export const description = ` Util math unit tests. `; import { makeTestGroup } from '../common/framework/test_group.js'; import { objectEquals } from '../common/util/util.js'; import { kBit, kValue } from '../webgpu/util/constants.js'; import { f16, f32, f64, float16ToUint16, float32ToUint32, uint16ToFloat16, uint32ToFloat32, } from '../webgpu/util/conversion.js'; import { biasedRange, calculatePermutations, cartesianProduct, correctlyRoundedF16, correctlyRoundedF32, FlushMode, frexp, fullF16Range, fullF32Range, fullI32Range, lerp, linearRange, nextAfterF16, nextAfterF32, nextAfterF64, NextDirection, oneULPF16, oneULPF32, oneULPF64, lerpBigInt, linearRangeBigInt, } from '../webgpu/util/math.js'; import { reinterpretU16AsF16, reinterpretU32AsF32, reinterpretU64AsF64, } from '../webgpu/util/reinterpret.js'; import { UnitTest } from './unit_test.js'; export const g = makeTestGroup(UnitTest); /** * Utility wrapper around oneULP to test if a value is within 1 ULP(x) * * @param got number to test * @param expected number to be within 1 ULP of * @param mode should oneULP FTZ * @returns if got is within 1 ULP of expected */ function withinOneULPF32(got: number, expected: number, mode: FlushMode): boolean { const ulp = oneULPF32(expected, mode); return got >= expected - ulp && got <= expected + ulp; } /** * @returns true if arrays are equal within 1ULP, doing element-wise comparison * as needed, and considering NaNs to be equal. * * Depends on the correctness of oneULP, which is tested in this file. ** * @param got array of numbers to compare for equality * @param expect array of numbers to compare against * @param mode should different subnormals be considered the same, i.e. should * FTZ occur during comparison **/ function compareArrayOfNumbersF32( got: readonly number[], expect: readonly number[], mode: FlushMode = 'flush' ): boolean { return ( got.length === expect.length && got.every((value, index) => { const expected = expect[index]; return ( (Number.isNaN(value) && Number.isNaN(expected)) || withinOneULPF32(value, expected, mode) ); }) ); } /** @returns the hex value representation of a f64, from is numeric representation */ function float64ToUint64(value: number): bigint { return new BigUint64Array(new Float64Array([value]).buffer)[0]; } /** @returns the numeric representation of a f64, from its hex value representation */ function uint64ToFloat64(bits: bigint): number { return new Float64Array(new BigUint64Array([bits]).buffer)[0]; } interface nextAfterCase { val: number; dir: NextDirection; result: number; } g.test('nextAfterF64FlushToZero') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f64.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f64.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f64.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f64.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f64.positive.min }, { val: +0, dir: 'negative', result: kValue.f64.negative.max }, { val: -0, dir: 'positive', result: kValue.f64.positive.min }, { val: -0, dir: 'negative', result: kValue.f64.negative.max }, // Subnormals { val: kValue.f64.positive.subnormal.min, dir: 'positive', result: kValue.f64.positive.min }, { val: kValue.f64.positive.subnormal.min, dir: 'negative', result: kValue.f64.negative.max }, { val: kValue.f64.positive.subnormal.max, dir: 'positive', result: kValue.f64.positive.min }, { val: kValue.f64.positive.subnormal.max, dir: 'negative', result: kValue.f64.negative.max }, { val: kValue.f64.negative.subnormal.min, dir: 'positive', result: kValue.f64.positive.min }, { val: kValue.f64.negative.subnormal.min, dir: 'negative', result: kValue.f64.negative.max }, { val: kValue.f64.negative.subnormal.max, dir: 'positive', result: kValue.f64.positive.min }, { val: kValue.f64.negative.subnormal.max, dir: 'negative', result: kValue.f64.negative.max }, // Normals { val: kValue.f64.positive.max, dir: 'positive', result: kValue.f64.positive.infinity }, { val: kValue.f64.positive.max, dir: 'negative', result: kValue.f64.positive.nearest_max }, { val: kValue.f64.positive.min, dir: 'positive', result: reinterpretU64AsF64(0x0010_0000_0000_0001n ) }, { val: kValue.f64.positive.min, dir: 'negative', result: 0 }, { val: kValue.f64.negative.max, dir: 'positive', result: 0 }, { val: kValue.f64.negative.max, dir: 'negative', result: reinterpretU64AsF64(0x8010_0000_0000_0001n) }, { val: kValue.f64.negative.min, dir: 'positive', result: kValue.f64.negative.nearest_min }, { val: kValue.f64.negative.min, dir: 'negative', result: kValue.f64.negative.infinity }, { val: reinterpretU64AsF64(0x0380_0000_0000_0000n), dir: 'positive', result: reinterpretU64AsF64(0x0380_0000_0000_0001n) }, { val: reinterpretU64AsF64(0x0380_0000_0000_0000n), dir: 'negative', result: reinterpretU64AsF64(0x037f_ffff_ffff_ffffn) }, { val: reinterpretU64AsF64(0x8380_0000_0000_0000n), dir: 'positive', result: reinterpretU64AsF64(0x837f_ffff_ffff_ffffn) }, { val: reinterpretU64AsF64(0x8380_0000_0000_0000n), dir: 'negative', result: reinterpretU64AsF64(0x8380_0000_0000_0001n) }, ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF64(val, dir, 'flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF64(${f64(val)}, '${dir}', 'flush') returned ${f64(got)}. Expected ${f64(expect)}` ); }); g.test('nextAfterF64NoFlush') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f64.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f64.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f64.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f64.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f64.positive.subnormal.min }, { val: +0, dir: 'negative', result: kValue.f64.negative.subnormal.max }, { val: -0, dir: 'positive', result: kValue.f64.positive.subnormal.min }, { val: -0, dir: 'negative', result: kValue.f64.negative.subnormal.max }, // Subnormals { val: kValue.f64.positive.subnormal.min, dir: 'positive', result: reinterpretU64AsF64(0x0000_0000_0000_0002n) }, { val: kValue.f64.positive.subnormal.min, dir: 'negative', result: 0 }, { val: kValue.f64.positive.subnormal.max, dir: 'positive', result: kValue.f64.positive.min }, { val: kValue.f64.positive.subnormal.max, dir: 'negative', result: reinterpretU64AsF64(0x000f_ffff_ffff_fffen) }, { val: kValue.f64.negative.subnormal.min, dir: 'positive', result: reinterpretU64AsF64(0x800f_ffff_ffff_fffen) }, { val: kValue.f64.negative.subnormal.min, dir: 'negative', result: kValue.f64.negative.max }, { val: kValue.f64.negative.subnormal.max, dir: 'positive', result: 0 }, { val: kValue.f64.negative.subnormal.max, dir: 'negative', result: reinterpretU64AsF64(0x8000_0000_0000_0002n) }, // Normals { val: kValue.f64.positive.max, dir: 'positive', result: kValue.f64.positive.infinity }, { val: kValue.f64.positive.max, dir: 'negative', result: kValue.f64.positive.nearest_max }, { val: kValue.f64.positive.min, dir: 'positive', result: reinterpretU64AsF64(0x0010_0000_0000_0001n ) }, { val: kValue.f64.positive.min, dir: 'negative', result: reinterpretU64AsF64(0x000f_ffff_ffff_ffffn) }, { val: kValue.f64.negative.max, dir: 'positive', result: reinterpretU64AsF64(0x800f_ffff_ffff_ffffn) }, { val: kValue.f64.negative.max, dir: 'negative', result: reinterpretU64AsF64(0x8010_0000_0000_0001n) }, { val: kValue.f64.negative.min, dir: 'positive', result: kValue.f64.negative.nearest_min }, { val: kValue.f64.negative.min, dir: 'negative', result: kValue.f64.negative.infinity }, { val: reinterpretU64AsF64(0x0380_0000_0000_0000n), dir: 'positive', result: reinterpretU64AsF64(0x0380_0000_0000_0001n) }, { val: reinterpretU64AsF64(0x0380_0000_0000_0000n), dir: 'negative', result: reinterpretU64AsF64(0x037f_ffff_ffff_ffffn) }, { val: reinterpretU64AsF64(0x8380_0000_0000_0000n), dir: 'positive', result: reinterpretU64AsF64(0x837f_ffff_ffff_ffffn) }, { val: reinterpretU64AsF64(0x8380_0000_0000_0000n), dir: 'negative', result: reinterpretU64AsF64(0x8380_0000_0000_0001n) }, ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF64(val, dir, 'no-flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF64(${f64(val)}, '${dir}', 'no-flush') returned ${f64(got)}. Expected ${f64( expect )}` ); }); g.test('nextAfterF32FlushToZero') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f32.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f32.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f32.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f32.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f32.positive.min }, { val: +0, dir: 'negative', result: kValue.f32.negative.max }, { val: -0, dir: 'positive', result: kValue.f32.positive.min }, { val: -0, dir: 'negative', result: kValue.f32.negative.max }, // Subnormals { val: kValue.f32.positive.subnormal.min, dir: 'positive', result: kValue.f32.positive.min }, { val: kValue.f32.positive.subnormal.min, dir: 'negative', result: kValue.f32.negative.max }, { val: kValue.f32.positive.subnormal.max, dir: 'positive', result: kValue.f32.positive.min }, { val: kValue.f32.positive.subnormal.max, dir: 'negative', result: kValue.f32.negative.max }, { val: kValue.f32.negative.subnormal.min, dir: 'positive', result: kValue.f32.positive.min }, { val: kValue.f32.negative.subnormal.min, dir: 'negative', result: kValue.f32.negative.max }, { val: kValue.f32.negative.subnormal.max, dir: 'positive', result: kValue.f32.positive.min }, { val: kValue.f32.negative.subnormal.max, dir: 'negative', result: kValue.f32.negative.max }, // Normals { val: kValue.f32.positive.max, dir: 'positive', result: kValue.f32.positive.infinity }, { val: kValue.f32.positive.max, dir: 'negative', result: kValue.f32.positive.nearest_max }, { val: kValue.f32.positive.min, dir: 'positive', result: reinterpretU32AsF32(0x00800001) }, { val: kValue.f32.positive.min, dir: 'negative', result: 0 }, { val: kValue.f32.negative.max, dir: 'positive', result: 0 }, { val: kValue.f32.negative.max, dir: 'negative', result: reinterpretU32AsF32(0x80800001) }, { val: kValue.f32.negative.min, dir: 'positive', result: reinterpretU32AsF32(0xff7ffffe) }, { val: kValue.f32.negative.min, dir: 'negative', result: kValue.f32.negative.infinity }, { val: reinterpretU32AsF32(0x03800000), dir: 'positive', result: reinterpretU32AsF32(0x03800001) }, { val: reinterpretU32AsF32(0x03800000), dir: 'negative', result: reinterpretU32AsF32(0x037fffff) }, { val: reinterpretU32AsF32(0x83800000), dir: 'positive', result: reinterpretU32AsF32(0x837fffff) }, { val: reinterpretU32AsF32(0x83800000), dir: 'negative', result: reinterpretU32AsF32(0x83800001) }, // Not precisely expressible as f32 { val: 0.001, dir: 'positive', result: reinterpretU32AsF32(0x3a83126f) }, // positive normal { val: 0.001, dir: 'negative', result: reinterpretU32AsF32(0x3a83126e) }, // positive normal { val: -0.001, dir: 'positive', result: reinterpretU32AsF32(0xba83126e) }, // negative normal { val: -0.001, dir: 'negative', result: reinterpretU32AsF32(0xba83126f) }, // negative normal { val: 2.82E-40, dir: 'positive', result: kValue.f32.positive.min }, // positive subnormal { val: 2.82E-40, dir: 'negative', result: kValue.f32.negative.max }, // positive subnormal { val: -2.82E-40, dir: 'positive', result: kValue.f32.positive.min }, // negative subnormal { val: -2.82E-40, dir: 'negative', result: kValue.f32.negative.max }, // negative subnormal ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF32(val, dir, 'flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF32(${f64(val)}, '${dir}', 'flush') returned ${f32(got)}. Expected ${f32(expect)}` ); }); g.test('nextAfterF32NoFlush') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f32.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f32.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f32.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f32.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f32.positive.subnormal.min }, { val: +0, dir: 'negative', result: kValue.f32.negative.subnormal.max }, { val: -0, dir: 'positive', result: kValue.f32.positive.subnormal.min }, { val: -0, dir: 'negative', result: kValue.f32.negative.subnormal.max }, // Subnormals { val:kValue.f32.positive.subnormal.min, dir: 'positive', result: reinterpretU32AsF32(0x00000002) }, { val:kValue.f32.positive.subnormal.min, dir: 'negative', result: 0 }, { val:kValue.f32.positive.subnormal.max, dir: 'positive', result: kValue.f32.positive.min }, { val:kValue.f32.positive.subnormal.max, dir: 'negative', result: reinterpretU32AsF32(0x007ffffe) }, { val:kValue.f32.negative.subnormal.min, dir: 'positive', result: reinterpretU32AsF32(0x807ffffe) }, { val:kValue.f32.negative.subnormal.min, dir: 'negative', result: kValue.f32.negative.max }, { val:kValue.f32.negative.subnormal.max, dir: 'positive', result: 0 }, { val:kValue.f32.negative.subnormal.max, dir: 'negative', result: reinterpretU32AsF32(0x80000002) }, // Normals { val: kValue.f32.positive.max, dir: 'positive', result: kValue.f32.positive.infinity }, { val: kValue.f32.positive.max, dir: 'negative', result: kValue.f32.positive.nearest_max }, { val: kValue.f32.positive.min, dir: 'positive', result: reinterpretU32AsF32(0x00800001) }, { val: kValue.f32.positive.min, dir: 'negative', result: kValue.f32.positive.subnormal.max }, { val: kValue.f32.negative.max, dir: 'positive', result: kValue.f32.negative.subnormal.min }, { val: kValue.f32.negative.max, dir: 'negative', result: reinterpretU32AsF32(0x80800001) }, { val: kValue.f32.negative.min, dir: 'positive', result: kValue.f32.negative.nearest_min }, { val: kValue.f32.negative.min, dir: 'negative', result: kValue.f32.negative.infinity }, { val: reinterpretU32AsF32(0x03800000), dir: 'positive', result: reinterpretU32AsF32(0x03800001) }, { val: reinterpretU32AsF32(0x03800000), dir: 'negative', result: reinterpretU32AsF32(0x037fffff) }, { val: reinterpretU32AsF32(0x83800000), dir: 'positive', result: reinterpretU32AsF32(0x837fffff) }, { val: reinterpretU32AsF32(0x83800000), dir: 'negative', result: reinterpretU32AsF32(0x83800001) }, // Not precisely expressible as f32 { val: 0.001, dir: 'positive', result: reinterpretU32AsF32(0x3a83126f) }, // positive normal { val: 0.001, dir: 'negative', result: reinterpretU32AsF32(0x3a83126e) }, // positive normal { val: -0.001, dir: 'positive', result: reinterpretU32AsF32(0xba83126e) }, // negative normal { val: -0.001, dir: 'negative', result: reinterpretU32AsF32(0xba83126f) }, // negative normal { val: 2.82E-40, dir: 'positive', result: reinterpretU32AsF32(0x0003121a) }, // positive subnormal { val: 2.82E-40, dir: 'negative', result: reinterpretU32AsF32(0x00031219) }, // positive subnormal { val: -2.82E-40, dir: 'positive', result: reinterpretU32AsF32(0x80031219) }, // negative subnormal { val: -2.82E-40, dir: 'negative', result: reinterpretU32AsF32(0x8003121a) }, // negative subnormal ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF32(val, dir, 'no-flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF32(${f64(val)}, '${dir}', 'no-flush') returned ${f32(got)}. Expected ${f32( expect )}` ); }); g.test('nextAfterF16FlushToZero') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f16.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f16.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f16.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f16.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f16.positive.min }, { val: +0, dir: 'negative', result: kValue.f16.negative.max }, { val: -0, dir: 'positive', result: kValue.f16.positive.min }, { val: -0, dir: 'negative', result: kValue.f16.negative.max }, // Subnormals { val: kValue.f16.positive.subnormal.min, dir: 'positive', result: kValue.f16.positive.min }, { val: kValue.f16.positive.subnormal.min, dir: 'negative', result: kValue.f16.negative.max }, { val: kValue.f16.positive.subnormal.max, dir: 'positive', result: kValue.f16.positive.min }, { val: kValue.f16.positive.subnormal.max, dir: 'negative', result: kValue.f16.negative.max }, { val: kValue.f16.negative.subnormal.min, dir: 'positive', result: kValue.f16.positive.min }, { val: kValue.f16.negative.subnormal.min, dir: 'negative', result: kValue.f16.negative.max }, { val: kValue.f16.negative.subnormal.max, dir: 'positive', result: kValue.f16.positive.min }, { val: kValue.f16.negative.subnormal.max, dir: 'negative', result: kValue.f16.negative.max }, // Normals { val: kValue.f16.positive.max, dir: 'positive', result: kValue.f16.positive.infinity }, { val: kValue.f16.positive.max, dir: 'negative', result: reinterpretU16AsF16(0x7bfe) }, { val: kValue.f16.positive.min, dir: 'positive', result: reinterpretU16AsF16(0x0401) }, { val: kValue.f16.positive.min, dir: 'negative', result: 0 }, { val: kValue.f16.negative.max, dir: 'positive', result: 0 }, { val: kValue.f16.negative.max, dir: 'negative', result: reinterpretU16AsF16(0x8401) }, { val: kValue.f16.negative.min, dir: 'positive', result: reinterpretU16AsF16(0xfbfe) }, { val: kValue.f16.negative.min, dir: 'negative', result: kValue.f16.negative.infinity }, { val: reinterpretU16AsF16(0x1380), dir: 'positive', result: reinterpretU16AsF16(0x1381) }, { val: reinterpretU16AsF16(0x1380), dir: 'negative', result: reinterpretU16AsF16(0x137f) }, { val: reinterpretU16AsF16(0x9380), dir: 'positive', result: reinterpretU16AsF16(0x937f) }, { val: reinterpretU16AsF16(0x9380), dir: 'negative', result: reinterpretU16AsF16(0x9381) }, // Not precisely expressible as f16 { val: 0.01, dir: 'positive', result: reinterpretU16AsF16(0x211f) }, // positive normal { val: 0.01, dir: 'negative', result: reinterpretU16AsF16(0x211e) }, // positive normal { val: -0.01, dir: 'positive', result: reinterpretU16AsF16(0xa11e) }, // negative normal { val: -0.01, dir: 'negative', result: reinterpretU16AsF16(0xa11f) }, // negative normal { val: 2.82E-40, dir: 'positive', result: kValue.f16.positive.min }, // positive subnormal { val: 2.82E-40, dir: 'negative', result: kValue.f16.negative.max }, // positive subnormal { val: -2.82E-40, dir: 'positive', result: kValue.f16.positive.min }, // negative subnormal { val: -2.82E-40, dir: 'negative', result: kValue.f16.negative.max }, // negative subnormal ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF16(val, dir, 'flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF16(${f64(val)}, '${dir}', 'flush') returned ${f16(got)}. Expected ${f16(expect)}` ); }); g.test('nextAfterF16NoFlush') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { val: Number.NaN, dir: 'positive', result: Number.NaN }, { val: Number.NaN, dir: 'negative', result: Number.NaN }, { val: Number.POSITIVE_INFINITY, dir: 'positive', result: kValue.f16.positive.infinity }, { val: Number.POSITIVE_INFINITY, dir: 'negative', result: kValue.f16.positive.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'positive', result: kValue.f16.negative.infinity }, { val: Number.NEGATIVE_INFINITY, dir: 'negative', result: kValue.f16.negative.infinity }, // Zeroes { val: +0, dir: 'positive', result: kValue.f16.positive.subnormal.min }, { val: +0, dir: 'negative', result: kValue.f16.negative.subnormal.max }, { val: -0, dir: 'positive', result: kValue.f16.positive.subnormal.min }, { val: -0, dir: 'negative', result: kValue.f16.negative.subnormal.max }, // Subnormals { val: kValue.f16.positive.subnormal.min, dir: 'positive', result: reinterpretU16AsF16(0x0002) }, { val: kValue.f16.positive.subnormal.min, dir: 'negative', result: 0 }, { val: kValue.f16.positive.subnormal.max, dir: 'positive', result: kValue.f16.positive.min }, { val: kValue.f16.positive.subnormal.max, dir: 'negative', result: reinterpretU16AsF16(0x03fe) }, { val: kValue.f16.negative.subnormal.min, dir: 'positive', result: reinterpretU16AsF16(0x83fe) }, { val: kValue.f16.negative.subnormal.min, dir: 'negative', result: kValue.f16.negative.max }, { val: kValue.f16.negative.subnormal.max, dir: 'positive', result: 0 }, { val: kValue.f16.negative.subnormal.max, dir: 'negative', result: reinterpretU16AsF16(0x8002) }, // Normals { val: kValue.f16.positive.max, dir: 'positive', result: kValue.f16.positive.infinity }, { val: kValue.f16.positive.max, dir: 'negative', result: reinterpretU16AsF16(0x7bfe) }, { val: kValue.f16.positive.min, dir: 'positive', result: reinterpretU16AsF16(0x0401) }, { val: kValue.f16.positive.min, dir: 'negative', result: kValue.f16.positive.subnormal.max }, { val: kValue.f16.negative.max, dir: 'positive', result: kValue.f16.negative.subnormal.min }, { val: kValue.f16.negative.max, dir: 'negative', result: reinterpretU16AsF16(0x8401) }, { val: kValue.f16.negative.min, dir: 'positive', result: reinterpretU16AsF16(0xfbfe) }, { val: kValue.f16.negative.min, dir: 'negative', result: kValue.f16.negative.infinity }, { val: reinterpretU16AsF16(0x1380), dir: 'positive', result: reinterpretU16AsF16(0x1381) }, { val: reinterpretU16AsF16(0x1380), dir: 'negative', result: reinterpretU16AsF16(0x137f) }, { val: reinterpretU16AsF16(0x9380), dir: 'positive', result: reinterpretU16AsF16(0x937f) }, { val: reinterpretU16AsF16(0x9380), dir: 'negative', result: reinterpretU16AsF16(0x9381) }, // Not precisely expressible as f16 { val: 0.01, dir: 'positive', result: reinterpretU16AsF16(0x211f) }, // positive normal { val: 0.01, dir: 'negative', result: reinterpretU16AsF16(0x211e) }, // positive normal { val: -0.01, dir: 'positive', result: reinterpretU16AsF16(0xa11e) }, // negative normal { val: -0.01, dir: 'negative', result: reinterpretU16AsF16(0xa11f) }, // negative normal { val: 2.82E-40, dir: 'positive', result: kValue.f16.positive.subnormal.min }, // positive subnormal { val: 2.82E-40, dir: 'negative', result: 0 }, // positive subnormal { val: -2.82E-40, dir: 'positive', result: 0 }, // negative subnormal { val: -2.82E-40, dir: 'negative', result: kValue.f16.negative.subnormal.max }, // negative subnormal ] ) .fn(t => { const val = t.params.val; const dir = t.params.dir; const expect = t.params.result; const got = nextAfterF16(val, dir, 'no-flush'); t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `nextAfterF16(${f64(val)}, '${dir}', 'no-flush') returned ${f16(got)}. Expected ${f16( expect )}` ); }); interface OneULPCase { target: number; expect: number; } g.test('oneULPF64FlushToZero') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, // Zeroes { target: +0, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n) }, { target: -0, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n) }, // Subnormals { target: kValue.f64.positive.subnormal.min, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.positive.subnormal.max, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.negative.subnormal.min, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.negative.subnormal.max, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, // Normals { target: kValue.f64.positive.min, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: 1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: 2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: 4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: 1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.positive.max, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: kValue.f64.negative.max, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: -1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: -2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: -4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: -1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.negative.min, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, ]) .fn(t => { const target = t.params.target; const got = oneULPF64(target, 'flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF64(${f64(target)}, 'flush') returned ${f64(got)}. Expected ${f64(expect)}` ); }); g.test('oneULPF64NoFlush') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, // Zeroes { target: +0, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: -0, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, // Subnormals { target: kValue.f64.positive.subnormal.min, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n), }, { target: kValue.f64.positive.subnormal.max, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n), }, { target: kValue.f64.negative.subnormal.min, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n), }, { target: kValue.f64.negative.subnormal.max, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n), }, // Normals { target: kValue.f64.positive.min, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: 1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: 2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: 4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: 1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.positive.max, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: kValue.f64.negative.max, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: -1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: -2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: -4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: -1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.negative.min, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, ]) .fn(t => { const target = t.params.target; const got = oneULPF64(target, 'no-flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF64(${f64(target)}, 'no-flush') returned ${f64(got)}. Expected ${f64(expect)}` ); }); g.test('oneULPF64') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, // Zeroes { target: +0, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n) }, { target: -0, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n) }, // Subnormals { target: kValue.f64.positive.subnormal.min, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.positive.subnormal.max, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.negative.subnormal.min, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, { target: kValue.f64.negative.subnormal.max, expect: reinterpretU64AsF64(0x0010_0000_0000_0000n), }, // Normals { target: kValue.f64.positive.min, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: 1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: 2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: 4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: 1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.positive.max, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, { target: kValue.f64.negative.max, expect: reinterpretU64AsF64(0x0000_0000_0000_0001n) }, { target: -1, expect: reinterpretU64AsF64(0x3ca0_0000_0000_0000n) }, { target: -2, expect: reinterpretU64AsF64(0x3cb0_0000_0000_0000n) }, { target: -4, expect: reinterpretU64AsF64(0x3cc0_0000_0000_0000n) }, { target: -1000000, expect: reinterpretU64AsF64(0x3de0_0000_0000_0000n) }, { target: kValue.f64.negative.min, expect: reinterpretU64AsF64(0x7ca0_0000_0000_0000n) }, ]) .fn(t => { const target = t.params.target; const got = oneULPF64(target); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF64(${f64(target)}) returned ${f64(got)}. Expected ${f64(expect)}` ); }); g.test('oneULPF32FlushToZero') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, // Zeroes { target: +0, expect: reinterpretU32AsF32(0x00800000) }, { target: -0, expect: reinterpretU32AsF32(0x00800000) }, // Subnormals { target: kValue.f32.positive.subnormal.min, expect: reinterpretU32AsF32(0x00800000) }, { target: 2.82e-40, expect: reinterpretU32AsF32(0x00800000) }, // positive subnormal { target: kValue.f32.positive.subnormal.max, expect: reinterpretU32AsF32(0x00800000) }, { target: kValue.f32.negative.subnormal.min, expect: reinterpretU32AsF32(0x00800000) }, { target: -2.82e-40, expect: reinterpretU32AsF32(0x00800000) }, // negative subnormal { target: kValue.f32.negative.subnormal.max, expect: reinterpretU32AsF32(0x00800000) }, // Normals { target: kValue.f32.positive.min, expect: reinterpretU32AsF32(0x00000001) }, { target: 1, expect: reinterpretU32AsF32(0x33800000) }, { target: 2, expect: reinterpretU32AsF32(0x34000000) }, { target: 4, expect: reinterpretU32AsF32(0x34800000) }, { target: 1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.positive.max, expect: reinterpretU32AsF32(0x73800000) }, { target: kValue.f32.negative.max, expect: reinterpretU32AsF32(0x00000001) }, { target: -1, expect: reinterpretU32AsF32(0x33800000) }, { target: -2, expect: reinterpretU32AsF32(0x34000000) }, { target: -4, expect: reinterpretU32AsF32(0x34800000) }, { target: -1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.negative.min, expect: reinterpretU32AsF32(0x73800000) }, // No precise f32 value { target: 0.001, expect: reinterpretU32AsF32(0x2f000000) }, // positive normal { target: -0.001, expect: reinterpretU32AsF32(0x2f000000) }, // negative normal { target: 1e40, expect: reinterpretU32AsF32(0x73800000) }, // positive out of range { target: -1e40, expect: reinterpretU32AsF32(0x73800000) }, // negative out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF32(target, 'flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF32(${target}, 'flush') returned ${got}. Expected ${expect}` ); }); g.test('oneULPF32NoFlush') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, // Zeroes { target: +0, expect: reinterpretU32AsF32(0x00000001) }, { target: -0, expect: reinterpretU32AsF32(0x00000001) }, // Subnormals { target: kValue.f32.positive.subnormal.min, expect: reinterpretU32AsF32(0x00000001) }, { target: -2.82e-40, expect: reinterpretU32AsF32(0x00000001) }, // negative subnormal { target: kValue.f32.positive.subnormal.max, expect: reinterpretU32AsF32(0x00000001) }, { target: kValue.f32.negative.subnormal.min, expect: reinterpretU32AsF32(0x00000001) }, { target: 2.82e-40, expect: reinterpretU32AsF32(0x00000001) }, // positive subnormal { target: kValue.f32.negative.subnormal.max, expect: reinterpretU32AsF32(0x00000001) }, // Normals { target: kValue.f32.positive.min, expect: reinterpretU32AsF32(0x00000001) }, { target: 1, expect: reinterpretU32AsF32(0x33800000) }, { target: 2, expect: reinterpretU32AsF32(0x34000000) }, { target: 4, expect: reinterpretU32AsF32(0x34800000) }, { target: 1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.positive.max, expect: reinterpretU32AsF32(0x73800000) }, { target: kValue.f32.negative.max, expect: reinterpretU32AsF32(0x00000001) }, { target: -1, expect: reinterpretU32AsF32(0x33800000) }, { target: -2, expect: reinterpretU32AsF32(0x34000000) }, { target: -4, expect: reinterpretU32AsF32(0x34800000) }, { target: -1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.negative.min, expect: reinterpretU32AsF32(0x73800000) }, // No precise f32 value { target: 0.001, expect: reinterpretU32AsF32(0x2f000000) }, // positive normal { target: -0.001, expect: reinterpretU32AsF32(0x2f000000) }, // negative normal { target: 1e40, expect: reinterpretU32AsF32(0x73800000) }, // positive out of range { target: -1e40, expect: reinterpretU32AsF32(0x73800000) }, // negative out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF32(target, 'no-flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF32(${target}, no-flush) returned ${got}. Expected ${expect}` ); }); g.test('oneULPF32') .paramsSimple([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU32AsF32(0x73800000) }, // Zeroes { target: +0, expect: reinterpretU32AsF32(0x00800000) }, { target: -0, expect: reinterpretU32AsF32(0x00800000) }, // Subnormals { target: kValue.f32.negative.subnormal.max, expect: reinterpretU32AsF32(0x00800000) }, { target: -2.82e-40, expect: reinterpretU32AsF32(0x00800000) }, { target: kValue.f32.negative.subnormal.min, expect: reinterpretU32AsF32(0x00800000) }, { target: kValue.f32.positive.subnormal.max, expect: reinterpretU32AsF32(0x00800000) }, { target: 2.82e-40, expect: reinterpretU32AsF32(0x00800000) }, { target: kValue.f32.positive.subnormal.min, expect: reinterpretU32AsF32(0x00800000) }, // Normals { target: kValue.f32.positive.min, expect: reinterpretU32AsF32(0x00000001) }, { target: 1, expect: reinterpretU32AsF32(0x33800000) }, { target: 2, expect: reinterpretU32AsF32(0x34000000) }, { target: 4, expect: reinterpretU32AsF32(0x34800000) }, { target: 1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.positive.max, expect: reinterpretU32AsF32(0x73800000) }, { target: kValue.f32.negative.max, expect: reinterpretU32AsF32(0x000000001) }, { target: -1, expect: reinterpretU32AsF32(0x33800000) }, { target: -2, expect: reinterpretU32AsF32(0x34000000) }, { target: -4, expect: reinterpretU32AsF32(0x34800000) }, { target: -1000000, expect: reinterpretU32AsF32(0x3d800000) }, { target: kValue.f32.negative.min, expect: reinterpretU32AsF32(0x73800000) }, // No precise f32 value { target: -0.001, expect: reinterpretU32AsF32(0x2f000000) }, // negative normal { target: -1e40, expect: reinterpretU32AsF32(0x73800000) }, // negative out of range { target: 0.001, expect: reinterpretU32AsF32(0x2f000000) }, // positive normal { target: 1e40, expect: reinterpretU32AsF32(0x73800000) }, // positive out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF32(target); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF32(${target}) returned ${got}. Expected ${expect}` ); }); g.test('oneULPF16FlushToZero') .paramsSubcasesOnly([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, // Zeroes, expect positive.min in flush mode { target: +0, expect: reinterpretU16AsF16(0x0400) }, { target: -0, expect: reinterpretU16AsF16(0x0400) }, // Subnormals { target: kValue.f16.positive.subnormal.min, expect: reinterpretU16AsF16(0x0400) }, { target: 1.91e-6, expect: reinterpretU16AsF16(0x0400) }, // positive subnormal { target: kValue.f16.positive.subnormal.max, expect: reinterpretU16AsF16(0x0400) }, { target: kValue.f16.negative.subnormal.min, expect: reinterpretU16AsF16(0x0400) }, { target: -1.91e-6, expect: reinterpretU16AsF16(0x0400) }, // negative subnormal { target: kValue.f16.negative.subnormal.max, expect: reinterpretU16AsF16(0x0400) }, // Normals { target: kValue.f16.positive.min, expect: reinterpretU16AsF16(0x0001) }, { target: 1, expect: reinterpretU16AsF16(0x1000) }, { target: 2, expect: reinterpretU16AsF16(0x1400) }, { target: 4, expect: reinterpretU16AsF16(0x1800) }, { target: 1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.positive.max, expect: reinterpretU16AsF16(0x5000) }, { target: kValue.f16.negative.max, expect: reinterpretU16AsF16(0x0001) }, { target: -1, expect: reinterpretU16AsF16(0x1000) }, { target: -2, expect: reinterpretU16AsF16(0x1400) }, { target: -4, expect: reinterpretU16AsF16(0x1800) }, { target: -1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.negative.min, expect: reinterpretU16AsF16(0x5000) }, // No precise f16 value { target: 0.001, expect: reinterpretU16AsF16(0x0010) }, // positive normal { target: -0.001, expect: reinterpretU16AsF16(0x0010) }, // negative normal { target: 1e8, expect: reinterpretU16AsF16(0x5000) }, // positive out of range { target: -1e8, expect: reinterpretU16AsF16(0x5000) }, // negative out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF16(target, 'flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF16(${target}, 'flush') returned ${got}. Expected ${expect}` ); }); g.test('oneULPF16NoFlush') .paramsSubcasesOnly([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, // Zeroes, expect positive.min in flush mode { target: +0, expect: reinterpretU16AsF16(0x0001) }, { target: -0, expect: reinterpretU16AsF16(0x0001) }, // Subnormals { target: kValue.f16.positive.subnormal.min, expect: reinterpretU16AsF16(0x0001) }, { target: 1.91e-6, expect: reinterpretU16AsF16(0x0001) }, // positive subnormal { target: kValue.f16.positive.subnormal.max, expect: reinterpretU16AsF16(0x0001) }, { target: kValue.f16.negative.subnormal.min, expect: reinterpretU16AsF16(0x0001) }, { target: -1.91e-6, expect: reinterpretU16AsF16(0x0001) }, // negative subnormal { target: kValue.f16.negative.subnormal.max, expect: reinterpretU16AsF16(0x0001) }, // Normals { target: kValue.f16.positive.min, expect: reinterpretU16AsF16(0x0001) }, { target: 1, expect: reinterpretU16AsF16(0x1000) }, { target: 2, expect: reinterpretU16AsF16(0x1400) }, { target: 4, expect: reinterpretU16AsF16(0x1800) }, { target: 1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.positive.max, expect: reinterpretU16AsF16(0x5000) }, { target: kValue.f16.negative.max, expect: reinterpretU16AsF16(0x0001) }, { target: -1, expect: reinterpretU16AsF16(0x1000) }, { target: -2, expect: reinterpretU16AsF16(0x1400) }, { target: -4, expect: reinterpretU16AsF16(0x1800) }, { target: -1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.negative.min, expect: reinterpretU16AsF16(0x5000) }, // No precise f16 value { target: 0.001, expect: reinterpretU16AsF16(0x0010) }, // positive normal { target: -0.001, expect: reinterpretU16AsF16(0x0010) }, // negative normal { target: 1e8, expect: reinterpretU16AsF16(0x5000) }, // positive out of range { target: -1e8, expect: reinterpretU16AsF16(0x5000) }, // negative out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF16(target, 'no-flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF16(${target}, no-flush) returned ${got}. Expected ${expect}` ); }); g.test('oneULPF16') .paramsSubcasesOnly([ // Edge Cases { target: Number.NaN, expect: Number.NaN }, { target: Number.POSITIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, { target: Number.NEGATIVE_INFINITY, expect: reinterpretU16AsF16(0x5000) }, // Zeroes, expect positive.min in flush mode { target: +0, expect: reinterpretU16AsF16(0x0400) }, { target: -0, expect: reinterpretU16AsF16(0x0400) }, // Subnormals { target: kValue.f16.positive.subnormal.min, expect: reinterpretU16AsF16(0x0400) }, { target: 1.91e-6, expect: reinterpretU16AsF16(0x0400) }, // positive subnormal { target: kValue.f16.positive.subnormal.max, expect: reinterpretU16AsF16(0x0400) }, { target: kValue.f16.negative.subnormal.min, expect: reinterpretU16AsF16(0x0400) }, { target: -1.91e-6, expect: reinterpretU16AsF16(0x0400) }, // negative subnormal { target: kValue.f16.negative.subnormal.max, expect: reinterpretU16AsF16(0x0400) }, // Normals { target: kValue.f16.positive.min, expect: reinterpretU16AsF16(0x0001) }, { target: 1, expect: reinterpretU16AsF16(0x1000) }, { target: 2, expect: reinterpretU16AsF16(0x1400) }, { target: 4, expect: reinterpretU16AsF16(0x1800) }, { target: 1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.positive.max, expect: reinterpretU16AsF16(0x5000) }, { target: kValue.f16.negative.max, expect: reinterpretU16AsF16(0x0001) }, { target: -1, expect: reinterpretU16AsF16(0x1000) }, { target: -2, expect: reinterpretU16AsF16(0x1400) }, { target: -4, expect: reinterpretU16AsF16(0x1800) }, { target: -1000, expect: reinterpretU16AsF16(0x3800) }, { target: kValue.f16.negative.min, expect: reinterpretU16AsF16(0x5000) }, // No precise f16 value { target: 0.001, expect: reinterpretU16AsF16(0x0010) }, // positive normal { target: -0.001, expect: reinterpretU16AsF16(0x0010) }, // negative normal { target: 1e8, expect: reinterpretU16AsF16(0x5000) }, // positive out of range { target: -1e8, expect: reinterpretU16AsF16(0x5000) }, // negative out of range ]) .fn(t => { const target = t.params.target; const got = oneULPF16(target, 'flush'); const expect = t.params.expect; t.expect( got === expect || (Number.isNaN(got) && Number.isNaN(expect)), `oneULPF16(${target}, 'flush') returned ${got}. Expected ${expect}` ); }); interface correctlyRoundedCase { value: number; expected: Array; } g.test('correctlyRoundedF32') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { value: kValue.f32.positive.max, expected: [kValue.f32.positive.max] }, { value: kValue.f32.negative.min, expected: [kValue.f32.negative.min] }, { value: kValue.f32.positive.max + oneULPF64(kValue.f32.positive.max), expected: [kValue.f32.positive.max, Number.POSITIVE_INFINITY] }, { value: kValue.f32.negative.min - oneULPF64(kValue.f32.negative.min), expected: [Number.NEGATIVE_INFINITY, kValue.f32.negative.min] }, { value: 2 ** (kValue.f32.emax + 1) - oneULPF64(kValue.f32.positive.max), expected: [kValue.f32.positive.max, Number.POSITIVE_INFINITY] }, { value: -(2 ** (kValue.f32.emax + 1)) + oneULPF64(kValue.f32.positive.max), expected: [Number.NEGATIVE_INFINITY, kValue.f32.negative.min] }, { value: 2 ** (kValue.f32.emax + 1), expected: [Number.POSITIVE_INFINITY] }, { value: -(2 ** (kValue.f32.emax + 1)), expected: [Number.NEGATIVE_INFINITY] }, { value: kValue.f32.positive.infinity, expected: [Number.POSITIVE_INFINITY] }, { value: kValue.f32.negative.infinity, expected: [Number.NEGATIVE_INFINITY] }, // 32-bit subnormals { value: kValue.f32.positive.subnormal.min, expected: [kValue.f32.positive.subnormal.min] }, { value: kValue.f32.positive.subnormal.max, expected: [kValue.f32.positive.subnormal.max] }, { value: kValue.f32.negative.subnormal.min, expected: [kValue.f32.negative.subnormal.min] }, { value: kValue.f32.negative.subnormal.max, expected: [kValue.f32.negative.subnormal.max] }, // 64-bit subnormals { value: reinterpretU64AsF64(0x0000_0000_0000_0001n), expected: [0, kValue.f32.positive.subnormal.min] }, { value: reinterpretU64AsF64(0x0000_0000_0000_0002n), expected: [0, kValue.f32.positive.subnormal.min] }, { value: reinterpretU64AsF64(0x800f_ffff_ffff_ffffn), expected: [kValue.f32.negative.subnormal.max, 0] }, { value: reinterpretU64AsF64(0x800f_ffff_ffff_fffen), expected: [kValue.f32.negative.subnormal.max, 0] }, // 32-bit normals { value: 0, expected: [0] }, { value: kValue.f32.positive.min, expected: [kValue.f32.positive.min] }, { value: kValue.f32.negative.max, expected: [kValue.f32.negative.max] }, { value: reinterpretU32AsF32(0x03800000), expected: [reinterpretU32AsF32(0x03800000)] }, { value: reinterpretU32AsF32(0x03800001), expected: [reinterpretU32AsF32(0x03800001)] }, { value: reinterpretU32AsF32(0x83800000), expected: [reinterpretU32AsF32(0x83800000)] }, { value: reinterpretU32AsF32(0x83800001), expected: [reinterpretU32AsF32(0x83800001)] }, // 64-bit normals { value: reinterpretU64AsF64(0x3ff0_0000_0000_0001n), expected: [reinterpretU32AsF32(0x3f800000), reinterpretU32AsF32(0x3f800001)] }, { value: reinterpretU64AsF64(0x3ff0_0000_0000_0002n), expected: [reinterpretU32AsF32(0x3f800000), reinterpretU32AsF32(0x3f800001)] }, { value: reinterpretU64AsF64(0x3ff0_0010_0000_0010n), expected: [reinterpretU32AsF32(0x3f800080), reinterpretU32AsF32(0x3f800081)] }, { value: reinterpretU64AsF64(0x3ff0_0020_0000_0020n), expected: [reinterpretU32AsF32(0x3f800100), reinterpretU32AsF32(0x3f800101)] }, { value: reinterpretU64AsF64(0xbff0_0000_0000_0001n), expected: [reinterpretU32AsF32(0xbf800001), reinterpretU32AsF32(0xbf800000)] }, { value: reinterpretU64AsF64(0xbff0_0000_0000_0002n), expected: [reinterpretU32AsF32(0xbf800001), reinterpretU32AsF32(0xbf800000)] }, { value: reinterpretU64AsF64(0xbff0_0010_0000_0010n), expected: [reinterpretU32AsF32(0xbf800081), reinterpretU32AsF32(0xbf800080)] }, { value: reinterpretU64AsF64(0xbff0_0020_0000_0020n), expected: [reinterpretU32AsF32(0xbf800101), reinterpretU32AsF32(0xbf800100)] }, ] ) .fn(t => { const value = t.params.value; const expected = t.params.expected; const got = correctlyRoundedF32(value); t.expect( objectEquals(expected, got), `correctlyRoundedF32(${f64(value)}) returned [${got.map(f32)}]. Expected [${expected.map( f32 )}]` ); }); g.test('correctlyRoundedF16') .paramsSubcasesOnly( // prettier-ignore [ // Edge Cases { value: kValue.f16.positive.max, expected: [kValue.f16.positive.max] }, { value: kValue.f16.negative.min, expected: [kValue.f16.negative.min] }, { value: kValue.f16.positive.max + oneULPF64(kValue.f16.positive.max), expected: [kValue.f16.positive.max, Number.POSITIVE_INFINITY] }, { value: kValue.f16.negative.min - oneULPF64(kValue.f16.negative.min), expected: [Number.NEGATIVE_INFINITY, kValue.f16.negative.min] }, { value: 2 ** (kValue.f16.emax + 1) - oneULPF64(kValue.f16.positive.max), expected: [kValue.f16.positive.max, Number.POSITIVE_INFINITY] }, { value: -(2 ** (kValue.f16.emax + 1)) + oneULPF64(kValue.f16.positive.max), expected: [Number.NEGATIVE_INFINITY, kValue.f16.negative.min] }, { value: 2 ** (kValue.f16.emax + 1), expected: [Number.POSITIVE_INFINITY] }, { value: -(2 ** (kValue.f16.emax + 1)), expected: [Number.NEGATIVE_INFINITY] }, { value: kValue.f16.positive.infinity, expected: [Number.POSITIVE_INFINITY] }, { value: kValue.f16.negative.infinity, expected: [Number.NEGATIVE_INFINITY] }, // 16-bit subnormals { value: kValue.f16.positive.subnormal.min, expected: [kValue.f16.positive.subnormal.min] }, { value: kValue.f16.positive.subnormal.max, expected: [kValue.f16.positive.subnormal.max] }, { value: kValue.f16.negative.subnormal.min, expected: [kValue.f16.negative.subnormal.min] }, { value: kValue.f16.negative.subnormal.max, expected: [kValue.f16.negative.subnormal.max] }, // 32-bit subnormals { value: kValue.f32.positive.subnormal.min, expected: [0, kValue.f16.positive.subnormal.min] }, { value: kValue.f32.positive.subnormal.max, expected: [0, kValue.f16.positive.subnormal.min] }, { value: kValue.f32.negative.subnormal.max, expected: [kValue.f16.negative.subnormal.max, 0] }, { value: kValue.f32.negative.subnormal.min, expected: [kValue.f16.negative.subnormal.max, 0] }, // 16-bit normals { value: 0, expected: [0] }, { value: kValue.f16.positive.min, expected: [kValue.f16.positive.min] }, { value: kValue.f16.negative.max, expected: [kValue.f16.negative.max] }, { value: reinterpretU16AsF16(0x1380), expected: [reinterpretU16AsF16(0x1380)] }, { value: reinterpretU16AsF16(0x1381), expected: [reinterpretU16AsF16(0x1381)] }, { value: reinterpretU16AsF16(0x9380), expected: [reinterpretU16AsF16(0x9380)] }, { value: reinterpretU16AsF16(0x9381), expected: [reinterpretU16AsF16(0x9381)] }, // 32-bit normals { value: reinterpretU32AsF32(0x3a700001), expected: [reinterpretU16AsF16(0x1380), reinterpretU16AsF16(0x1381)] }, { value: reinterpretU32AsF32(0x3a700002), expected: [reinterpretU16AsF16(0x1380), reinterpretU16AsF16(0x1381)] }, { value: reinterpretU32AsF32(0xba700001), expected: [reinterpretU16AsF16(0x9381), reinterpretU16AsF16(0x9380)] }, { value: reinterpretU32AsF32(0xba700002), expected: [reinterpretU16AsF16(0x9381), reinterpretU16AsF16(0x9380)] }, ] ) .fn(t => { const value = t.params.value; const expected = t.params.expected; const got = correctlyRoundedF16(value); t.expect( objectEquals(expected, got), `correctlyRoundedF16(${f64(value)}) returned [${got.map(f16)}]. Expected [${expected.map( f16 )}]` ); }); interface frexpCase { input: number; fract: number; exp: number; } // prettier-ignore const kFrexpCases = { f32: [ { input: kValue.f32.positive.max, fract: 0.9999999403953552, exp: 128 }, { input: kValue.f32.positive.min, fract: 0.5, exp: -125 }, { input: kValue.f32.negative.max, fract: -0.5, exp: -125 }, { input: kValue.f32.negative.min, fract: -0.9999999403953552, exp: 128 }, { input: kValue.f32.positive.subnormal.max, fract: 0.9999998807907104, exp: -126 }, { input: kValue.f32.positive.subnormal.min, fract: 0.5, exp: -148 }, { input: kValue.f32.negative.subnormal.max, fract: -0.5, exp: -148 }, { input: kValue.f32.negative.subnormal.min, fract: -0.9999998807907104, exp: -126 }, ] as frexpCase[], f16: [ { input: kValue.f16.positive.max, fract: 0.99951171875, exp: 16 }, { input: kValue.f16.positive.min, fract: 0.5, exp: -13 }, { input: kValue.f16.negative.max, fract: -0.5, exp: -13 }, { input: kValue.f16.negative.min, fract: -0.99951171875, exp: 16 }, { input: kValue.f16.positive.subnormal.max, fract: 0.9990234375, exp: -14 }, { input: kValue.f16.positive.subnormal.min, fract: 0.5, exp: -23 }, { input: kValue.f16.negative.subnormal.max, fract: -0.5, exp: -23 }, { input: kValue.f16.negative.subnormal.min, fract: -0.9990234375, exp: -14 }, ] as frexpCase[], f64: [ { input: kValue.f64.positive.max, fract: reinterpretU64AsF64(0x3fef_ffff_ffff_ffffn) /* ~0.9999999999999999 */, exp: 1024 }, { input: kValue.f64.positive.min, fract: 0.5, exp: -1021 }, { input: kValue.f64.negative.max, fract: -0.5, exp: -1021 }, { input: kValue.f64.negative.min, fract: reinterpretU64AsF64(0xbfef_ffff_ffff_ffffn) /* ~-0.9999999999999999 */, exp: 1024 }, { input: kValue.f64.positive.subnormal.max, fract: reinterpretU64AsF64(0x3fef_ffff_ffff_fffen) /* ~0.9999999999999998 */, exp: -1022 }, { input: kValue.f64.positive.subnormal.min, fract: 0.5, exp: -1073 }, { input: kValue.f64.negative.subnormal.max, fract: -0.5, exp: -1073 }, { input: kValue.f64.negative.subnormal.min, fract: reinterpretU64AsF64(0xbfef_ffff_ffff_fffen) /* ~-0.9999999999999998 */, exp: -1022 }, ] as frexpCase[], } as const; g.test('frexp') .params(u => u .combine('trait', ['f32', 'f16', 'f64'] as const) .beginSubcases() .expandWithParams(p => { // prettier-ignore return [ // +/- 0.0 { input: 0, fract: 0, exp: 0 }, { input: -0, fract: -0, exp: 0 }, // Normal float values that can be exactly represented by all float types { input: 0.171875, fract: 0.6875, exp: -2 }, { input: -0.171875, fract: -0.6875, exp: -2 }, { input: 0.5, fract: 0.5, exp: 0 }, { input: -0.5, fract: -0.5, exp: 0 }, { input: 1, fract: 0.5, exp: 1 }, { input: -1, fract: -0.5, exp: 1 }, { input: 2, fract: 0.5, exp: 2 }, { input: -2, fract: -0.5, exp: 2 }, { input: 10000, fract: 0.6103515625, exp: 14 }, { input: -10000, fract: -0.6103515625, exp: 14 }, // Normal ans subnormal cases that are different for each type ...kFrexpCases[p.trait], // Inf and NaN { input: Number.POSITIVE_INFINITY, fract: Number.POSITIVE_INFINITY, exp: 0 }, { input: Number.NEGATIVE_INFINITY, fract: Number.NEGATIVE_INFINITY, exp: 0 }, { input: Number.NaN, fract: Number.NaN, exp: 0 }, ]; }) ) .fn(test => { const input = test.params.input; const got = frexp(input, test.params.trait); const expect = { fract: test.params.fract, exp: test.params.exp }; test.expect( objectEquals(got, expect), `frexp(${input}, ${test.params.trait}) returned { fract: ${got.fract}, exp: ${got.exp} }. Expected { fract: ${expect.fract}, exp: ${expect.exp} }` ); }); interface lerpCase { a: number; b: number; t: number; result: number; } g.test('lerp') .paramsSimple([ // Infinite cases { a: 0.0, b: Number.POSITIVE_INFINITY, t: 0.5, result: Number.NaN }, { a: Number.POSITIVE_INFINITY, b: 0.0, t: 0.5, result: Number.NaN }, { a: Number.NEGATIVE_INFINITY, b: 1.0, t: 0.5, result: Number.NaN }, { a: 1.0, b: Number.NEGATIVE_INFINITY, t: 0.5, result: Number.NaN }, { a: Number.NEGATIVE_INFINITY, b: Number.POSITIVE_INFINITY, t: 0.5, result: Number.NaN }, { a: Number.POSITIVE_INFINITY, b: Number.NEGATIVE_INFINITY, t: 0.5, result: Number.NaN }, { a: 0.0, b: 1.0, t: Number.NEGATIVE_INFINITY, result: Number.NaN }, { a: 1.0, b: 0.0, t: Number.NEGATIVE_INFINITY, result: Number.NaN }, { a: 0.0, b: 1.0, t: Number.POSITIVE_INFINITY, result: Number.NaN }, { a: 1.0, b: 0.0, t: Number.POSITIVE_INFINITY, result: Number.NaN }, // [0.0, 1.0] cases { a: 0.0, b: 1.0, t: -1.0, result: -1.0 }, { a: 0.0, b: 1.0, t: 0.0, result: 0.0 }, { a: 0.0, b: 1.0, t: 0.1, result: 0.1 }, { a: 0.0, b: 1.0, t: 0.01, result: 0.01 }, { a: 0.0, b: 1.0, t: 0.001, result: 0.001 }, { a: 0.0, b: 1.0, t: 0.25, result: 0.25 }, { a: 0.0, b: 1.0, t: 0.5, result: 0.5 }, { a: 0.0, b: 1.0, t: 0.9, result: 0.9 }, { a: 0.0, b: 1.0, t: 0.99, result: 0.99 }, { a: 0.0, b: 1.0, t: 0.999, result: 0.999 }, { a: 0.0, b: 1.0, t: 1.0, result: 1.0 }, { a: 0.0, b: 1.0, t: 2.0, result: 2.0 }, // [1.0, 0.0] cases { a: 1.0, b: 0.0, t: -1.0, result: 2.0 }, { a: 1.0, b: 0.0, t: 0.0, result: 1.0 }, { a: 1.0, b: 0.0, t: 0.1, result: 0.9 }, { a: 1.0, b: 0.0, t: 0.01, result: 0.99 }, { a: 1.0, b: 0.0, t: 0.001, result: 0.999 }, { a: 1.0, b: 0.0, t: 0.25, result: 0.75 }, { a: 1.0, b: 0.0, t: 0.5, result: 0.5 }, { a: 1.0, b: 0.0, t: 0.9, result: 0.1 }, { a: 1.0, b: 0.0, t: 0.99, result: 0.01 }, { a: 1.0, b: 0.0, t: 0.999, result: 0.001 }, { a: 1.0, b: 0.0, t: 1.0, result: 0.0 }, { a: 1.0, b: 0.0, t: 2.0, result: -1.0 }, // [0.0, 10.0] cases { a: 0.0, b: 10.0, t: -1.0, result: -10.0 }, { a: 0.0, b: 10.0, t: 0.0, result: 0.0 }, { a: 0.0, b: 10.0, t: 0.1, result: 1.0 }, { a: 0.0, b: 10.0, t: 0.01, result: 0.1 }, { a: 0.0, b: 10.0, t: 0.001, result: 0.01 }, { a: 0.0, b: 10.0, t: 0.25, result: 2.5 }, { a: 0.0, b: 10.0, t: 0.5, result: 5.0 }, { a: 0.0, b: 10.0, t: 0.9, result: 9.0 }, { a: 0.0, b: 10.0, t: 0.99, result: 9.9 }, { a: 0.0, b: 10.0, t: 0.999, result: 9.99 }, { a: 0.0, b: 10.0, t: 1.0, result: 10.0 }, { a: 0.0, b: 10.0, t: 2.0, result: 20.0 }, // [10.0, 0.0] cases { a: 10.0, b: 0.0, t: -1.0, result: 20.0 }, { a: 10.0, b: 0.0, t: 0.0, result: 10.0 }, { a: 10.0, b: 0.0, t: 0.1, result: 9 }, { a: 10.0, b: 0.0, t: 0.01, result: 9.9 }, { a: 10.0, b: 0.0, t: 0.001, result: 9.99 }, { a: 10.0, b: 0.0, t: 0.25, result: 7.5 }, { a: 10.0, b: 0.0, t: 0.5, result: 5.0 }, { a: 10.0, b: 0.0, t: 0.9, result: 1.0 }, { a: 10.0, b: 0.0, t: 0.99, result: 0.1 }, { a: 10.0, b: 0.0, t: 0.999, result: 0.01 }, { a: 10.0, b: 0.0, t: 1.0, result: 0.0 }, { a: 10.0, b: 0.0, t: 2.0, result: -10.0 }, // [2.0, 10.0] cases { a: 2.0, b: 10.0, t: -1.0, result: -6.0 }, { a: 2.0, b: 10.0, t: 0.0, result: 2.0 }, { a: 2.0, b: 10.0, t: 0.1, result: 2.8 }, { a: 2.0, b: 10.0, t: 0.01, result: 2.08 }, { a: 2.0, b: 10.0, t: 0.001, result: 2.008 }, { a: 2.0, b: 10.0, t: 0.25, result: 4.0 }, { a: 2.0, b: 10.0, t: 0.5, result: 6.0 }, { a: 2.0, b: 10.0, t: 0.9, result: 9.2 }, { a: 2.0, b: 10.0, t: 0.99, result: 9.92 }, { a: 2.0, b: 10.0, t: 0.999, result: 9.992 }, { a: 2.0, b: 10.0, t: 1.0, result: 10.0 }, { a: 2.0, b: 10.0, t: 2.0, result: 18.0 }, // [10.0, 2.0] cases { a: 10.0, b: 2.0, t: -1.0, result: 18.0 }, { a: 10.0, b: 2.0, t: 0.0, result: 10.0 }, { a: 10.0, b: 2.0, t: 0.1, result: 9.2 }, { a: 10.0, b: 2.0, t: 0.01, result: 9.92 }, { a: 10.0, b: 2.0, t: 0.001, result: 9.992 }, { a: 10.0, b: 2.0, t: 0.25, result: 8.0 }, { a: 10.0, b: 2.0, t: 0.5, result: 6.0 }, { a: 10.0, b: 2.0, t: 0.9, result: 2.8 }, { a: 10.0, b: 2.0, t: 0.99, result: 2.08 }, { a: 10.0, b: 2.0, t: 0.999, result: 2.008 }, { a: 10.0, b: 2.0, t: 1.0, result: 2.0 }, { a: 10.0, b: 2.0, t: 2.0, result: -6.0 }, // [-1.0, 1.0] cases { a: -1.0, b: 1.0, t: -2.0, result: -5.0 }, { a: -1.0, b: 1.0, t: 0.0, result: -1.0 }, { a: -1.0, b: 1.0, t: 0.1, result: -0.8 }, { a: -1.0, b: 1.0, t: 0.01, result: -0.98 }, { a: -1.0, b: 1.0, t: 0.001, result: -0.998 }, { a: -1.0, b: 1.0, t: 0.25, result: -0.5 }, { a: -1.0, b: 1.0, t: 0.5, result: 0.0 }, { a: -1.0, b: 1.0, t: 0.9, result: 0.8 }, { a: -1.0, b: 1.0, t: 0.99, result: 0.98 }, { a: -1.0, b: 1.0, t: 0.999, result: 0.998 }, { a: -1.0, b: 1.0, t: 1.0, result: 1.0 }, { a: -1.0, b: 1.0, t: 2.0, result: 3.0 }, // [1.0, -1.0] cases { a: 1.0, b: -1.0, t: -2.0, result: 5.0 }, { a: 1.0, b: -1.0, t: 0.0, result: 1.0 }, { a: 1.0, b: -1.0, t: 0.1, result: 0.8 }, { a: 1.0, b: -1.0, t: 0.01, result: 0.98 }, { a: 1.0, b: -1.0, t: 0.001, result: 0.998 }, { a: 1.0, b: -1.0, t: 0.25, result: 0.5 }, { a: 1.0, b: -1.0, t: 0.5, result: 0.0 }, { a: 1.0, b: -1.0, t: 0.9, result: -0.8 }, { a: 1.0, b: -1.0, t: 0.99, result: -0.98 }, { a: 1.0, b: -1.0, t: 0.999, result: -0.998 }, { a: 1.0, b: -1.0, t: 1.0, result: -1.0 }, { a: 1.0, b: -1.0, t: 2.0, result: -3.0 }, // [-1.0, 0.0] cases { a: -1.0, b: 0.0, t: -1.0, result: -2.0 }, { a: -1.0, b: 0.0, t: 0.0, result: -1.0 }, { a: -1.0, b: 0.0, t: 0.1, result: -0.9 }, { a: -1.0, b: 0.0, t: 0.01, result: -0.99 }, { a: -1.0, b: 0.0, t: 0.001, result: -0.999 }, { a: -1.0, b: 0.0, t: 0.25, result: -0.75 }, { a: -1.0, b: 0.0, t: 0.5, result: -0.5 }, { a: -1.0, b: 0.0, t: 0.9, result: -0.1 }, { a: -1.0, b: 0.0, t: 0.99, result: -0.01 }, { a: -1.0, b: 0.0, t: 0.999, result: -0.001 }, { a: -1.0, b: 0.0, t: 1.0, result: 0.0 }, { a: -1.0, b: 0.0, t: 2.0, result: 1.0 }, // [0.0, -1.0] cases { a: 0.0, b: -1.0, t: -1.0, result: 1.0 }, { a: 0.0, b: -1.0, t: 0.0, result: 0.0 }, { a: 0.0, b: -1.0, t: 0.1, result: -0.1 }, { a: 0.0, b: -1.0, t: 0.01, result: -0.01 }, { a: 0.0, b: -1.0, t: 0.001, result: -0.001 }, { a: 0.0, b: -1.0, t: 0.25, result: -0.25 }, { a: 0.0, b: -1.0, t: 0.5, result: -0.5 }, { a: 0.0, b: -1.0, t: 0.9, result: -0.9 }, { a: 0.0, b: -1.0, t: 0.99, result: -0.99 }, { a: 0.0, b: -1.0, t: 0.999, result: -0.999 }, { a: 0.0, b: -1.0, t: 1.0, result: -1.0 }, { a: 0.0, b: -1.0, t: 2.0, result: -2.0 }, ]) .fn(test => { const a = test.params.a; const b = test.params.b; const t = test.params.t; const got = lerp(a, b, t); const expect = test.params.result; test.expect( (Number.isNaN(got) && Number.isNaN(expect)) || withinOneULPF32(got, expect, 'flush'), `lerp(${a}, ${b}, ${t}) returned ${got}. Expected ${expect}` ); }); interface lerpBigIntCase { a: bigint; b: bigint; idx: number; steps: number; result: bigint; } g.test('lerpBigInt') .paramsSimple([ // [0n, 1000n] cases { a: 0n, b: 1000n, idx: 0, steps: 1, result: 0n }, { a: 0n, b: 1000n, idx: 0, steps: 2, result: 0n }, { a: 0n, b: 1000n, idx: 1, steps: 2, result: 1000n }, { a: 0n, b: 1000n, idx: 0, steps: 1000, result: 0n }, { a: 0n, b: 1000n, idx: 500, steps: 1000, result: 500n }, { a: 0n, b: 1000n, idx: 999, steps: 1000, result: 1000n }, // [1000n, 0n] cases { a: 1000n, b: 0n, idx: 0, steps: 1, result: 1000n }, { a: 1000n, b: 0n, idx: 0, steps: 2, result: 1000n }, { a: 1000n, b: 0n, idx: 1, steps: 2, result: 0n }, { a: 1000n, b: 0n, idx: 0, steps: 1000, result: 1000n }, { a: 1000n, b: 0n, idx: 500, steps: 1000, result: 500n }, { a: 1000n, b: 0n, idx: 999, steps: 1000, result: 0n }, // [0n, -1000n] cases { a: 0n, b: -1000n, idx: 0, steps: 1, result: 0n }, { a: 0n, b: -1000n, idx: 0, steps: 2, result: 0n }, { a: 0n, b: -1000n, idx: 1, steps: 2, result: -1000n }, { a: 0n, b: -1000n, idx: 0, steps: 1000, result: 0n }, { a: 0n, b: -1000n, idx: 500, steps: 1000, result: -500n }, { a: 0n, b: -1000n, idx: 999, steps: 1000, result: -1000n }, // [-1000n, 0n] cases { a: -1000n, b: 0n, idx: 0, steps: 1, result: -1000n }, { a: -1000n, b: 0n, idx: 0, steps: 2, result: -1000n }, { a: -1000n, b: 0n, idx: 1, steps: 2, result: 0n }, { a: -1000n, b: 0n, idx: 0, steps: 1000, result: -1000n }, { a: -1000n, b: 0n, idx: 500, steps: 1000, result: -500n }, { a: -1000n, b: 0n, idx: 999, steps: 1000, result: 0n }, // [100n, 1000n] cases { a: 100n, b: 1000n, idx: 0, steps: 1, result: 100n }, { a: 100n, b: 1000n, idx: 0, steps: 2, result: 100n }, { a: 100n, b: 1000n, idx: 1, steps: 2, result: 1000n }, { a: 100n, b: 1000n, idx: 0, steps: 9, result: 100n }, { a: 100n, b: 1000n, idx: 4, steps: 9, result: 550n }, { a: 100n, b: 1000n, idx: 8, steps: 9, result: 1000n }, // [1000n, 100n] cases { a: 1000n, b: 100n, idx: 0, steps: 1, result: 1000n }, { a: 1000n, b: 100n, idx: 0, steps: 2, result: 1000n }, { a: 1000n, b: 100n, idx: 1, steps: 2, result: 100n }, { a: 1000n, b: 100n, idx: 0, steps: 9, result: 1000n }, { a: 1000n, b: 100n, idx: 4, steps: 9, result: 550n }, { a: 1000n, b: 100n, idx: 8, steps: 9, result: 100n }, // [01000n, 1000n] cases { a: -1000n, b: 1000n, idx: 0, steps: 1, result: -1000n }, { a: -1000n, b: 1000n, idx: 0, steps: 2, result: -1000n }, { a: -1000n, b: 1000n, idx: 1, steps: 2, result: 1000n }, { a: -1000n, b: 1000n, idx: 0, steps: 9, result: -1000n }, { a: -1000n, b: 1000n, idx: 4, steps: 9, result: 0n }, { a: -1000n, b: 1000n, idx: 8, steps: 9, result: 1000n }, ]) .fn(test => { const a = test.params.a; const b = test.params.b; const idx = test.params.idx; const steps = test.params.steps; const got = lerpBigInt(a, b, idx, steps); const expect = test.params.result; test.expect( got === expect, `lerpBigInt(${a}, ${b}, ${idx}, ${steps}) returned ${got}. Expected ${expect}` ); }); interface rangeCase { a: number; b: number; num_steps: number; result: number[]; } g.test('linearRange') .paramsSimple( // prettier-ignore [ { a: 0.0, b: Number.POSITIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.POSITIVE_INFINITY, b: 0.0, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.NEGATIVE_INFINITY, b: 1.0, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: 1.0, b: Number.NEGATIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.NEGATIVE_INFINITY, b: Number.POSITIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.POSITIVE_INFINITY, b: Number.NEGATIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: 0.0, b: 0.0, num_steps: 10, result: new Array(10).fill(0.0) }, { a: 10.0, b: 10.0, num_steps: 10, result: new Array(10).fill(10.0) }, { a: 0.0, b: 10.0, num_steps: 1, result: [0.0] }, { a: 10.0, b: 0.0, num_steps: 1, result: [10] }, { a: 0.0, b: 10.0, num_steps: 11, result: [0.0, 1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0] }, { a: 10.0, b: 0.0, num_steps: 11, result: [10.0, 9.0, 8.0, 7.0, 6.0, 5.0, 4.0, 3.0, 2.0, 1.0, 0.0] }, { a: 0.0, b: 1000.0, num_steps: 11, result: [0.0, 100.0, 200.0, 300.0, 400.0, 500.0, 600.0, 700.0, 800.0, 900.0, 1000.0] }, { a: 1000.0, b: 0.0, num_steps: 11, result: [1000.0, 900.0, 800.0, 700.0, 600.0, 500.0, 400.0, 300.0, 200.0, 100.0, 0.0] }, { a: 1.0, b: 5.0, num_steps: 5, result: [1.0, 2.0, 3.0, 4.0, 5.0] }, { a: 5.0, b: 1.0, num_steps: 5, result: [5.0, 4.0, 3.0, 2.0, 1.0] }, { a: 0.0, b: 1.0, num_steps: 11, result: [0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0] }, { a: 1.0, b: 0.0, num_steps: 11, result: [1.0, 0.9, 0.8, 0.7, 0.6, 0.5, 0.4, 0.3, 0.2, 0.1, 0.0] }, { a: 0.0, b: 1.0, num_steps: 5, result: [0.0, 0.25, 0.5, 0.75, 1.0] }, { a: 1.0, b: 0.0, num_steps: 5, result: [1.0, 0.75, 0.5, 0.25, 0.0] }, { a: -1.0, b: 1.0, num_steps: 11, result: [-1.0, -0.8, -0.6, -0.4, -0.2, 0.0, 0.2, 0.4, 0.6, 0.8, 1.0] }, { a: 1.0, b: -1.0, num_steps: 11, result: [1.0, 0.8, 0.6, 0.4, 0.2, 0.0, -0.2, -0.4, -0.6, -0.8, -1.0] }, { a: -1.0, b: 0, num_steps: 11, result: [-1.0, -0.9, -0.8, -0.7, -0.6, -0.5, -0.4, -0.3, -0.2, -0.1, 0.0] }, { a: 0.0, b: -1.0, num_steps: 11, result: [0.0, -0.1, -0.2, -0.3, -0.4, -0.5, -0.6, -0.7, -0.8, -0.9, -1.0] }, ] ) .fn(test => { const a = test.params.a; const b = test.params.b; const num_steps = test.params.num_steps; const got = linearRange(a, b, num_steps); const expect = test.params.result; test.expect( compareArrayOfNumbersF32(got, expect, 'no-flush'), `linearRange(${a}, ${b}, ${num_steps}) returned ${got}. Expected ${expect}` ); }); g.test('biasedRange') .paramsSimple( // prettier-ignore [ { a: 0.0, b: Number.POSITIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.POSITIVE_INFINITY, b: 0.0, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.NEGATIVE_INFINITY, b: 1.0, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: 1.0, b: Number.NEGATIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.NEGATIVE_INFINITY, b: Number.POSITIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: Number.POSITIVE_INFINITY, b: Number.NEGATIVE_INFINITY, num_steps: 10, result: new Array(10).fill(Number.NaN) }, { a: 0.0, b: 0.0, num_steps: 10, result: new Array(10).fill(0.0) }, { a: 10.0, b: 10.0, num_steps: 10, result: new Array(10).fill(10.0) }, { a: 0.0, b: 10.0, num_steps: 1, result: [0.0] }, { a: 10.0, b: 0.0, num_steps: 1, result: [10.0] }, { a: 0.0, b: 10.0, num_steps: 11, result: [0.0, 0.1, 0.4, 0.9, 1.6, 2.5, 3.6, 4.9, 6.4, 8.1, 10.0] }, { a: 10.0, b: 0.0, num_steps: 11, result: [10.0, 9.9, 9.6, 9.1, 8.4, 7.5, 6.4, 5.1, 3.6, 1.9, 0.0] }, { a: 0.0, b: 1000.0, num_steps: 11, result: [0.0, 10.0, 40.0, 90.0, 160.0, 250.0, 360.0, 490.0, 640.0, 810.0, 1000.0] }, { a: 1000.0, b: 0.0, num_steps: 11, result: [1000.0, 990.0, 960.0, 910.0, 840.0, 750.0, 640.0, 510.0, 360.0, 190.0, 0.0] }, { a: 1.0, b: 5.0, num_steps: 5, result: [1.0, 1.25, 2.0, 3.25, 5.0] }, { a: 5.0, b: 1.0, num_steps: 5, result: [5.0, 4.75, 4.0, 2.75, 1.0] }, { a: 0.0, b: 1.0, num_steps: 11, result: [0.0, 0.01, 0.04, 0.09, 0.16, 0.25, 0.36, 0.49, 0.64, 0.81, 1.0] }, { a: 1.0, b: 0.0, num_steps: 11, result: [1.0, 0.99, 0.96, 0.91, 0.84, 0.75, 0.64, 0.51, 0.36, 0.19, 0.0] }, { a: 0.0, b: 1.0, num_steps: 5, result: [0.0, 0.0625, 0.25, 0.5625, 1.0] }, { a: 1.0, b: 0.0, num_steps: 5, result: [1.0, 0.9375, 0.75, 0.4375, 0.0] }, { a: -1.0, b: 1.0, num_steps: 11, result: [-1.0, -0.98, -0.92, -0.82, -0.68, -0.5, -0.28 ,-0.02, 0.28, 0.62, 1.0] }, { a: 1.0, b: -1.0, num_steps: 11, result: [1.0, 0.98, 0.92, 0.82, 0.68, 0.5, 0.28 ,0.02, -0.28, -0.62, -1.0] }, { a: -1.0, b: 0, num_steps: 11, result: [-1.0 , -0.99, -0.96, -0.91, -0.84, -0.75, -0.64, -0.51, -0.36, -0.19, 0.0] }, { a: 0.0, b: -1.0, num_steps: 11, result: [0.0, -0.01, -0.04, -0.09, -0.16, -0.25, -0.36, -0.49, -0.64, -0.81, -1.0] }, ] ) .fn(test => { const a = test.params.a; const b = test.params.b; const num_steps = test.params.num_steps; const got = biasedRange(a, b, num_steps); const expect = test.params.result; test.expect( compareArrayOfNumbersF32(got, expect, 'no-flush'), `biasedRange(${a}, ${b}, ${num_steps}) returned ${got}. Expected ${expect}` ); }); interface rangeBigIntCase { a: bigint; b: bigint; num_steps: number; result: bigint[]; } g.test('linearRangeBigInt') .paramsSimple( // prettier-ignore [ { a: 0n, b: 0n, num_steps: 10, result: new Array(10).fill(0n) }, { a: 10n, b: 10n, num_steps: 10, result: new Array(10).fill(10n) }, { a: 0n, b: 10n, num_steps: 1, result: [0n] }, { a: 10n, b: 0n, num_steps: 1, result: [10n] }, { a: 0n, b: 10n, num_steps: 11, result: [0n, 1n, 2n, 3n, 4n, 5n, 6n, 7n, 8n, 9n, 10n] }, { a: 10n, b: 0n, num_steps: 11, result: [10n, 9n, 8n, 7n, 6n, 5n, 4n, 3n, 2n, 1n, 0n] }, { a: 0n, b: 1000n, num_steps: 11, result: [0n, 100n, 200n, 300n, 400n, 500n, 600n, 700n, 800n, 900n, 1000n] }, { a: 1000n, b: 0n, num_steps: 11, result: [1000n, 900n, 800n, 700n, 600n, 500n, 400n, 300n, 200n, 100n, 0n] }, { a: 1n, b: 5n, num_steps: 5, result: [1n, 2n, 3n, 4n, 5n] }, { a: 5n, b: 1n, num_steps: 5, result: [5n, 4n, 3n, 2n, 1n] }, { a: 0n, b: 10n, num_steps: 5, result: [0n, 2n, 5n, 7n, 10n] }, { a: 10n, b: 0n, num_steps: 5, result: [10n, 8n, 5n, 3n, 0n] }, { a: -10n, b: 10n, num_steps: 11, result: [-10n, -8n, -6n, -4n, -2n, 0n, 2n, 4n, 6n, 8n, 10n] }, { a: 10n, b: -10n, num_steps: 11, result: [10n, 8n, 6n, 4n, 2n, 0n, -2n, -4n, -6n, -8n, -10n] }, { a: -10n, b: 0n, num_steps: 11, result: [-10n, -9n, -8n, -7n, -6n, -5n, -4n, -3n, -2n, -1n, 0n] }, { a: 0n, b: -10n, num_steps: 11, result: [0n, -1n, -2n, -3n, -4n, -5n, -6n, -7n, -8n, -9n, -10n] }, ] ) .fn(test => { const a = test.params.a; const b = test.params.b; const num_steps = test.params.num_steps; const got = linearRangeBigInt(a, b, num_steps); const expect = test.params.result; test.expect( objectEquals(got, expect), `linearRangeBigInt(${a}, ${b}, ${num_steps}) returned ${got}. Expected ${expect}` ); }); interface fullF32RangeCase { neg_norm: number; neg_sub: number; pos_sub: number; pos_norm: number; expect: Array; } g.test('fullF32Range') .paramsSimple( // prettier-ignore [ { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ -0.0, 0.0 ] }, { neg_norm: 1, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f32.negative.min, -0.0, 0.0] }, { neg_norm: 2, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f32.negative.min, kValue.f32.negative.max, -0.0, 0.0 ] }, { neg_norm: 3, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f32.negative.min, -1.9999998807907104, kValue.f32.negative.max, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 1, pos_sub: 0, pos_norm: 0, expect: [ kValue.f32.negative.subnormal.min, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 2, pos_sub: 0, pos_norm: 0, expect: [ kValue.f32.negative.subnormal.min, kValue.f32.negative.subnormal.max, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 1, pos_norm: 0, expect: [ -0.0, 0.0, kValue.f32.positive.subnormal.min ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 2, pos_norm: 0, expect: [ -0.0, 0.0, kValue.f32.positive.subnormal.min, kValue.f32.positive.subnormal.max ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 1, expect: [ -0.0, 0.0, kValue.f32.positive.min ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 2, expect: [ -0.0, 0.0, kValue.f32.positive.min, kValue.f32.positive.max ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 3, expect: [ -0.0, 0.0, kValue.f32.positive.min, 1.9999998807907104, kValue.f32.positive.max ] }, { neg_norm: 1, neg_sub: 1, pos_sub: 1, pos_norm: 1, expect: [ kValue.f32.negative.min, kValue.f32.negative.subnormal.min, -0.0, 0.0, kValue.f32.positive.subnormal.min, kValue.f32.positive.min ] }, { neg_norm: 2, neg_sub: 2, pos_sub: 2, pos_norm: 2, expect: [ kValue.f32.negative.min, kValue.f32.negative.max, kValue.f32.negative.subnormal.min, kValue.f32.negative.subnormal.max, -0.0, 0.0, kValue.f32.positive.subnormal.min, kValue.f32.positive.subnormal.max, kValue.f32.positive.min, kValue.f32.positive.max ] }, ] ) .fn(test => { const neg_norm = test.params.neg_norm; const neg_sub = test.params.neg_sub; const pos_sub = test.params.pos_sub; const pos_norm = test.params.pos_norm; const got = fullF32Range({ neg_norm, neg_sub, pos_sub, pos_norm }); const expect = test.params.expect; test.expect( compareArrayOfNumbersF32(got, expect, 'no-flush'), `fullF32Range(${neg_norm}, ${neg_sub}, ${pos_sub}, ${pos_norm}) returned [${got}]. Expected [${expect}]` ); }); interface fullF16RangeCase { neg_norm: number; neg_sub: number; pos_sub: number; pos_norm: number; expect: Array; } g.test('fullF16Range') .paramsSimple( // prettier-ignore [ { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ -0.0, 0.0 ] }, { neg_norm: 1, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f16.negative.min, -0.0, 0.0] }, { neg_norm: 2, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f16.negative.min, kValue.f16.negative.max, -0.0, 0.0 ] }, { neg_norm: 3, neg_sub: 0, pos_sub: 0, pos_norm: 0, expect: [ kValue.f16.negative.min, -1.9990234375, kValue.f16.negative.max, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 1, pos_sub: 0, pos_norm: 0, expect: [ kValue.f16.negative.subnormal.min, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 2, pos_sub: 0, pos_norm: 0, expect: [ kValue.f16.negative.subnormal.min, kValue.f16.negative.subnormal.max, -0.0, 0.0 ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 1, pos_norm: 0, expect: [ -0.0, 0.0, kValue.f16.positive.subnormal.min ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 2, pos_norm: 0, expect: [ -0.0, 0.0, kValue.f16.positive.subnormal.min, kValue.f16.positive.subnormal.max ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 1, expect: [ -0.0, 0.0, kValue.f16.positive.min ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 2, expect: [ -0.0, 0.0, kValue.f16.positive.min, kValue.f16.positive.max ] }, { neg_norm: 0, neg_sub: 0, pos_sub: 0, pos_norm: 3, expect: [ -0.0, 0.0, kValue.f16.positive.min, 1.9990234375, kValue.f16.positive.max ] }, { neg_norm: 1, neg_sub: 1, pos_sub: 1, pos_norm: 1, expect: [ kValue.f16.negative.min, kValue.f16.negative.subnormal.min, -0.0, 0.0, kValue.f16.positive.subnormal.min, kValue.f16.positive.min ] }, { neg_norm: 2, neg_sub: 2, pos_sub: 2, pos_norm: 2, expect: [ kValue.f16.negative.min, kValue.f16.negative.max, kValue.f16.negative.subnormal.min, kValue.f16.negative.subnormal.max, -0.0, 0.0, kValue.f16.positive.subnormal.min, kValue.f16.positive.subnormal.max, kValue.f16.positive.min, kValue.f16.positive.max ] }, ] ) .fn(test => { const neg_norm = test.params.neg_norm; const neg_sub = test.params.neg_sub; const pos_sub = test.params.pos_sub; const pos_norm = test.params.pos_norm; const got = fullF16Range({ neg_norm, neg_sub, pos_sub, pos_norm }); const expect = test.params.expect; test.expect( compareArrayOfNumbersF32(got, expect), `fullF16Range(${neg_norm}, ${neg_sub}, ${pos_sub}, ${pos_norm}) returned [${got}]. Expected [${expect}]` ); }); interface fullI32RangeCase { neg_count: number; pos_count: number; expect: Array; } g.test('fullI32Range') .paramsSimple( // prettier-ignore [ { neg_count: 0, pos_count: 0, expect: [0] }, { neg_count: 1, pos_count: 0, expect: [kValue.i32.negative.min, 0] }, { neg_count: 2, pos_count: 0, expect: [kValue.i32.negative.min, -1, 0] }, { neg_count: 3, pos_count: 0, expect: [kValue.i32.negative.min, -1610612736, -1, 0] }, { neg_count: 0, pos_count: 1, expect: [0, 1] }, { neg_count: 0, pos_count: 2, expect: [0, 1, kValue.i32.positive.max] }, { neg_count: 0, pos_count: 3, expect: [0, 1, 536870912, kValue.i32.positive.max] }, { neg_count: 1, pos_count: 1, expect: [kValue.i32.negative.min, 0, 1] }, { neg_count: 2, pos_count: 2, expect: [kValue.i32.negative.min, -1, 0, 1, kValue.i32.positive.max ] }, ] ) .fn(test => { const neg_count = test.params.neg_count; const pos_count = test.params.pos_count; const got = fullI32Range({ negative: neg_count, positive: pos_count }); const expect = test.params.expect; test.expect( compareArrayOfNumbersF32(got, expect), `fullI32Range(${neg_count}, ${pos_count}) returned [${got}]. Expected [${expect}]` ); }); interface limitsBigIntBitsF64Case { bits: bigint; value: number; } // Test to confirm kBit and kValue constants are equivalent for f64 g.test('f64LimitsEquivalency') .paramsSimple([ { bits: kBit.f64.positive.max, value: kValue.f64.positive.max }, { bits: kBit.f64.positive.min, value: kValue.f64.positive.min }, { bits: kBit.f64.positive.nearest_max, value: kValue.f64.positive.nearest_max }, { bits: kBit.f64.positive.less_than_one, value: kValue.f64.positive.less_than_one }, { bits: kBit.f64.positive.pi.whole, value: kValue.f64.positive.pi.whole }, { bits: kBit.f64.positive.pi.three_quarters, value: kValue.f64.positive.pi.three_quarters }, { bits: kBit.f64.positive.pi.half, value: kValue.f64.positive.pi.half }, { bits: kBit.f64.positive.pi.third, value: kValue.f64.positive.pi.third }, { bits: kBit.f64.positive.pi.quarter, value: kValue.f64.positive.pi.quarter }, { bits: kBit.f64.positive.pi.sixth, value: kValue.f64.positive.pi.sixth }, { bits: kBit.f64.positive.e, value: kValue.f64.positive.e }, { bits: kBit.f64.max_ulp, value: kValue.f64.max_ulp }, { bits: kBit.f64.negative.max, value: kValue.f64.negative.max }, { bits: kBit.f64.negative.min, value: kValue.f64.negative.min }, { bits: kBit.f64.negative.nearest_min, value: kValue.f64.negative.nearest_min }, { bits: kBit.f64.negative.pi.whole, value: kValue.f64.negative.pi.whole }, { bits: kBit.f64.negative.pi.three_quarters, value: kValue.f64.negative.pi.three_quarters }, { bits: kBit.f64.negative.pi.half, value: kValue.f64.negative.pi.half }, { bits: kBit.f64.negative.pi.third, value: kValue.f64.negative.pi.third }, { bits: kBit.f64.negative.pi.quarter, value: kValue.f64.negative.pi.quarter }, { bits: kBit.f64.negative.pi.sixth, value: kValue.f64.negative.pi.sixth }, { bits: kBit.f64.positive.subnormal.max, value: kValue.f64.positive.subnormal.max }, { bits: kBit.f64.positive.subnormal.min, value: kValue.f64.positive.subnormal.min }, { bits: kBit.f64.negative.subnormal.max, value: kValue.f64.negative.subnormal.max }, { bits: kBit.f64.negative.subnormal.min, value: kValue.f64.negative.subnormal.min }, { bits: kBit.f64.positive.infinity, value: kValue.f64.positive.infinity }, { bits: kBit.f64.negative.infinity, value: kValue.f64.negative.infinity }, ]) .fn(test => { const bits = test.params.bits; const value = test.params.value; const val_to_bits = bits === float64ToUint64(value); const bits_to_val = value === uint64ToFloat64(bits); test.expect( val_to_bits && bits_to_val, `bits = ${bits}, value = ${value}, returned val_to_bits as ${val_to_bits}, and bits_to_val as ${bits_to_val}, they are expected to be equivalent` ); }); interface limitsNumberBitsCase { bits: number; value: number; } // Test to confirm kBit and kValue constants are equivalent for f32 g.test('f32LimitsEquivalency') .paramsSimple([ { bits: kBit.f32.positive.max, value: kValue.f32.positive.max }, { bits: kBit.f32.positive.min, value: kValue.f32.positive.min }, { bits: kBit.f32.positive.nearest_max, value: kValue.f32.positive.nearest_max }, { bits: kBit.f32.positive.less_than_one, value: kValue.f32.positive.less_than_one }, { bits: kBit.f32.positive.pi.whole, value: kValue.f32.positive.pi.whole }, { bits: kBit.f32.positive.pi.three_quarters, value: kValue.f32.positive.pi.three_quarters }, { bits: kBit.f32.positive.pi.half, value: kValue.f32.positive.pi.half }, { bits: kBit.f32.positive.pi.third, value: kValue.f32.positive.pi.third }, { bits: kBit.f32.positive.pi.quarter, value: kValue.f32.positive.pi.quarter }, { bits: kBit.f32.positive.pi.sixth, value: kValue.f32.positive.pi.sixth }, { bits: kBit.f32.positive.e, value: kValue.f32.positive.e }, { bits: kBit.f32.max_ulp, value: kValue.f32.max_ulp }, { bits: kBit.f32.negative.max, value: kValue.f32.negative.max }, { bits: kBit.f32.negative.min, value: kValue.f32.negative.min }, { bits: kBit.f32.negative.nearest_min, value: kValue.f32.negative.nearest_min }, { bits: kBit.f32.negative.pi.whole, value: kValue.f32.negative.pi.whole }, { bits: kBit.f32.negative.pi.three_quarters, value: kValue.f32.negative.pi.three_quarters }, { bits: kBit.f32.negative.pi.half, value: kValue.f32.negative.pi.half }, { bits: kBit.f32.negative.pi.third, value: kValue.f32.negative.pi.third }, { bits: kBit.f32.negative.pi.quarter, value: kValue.f32.negative.pi.quarter }, { bits: kBit.f32.negative.pi.sixth, value: kValue.f32.negative.pi.sixth }, { bits: kBit.f32.positive.subnormal.max, value: kValue.f32.positive.subnormal.max }, { bits: kBit.f32.positive.subnormal.min, value: kValue.f32.positive.subnormal.min }, { bits: kBit.f32.negative.subnormal.max, value: kValue.f32.negative.subnormal.max }, { bits: kBit.f32.negative.subnormal.min, value: kValue.f32.negative.subnormal.min }, { bits: kBit.f32.positive.infinity, value: kValue.f32.positive.infinity }, { bits: kBit.f32.negative.infinity, value: kValue.f32.negative.infinity }, ]) .fn(test => { const bits = test.params.bits; const value = test.params.value; const val_to_bits = bits === float32ToUint32(value); const bits_to_val = value === uint32ToFloat32(bits); test.expect( val_to_bits && bits_to_val, `bits = ${bits}, value = ${value}, returned val_to_bits as ${val_to_bits}, and bits_to_val as ${bits_to_val}, they are expected to be equivalent` ); }); // Test to confirm kBit and kValue constants are equivalent for f16 g.test('f16LimitsEquivalency') .paramsSimple([ { bits: kBit.f16.positive.max, value: kValue.f16.positive.max }, { bits: kBit.f16.positive.min, value: kValue.f16.positive.min }, { bits: kBit.f16.positive.nearest_max, value: kValue.f16.positive.nearest_max }, { bits: kBit.f16.positive.less_than_one, value: kValue.f16.positive.less_than_one }, { bits: kBit.f16.positive.pi.whole, value: kValue.f16.positive.pi.whole }, { bits: kBit.f16.positive.pi.three_quarters, value: kValue.f16.positive.pi.three_quarters }, { bits: kBit.f16.positive.pi.half, value: kValue.f16.positive.pi.half }, { bits: kBit.f16.positive.pi.third, value: kValue.f16.positive.pi.third }, { bits: kBit.f16.positive.pi.quarter, value: kValue.f16.positive.pi.quarter }, { bits: kBit.f16.positive.pi.sixth, value: kValue.f16.positive.pi.sixth }, { bits: kBit.f16.positive.e, value: kValue.f16.positive.e }, { bits: kBit.f16.max_ulp, value: kValue.f16.max_ulp }, { bits: kBit.f16.negative.max, value: kValue.f16.negative.max }, { bits: kBit.f16.negative.min, value: kValue.f16.negative.min }, { bits: kBit.f16.negative.nearest_min, value: kValue.f16.negative.nearest_min }, { bits: kBit.f16.negative.pi.whole, value: kValue.f16.negative.pi.whole }, { bits: kBit.f16.negative.pi.three_quarters, value: kValue.f16.negative.pi.three_quarters }, { bits: kBit.f16.negative.pi.half, value: kValue.f16.negative.pi.half }, { bits: kBit.f16.negative.pi.third, value: kValue.f16.negative.pi.third }, { bits: kBit.f16.negative.pi.quarter, value: kValue.f16.negative.pi.quarter }, { bits: kBit.f16.negative.pi.sixth, value: kValue.f16.negative.pi.sixth }, { bits: kBit.f16.positive.subnormal.max, value: kValue.f16.positive.subnormal.max }, { bits: kBit.f16.positive.subnormal.min, value: kValue.f16.positive.subnormal.min }, { bits: kBit.f16.negative.subnormal.max, value: kValue.f16.negative.subnormal.max }, { bits: kBit.f16.negative.subnormal.min, value: kValue.f16.negative.subnormal.min }, { bits: kBit.f16.positive.infinity, value: kValue.f16.positive.infinity }, { bits: kBit.f16.negative.infinity, value: kValue.f16.negative.infinity }, ]) .fn(test => { const bits = test.params.bits; const value = test.params.value; const val_to_bits = bits === float16ToUint16(value); const bits_to_val = value === uint16ToFloat16(bits); test.expect( val_to_bits && bits_to_val, `bits = ${bits}, value = ${value}, returned val_to_bits as ${val_to_bits}, and bits_to_val as ${bits_to_val}, they are expected to be equivalent` ); }); interface cartesianProductCase { inputs: T[][]; result: T[][]; } g.test('cartesianProductNumber') .paramsSimple>( // prettier-ignore [ { inputs: [[0], [1]], result: [[0, 1]] }, { inputs: [[0, 1], [2]], result: [[0, 2], [1, 2]] }, { inputs: [[0], [1, 2]], result: [[0, 1], [0, 2]] }, { inputs: [[0, 1], [2, 3]], result: [[0,2], [1, 2], [0, 3], [1, 3]] }, { inputs: [[0, 1, 2], [3, 4, 5]], result: [[0, 3], [1, 3], [2, 3], [0, 4], [1, 4], [2, 4], [0, 5], [1, 5], [2, 5]] }, { inputs: [[0, 1], [2, 3], [4, 5]], result: [[0, 2, 4], [1, 2, 4], [0, 3, 4], [1, 3, 4], [0, 2, 5], [1, 2, 5], [0, 3, 5], [1, 3, 5]] }, ] ) .fn(test => { const inputs = test.params.inputs; const got = cartesianProduct(...inputs); const expect = test.params.result; test.expect( objectEquals(got, expect), `cartesianProduct(${JSON.stringify(inputs)}) returned ${JSON.stringify( got )}. Expected ${JSON.stringify(expect)} ` ); }); g.test('cartesianProductArray') .paramsSimple>( // prettier-ignore [ { inputs: [[[0, 1], [2, 3]], [[4, 5], [6, 7]]], result: [[[0, 1], [4, 5]], [[2, 3], [4, 5]], [[0, 1], [6, 7]], [[2, 3], [6, 7]]]}, { inputs: [[[0, 1], [2, 3]], [[4, 5], [6, 7]], [[8, 9]]], result: [[[0, 1], [4, 5], [8, 9]], [[2, 3], [4, 5], [8, 9]], [[0, 1], [6, 7], [8, 9]], [[2, 3], [6, 7], [8, 9]]]}, { inputs: [[[0, 1, 2], [3, 4, 5], [6, 7, 8]], [[2, 1, 0], [5, 4, 3], [8, 7, 6]]], result: [[[0, 1, 2], [2, 1, 0]], [[3, 4, 5], [2, 1, 0]], [[6, 7, 8], [2, 1, 0]], [[0, 1, 2], [5, 4, 3]], [[3, 4, 5], [5, 4, 3]], [[6, 7, 8], [5, 4, 3]], [[0, 1, 2], [8, 7, 6]], [[3, 4, 5], [8, 7, 6]], [[6, 7, 8], [8, 7, 6]]]} ] ) .fn(test => { const inputs = test.params.inputs; const got = cartesianProduct(...inputs); const expect = test.params.result; test.expect( objectEquals(got, expect), `cartesianProduct(${JSON.stringify(inputs)}) returned ${JSON.stringify( got )}. Expected ${JSON.stringify(expect)} ` ); }); interface calculatePermutationsCase { input: T[]; result: T[][]; } g.test('calculatePermutations') .paramsSimple>( // prettier-ignore [ { input: [0, 1], result: [[0, 1], [1, 0]] }, { input: [0, 1, 2], result: [[0, 1, 2], [0, 2, 1], [1, 0, 2], [1, 2, 0], [2, 0, 1], [2, 1, 0]] }, { input: [0, 1, 2, 3], result: [[0, 1, 2, 3], [0, 1, 3, 2], [0, 2, 1, 3], [0, 2, 3, 1], [0, 3, 1, 2], [0, 3, 2, 1], [1, 0, 2, 3], [1, 0, 3, 2], [1, 2, 0, 3], [1, 2, 3, 0], [1, 3, 0, 2], [1, 3, 2, 0], [2, 0, 1, 3], [2, 0, 3, 1], [2, 1, 0, 3], [2, 1, 3, 0], [2, 3, 0, 1], [2, 3, 1, 0], [3, 0, 1, 2], [3, 0, 2, 1], [3, 1, 0, 2], [3, 1, 2, 0], [3, 2, 0, 1], [3, 2, 1, 0]] }, ] ) .fn(test => { const input = test.params.input; const got = calculatePermutations(input); const expect = test.params.result; test.expect( objectEquals(got, expect), `calculatePermutations(${JSON.stringify(input)}) returned ${JSON.stringify( got )}. Expected ${JSON.stringify(expect)} ` ); });