASTCENC_SIMD_INLINE void storea(vint4 a, int* p)
{
p[0] = a.m[0];
p[1] = a.m[1];
p[2] = a.m[2];
p[3] = a.m[3];
}
/**
* @brief Store a vector to an unaligned memory address.
*/
ASTCENC_SIMD_INLINE void store(vint4 a, int* p)
{
p[0] = a.m[0];
p[1] = a.m[1];
p[2] = a.m[2];
p[3] = a.m[3];
}
/**
* @brief Store a vector to an unaligned memory address.
*/
ASTCENC_SIMD_INLINE void store(vint4 a, uint8_t* p)
{
std::memcpy(p, a.m, sizeof(int) * 4);
}
/**
* @brief Store lowest N (vector width) bytes into an unaligned address.
*/
ASTCENC_SIMD_INLINE void store_nbytes(vint4 a, uint8_t* p)
{
std::memcpy(p, a.m, sizeof(uint8_t) * 4);
}
/**
* @brief Gather N (vector width) indices from the array.
*/
ASTCENC_SIMD_INLINE vint4 gatheri(const int* base, vint4 indices)
{
return vint4(base[indices.m[0]],
base[indices.m[1]],
base[indices.m[2]],
base[indices.m[3]]);
}
/**
* @brief Pack low 8 bits of N (vector width) lanes into bottom of vector.
*/
ASTCENC_SIMD_INLINE vint4 pack_low_bytes(vint4 a)
{
int b0 = a.m[0] & 0xFF;
int b1 = a.m[1] & 0xFF;
int b2 = a.m[2] & 0xFF;
int b3 = a.m[3] & 0xFF;
int b = b0 | (b1 << 8) | (b2 << 16) | (b3 << 24);
return vint4(b, 0, 0, 0);
}
/**
* @brief Return lanes from @c b if MSB of @c cond is set, else @c a.
*/
ASTCENC_SIMD_INLINE vint4 select(vint4 a, vint4 b, vmask4 cond)
{
return vint4((cond.m[0] & static_cast<int>(0x80000000)) ? b.m[0] : a.m[0],
(cond.m[1] & static_cast<int>(0x80000000)) ? b.m[1] : a.m[1],
(cond.m[2] & static_cast<int>(0x80000000)) ? b.m[2] : a.m[2],
(cond.m[3] & static_cast<int>(0x80000000)) ? b.m[3] : a.m[3]);
}
// ============================================================================
// vfloat4 operators and functions
// ============================================================================
/**
* @brief Overload: vector by vector addition.
*/
ASTCENC_SIMD_INLINE vfloat4 operator+(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] + b.m[0],
a.m[1] + b.m[1],
a.m[2] + b.m[2],
a.m[3] + b.m[3]);
}
/**
* @brief Overload: vector by vector subtraction.
*/
ASTCENC_SIMD_INLINE vfloat4 operator-(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] - b.m[0],
a.m[1] - b.m[1],
a.m[2] - b.m[2],
a.m[3] - b.m[3]);
}
/**
* @brief Overload: vector by vector multiplication.
*/
ASTCENC_SIMD_INLINE vfloat4 operator*(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] * b.m[0],
a.m[1] * b.m[1],
a.m[2] * b.m[2],
a.m[3] * b.m[3]);
}
/**
* @brief Overload: vector by vector division.
*/
ASTCENC_SIMD_INLINE vfloat4 operator/(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] / b.m[0],
a.m[1] / b.m[1],
a.m[2] / b.m[2],
a.m[3] / b.m[3]);
}
/**
* @brief Overload: vector by vector equality.
*/
ASTCENC_SIMD_INLINE vmask4 operator==(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] == b.m[0],
a.m[1] == b.m[1],
a.m[2] == b.m[2],
a.m[3] == b.m[3]);
}
/**
* @brief Overload: vector by vector inequality.
*/
ASTCENC_SIMD_INLINE vmask4 operator!=(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] != b.m[0],
a.m[1] != b.m[1],
a.m[2] != b.m[2],
a.m[3] != b.m[3]);
}
/**
* @brief Overload: vector by vector less than.
*/
ASTCENC_SIMD_INLINE vmask4 operator<(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] < b.m[0],
a.m[1] < b.m[1],
a.m[2] < b.m[2],
a.m[3] < b.m[3]);
}
/**
* @brief Overload: vector by vector greater than.
*/
ASTCENC_SIMD_INLINE vmask4 operator>(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] > b.m[0],
a.m[1] > b.m[1],
a.m[2] > b.m[2],
a.m[3] > b.m[3]);
}
/**
* @brief Overload: vector by vector less than or equal.
*/
ASTCENC_SIMD_INLINE vmask4 operator<=(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] <= b.m[0],
a.m[1] <= b.m[1],
a.m[2] <= b.m[2],
a.m[3] <= b.m[3]);
}
/**
* @brief Overload: vector by vector greater than or equal.
*/
ASTCENC_SIMD_INLINE vmask4 operator>=(vfloat4 a, vfloat4 b)
{
return vmask4(a.m[0] >= b.m[0],
a.m[1] >= b.m[1],
a.m[2] >= b.m[2],
a.m[3] >= b.m[3]);
}
/**
* @brief Return the min vector of two vectors.
*
* If either lane value is NaN, @c b will be returned for that lane.
*/
ASTCENC_SIMD_INLINE vfloat4 min(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] < b.m[0] ? a.m[0] : b.m[0],
a.m[1] < b.m[1] ? a.m[1] : b.m[1],
a.m[2] < b.m[2] ? a.m[2] : b.m[2],
a.m[3] < b.m[3] ? a.m[3] : b.m[3]);
}
/**
* @brief Return the max vector of two vectors.
*
* If either lane value is NaN, @c b will be returned for that lane.
*/
ASTCENC_SIMD_INLINE vfloat4 max(vfloat4 a, vfloat4 b)
{
return vfloat4(a.m[0] > b.m[0] ? a.m[0] : b.m[0],
a.m[1] > b.m[1] ? a.m[1] : b.m[1],
a.m[2] > b.m[2] ? a.m[2] : b.m[2],
a.m[3] > b.m[3] ? a.m[3] : b.m[3]);
}
/**
* @brief Return the absolute value of the float vector.
*/
ASTCENC_SIMD_INLINE vfloat4 abs(vfloat4 a)
{
return vfloat4(std::abs(a.m[0]),
std::abs(a.m[1]),
std::abs(a.m[2]),
std::abs(a.m[3]));
}
/**
* @brief Return a float rounded to the nearest integer value.
*/
ASTCENC_SIMD_INLINE vfloat4 round(vfloat4 a)
{
assert(std::fegetround() == FE_TONEAREST);
return vfloat4(std::nearbyint(a.m[0]),
std::nearbyint(a.m[1]),
std::nearbyint(a.m[2]),
std::nearbyint(a.m[3]));
}
/**
* @brief Return the horizontal minimum of a vector.
*/
ASTCENC_SIMD_INLINE vfloat4 hmin(vfloat4 a)
{
float tmp1 = std::min(a.m[0], a.m[1]);
float tmp2 = std::min(a.m[2], a.m[3]);
return vfloat4(std::min(tmp1, tmp2));
}
/**
* @brief Return the horizontal maximum of a vector.
*/
ASTCENC_SIMD_INLINE vfloat4 hmax(vfloat4 a)
{
float tmp1 = std::max(a.m[0], a.m[1]);
float tmp2 = std::max(a.m[2], a.m[3]);
return vfloat4(std::max(tmp1, tmp2));
}
/**
* @brief Return the horizontal sum of a vector.
*/
ASTCENC_SIMD_INLINE float hadd_s(vfloat4 a)
{
// Use halving add, gives invariance with SIMD versions
return (a.m[0] + a.m[2]) + (a.m[1] + a.m[3]);
}
/**
* @brief Return the sqrt of the lanes in the vector.
*/
ASTCENC_SIMD_INLINE vfloat4 sqrt(vfloat4 a)
{
return vfloat4(std::sqrt(a.m[0]),
std::sqrt(a.m[1]),
std::sqrt(a.m[2]),
std::sqrt(a.m[3]));
}
/**
* @brief Return lanes from @c b if @c cond is set, else @c a.
*/
ASTCENC_SIMD_INLINE vfloat4 select(vfloat4 a, vfloat4 b, vmask4 cond)
{
return vfloat4((cond.m[0] & static_cast<int>(0x80000000)) ? b.m[0] : a.m[0],
(cond.m[1] & static_cast<int>(0x80000000)) ? b.m[1] : a.m[1],
(cond.m[2] & static_cast<int>(0x80000000)) ? b.m[2] : a.m[2],
(cond.m[3] & static_cast<int>(0x80000000)) ? b.m[3] : a.m[3]);
}
/**
* @brief Return lanes from @c b if MSB of @c cond is set, else @c a.
*/
ASTCENC_SIMD_INLINE vfloat4 select_msb(vfloat4 a, vfloat4 b, vmask4 cond)
{
return vfloat4((cond.m[0] & static_cast<int>(0x80000000)) ? b.m[0] : a.m[0],
(cond.m[1] & static_cast<int>(0x80000000)) ? b.m[1] : a.m[1],
(cond.m[2] & static_cast<int>(0x80000000)) ? b.m[2] : a.m[2],
(cond.m[3] & static_cast<int>(0x80000000)) ? b.m[3] : a.m[3]);
}
/**
* @brief Load a vector of gathered results from an array;
*/
ASTCENC_SIMD_INLINE vfloat4 gatherf(const float* base, vint4 indices)
{
return vfloat4(base[indices.m[0]],
base[indices.m[1]],
base[indices.m[2]],
base[indices.m[3]]);
}
/**
* @brief Store a vector to an unaligned memory address.
*/
ASTCENC_SIMD_INLINE void store(vfloat4 a, float* ptr)
{
ptr[0] = a.m[0];
ptr[1] = a.m[1];
ptr[2] = a.m[2];
ptr[3] = a.m[3];
}
/**
* @brief Store a vector to an aligned memory address.
*/
ASTCENC_SIMD_INLINE void storea(vfloat4 a, float* ptr)
{
ptr[0] = a.m[0];
ptr[1] = a.m[1];
ptr[2] = a.m[2];
ptr[3] = a.m[3];
}
/**
* @brief Return a integer value for a float vector, using truncation.
*/
ASTCENC_SIMD_INLINE vint4 float_to_int(vfloat4 a)
{
return vint4(static_cast<int>(a.m[0]),
static_cast<int>(a.m[1]),
static_cast<int>(a.m[2]),
static_cast<int>(a.m[3]));
}
/**f
* @brief Return a integer value for a float vector, using round-to-nearest.
*/
ASTCENC_SIMD_INLINE vint4 float_to_int_rtn(vfloat4 a)
{
a = a + vfloat4(0.5f);
return vint4(static_cast<int>(a.m[0]),
static_cast<int>(a.m[1]),
static_cast<int>(a.m[2]),
static_cast<int>(a.m[3]));
}
/**
* @brief Return a float value for a integer vector.
*/
ASTCENC_SIMD_INLINE vfloat4 int_to_float(vint4 a)
{
return vfloat4(static_cast<float>(a.m[0]),
static_cast<float>(a.m[1]),
static_cast<float>(a.m[2]),
static_cast<float>(a.m[3]));
}
/**
* @brief Return a float16 value for a float vector, using round-to-nearest.
*/
ASTCENC_SIMD_INLINE vint4 float_to_float16(vfloat4 a)
{
return vint4(
float_to_sf16(a.lane<0>()),
float_to_sf16(a.lane<1>()),
float_to_sf16(a.lane<2>()),
float_to_sf16(a.lane<3>()));
}
/**
* @brief Return a float16 value for a float scalar, using round-to-nearest.
*/
static inline uint16_t float_to_float16(float a)
{
return float_to_sf16(a);
}
/**
* @brief Return a float value for a float16 vector.
*/
ASTCENC_SIMD_INLINE vfloat4 float16_to_float(vint4 a)
{
return vfloat4(
sf16_to_float(static_cast<uint16_t>(a.lane<0>())),
sf16_to_float(static_cast<uint16_t>(a.lane<1>())),
sf16_to_float(static_cast<uint16_t>(a.lane<2>())),
sf16_to_float(static_cast<uint16_t>(a.lane<3>())));
}
/**
* @brief Return a float value for a float16 scalar.
*/
ASTCENC_SIMD_INLINE float float16_to_float(uint16_t a)
{
return sf16_to_float(a);
}
/**
* @brief Return a float value as an integer bit pattern (i.e. no conversion).
*
* It is a common trick to convert floats into integer bit patterns, perform
* some bit hackery based on knowledge they are IEEE 754 layout, and then
* convert them back again. This is the first half of that flip.
*/
ASTCENC_SIMD_INLINE vint4 float_as_int(vfloat4 a)
{
vint4 r;
std::memcpy(r.m, a.m, 4 * 4);
return r;
}
/**
* @brief Return a integer value as a float bit pattern (i.e. no conversion).
*
* It is a common trick to convert floats into integer bit patterns, perform
* some bit hackery based on knowledge they are IEEE 754 layout, and then
* convert them back again. This is the second half of that flip.
*/
ASTCENC_SIMD_INLINE vfloat4 int_as_float(vint4 a)
{
vfloat4 r;
std::memcpy(r.m, a.m, 4 * 4);
return r;
}
/**
* @brief Prepare a vtable lookup table for use with the native SIMD size.
*/
ASTCENC_SIMD_INLINE void vtable_prepare(vint4 t0, vint4& t0p)
{
t0p = t0;
}
/**
* @brief Prepare a vtable lookup table for use with the native SIMD size.
*/
ASTCENC_SIMD_INLINE void vtable_prepare(vint4 t0, vint4 t1, vint4& t0p, vint4& t1p)
{
t0p = t0;
t1p = t1;
}
/**
* @brief Prepare a vtable lookup table for use with the native SIMD size.
*/
ASTCENC_SIMD_INLINE void vtable_prepare(
vint4 t0, vint4 t1, vint4 t2, vint4 t3,
vint4& t0p, vint4& t1p, vint4& t2p, vint4& t3p)
{
t0p = t0;
t1p = t1;
t2p = t2;
t3p = t3;
}
/**
* @brief Perform an 8-bit 16-entry table lookup, with 32-bit indexes.
*/
ASTCENC_SIMD_INLINE vint4 vtable_8bt_32bi(vint4 t0, vint4 idx)
{
uint8_t table[16];
std::memcpy(table + 0, t0.m, 4 * sizeof(int));
return vint4(table[idx.lane<0>()],
table[idx.lane<1>()],
table[idx.lane<2>()],
table[idx.lane<3>()]);
}
/**
* @brief Perform an 8-bit 32-entry table lookup, with 32-bit indexes.
*/
ASTCENC_SIMD_INLINE vint4 vtable_8bt_32bi(vint4 t0, vint4 t1, vint4 idx)
{
uint8_t table[32];
std::memcpy(table + 0, t0.m, 4 * sizeof(int));
std::memcpy(table + 16, t1.m, 4 * sizeof(int));
return vint4(table[idx.lane<0>()],
table[idx.lane<1>()],
table[idx.lane<2>()],
table[idx.lane<3>()]);
}
/**
* @brief Perform an 8-bit 64-entry table lookup, with 32-bit indexes.
*/
ASTCENC_SIMD_INLINE vint4 vtable_8bt_32bi(vint4 t0, vint4 t1, vint4 t2, vint4 t3, vint4 idx)
{
uint8_t table[64];
std::memcpy(table + 0, t0.m, 4 * sizeof(int));
std::memcpy(table + 16, t1.m, 4 * sizeof(int));
std::memcpy(table + 32, t2.m, 4 * sizeof(int));
std::memcpy(table + 48, t3.m, 4 * sizeof(int));
return vint4(table[idx.lane<0>()],
table[idx.lane<1>()],
table[idx.lane<2>()],
table[idx.lane<3>()]);
}
/**
* @brief Return a vector of interleaved RGBA data.
*
* Input vectors have the value stored in the bottom 8 bits of each lane,
* with high bits set to zero.
*
* Output vector stores a single RGBA texel packed in each lane.
*/
ASTCENC_SIMD_INLINE vint4 interleave_rgba8(vint4 r, vint4 g, vint4 b, vint4 a)
{
return r + lsl<8>(g) + lsl<16>(b) + lsl<24>(a);
}
/**
* @brief Store a single vector lane to an unaligned address.
*/
ASTCENC_SIMD_INLINE void store_lane(uint8_t* base, int data)
{
std::memcpy(base, &data, sizeof(int));
}
/**
* @brief Store a vector, skipping masked lanes.
*
* All masked lanes must be at the end of vector, after all non-masked lanes.
* Input is a byte array of at least 4 bytes per unmasked entry.
*/
ASTCENC_SIMD_INLINE void store_lanes_masked(uint8_t* base, vint4 data, vmask4 mask)
{
if (mask.m[3])
{
store(data, base);
}
else if (mask.m[2])
{
store_lane(base + 0, data.lane<0>());
store_lane(base + 4, data.lane<1>());
store_lane(base + 8, data.lane<2>());
}
else if (mask.m[1])
{
store_lane(base + 0, data.lane<0>());
store_lane(base + 4, data.lane<1>());
}
else if (mask.m[0])
{
store_lane(base + 0, data.lane<0>());
}
}
#endif // #ifndef ASTC_VECMATHLIB_NONE_4_H_INCLUDED