src/third_party/v8/test/mjsunit/wasm/futex.js - cobalt - Git at Google

 // Copyright 2018 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 --harmony-sharedarraybuffer
 // Flags: --experimental-wasm-threads

 'use strict';

 load("test/mjsunit/wasm/wasm-module-builder.js");

 function WasmAtomicNotify(memory, offset, index, num) {
   let builder = new WasmModuleBuilder();
   builder.addImportedMemory("m", "memory", 0, 20, "shared");
   builder.addFunction("main", kSig_i_ii)
     .addBody([
       kExprLocalGet, 0,
       kExprLocalGet, 1,
       kAtomicPrefix,
       kExprAtomicNotify, /* alignment */ 0, offset])
     .exportAs("main");

   // Instantiate module, get function exports
   let module = new WebAssembly.Module(builder.toBuffer());
   let instance = new WebAssembly.Instance(module, {m: {memory}});
   return instance.exports.main(index, num);
 }

 function WasmI32AtomicWait(memory, offset, index, val, timeout) {
   let builder = new WasmModuleBuilder();
   builder.addImportedMemory("m", "memory", 0, 20, "shared");
   builder.addFunction("main",
     makeSig([kWasmI32, kWasmI32, kWasmF64], [kWasmI32]))
     .addBody([
       kExprLocalGet, 0,
       kExprLocalGet, 1,
       kExprLocalGet, 2,
       kExprI64SConvertF64,
       kAtomicPrefix,
       kExprI32AtomicWait, /* alignment */ 0, offset])
       .exportAs("main");

   // Instantiate module, get function exports
   let module = new WebAssembly.Module(builder.toBuffer());
   let instance = new WebAssembly.Instance(module, {m: {memory}});
   return instance.exports.main(index, val, timeout);
 }

 function WasmI64AtomicWait(memory, offset, index, val_low,
                                    val_high, timeout) {
   let builder = new WasmModuleBuilder();
   builder.addImportedMemory("m", "memory", 0, 20, "shared");
   // Wrapper for I64AtomicWait that takes two I32 values and combines to into
   // I64 for the instruction parameter.
   builder.addFunction("main",
     makeSig([kWasmI32, kWasmI32, kWasmI32, kWasmF64], [kWasmI32]))
     .addLocals(kWasmI64, 1) // local that is passed as value param to wait
     .addBody([
       kExprLocalGet, 1,
       kExprI64UConvertI32,
       kExprI64Const, 32,
       kExprI64Shl,
       kExprLocalGet, 2,
       kExprI64UConvertI32,
       kExprI64Ior,
       kExprLocalSet, 4, // Store the created I64 value in local
       kExprLocalGet, 0,
       kExprLocalGet, 4,
       kExprLocalGet, 3,
       kExprI64SConvertF64,
       kAtomicPrefix,
       kExprI64AtomicWait, /* alignment */ 0, offset])
       .exportAs("main");

   // Instantiate module, get function exports
   let module = new WebAssembly.Module(builder.toBuffer());
   let instance = new WebAssembly.Instance(module, {m: {memory}});
   return instance.exports.main(index, val_high, val_low, timeout);
 }

 (function TestInvalidIndex() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

   // Valid indexes are 0-65535 (1 page).
   [-2, 65536, 0xffffffff].forEach(function(invalidIndex) {
     assertThrows(function() {
       WasmAtomicNotify(memory, 0, invalidIndex, -1);
     }, Error);
     assertThrows(function() {
       WasmI32AtomicWait(memory, 0, invalidIndex, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, 0, invalidIndex, 0, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmAtomicNotify(memory, invalidIndex, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmI32AtomicWait(memory, invalidIndex, 0, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, invalidIndex, 0, 0, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmAtomicNotify(memory, invalidIndex/2, invalidIndex/2, -1);
     }, Error);
     assertThrows(function() {
       WasmI32AtomicWait(memory, invalidIndex/2, invalidIndex/2, 0, -1);
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, invalidIndex/2, invalidIndex/2, 0, 0, -1);
     }, Error);
   });
 })();

 (function TestInvalidAlignment() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

   // Wait and wake must be 4 byte aligned.
   [1, 2, 3].forEach(function(invalid) {
     assertThrows(function() {
       WasmAtomicNotify(memory, invalid, 0, -1)
     }, Error);
     assertThrows(function() {
       WasmAtomicNotify(memory, 0, invalid, -1)
     }, Error);
     assertThrows(function() {
       WasmI32AtomicWait(memory, invalid, 0, 0, -1)
     }, Error);
     assertThrows(function() {
       WasmI32AtomicWait(memory, 0, invalid, 0, -1)
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, invalid, 0, 0, 0, -1)
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, 0, invalid, 0, 0, -1)
     }, Error);
   });

   //WasmI64AtomicWait must be 8 byte aligned.
   [4, 5, 6, 7].forEach(function(invalid) {
     assertThrows(function() {
       WasmI64AtomicWait(memory, 0, invalid, 0, 0, -1)
     }, Error);
     assertThrows(function() {
       WasmI64AtomicWait(memory, invalid, 0, 0, 0, -1)
     }, Error);
   });
 })();

 (function TestI32WaitTimeout() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
   var waitMs = 100;
   var startTime = new Date();
   assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 0, waitMs*1000000));
   var endTime = new Date();
   assertTrue(endTime - startTime >= waitMs);
 })();

 (function TestI64WaitTimeout() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
   var waitMs = 100;
   var startTime = new Date();
   assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 0, 0, waitMs*1000000));
   var endTime = new Date();
   assertTrue(endTime - startTime >= waitMs);
 })();

 (function TestI32WaitNotEqual() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
   assertEquals(1, WasmI32AtomicWait(memory, 0, 0, 42, -1));

   assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 0, 0));

   let i32a = new Int32Array(memory.buffer);
   i32a[0] = 1;
   assertEquals(1, WasmI32AtomicWait(memory, 0, 0, 0, -1));
   assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 1, 0));
 })();

 (function TestI64WaitNotEqual() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
   assertEquals(1, WasmI64AtomicWait(memory, 0, 0, 42, 0, -1));

   assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 0, 0, 0));

   let i32a = new Int32Array(memory.buffer);
   i32a[0] = 1;
   i32a[1] = 2;
   assertEquals(1, WasmI64AtomicWait(memory, 0, 0, 0, 0, -1));
   assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 1, 2, 0));
 })();

 (function TestWakeCounts() {
   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

   [-1, 0, 4, 100, 0xffffffff].forEach(function(count) {
     WasmAtomicNotify(memory, 0, 0, count);
   });
 })();

 //// WORKER ONLY TESTS

 if (this.Worker) {

   // This test creates 4 workers that wait on consecutive (8 byte separated to
   // satisfy alignments for all kinds of wait) memory locations to test various
   // wait/wake combinations. For each combination, each thread waits 3 times
   // expecting all 4 threads to be woken with wake(4) in first iteration, all 4
   // to be woken with wake(5) in second iteration and, 3 and 1 to be woken in
   // third iteration.

   let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
   let i32a = new Int32Array(memory.buffer);
   const numWorkers = 4;

   let workerScript = `onmessage = function(msg) {
     load("test/mjsunit/wasm/wasm-module-builder.js");
     ${WasmI32AtomicWait.toString()}
     ${WasmI64AtomicWait.toString()}
     let id = msg.id;
     let memory = msg.memory;
     let i32a = new Int32Array(memory.buffer);
     // indices are right shifted by 2 for Atomics.wait to convert them to index
     // for Int32Array
     // for wasm-wake numWorkers threads
     let result = Atomics.wait(i32a, 0>>>2, 0);
     postMessage(result);
     // for wasm-wake numWorkers + 1 threads
     result = Atomics.wait(i32a, 8>>>2, 0);
     postMessage(result);
     // for wasm-wake numWorkers - 1 threads
     result = Atomics.wait(i32a, 16>>>2, 0);
     postMessage(result);
     // for js-wake numWorkers threads
     result = WasmI32AtomicWait(memory, 0, 24, 0, -1);
     postMessage(result);
     // for js-wake numWorkers + 1 threads
     result = WasmI32AtomicWait(memory, 0, 32, 0, -1);
     postMessage(result);
     // for js-wake numWorkers - 1 threads
     result = WasmI32AtomicWait(memory, 0, 40, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers threads
     result = WasmI32AtomicWait(memory, 0, 48, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers + 1 threads
     result = WasmI32AtomicWait(memory, 0, 56, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers - 1 threads
     result = WasmI32AtomicWait(memory, 0, 64, 0, -1);
     postMessage(result);
     // for js-wake numWorkers threads
     result = WasmI64AtomicWait(memory, 0, 72, 0, 0, -1);
     postMessage(result);
     // for js-wake numWorkers + 1 threads
     result = WasmI64AtomicWait(memory, 0, 80, 0, 0, -1);
     postMessage(result);
     // for js-wake numWorkers - 1 threads
     result = WasmI64AtomicWait(memory, 0, 88, 0, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers threads
     result = WasmI64AtomicWait(memory, 0, 96, 0, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers + 1 threads
     result = WasmI64AtomicWait(memory, 0, 104, 0, 0, -1);
     postMessage(result);
     // for wasm-wake numWorkers - 1 threads
     result = WasmI64AtomicWait(memory, 0, 112, 0, 0, -1);
     postMessage(result);
   };`;

   let waitForAllWorkers = function(index) {
     // index is right shifted by 2 to convert to index in Int32Array
     while (%AtomicsNumWaitersForTesting(i32a, index>>>2) != numWorkers) {}
   }

   let jsWakeCheck = function(index, num, workers, msg) {
     waitForAllWorkers(index);
     let indexJs = index>>>2; // convert to index in Int32Array
     if (num >= numWorkers) {
       // if numWorkers or more is passed to wake, numWorkers workers should be
       // woken.
       assertEquals(numWorkers, Atomics.notify(i32a, indexJs, num));
     } else {
       // if num < numWorkers is passed to wake, num workers should be woken.
       // Then the remaining workers are woken for the next part
       assertEquals(num, Atomics.notify(i32a, indexJs, num));
       assertEquals(numWorkers-num, Atomics.notify(i32a, indexJs, numWorkers));
     }
     for (let id = 0; id < numWorkers; id++) {
       assertEquals(msg, workers[id].getMessage());
     }
   };

   let wasmWakeCheck = function(index, num, workers, msg) {
     waitForAllWorkers(index);
     if (num >= numWorkers) {
       // if numWorkers or more is passed to wake, numWorkers workers should be
       // woken.
       assertEquals(numWorkers, WasmAtomicNotify(memory, 0, index, num));
     } else {
       // if num < numWorkers is passed to wake, num workers should be woken.
       // Then the remaining workers are woken for the next part
       assertEquals(num, WasmAtomicNotify(memory, 0, index, num));
       assertEquals(numWorkers-num,
                    WasmAtomicNotify(memory, 0, index, numWorkers));
     }
     for (let id = 0; id < numWorkers; id++) {
       assertEquals(msg, workers[id].getMessage());
     }
   };

   let workers = [];
   for (let id = 0; id < numWorkers; id++) {
     workers[id] = new Worker(workerScript, {type: 'string'});
     workers[id].postMessage({id, memory});
   }

   wasmWakeCheck(0, numWorkers, workers, "ok");
   wasmWakeCheck(8, numWorkers + 1, workers, "ok");
   wasmWakeCheck(16, numWorkers - 1, workers, "ok");

   jsWakeCheck(24, numWorkers, workers, 0);
   jsWakeCheck(32, numWorkers + 1, workers, 0);
   jsWakeCheck(40, numWorkers - 1, workers, 0);

   wasmWakeCheck(48, numWorkers, workers, 0);
   wasmWakeCheck(56, numWorkers + 1, workers, 0);
   wasmWakeCheck(64, numWorkers - 1, workers, 0);

   jsWakeCheck(72, numWorkers, workers, 0);
   jsWakeCheck(80, numWorkers + 1, workers, 0);
   jsWakeCheck(88, numWorkers - 1, workers, 0);

   wasmWakeCheck(96, numWorkers, workers, 0);
   wasmWakeCheck(104, numWorkers + 1, workers, 0);
   wasmWakeCheck(112, numWorkers - 1, workers, 0);

   for (let id = 0; id < numWorkers; id++) {
     workers[id].terminate();
   }
 }
	// Copyright 2018 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 --harmony-sharedarraybuffer
	// Flags: --experimental-wasm-threads

	'use strict';

	load("test/mjsunit/wasm/wasm-module-builder.js");

	function WasmAtomicNotify(memory, offset, index, num) {
	let builder = new WasmModuleBuilder();
	builder.addImportedMemory("m", "memory", 0, 20, "shared");
	builder.addFunction("main", kSig_i_ii)
	.addBody([
	kExprLocalGet, 0,
	kExprLocalGet, 1,
	kAtomicPrefix,
	kExprAtomicNotify, /* alignment */ 0, offset])
	.exportAs("main");

	// Instantiate module, get function exports
	let module = new WebAssembly.Module(builder.toBuffer());
	let instance = new WebAssembly.Instance(module, {m: {memory}});
	return instance.exports.main(index, num);
	}

	function WasmI32AtomicWait(memory, offset, index, val, timeout) {
	let builder = new WasmModuleBuilder();
	builder.addImportedMemory("m", "memory", 0, 20, "shared");
	builder.addFunction("main",
	makeSig([kWasmI32, kWasmI32, kWasmF64], [kWasmI32]))
	.addBody([
	kExprLocalGet, 0,
	kExprLocalGet, 1,
	kExprLocalGet, 2,
	kExprI64SConvertF64,
	kAtomicPrefix,
	kExprI32AtomicWait, /* alignment */ 0, offset])
	.exportAs("main");

	// Instantiate module, get function exports
	let module = new WebAssembly.Module(builder.toBuffer());
	let instance = new WebAssembly.Instance(module, {m: {memory}});
	return instance.exports.main(index, val, timeout);
	}

	function WasmI64AtomicWait(memory, offset, index, val_low,
	val_high, timeout) {
	let builder = new WasmModuleBuilder();
	builder.addImportedMemory("m", "memory", 0, 20, "shared");
	// Wrapper for I64AtomicWait that takes two I32 values and combines to into
	// I64 for the instruction parameter.
	builder.addFunction("main",
	makeSig([kWasmI32, kWasmI32, kWasmI32, kWasmF64], [kWasmI32]))
	.addLocals(kWasmI64, 1) // local that is passed as value param to wait
	.addBody([
	kExprLocalGet, 1,
	kExprI64UConvertI32,
	kExprI64Const, 32,
	kExprI64Shl,
	kExprLocalGet, 2,
	kExprI64UConvertI32,
	kExprI64Ior,
	kExprLocalSet, 4, // Store the created I64 value in local
	kExprLocalGet, 0,
	kExprLocalGet, 4,
	kExprLocalGet, 3,
	kExprI64SConvertF64,
	kAtomicPrefix,
	kExprI64AtomicWait, /* alignment */ 0, offset])
	.exportAs("main");

	// Instantiate module, get function exports
	let module = new WebAssembly.Module(builder.toBuffer());
	let instance = new WebAssembly.Instance(module, {m: {memory}});
	return instance.exports.main(index, val_high, val_low, timeout);
	}

	(function TestInvalidIndex() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

	// Valid indexes are 0-65535 (1 page).
	[-2, 65536, 0xffffffff].forEach(function(invalidIndex) {
	assertThrows(function() {
	WasmAtomicNotify(memory, 0, invalidIndex, -1);
	}, Error);
	assertThrows(function() {
	WasmI32AtomicWait(memory, 0, invalidIndex, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, 0, invalidIndex, 0, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmAtomicNotify(memory, invalidIndex, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmI32AtomicWait(memory, invalidIndex, 0, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, invalidIndex, 0, 0, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmAtomicNotify(memory, invalidIndex/2, invalidIndex/2, -1);
	}, Error);
	assertThrows(function() {
	WasmI32AtomicWait(memory, invalidIndex/2, invalidIndex/2, 0, -1);
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, invalidIndex/2, invalidIndex/2, 0, 0, -1);
	}, Error);
	});
	})();

	(function TestInvalidAlignment() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

	// Wait and wake must be 4 byte aligned.
	[1, 2, 3].forEach(function(invalid) {
	assertThrows(function() {
	WasmAtomicNotify(memory, invalid, 0, -1)
	}, Error);
	assertThrows(function() {
	WasmAtomicNotify(memory, 0, invalid, -1)
	}, Error);
	assertThrows(function() {
	WasmI32AtomicWait(memory, invalid, 0, 0, -1)
	}, Error);
	assertThrows(function() {
	WasmI32AtomicWait(memory, 0, invalid, 0, -1)
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, invalid, 0, 0, 0, -1)
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, 0, invalid, 0, 0, -1)
	}, Error);
	});

	//WasmI64AtomicWait must be 8 byte aligned.
	[4, 5, 6, 7].forEach(function(invalid) {
	assertThrows(function() {
	WasmI64AtomicWait(memory, 0, invalid, 0, 0, -1)
	}, Error);
	assertThrows(function() {
	WasmI64AtomicWait(memory, invalid, 0, 0, 0, -1)
	}, Error);
	});
	})();

	(function TestI32WaitTimeout() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
	var waitMs = 100;
	var startTime = new Date();
	assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 0, waitMs*1000000));
	var endTime = new Date();
	assertTrue(endTime - startTime >= waitMs);
	})();

	(function TestI64WaitTimeout() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
	var waitMs = 100;
	var startTime = new Date();
	assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 0, 0, waitMs*1000000));
	var endTime = new Date();
	assertTrue(endTime - startTime >= waitMs);
	})();

	(function TestI32WaitNotEqual() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
	assertEquals(1, WasmI32AtomicWait(memory, 0, 0, 42, -1));

	assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 0, 0));

	let i32a = new Int32Array(memory.buffer);
	i32a[0] = 1;
	assertEquals(1, WasmI32AtomicWait(memory, 0, 0, 0, -1));
	assertEquals(2, WasmI32AtomicWait(memory, 0, 0, 1, 0));
	})();

	(function TestI64WaitNotEqual() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
	assertEquals(1, WasmI64AtomicWait(memory, 0, 0, 42, 0, -1));

	assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 0, 0, 0));

	let i32a = new Int32Array(memory.buffer);
	i32a[0] = 1;
	i32a[1] = 2;
	assertEquals(1, WasmI64AtomicWait(memory, 0, 0, 0, 0, -1));
	assertEquals(2, WasmI64AtomicWait(memory, 0, 0, 1, 2, 0));
	})();

	(function TestWakeCounts() {
	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});

	[-1, 0, 4, 100, 0xffffffff].forEach(function(count) {
	WasmAtomicNotify(memory, 0, 0, count);
	});
	})();

	//// WORKER ONLY TESTS

	if (this.Worker) {

	// This test creates 4 workers that wait on consecutive (8 byte separated to
	// satisfy alignments for all kinds of wait) memory locations to test various
	// wait/wake combinations. For each combination, each thread waits 3 times
	// expecting all 4 threads to be woken with wake(4) in first iteration, all 4
	// to be woken with wake(5) in second iteration and, 3 and 1 to be woken in
	// third iteration.

	let memory = new WebAssembly.Memory({initial: 1, maximum: 1, shared: true});
	let i32a = new Int32Array(memory.buffer);
	const numWorkers = 4;

	let workerScript = `onmessage = function(msg) {
	load("test/mjsunit/wasm/wasm-module-builder.js");
	${WasmI32AtomicWait.toString()}
	${WasmI64AtomicWait.toString()}
	let id = msg.id;
	let memory = msg.memory;
	let i32a = new Int32Array(memory.buffer);
	// indices are right shifted by 2 for Atomics.wait to convert them to index
	// for Int32Array
	// for wasm-wake numWorkers threads
	let result = Atomics.wait(i32a, 0>>>2, 0);
	postMessage(result);
	// for wasm-wake numWorkers + 1 threads
	result = Atomics.wait(i32a, 8>>>2, 0);
	postMessage(result);
	// for wasm-wake numWorkers - 1 threads
	result = Atomics.wait(i32a, 16>>>2, 0);
	postMessage(result);
	// for js-wake numWorkers threads
	result = WasmI32AtomicWait(memory, 0, 24, 0, -1);
	postMessage(result);
	// for js-wake numWorkers + 1 threads
	result = WasmI32AtomicWait(memory, 0, 32, 0, -1);
	postMessage(result);
	// for js-wake numWorkers - 1 threads
	result = WasmI32AtomicWait(memory, 0, 40, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers threads
	result = WasmI32AtomicWait(memory, 0, 48, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers + 1 threads
	result = WasmI32AtomicWait(memory, 0, 56, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers - 1 threads
	result = WasmI32AtomicWait(memory, 0, 64, 0, -1);
	postMessage(result);
	// for js-wake numWorkers threads
	result = WasmI64AtomicWait(memory, 0, 72, 0, 0, -1);
	postMessage(result);
	// for js-wake numWorkers + 1 threads
	result = WasmI64AtomicWait(memory, 0, 80, 0, 0, -1);
	postMessage(result);
	// for js-wake numWorkers - 1 threads
	result = WasmI64AtomicWait(memory, 0, 88, 0, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers threads
	result = WasmI64AtomicWait(memory, 0, 96, 0, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers + 1 threads
	result = WasmI64AtomicWait(memory, 0, 104, 0, 0, -1);
	postMessage(result);
	// for wasm-wake numWorkers - 1 threads
	result = WasmI64AtomicWait(memory, 0, 112, 0, 0, -1);
	postMessage(result);
	};`;

	let waitForAllWorkers = function(index) {
	// index is right shifted by 2 to convert to index in Int32Array
	while (%AtomicsNumWaitersForTesting(i32a, index>>>2) != numWorkers) {}
	}

	let jsWakeCheck = function(index, num, workers, msg) {
	waitForAllWorkers(index);
	let indexJs = index>>>2; // convert to index in Int32Array
	if (num >= numWorkers) {
	// if numWorkers or more is passed to wake, numWorkers workers should be
	// woken.
	assertEquals(numWorkers, Atomics.notify(i32a, indexJs, num));
	} else {
	// if num < numWorkers is passed to wake, num workers should be woken.
	// Then the remaining workers are woken for the next part
	assertEquals(num, Atomics.notify(i32a, indexJs, num));
	assertEquals(numWorkers-num, Atomics.notify(i32a, indexJs, numWorkers));
	}
	for (let id = 0; id < numWorkers; id++) {
	assertEquals(msg, workers[id].getMessage());
	}
	};

	let wasmWakeCheck = function(index, num, workers, msg) {
	waitForAllWorkers(index);
	if (num >= numWorkers) {
	// if numWorkers or more is passed to wake, numWorkers workers should be
	// woken.
	assertEquals(numWorkers, WasmAtomicNotify(memory, 0, index, num));
	} else {
	// if num < numWorkers is passed to wake, num workers should be woken.
	// Then the remaining workers are woken for the next part
	assertEquals(num, WasmAtomicNotify(memory, 0, index, num));
	assertEquals(numWorkers-num,
	WasmAtomicNotify(memory, 0, index, numWorkers));
	}
	for (let id = 0; id < numWorkers; id++) {
	assertEquals(msg, workers[id].getMessage());
	}
	};

	let workers = [];
	for (let id = 0; id < numWorkers; id++) {
	workers[id] = new Worker(workerScript, {type: 'string'});
	workers[id].postMessage({id, memory});
	}

	wasmWakeCheck(0, numWorkers, workers, "ok");
	wasmWakeCheck(8, numWorkers + 1, workers, "ok");
	wasmWakeCheck(16, numWorkers - 1, workers, "ok");

	jsWakeCheck(24, numWorkers, workers, 0);
	jsWakeCheck(32, numWorkers + 1, workers, 0);
	jsWakeCheck(40, numWorkers - 1, workers, 0);

	wasmWakeCheck(48, numWorkers, workers, 0);
	wasmWakeCheck(56, numWorkers + 1, workers, 0);
	wasmWakeCheck(64, numWorkers - 1, workers, 0);

	jsWakeCheck(72, numWorkers, workers, 0);
	jsWakeCheck(80, numWorkers + 1, workers, 0);
	jsWakeCheck(88, numWorkers - 1, workers, 0);

	wasmWakeCheck(96, numWorkers, workers, 0);
	wasmWakeCheck(104, numWorkers + 1, workers, 0);
	wasmWakeCheck(112, numWorkers - 1, workers, 0);

	for (let id = 0; id < numWorkers; id++) {
	workers[id].terminate();
	}
	}