export const description = `Unit tests for conversion`; import { mergeParams } from '../common/internal/params_utils.js'; import { makeTestGroup } from '../common/internal/test_group.js'; import { keysOf } from '../common/util/data_tables.js'; import { assert, objectEquals } from '../common/util/util.js'; import { kValue } from '../webgpu/util/constants.js'; import { bool, f16Bits, f32, f32Bits, float16BitsToFloat32, float32ToFloat16Bits, float32ToFloatBits, floatBitsToNormalULPFromZero, floatBitsToNumber, i32, kFloat16Format, kFloat32Format, Matrix, numbersApproximatelyEqual, pack2x16float, pack2x16snorm, pack2x16unorm, pack4x8snorm, pack4x8unorm, packRGB9E5UFloat, Scalar, toMatrix, u32, unpackRGB9E5UFloat, vec2, vec3, vec4, Vector, } from '../webgpu/util/conversion.js'; import { UnitTest } from './unit_test.js'; export const g = makeTestGroup(UnitTest); const kFloat16BitsToNumberCases = [ [0b0_01111_0000000000, 1], [0b0_00001_0000000000, 0.00006103515625], [0b0_01101_0101010101, 0.33325195], [0b0_11110_1111111111, 65504], [0b0_00000_0000000000, 0], [0b1_00000_0000000000, -0.0], // -0.0 compares as equal to 0.0 [0b0_01110_0000000000, 0.5], [0b0_01100_1001100110, 0.1999512], [0b0_01111_0000000001, 1.00097656], [0b0_10101_1001000000, 100], [0b1_01100_1001100110, -0.1999512], [0b1_10101_1001000000, -100], [0b0_11111_1111111111, Number.NaN], [0b0_11111_0000000000, Number.POSITIVE_INFINITY], [0b1_11111_0000000000, Number.NEGATIVE_INFINITY], ]; g.test('float16BitsToFloat32').fn(t => { for (const [bits, number] of [ ...kFloat16BitsToNumberCases, [0b0_00000_1111111111, 0.00006104], // subnormal f16 input [0b1_00000_1111111111, -0.00006104], ]) { const actual = float16BitsToFloat32(bits); t.expect( // some loose check numbersApproximatelyEqual(actual, number, 0.00001), `for ${bits.toString(2)}, expected ${number}, got ${actual}` ); } }); g.test('float32ToFloat16Bits').fn(t => { for (const [bits, number] of [ ...kFloat16BitsToNumberCases, [0b0_00000_0000000000, 0.00001], // input that becomes subnormal in f16 is rounded to 0 [0b1_00000_0000000000, -0.00001], // and sign is preserved ]) { // some loose check const actual = float32ToFloat16Bits(number); t.expect( Math.abs(actual - bits) <= 1, `for ${number}, expected ${bits.toString(2)}, got ${actual.toString(2)}` ); } }); g.test('float32ToFloatBits_floatBitsToNumber') .paramsSubcasesOnly(u => u .combine('signed', [0, 1] as const) .combine('exponentBits', [5, 8]) .combine('mantissaBits', [10, 23]) ) .fn(t => { const { signed, exponentBits, mantissaBits } = t.params; const bias = (1 << (exponentBits - 1)) - 1; for (const [, value] of kFloat16BitsToNumberCases) { if (value < 0 && signed === 0) continue; const bits = float32ToFloatBits(value, signed, exponentBits, mantissaBits, bias); const reconstituted = floatBitsToNumber(bits, { signed, exponentBits, mantissaBits, bias }); t.expect( numbersApproximatelyEqual(reconstituted, value, 0.0000001), `${reconstituted} vs ${value}` ); } }); g.test('floatBitsToULPFromZero,16').fn(t => { const test = (bits: number, ulpFromZero: number) => t.expect(floatBitsToNormalULPFromZero(bits, kFloat16Format) === ulpFromZero, bits.toString(2)); // Zero test(0b0_00000_0000000000, 0); test(0b1_00000_0000000000, 0); // Subnormal test(0b0_00000_0000000001, 0); test(0b1_00000_0000000001, 0); test(0b0_00000_1111111111, 0); test(0b1_00000_1111111111, 0); // Normal test(0b0_00001_0000000000, 1); // 0 + 1ULP test(0b1_00001_0000000000, -1); // 0 - 1ULP test(0b0_00001_0000000001, 2); // 0 + 2ULP test(0b1_00001_0000000001, -2); // 0 - 2ULP test(0b0_01110_0000000000, 0b01101_0000000001); // 0.5 test(0b1_01110_0000000000, -0b01101_0000000001); // -0.5 test(0b0_01110_1111111110, 0b01101_1111111111); // 1.0 - 2ULP test(0b1_01110_1111111110, -0b01101_1111111111); // -(1.0 - 2ULP) test(0b0_01110_1111111111, 0b01110_0000000000); // 1.0 - 1ULP test(0b1_01110_1111111111, -0b01110_0000000000); // -(1.0 - 1ULP) test(0b0_01111_0000000000, 0b01110_0000000001); // 1.0 test(0b1_01111_0000000000, -0b01110_0000000001); // -1.0 test(0b0_01111_0000000001, 0b01110_0000000010); // 1.0 + 1ULP test(0b1_01111_0000000001, -0b01110_0000000010); // -(1.0 + 1ULP) test(0b0_10000_0000000000, 0b01111_0000000001); // 2.0 test(0b1_10000_0000000000, -0b01111_0000000001); // -2.0 const testThrows = (b: number) => t.shouldThrow('Error', () => floatBitsToNormalULPFromZero(b, kFloat16Format)); // Infinity testThrows(0b0_11111_0000000000); testThrows(0b1_11111_0000000000); // NaN testThrows(0b0_11111_1111111111); testThrows(0b1_11111_1111111111); }); g.test('floatBitsToULPFromZero,32').fn(t => { const test = (bits: number, ulpFromZero: number) => t.expect(floatBitsToNormalULPFromZero(bits, kFloat32Format) === ulpFromZero, bits.toString(2)); // Zero test(0b0_00000000_00000000000000000000000, 0); test(0b1_00000000_00000000000000000000000, 0); // Subnormal test(0b0_00000000_00000000000000000000001, 0); test(0b1_00000000_00000000000000000000001, 0); test(0b0_00000000_11111111111111111111111, 0); test(0b1_00000000_11111111111111111111111, 0); // Normal test(0b0_00000001_00000000000000000000000, 1); // 0 + 1ULP test(0b1_00000001_00000000000000000000000, -1); // 0 - 1ULP test(0b0_00000001_00000000000000000000001, 2); // 0 + 2ULP test(0b1_00000001_00000000000000000000001, -2); // 0 - 2ULP test(0b0_01111110_00000000000000000000000, 0b01111101_00000000000000000000001); // 0.5 test(0b1_01111110_00000000000000000000000, -0b01111101_00000000000000000000001); // -0.5 test(0b0_01111110_11111111111111111111110, 0b01111101_11111111111111111111111); // 1.0 - 2ULP test(0b1_01111110_11111111111111111111110, -0b01111101_11111111111111111111111); // -(1.0 - 2ULP) test(0b0_01111110_11111111111111111111111, 0b01111110_00000000000000000000000); // 1.0 - 1ULP test(0b1_01111110_11111111111111111111111, -0b01111110_00000000000000000000000); // -(1.0 - 1ULP) test(0b0_01111111_00000000000000000000000, 0b01111110_00000000000000000000001); // 1.0 test(0b1_01111111_00000000000000000000000, -0b01111110_00000000000000000000001); // -1.0 test(0b0_01111111_00000000000000000000001, 0b01111110_00000000000000000000010); // 1.0 + 1ULP test(0b1_01111111_00000000000000000000001, -0b01111110_00000000000000000000010); // -(1.0 + 1ULP) test(0b0_11110000_00000000000000000000000, 0b11101111_00000000000000000000001); // 2.0 test(0b1_11110000_00000000000000000000000, -0b11101111_00000000000000000000001); // -2.0 const testThrows = (b: number) => t.shouldThrow('Error', () => floatBitsToNormalULPFromZero(b, kFloat32Format)); // Infinity testThrows(0b0_11111111_00000000000000000000000); testThrows(0b1_11111111_00000000000000000000000); // NaN testThrows(0b0_11111111_11111111111111111111111); testThrows(0b0_11111111_00000000000000000000001); testThrows(0b1_11111111_11111111111111111111111); testThrows(0b1_11111111_00000000000000000000001); }); g.test('scalarWGSL').fn(t => { const cases: Array<[Scalar, string]> = [ [f32(0.0), '0.0f'], // The number -0.0 can be remapped to 0.0 when stored in a Scalar // object. It is not possible to guarantee that '-0.0f' will // be emitted. So the WGSL scalar value printing does not try // to handle this case. [f32(-0.0), '0.0f'], // -0.0 can be remapped to 0.0 [f32(1.0), '1.0f'], [f32(-1.0), '-1.0f'], [f32Bits(0x70000000), '1.5845632502852868e+29f'], [f32Bits(0xf0000000), '-1.5845632502852868e+29f'], [f16Bits(0), '0.0h'], [f16Bits(0x3c00), '1.0h'], [f16Bits(0xbc00), '-1.0h'], [u32(0), '0u'], [u32(1), '1u'], [u32(2000000000), '2000000000u'], [u32(-1), '4294967295u'], [i32(0), 'i32(0)'], [i32(1), 'i32(1)'], [i32(-1), 'i32(-1)'], [bool(true), 'true'], [bool(false), 'false'], ]; for (const [value, expect] of cases) { const got = value.wgsl(); t.expect( got === expect, `[value: ${value.value}, type: ${value.type}] got: ${got} expect: ${expect}` ); } }); g.test('vectorWGSL').fn(t => { const cases: Array<[Vector, string]> = [ [vec2(f32(42.0), f32(24.0)), 'vec2(42.0f, 24.0f)'], [vec2(f16Bits(0x5140), f16Bits(0x4e00)), 'vec2(42.0h, 24.0h)'], [vec2(u32(42), u32(24)), 'vec2(42u, 24u)'], [vec2(i32(42), i32(24)), 'vec2(i32(42), i32(24))'], [vec2(bool(false), bool(true)), 'vec2(false, true)'], [vec3(f32(0.0), f32(1.0), f32(-1.0)), 'vec3(0.0f, 1.0f, -1.0f)'], [vec3(f16Bits(0), f16Bits(0x3c00), f16Bits(0xbc00)), 'vec3(0.0h, 1.0h, -1.0h)'], [vec3(u32(0), u32(1), u32(-1)), 'vec3(0u, 1u, 4294967295u)'], [vec3(i32(0), i32(1), i32(-1)), 'vec3(i32(0), i32(1), i32(-1))'], [vec3(bool(true), bool(false), bool(true)), 'vec3(true, false, true)'], [vec4(f32(1.0), f32(-2.0), f32(4.0), f32(-8.0)), 'vec4(1.0f, -2.0f, 4.0f, -8.0f)'], [ vec4(f16Bits(0xbc00), f16Bits(0x4000), f16Bits(0xc400), f16Bits(0x4800)), 'vec4(-1.0h, 2.0h, -4.0h, 8.0h)', ], [vec4(u32(1), u32(-2), u32(4), u32(-8)), 'vec4(1u, 4294967294u, 4u, 4294967288u)'], [vec4(i32(1), i32(-2), i32(4), i32(-8)), 'vec4(i32(1), i32(-2), i32(4), i32(-8))'], [vec4(bool(false), bool(true), bool(true), bool(false)), 'vec4(false, true, true, false)'], ]; for (const [value, expect] of cases) { const got = value.wgsl(); t.expect( got === expect, `[values: ${value.elements}, type: ${value.type}] got: ${got} expect: ${expect}` ); } }); g.test('matrixWGSL').fn(t => { const cases: Array<[Matrix, string]> = [ [ toMatrix( [ [0.0, 1.0], [2.0, 3.0], ], f32 ), 'mat2x2(0.0f, 1.0f, 2.0f, 3.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0], [3.0, 4.0, 5.0], ], f32 ), 'mat2x3(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0, 3.0], [4.0, 5.0, 6.0, 7.0], ], f32 ), 'mat2x4(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f)', ], [ toMatrix( [ [0.0, 1.0], [2.0, 3.0], [4.0, 5.0], ], f32 ), 'mat3x2(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0], [3.0, 4.0, 5.0], [6.0, 7.0, 8.0], ], f32 ), 'mat3x3(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0, 3.0], [4.0, 5.0, 6.0, 7.0], [8.0, 9.0, 10.0, 11.0], ], f32 ), 'mat3x4(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f, 10.0f, 11.0f)', ], [ toMatrix( [ [0.0, 1.0], [2.0, 3.0], [4.0, 5.0], [6.0, 7.0], ], f32 ), 'mat4x2(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0], [3.0, 4.0, 5.0], [6.0, 7.0, 8.0], [9.0, 10.0, 11.0], ], f32 ), 'mat4x3(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f, 10.0f, 11.0f)', ], [ toMatrix( [ [0.0, 1.0, 2.0, 3.0], [4.0, 5.0, 6.0, 7.0], [8.0, 9.0, 10.0, 11.0], [12.0, 13.0, 14.0, 15.0], ], f32 ), 'mat4x4(0.0f, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f, 10.0f, 11.0f, 12.0f, 13.0f, 14.0f, 15.0f)', ], ]; for (const [value, expect] of cases) { const got = value.wgsl(); t.expect( got === expect, `[values: ${value.elements}, type: ${value.type}] got: ${got} expect: ${expect}` ); } }); g.test('constructorMatrix') .params(u => u .combine('cols', [2, 3, 4] as const) .combine('rows', [2, 3, 4] as const) .combine('type', ['f32'] as const) ) .fn(t => { const cols = t.params.cols; const rows = t.params.rows; const type = t.params.type; const scalar_builder = type === 'f32' ? f32 : undefined; assert(scalar_builder !== undefined, `Unexpected type param '${type}' provided`); const elements = [...Array(cols).keys()].map(c => { return [...Array(rows).keys()].map(r => scalar_builder(c * cols + r)); }); const got = new Matrix(elements); const got_type = got.type; t.expect( got_type.cols === cols, `expected Matrix to have ${cols} columns, received ${got_type.cols} instead` ); t.expect( got_type.rows === rows, `expected Matrix to have ${rows} columns, received ${got_type.rows} instead` ); t.expect( got_type.elementType.kind === type, `expected Matrix to have ${type} elements, received ${got_type.elementType.kind} instead` ); t.expect( objectEquals(got.elements, elements), `Matrix did not have expected elements (${JSON.stringify(elements)}), instead had (${ got.elements })` ); }); g.test('pack2x16float') .paramsSimple([ // f16 normals { inputs: [0, 0], result: [0x00000000, 0x80000000, 0x00008000, 0x80008000] }, { inputs: [1, 0], result: [0x00003c00, 0x80003c00] }, { inputs: [1, 1], result: [0x3c003c00] }, { inputs: [-1, -1], result: [0xbc00bc00] }, { inputs: [10, 1], result: [0x3c004900] }, { inputs: [-10, 1], result: [0x3c00c900] }, // f32 normal, but not f16 precise { inputs: [1.00000011920928955078125, 1], result: [0x3c003c00, 0x3c003c01] }, // f32 subnormals // prettier-ignore { inputs: [kValue.f32.positive.subnormal.max, 1], result: [0x3c000000, 0x3c008000, 0x3c000001] }, // prettier-ignore { inputs: [kValue.f32.negative.subnormal.min, 1], result: [0x3c008001, 0x3c000000, 0x3c008000] }, // f16 subnormals // prettier-ignore { inputs: [kValue.f16.positive.subnormal.max, 1], result: [0x3c0003ff, 0x3c000000, 0x3c008000] }, // prettier-ignore { inputs: [kValue.f16.negative.subnormal.min, 1], result: [0x03c0083ff, 0x3c000000, 0x3c008000] }, // f16 out of bounds { inputs: [kValue.f16.positive.max + 1, 1], result: [undefined] }, { inputs: [kValue.f16.negative.min - 1, 1], result: [undefined] }, { inputs: [1, kValue.f16.positive.max + 1], result: [undefined] }, { inputs: [1, kValue.f16.negative.min - 1], result: [undefined] }, ] as const) .fn(test => { const toString = (data: readonly (undefined | number)[]): String[] => { return data.map(d => (d !== undefined ? u32(d).toString() : 'undefined')); }; const inputs = test.params.inputs; const got = pack2x16float(inputs[0], inputs[1]); const expect = test.params.result; const got_str = toString(got); const expect_str = toString(expect); // Using strings of the outputs, so they can be easily sorted, since order of the results doesn't matter. test.expect( objectEquals(got_str.sort(), expect_str.sort()), `pack2x16float(${inputs}) returned [${got_str}]. Expected [${expect_str}]` ); }); g.test('pack2x16snorm') .paramsSimple([ // Normals { inputs: [0, 0], result: 0x00000000 }, { inputs: [1, 0], result: 0x00007fff }, { inputs: [0, 1], result: 0x7fff0000 }, { inputs: [1, 1], result: 0x7fff7fff }, { inputs: [-1, -1], result: 0x80018001 }, { inputs: [10, 10], result: 0x7fff7fff }, { inputs: [-10, -10], result: 0x80018001 }, { inputs: [0.1, 0.1], result: 0x0ccd0ccd }, { inputs: [-0.1, -0.1], result: 0xf333f333 }, { inputs: [0.5, 0.5], result: 0x40004000 }, { inputs: [-0.5, -0.5], result: 0xc001c001 }, { inputs: [0.1, 0.5], result: 0x40000ccd }, { inputs: [-0.1, -0.5], result: 0xc001f333 }, // Subnormals { inputs: [kValue.f32.positive.subnormal.max, 1], result: 0x7fff0000 }, { inputs: [kValue.f32.negative.subnormal.min, 1], result: 0x7fff0000 }, ] as const) .fn(test => { const inputs = test.params.inputs; const got = pack2x16snorm(inputs[0], inputs[1]); const expect = test.params.result; test.expect(got === expect, `pack2x16snorm(${inputs}) returned ${got}. Expected ${expect}`); }); g.test('pack2x16unorm') .paramsSimple([ // Normals { inputs: [0, 0], result: 0x00000000 }, { inputs: [1, 0], result: 0x0000ffff }, { inputs: [0, 1], result: 0xffff0000 }, { inputs: [1, 1], result: 0xffffffff }, { inputs: [-1, -1], result: 0x00000000 }, { inputs: [0.1, 0.1], result: 0x199a199a }, { inputs: [0.5, 0.5], result: 0x80008000 }, { inputs: [0.1, 0.5], result: 0x8000199a }, { inputs: [10, 10], result: 0xffffffff }, // Subnormals { inputs: [kValue.f32.positive.subnormal.max, 1], result: 0xffff0000 }, ] as const) .fn(test => { const inputs = test.params.inputs; const got = pack2x16unorm(inputs[0], inputs[1]); const expect = test.params.result; test.expect(got === expect, `pack2x16unorm(${inputs}) returned ${got}. Expected ${expect}`); }); g.test('pack4x8snorm') .paramsSimple([ // Normals { inputs: [0, 0, 0, 0], result: 0x00000000 }, { inputs: [1, 0, 0, 0], result: 0x0000007f }, { inputs: [0, 1, 0, 0], result: 0x00007f00 }, { inputs: [0, 0, 1, 0], result: 0x007f0000 }, { inputs: [0, 0, 0, 1], result: 0x7f000000 }, { inputs: [1, 1, 1, 1], result: 0x7f7f7f7f }, { inputs: [10, 10, 10, 10], result: 0x7f7f7f7f }, { inputs: [-1, 0, 0, 0], result: 0x00000081 }, { inputs: [0, -1, 0, 0], result: 0x00008100 }, { inputs: [0, 0, -1, 0], result: 0x00810000 }, { inputs: [0, 0, 0, -1], result: 0x81000000 }, { inputs: [-1, -1, -1, -1], result: 0x81818181 }, { inputs: [-10, -10, -10, -10], result: 0x81818181 }, { inputs: [0.1, 0.1, 0.1, 0.1], result: 0x0d0d0d0d }, { inputs: [-0.1, -0.1, -0.1, -0.1], result: 0xf3f3f3f3 }, { inputs: [0.1, -0.1, 0.1, -0.1], result: 0xf30df30d }, { inputs: [0.5, 0.5, 0.5, 0.5], result: 0x40404040 }, { inputs: [-0.5, -0.5, -0.5, -0.5], result: 0xc1c1c1c1 }, { inputs: [-0.5, 0.5, -0.5, 0.5], result: 0x40c140c1 }, { inputs: [0.1, 0.5, 0.1, 0.5], result: 0x400d400d }, { inputs: [-0.1, -0.5, -0.1, -0.5], result: 0xc1f3c1f3 }, // Subnormals { inputs: [kValue.f32.positive.subnormal.max, 1, 1, 1], result: 0x7f7f7f00 }, { inputs: [kValue.f32.negative.subnormal.min, 1, 1, 1], result: 0x7f7f7f00 }, ] as const) .fn(test => { const inputs = test.params.inputs; const got = pack4x8snorm(inputs[0], inputs[1], inputs[2], inputs[3]); const expect = test.params.result; test.expect(got === expect, `pack4x8snorm(${inputs}) returned ${u32(got)}. Expected ${expect}`); }); g.test('pack4x8unorm') .paramsSimple([ // Normals { inputs: [0, 0, 0, 0], result: 0x00000000 }, { inputs: [1, 0, 0, 0], result: 0x000000ff }, { inputs: [0, 1, 0, 0], result: 0x0000ff00 }, { inputs: [0, 0, 1, 0], result: 0x00ff0000 }, { inputs: [0, 0, 0, 1], result: 0xff000000 }, { inputs: [1, 1, 1, 1], result: 0xffffffff }, { inputs: [10, 10, 10, 10], result: 0xffffffff }, { inputs: [-1, -1, -1, -1], result: 0x00000000 }, { inputs: [-10, -10, -10, -10], result: 0x00000000 }, { inputs: [0.1, 0.1, 0.1, 0.1], result: 0x1a1a1a1a }, { inputs: [0.5, 0.5, 0.5, 0.5], result: 0x80808080 }, { inputs: [0.1, 0.5, 0.1, 0.5], result: 0x801a801a }, // Subnormals { inputs: [kValue.f32.positive.subnormal.max, 1, 1, 1], result: 0xffffff00 }, ] as const) .fn(test => { const inputs = test.params.inputs; const got = pack4x8unorm(inputs[0], inputs[1], inputs[2], inputs[3]); const expect = test.params.result; test.expect(got === expect, `pack4x8unorm(${inputs}) returned ${got}. Expected ${expect}`); }); const kRGB9E5UFloatCommonData = { zero: /* */ { encoded: 0b00000_000000000_000000000_000000000, rgb: [0, 0, 0] }, max: /* */ { encoded: 0b11111_111111111_111111111_111111111, rgb: [65408, 65408, 65408] }, r1: /* */ { encoded: 0b10000_000000000_000000000_100000000, rgb: [1, 0, 0] }, r2: /* */ { encoded: 0b10001_000000000_000000000_100000000, rgb: [2, 0, 0] }, g1: /* */ { encoded: 0b10000_000000000_100000000_000000000, rgb: [0, 1, 0] }, g2: /* */ { encoded: 0b10001_000000000_100000000_000000000, rgb: [0, 2, 0] }, b1: /* */ { encoded: 0b10000_100000000_000000000_000000000, rgb: [0, 0, 1] }, b2: /* */ { encoded: 0b10001_100000000_000000000_000000000, rgb: [0, 0, 2] }, r1_g1_b1: /* */ { encoded: 0b10000_100000000_100000000_100000000, rgb: [1, 1, 1] }, r1_g2_b1: /* */ { encoded: 0b10001_010000000_100000000_010000000, rgb: [1, 2, 1] }, r4_g8_b2: /* */ { encoded: 0b10011_001000000_100000000_010000000, rgb: [4, 8, 2] }, r1_g2_b3: /* */ { encoded: 0b10001_110000000_100000000_010000000, rgb: [1, 2, 3] }, r128_g3968_b65408: { encoded: 0b11111_111111111_000011111_000000001, rgb: [128, 3968, 65408] }, r128_g1984_b30016: { encoded: 0b11110_111010101_000011111_000000010, rgb: [128, 1984, 30016] }, r_5_g_25_b_8: /**/ { encoded: 0b10011_100000000_000001000_000010000, rgb: [0.5, 0.25, 8] }, }; const kPackRGB9E5UFloatData = mergeParams(kRGB9E5UFloatCommonData, { clamp_max: /* */ { encoded: 0b11111_111111111_111111111_111111111, rgb: [1e7, 1e10, 1e50] }, subnormals: /* */ { encoded: 0b00000_000000000_000000000_000000000, rgb: [1e-10, 1e-20, 1e-30] }, r57423_g54_b3478: { encoded: 0b11111_000011011_000000000_111000001, rgb: [57423, 54, 3478] }, r6852_g3571_b2356: { encoded: 0b11100_010010011_011011111_110101100, rgb: [6852, 3571, 2356] }, r68312_g12_b8123: { encoded: 0b11111_000111111_000000000_111111111, rgb: [68312, 12, 8123] }, r7321_g846_b32: { encoded: 0b11100_000000010_000110101_111001010, rgb: [7321, 846, 32] }, }); function bits5_9_9_9(x: number) { const s = (x >>> 0).toString(2).padStart(32, '0'); return `${s.slice(0, 5)}_${s.slice(5, 14)}_${s.slice(14, 23)}_${s.slice(23, 32)}`; } g.test('packRGB9E5UFloat') .params(u => u.combine('case', keysOf(kPackRGB9E5UFloatData))) .fn(test => { const c = kPackRGB9E5UFloatData[test.params.case]; const got = packRGB9E5UFloat(c.rgb[0], c.rgb[1], c.rgb[2]); const expect = c.encoded; test.expect( got === expect, `packRGB9E5UFloat(${c.rgb}) returned ${bits5_9_9_9(got)}. Expected ${bits5_9_9_9(expect)}` ); }); g.test('unpackRGB9E5UFloat') .params(u => u.combine('case', keysOf(kRGB9E5UFloatCommonData))) .fn(test => { const c = kRGB9E5UFloatCommonData[test.params.case]; const got = unpackRGB9E5UFloat(c.encoded); const expect = c.rgb; test.expect( got.R === expect[0] && got.G === expect[1] && got.B === expect[2], `unpackRGB9E5UFloat(${bits5_9_9_9(c.encoded)} ` + `returned ${got.R},${got.G},${got.B}. Expected ${expect}` ); });