// Currently in sync with Node.js lib/internal/util/comparisons.js
// https://github.com/nodejs/node/commit/112cc7c27551254aa2b17098fb774867f05ed0d9
'use strict';
function _slicedToArray(arr, i) { return _arrayWithHoles(arr) || _iterableToArrayLimit(arr, i) || _unsupportedIterableToArray(arr, i) || _nonIterableRest(); }
function _nonIterableRest() { throw new TypeError("Invalid attempt to destructure non-iterable instance.\nIn order to be iterable, non-array objects must have a [Symbol.iterator]() method."); }
function _unsupportedIterableToArray(o, minLen) { if (!o) return; if (typeof o === "string") return _arrayLikeToArray(o, minLen); var n = Object.prototype.toString.call(o).slice(8, -1); if (n === "Object" && o.constructor) n = o.constructor.name; if (n === "Map" || n === "Set") return Array.from(o); if (n === "Arguments" || /^(?:Ui|I)nt(?:8|16|32)(?:Clamped)?Array$/.test(n)) return _arrayLikeToArray(o, minLen); }
function _arrayLikeToArray(arr, len) { if (len == null || len > arr.length) len = arr.length; for (var i = 0, arr2 = new Array(len); i < len; i++) { arr2[i] = arr[i]; } return arr2; }
function _iterableToArrayLimit(arr, i) { var _i = arr == null ? null : typeof Symbol !== "undefined" && arr[Symbol.iterator] || arr["@@iterator"]; if (_i == null) return; var _arr = []; var _n = true; var _d = false; var _s, _e; try { for (_i = _i.call(arr); !(_n = (_s = _i.next()).done); _n = true) { _arr.push(_s.value); if (i && _arr.length === i) break; } } catch (err) { _d = true; _e = err; } finally { try { if (!_n && _i["return"] != null) _i["return"](); } finally { if (_d) throw _e; } } return _arr; }
function _arrayWithHoles(arr) { if (Array.isArray(arr)) return arr; }
function _typeof(obj) { "@babel/helpers - typeof"; return _typeof = "function" == typeof Symbol && "symbol" == typeof Symbol.iterator ? function (obj) { return typeof obj; } : function (obj) { return obj && "function" == typeof Symbol && obj.constructor === Symbol && obj !== Symbol.prototype ? "symbol" : typeof obj; }, _typeof(obj); }
var regexFlagsSupported = /a/g.flags !== undefined;
var arrayFromSet = function arrayFromSet(set) {
var array = [];
set.forEach(function (value) {
return array.push(value);
});
return array;
};
var arrayFromMap = function arrayFromMap(map) {
var array = [];
map.forEach(function (value, key) {
return array.push([key, value]);
});
return array;
};
var objectIs = Object.is ? Object.is : require('object-is');
var objectGetOwnPropertySymbols = Object.getOwnPropertySymbols ? Object.getOwnPropertySymbols : function () {
return [];
};
var numberIsNaN = Number.isNaN ? Number.isNaN : require('is-nan');
function uncurryThis(f) {
return f.call.bind(f);
}
var hasOwnProperty = uncurryThis(Object.prototype.hasOwnProperty);
var propertyIsEnumerable = uncurryThis(Object.prototype.propertyIsEnumerable);
var objectToString = uncurryThis(Object.prototype.toString);
var _require$types = require('util/').types,
isAnyArrayBuffer = _require$types.isAnyArrayBuffer,
isArrayBufferView = _require$types.isArrayBufferView,
isDate = _require$types.isDate,
isMap = _require$types.isMap,
isRegExp = _require$types.isRegExp,
isSet = _require$types.isSet,
isNativeError = _require$types.isNativeError,
isBoxedPrimitive = _require$types.isBoxedPrimitive,
isNumberObject = _require$types.isNumberObject,
isStringObject = _require$types.isStringObject,
isBooleanObject = _require$types.isBooleanObject,
isBigIntObject = _require$types.isBigIntObject,
isSymbolObject = _require$types.isSymbolObject,
isFloat32Array = _require$types.isFloat32Array,
isFloat64Array = _require$types.isFloat64Array;
function isNonIndex(key) {
if (key.length === 0 || key.length > 10) return true;
for (var i = 0; i < key.length; i++) {
var code = key.charCodeAt(i);
if (code < 48 || code > 57) return true;
} // The maximum size for an array is 2 ** 32 -1.
return key.length === 10 && key >= Math.pow(2, 32);
}
function getOwnNonIndexProperties(value) {
return Object.keys(value).filter(isNonIndex).concat(objectGetOwnPropertySymbols(value).filter(Object.prototype.propertyIsEnumerable.bind(value)));
} // Taken from https://github.com/feross/buffer/blob/680e9e5e488f22aac27599a57dc844a6315928dd/index.js
// original notice:
/*!
* The buffer module from node.js, for the browser.
*
* @author Feross Aboukhadijeh <feross@feross.org> <http://feross.org>
* @license MIT
*/
function compare(a, b) {
if (a === b) {
return 0;
}
var x = a.length;
var y = b.length;
for (var i = 0, len = Math.min(x, y); i < len; ++i) {
if (a[i] !== b[i]) {
x = a[i];
y = b[i];
break;
}
}
if (x < y) {
return -1;
}
if (y < x) {
return 1;
}
return 0;
}
var ONLY_ENUMERABLE = undefined;
var kStrict = true;
var kLoose = false;
var kNoIterator = 0;
var kIsArray = 1;
var kIsSet = 2;
var kIsMap = 3; // Check if they have the same source and flags
function areSimilarRegExps(a, b) {
return regexFlagsSupported ? a.source === b.source && a.flags === b.flags : RegExp.prototype.toString.call(a) === RegExp.prototype.toString.call(b);
}
function areSimilarFloatArrays(a, b) {
if (a.byteLength !== b.byteLength) {
return false;
}
for (var offset = 0; offset < a.byteLength; offset++) {
if (a[offset] !== b[offset]) {
return false;
}
}
return true;
}
function areSimilarTypedArrays(a, b) {
if (a.byteLength !== b.byteLength) {
return false;
}
return compare(new Uint8Array(a.buffer, a.byteOffset, a.byteLength), new Uint8Array(b.buffer, b.byteOffset, b.byteLength)) === 0;
}
function areEqualArrayBuffers(buf1, buf2) {
return buf1.byteLength === buf2.byteLength && compare(new Uint8Array(buf1), new Uint8Array(buf2)) === 0;
}
function isEqualBoxedPrimitive(val1, val2) {
if (isNumberObject(val1)) {
return isNumberObject(val2) && objectIs(Number.prototype.valueOf.call(val1), Number.prototype.valueOf.call(val2));
}
if (isStringObject(val1)) {
return isStringObject(val2) && String.prototype.valueOf.call(val1) === String.prototype.valueOf.call(val2);
}
if (isBooleanObject(val1)) {
return isBooleanObject(val2) && Boolean.prototype.valueOf.call(val1) === Boolean.prototype.valueOf.call(val2);
}
if (isBigIntObject(val1)) {
return isBigIntObject(val2) && BigInt.prototype.valueOf.call(val1) === BigInt.prototype.valueOf.call(val2);
}
return isSymbolObject(val2) && Symbol.prototype.valueOf.call(val1) === Symbol.prototype.valueOf.call(val2);
} // Notes: Type tags are historical [[Class]] properties that can be set by
// FunctionTemplate::SetClassName() in C++ or Symbol.toStringTag in JS
// and retrieved using Object.prototype.toString.call(obj) in JS
// See https://tc39.github.io/ecma262/#sec-object.prototype.tostring
// for a list of tags pre-defined in the spec.
// There are some unspecified tags in the wild too (e.g. typed array tags).
// Since tags can be altered, they only serve fast failures
//
// Typed arrays and buffers are checked by comparing the content in their
// underlying ArrayBuffer. This optimization requires that it's
// reasonable to interpret their underlying memory in the same way,
// which is checked by comparing their type tags.
// (e.g. a Uint8Array and a Uint16Array with the same memory content
// could still be different because they will be interpreted differently).
//
// For strict comparison, objects should have
// a) The same built-in type tags
// b) The same prototypes.
function innerDeepEqual(val1, val2, strict, memos) {
// All identical values are equivalent, as determined by ===.
if (val1 === val2) {
if (val1 !== 0) return true;
return strict ? objectIs(val1, val2) : true;
} // Check more closely if val1 and val2 are equal.
if (strict) {
if (_typeof(val1) !== 'object') {
return typeof val1 === 'number' && numberIsNaN(val1) && numberIsNaN(val2);
}
if (_typeof(val2) !== 'object' || val1 === null || val2 === null) {
return false;
}
if (Object.getPrototypeOf(val1) !== Object.getPrototypeOf(val2)) {
return false;
}
} else {
if (val1 === null || _typeof(val1) !== 'object') {
if (val2 === null || _typeof(val2) !== 'object') {
// eslint-disable-next-line eqeqeq
return val1 == val2;
}
return false;
}
if (val2 === null || _typeof(val2) !== 'object') {
return false;
}
}
var val1Tag = objectToString(val1);
var val2Tag = objectToString(val2);
if (val1Tag !== val2Tag) {
return false;
}
if (Array.isArray(val1)) {
// Check for sparse arrays and general fast path
if (val1.length !== val2.length) {
return false;
}
var keys1 = getOwnNonIndexProperties(val1, ONLY_ENUMERABLE);
var keys2 = getOwnNonIndexProperties(val2, ONLY_ENUMERABLE);
if (keys1.length !== keys2.length) {
return false;
}
return keyCheck(val1, val2, strict, memos, kIsArray, keys1);
} // [browserify] This triggers on certain types in IE (Map/Set) so we don't
// wan't to early return out of the rest of the checks. However we can check
// if the second value is one of these values and the first isn't.
if (val1Tag === '[object Object]') {
// return keyCheck(val1, val2, strict, memos, kNoIterator);
if (!isMap(val1) && isMap(val2) || !isSet(val1) && isSet(val2)) {
return false;
}
}
if (isDate(val1)) {
if (!isDate(val2) || Date.prototype.getTime.call(val1) !== Date.prototype.getTime.call(val2)) {
return false;
}
} else if (isRegExp(val1)) {
if (!isRegExp(val2) || !areSimilarRegExps(val1, val2)) {
return false;
}
} else if (isNativeError(val1) || val1 instanceof Error) {
// Do not compare the stack as it might differ even though the error itself
// is otherwise identical.
if (val1.message !== val2.message || val1.name !== val2.name) {
return false;
}
} else if (isArrayBufferView(val1)) {
if (!strict && (isFloat32Array(val1) || isFloat64Array(val1))) {
if (!areSimilarFloatArrays(val1, val2)) {
return false;
}
} else if (!areSimilarTypedArrays(val1, val2)) {
return false;
} // Buffer.compare returns true, so val1.length === val2.length. If they both
// only contain numeric keys, we don't need to exam further than checking
// the symbols.
var _keys = getOwnNonIndexProperties(val1, ONLY_ENUMERABLE);
var _keys2 = getOwnNonIndexProperties(val2, ONLY_ENUMERABLE);
if (_keys.length !== _keys2.length) {
return false;
}
return keyCheck(val1, val2, strict, memos, kNoIterator, _keys);
} else if (isSet(val1)) {
if (!isSet(val2) || val1.size !== val2.size) {
return false;
}
return keyCheck(val1, val2, strict, memos, kIsSet);
} else if (isMap(val1)) {
if (!isMap(val2) || val1.size !== val2.size) {
return false;
}
return keyCheck(val1, val2, strict, memos, kIsMap);
} else if (isAnyArrayBuffer(val1)) {
if (!areEqualArrayBuffers(val1, val2)) {
return false;
}
} else if (isBoxedPrimitive(val1) && !isEqualBoxedPrimitive(val1, val2)) {
return false;
}
return keyCheck(val1, val2, strict, memos, kNoIterator);
}
function getEnumerables(val, keys) {
return keys.filter(function (k) {
return propertyIsEnumerable(val, k);
});
}
function keyCheck(val1, val2, strict, memos, iterationType, aKeys) {
// For all remaining Object pairs, including Array, objects and Maps,
// equivalence is determined by having:
// a) The same number of owned enumerable properties
// b) The same set of keys/indexes (although not necessarily the same order)
// c) Equivalent values for every corresponding key/index
// d) For Sets and Maps, equal contents
// Note: this accounts for both named and indexed properties on Arrays.
if (arguments.length === 5) {
aKeys = Object.keys(val1);
var bKeys = Object.keys(val2); // The pair must have the same number of owned properties.
if (aKeys.length !== bKeys.length) {
return false;
}
} // Cheap key test
var i = 0;
for (; i < aKeys.length; i++) {
if (!hasOwnProperty(val2, aKeys[i])) {
return false;
}
}
if (strict && arguments.length === 5) {
var symbolKeysA = objectGetOwnPropertySymbols(val1);
if (symbolKeysA.length !== 0) {
var count = 0;
for (i = 0; i < symbolKeysA.length; i++) {
var key = symbolKeysA[i];
if (propertyIsEnumerable(val1, key)) {
if (!propertyIsEnumerable(val2, key)) {
return false;
}
aKeys.push(key);
count++;
} else if (propertyIsEnumerable(val2, key)) {
return false;
}
}
var symbolKeysB = objectGetOwnPropertySymbols(val2);
if (symbolKeysA.length !== symbolKeysB.length && getEnumerables(val2, symbolKeysB).length !== count) {
return false;
}
} else {
var _symbolKeysB = objectGetOwnPropertySymbols(val2);
if (_symbolKeysB.length !== 0 && getEnumerables(val2, _symbolKeysB).length !== 0) {
return false;
}
}
}
if (aKeys.length === 0 && (iterationType === kNoIterator || iterationType === kIsArray && val1.length === 0 || val1.size === 0)) {
return true;
} // Use memos to handle cycles.
if (memos === undefined) {
memos = {
val1: new Map(),
val2: new Map(),
position: 0
};
} else {
// We prevent up to two map.has(x) calls by directly retrieving the value
// and checking for undefined. The map can only contain numbers, so it is
// safe to check for undefined only.
var val2MemoA = memos.val1.get(val1);
if (val2MemoA !== undefined) {
var val2MemoB = memos.val2.get(val2);
if (val2MemoB !== undefined) {
return val2MemoA === val2MemoB;
}
}
memos.position++;
}
memos.val1.set(val1, memos.position);
memos.val2.set(val2, memos.position);
var areEq = objEquiv(val1, val2, strict, aKeys, memos, iterationType);
memos.val1.delete(val1);
memos.val2.delete(val2);
return areEq;
}
function setHasEqualElement(set, val1, strict, memo) {
// Go looking.
var setValues = arrayFromSet(set);
for (var i = 0; i < setValues.length; i++) {
var val2 = setValues[i];
if (innerDeepEqual(val1, val2, strict, memo)) {
// Remove the matching element to make sure we do not check that again.
set.delete(val2);
return true;
}
}
return false;
} // See https://developer.mozilla.org/en-US/docs/Web/JavaScript/Equality_comparisons_and_sameness#Loose_equality_using
// Sadly it is not possible to detect corresponding values properly in case the
// type is a string, number, bigint or boolean. The reason is that those values
// can match lots of different string values (e.g., 1n == '+00001').
function findLooseMatchingPrimitives(prim) {
switch (_typeof(prim)) {
case 'undefined':
return null;
case 'object':
// Only pass in null as object!
return undefined;
case 'symbol':
return false;
case 'string':
prim = +prim;
// Loose equal entries exist only if the string is possible to convert to
// a regular number and not NaN.
// Fall through
case 'number':
if (numberIsNaN(prim)) {
return false;
}
}
return true;
}
function setMightHaveLoosePrim(a, b, prim) {
var altValue = findLooseMatchingPrimitives(prim);
if (altValue != null) return altValue;
return b.has(altValue) && !a.has(altValue);
}
function mapMightHaveLoosePrim(a, b, prim, item, memo) {
var altValue = findLooseMatchingPrimitives(prim);
if (altValue != null) {
return altValue;
}
var curB = b.get(altValue);
if (curB === undefined && !b.has(altValue) || !innerDeepEqual(item, curB, false, memo)) {
return false;
}
return !a.has(altValue) && innerDeepEqual(item, curB, false, memo);
}
function setEquiv(a, b, strict, memo) {
// This is a lazily initiated Set of entries which have to be compared
// pairwise.
var set = null;
var aValues = arrayFromSet(a);
for (var i = 0; i < aValues.length; i++) {
var val = aValues[i]; // Note: Checking for the objects first improves the performance for object
// heavy sets but it is a minor slow down for primitives. As they are fast
// to check this improves the worst case scenario instead.
if (_typeof(val) === 'object' && val !== null) {
if (set === null) {
set = new Set();
} // If the specified value doesn't exist in the second set its an not null
// object (or non strict only: a not matching primitive) we'll need to go
// hunting for something thats deep-(strict-)equal to it. To make this
// O(n log n) complexity we have to copy these values in a new set first.
set.add(val);
} else if (!b.has(val)) {
if (strict) return false; // Fast path to detect missing string, symbol, undefined and null values.
if (!setMightHaveLoosePrim(a, b, val)) {
return false;
}
if (set === null) {
set = new Set();
}
set.add(val);
}
}
if (set !== null) {
var bValues = arrayFromSet(b);
for (var _i = 0; _i < bValues.length; _i++) {
var _val = bValues[_i]; // We have to check if a primitive value is already
// matching and only if it's not, go hunting for it.
if (_typeof(_val) === 'object' && _val !== null) {
if (!setHasEqualElement(set, _val, strict, memo)) return false;
} else if (!strict && !a.has(_val) && !setHasEqualElement(set, _val, strict, memo)) {
return false;
}
}
return set.size === 0;
}
return true;
}
function mapHasEqualEntry(set, map, key1, item1, strict, memo) {
// To be able to handle cases like:
// Map([[{}, 'a'], [{}, 'b']]) vs Map([[{}, 'b'], [{}, 'a']])
// ... we need to consider *all* matching keys, not just the first we find.
var setValues = arrayFromSet(set);
for (var i = 0; i < setValues.length; i++) {
var key2 = setValues[i];
if (innerDeepEqual(key1, key2, strict, memo) && innerDeepEqual(item1, map.get(key2), strict, memo)) {
set.delete(key2);
return true;
}
}
return false;
}
function mapEquiv(a, b, strict, memo) {
var set = null;
var aEntries = arrayFromMap(a);
for (var i = 0; i < aEntries.length; i++) {
var _aEntries$i = _slicedToArray(aEntries[i], 2),
key = _aEntries$i[0],
item1 = _aEntries$i[1];
if (_typeof(key) === 'object' && key !== null) {
if (set === null) {
set = new Set();
}
set.add(key);
} else {
// By directly retrieving the value we prevent another b.has(key) check in
// almost all possible cases.
var item2 = b.get(key);
if (item2 === undefined && !b.has(key) || !innerDeepEqual(item1, item2, strict, memo)) {
if (strict) return false; // Fast path to detect missing string, symbol, undefined and null
// keys.
if (!mapMightHaveLoosePrim(a, b, key, item1, memo)) return false;
if (set === null) {
set = new Set();
}
set.add(key);
}
}
}
if (set !== null) {
var bEntries = arrayFromMap(b);
for (var _i2 = 0; _i2 < bEntries.length; _i2++) {
var _bEntries$_i = _slicedToArray(bEntries[_i2], 2),
_key = _bEntries$_i[0],
item = _bEntries$_i[1];
if (_typeof(_key) === 'object' && _key !== null) {
if (!mapHasEqualEntry(set, a, _key, item, strict, memo)) return false;
} else if (!strict && (!a.has(_key) || !innerDeepEqual(a.get(_key), item, false, memo)) && !mapHasEqualEntry(set, a, _key, item, false, memo)) {
return false;
}
}
return set.size === 0;
}
return true;
}
function objEquiv(a, b, strict, keys, memos, iterationType) {
// Sets and maps don't have their entries accessible via normal object
// properties.
var i = 0;
if (iterationType === kIsSet) {
if (!setEquiv(a, b, strict, memos)) {
return false;
}
} else if (iterationType === kIsMap) {
if (!mapEquiv(a, b, strict, memos)) {
return false;
}
} else if (iterationType === kIsArray) {
for (; i < a.length; i++) {
if (hasOwnProperty(a, i)) {
if (!hasOwnProperty(b, i) || !innerDeepEqual(a[i], b[i], strict, memos)) {
return false;
}
} else if (hasOwnProperty(b, i)) {
return false;
} else {
// Array is sparse.
var keysA = Object.keys(a);
for (; i < keysA.length; i++) {
var key = keysA[i];
if (!hasOwnProperty(b, key) || !innerDeepEqual(a[key], b[key], strict, memos)) {
return false;
}
}
if (keysA.length !== Object.keys(b).length) {
return false;
}
return true;
}
}
} // The pair must have equivalent values for every corresponding key.
// Possibly expensive deep test:
for (i = 0; i < keys.length; i++) {
var _key2 = keys[i];
if (!innerDeepEqual(a[_key2], b[_key2], strict, memos)) {
return false;
}
}
return true;
}
function isDeepEqual(val1, val2) {
return innerDeepEqual(val1, val2, kLoose);
}
function isDeepStrictEqual(val1, val2) {
return innerDeepEqual(val1, val2, kStrict);
}
module.exports = {
isDeepEqual: isDeepEqual,
isDeepStrictEqual: isDeepStrictEqual
}; |