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export const description = `
Execution Tests for non-matrix f32 multiplication expression
`;
import { makeTestGroup } from '../../../../../common/framework/test_group.js';
import { GPUTest } from '../../../../gpu_test.js';
import { Type } from '../../../../util/conversion.js';
import { allInputSources, run } from '../expression.js';
import { binary, compoundBinary } from './binary.js';
import { d } from './f32_multiplication.cache.js';
export const g = makeTestGroup(GPUTest);
g.test('scalar')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x * y, where x and y are scalars
Accuracy: Correctly rounded
`
)
.params(u => u.combine('inputSource', allInputSources))
.fn(async t => {
const cases = await d.get(
t.params.inputSource === 'const' ? 'scalar_const' : 'scalar_non_const'
);
await run(t, binary('*'), [Type.f32, Type.f32], Type.f32, t.params, cases);
});
g.test('vector')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x * y, where x and y are vectors
Accuracy: Correctly rounded
`
)
.params(u => u.combine('inputSource', allInputSources).combine('vectorize', [2, 3, 4] as const))
.fn(async t => {
const cases = await d.get(
t.params.inputSource === 'const' ? 'scalar_const' : 'scalar_non_const' // Using vectorize to generate vector cases based on scalar cases
);
await run(t, binary('*'), [Type.f32, Type.f32], Type.f32, t.params, cases);
});
g.test('scalar_compound')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x *= y
Accuracy: Correctly rounded
`
)
.params(u =>
u.combine('inputSource', allInputSources).combine('vectorize', [undefined, 2, 3, 4] as const)
)
.fn(async t => {
const cases = await d.get(
t.params.inputSource === 'const' ? 'scalar_const' : 'scalar_non_const'
);
await run(t, compoundBinary('*='), [Type.f32, Type.f32], Type.f32, t.params, cases);
});
g.test('vector_scalar')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x * y, where x is a vector and y is a scalar
Accuracy: Correctly rounded
`
)
.params(u => u.combine('inputSource', allInputSources).combine('dim', [2, 3, 4] as const))
.fn(async t => {
const dim = t.params.dim;
const cases = await d.get(
t.params.inputSource === 'const' ? `vec${dim}_scalar_const` : `vec${dim}_scalar_non_const`
);
await run(
t,
binary('*'),
[Type.vec(dim, Type.f32), Type.f32],
Type.vec(dim, Type.f32),
t.params,
cases
);
});
g.test('vector_scalar_compound')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x *= y, where x is a vector and y is a scalar
Accuracy: Correctly rounded
`
)
.params(u => u.combine('inputSource', allInputSources).combine('dim', [2, 3, 4] as const))
.fn(async t => {
const dim = t.params.dim;
const cases = await d.get(
t.params.inputSource === 'const' ? `vec${dim}_scalar_const` : `vec${dim}_scalar_non_const`
);
await run(
t,
compoundBinary('*='),
[Type.vec(dim, Type.f32), Type.f32],
Type.vec(dim, Type.f32),
t.params,
cases
);
});
g.test('scalar_vector')
.specURL('https://www.w3.org/TR/WGSL/#floating-point-evaluation')
.desc(
`
Expression: x * y, where x is a scalar and y is a vector
Accuracy: Correctly rounded
`
)
.params(u => u.combine('inputSource', allInputSources).combine('dim', [2, 3, 4] as const))
.fn(async t => {
const dim = t.params.dim;
const cases = await d.get(
t.params.inputSource === 'const' ? `scalar_vec${dim}_const` : `scalar_vec${dim}_non_const`
);
await run(
t,
binary('*'),
[Type.f32, Type.vec(dim, Type.f32)],
Type.vec(dim, Type.f32),
t.params,
cases
);
});
|
