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dawn-cmake/test/vk-gl-cts/graphicsfuzz/cov-ldexp-undefined-mat-vec.../0.wgsl

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Add tests derived from VK-GL-CTS This adds SPIR-V assembly and WGSL tests derived from VK-GL-CTS commit 571256871c2e2f03995373e1e4a02958d8cd8cf5. The following procedure was followed: - Those .amber files in VK-GL-CTS wholly owned by Google were identified - All GLSL and SPIR-V shaders were extracted from the Amber files and converted into SPIR-V binaries - The compact-ids pass of spirv-opt was applied to each binary - Duplicate binaries were removed - spirv-opt -O was used to obtain an optimized version of each remaining binary, with duplicates discarded - Binaries that failed validation using spirv-val with target environment SPIR-V 1.3 were discarded - Those binaries that tint could not successfully convert into WGSL were put aside for further investigation - SPIR-V assembly versions of the remaining binaries are included in this CL - test-runner with -generate-expected and -generate-skip was used to generate expected .spvasm, .msl, .hlsl and .wgsl outputs for these SPIR-V assembly tests - Each successfully-generated .expected.wgsl is included in this CL again, as a WGLSL test - test-runner with -generate-expected and -generate-skip was used again, to generate expected outputs for these WGSL tests Change-Id: Ibe9baf2729cf97e0b633db9a426f53362a5de540 Reviewed-on: https://dawn-review.googlesource.com/c/tint/+/58842 Kokoro: Kokoro <noreply+kokoro@google.com> Commit-Queue: Ben Clayton <bclayton@google.com> Reviewed-by: Ben Clayton <bclayton@google.com>
2021-07-23 13:10:12 +00:00
type Arr = [[stride(16)]] array<f32, 2>;
struct buf0 {
x_GLF_uniform_float_values : Arr;
};
type Arr_1 = [[stride(16)]] array<i32, 2>;
struct buf1 {
x_GLF_uniform_int_values : Arr_1;
};
[[group(0), binding(0)]] var<uniform> x_6 : buf0;
[[group(0), binding(1)]] var<uniform> x_8 : buf1;
var<private> x_GLF_color : vec4<f32>;
fn main_1() {
var v1 : vec2<f32>;
let x_35 : f32 = x_6.x_GLF_uniform_float_values[0];
v1 = vec2<f32>(x_35, x_35);
let x_38 : i32 = x_8.x_GLF_uniform_int_values[0];
let x_40 : f32 = v1.y;
v1[x_38] = ldexp(x_40, -256);
let x_43 : vec2<f32> = v1;
if ((((x_43 * mat2x2<f32>(vec2<f32>(x_35, 0.0), vec2<f32>(0.0, x_35)))).x == x_35)) {
let x_53 : f32 = f32(x_38);
let x_55 : i32 = x_8.x_GLF_uniform_int_values[1];
let x_56 : f32 = f32(x_55);
x_GLF_color = vec4<f32>(x_53, x_56, x_56, x_53);
} else {
let x_59 : i32 = x_8.x_GLF_uniform_int_values[1];
let x_60 : f32 = f32(x_59);
x_GLF_color = vec4<f32>(x_60, x_60, x_60, x_60);
}
return;
}
struct main_out {
[[location(0)]]
x_GLF_color_1 : vec4<f32>;
};
[[stage(fragment)]]
fn main() -> main_out {
main_1();
return main_out(x_GLF_color);
}