251 lines
7.8 KiB
JavaScript
251 lines
7.8 KiB
JavaScript
// angular-uuid created by Ivan Hayes @munkychop
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// MIT License - http://opensource.org/licenses/mit-license.php
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// --------------------------------------------------------------
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// This is an AngularJS wrapper for the original node-uuid library
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// written by Robert Kieffer – https://github.com/broofa/node-uuid
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// MIT License - http://opensource.org/licenses/mit-license.php
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// The wrapped node-uuid library is at version 1.4.7
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function AngularUUID () {
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'use strict';
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angular.module('angular-uuid',[]).factory('uuid', ['$window', nodeUUID]);
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function nodeUUID ($window) {
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// Unique ID creation requires a high quality random # generator. We feature
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// detect to determine the best RNG source, normalizing to a function that
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// returns 128-bits of randomness, since that's what's usually required
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var _rng, _mathRNG, _whatwgRNG;
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// Allow for MSIE11 msCrypto
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var _crypto = $window.crypto || $window.msCrypto;
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if (!_rng && _crypto && _crypto.getRandomValues) {
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// WHATWG crypto-based RNG - http://wiki.whatwg.org/wiki/Crypto
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//
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// Moderately fast, high quality
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try {
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var _rnds8 = new Uint8Array(16);
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_whatwgRNG = _rng = function whatwgRNG() {
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_crypto.getRandomValues(_rnds8);
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return _rnds8;
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};
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_rng();
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} catch(e) {}
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}
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if (!_rng) {
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// Math.random()-based (RNG)
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//
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// If all else fails, use Math.random(). It's fast, but is of unspecified
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// quality.
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var _rnds = new Array(16);
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_mathRNG = _rng = function() {
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for (var i = 0, r; i < 16; i++) {
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if ((i & 0x03) === 0) { r = Math.random() * 0x100000000; }
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_rnds[i] = r >>> ((i & 0x03) << 3) & 0xff;
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}
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return _rnds;
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};
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if ('undefined' !== typeof console && console.warn) {
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console.warn('[SECURITY] node-uuid: crypto not usable, falling back to insecure Math.random()');
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}
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}
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// Buffer class to use
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var BufferClass = ('function' === typeof Buffer) ? Buffer : Array;
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// Maps for number <-> hex string conversion
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var _byteToHex = [];
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var _hexToByte = {};
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for (var i = 0; i < 256; i++) {
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_byteToHex[i] = (i + 0x100).toString(16).substr(1);
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_hexToByte[_byteToHex[i]] = i;
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}
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// **`parse()` - Parse a UUID into it's component bytes**
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function parse(s, buf, offset) {
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var i = (buf && offset) || 0, ii = 0;
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buf = buf || [];
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s.toLowerCase().replace(/[0-9a-f]{2}/g, function(oct) {
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if (ii < 16) { // Don't overflow!
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buf[i + ii++] = _hexToByte[oct];
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}
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});
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// Zero out remaining bytes if string was short
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while (ii < 16) {
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buf[i + ii++] = 0;
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}
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return buf;
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}
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// **`unparse()` - Convert UUID byte array (ala parse()) into a string**
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function unparse(buf, offset) {
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var i = offset || 0, bth = _byteToHex;
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return bth[buf[i++]] + bth[buf[i++]] +
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bth[buf[i++]] + bth[buf[i++]] + '-' +
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bth[buf[i++]] + bth[buf[i++]] + '-' +
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bth[buf[i++]] + bth[buf[i++]] + '-' +
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bth[buf[i++]] + bth[buf[i++]] + '-' +
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bth[buf[i++]] + bth[buf[i++]] +
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bth[buf[i++]] + bth[buf[i++]] +
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bth[buf[i++]] + bth[buf[i++]];
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}
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// **`v1()` - Generate time-based UUID**
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//
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// Inspired by https://github.com/LiosK/UUID.js
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// and http://docs.python.org/library/uuid.html
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// random #'s we need to init node and clockseq
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var _seedBytes = _rng();
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// Per 4.5, create and 48-bit node id, (47 random bits + multicast bit = 1)
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var _nodeId = [
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_seedBytes[0] | 0x01,
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_seedBytes[1], _seedBytes[2], _seedBytes[3], _seedBytes[4], _seedBytes[5]
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];
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// Per 4.2.2, randomize (14 bit) clockseq
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var _clockseq = (_seedBytes[6] << 8 | _seedBytes[7]) & 0x3fff;
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// Previous uuid creation time
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var _lastMSecs = 0, _lastNSecs = 0;
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// See https://github.com/broofa/node-uuid for API details
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function v1(options, buf, offset) {
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var i = buf && offset || 0;
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var b = buf || [];
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options = options || {};
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var clockseq = (options.clockseq != null) ? options.clockseq : _clockseq;
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// UUID timestamps are 100 nano-second units since the Gregorian epoch,
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// (1582-10-15 00:00). JSNumbers aren't precise enough for this, so
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// time is handled internally as 'msecs' (integer milliseconds) and 'nsecs'
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// (100-nanoseconds offset from msecs) since unix epoch, 1970-01-01 00:00.
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var msecs = (options.msecs != null) ? options.msecs : new Date().getTime();
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// Per 4.2.1.2, use count of uuid's generated during the current clock
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// cycle to simulate higher resolution clock
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var nsecs = (options.nsecs != null) ? options.nsecs : _lastNSecs + 1;
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// Time since last uuid creation (in msecs)
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var dt = (msecs - _lastMSecs) + (nsecs - _lastNSecs)/10000;
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// Per 4.2.1.2, Bump clockseq on clock regression
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if (dt < 0 && options.clockseq == null) {
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clockseq = clockseq + 1 & 0x3fff;
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}
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// Reset nsecs if clock regresses (new clockseq) or we've moved onto a new
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// time interval
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if ((dt < 0 || msecs > _lastMSecs) && options.nsecs == null) {
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nsecs = 0;
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}
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// Per 4.2.1.2 Throw error if too many uuids are requested
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if (nsecs >= 10000) {
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throw new Error('uuid.v1(): Can\'t create more than 10M uuids/sec');
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}
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_lastMSecs = msecs;
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_lastNSecs = nsecs;
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_clockseq = clockseq;
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// Per 4.1.4 - Convert from unix epoch to Gregorian epoch
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msecs += 12219292800000;
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// `time_low`
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var tl = ((msecs & 0xfffffff) * 10000 + nsecs) % 0x100000000;
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b[i++] = tl >>> 24 & 0xff;
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b[i++] = tl >>> 16 & 0xff;
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b[i++] = tl >>> 8 & 0xff;
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b[i++] = tl & 0xff;
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// `time_mid`
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var tmh = (msecs / 0x100000000 * 10000) & 0xfffffff;
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b[i++] = tmh >>> 8 & 0xff;
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b[i++] = tmh & 0xff;
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// `time_high_and_version`
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b[i++] = tmh >>> 24 & 0xf | 0x10; // include version
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b[i++] = tmh >>> 16 & 0xff;
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// `clock_seq_hi_and_reserved` (Per 4.2.2 - include variant)
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b[i++] = clockseq >>> 8 | 0x80;
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// `clock_seq_low`
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b[i++] = clockseq & 0xff;
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// `node`
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var node = options.node || _nodeId;
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for (var n = 0; n < 6; n++) {
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b[i + n] = node[n];
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}
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return buf ? buf : unparse(b);
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}
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// **`v4()` - Generate random UUID**
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// See https://github.com/broofa/node-uuid for API details
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function v4(options, buf, offset) {
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// Deprecated - 'format' argument, as supported in v1.2
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var i = buf && offset || 0;
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if (typeof(options) === 'string') {
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buf = (options === 'binary') ? new BufferClass(16) : null;
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options = null;
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}
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options = options || {};
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var rnds = options.random || (options.rng || _rng)();
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// Per 4.4, set bits for version and `clock_seq_hi_and_reserved`
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rnds[6] = (rnds[6] & 0x0f) | 0x40;
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rnds[8] = (rnds[8] & 0x3f) | 0x80;
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// Copy bytes to buffer, if provided
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if (buf) {
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for (var ii = 0; ii < 16; ii++) {
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buf[i + ii] = rnds[ii];
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}
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}
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return buf || unparse(rnds);
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}
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// Export public API
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var uuid = v4;
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uuid.v1 = v1;
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uuid.v4 = v4;
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uuid.parse = parse;
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uuid.unparse = unparse;
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uuid.BufferClass = BufferClass;
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uuid._rng = _rng;
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uuid._mathRNG = _mathRNG;
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uuid._whatwgRNG = _whatwgRNG;
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return uuid;
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}
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}
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// check for Module/AMD support, otherwise call the uuid function to setup the angular module.
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if (typeof module !== 'undefined' && module.exports) {
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module.exports = new AngularUUID();
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} else if (typeof define !== 'undefined' && define.amd) {
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// AMD. Register as an anonymous module.
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define (function() {
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return new AngularUUID();
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});
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} else {
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AngularUUID();
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} |