/*
* Copyright (C) 2014 Intel Corporation
*
* 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.
*
* Authors:
* Jason Ekstrand (jason@jlekstrand.net)
*/
#include <math.h>
#include "main/core.h"
#include "util/rounding.h" /* for _mesa_roundeven */
#include "util/half_float.h"
#include "nir_constant_expressions.h"
/**
* Evaluate one component of packSnorm4x8.
*/
static uint8_t
pack_snorm_1x8(float x)
{
/* From section 8.4 of the GLSL 4.30 spec:
*
* packSnorm4x8
* ------------
* The conversion for component c of v to fixed point is done as
* follows:
*
* packSnorm4x8: round(clamp(c, -1, +1) * 127.0)
*
* We must first cast the float to an int, because casting a negative
* float to a uint is undefined.
*/
return (uint8_t) (int)
_mesa_roundevenf(CLAMP(x, -1.0f, +1.0f) * 127.0f);
}
/**
* Evaluate one component of packSnorm2x16.
*/
static uint16_t
pack_snorm_1x16(float x)
{
/* From section 8.4 of the GLSL ES 3.00 spec:
*
* packSnorm2x16
* -------------
* The conversion for component c of v to fixed point is done as
* follows:
*
* packSnorm2x16: round(clamp(c, -1, +1) * 32767.0)
*
* We must first cast the float to an int, because casting a negative
* float to a uint is undefined.
*/
return (uint16_t) (int)
_mesa_roundevenf(CLAMP(x, -1.0f, +1.0f) * 32767.0f);
}
/**
* Evaluate one component of unpackSnorm4x8.
*/
static float
unpack_snorm_1x8(uint8_t u)
{
/* From section 8.4 of the GLSL 4.30 spec:
*
* unpackSnorm4x8
* --------------
* The conversion for unpacked fixed-point value f to floating point is
* done as follows:
*
* unpackSnorm4x8: clamp(f / 127.0, -1, +1)
*/
return CLAMP((int8_t) u / 127.0f, -1.0f, +1.0f);
}
/**
* Evaluate one component of unpackSnorm2x16.
*/
static float
unpack_snorm_1x16(uint16_t u)
{
/* From section 8.4 of the GLSL ES 3.00 spec:
*
* unpackSnorm2x16
* ---------------
* The conversion for unpacked fixed-point value f to floating point is
* done as follows:
*
* unpackSnorm2x16: clamp(f / 32767.0, -1, +1)
*/
return CLAMP((int16_t) u / 32767.0f, -1.0f, +1.0f);
}
/**
* Evaluate one component packUnorm4x8.
*/
static uint8_t
pack_unorm_1x8(float x)
{
/* From section 8.4 of the GLSL 4.30 spec:
*
* packUnorm4x8
* ------------
* The conversion for component c of v to fixed point is done as
* follows:
*
* packUnorm4x8: round(clamp(c, 0, +1) * 255.0)
*/
return (uint8_t) (int)
_mesa_roundevenf(CLAMP(x, 0.0f, 1.0f) * 255.0f);
}
/**
* Evaluate one component packUnorm2x16.
*/
static uint16_t
pack_unorm_1x16(float x)
{
/* From section 8.4 of the GLSL ES 3.00 spec:
*
* packUnorm2x16
* -------------
* The conversion for component c of v to fixed point is done as
* follows:
*
* packUnorm2x16: round(clamp(c, 0, +1) * 65535.0)
*/
return (uint16_t) (int)
_mesa_roundevenf(CLAMP(x, 0.0f, 1.0f) * 65535.0f);
}
/**
* Evaluate one component of unpackUnorm4x8.
*/
static float
unpack_unorm_1x8(uint8_t u)
{
/* From section 8.4 of the GLSL 4.30 spec:
*
* unpackUnorm4x8
* --------------
* The conversion for unpacked fixed-point value f to floating point is
* done as follows:
*
* unpackUnorm4x8: f / 255.0
*/
return (float) u / 255.0f;
}
/**
* Evaluate one component of unpackUnorm2x16.
*/
static float
unpack_unorm_1x16(uint16_t u)
{
/* From section 8.4 of the GLSL ES 3.00 spec:
*
* unpackUnorm2x16
* ---------------
* The conversion for unpacked fixed-point value f to floating point is
* done as follows:
*
* unpackUnorm2x16: f / 65535.0
*/
return (float) u / 65535.0f;
}
/**
* Evaluate one component of packHalf2x16.
*/
static uint16_t
pack_half_1x16(float x)
{
return _mesa_float_to_half(x);
}
/**
* Evaluate one component of unpackHalf2x16.
*/
static float
unpack_half_1x16(uint16_t u)
{
return _mesa_half_to_float(u);
}
/* Some typed vector structures to make things like src0.y work */
typedef float float32_t;
typedef double float64_t;
typedef bool bool32_t;
struct float32_vec {
float32_t x;
float32_t y;
float32_t z;
float32_t w;
};
struct float64_vec {
float64_t x;
float64_t y;
float64_t z;
float64_t w;
};
struct int32_vec {
int32_t x;
int32_t y;
int32_t z;
int32_t w;
};
struct int64_vec {
int64_t x;
int64_t y;
int64_t z;
int64_t w;
};
struct uint32_vec {
uint32_t x;
uint32_t y;
uint32_t z;
uint32_t w;
};
struct uint64_vec {
uint64_t x;
uint64_t y;
uint64_t z;
uint64_t w;
};
struct bool32_vec {
bool x;
bool y;
bool z;
bool w;
};
static nir_const_value
evaluate_b2f(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
float32_t dst = src0 ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
float32_t dst = src0 ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_b2i(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
int32_t dst = src0 ? 1 : 0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
int32_t dst = src0 ? 1 : 0;
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_fequal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
0,
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_fequal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_fequal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
_src[0].f64[3],
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_iequal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
0,
0,
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
0,
0,
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_iequal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
_src[0].i32[2],
0,
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
_src[1].i32[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
_src[0].i64[2],
0,
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
_src[1].i64[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ball_iequal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
_src[0].i32[2],
_src[0].i32[3],
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
_src[1].i32[2],
_src[1].i32[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
_src[0].i64[2],
_src[0].i64[3],
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
_src[1].i64[2],
_src[1].i64[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_fnequal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
0,
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_fnequal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_fnequal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
_src[0].f64[3],
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_inequal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
0,
0,
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
0,
0,
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
0,
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_inequal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
_src[0].i32[2],
0,
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
_src[1].i32[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
_src[0].i64[2],
0,
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
_src[1].i64[2],
0,
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bany_inequal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct int32_vec src0 = {
_src[0].i32[0],
_src[0].i32[1],
_src[0].i32[2],
_src[0].i32[3],
};
const struct int32_vec src1 = {
_src[1].i32[0],
_src[1].i32[1],
_src[1].i32[2],
_src[1].i32[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
case 64: {
const struct int64_vec src0 = {
_src[0].i64[0],
_src[0].i64[1],
_src[0].i64[2],
_src[0].i64[3],
};
const struct int64_vec src1 = {
_src[1].i64[0],
_src[1].i64[1],
_src[1].i64[2],
_src[1].i64[3],
};
struct bool32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w));
_dst_val.u32[0] = dst.x ? NIR_TRUE : NIR_FALSE;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bcsel(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
const uint32_t src1 =
_src[1].u32[_i];
const uint32_t src2 =
_src[2].u32[_i];
uint32_t dst = src0 ? src1 : src2;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const bool src0 = _src[0].u32[_i] != 0;
const uint64_t src1 =
_src[1].u64[_i];
const uint64_t src2 =
_src[2].u64[_i];
uint64_t dst = src0 ? src1 : src2;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bfi(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
const uint32_t src2 =
_src[2].u32[_i];
uint32_t dst;
unsigned mask = src0, insert = src1, base = src2;
if (mask == 0) {
dst = base;
} else {
unsigned tmp = mask;
while (!(tmp & 1)) {
tmp >>= 1;
insert <<= 1;
}
dst = (base & ~mask) | (insert & mask);
}
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
const uint32_t src2 =
_src[2].u32[_i];
uint32_t dst;
unsigned mask = src0, insert = src1, base = src2;
if (mask == 0) {
dst = base;
} else {
unsigned tmp = mask;
while (!(tmp & 1)) {
tmp >>= 1;
insert <<= 1;
}
dst = (base & ~mask) | (insert & mask);
}
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bfm(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
uint32_t dst;
int bits = src0, offset = src1;
if (offset < 0 || bits < 0 || offset > 31 || bits > 31 || offset + bits > 32)
dst = 0; /* undefined */
else
dst = ((1u << bits) - 1) << offset;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
uint32_t dst;
int bits = src0, offset = src1;
if (offset < 0 || bits < 0 || offset > 31 || bits > 31 || offset + bits > 32)
dst = 0; /* undefined */
else
dst = ((1u << bits) - 1) << offset;
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bit_count(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
uint32_t dst;
dst = 0;
for (unsigned bit = 0; bit < 32; bit++) {
if ((src0 >> bit) & 1)
dst++;
}
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
uint32_t dst;
dst = 0;
for (unsigned bit = 0; bit < 32; bit++) {
if ((src0 >> bit) & 1)
dst++;
}
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bitfield_insert(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
const int32_t src2 =
_src[2].i32[_i];
const int32_t src3 =
_src[3].i32[_i];
uint32_t dst;
unsigned base = src0, insert = src1;
int offset = src2, bits = src3;
if (bits == 0) {
dst = 0;
} else if (offset < 0 || bits < 0 || bits + offset > 32) {
dst = 0;
} else {
unsigned mask = ((1ull << bits) - 1) << offset;
dst = (base & ~mask) | ((insert << bits) & mask);
}
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
const int32_t src2 =
_src[2].i32[_i];
const int32_t src3 =
_src[3].i32[_i];
uint32_t dst;
unsigned base = src0, insert = src1;
int offset = src2, bits = src3;
if (bits == 0) {
dst = 0;
} else if (offset < 0 || bits < 0 || bits + offset > 32) {
dst = 0;
} else {
unsigned mask = ((1ull << bits) - 1) << offset;
dst = (base & ~mask) | ((insert << bits) & mask);
}
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_bitfield_reverse(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
uint32_t dst;
/* we're not winning any awards for speed here, but that's ok */
dst = 0;
for (unsigned bit = 0; bit < 32; bit++)
dst |= ((src0 >> bit) & 1) << (31 - bit);
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
uint32_t dst;
/* we're not winning any awards for speed here, but that's ok */
dst = 0;
for (unsigned bit = 0; bit < 32; bit++)
dst |= ((src0 >> bit) & 1) << (31 - bit);
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_d2b(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
bool32_t dst = src0 != 0.0;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
bool32_t dst = src0 != 0.0;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_d2f(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_d2i(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
int32_t dst = src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
int32_t dst = src0;
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_d2u(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_extract_i16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = (int16_t)(src0 >> (src1 * 16));
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = (int16_t)(src0 >> (src1 * 16));
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_extract_i8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = (int8_t)(src0 >> (src1 * 8));
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = (int8_t)(src0 >> (src1 * 8));
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_extract_u16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = (uint16_t)(src0 >> (src1 * 16));
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = (uint16_t)(src0 >> (src1 * 16));
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_extract_u8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = (uint8_t)(src0 >> (src1 * 8));
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = (uint8_t)(src0 >> (src1 * 8));
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_f2b(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
bool32_t dst = src0 != 0.0f;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
bool32_t dst = src0 != 0.0f;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_f2d(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_f2i(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
int32_t dst = src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
int32_t dst = src0;
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_f2u(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fabs(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? fabs(src0) : fabsf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? fabs(src0) : fabsf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fadd(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 + src1;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 + src1;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fall_equal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fall_equal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fall_equal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x == src1.x) && (src0.y == src1.y) && (src0.z == src1.z) && (src0.w == src1.w)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fand(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = ((src0 != 0.0f) && (src1 != 0.0f)) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = ((src0 != 0.0f) && (src1 != 0.0f)) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fany_nequal2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fany_nequal3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fany_nequal4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x != src1.x) || (src0.y != src1.y) || (src0.z != src1.z) || (src0.w != src1.w)) ? 1.0f : 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fceil(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? ceil(src0) : ceilf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? ceil(src0) : ceilf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fcos(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? cos(src0) : cosf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? cos(src0) : cosf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fcsel(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
const float32_t src2 =
_src[2].f32[_i];
float32_t dst = (src0 != 0.0f) ? src1 : src2;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
const float32_t src2 =
_src[2].f32[_i];
float32_t dst = (src0 != 0.0f) ? src1 : src2;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddx(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddx_coarse(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddx_fine(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddy(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddy_coarse(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fddy_fine(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
float32_t dst = 0.0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
float64_t dst = 0.0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdiv(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 / src1;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 / src1;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y));
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
0,
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
0,
0,
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y));
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z));
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
0,
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z));
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z) + (src0.w * src1.w));
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
_src[0].f64[3],
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z) + (src0.w * src1.w));
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot_replicated2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
0,
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
0,
0,
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y));
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot_replicated3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
0,
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z));
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdot_replicated4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z) + (src0.w * src1.w));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
_src[0].f64[3],
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = ((src0.x * src1.x) + (src0.y * src1.y) + (src0.z * src1.z) + (src0.w * src1.w));
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdph(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = src0.x * src1.x + src0.y * src1.y + src0.z * src1.z + src1.w;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = src0.x * src1.x + src0.y * src1.y + src0.z * src1.z + src1.w;
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fdph_replicated(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
_src[1].f32[1],
_src[1].f32[2],
_src[1].f32[3],
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = src0.x * src1.x + src0.y * src1.y + src0.z * src1.z + src1.w;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct float64_vec src0 = {
_src[0].f64[0],
_src[0].f64[1],
_src[0].f64[2],
0,
};
const struct float64_vec src1 = {
_src[1].f64[0],
_src[1].f64[1],
_src[1].f64[2],
_src[1].f64[3],
};
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = src0.x * src1.x + src0.y * src1.y + src0.z * src1.z + src1.w;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_feq(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
bool32_t dst = src0 == src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
bool32_t dst = src0 == src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fexp2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = exp2f(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = exp2f(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ffloor(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? floor(src0) : floorf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? floor(src0) : floorf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ffma(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
const float32_t src2 =
_src[2].f32[_i];
float32_t dst = src0 * src1 + src2;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
const float64_t src2 =
_src[2].f64[_i];
float64_t dst = src0 * src1 + src2;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ffract(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = src0 - (bit_size == 64 ? floor(src0) : floorf(src0));
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = src0 - (bit_size == 64 ? floor(src0) : floorf(src0));
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fge(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_find_lsb(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst;
dst = -1;
for (unsigned bit = 0; bit < 32; bit++) {
if ((src0 >> bit) & 1) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst;
dst = -1;
for (unsigned bit = 0; bit < 32; bit++) {
if ((src0 >> bit) & 1) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_flog2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = log2f(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = log2f(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_flrp(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
const float32_t src2 =
_src[2].f32[_i];
float32_t dst = src0 * (1 - src2) + src1 * src2;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
const float64_t src2 =
_src[2].f64[_i];
float64_t dst = src0 * (1 - src2) + src1 * src2;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_flt(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fmax(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = fmaxf(src0, src1);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = fmaxf(src0, src1);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fmin(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = fminf(src0, src1);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = fminf(src0, src1);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fmod(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 - src1 * floorf(src0 / src1);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 - src1 * floorf(src0 / src1);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fmov(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fmul(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 * src1;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 * src1;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fne(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
bool32_t dst = src0 != src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
bool32_t dst = src0 != src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fneg(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = -src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = -src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise1_1(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise1_2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise1_3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise1_4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise2_1(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise2_2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise2_3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise2_4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise3_1(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise3_2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise3_3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise3_4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise4_1(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise4_2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise4_3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnoise4_4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
struct float64_vec dst;
dst.x = dst.y = dst.z = dst.w = 0.0f;
_dst_val.f64[0] = dst.x;
_dst_val.f64[1] = dst.y;
_dst_val.f64[2] = dst.z;
_dst_val.f64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fnot(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? ((src0 == 0.0) ? 1.0 : 0.0f) : ((src0 == 0.0f) ? 1.0f : 0.0f);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? ((src0 == 0.0) ? 1.0 : 0.0f) : ((src0 == 0.0f) ? 1.0f : 0.0f);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_for(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = ((src0 != 0.0f) || (src1 != 0.0f)) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = ((src0 != 0.0f) || (src1 != 0.0f)) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fpow(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = bit_size == 64 ? powf(src0, src1) : pow(src0, src1);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = bit_size == 64 ? powf(src0, src1) : pow(src0, src1);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fquantize2f16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = (fabs(src0) < ldexpf(1.0, -14)) ? copysignf(0.0f, src0) : _mesa_half_to_float(_mesa_float_to_half(src0));
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = (fabs(src0) < ldexpf(1.0, -14)) ? copysignf(0.0f, src0) : _mesa_half_to_float(_mesa_float_to_half(src0));
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_frcp(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? 1.0 / src0 : 1.0f / src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? 1.0 / src0 : 1.0f / src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_frem(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 - src1 * truncf(src0 / src1);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 - src1 * truncf(src0 / src1);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fround_even(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? _mesa_roundeven(src0) : _mesa_roundevenf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? _mesa_roundeven(src0) : _mesa_roundevenf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_frsq(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? 1.0 / sqrt(src0) : 1.0f / sqrtf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? 1.0 / sqrt(src0) : 1.0f / sqrtf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fsat(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? ((src0 > 1.0) ? 1.0 : ((src0 <= 0.0) ? 0.0 : src0)) : ((src0 > 1.0f) ? 1.0f : ((src0 <= 0.0f) ? 0.0f : src0));
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? ((src0 > 1.0) ? 1.0 : ((src0 <= 0.0) ? 0.0 : src0)) : ((src0 > 1.0f) ? 1.0f : ((src0 <= 0.0f) ? 0.0f : src0));
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fsign(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? ((src0 == 0.0) ? 0.0 : ((src0 > 0.0) ? 1.0 : -1.0)) : ((src0 == 0.0f) ? 0.0f : ((src0 > 0.0f) ? 1.0f : -1.0f));
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? ((src0 == 0.0) ? 0.0 : ((src0 > 0.0) ? 1.0 : -1.0)) : ((src0 == 0.0f) ? 0.0f : ((src0 > 0.0f) ? 1.0f : -1.0f));
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fsin(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? sin(src0) : sinf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? sin(src0) : sinf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fsqrt(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? sqrt(src0) : sqrtf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? sqrt(src0) : sqrtf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fsub(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = src0 - src1;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const float64_t src1 =
_src[1].f64[_i];
float64_t dst = src0 - src1;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ftrunc(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
float32_t dst = bit_size == 64 ? trunc(src0) : truncf(src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
float64_t dst = bit_size == 64 ? trunc(src0) : truncf(src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_fxor(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 != 0.0f && src1 == 0.0f) || (src0 == 0.0f && src1 != 0.0f) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 != 0.0f && src1 == 0.0f) || (src0 == 0.0f && src1 != 0.0f) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_i2b(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
bool32_t dst = src0 != 0;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
bool32_t dst = src0 != 0;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_i2d(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_i2f(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_iabs(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst = (src0 < 0) ? -src0 : src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
int64_t dst = (src0 < 0) ? -src0 : src0;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_iadd(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 + src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 + src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_iand(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 & src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 & src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ibfe(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
int32_t dst;
int base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0) {
dst = 0; /* undefined */
} else if (offset + bits < 32) {
dst = (base << (32 - bits - offset)) >> (32 - bits);
} else {
dst = base >> offset;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
int32_t dst;
int base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0) {
dst = 0; /* undefined */
} else if (offset + bits < 32) {
dst = (base << (32 - bits - offset)) >> (32 - bits);
} else {
dst = base >> offset;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ibitfield_extract(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
int32_t dst;
int base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (offset < 0 || bits < 0 || offset + bits > 32) {
dst = 0;
} else {
dst = (base << (32 - offset - bits)) >> offset; /* use sign-extending shift */
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
int32_t dst;
int base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (offset < 0 || bits < 0 || offset + bits > 32) {
dst = 0;
} else {
dst = (base << (32 - offset - bits)) >> offset; /* use sign-extending shift */
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_idiv(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 / src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 / src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ieq(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
bool32_t dst = src0 == src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
bool32_t dst = src0 == src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ifind_msb(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst;
dst = -1;
for (int bit = 31; bit >= 0; bit--) {
/* If src0 < 0, we're looking for the first 0 bit.
* if src0 >= 0, we're looking for the first 1 bit.
*/
if ((((src0 >> bit) & 1) && (src0 >= 0)) ||
(!((src0 >> bit) & 1) && (src0 < 0))) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst;
dst = -1;
for (int bit = 31; bit >= 0; bit--) {
/* If src0 < 0, we're looking for the first 0 bit.
* if src0 >= 0, we're looking for the first 1 bit.
*/
if ((((src0 >> bit) & 1) && (src0 >= 0)) ||
(!((src0 >> bit) & 1) && (src0 < 0))) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ige(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ilt(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imax(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src1 > src0 ? src1 : src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src1 > src0 ? src1 : src0;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imin(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src1 > src0 ? src0 : src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src1 > src0 ? src0 : src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imod(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src1 == 0 ? 0 : ((src0 % src1 == 0 || (src0 >= 0) == (src1 >= 0)) ? src0 % src1 : src0 % src1 + src1);
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src1 == 0 ? 0 : ((src0 % src1 == 0 || (src0 >= 0) == (src1 >= 0)) ? src0 % src1 : src0 % src1 + src1);
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imov(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst = src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
int64_t dst = src0;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imul(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 * src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 * src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_imul_high(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = (int32_t)(((int64_t) src0 * (int64_t) src1) >> 32);
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = (int32_t)(((int64_t) src0 * (int64_t) src1) >> 32);
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ine(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
bool32_t dst = src0 != src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
bool32_t dst = src0 != src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ineg(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst = -src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
int64_t dst = -src0;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_inot(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst = ~src0;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
int64_t dst = ~src0;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ior(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 | src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 | src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_irem(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src1 == 0 ? 0 : src0 % src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src1 == 0 ? 0 : src0 % src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ishl(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 << src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 << src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ishr(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 >> src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 >> src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_isign(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
int32_t dst = (src0 == 0) ? 0 : ((src0 > 0) ? 1 : -1);
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
int64_t dst = (src0 == 0) ? 0 : ((src0 > 0) ? 1 : -1);
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_isub(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst = src0 - src1;
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int64_t src0 =
_src[0].i64[_i];
const int64_t src1 =
_src[1].i64[_i];
int64_t dst = src0 - src1;
_dst_val.i64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ixor(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 ^ src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 ^ src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ldexp(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const int32_t src1 =
_src[1].i32[_i];
float32_t dst;
dst = (bit_size == 64) ? ldexp(src0, src1) : ldexpf(src0, src1);
/* flush denormals to zero. */
if (!isnormal(dst))
dst = copysignf(0.0f, src0);
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float64_t src0 =
_src[0].f64[_i];
const int32_t src1 =
_src[1].i32[_i];
float64_t dst;
dst = (bit_size == 64) ? ldexp(src0, src1) : ldexpf(src0, src1);
/* flush denormals to zero. */
if (!isnormal(dst))
dst = copysignf(0.0f, src0);
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_double_2x32(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
0,
0,
};
struct uint64_vec dst;
dst.x = src0.x | ((uint64_t)src0.y << 32);
_dst_val.u64[0] = dst.x;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
0,
0,
};
struct uint64_vec dst;
dst.x = src0.x | ((uint64_t)src0.y << 32);
_dst_val.u64[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_double_2x32_split(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint64_t dst = src0 | ((uint64_t)src1 << 32);
_dst_val.u64[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint64_t dst = src0 | ((uint64_t)src1 << 32);
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_half_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_half_1x16(src0.x);
dst.x |= ((uint32_t) pack_half_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_half_1x16(src0.x);
dst.x |= ((uint32_t) pack_half_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_half_2x16_split(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
0,
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = dst.y = dst.z = dst.w = pack_half_1x16(src0.x) | (pack_half_1x16(src1.x) << 16);
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
0,
0,
0,
};
const struct float32_vec src1 = {
_src[1].f32[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = dst.y = dst.z = dst.w = pack_half_1x16(src0.x) | (pack_half_1x16(src1.x) << 16);
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_snorm_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_snorm_1x16(src0.x);
dst.x |= ((uint32_t) pack_snorm_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_snorm_1x16(src0.x);
dst.x |= ((uint32_t) pack_snorm_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_snorm_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_snorm_1x8(src0.x);
dst.x |= ((uint32_t) pack_snorm_1x8(src0.y)) << 8;
dst.x |= ((uint32_t) pack_snorm_1x8(src0.z)) << 16;
dst.x |= ((uint32_t) pack_snorm_1x8(src0.w)) << 24;
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_snorm_1x8(src0.x);
dst.x |= ((uint32_t) pack_snorm_1x8(src0.y)) << 8;
dst.x |= ((uint32_t) pack_snorm_1x8(src0.z)) << 16;
dst.x |= ((uint32_t) pack_snorm_1x8(src0.w)) << 24;
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_unorm_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_unorm_1x16(src0.x);
dst.x |= ((uint32_t) pack_unorm_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_unorm_1x16(src0.x);
dst.x |= ((uint32_t) pack_unorm_1x16(src0.y)) << 16;
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_unorm_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_unorm_1x8(src0.x);
dst.x |= ((uint32_t) pack_unorm_1x8(src0.y)) << 8;
dst.x |= ((uint32_t) pack_unorm_1x8(src0.z)) << 16;
dst.x |= ((uint32_t) pack_unorm_1x8(src0.w)) << 24;
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct float32_vec src0 = {
_src[0].f32[0],
_src[0].f32[1],
_src[0].f32[2],
_src[0].f32[3],
};
struct uint32_vec dst;
dst.x = (uint32_t) pack_unorm_1x8(src0.x);
dst.x |= ((uint32_t) pack_unorm_1x8(src0.y)) << 8;
dst.x |= ((uint32_t) pack_unorm_1x8(src0.z)) << 16;
dst.x |= ((uint32_t) pack_unorm_1x8(src0.w)) << 24;
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_uvec2_to_uint(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (src0.x & 0xffff) | (src0.y << 16);
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
0,
0,
};
struct uint32_vec dst;
dst.x = (src0.x & 0xffff) | (src0.y << 16);
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_pack_uvec4_to_uint(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
_src[0].u32[2],
_src[0].u32[3],
};
struct uint32_vec dst;
dst.x = (src0.x << 0) |
(src0.y << 8) |
(src0.z << 16) |
(src0.w << 24);
_dst_val.u32[0] = dst.x;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
_src[0].u32[1],
_src[0].u32[2],
_src[0].u32[3],
};
struct uint32_vec dst;
dst.x = (src0.x << 0) |
(src0.y << 8) |
(src0.z << 16) |
(src0.w << 24);
_dst_val.u32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_seq(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 == src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 == src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_sge(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 >= src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 >= src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_slt(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 < src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 < src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_sne(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 != src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const float32_t src0 =
_src[0].f32[_i];
const float32_t src1 =
_src[1].f32[_i];
float32_t dst = (src0 != src1) ? 1.0f : 0.0f;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_u2d(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
float64_t dst = src0;
_dst_val.f64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_u2f(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
float32_t dst = src0;
_dst_val.f32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_uadd_carry(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 + src1 < src0;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 + src1 < src0;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ubfe(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
uint32_t dst;
unsigned base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0) {
dst = 0; /* undefined */
} else if (offset + bits < 32) {
dst = (base << (32 - bits - offset)) >> (32 - bits);
} else {
dst = base >> offset;
}
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
uint32_t dst;
unsigned base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0) {
dst = 0; /* undefined */
} else if (offset + bits < 32) {
dst = (base << (32 - bits - offset)) >> (32 - bits);
} else {
dst = base >> offset;
}
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ubitfield_extract(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
uint32_t dst;
unsigned base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0 || offset + bits > 32) {
dst = 0; /* undefined per the spec */
} else {
dst = (base >> offset) & ((1ull << bits) - 1);
}
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const int32_t src1 =
_src[1].i32[_i];
const int32_t src2 =
_src[2].i32[_i];
uint32_t dst;
unsigned base = src0;
int offset = src1, bits = src2;
if (bits == 0) {
dst = 0;
} else if (bits < 0 || offset < 0 || offset + bits > 32) {
dst = 0; /* undefined per the spec */
} else {
dst = (base >> offset) & ((1ull << bits) - 1);
}
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_udiv(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 / src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 / src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ufind_msb(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
int32_t dst;
dst = -1;
for (int bit = 31; bit > 0; bit--) {
if ((src0 >> bit) & 1) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
int32_t dst;
dst = -1;
for (int bit = 31; bit > 0; bit--) {
if ((src0 >> bit) & 1) {
dst = bit;
break;
}
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_uge(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
bool32_t dst = src0 >= src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ult(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
bool32_t dst = src0 < src1;
_dst_val.u32[_i] = dst ? NIR_TRUE : NIR_FALSE;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umax(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src1 > src0 ? src1 : src0;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src1 > src0 ? src1 : src0;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umax_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MAX2((src0 >> i) & 0xff, (src1 >> i) & 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MAX2((src0 >> i) & 0xff, (src1 >> i) & 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umin(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src1 > src0 ? src0 : src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src1 > src0 ? src0 : src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umin_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MIN2((src0 >> i) & 0xff, (src1 >> i) & 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MIN2((src0 >> i) & 0xff, (src1 >> i) & 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umod(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src1 == 0 ? 0 : src0 % src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src1 == 0 ? 0 : src0 % src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umul_high(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = (uint32_t)(((uint64_t) src0 * (uint64_t) src1) >> 32);
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = (uint32_t)(((uint64_t) src0 * (uint64_t) src1) >> 32);
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_umul_unorm_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
int src0_chan = (src0 >> i) & 0xff;
int src1_chan = (src1 >> i) & 0xff;
dst |= ((src0_chan * src1_chan) / 255) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
int src0_chan = (src0 >> i) & 0xff;
int src1_chan = (src1 >> i) & 0xff;
dst |= ((src0_chan * src1_chan) / 255) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_double_2x32(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint64_vec src0 = {
_src[0].u64[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = src0.x; dst.y = src0.x >> 32;
_dst_val.u32[0] = dst.x;
_dst_val.u32[1] = dst.y;
break;
}
case 64: {
const struct uint64_vec src0 = {
_src[0].u64[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = src0.x; dst.y = src0.x >> 32;
_dst_val.u32[0] = dst.x;
_dst_val.u32[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_double_2x32_split_x(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
uint32_t dst = src0;
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_double_2x32_split_y(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
uint32_t dst = src0 >> 32;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
uint32_t dst = src0 >> 32;
_dst_val.u32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_half_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_half_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_half_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_half_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_half_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_half_2x16_split_x(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = unpack_half_1x16((uint16_t)(src0.x & 0xffff));
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = unpack_half_1x16((uint16_t)(src0.x & 0xffff));
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_half_2x16_split_y(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = unpack_half_1x16((uint16_t)(src0.x >> 16));
_dst_val.f32[0] = dst.x;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = dst.y = dst.z = dst.w = unpack_half_1x16((uint16_t)(src0.x >> 16));
_dst_val.f32[0] = dst.x;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_snorm_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_snorm_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_snorm_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_snorm_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_snorm_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_snorm_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_snorm_1x8((uint8_t)(src0.x & 0xff));
dst.y = unpack_snorm_1x8((uint8_t)((src0.x >> 8) & 0xff));
dst.z = unpack_snorm_1x8((uint8_t)((src0.x >> 16) & 0xff));
dst.w = unpack_snorm_1x8((uint8_t)(src0.x >> 24));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_snorm_1x8((uint8_t)(src0.x & 0xff));
dst.y = unpack_snorm_1x8((uint8_t)((src0.x >> 8) & 0xff));
dst.z = unpack_snorm_1x8((uint8_t)((src0.x >> 16) & 0xff));
dst.w = unpack_snorm_1x8((uint8_t)(src0.x >> 24));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_unorm_2x16(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_unorm_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_unorm_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_unorm_1x16((uint16_t)(src0.x & 0xffff));
dst.y = unpack_unorm_1x16((uint16_t)(src0.x << 16));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_unpack_unorm_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_unorm_1x8((uint8_t)(src0.x & 0xff));
dst.y = unpack_unorm_1x8((uint8_t)((src0.x >> 8) & 0xff));
dst.z = unpack_unorm_1x8((uint8_t)((src0.x >> 16) & 0xff));
dst.w = unpack_unorm_1x8((uint8_t)(src0.x >> 24));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
case 64: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
struct float32_vec dst;
dst.x = unpack_unorm_1x8((uint8_t)(src0.x & 0xff));
dst.y = unpack_unorm_1x8((uint8_t)((src0.x >> 8) & 0xff));
dst.z = unpack_unorm_1x8((uint8_t)((src0.x >> 16) & 0xff));
dst.w = unpack_unorm_1x8((uint8_t)(src0.x >> 24));
_dst_val.f32[0] = dst.x;
_dst_val.f32[1] = dst.y;
_dst_val.f32[2] = dst.z;
_dst_val.f32[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_usadd_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MIN2(((src0 >> i) & 0xff) + ((src1 >> i) & 0xff), 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
dst |= MIN2(((src0 >> i) & 0xff) + ((src1 >> i) & 0xff), 0xff) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ushr(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 >> src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 >> src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_ussub_4x8(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
int src0_chan = (src0 >> i) & 0xff;
int src1_chan = (src1 >> i) & 0xff;
if (src0_chan > src1_chan)
dst |= (src0_chan - src1_chan) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const int32_t src0 =
_src[0].i32[_i];
const int32_t src1 =
_src[1].i32[_i];
int32_t dst;
dst = 0;
for (int i = 0; i < 32; i += 8) {
int src0_chan = (src0 >> i) & 0xff;
int src1_chan = (src1 >> i) & 0xff;
if (src0_chan > src1_chan)
dst |= (src0_chan - src1_chan) << i;
}
_dst_val.i32[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_usub_borrow(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint32_t src0 =
_src[0].u32[_i];
const uint32_t src1 =
_src[1].u32[_i];
uint32_t dst = src0 < src1;
_dst_val.u32[_i] = dst;
}
break;
}
case 64: {
for (unsigned _i = 0; _i < num_components; _i++) {
const uint64_t src0 =
_src[0].u64[_i];
const uint64_t src1 =
_src[1].u64[_i];
uint64_t dst = src0 < src1;
_dst_val.u64[_i] = dst;
}
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_vec2(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
const struct uint32_vec src1 = {
_src[1].u32[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = src0.x;
dst.y = src1.x;
_dst_val.u32[0] = dst.x;
_dst_val.u32[1] = dst.y;
break;
}
case 64: {
const struct uint64_vec src0 = {
_src[0].u64[0],
0,
0,
0,
};
const struct uint64_vec src1 = {
_src[1].u64[0],
0,
0,
0,
};
struct uint64_vec dst;
dst.x = src0.x;
dst.y = src1.x;
_dst_val.u64[0] = dst.x;
_dst_val.u64[1] = dst.y;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_vec3(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
const struct uint32_vec src1 = {
_src[1].u32[0],
0,
0,
0,
};
const struct uint32_vec src2 = {
_src[2].u32[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = src0.x;
dst.y = src1.x;
dst.z = src2.x;
_dst_val.u32[0] = dst.x;
_dst_val.u32[1] = dst.y;
_dst_val.u32[2] = dst.z;
break;
}
case 64: {
const struct uint64_vec src0 = {
_src[0].u64[0],
0,
0,
0,
};
const struct uint64_vec src1 = {
_src[1].u64[0],
0,
0,
0,
};
const struct uint64_vec src2 = {
_src[2].u64[0],
0,
0,
0,
};
struct uint64_vec dst;
dst.x = src0.x;
dst.y = src1.x;
dst.z = src2.x;
_dst_val.u64[0] = dst.x;
_dst_val.u64[1] = dst.y;
_dst_val.u64[2] = dst.z;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
static nir_const_value
evaluate_vec4(MAYBE_UNUSED unsigned num_components, unsigned bit_size,
MAYBE_UNUSED nir_const_value *_src)
{
nir_const_value _dst_val = { {0, } };
switch (bit_size) {
case 32: {
const struct uint32_vec src0 = {
_src[0].u32[0],
0,
0,
0,
};
const struct uint32_vec src1 = {
_src[1].u32[0],
0,
0,
0,
};
const struct uint32_vec src2 = {
_src[2].u32[0],
0,
0,
0,
};
const struct uint32_vec src3 = {
_src[3].u32[0],
0,
0,
0,
};
struct uint32_vec dst;
dst.x = src0.x;
dst.y = src1.x;
dst.z = src2.x;
dst.w = src3.x;
_dst_val.u32[0] = dst.x;
_dst_val.u32[1] = dst.y;
_dst_val.u32[2] = dst.z;
_dst_val.u32[3] = dst.w;
break;
}
case 64: {
const struct uint64_vec src0 = {
_src[0].u64[0],
0,
0,
0,
};
const struct uint64_vec src1 = {
_src[1].u64[0],
0,
0,
0,
};
const struct uint64_vec src2 = {
_src[2].u64[0],
0,
0,
0,
};
const struct uint64_vec src3 = {
_src[3].u64[0],
0,
0,
0,
};
struct uint64_vec dst;
dst.x = src0.x;
dst.y = src1.x;
dst.z = src2.x;
dst.w = src3.x;
_dst_val.u64[0] = dst.x;
_dst_val.u64[1] = dst.y;
_dst_val.u64[2] = dst.z;
_dst_val.u64[3] = dst.w;
break;
}
default:
unreachable("unknown bit width");
}
return _dst_val;
}
nir_const_value
nir_eval_const_opcode(nir_op op, unsigned num_components,
unsigned bit_width, nir_const_value *src)
{
switch (op) {
case nir_op_b2f:
return evaluate_b2f(num_components, bit_width, src);
case nir_op_b2i:
return evaluate_b2i(num_components, bit_width, src);
case nir_op_ball_fequal2:
return evaluate_ball_fequal2(num_components, bit_width, src);
case nir_op_ball_fequal3:
return evaluate_ball_fequal3(num_components, bit_width, src);
case nir_op_ball_fequal4:
return evaluate_ball_fequal4(num_components, bit_width, src);
case nir_op_ball_iequal2:
return evaluate_ball_iequal2(num_components, bit_width, src);
case nir_op_ball_iequal3:
return evaluate_ball_iequal3(num_components, bit_width, src);
case nir_op_ball_iequal4:
return evaluate_ball_iequal4(num_components, bit_width, src);
case nir_op_bany_fnequal2:
return evaluate_bany_fnequal2(num_components, bit_width, src);
case nir_op_bany_fnequal3:
return evaluate_bany_fnequal3(num_components, bit_width, src);
case nir_op_bany_fnequal4:
return evaluate_bany_fnequal4(num_components, bit_width, src);
case nir_op_bany_inequal2:
return evaluate_bany_inequal2(num_components, bit_width, src);
case nir_op_bany_inequal3:
return evaluate_bany_inequal3(num_components, bit_width, src);
case nir_op_bany_inequal4:
return evaluate_bany_inequal4(num_components, bit_width, src);
case nir_op_bcsel:
return evaluate_bcsel(num_components, bit_width, src);
case nir_op_bfi:
return evaluate_bfi(num_components, bit_width, src);
case nir_op_bfm:
return evaluate_bfm(num_components, bit_width, src);
case nir_op_bit_count:
return evaluate_bit_count(num_components, bit_width, src);
case nir_op_bitfield_insert:
return evaluate_bitfield_insert(num_components, bit_width, src);
case nir_op_bitfield_reverse:
return evaluate_bitfield_reverse(num_components, bit_width, src);
case nir_op_d2b:
return evaluate_d2b(num_components, bit_width, src);
case nir_op_d2f:
return evaluate_d2f(num_components, bit_width, src);
case nir_op_d2i:
return evaluate_d2i(num_components, bit_width, src);
case nir_op_d2u:
return evaluate_d2u(num_components, bit_width, src);
case nir_op_extract_i16:
return evaluate_extract_i16(num_components, bit_width, src);
case nir_op_extract_i8:
return evaluate_extract_i8(num_components, bit_width, src);
case nir_op_extract_u16:
return evaluate_extract_u16(num_components, bit_width, src);
case nir_op_extract_u8:
return evaluate_extract_u8(num_components, bit_width, src);
case nir_op_f2b:
return evaluate_f2b(num_components, bit_width, src);
case nir_op_f2d:
return evaluate_f2d(num_components, bit_width, src);
case nir_op_f2i:
return evaluate_f2i(num_components, bit_width, src);
case nir_op_f2u:
return evaluate_f2u(num_components, bit_width, src);
case nir_op_fabs:
return evaluate_fabs(num_components, bit_width, src);
case nir_op_fadd:
return evaluate_fadd(num_components, bit_width, src);
case nir_op_fall_equal2:
return evaluate_fall_equal2(num_components, bit_width, src);
case nir_op_fall_equal3:
return evaluate_fall_equal3(num_components, bit_width, src);
case nir_op_fall_equal4:
return evaluate_fall_equal4(num_components, bit_width, src);
case nir_op_fand:
return evaluate_fand(num_components, bit_width, src);
case nir_op_fany_nequal2:
return evaluate_fany_nequal2(num_components, bit_width, src);
case nir_op_fany_nequal3:
return evaluate_fany_nequal3(num_components, bit_width, src);
case nir_op_fany_nequal4:
return evaluate_fany_nequal4(num_components, bit_width, src);
case nir_op_fceil:
return evaluate_fceil(num_components, bit_width, src);
case nir_op_fcos:
return evaluate_fcos(num_components, bit_width, src);
case nir_op_fcsel:
return evaluate_fcsel(num_components, bit_width, src);
case nir_op_fddx:
return evaluate_fddx(num_components, bit_width, src);
case nir_op_fddx_coarse:
return evaluate_fddx_coarse(num_components, bit_width, src);
case nir_op_fddx_fine:
return evaluate_fddx_fine(num_components, bit_width, src);
case nir_op_fddy:
return evaluate_fddy(num_components, bit_width, src);
case nir_op_fddy_coarse:
return evaluate_fddy_coarse(num_components, bit_width, src);
case nir_op_fddy_fine:
return evaluate_fddy_fine(num_components, bit_width, src);
case nir_op_fdiv:
return evaluate_fdiv(num_components, bit_width, src);
case nir_op_fdot2:
return evaluate_fdot2(num_components, bit_width, src);
case nir_op_fdot3:
return evaluate_fdot3(num_components, bit_width, src);
case nir_op_fdot4:
return evaluate_fdot4(num_components, bit_width, src);
case nir_op_fdot_replicated2:
return evaluate_fdot_replicated2(num_components, bit_width, src);
case nir_op_fdot_replicated3:
return evaluate_fdot_replicated3(num_components, bit_width, src);
case nir_op_fdot_replicated4:
return evaluate_fdot_replicated4(num_components, bit_width, src);
case nir_op_fdph:
return evaluate_fdph(num_components, bit_width, src);
case nir_op_fdph_replicated:
return evaluate_fdph_replicated(num_components, bit_width, src);
case nir_op_feq:
return evaluate_feq(num_components, bit_width, src);
case nir_op_fexp2:
return evaluate_fexp2(num_components, bit_width, src);
case nir_op_ffloor:
return evaluate_ffloor(num_components, bit_width, src);
case nir_op_ffma:
return evaluate_ffma(num_components, bit_width, src);
case nir_op_ffract:
return evaluate_ffract(num_components, bit_width, src);
case nir_op_fge:
return evaluate_fge(num_components, bit_width, src);
case nir_op_find_lsb:
return evaluate_find_lsb(num_components, bit_width, src);
case nir_op_flog2:
return evaluate_flog2(num_components, bit_width, src);
case nir_op_flrp:
return evaluate_flrp(num_components, bit_width, src);
case nir_op_flt:
return evaluate_flt(num_components, bit_width, src);
case nir_op_fmax:
return evaluate_fmax(num_components, bit_width, src);
case nir_op_fmin:
return evaluate_fmin(num_components, bit_width, src);
case nir_op_fmod:
return evaluate_fmod(num_components, bit_width, src);
case nir_op_fmov:
return evaluate_fmov(num_components, bit_width, src);
case nir_op_fmul:
return evaluate_fmul(num_components, bit_width, src);
case nir_op_fne:
return evaluate_fne(num_components, bit_width, src);
case nir_op_fneg:
return evaluate_fneg(num_components, bit_width, src);
case nir_op_fnoise1_1:
return evaluate_fnoise1_1(num_components, bit_width, src);
case nir_op_fnoise1_2:
return evaluate_fnoise1_2(num_components, bit_width, src);
case nir_op_fnoise1_3:
return evaluate_fnoise1_3(num_components, bit_width, src);
case nir_op_fnoise1_4:
return evaluate_fnoise1_4(num_components, bit_width, src);
case nir_op_fnoise2_1:
return evaluate_fnoise2_1(num_components, bit_width, src);
case nir_op_fnoise2_2:
return evaluate_fnoise2_2(num_components, bit_width, src);
case nir_op_fnoise2_3:
return evaluate_fnoise2_3(num_components, bit_width, src);
case nir_op_fnoise2_4:
return evaluate_fnoise2_4(num_components, bit_width, src);
case nir_op_fnoise3_1:
return evaluate_fnoise3_1(num_components, bit_width, src);
case nir_op_fnoise3_2:
return evaluate_fnoise3_2(num_components, bit_width, src);
case nir_op_fnoise3_3:
return evaluate_fnoise3_3(num_components, bit_width, src);
case nir_op_fnoise3_4:
return evaluate_fnoise3_4(num_components, bit_width, src);
case nir_op_fnoise4_1:
return evaluate_fnoise4_1(num_components, bit_width, src);
case nir_op_fnoise4_2:
return evaluate_fnoise4_2(num_components, bit_width, src);
case nir_op_fnoise4_3:
return evaluate_fnoise4_3(num_components, bit_width, src);
case nir_op_fnoise4_4:
return evaluate_fnoise4_4(num_components, bit_width, src);
case nir_op_fnot:
return evaluate_fnot(num_components, bit_width, src);
case nir_op_for:
return evaluate_for(num_components, bit_width, src);
case nir_op_fpow:
return evaluate_fpow(num_components, bit_width, src);
case nir_op_fquantize2f16:
return evaluate_fquantize2f16(num_components, bit_width, src);
case nir_op_frcp:
return evaluate_frcp(num_components, bit_width, src);
case nir_op_frem:
return evaluate_frem(num_components, bit_width, src);
case nir_op_fround_even:
return evaluate_fround_even(num_components, bit_width, src);
case nir_op_frsq:
return evaluate_frsq(num_components, bit_width, src);
case nir_op_fsat:
return evaluate_fsat(num_components, bit_width, src);
case nir_op_fsign:
return evaluate_fsign(num_components, bit_width, src);
case nir_op_fsin:
return evaluate_fsin(num_components, bit_width, src);
case nir_op_fsqrt:
return evaluate_fsqrt(num_components, bit_width, src);
case nir_op_fsub:
return evaluate_fsub(num_components, bit_width, src);
case nir_op_ftrunc:
return evaluate_ftrunc(num_components, bit_width, src);
case nir_op_fxor:
return evaluate_fxor(num_components, bit_width, src);
case nir_op_i2b:
return evaluate_i2b(num_components, bit_width, src);
case nir_op_i2d:
return evaluate_i2d(num_components, bit_width, src);
case nir_op_i2f:
return evaluate_i2f(num_components, bit_width, src);
case nir_op_iabs:
return evaluate_iabs(num_components, bit_width, src);
case nir_op_iadd:
return evaluate_iadd(num_components, bit_width, src);
case nir_op_iand:
return evaluate_iand(num_components, bit_width, src);
case nir_op_ibfe:
return evaluate_ibfe(num_components, bit_width, src);
case nir_op_ibitfield_extract:
return evaluate_ibitfield_extract(num_components, bit_width, src);
case nir_op_idiv:
return evaluate_idiv(num_components, bit_width, src);
case nir_op_ieq:
return evaluate_ieq(num_components, bit_width, src);
case nir_op_ifind_msb:
return evaluate_ifind_msb(num_components, bit_width, src);
case nir_op_ige:
return evaluate_ige(num_components, bit_width, src);
case nir_op_ilt:
return evaluate_ilt(num_components, bit_width, src);
case nir_op_imax:
return evaluate_imax(num_components, bit_width, src);
case nir_op_imin:
return evaluate_imin(num_components, bit_width, src);
case nir_op_imod:
return evaluate_imod(num_components, bit_width, src);
case nir_op_imov:
return evaluate_imov(num_components, bit_width, src);
case nir_op_imul:
return evaluate_imul(num_components, bit_width, src);
case nir_op_imul_high:
return evaluate_imul_high(num_components, bit_width, src);
case nir_op_ine:
return evaluate_ine(num_components, bit_width, src);
case nir_op_ineg:
return evaluate_ineg(num_components, bit_width, src);
case nir_op_inot:
return evaluate_inot(num_components, bit_width, src);
case nir_op_ior:
return evaluate_ior(num_components, bit_width, src);
case nir_op_irem:
return evaluate_irem(num_components, bit_width, src);
case nir_op_ishl:
return evaluate_ishl(num_components, bit_width, src);
case nir_op_ishr:
return evaluate_ishr(num_components, bit_width, src);
case nir_op_isign:
return evaluate_isign(num_components, bit_width, src);
case nir_op_isub:
return evaluate_isub(num_components, bit_width, src);
case nir_op_ixor:
return evaluate_ixor(num_components, bit_width, src);
case nir_op_ldexp:
return evaluate_ldexp(num_components, bit_width, src);
case nir_op_pack_double_2x32:
return evaluate_pack_double_2x32(num_components, bit_width, src);
case nir_op_pack_double_2x32_split:
return evaluate_pack_double_2x32_split(num_components, bit_width, src);
case nir_op_pack_half_2x16:
return evaluate_pack_half_2x16(num_components, bit_width, src);
case nir_op_pack_half_2x16_split:
return evaluate_pack_half_2x16_split(num_components, bit_width, src);
case nir_op_pack_snorm_2x16:
return evaluate_pack_snorm_2x16(num_components, bit_width, src);
case nir_op_pack_snorm_4x8:
return evaluate_pack_snorm_4x8(num_components, bit_width, src);
case nir_op_pack_unorm_2x16:
return evaluate_pack_unorm_2x16(num_components, bit_width, src);
case nir_op_pack_unorm_4x8:
return evaluate_pack_unorm_4x8(num_components, bit_width, src);
case nir_op_pack_uvec2_to_uint:
return evaluate_pack_uvec2_to_uint(num_components, bit_width, src);
case nir_op_pack_uvec4_to_uint:
return evaluate_pack_uvec4_to_uint(num_components, bit_width, src);
case nir_op_seq:
return evaluate_seq(num_components, bit_width, src);
case nir_op_sge:
return evaluate_sge(num_components, bit_width, src);
case nir_op_slt:
return evaluate_slt(num_components, bit_width, src);
case nir_op_sne:
return evaluate_sne(num_components, bit_width, src);
case nir_op_u2d:
return evaluate_u2d(num_components, bit_width, src);
case nir_op_u2f:
return evaluate_u2f(num_components, bit_width, src);
case nir_op_uadd_carry:
return evaluate_uadd_carry(num_components, bit_width, src);
case nir_op_ubfe:
return evaluate_ubfe(num_components, bit_width, src);
case nir_op_ubitfield_extract:
return evaluate_ubitfield_extract(num_components, bit_width, src);
case nir_op_udiv:
return evaluate_udiv(num_components, bit_width, src);
case nir_op_ufind_msb:
return evaluate_ufind_msb(num_components, bit_width, src);
case nir_op_uge:
return evaluate_uge(num_components, bit_width, src);
case nir_op_ult:
return evaluate_ult(num_components, bit_width, src);
case nir_op_umax:
return evaluate_umax(num_components, bit_width, src);
case nir_op_umax_4x8:
return evaluate_umax_4x8(num_components, bit_width, src);
case nir_op_umin:
return evaluate_umin(num_components, bit_width, src);
case nir_op_umin_4x8:
return evaluate_umin_4x8(num_components, bit_width, src);
case nir_op_umod:
return evaluate_umod(num_components, bit_width, src);
case nir_op_umul_high:
return evaluate_umul_high(num_components, bit_width, src);
case nir_op_umul_unorm_4x8:
return evaluate_umul_unorm_4x8(num_components, bit_width, src);
case nir_op_unpack_double_2x32:
return evaluate_unpack_double_2x32(num_components, bit_width, src);
case nir_op_unpack_double_2x32_split_x:
return evaluate_unpack_double_2x32_split_x(num_components, bit_width, src);
case nir_op_unpack_double_2x32_split_y:
return evaluate_unpack_double_2x32_split_y(num_components, bit_width, src);
case nir_op_unpack_half_2x16:
return evaluate_unpack_half_2x16(num_components, bit_width, src);
case nir_op_unpack_half_2x16_split_x:
return evaluate_unpack_half_2x16_split_x(num_components, bit_width, src);
case nir_op_unpack_half_2x16_split_y:
return evaluate_unpack_half_2x16_split_y(num_components, bit_width, src);
case nir_op_unpack_snorm_2x16:
return evaluate_unpack_snorm_2x16(num_components, bit_width, src);
case nir_op_unpack_snorm_4x8:
return evaluate_unpack_snorm_4x8(num_components, bit_width, src);
case nir_op_unpack_unorm_2x16:
return evaluate_unpack_unorm_2x16(num_components, bit_width, src);
case nir_op_unpack_unorm_4x8:
return evaluate_unpack_unorm_4x8(num_components, bit_width, src);
case nir_op_usadd_4x8:
return evaluate_usadd_4x8(num_components, bit_width, src);
case nir_op_ushr:
return evaluate_ushr(num_components, bit_width, src);
case nir_op_ussub_4x8:
return evaluate_ussub_4x8(num_components, bit_width, src);
case nir_op_usub_borrow:
return evaluate_usub_borrow(num_components, bit_width, src);
case nir_op_vec2:
return evaluate_vec2(num_components, bit_width, src);
case nir_op_vec3:
return evaluate_vec3(num_components, bit_width, src);
case nir_op_vec4:
return evaluate_vec4(num_components, bit_width, src);
default:
unreachable("shouldn't get here");
}
}