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denoland-deno/extensions/webidl/00_webidl.js
2021-04-30 15:51:48 -04:00

919 lines
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JavaScript

// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license.
// Adapted from https://github.com/jsdom/webidl-conversions.
// Copyright Domenic Denicola. Licensed under BSD-2-Clause License.
// Original license at https://github.com/jsdom/webidl-conversions/blob/master/LICENSE.md.
"use strict";
((window) => {
function makeException(ErrorType, message, opts = {}) {
if (opts.globals) {
ErrorType = opts.globals[ErrorType.name];
}
return new ErrorType(
`${opts.prefix ? opts.prefix + ": " : ""}${
opts.context ? opts.context : "Value"
} ${message}`,
);
}
function toNumber(value, opts = {}) {
if (!opts.globals) {
return +value;
}
if (typeof value === "bigint") {
throw opts.globals.TypeError("Cannot convert a BigInt value to a number");
}
return opts.globals.Number(value);
}
function type(V) {
if (V === null) {
return "Null";
}
switch (typeof V) {
case "undefined":
return "Undefined";
case "boolean":
return "Boolean";
case "number":
return "Number";
case "string":
return "String";
case "symbol":
return "Symbol";
case "bigint":
return "BigInt";
case "object":
// Falls through
case "function":
// Falls through
default:
// Per ES spec, typeof returns an implemention-defined value that is not any of the existing ones for
// uncallable non-standard exotic objects. Yet Type() which the Web IDL spec depends on returns Object for
// such cases. So treat the default case as an object.
return "Object";
}
}
// Round x to the nearest integer, choosing the even integer if it lies halfway between two.
function evenRound(x) {
// There are four cases for numbers with fractional part being .5:
//
// case | x | floor(x) | round(x) | expected | x <> 0 | x % 1 | x & 1 | example
// 1 | 2n + 0.5 | 2n | 2n + 1 | 2n | > | 0.5 | 0 | 0.5 -> 0
// 2 | 2n + 1.5 | 2n + 1 | 2n + 2 | 2n + 2 | > | 0.5 | 1 | 1.5 -> 2
// 3 | -2n - 0.5 | -2n - 1 | -2n | -2n | < | -0.5 | 0 | -0.5 -> 0
// 4 | -2n - 1.5 | -2n - 2 | -2n - 1 | -2n - 2 | < | -0.5 | 1 | -1.5 -> -2
// (where n is a non-negative integer)
//
// Branch here for cases 1 and 4
if (
(x > 0 && x % 1 === +0.5 && (x & 1) === 0) ||
(x < 0 && x % 1 === -0.5 && (x & 1) === 1)
) {
return censorNegativeZero(Math.floor(x));
}
return censorNegativeZero(Math.round(x));
}
function integerPart(n) {
return censorNegativeZero(Math.trunc(n));
}
function sign(x) {
return x < 0 ? -1 : 1;
}
function modulo(x, y) {
// https://tc39.github.io/ecma262/#eqn-modulo
// Note that http://stackoverflow.com/a/4467559/3191 does NOT work for large modulos
const signMightNotMatch = x % y;
if (sign(y) !== sign(signMightNotMatch)) {
return signMightNotMatch + y;
}
return signMightNotMatch;
}
function censorNegativeZero(x) {
return x === 0 ? 0 : x;
}
function createIntegerConversion(bitLength, typeOpts) {
const isSigned = !typeOpts.unsigned;
let lowerBound;
let upperBound;
if (bitLength === 64) {
upperBound = Number.MAX_SAFE_INTEGER;
lowerBound = !isSigned ? 0 : Number.MIN_SAFE_INTEGER;
} else if (!isSigned) {
lowerBound = 0;
upperBound = Math.pow(2, bitLength) - 1;
} else {
lowerBound = -Math.pow(2, bitLength - 1);
upperBound = Math.pow(2, bitLength - 1) - 1;
}
const twoToTheBitLength = Math.pow(2, bitLength);
const twoToOneLessThanTheBitLength = Math.pow(2, bitLength - 1);
return (V, opts = {}) => {
let x = toNumber(V, opts);
x = censorNegativeZero(x);
if (opts.enforceRange) {
if (!Number.isFinite(x)) {
throw makeException(TypeError, "is not a finite number", opts);
}
x = integerPart(x);
if (x < lowerBound || x > upperBound) {
throw makeException(
TypeError,
`is outside the accepted range of ${lowerBound} to ${upperBound}, inclusive`,
opts,
);
}
return x;
}
if (!Number.isNaN(x) && opts.clamp) {
x = Math.min(Math.max(x, lowerBound), upperBound);
x = evenRound(x);
return x;
}
if (!Number.isFinite(x) || x === 0) {
return 0;
}
x = integerPart(x);
// Math.pow(2, 64) is not accurately representable in JavaScript, so try to avoid these per-spec operations if
// possible. Hopefully it's an optimization for the non-64-bitLength cases too.
if (x >= lowerBound && x <= upperBound) {
return x;
}
// These will not work great for bitLength of 64, but oh well. See the README for more details.
x = modulo(x, twoToTheBitLength);
if (isSigned && x >= twoToOneLessThanTheBitLength) {
return x - twoToTheBitLength;
}
return x;
};
}
function createLongLongConversion(bitLength, { unsigned }) {
const upperBound = Number.MAX_SAFE_INTEGER;
const lowerBound = unsigned ? 0 : Number.MIN_SAFE_INTEGER;
const asBigIntN = unsigned ? BigInt.asUintN : BigInt.asIntN;
return (V, opts = {}) => {
let x = toNumber(V, opts);
x = censorNegativeZero(x);
if (opts.enforceRange) {
if (!Number.isFinite(x)) {
throw makeException(TypeError, "is not a finite number", opts);
}
x = integerPart(x);
if (x < lowerBound || x > upperBound) {
throw makeException(
TypeError,
`is outside the accepted range of ${lowerBound} to ${upperBound}, inclusive`,
opts,
);
}
return x;
}
if (!Number.isNaN(x) && opts.clamp) {
x = Math.min(Math.max(x, lowerBound), upperBound);
x = evenRound(x);
return x;
}
if (!Number.isFinite(x) || x === 0) {
return 0;
}
let xBigInt = BigInt(integerPart(x));
xBigInt = asBigIntN(bitLength, xBigInt);
return Number(xBigInt);
};
}
const converters = [];
converters.any = (V) => {
return V;
};
converters.boolean = function (val) {
return !!val;
};
converters.byte = createIntegerConversion(8, { unsigned: false });
converters.octet = createIntegerConversion(8, { unsigned: true });
converters.short = createIntegerConversion(16, { unsigned: false });
converters["unsigned short"] = createIntegerConversion(16, {
unsigned: true,
});
converters.long = createIntegerConversion(32, { unsigned: false });
converters["unsigned long"] = createIntegerConversion(32, { unsigned: true });
converters["long long"] = createLongLongConversion(64, { unsigned: false });
converters["unsigned long long"] = createLongLongConversion(64, {
unsigned: true,
});
converters.float = (V, opts) => {
const x = toNumber(V, opts);
if (!Number.isFinite(x)) {
throw makeException(
TypeError,
"is not a finite floating-point value",
opts,
);
}
if (Object.is(x, -0)) {
return x;
}
const y = Math.fround(x);
if (!Number.isFinite(y)) {
throw makeException(
TypeError,
"is outside the range of a single-precision floating-point value",
opts,
);
}
return y;
};
converters["unrestricted float"] = (V, opts) => {
const x = toNumber(V, opts);
if (isNaN(x)) {
return x;
}
if (Object.is(x, -0)) {
return x;
}
return Math.fround(x);
};
converters.double = (V, opts) => {
const x = toNumber(V, opts);
if (!Number.isFinite(x)) {
throw makeException(
TypeError,
"is not a finite floating-point value",
opts,
);
}
return x;
};
converters["unrestricted double"] = (V, opts) => {
const x = toNumber(V, opts);
return x;
};
converters.DOMString = function (V, opts = {}) {
if (opts.treatNullAsEmptyString && V === null) {
return "";
}
if (typeof V === "symbol") {
throw makeException(
TypeError,
"is a symbol, which cannot be converted to a string",
opts,
);
}
const StringCtor = opts.globals ? opts.globals.String : String;
return StringCtor(V);
};
converters.ByteString = (V, opts) => {
const x = converters.DOMString(V, opts);
let c;
for (let i = 0; (c = x.codePointAt(i)) !== undefined; ++i) {
if (c > 255) {
throw makeException(TypeError, "is not a valid ByteString", opts);
}
}
return x;
};
converters.USVString = (V, opts) => {
const S = converters.DOMString(V, opts);
const n = S.length;
const U = [];
for (let i = 0; i < n; ++i) {
const c = S.charCodeAt(i);
if (c < 0xd800 || c > 0xdfff) {
U.push(String.fromCodePoint(c));
} else if (0xdc00 <= c && c <= 0xdfff) {
U.push(String.fromCodePoint(0xfffd));
} else if (i === n - 1) {
U.push(String.fromCodePoint(0xfffd));
} else {
const d = S.charCodeAt(i + 1);
if (0xdc00 <= d && d <= 0xdfff) {
const a = c & 0x3ff;
const b = d & 0x3ff;
U.push(String.fromCodePoint((2 << 15) + (2 << 9) * a + b));
++i;
} else {
U.push(String.fromCodePoint(0xfffd));
}
}
}
return U.join("");
};
converters.object = (V, opts) => {
if (type(V) !== "Object") {
throw makeException(TypeError, "is not an object", opts);
}
return V;
};
// Not exported, but used in Function and VoidFunction.
// Neither Function nor VoidFunction is defined with [TreatNonObjectAsNull], so
// handling for that is omitted.
function convertCallbackFunction(V, opts) {
if (typeof V !== "function") {
throw makeException(TypeError, "is not a function", opts);
}
return V;
}
function isNonSharedArrayBuffer(V) {
return V instanceof ArrayBuffer;
}
function isSharedArrayBuffer(V) {
return V instanceof SharedArrayBuffer;
}
function isArrayBufferDetached(V) {
try {
// eslint-disable-next-line no-new
new Uint8Array(V);
return false;
} catch {
return true;
}
}
converters.ArrayBuffer = (V, opts = {}) => {
if (!isNonSharedArrayBuffer(V)) {
if (opts.allowShared && !isSharedArrayBuffer(V)) {
throw makeException(
TypeError,
"is not an ArrayBuffer or SharedArrayBuffer",
opts,
);
}
throw makeException(TypeError, "is not an ArrayBuffer", opts);
}
if (isArrayBufferDetached(V)) {
throw makeException(TypeError, "is a detached ArrayBuffer", opts);
}
return V;
};
converters.DataView = (V, opts = {}) => {
if (!(V instanceof DataView)) {
throw makeException(TypeError, "is not a DataView", opts);
}
if (!opts.allowShared && isSharedArrayBuffer(V.buffer)) {
throw makeException(
TypeError,
"is backed by a SharedArrayBuffer, which is not allowed",
opts,
);
}
if (isArrayBufferDetached(V.buffer)) {
throw makeException(
TypeError,
"is backed by a detached ArrayBuffer",
opts,
);
}
return V;
};
// Returns the unforgeable `TypedArray` constructor name or `undefined`,
// if the `this` value isn't a valid `TypedArray` object.
//
// https://tc39.es/ecma262/#sec-get-%typedarray%.prototype-@@tostringtag
const typedArrayNameGetter = Object.getOwnPropertyDescriptor(
Object.getPrototypeOf(Uint8Array).prototype,
Symbol.toStringTag,
).get;
[
Int8Array,
Int16Array,
Int32Array,
Uint8Array,
Uint16Array,
Uint32Array,
Uint8ClampedArray,
Float32Array,
Float64Array,
].forEach((func) => {
const name = func.name;
const article = /^[AEIOU]/.test(name) ? "an" : "a";
converters[name] = (V, opts = {}) => {
if (!ArrayBuffer.isView(V) || typedArrayNameGetter.call(V) !== name) {
throw makeException(
TypeError,
`is not ${article} ${name} object`,
opts,
);
}
if (!opts.allowShared && isSharedArrayBuffer(V.buffer)) {
throw makeException(
TypeError,
"is a view on a SharedArrayBuffer, which is not allowed",
opts,
);
}
if (isArrayBufferDetached(V.buffer)) {
throw makeException(
TypeError,
"is a view on a detached ArrayBuffer",
opts,
);
}
return V;
};
});
// Common definitions
converters.ArrayBufferView = (V, opts = {}) => {
if (!ArrayBuffer.isView(V)) {
throw makeException(
TypeError,
"is not a view on an ArrayBuffer or SharedArrayBuffer",
opts,
);
}
if (!opts.allowShared && isSharedArrayBuffer(V.buffer)) {
throw makeException(
TypeError,
"is a view on a SharedArrayBuffer, which is not allowed",
opts,
);
}
if (isArrayBufferDetached(V.buffer)) {
throw makeException(
TypeError,
"is a view on a detached ArrayBuffer",
opts,
);
}
return V;
};
converters.BufferSource = (V, opts = {}) => {
if (ArrayBuffer.isView(V)) {
if (!opts.allowShared && isSharedArrayBuffer(V.buffer)) {
throw makeException(
TypeError,
"is a view on a SharedArrayBuffer, which is not allowed",
opts,
);
}
if (isArrayBufferDetached(V.buffer)) {
throw makeException(
TypeError,
"is a view on a detached ArrayBuffer",
opts,
);
}
return V;
}
if (!opts.allowShared && !isNonSharedArrayBuffer(V)) {
throw makeException(
TypeError,
"is not an ArrayBuffer or a view on one",
opts,
);
}
if (
opts.allowShared &&
!isSharedArrayBuffer(V) &&
!isNonSharedArrayBuffer(V)
) {
throw makeException(
TypeError,
"is not an ArrayBuffer, SharedArrayBuffer, or a view on one",
opts,
);
}
if (isArrayBufferDetached(V)) {
throw makeException(TypeError, "is a detached ArrayBuffer", opts);
}
return V;
};
converters.DOMTimeStamp = converters["unsigned long long"];
converters.Function = convertCallbackFunction;
converters.VoidFunction = convertCallbackFunction;
converters["UVString?"] = createNullableConverter(
converters.USVString,
);
converters["sequence<double>"] = createSequenceConverter(
converters["double"],
);
function requiredArguments(length, required, opts = {}) {
if (length < required) {
const errMsg = `${
opts.prefix ? opts.prefix + ": " : ""
}${required} argument${
required === 1 ? "" : "s"
} required, but only ${length} present.`;
throw new TypeError(errMsg);
}
}
function isEmptyObject(V) {
for (const _ in V) return false;
return true;
}
function createDictionaryConverter(name, ...dictionaries) {
let hasRequiredKey = false;
const allMembers = [];
for (const members of dictionaries) {
for (const member of members) {
if (member.required) {
hasRequiredKey = true;
}
allMembers.push(member);
}
}
allMembers.sort((a, b) => {
if (a.key == b.key) {
return 0;
}
return a.key < b.key ? -1 : 1;
});
const defaultValues = {};
for (const member of allMembers) {
if ("defaultValue" in member) {
const idlMemberValue = member.defaultValue;
const imvType = typeof idlMemberValue;
// Copy by value types can be directly assigned, copy by reference types
// need to be re-created for each allocation.
if (
imvType === "number" || imvType === "boolean" ||
imvType === "string" || imvType === "bigint" ||
imvType === "undefined"
) {
defaultValues[member.key] = idlMemberValue;
} else {
Object.defineProperty(defaultValues, member.key, {
get() {
return member.defaultValue;
},
});
}
}
}
return function (V, opts = {}) {
const typeV = type(V);
switch (typeV) {
case "Undefined":
case "Null":
case "Object":
break;
default:
throw makeException(
TypeError,
"can not be converted to a dictionary",
opts,
);
}
const esDict = V;
const idlDict = { ...defaultValues };
// NOTE: fast path Null and Undefined and empty objects.
if (
(V === undefined || V === null || isEmptyObject(V)) && !hasRequiredKey
) {
return idlDict;
}
for (const member of allMembers) {
const key = member.key;
let esMemberValue;
if (typeV === "Undefined" || typeV === "Null") {
esMemberValue = undefined;
} else {
esMemberValue = esDict[key];
}
if (esMemberValue !== undefined) {
const context = `'${key}' of '${name}'${
opts.context ? ` (${opts.context})` : ""
}`;
const converter = member.converter;
const idlMemberValue = converter(esMemberValue, { ...opts, context });
idlDict[key] = idlMemberValue;
} else if (member.required) {
throw makeException(
TypeError,
`can not be converted to '${name}' because '${key}' is required in '${name}'.`,
{ ...opts },
);
}
}
return idlDict;
};
}
// https://heycam.github.io/webidl/#es-enumeration
function createEnumConverter(name, values) {
const E = new Set(values);
return function (V, opts = {}) {
const S = String(V);
if (!E.has(S)) {
throw new TypeError(
`${
opts.prefix ? opts.prefix + ": " : ""
}The provided value '${S}' is not a valid enum value of type ${name}.`,
);
}
return S;
};
}
function createNullableConverter(converter) {
return (V, opts = {}) => {
// FIXME: If Type(V) is not Object, and the conversion to an IDL value is
// being performed due to V being assigned to an attribute whose type is a
// nullable callback function that is annotated with
// [LegacyTreatNonObjectAsNull], then return the IDL nullable type T?
// value null.
if (V === null || V === undefined) return null;
return converter(V, opts);
};
}
// https://heycam.github.io/webidl/#es-sequence
function createSequenceConverter(converter) {
return function (V, opts = {}) {
if (typeof V !== "object") {
throw makeException(
TypeError,
"can not be converted to sequence.",
opts,
);
}
const iter = V?.[Symbol.iterator]?.();
if (iter === undefined) {
throw makeException(
TypeError,
"can not be converted to sequence.",
opts,
);
}
const array = [];
while (true) {
const res = iter?.next?.();
if (res === undefined) {
throw makeException(
TypeError,
"can not be converted to sequence.",
opts,
);
}
if (res.done === true) break;
const val = converter(res.value, {
...opts,
context: `${opts.context}, index ${array.length}`,
});
array.push(val);
}
return array;
};
}
function createRecordConverter(keyConverter, valueConverter) {
return (V, opts) => {
if (typeof V !== "object") {
throw makeException(
TypeError,
"can not be converted to dictionary.",
opts,
);
}
const keys = Reflect.ownKeys(V);
const result = {};
for (const key of keys) {
const desc = Object.getOwnPropertyDescriptor(V, key);
if (desc !== undefined && desc.enumerable === true) {
const typedKey = keyConverter(key, opts);
const value = V[key];
const typedValue = valueConverter(value, opts);
result[typedKey] = typedValue;
}
}
return result;
};
}
const brand = Symbol("[[webidl.brand]]");
function createInterfaceConverter(name, prototype) {
return (V, opts) => {
if (!(V instanceof prototype) || V[brand] !== brand) {
throw makeException(TypeError, `is not of type ${name}.`, opts);
}
return V;
};
}
function createBranded(Type) {
const t = Object.create(Type.prototype);
t[brand] = brand;
return t;
}
function assertBranded(self, prototype) {
if (!(self instanceof prototype) || self[brand] !== brand) {
throw new TypeError("Illegal invocation");
}
}
function illegalConstructor() {
throw new TypeError("Illegal constructor");
}
function define(target, source) {
for (const key of Reflect.ownKeys(source)) {
const descriptor = Reflect.getOwnPropertyDescriptor(source, key);
if (descriptor && !Reflect.defineProperty(target, key, descriptor)) {
throw new TypeError(`Cannot redefine property: ${String(key)}`);
}
}
}
const _iteratorInternal = Symbol("iterator internal");
const globalIteratorPrototype = Object.getPrototypeOf(Object.getPrototypeOf(
[][Symbol.iterator](),
));
function mixinPairIterable(name, prototype, dataSymbol, keyKey, valueKey) {
const iteratorPrototype = Object.create(globalIteratorPrototype, {
[Symbol.toStringTag]: { configurable: true, value: `${name} Iterator` },
});
define(iteratorPrototype, {
next() {
const internal = this && this[_iteratorInternal];
if (!internal) {
throw new TypeError(
`next() called on a value that is not a ${name} iterator object`,
);
}
const { target, kind, index } = internal;
const values = target[dataSymbol];
const len = values.length;
if (index >= len) {
return { value: undefined, done: true };
}
const pair = values[index];
internal.index = index + 1;
let result;
switch (kind) {
case "key":
result = pair[keyKey];
break;
case "value":
result = pair[valueKey];
break;
case "key+value":
result = [pair[keyKey], pair[valueKey]];
break;
}
return { value: result, done: false };
},
});
function createDefaultIterator(target, kind) {
const iterator = Object.create(iteratorPrototype);
Object.defineProperty(iterator, _iteratorInternal, {
value: { target, kind, index: 0 },
configurable: true,
});
return iterator;
}
const methods = {
entries() {
assertBranded(this, prototype);
return createDefaultIterator(this, "key+value");
},
[Symbol.iterator]() {
assertBranded(this, prototype);
return createDefaultIterator(this, "key+value");
},
keys() {
assertBranded(this, prototype);
return createDefaultIterator(this, "key");
},
values() {
assertBranded(this, prototype);
return createDefaultIterator(this, "value");
},
forEach(idlCallback, thisArg) {
assertBranded(this, prototype);
const prefix = `Failed to execute 'forEach' on '${name}'`;
requiredArguments(arguments.length, 1, { prefix });
idlCallback = converters["Function"](idlCallback, {
prefix,
context: "Argument 1",
});
idlCallback = idlCallback.bind(thisArg ?? globalThis);
const pairs = this[dataSymbol];
for (let i = 0; i < pairs.length; i++) {
const entry = pairs[i];
idlCallback(entry[valueKey], entry[keyKey], this);
}
},
};
return Object.assign(prototype.prototype, methods);
}
window.__bootstrap ??= {};
window.__bootstrap.webidl = {
makeException,
converters,
requiredArguments,
createDictionaryConverter,
createEnumConverter,
createNullableConverter,
createSequenceConverter,
createRecordConverter,
createInterfaceConverter,
brand,
createBranded,
assertBranded,
illegalConstructor,
mixinPairIterable,
};
})(this);