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onnxruntime/js/node/test/test-utils.ts
Yulong Wang f972d21e81
[js] upgrade dependencies and enable strict mode (#14930) 
### Description
This PR includes the following changes:
- upgrade js dependencies
- enable STRICT mode for web assembly build.
- corresponding fix for cmake-js upgrade
- corresponsing fix for linter upgrade
- upgrade default typescript compile option of:
    - `moduleResolution`: from `node` to `node16`
    - `target`: from `es2017` to `es2020`
- fix ESM module import in commonJS source file

## change explanation

### changes to onnxruntime_webassembly.cmake
`-s WASM=1` and `-s LLD_REPORT_UNDEFINED` in latest version is
by-default and deprecated.

### changes to onnxruntime_node.cmake
The npm package `cmake-js` updated its way to find file `node.lib`.
previously it downloads this file from Node.js public release channel,
and now it generates it from a definition file.

The node.js release channel does not contain a windows/arm64 version, so
previously cmake-js will fail to download `node.lib` for that platform.
this is why we made special handling to download the unofficial binary
to build. now this is no longer needed so we removed that from the cmake
file.

### changes to tsconfig.json
`node16` module resolution supports async import and `es2020` as target
supports top level await.
2023-03-22 15:05:04 -07:00

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// Copyright (c) Microsoft Corporation. All rights reserved.
// Licensed under the MIT License.
import assert from 'assert';
import * as fs from 'fs-extra';
import {jsonc} from 'jsonc';
import * as onnx_proto from 'onnx-proto';
import {InferenceSession, Tensor} from 'onnxruntime-common';
import * as path from 'path';
export const TEST_ROOT = __dirname;
export const TEST_DATA_ROOT = path.join(TEST_ROOT, 'testdata');
export const ORT_ROOT = path.join(__dirname, '../../..');
export const NODE_TESTS_ROOT = path.join(ORT_ROOT, 'js/test/data/node');
export const SQUEEZENET_INPUT0_DATA: number[] = require(path.join(TEST_DATA_ROOT, 'squeezenet.input0.json'));
export const SQUEEZENET_OUTPUT0_DATA: number[] = require(path.join(TEST_DATA_ROOT, 'squeezenet.output0.json'));
const BACKEND_TEST_SERIES_FILTERS: {[name: string]: Array<string|[string, string]>} =
jsonc.readSync(path.join(ORT_ROOT, 'onnxruntime/test/testdata/onnx_backend_test_series_filters.jsonc'));
const OVERRIDES: {
atol_default: number; rtol_default: number; atol_overrides: {[name: string]: number};
rtol_overrides: {[name: string]: number};
} = jsonc.readSync(path.join(ORT_ROOT, 'onnxruntime/test/testdata/onnx_backend_test_series_overrides.jsonc'));
const ATOL_DEFAULT = OVERRIDES.atol_default;
const RTOL_DEFAULT = OVERRIDES.rtol_default;
export const NUMERIC_TYPE_MAP = new Map<Tensor.Type, new (len: number) => Tensor.DataType>([
['float32', Float32Array],
['bool', Uint8Array],
['uint8', Uint8Array],
['int8', Int8Array],
['uint16', Uint16Array],
['int16', Int16Array],
['int32', Int32Array],
['int64', BigInt64Array],
['bool', Uint8Array],
['float64', Float64Array],
['uint32', Uint32Array],
['uint64', BigUint64Array],
]);
// a simple function to create a tensor data for test
export function createTestData(type: Tensor.Type, length: number): Tensor.DataType {
let data: Tensor.DataType;
if (type === 'string') {
data = new Array<string>(length);
for (let i = 0; i < length; i++) {
data[i] = `str${i}`;
}
} else {
data = new (NUMERIC_TYPE_MAP.get(type)!)(length);
for (let i = 0; i < length; i++) {
data[i] = (type === 'uint64' || type === 'int64') ? BigInt(i) : i;
}
}
return data;
}
// a simple function to create a tensor for test
export function createTestTensor(type: Tensor.Type, lengthOrDims?: number|number[]): Tensor {
let length = 100;
let dims = [100];
if (typeof lengthOrDims === 'number') {
length = lengthOrDims;
dims = [length];
} else if (Array.isArray(lengthOrDims)) {
dims = lengthOrDims;
length = dims.reduce((a, b) => a * b, 1);
}
return new Tensor(type, createTestData(type, length), dims);
}
// call the addon directly to make sure DLL is loaded
export function warmup(): void {
describe('Warmup', async function() {
// eslint-disable-next-line no-invalid-this
this.timeout(0);
// we have test cases to verify correctness in other place, so do no check here.
try {
const session = await InferenceSession.create(path.join(TEST_DATA_ROOT, 'test_types_int32.onnx'));
await session.run({input: new Tensor(new Float32Array(5), [1, 5])}, {output: null}, {});
} catch (e) {
}
});
}
export function assertFloatEqual(
actual: number[]|Float32Array|Float64Array, expected: number[]|Float32Array|Float64Array, atol?: number,
rtol?: number): void {
const absolute_tol: number = atol ?? 1.0e-4;
const relative_tol: number = 1 + (rtol ?? 1.0e-6);
assert.strictEqual(actual.length, expected.length);
for (let i = actual.length - 1; i >= 0; i--) {
const a = actual[i], b = expected[i];
if (a === b) {
continue;
}
// check for NaN
//
if (Number.isNaN(a) && Number.isNaN(b)) {
continue; // 2 numbers are NaN, treat as equal
}
if (Number.isNaN(a) || Number.isNaN(b)) {
// one is NaN and the other is not
assert.fail(`actual[${i}]=${a}, expected[${i}]=${b}`);
}
// Comparing 2 float numbers: (Suppose a >= b)
//
// if ( a - b < ABSOLUTE_ERROR || 1.0 < a / b < RELATIVE_ERROR)
// test pass
// else
// test fail
// endif
//
if (Math.abs(a - b) < absolute_tol) {
continue; // absolute error check pass
}
if (a !== 0 && b !== 0 && a * b > 0 && a / b < relative_tol && b / a < relative_tol) {
continue; // relative error check pass
}
// if code goes here, it means both (abs/rel) check failed.
assert.fail(`actual[${i}]=${a}, expected[${i}]=${b}`);
}
}
export function assertDataEqual(
type: Tensor.Type, actual: Tensor.DataType, expected: Tensor.DataType, atol?: number, rtol?: number): void {
switch (type) {
case 'float32':
case 'float64':
assertFloatEqual(
actual as number[] | Float32Array | Float64Array, expected as number[] | Float32Array | Float64Array, atol,
rtol);
break;
case 'uint8':
case 'int8':
case 'uint16':
case 'int16':
case 'uint32':
case 'int32':
case 'uint64':
case 'int64':
case 'bool':
case 'string':
assert.deepStrictEqual(actual, expected);
break;
default:
throw new Error('type not implemented or not supported');
}
}
// This function check whether 2 tensors should be considered as 'match' or not
export function assertTensorEqual(actual: Tensor, expected: Tensor, atol?: number, rtol?: number): void {
assert(typeof actual === 'object');
assert(typeof expected === 'object');
assert(Array.isArray(actual.dims));
assert(Array.isArray(expected.dims));
const actualDims = actual.dims;
const actualType = actual.type;
const expectedDims = expected.dims;
const expectedType = expected.type;
assert.strictEqual(actualType, expectedType);
assert.deepStrictEqual(actualDims, expectedDims);
assertDataEqual(actualType, actual.data, expected.data, atol, rtol);
}
export function loadTensorFromFile(pbFile: string): Tensor {
const tensorProto = onnx_proto.onnx.TensorProto.decode(fs.readFileSync(pbFile));
let transferredTypedArray: Tensor.DataType;
let type: Tensor.Type;
const dims = tensorProto.dims.map((dim) => typeof dim === 'number' ? dim : dim.toNumber());
if (tensorProto.dataType === 8) { // string
return new Tensor('string', tensorProto.stringData.map(i => i.toString()), dims);
} else {
switch (tensorProto.dataType) {
// FLOAT = 1,
// UINT8 = 2,
// INT8 = 3,
// UINT16 = 4,
// INT16 = 5,
// INT32 = 6,
// INT64 = 7,
// STRING = 8,
// BOOL = 9,
// FLOAT16 = 10,
// DOUBLE = 11,
// UINT32 = 12,
// UINT64 = 13,
case onnx_proto.onnx.TensorProto.DataType.FLOAT:
transferredTypedArray = new Float32Array(tensorProto.rawData.byteLength / 4);
type = 'float32';
break;
case onnx_proto.onnx.TensorProto.DataType.UINT8:
transferredTypedArray = new Uint8Array(tensorProto.rawData.byteLength);
type = 'uint8';
break;
case onnx_proto.onnx.TensorProto.DataType.INT8:
transferredTypedArray = new Int8Array(tensorProto.rawData.byteLength);
type = 'int8';
break;
case onnx_proto.onnx.TensorProto.DataType.UINT16:
transferredTypedArray = new Uint16Array(tensorProto.rawData.byteLength / 2);
type = 'uint16';
break;
case onnx_proto.onnx.TensorProto.DataType.INT16:
transferredTypedArray = new Int16Array(tensorProto.rawData.byteLength / 2);
type = 'int16';
break;
case onnx_proto.onnx.TensorProto.DataType.INT32:
transferredTypedArray = new Int32Array(tensorProto.rawData.byteLength / 4);
type = 'int32';
break;
case onnx_proto.onnx.TensorProto.DataType.INT64:
transferredTypedArray = new BigInt64Array(tensorProto.rawData.byteLength / 8);
type = 'int64';
break;
case onnx_proto.onnx.TensorProto.DataType.BOOL:
transferredTypedArray = new Uint8Array(tensorProto.rawData.byteLength);
type = 'bool';
break;
case onnx_proto.onnx.TensorProto.DataType.DOUBLE:
transferredTypedArray = new Float64Array(tensorProto.rawData.byteLength / 8);
type = 'float64';
break;
case onnx_proto.onnx.TensorProto.DataType.UINT32:
transferredTypedArray = new Uint32Array(tensorProto.rawData.byteLength / 4);
type = 'uint32';
break;
case onnx_proto.onnx.TensorProto.DataType.UINT64:
transferredTypedArray = new BigUint64Array(tensorProto.rawData.byteLength / 8);
type = 'uint64';
break;
default:
throw new Error(`not supported tensor type: ${tensorProto.dataType}`);
}
const transferredTypedArrayRawDataView =
new Uint8Array(transferredTypedArray.buffer, transferredTypedArray.byteOffset, tensorProto.rawData.byteLength);
transferredTypedArrayRawDataView.set(tensorProto.rawData);
return new Tensor(type, transferredTypedArray, dims);
}
}
function loadFiltersRegex(): Array<{opset?: RegExp | undefined; name: RegExp}> {
const filters: Array<string|[string, string]> = ['(FLOAT16)'];
filters.push(...BACKEND_TEST_SERIES_FILTERS.current_failing_tests);
if (process.arch === 'ia32') {
filters.push(...BACKEND_TEST_SERIES_FILTERS.current_failing_tests_x86);
}
filters.push(...BACKEND_TEST_SERIES_FILTERS.tests_with_pre_opset7_dependencies);
filters.push(...BACKEND_TEST_SERIES_FILTERS.unsupported_usages);
filters.push(...BACKEND_TEST_SERIES_FILTERS.failing_permanently);
filters.push(...BACKEND_TEST_SERIES_FILTERS.test_with_types_disabled_due_to_binary_size_concerns);
filters.push(...BACKEND_TEST_SERIES_FILTERS.failing_permanently_nodejs_binding);
return filters.map(
filter => typeof filter === 'string' ? {name: new RegExp(filter)} :
{opset: new RegExp(filter[0]), name: new RegExp(filter[1])});
}
const BACKEND_TEST_SERIES_FILTERS_REGEX = loadFiltersRegex();
export function shouldSkipModel(model: string, opset: string, eps: string[]): boolean {
for (const regex of BACKEND_TEST_SERIES_FILTERS_REGEX) {
if (regex.opset) {
if (!regex.opset.test(opset)) {
continue;
}
}
for (const ep of eps) {
if (regex.name.test(`${model}_${ep}`)) {
return true;
}
}
}
return false;
}
export function atol(model: string): number {
return OVERRIDES.atol_overrides[model] ?? ATOL_DEFAULT;
}
export function rtol(model: string): number {
return OVERRIDES.rtol_overrides[model] ?? RTOL_DEFAULT;
}
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