blob: f88926bbfdfe67674828848c252c19520c59b86e [file] [log] [blame] [edit]
SKIP: FAILED
#version 310 es
precision mediump float;
struct Uniforms {
float NAN;
ivec3 aShape;
ivec3 bShape;
ivec3 outShape;
ivec2 outShapeStrides;
};
struct ssbOut {
float result[];
};
struct ssbA {
float A[];
};
struct ssbB {
float B[];
};
int dimAOuter_1 = 0;
layout(binding = 3) uniform Uniforms_1 {
float NAN;
ivec3 aShape;
ivec3 bShape;
ivec3 outShape;
ivec2 outShapeStrides;
} x_48;
int dimInner_1 = 0;
int dimBOuter_1 = 0;
layout(binding = 0) buffer ssbOut_1 {
float result[];
} x_54;
uvec3 tint_symbol = uvec3(0u, 0u, 0u);
uvec3 tint_symbol_1 = uvec3(0u, 0u, 0u);
shared float mm_Asub[64][64];
shared float mm_Bsub[64][1];
layout(binding = 1) buffer ssbA_1 {
float A[];
} x_165;
int batch = 0;
layout(binding = 2) buffer ssbB_1 {
float B[];
} x_185;
bool coordsInBounds_vi2_vi2_(inout ivec2 coord, inout ivec2 shape) {
bool x_87 = false;
bool x_88_phi = false;
ivec2 x_76 = coord;
bool x_81 = all(greaterThanEqual(x_76, ivec2(0, 0)));
x_88_phi = x_81;
if (x_81) {
ivec2 x_84 = coord;
ivec2 x_85 = shape;
x_87 = all(lessThan(x_84, x_85));
x_88_phi = x_87;
}
return x_88_phi;
}
float mm_readA_i1_i1_(inout int row, inout int col) {
int batchASize = 0;
ivec2 param_10 = ivec2(0, 0);
ivec2 param_11 = ivec2(0, 0);
float x_430 = 0.0f;
int x_417 = x_48.aShape.y;
int x_419 = x_48.aShape.z;
batchASize = (x_417 * x_419);
int x_421 = row;
int x_422 = col;
int x_424 = dimAOuter_1;
int x_425 = dimInner_1;
param_10 = ivec2(x_421, x_422);
param_11 = ivec2(x_424, x_425);
bool x_429 = coordsInBounds_vi2_vi2_(param_10, param_11);
if (x_429) {
int x_438 = batch;
int x_439 = batchASize;
int x_441 = row;
int x_442 = dimInner_1;
int x_445 = col;
float x_448 = x_165.A[(((x_438 * x_439) + (x_441 * x_442)) + x_445)];
x_430 = x_448;
} else {
x_430 = 0.0f;
}
return x_430;
}
float mm_readB_i1_i1_(inout int row_1, inout int col_1) {
int batchBSize = 0;
ivec2 param_12 = ivec2(0, 0);
ivec2 param_13 = ivec2(0, 0);
float x_468 = 0.0f;
int x_455 = x_48.bShape.y;
int x_457 = x_48.bShape.z;
batchBSize = (x_455 * x_457);
int x_459 = row_1;
int x_460 = col_1;
int x_462 = dimInner_1;
int x_463 = dimBOuter_1;
param_12 = ivec2(x_459, x_460);
param_13 = ivec2(x_462, x_463);
bool x_467 = coordsInBounds_vi2_vi2_(param_12, param_13);
if (x_467) {
int x_475 = batch;
int x_476 = batchBSize;
int x_478 = row_1;
int x_479 = dimBOuter_1;
int x_482 = col_1;
float x_485 = x_185.B[(((x_475 * x_476) + (x_478 * x_479)) + x_482)];
x_468 = x_485;
} else {
x_468 = 0.0f;
}
return x_468;
}
int getOutputFlatIndex_vi3_(inout ivec3 coords) {
ivec3 x_99 = coords;
int x_105 = x_48.outShapeStrides.x;
int x_107 = x_48.outShapeStrides.y;
return int(dot(vec3(x_99), vec3(ivec3(x_105, x_107, 1))));
}
void setOutput_i1_f1_(inout int flatIndex, inout float value) {
int x_95 = flatIndex;
float x_96 = value;
x_54.result[x_95] = x_96;
return;
}
void setOutput_i1_i1_i1_f1_(inout int d0, inout int d1, inout int d2, inout float value_1) {
int flatIndex_1 = 0;
ivec3 param = ivec3(0, 0, 0);
int param_1 = 0;
float param_2 = 0.0f;
int x_115 = d0;
int x_116 = d1;
int x_117 = d2;
param = ivec3(x_115, x_116, x_117);
int x_120 = getOutputFlatIndex_vi3_(param);
flatIndex_1 = x_120;
param_1 = flatIndex_1;
float x_124 = value_1;
param_2 = x_124;
setOutput_i1_f1_(param_1, param_2);
return;
}
void mm_write_i1_i1_f1_(inout int row_2, inout int col_2, inout float value_2) {
ivec3 outCoord = ivec3(0, 0, 0);
int param_14 = 0;
int param_15 = 0;
int param_16 = 0;
float param_17 = 0.0f;
int x_491 = batch;
int x_492 = row_2;
int x_493 = col_2;
outCoord = ivec3(x_491, x_492, x_493);
param_14 = batch;
int x_498 = row_2;
param_15 = x_498;
int x_500 = col_2;
param_16 = x_500;
float x_502 = value_2;
param_17 = x_502;
setOutput_i1_i1_i1_f1_(param_14, param_15, param_16, param_17);
return;
}
void mm_matMul_i1_i1_i1_(inout int dimAOuter, inout int dimInner, inout int dimBOuter) {
int tileRow = 0;
int tileCol = 0;
int globalRow = 0;
int globalCol = 0;
int numTiles = 0;
int innerRow = 0;
int innerCol = 0;
float acc[1][1] = float[1][1](float[1](0.0f));
int tileColA = 0;
int tileRowB = 0;
int t = 0;
int innerRow_1 = 0;
int innerCol_1 = 0;
int inputRow = 0;
int inputCol = 0;
int param_3 = 0;
int param_4 = 0;
int innerRow_2 = 0;
int innerCol_2 = 0;
int inputRow_1 = 0;
int inputCol_1 = 0;
int param_5 = 0;
int param_6 = 0;
int k = 0;
int inner = 0;
float BCached[1] = float[1](0.0f);
int innerRow_3 = 0;
float ACached = 0.0f;
int innerCol_3 = 0;
int innerRow_4 = 0;
int innerCol_4 = 0;
int param_7 = 0;
int param_8 = 0;
float param_9 = 0.0f;
uint x_132 = tint_symbol.y;
tileRow = (int(x_132) * 1);
uint x_137 = tint_symbol.x;
tileCol = (int(x_137) * 1);
uint x_143 = tint_symbol_1.y;
globalRow = (int(x_143) * 1);
uint x_148 = tint_symbol_1.x;
globalCol = (int(x_148) * 1);
int x_152 = dimInner;
numTiles = (((x_152 - 1) / 64) + 1);
innerRow = 0;
{
for(; (innerRow < 1); innerRow = (innerRow + 1)) {
innerCol = 0;
{
for(; (innerCol < 1); innerCol = (innerCol + 1)) {
acc[innerRow][innerCol] = 0.0f;
}
}
}
}
uint x_187 = tint_symbol.x;
tileColA = (int(x_187) * 64);
uint x_192 = tint_symbol.y;
tileRowB = (int(x_192) * 1);
t = 0;
{
for(; (t < numTiles); t = (t + 1)) {
innerRow_1 = 0;
{
for(; (innerRow_1 < 1); innerRow_1 = (innerRow_1 + 1)) {
innerCol_1 = 0;
{
for(; (innerCol_1 < 64); innerCol_1 = (innerCol_1 + 1)) {
inputRow = (tileRow + innerRow_1);
inputCol = (tileColA + innerCol_1);
int x_233 = inputRow;
int x_234 = inputCol;
int x_238 = t;
int x_240 = inputCol;
param_3 = (globalRow + innerRow_1);
param_4 = ((x_238 * 64) + x_240);
float x_244 = mm_readA_i1_i1_(param_3, param_4);
mm_Asub[x_233][x_234] = x_244;
}
}
}
}
innerRow_2 = 0;
{
for(; (innerRow_2 < 1); innerRow_2 = (innerRow_2 + 1)) {
innerCol_2 = 0;
{
for(; (innerCol_2 < 1); innerCol_2 = (innerCol_2 + 1)) {
inputRow_1 = (tileRowB + innerRow_2);
inputCol_1 = (tileCol + innerCol_2);
int x_278 = inputRow_1;
int x_279 = inputCol_1;
int x_284 = globalCol;
int x_285 = innerCol_2;
param_5 = ((t * 64) + inputRow_1);
param_6 = (x_284 + x_285);
float x_289 = mm_readB_i1_i1_(param_5, param_6);
mm_Bsub[x_278][x_279] = x_289;
}
}
}
}
memoryBarrierShared();
k = 0;
{
for(; (k < 64); k = (k + 1)) {
inner = 0;
{
for(; (inner < 1); inner = (inner + 1)) {
int x_314 = inner;
float x_320 = mm_Bsub[k][(tileCol + inner)];
BCached[x_314] = x_320;
}
}
innerRow_3 = 0;
{
for(; (innerRow_3 < 1); innerRow_3 = (innerRow_3 + 1)) {
float x_338 = mm_Asub[(tileRow + innerRow_3)][k];
ACached = x_338;
innerCol_3 = 0;
{
for(; (innerCol_3 < 1); innerCol_3 = (innerCol_3 + 1)) {
int x_347 = innerRow_3;
int x_348 = innerCol_3;
float x_349 = ACached;
float x_352 = BCached[innerCol_3];
float x_355 = acc[x_347][x_348];
acc[x_347][x_348] = (x_355 + (x_349 * x_352));
}
}
}
}
}
}
memoryBarrierShared();
}
}
innerRow_4 = 0;
{
for(; (innerRow_4 < 1); innerRow_4 = (innerRow_4 + 1)) {
innerCol_4 = 0;
while (true) {
bool x_393 = false;
bool x_394_phi = false;
if ((innerCol_4 < 1)) {
} else {
break;
}
int x_382 = globalCol;
int x_383 = innerCol_4;
int x_385 = dimBOuter;
bool x_386 = ((x_382 + x_383) < x_385);
x_394_phi = x_386;
if (x_386) {
int x_389 = globalRow;
int x_390 = innerRow_4;
int x_392 = dimAOuter;
x_393 = ((x_389 + x_390) < x_392);
x_394_phi = x_393;
}
if (x_394_phi) {
int x_400 = globalCol;
int x_401 = innerCol_4;
int x_403 = innerRow_4;
int x_404 = innerCol_4;
param_7 = (globalRow + innerRow_4);
param_8 = (x_400 + x_401);
float x_409 = acc[x_403][x_404];
param_9 = x_409;
mm_write_i1_i1_f1_(param_7, param_8, param_9);
}
{
innerCol_4 = (innerCol_4 + 1);
}
}
}
}
return;
}
void main_1() {
int param_18 = 0;
int param_19 = 0;
int param_20 = 0;
int x_67 = x_48.aShape.y;
dimAOuter_1 = x_67;
int x_71 = x_48.aShape.z;
dimInner_1 = x_71;
int x_75 = x_48.bShape.z;
dimBOuter_1 = x_75;
uint x_505 = tint_symbol_1.z;
batch = int(x_505);
param_18 = dimAOuter_1;
param_19 = dimInner_1;
param_20 = dimBOuter_1;
mm_matMul_i1_i1_i1_(param_18, param_19, param_20);
return;
}
void tint_symbol_2(uvec3 tint_symbol_3, uvec3 tint_symbol_4, uint local_invocation_index) {
{
uint i_1 = local_invocation_index;
uint i_2 = (local_invocation_index % 1u);
mm_Bsub[i_1][i_2] = 0.0f;
}
{
for(uint idx = local_invocation_index; (idx < 4096u); idx = (idx + 64u)) {
uint i = (idx / 64u);
uint i_1 = (idx % 64u);
mm_Asub[i][i_1] = 0.0f;
}
}
memoryBarrierShared();
tint_symbol = tint_symbol_3;
tint_symbol_1 = tint_symbol_4;
main_1();
}
layout(local_size_x = 1, local_size_y = 64, local_size_z = 1) in;
void main() {
tint_symbol_2(gl_LocalInvocationID, gl_GlobalInvocationID, gl_LocalInvocationIndex);
return;
}
Error parsing GLSL shader:
ERROR: 0:13: '' : array size required
ERROR: 0:14: '' : compilation terminated
ERROR: 2 compilation errors. No code generated.