src/third_party/v8/test/mjsunit/tools/foozzie.js - cobalt - Git at Google

 // Copyright 2020 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Flags: --allow-natives-syntax
 // Files: tools/clusterfuzz/v8_mock.js

 // Test foozzie mocks for differential fuzzing.

 // Deterministic Math.random.
 assertEquals(0.7098480789645691, Math.random());
 assertEquals(0.9742682568175951, Math.random());
 assertEquals(0.20008059867222983, Math.random());

 // Deterministic date.
 assertEquals(1477662728698, Date.now());
 assertEquals(1477662728701, Date.now());
 assertEquals(1477662728705, new Date().getTime());
 assertEquals(710, new Date.prototype.constructor().getUTCMilliseconds());

 // Deterministic arguments in constructor keep working.
 assertEquals(819134640000,
              new Date('December 17, 1995 03:24:00 GMT+1000').getTime());

 // Dummy performance methods.
 assertEquals(1.2, performance.now());
 assertEquals([], performance.measureMemory());

 // Worker messages follow a predefined deterministic pattern.
 const worker = new Worker(``, {type: 'string'});
 assertEquals(0, worker.getMessage());
 assertEquals(-1, worker.getMessage());

 // NaN patterns in typed arrays are mocked out. Test that we get no
 // difference between unoptimized and optimized code.
 function testSameOptimized(pattern, create_fun) {
   const expected = new Uint32Array(pattern);
   %PrepareFunctionForOptimization(create_fun);
   assertEquals(expected, create_fun());
   %OptimizeFunctionOnNextCall(create_fun);
   assertEquals(expected, create_fun());
 }

 function testArrayType(arrayType, pattern) {
   // Test passing NaNs to constructor with array.
   let create = function() {
     return new Uint32Array(new arrayType([-NaN]).buffer);
   };
   testSameOptimized(pattern, create);
   // Test passing NaNs to constructor with iterator.
   create = function() {
     const iter = function*(){ yield* [-NaN]; }();
     return new Uint32Array(new arrayType(iter).buffer);
   };
   testSameOptimized(pattern, create);
   // Test setting NaN property.
   create = function() {
     const arr = new arrayType(1);
     arr[0] = -NaN;
     return new Uint32Array(arr.buffer);
   };
   testSameOptimized(pattern, create);
   // Test passing NaN using set.
   create = function() {
     const arr = new arrayType(1);
     arr.set([-NaN], 0);
     return new Uint32Array(arr.buffer);
   };
   testSameOptimized(pattern, create);
 }

 var isBigEndian = new Uint8Array(new Uint16Array([0xABCD]).buffer)[0] === 0xAB;
 testArrayType(Float32Array, [1065353216]);
 if (isBigEndian){
   testArrayType(Float64Array, [1072693248, 0]);
 }
 else {
   testArrayType(Float64Array, [0, 1072693248]);
 }

 // Test that DataView has the same NaN patterns with optimized and
 // unoptimized code.
 var expected_array = [4213246272,405619796,61503,0,3675212096,32831];
 if (isBigEndian){
   expected_array = [1074340347,1413754136,1072693248,0,1078530011,1065353216];
 }
 testSameOptimized(expected_array, () => {
   const array = new Uint32Array(6);
   const view = new DataView(array.buffer);
   view.setFloat64(0, Math.PI);
   view.setFloat64(8, -undefined);
   view.setFloat32(16, Math.fround(Math.PI));
   view.setFloat32(20, -undefined);
   assertEquals(Math.PI, view.getFloat64(0));
   assertEquals(Math.fround(Math.PI), view.getFloat32(16));
   return array;
 });

 // Realm.eval is just eval.
 assertEquals(1477662728716, Realm.eval(Realm.create(), `Date.now()`));

 // Test suppressions when Math.pow is optimized.
 function callPow(v) {
   return Math.pow(v, -0.5);
 }
 %PrepareFunctionForOptimization(callPow);
 const unoptimized = callPow(6996);
 %OptimizeFunctionOnNextCall(callPow);
 assertEquals(unoptimized, callPow(6996));

 // Test mocked Atomics.waitAsync.
 let then_called = false;
 Atomics.waitAsync().value.then(() => {then_called = true;});
 assertEquals(true, then_called);
	// Copyright 2020 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Flags: --allow-natives-syntax
	// Files: tools/clusterfuzz/v8_mock.js

	// Test foozzie mocks for differential fuzzing.

	// Deterministic Math.random.
	assertEquals(0.7098480789645691, Math.random());
	assertEquals(0.9742682568175951, Math.random());
	assertEquals(0.20008059867222983, Math.random());

	// Deterministic date.
	assertEquals(1477662728698, Date.now());
	assertEquals(1477662728701, Date.now());
	assertEquals(1477662728705, new Date().getTime());
	assertEquals(710, new Date.prototype.constructor().getUTCMilliseconds());

	// Deterministic arguments in constructor keep working.
	assertEquals(819134640000,
	new Date('December 17, 1995 03:24:00 GMT+1000').getTime());

	// Dummy performance methods.
	assertEquals(1.2, performance.now());
	assertEquals([], performance.measureMemory());

	// Worker messages follow a predefined deterministic pattern.
	const worker = new Worker(``, {type: 'string'});
	assertEquals(0, worker.getMessage());
	assertEquals(-1, worker.getMessage());

	// NaN patterns in typed arrays are mocked out. Test that we get no
	// difference between unoptimized and optimized code.
	function testSameOptimized(pattern, create_fun) {
	const expected = new Uint32Array(pattern);
	%PrepareFunctionForOptimization(create_fun);
	assertEquals(expected, create_fun());
	%OptimizeFunctionOnNextCall(create_fun);
	assertEquals(expected, create_fun());
	}

	function testArrayType(arrayType, pattern) {
	// Test passing NaNs to constructor with array.
	let create = function() {
	return new Uint32Array(new arrayType([-NaN]).buffer);
	};
	testSameOptimized(pattern, create);
	// Test passing NaNs to constructor with iterator.
	create = function() {
	const iter = function(){ yield [-NaN]; }();
	return new Uint32Array(new arrayType(iter).buffer);
	};
	testSameOptimized(pattern, create);
	// Test setting NaN property.
	create = function() {
	const arr = new arrayType(1);
	arr[0] = -NaN;
	return new Uint32Array(arr.buffer);
	};
	testSameOptimized(pattern, create);
	// Test passing NaN using set.
	create = function() {
	const arr = new arrayType(1);
	arr.set([-NaN], 0);
	return new Uint32Array(arr.buffer);
	};
	testSameOptimized(pattern, create);
	}

	var isBigEndian = new Uint8Array(new Uint16Array([0xABCD]).buffer)[0] === 0xAB;
	testArrayType(Float32Array, [1065353216]);
	if (isBigEndian){
	testArrayType(Float64Array, [1072693248, 0]);
	}
	else {
	testArrayType(Float64Array, [0, 1072693248]);
	}

	// Test that DataView has the same NaN patterns with optimized and
	// unoptimized code.
	var expected_array = [4213246272,405619796,61503,0,3675212096,32831];
	if (isBigEndian){
	expected_array = [1074340347,1413754136,1072693248,0,1078530011,1065353216];
	}
	testSameOptimized(expected_array, () => {
	const array = new Uint32Array(6);
	const view = new DataView(array.buffer);
	view.setFloat64(0, Math.PI);
	view.setFloat64(8, -undefined);
	view.setFloat32(16, Math.fround(Math.PI));
	view.setFloat32(20, -undefined);
	assertEquals(Math.PI, view.getFloat64(0));
	assertEquals(Math.fround(Math.PI), view.getFloat32(16));
	return array;
	});

	// Realm.eval is just eval.
	assertEquals(1477662728716, Realm.eval(Realm.create(), `Date.now()`));

	// Test suppressions when Math.pow is optimized.
	function callPow(v) {
	return Math.pow(v, -0.5);
	}
	%PrepareFunctionForOptimization(callPow);
	const unoptimized = callPow(6996);
	%OptimizeFunctionOnNextCall(callPow);
	assertEquals(unoptimized, callPow(6996));

	// Test mocked Atomics.waitAsync.
	let then_called = false;
	Atomics.waitAsync().value.then(() => {then_called = true;});
	assertEquals(true, then_called);