// Copyright 2014 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: --harmony-atomics --harmony-sharedarraybuffer
//
function toRangeWrapped(value) {
var range = this.max - this.min + 1;
while (value < this.min) {
value += range;
}
while (value > this.max) {
value -= range;
}
return value;
}
function toRangeClamped(value) {
if (value < this.min) return this.min;
if (value > this.max) return this.max;
return value;
}
function makeConstructorObject(constr, min, max, toRange) {
var o = {constr: constr, min: min, max: max};
o.toRange = toRange.bind(o);
return o;
}
var IntegerTypedArrayConstructors = [
makeConstructorObject(Int8Array, -128, 127, toRangeWrapped),
makeConstructorObject(Int16Array, -32768, 32767, toRangeWrapped),
makeConstructorObject(Int32Array, -0x80000000, 0x7fffffff, toRangeWrapped),
makeConstructorObject(Uint8Array, 0, 255, toRangeWrapped),
makeConstructorObject(Uint8ClampedArray, 0, 255, toRangeClamped),
makeConstructorObject(Uint16Array, 0, 65535, toRangeWrapped),
makeConstructorObject(Uint32Array, 0, 0xffffffff, toRangeWrapped),
];
var TypedArrayConstructors = IntegerTypedArrayConstructors.concat([
{constr: Float32Array},
{constr: Float64Array},
]);
(function TestBadArray() {
var ab = new ArrayBuffer(16);
var u32a = new Uint32Array(16);
var sab = new SharedArrayBuffer(128);
var sf32a = new Float32Array(sab);
var sf64a = new Float64Array(sab);
// Atomic ops required shared typed arrays
[undefined, 1, 'hi', 3.4, ab, u32a, sab].forEach(function(o) {
assertThrows(function() { Atomics.compareExchange(o, 0, 0, 0); },
TypeError);
assertThrows(function() { Atomics.load(o, 0); }, TypeError);
assertThrows(function() { Atomics.store(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.add(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.sub(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.and(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.or(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.xor(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.exchange(o, 0, 0); }, TypeError);
});
// Arithmetic atomic ops require integer shared arrays
[sab, sf32a, sf64a].forEach(function(o) {
assertThrows(function() { Atomics.add(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.sub(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.and(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.or(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.xor(o, 0, 0); }, TypeError);
assertThrows(function() { Atomics.exchange(o, 0, 0); }, TypeError);
});
})();
function testAtomicOp(op, ia, index, expectedIndex, name) {
for (var i = 0; i < ia.length; ++i)
ia[i] = 22;
ia[expectedIndex] = 0;
assertEquals(0, op(ia, index, 0, 0), name);
assertEquals(0, ia[expectedIndex], name);
for (var i = 0; i < ia.length; ++i) {
if (i == expectedIndex) continue;
assertEquals(22, ia[i], name);
}
}
(function TestBadIndex() {
var sab = new SharedArrayBuffer(8);
var si32a = new Int32Array(sab);
// Non-integer indexes are converted to an integer first, so they should all
// operate on index 0.
[undefined, null, false, 'hi', {}].forEach(function(i) {
var name = String(i);
testAtomicOp(Atomics.compareExchange, si32a, i, 0, name);
testAtomicOp(Atomics.load, si32a, i, 0, name);
testAtomicOp(Atomics.store, si32a, i, 0, name);
testAtomicOp(Atomics.add, si32a, i, 0, name);
testAtomicOp(Atomics.sub, si32a, i, 0, name);
testAtomicOp(Atomics.and, si32a, i, 0, name);
testAtomicOp(Atomics.or, si32a, i, 0, name);
testAtomicOp(Atomics.xor, si32a, i, 0, name);
testAtomicOp(Atomics.exchange, si32a, i, 0, name);
});
// Out-of-bounds indexes should return undefined.
// TODO(binji): Should these throw RangeError instead?
[-1, 2, 100].forEach(function(i) {
var name = String(i);
assertEquals(undefined, Atomics.compareExchange(si32a, i, 0, 0), name);
assertEquals(undefined, Atomics.load(si32a, i), name);
assertEquals(undefined, Atomics.store(si32a, i, 0), name);
assertEquals(undefined, Atomics.add(si32a, i, 0), name);
assertEquals(undefined, Atomics.sub(si32a, i, 0), name);
assertEquals(undefined, Atomics.and(si32a, i, 0), name);
assertEquals(undefined, Atomics.or(si32a, i, 0), name);
assertEquals(undefined, Atomics.xor(si32a, i, 0), name);
assertEquals(undefined, Atomics.exchange(si32a, i, 0), name);
});
// Monkey-patch length and make sure these functions still return undefined.
Object.defineProperty(si32a, 'length', {get: function() { return 1000; }});
[2, 100].forEach(function(i) {
var name = String(i);
assertEquals(undefined, Atomics.compareExchange(si32a, i, 0, 0), name);
assertEquals(undefined, Atomics.load(si32a, i), name);
assertEquals(undefined, Atomics.store(si32a, i, 0), name);
assertEquals(undefined, Atomics.add(si32a, i, 0), name);
assertEquals(undefined, Atomics.sub(si32a, i, 0), name);
assertEquals(undefined, Atomics.and(si32a, i, 0), name);
assertEquals(undefined, Atomics.or(si32a, i, 0), name);
assertEquals(undefined, Atomics.xor(si32a, i, 0), name);
assertEquals(undefined, Atomics.exchange(si32a, i, 0), name);
});
})();
(function TestGoodIndex() {
var sab = new SharedArrayBuffer(64);
var si32a = new Int32Array(sab);
var valueOf = {valueOf: function(){ return 3;}};
var toString = {toString: function(){ return '3';}};
[3, 3.5, '3', '3.5', valueOf, toString].forEach(function(i) {
var name = String(i);
testAtomicOp(Atomics.compareExchange, si32a, i, 3, name);
testAtomicOp(Atomics.load, si32a, i, 3, name);
testAtomicOp(Atomics.store, si32a, i, 3, name);
testAtomicOp(Atomics.add, si32a, i, 3, name);
testAtomicOp(Atomics.sub, si32a, i, 3, name);
testAtomicOp(Atomics.and, si32a, i, 3, name);
testAtomicOp(Atomics.or, si32a, i, 3, name);
testAtomicOp(Atomics.xor, si32a, i, 3, name);
testAtomicOp(Atomics.exchange, si32a, i, 3, name);
});
})();
(function TestCompareExchange() {
TypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
// sta[i] == 0, CAS will store
assertEquals(0, Atomics.compareExchange(sta, i, 0, 50), name);
assertEquals(50, sta[i], name);
// sta[i] == 50, CAS will not store
assertEquals(50, Atomics.compareExchange(sta, i, 0, 100), name);
assertEquals(50, sta[i], name);
}
});
// * Exact float values should be OK
// * Infinity, -Infinity should be OK (has exact representation)
// * NaN is not OK, it has many representations, cannot ensure successful CAS
// because it does a bitwise compare
[1.5, 4.25, -1e8, -Infinity, Infinity].forEach(function(v) {
var sab = new SharedArrayBuffer(10 * Float32Array.BYTES_PER_ELEMENT);
var sf32a = new Float32Array(sab);
sf32a[0] = 0;
assertEquals(0, Atomics.compareExchange(sf32a, 0, 0, v));
assertEquals(v, sf32a[0]);
assertEquals(v, Atomics.compareExchange(sf32a, 0, v, 0));
assertEquals(0, sf32a[0]);
var sab2 = new SharedArrayBuffer(10 * Float64Array.BYTES_PER_ELEMENT);
var sf64a = new Float64Array(sab2);
sf64a[0] = 0;
assertEquals(0, Atomics.compareExchange(sf64a, 0, 0, v));
assertEquals(v, sf64a[0]);
assertEquals(v, Atomics.compareExchange(sf64a, 0, v, 0));
assertEquals(0, sf64a[0]);
});
})();
(function TestLoad() {
TypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 0;
assertEquals(0, Atomics.load(sta, i), name);
sta[i] = 50;
assertEquals(50, Atomics.load(sta, i), name);
}
});
})();
(function TestStore() {
TypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
assertEquals(50, Atomics.store(sta, i, 50), name);
assertEquals(50, sta[i], name);
assertEquals(100, Atomics.store(sta, i, 100), name);
assertEquals(100, sta[i], name);
}
});
[1.5, 4.25, -1e8, -Infinity, Infinity, NaN].forEach(function(v) {
var sab = new SharedArrayBuffer(10 * Float32Array.BYTES_PER_ELEMENT);
var sf32a = new Float32Array(sab);
sf32a[0] = 0;
assertEquals(v, Atomics.store(sf32a, 0, v));
assertEquals(v, sf32a[0]);
var sab2 = new SharedArrayBuffer(10 * Float64Array.BYTES_PER_ELEMENT);
var sf64a = new Float64Array(sab2);
sf64a[0] = 0;
assertEquals(v, Atomics.store(sf64a, 0, v));
assertEquals(v, sf64a[0]);
});
})();
(function TestAdd() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
assertEquals(0, Atomics.add(sta, i, 50), name);
assertEquals(50, sta[i], name);
assertEquals(50, Atomics.add(sta, i, 70), name);
assertEquals(120, sta[i], name);
}
});
})();
(function TestSub() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 120;
assertEquals(120, Atomics.sub(sta, i, 50), name);
assertEquals(70, sta[i], name);
assertEquals(70, Atomics.sub(sta, i, 70), name);
assertEquals(0, sta[i], name);
}
});
})();
(function TestAnd() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 0x3f;
assertEquals(0x3f, Atomics.and(sta, i, 0x30), name);
assertEquals(0x30, sta[i], name);
assertEquals(0x30, Atomics.and(sta, i, 0x20), name);
assertEquals(0x20, sta[i], name);
}
});
})();
(function TestOr() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 0x30;
assertEquals(0x30, Atomics.or(sta, i, 0x1c), name);
assertEquals(0x3c, sta[i], name);
assertEquals(0x3c, Atomics.or(sta, i, 0x09), name);
assertEquals(0x3d, sta[i], name);
}
});
})();
(function TestXor() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 0x30;
assertEquals(0x30, Atomics.xor(sta, i, 0x1c), name);
assertEquals(0x2c, sta[i], name);
assertEquals(0x2c, Atomics.xor(sta, i, 0x09), name);
assertEquals(0x25, sta[i], name);
}
});
})();
(function TestExchange() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
for (var i = 0; i < 10; ++i) {
sta[i] = 0x30;
assertEquals(0x30, Atomics.exchange(sta, i, 0x1c), name);
assertEquals(0x1c, sta[i], name);
assertEquals(0x1c, Atomics.exchange(sta, i, 0x09), name);
assertEquals(0x09, sta[i], name);
}
});
})();
(function TestIsLockFree() {
// For all platforms we support, 1, 2 and 4 bytes should be lock-free.
assertEquals(true, Atomics.isLockFree(1));
assertEquals(true, Atomics.isLockFree(2));
assertEquals(true, Atomics.isLockFree(4));
// Sizes that aren't equal to a typedarray BYTES_PER_ELEMENT always return
// false.
var validSizes = {};
TypedArrayConstructors.forEach(function(t) {
validSizes[t.constr.BYTES_PER_ELEMENT] = true;
});
for (var i = 0; i < 1000; ++i) {
if (!validSizes[i]) {
assertEquals(false, Atomics.isLockFree(i));
}
}
})();
(function TestToNumber() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(1 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var valueOf = {valueOf: function(){ return 3;}};
var toString = {toString: function(){ return '3';}};
[false, true, undefined, valueOf, toString].forEach(function(v) {
var name = Object.prototype.toString.call(sta) + ' - ' + v;
// CompareExchange
sta[0] = 50;
assertEquals(50, Atomics.compareExchange(sta, 0, v, v), name);
// Store
assertEquals(+v, Atomics.store(sta, 0, v), name);
assertEquals(v|0, sta[0], name);
// Add
sta[0] = 120;
assertEquals(120, Atomics.add(sta, 0, v), name);
assertEquals(120 + (v|0), sta[0], name);
// Sub
sta[0] = 70;
assertEquals(70, Atomics.sub(sta, 0, v), name);
assertEquals(70 - (v|0), sta[0]);
// And
sta[0] = 0x20;
assertEquals(0x20, Atomics.and(sta, 0, v), name);
assertEquals(0x20 & (v|0), sta[0]);
// Or
sta[0] = 0x3d;
assertEquals(0x3d, Atomics.or(sta, 0, v), name);
assertEquals(0x3d | (v|0), sta[0]);
// Xor
sta[0] = 0x25;
assertEquals(0x25, Atomics.xor(sta, 0, v), name);
assertEquals(0x25 ^ (v|0), sta[0]);
// Exchange
sta[0] = 0x09;
assertEquals(0x09, Atomics.exchange(sta, 0, v), name);
assertEquals(v|0, sta[0]);
});
});
})();
(function TestWrapping() {
IntegerTypedArrayConstructors.forEach(function(t) {
var sab = new SharedArrayBuffer(10 * t.constr.BYTES_PER_ELEMENT);
var sta = new t.constr(sab);
var name = Object.prototype.toString.call(sta);
var range = t.max - t.min + 1;
var offset;
var operand;
var val, newVal;
var valWrapped, newValWrapped;
for (offset = -range; offset <= range; offset += range) {
// CompareExchange
sta[0] = val = 0;
newVal = val + offset + 1;
newValWrapped = t.toRange(newVal);
assertEquals(val, Atomics.compareExchange(sta, 0, val, newVal), name);
assertEquals(newValWrapped, sta[0], name);
sta[0] = val = t.min;
newVal = val + offset - 1;
newValWrapped = t.toRange(newVal);
assertEquals(val, Atomics.compareExchange(sta, 0, val, newVal), name);
assertEquals(newValWrapped, sta[0], name);
// Store
sta[0] = 0;
val = t.max + offset + 1;
valWrapped = t.toRange(val);
assertEquals(val, Atomics.store(sta, 0, val), name);
assertEquals(valWrapped, sta[0], name);
sta[0] = val = t.min + offset - 1;
valWrapped = t.toRange(val);
assertEquals(val, Atomics.store(sta, 0, val), name);
assertEquals(valWrapped, sta[0], name);
// Add
sta[0] = val = t.max;
operand = offset + 1;
valWrapped = t.toRange(val + operand);
assertEquals(val, Atomics.add(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
sta[0] = val = t.min;
operand = offset - 1;
valWrapped = t.toRange(val + operand);
assertEquals(val, Atomics.add(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
// Sub
sta[0] = val = t.max;
operand = offset - 1;
valWrapped = t.toRange(val - operand);
assertEquals(val, Atomics.sub(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
sta[0] = val = t.min;
operand = offset + 1;
valWrapped = t.toRange(val - operand);
assertEquals(val, Atomics.sub(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
// There's no way to wrap results with logical operators, just test that
// using an out-of-range value is properly wrapped/clamped when written
// to memory.
// And
sta[0] = val = 0xf;
operand = 0x3 + offset;
valWrapped = t.toRange(val & operand);
assertEquals(val, Atomics.and(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
// Or
sta[0] = val = 0x12;
operand = 0x22 + offset;
valWrapped = t.toRange(val | operand);
assertEquals(val, Atomics.or(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
// Xor
sta[0] = val = 0x12;
operand = 0x22 + offset;
valWrapped = t.toRange(val ^ operand);
assertEquals(val, Atomics.xor(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
// Exchange
sta[0] = val = 0x12;
operand = 0x22 + offset;
valWrapped = t.toRange(operand);
assertEquals(val, Atomics.exchange(sta, 0, operand), name);
assertEquals(valWrapped, sta[0], name);
}
});
})();