v8/test/mjsunit/harmony/futex.js

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// Copyright 2015 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
(function TestFailsWithNonSharedArray() {
var ab = new ArrayBuffer(16);
var i8a = new Int8Array(ab);
var i16a = new Int16Array(ab);
var i32a = new Int32Array(ab);
var ui8a = new Uint8Array(ab);
var ui8ca = new Uint8ClampedArray(ab);
var ui16a = new Uint16Array(ab);
var ui32a = new Uint32Array(ab);
var f32a = new Float32Array(ab);
var f64a = new Float64Array(ab);
[i8a, i16a, i32a, ui8a, ui8ca, ui16a, ui32a, f32a, f64a].forEach(function(
ta) {
assertThrows(function() { Atomics.futexWait(ta, 0, 0); });
assertThrows(function() { Atomics.futexWake(ta, 0, 1); });
assertThrows(function() { Atomics.futexWakeOrRequeue(ta, 0, 1, 0, 0); });
});
})();
(function TestFailsWithNonSharedInt32Array() {
var sab = new SharedArrayBuffer(16);
var i8a = new Int8Array(sab);
var i16a = new Int16Array(sab);
var ui8a = new Uint8Array(sab);
var ui8ca = new Uint8ClampedArray(sab);
var ui16a = new Uint16Array(sab);
var ui32a = new Uint32Array(sab);
var f32a = new Float32Array(sab);
var f64a = new Float64Array(sab);
[i8a, i16a, ui8a, ui8ca, ui16a, ui32a, f32a, f64a].forEach(function(
ta) {
assertThrows(function() { Atomics.futexWait(ta, 0, 0); });
assertThrows(function() { Atomics.futexWake(ta, 0, 1); });
assertThrows(function() { Atomics.futexWakeOrRequeue(ta, 0, 1, 0, 0); });
});
})();
(function TestInvalidIndex() {
var i32a = new Int32Array(new SharedArrayBuffer(16));
// Valid indexes are 0-3.
[-1, 4, 100].forEach(function(invalidIndex) {
assertEquals(undefined, Atomics.futexWait(i32a, invalidIndex, 0));
assertEquals(undefined, Atomics.futexWake(i32a, invalidIndex, 0));
var validIndex = 0;
assertEquals(undefined, Atomics.futexWakeOrRequeue(i32a, invalidIndex, 0, 0,
validIndex));
assertEquals(undefined, Atomics.futexWakeOrRequeue(i32a, validIndex, 0, 0,
invalidIndex));
});
})();
(function TestWaitTimeout() {
var i32a = new Int32Array(new SharedArrayBuffer(16));
var waitMs = 100;
var startTime = new Date();
assertEquals(Atomics.TIMEDOUT, Atomics.futexWait(i32a, 0, 0, waitMs));
var endTime = new Date();
assertTrue(endTime - startTime >= waitMs);
})();
(function TestWaitNotEqual() {
var i32a = new Int32Array(new SharedArrayBuffer(16));
assertEquals(Atomics.NOTEQUAL, Atomics.futexWait(i32a, 0, 42));
})();
(function TestWaitNegativeTimeout() {
var i32a = new Int32Array(new SharedArrayBuffer(16));
assertEquals(Atomics.TIMEDOUT, Atomics.futexWait(i32a, 0, 0, -1));
assertEquals(Atomics.TIMEDOUT, Atomics.futexWait(i32a, 0, 0, -Infinity));
})();
//// WORKER ONLY TESTS
if (this.Worker) {
var TestWaitWithTimeout = function(timeout) {
var sab = new SharedArrayBuffer(16);
var i32a = new Int32Array(sab);
var workerScript =
`onmessage = function(sab) {
var i32a = new Int32Array(sab);
var result = Atomics.futexWait(i32a, 0, 0, ${timeout});
postMessage(result);
};`;
var worker = new Worker(workerScript);
worker.postMessage(sab, [sab]);
// Spin until the worker is waiting on the futex.
while (%AtomicsFutexNumWaitersForTesting(i32a, 0) != 1) {}
Atomics.futexWake(i32a, 0, 1);
assertEquals(Atomics.OK, worker.getMessage());
worker.terminate();
};
// Test various infinite timeouts
TestWaitWithTimeout(undefined);
TestWaitWithTimeout(NaN);
TestWaitWithTimeout(Infinity);
(function TestWakeMulti() {
var sab = new SharedArrayBuffer(20);
var i32a = new Int32Array(sab);
// SAB values:
// i32a[id], where id in range [0, 3]:
// 0 => Worker |id| is still waiting on the futex
// 1 => Worker |id| is not waiting on futex, but has not be reaped by the
// main thread.
// 2 => Worker |id| has been reaped.
//
// i32a[4]:
// always 0. Each worker is waiting on this index.
var workerScript =
`onmessage = function(msg) {
var id = msg.id;
var i32a = new Int32Array(msg.sab);
// Wait on i32a[4] (should be zero).
var result = Atomics.futexWait(i32a, 4, 0);
// Set i32a[id] to 1 to notify the main thread which workers were
// woken up.
Atomics.store(i32a, id, 1);
postMessage(result);
};`;
var id;
var workers = [];
for (id = 0; id < 4; id++) {
workers[id] = new Worker(workerScript);
workers[id].postMessage({sab: sab, id: id}, [sab]);
}
// Spin until all workers are waiting on the futex.
while (%AtomicsFutexNumWaitersForTesting(i32a, 4) != 4) {}
// Wake up three waiters.
assertEquals(3, Atomics.futexWake(i32a, 4, 3));
var wokenCount = 0;
var waitingId = 0 + 1 + 2 + 3;
while (wokenCount < 3) {
for (id = 0; id < 4; id++) {
// Look for workers that have not yet been reaped. Set i32a[id] to 2
// when they've been processed so we don't look at them again.
if (Atomics.compareExchange(i32a, id, 1, 2) == 1) {
assertEquals(Atomics.OK, workers[id].getMessage());
workers[id].terminate();
waitingId -= id;
wokenCount++;
}
}
}
assertEquals(3, wokenCount);
assertEquals(0, Atomics.load(i32a, waitingId));
assertEquals(1, %AtomicsFutexNumWaitersForTesting(i32a, 4));
// Finally wake the last waiter.
assertEquals(1, Atomics.futexWake(i32a, 4, 1));
assertEquals(Atomics.OK, workers[waitingId].getMessage());
workers[waitingId].terminate();
assertEquals(0, %AtomicsFutexNumWaitersForTesting(i32a, 4));
})();
(function TestWakeOrRequeue() {
var sab = new SharedArrayBuffer(24);
var i32a = new Int32Array(sab);
// SAB values:
// i32a[id], where id in range [0, 3]:
// 0 => Worker |id| is still waiting on the futex
// 1 => Worker |id| is not waiting on futex, but has not be reaped by the
// main thread.
// 2 => Worker |id| has been reaped.
//
// i32a[4]:
// always 0. Each worker will initially wait on this index.
//
// i32a[5]:
// always 0. Requeued workers will wait on this index.
var workerScript =
`onmessage = function(msg) {
var id = msg.id;
var i32a = new Int32Array(msg.sab);
var result = Atomics.futexWait(i32a, 4, 0, Infinity);
Atomics.store(i32a, id, 1);
postMessage(result);
};`;
var workers = [];
for (id = 0; id < 4; id++) {
workers[id] = new Worker(workerScript);
workers[id].postMessage({sab: sab, id: id}, [sab]);
}
// Spin until all workers are waiting on the futex.
while (%AtomicsFutexNumWaitersForTesting(i32a, 4) != 4) {}
var index1 = 4;
var index2 = 5;
// If futexWakeOrRequeue is called with the incorrect value, it shouldn't
// wake any waiters.
assertEquals(Atomics.NOTEQUAL,
Atomics.futexWakeOrRequeue(i32a, index1, 1, 42, index2));
assertEquals(4, %AtomicsFutexNumWaitersForTesting(i32a, index1));
assertEquals(0, %AtomicsFutexNumWaitersForTesting(i32a, index2));
// Now wake with the correct value.
assertEquals(1, Atomics.futexWakeOrRequeue(i32a, index1, 1, 0, index2));
// The workers that are still waiting should atomically be transferred to
// the new index.
assertEquals(3, %AtomicsFutexNumWaitersForTesting(i32a, index2));
// The woken worker may not have been scheduled yet. Look for which thread
// has set its i32a value to 1.
var wokenCount = 0;
while (wokenCount < 1) {
for (id = 0; id < 4; id++) {
if (Atomics.compareExchange(i32a, id, 1, 2) == 1) {
wokenCount++;
}
}
}
assertEquals(0, %AtomicsFutexNumWaitersForTesting(i32a, index1));
// Wake the remaining waiters.
assertEquals(3, Atomics.futexWake(i32a, index2, 3));
// As above, wait until the workers have been scheduled.
wokenCount = 0;
while (wokenCount < 3) {
for (id = 0; id < 4; id++) {
if (Atomics.compareExchange(i32a, id, 1, 2) == 1) {
wokenCount++;
}
}
}
assertEquals(0, %AtomicsFutexNumWaitersForTesting(i32a, index1));
assertEquals(0, %AtomicsFutexNumWaitersForTesting(i32a, index2));
for (id = 0; id < 4; ++id) {
assertEquals(Atomics.OK, workers[id].getMessage());
workers[id].terminate();
}
})();
}