/** * videojs-contrib-hls * @version 2.0.1 * @copyright 2016 Brightcove, Inc * @license Apache-2.0 */ (function(f){if(typeof exports==="object"&&typeof module!=="undefined"){module.exports=f()}else if(typeof define==="function"&&define.amd){define([],f)}else{var g;if(typeof window!=="undefined"){g=window}else if(typeof global!=="undefined"){g=global}else if(typeof self!=="undefined"){g=self}else{g=this}g.videojsContribHls = f()}})(function(){var define,module,exports;return (function e(t,n,r){function s(o,u){if(!n[o]){if(!t[o]){var a=typeof require=="function"&&require;if(!u&&a)return a(o,!0);if(i)return i(o,!0);var f=new Error("Cannot find module '"+o+"'");throw f.code="MODULE_NOT_FOUND",f}var l=n[o]={exports:{}};t[o][0].call(l.exports,function(e){var n=t[o][1][e];return s(n?n:e)},l,l.exports,e,t,n,r)}return n[o].exports}var i=typeof require=="function"&&require;for(var o=0;o= 0x20 && e < 0x7e) { return String.fromCharCode(e); } return '.'; }; var utils = { hexDump: function hexDump(data) { var bytes = Array.prototype.slice.call(data); var step = 16; var result = ''; var hex = undefined; var ascii = undefined; for (var j = 0; j < bytes.length / step; j++) { hex = bytes.slice(j * step, j * step + step).map(formatHexString).join(''); ascii = bytes.slice(j * step, j * step + step).map(formatAsciiString).join(''); result += hex + ' ' + ascii + '\n'; } return result; }, tagDump: function tagDump(tag) { return utils.hexDump(tag.bytes); }, textRanges: function textRanges(ranges) { var result = ''; var i = undefined; for (i = 0; i < ranges.length; i++) { result += textRange(ranges, i) + ' '; } return result; } }; exports['default'] = utils; module.exports = exports['default']; },{}],2:[function(require,module,exports){ /* * aes.js * * This file contains an adaptation of the AES decryption algorithm * from the Standford Javascript Cryptography Library. That work is * covered by the following copyright and permissions notice: * * Copyright 2009-2010 Emily Stark, Mike Hamburg, Dan Boneh. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials provided * with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation * are those of the authors and should not be interpreted as representing * official policies, either expressed or implied, of the authors. */ /** * Expand the S-box tables. * * @private */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } var precompute = function precompute() { var tables = [[[], [], [], [], []], [[], [], [], [], []]]; var encTable = tables[0]; var decTable = tables[1]; var sbox = encTable[4]; var sboxInv = decTable[4]; var i = undefined; var x = undefined; var xInv = undefined; var d = []; var th = []; var x2 = undefined; var x4 = undefined; var x8 = undefined; var s = undefined; var tEnc = undefined; var tDec = undefined; // Compute double and third tables for (i = 0; i < 256; i++) { th[(d[i] = i << 1 ^ (i >> 7) * 283) ^ i] = i; } for (x = xInv = 0; !sbox[x]; x ^= x2 || 1, xInv = th[xInv] || 1) { // Compute sbox s = xInv ^ xInv << 1 ^ xInv << 2 ^ xInv << 3 ^ xInv << 4; s = s >> 8 ^ s & 255 ^ 99; sbox[x] = s; sboxInv[s] = x; // Compute MixColumns x8 = d[x4 = d[x2 = d[x]]]; tDec = x8 * 0x1010101 ^ x4 * 0x10001 ^ x2 * 0x101 ^ x * 0x1010100; tEnc = d[s] * 0x101 ^ s * 0x1010100; for (i = 0; i < 4; i++) { encTable[i][x] = tEnc = tEnc << 24 ^ tEnc >>> 8; decTable[i][s] = tDec = tDec << 24 ^ tDec >>> 8; } } // Compactify. Considerable speedup on Firefox. for (i = 0; i < 5; i++) { encTable[i] = encTable[i].slice(0); decTable[i] = decTable[i].slice(0); } return tables; }; var aesTables = null; /** * Schedule out an AES key for both encryption and decryption. This * is a low-level class. Use a cipher mode to do bulk encryption. * * @constructor * @param key {Array} The key as an array of 4, 6 or 8 words. */ var AES = (function () { function AES(key) { _classCallCheck(this, AES); /** * The expanded S-box and inverse S-box tables. These will be computed * on the client so that we don't have to send them down the wire. * * There are two tables, _tables[0] is for encryption and * _tables[1] is for decryption. * * The first 4 sub-tables are the expanded S-box with MixColumns. The * last (_tables[01][4]) is the S-box itself. * * @private */ // if we have yet to precompute the S-box tables // do so now if (!aesTables) { aesTables = precompute(); } // then make a copy of that object for use this._tables = [[aesTables[0][0].slice(), aesTables[0][1].slice(), aesTables[0][2].slice(), aesTables[0][3].slice(), aesTables[0][4].slice()], [aesTables[1][0].slice(), aesTables[1][1].slice(), aesTables[1][2].slice(), aesTables[1][3].slice(), aesTables[1][4].slice()]]; var i = undefined; var j = undefined; var tmp = undefined; var encKey = undefined; var decKey = undefined; var sbox = this._tables[0][4]; var decTable = this._tables[1]; var keyLen = key.length; var rcon = 1; if (keyLen !== 4 && keyLen !== 6 && keyLen !== 8) { throw new Error('Invalid aes key size'); } encKey = key.slice(0); decKey = []; this._key = [encKey, decKey]; // schedule encryption keys for (i = keyLen; i < 4 * keyLen + 28; i++) { tmp = encKey[i - 1]; // apply sbox if (i % keyLen === 0 || keyLen === 8 && i % keyLen === 4) { tmp = sbox[tmp >>> 24] << 24 ^ sbox[tmp >> 16 & 255] << 16 ^ sbox[tmp >> 8 & 255] << 8 ^ sbox[tmp & 255]; // shift rows and add rcon if (i % keyLen === 0) { tmp = tmp << 8 ^ tmp >>> 24 ^ rcon << 24; rcon = rcon << 1 ^ (rcon >> 7) * 283; } } encKey[i] = encKey[i - keyLen] ^ tmp; } // schedule decryption keys for (j = 0; i; j++, i--) { tmp = encKey[j & 3 ? i : i - 4]; if (i <= 4 || j < 4) { decKey[j] = tmp; } else { decKey[j] = decTable[0][sbox[tmp >>> 24]] ^ decTable[1][sbox[tmp >> 16 & 255]] ^ decTable[2][sbox[tmp >> 8 & 255]] ^ decTable[3][sbox[tmp & 255]]; } } } /** * Decrypt 16 bytes, specified as four 32-bit words. * @param encrypted0 {number} the first word to decrypt * @param encrypted1 {number} the second word to decrypt * @param encrypted2 {number} the third word to decrypt * @param encrypted3 {number} the fourth word to decrypt * @param out {Int32Array} the array to write the decrypted words * into * @param offset {number} the offset into the output array to start * writing results * @return {Array} The plaintext. */ _createClass(AES, [{ key: 'decrypt', value: function decrypt(encrypted0, encrypted1, encrypted2, encrypted3, out, offset) { var key = this._key[1]; // state variables a,b,c,d are loaded with pre-whitened data var a = encrypted0 ^ key[0]; var b = encrypted3 ^ key[1]; var c = encrypted2 ^ key[2]; var d = encrypted1 ^ key[3]; var a2 = undefined; var b2 = undefined; var c2 = undefined; // key.length === 2 ? var nInnerRounds = key.length / 4 - 2; var i = undefined; var kIndex = 4; var table = this._tables[1]; // load up the tables var table0 = table[0]; var table1 = table[1]; var table2 = table[2]; var table3 = table[3]; var sbox = table[4]; // Inner rounds. Cribbed from OpenSSL. for (i = 0; i < nInnerRounds; i++) { a2 = table0[a >>> 24] ^ table1[b >> 16 & 255] ^ table2[c >> 8 & 255] ^ table3[d & 255] ^ key[kIndex]; b2 = table0[b >>> 24] ^ table1[c >> 16 & 255] ^ table2[d >> 8 & 255] ^ table3[a & 255] ^ key[kIndex + 1]; c2 = table0[c >>> 24] ^ table1[d >> 16 & 255] ^ table2[a >> 8 & 255] ^ table3[b & 255] ^ key[kIndex + 2]; d = table0[d >>> 24] ^ table1[a >> 16 & 255] ^ table2[b >> 8 & 255] ^ table3[c & 255] ^ key[kIndex + 3]; kIndex += 4; a = a2;b = b2;c = c2; } // Last round. for (i = 0; i < 4; i++) { out[(3 & -i) + offset] = sbox[a >>> 24] << 24 ^ sbox[b >> 16 & 255] << 16 ^ sbox[c >> 8 & 255] << 8 ^ sbox[d & 255] ^ key[kIndex++]; a2 = a;a = b;b = c;c = d;d = a2; } } }]); return AES; })(); exports['default'] = AES; module.exports = exports['default']; },{}],3:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _stream = require('../stream'); var _stream2 = _interopRequireDefault(_stream); /** * A wrapper around the Stream class to use setTiemout * and run stream "jobs" Asynchronously */ var AsyncStream = (function (_Stream) { _inherits(AsyncStream, _Stream); function AsyncStream() { _classCallCheck(this, AsyncStream); _get(Object.getPrototypeOf(AsyncStream.prototype), 'constructor', this).call(this, _stream2['default']); this.jobs = []; this.delay = 1; this.timeout_ = null; } _createClass(AsyncStream, [{ key: 'processJob_', value: function processJob_() { this.jobs.shift()(); if (this.jobs.length) { this.timeout_ = setTimeout(this.processJob_.bind(this), this.delay); } else { this.timeout_ = null; } } }, { key: 'push', value: function push(job) { this.jobs.push(job); if (!this.timeout_) { this.timeout_ = setTimeout(this.processJob_.bind(this), this.delay); } } }]); return AsyncStream; })(_stream2['default']); exports['default'] = AsyncStream; module.exports = exports['default']; },{"../stream":13}],4:[function(require,module,exports){ /* * decrypter.js * * An asynchronous implementation of AES-128 CBC decryption with * PKCS#7 padding. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } var _aes = require('./aes'); var _aes2 = _interopRequireDefault(_aes); var _asyncStream = require('./async-stream'); var _asyncStream2 = _interopRequireDefault(_asyncStream); var _pkcs7 = require('pkcs7'); /** * Convert network-order (big-endian) bytes into their little-endian * representation. */ var ntoh = function ntoh(word) { return word << 24 | (word & 0xff00) << 8 | (word & 0xff0000) >> 8 | word >>> 24; }; /* eslint-disable max-len */ /** * Decrypt bytes using AES-128 with CBC and PKCS#7 padding. * @param encrypted {Uint8Array} the encrypted bytes * @param key {Uint32Array} the bytes of the decryption key * @param initVector {Uint32Array} the initialization vector (IV) to * use for the first round of CBC. * @return {Uint8Array} the decrypted bytes * * @see http://en.wikipedia.org/wiki/Advanced_Encryption_Standard * @see http://en.wikipedia.org/wiki/Block_cipher_mode_of_operation#Cipher_Block_Chaining_.28CBC.29 * @see https://tools.ietf.org/html/rfc2315 */ /* eslint-enable max-len */ var decrypt = function decrypt(encrypted, key, initVector) { // word-level access to the encrypted bytes var encrypted32 = new Int32Array(encrypted.buffer, encrypted.byteOffset, encrypted.byteLength >> 2); var decipher = new _aes2['default'](Array.prototype.slice.call(key)); // byte and word-level access for the decrypted output var decrypted = new Uint8Array(encrypted.byteLength); var decrypted32 = new Int32Array(decrypted.buffer); // temporary variables for working with the IV, encrypted, and // decrypted data var init0 = undefined; var init1 = undefined; var init2 = undefined; var init3 = undefined; var encrypted0 = undefined; var encrypted1 = undefined; var encrypted2 = undefined; var encrypted3 = undefined; // iteration variable var wordIx = undefined; // pull out the words of the IV to ensure we don't modify the // passed-in reference and easier access init0 = initVector[0]; init1 = initVector[1]; init2 = initVector[2]; init3 = initVector[3]; // decrypt four word sequences, applying cipher-block chaining (CBC) // to each decrypted block for (wordIx = 0; wordIx < encrypted32.length; wordIx += 4) { // convert big-endian (network order) words into little-endian // (javascript order) encrypted0 = ntoh(encrypted32[wordIx]); encrypted1 = ntoh(encrypted32[wordIx + 1]); encrypted2 = ntoh(encrypted32[wordIx + 2]); encrypted3 = ntoh(encrypted32[wordIx + 3]); // decrypt the block decipher.decrypt(encrypted0, encrypted1, encrypted2, encrypted3, decrypted32, wordIx); // XOR with the IV, and restore network byte-order to obtain the // plaintext decrypted32[wordIx] = ntoh(decrypted32[wordIx] ^ init0); decrypted32[wordIx + 1] = ntoh(decrypted32[wordIx + 1] ^ init1); decrypted32[wordIx + 2] = ntoh(decrypted32[wordIx + 2] ^ init2); decrypted32[wordIx + 3] = ntoh(decrypted32[wordIx + 3] ^ init3); // setup the IV for the next round init0 = encrypted0; init1 = encrypted1; init2 = encrypted2; init3 = encrypted3; } return decrypted; }; exports.decrypt = decrypt; /** * The `Decrypter` class that manages decryption of AES * data through `AsyncStream` objects and the `decrypt` * function */ var Decrypter = (function () { function Decrypter(encrypted, key, initVector, done) { _classCallCheck(this, Decrypter); var step = Decrypter.STEP; var encrypted32 = new Int32Array(encrypted.buffer); var decrypted = new Uint8Array(encrypted.byteLength); var i = 0; this.asyncStream_ = new _asyncStream2['default'](); // split up the encryption job and do the individual chunks asynchronously this.asyncStream_.push(this.decryptChunk_(encrypted32.subarray(i, i + step), key, initVector, decrypted)); for (i = step; i < encrypted32.length; i += step) { initVector = new Uint32Array([ntoh(encrypted32[i - 4]), ntoh(encrypted32[i - 3]), ntoh(encrypted32[i - 2]), ntoh(encrypted32[i - 1])]); this.asyncStream_.push(this.decryptChunk_(encrypted32.subarray(i, i + step), key, initVector, decrypted)); } // invoke the done() callback when everything is finished this.asyncStream_.push(function () { // remove pkcs#7 padding from the decrypted bytes done(null, (0, _pkcs7.unpad)(decrypted)); }); } // the maximum number of bytes to process at one time // 4 * 8000; _createClass(Decrypter, [{ key: 'decryptChunk_', value: function decryptChunk_(encrypted, key, initVector, decrypted) { return function () { var bytes = decrypt(encrypted, key, initVector); decrypted.set(bytes, encrypted.byteOffset); }; } }]); return Decrypter; })(); exports.Decrypter = Decrypter; Decrypter.STEP = 32000; exports['default'] = { Decrypter: Decrypter, decrypt: decrypt }; },{"./aes":2,"./async-stream":3,"pkcs7":18}],5:[function(require,module,exports){ /* * index.js * * Index module to easily import the primary components of AES-128 * decryption. Like this: * * ```js * import {Decrypter, decrypt, AsyncStream} from './src/decrypter'; * ``` */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _decrypter = require('./decrypter'); var _asyncStream = require('./async-stream'); var _asyncStream2 = _interopRequireDefault(_asyncStream); exports['default'] = { decrypt: _decrypter.decrypt, Decrypter: _decrypter.Decrypter, AsyncStream: _asyncStream2['default'] }; module.exports = exports['default']; },{"./async-stream":3,"./decrypter":4}],6:[function(require,module,exports){ /** * Utilities for parsing M3U8 files. If the entire manifest is available, * `Parser` will create an object representation with enough detail for managing * playback. `ParseStream` and `LineStream` are lower-level parsing primitives * that do not assume the entirety of the manifest is ready and expose a * ReadableStream-like interface. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _lineStream = require('./line-stream'); var _lineStream2 = _interopRequireDefault(_lineStream); var _parseStream = require('./parse-stream'); var _parseStream2 = _interopRequireDefault(_parseStream); var _parser = require('./parser'); var _parser2 = _interopRequireDefault(_parser); exports['default'] = { LineStream: _lineStream2['default'], ParseStream: _parseStream2['default'], Parser: _parser2['default'] }; module.exports = exports['default']; },{"./line-stream":7,"./parse-stream":8,"./parser":9}],7:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _stream = require('../stream'); var _stream2 = _interopRequireDefault(_stream); /** * A stream that buffers string input and generates a `data` event for each * line. */ var LineStream = (function (_Stream) { _inherits(LineStream, _Stream); function LineStream() { _classCallCheck(this, LineStream); _get(Object.getPrototypeOf(LineStream.prototype), 'constructor', this).call(this); this.buffer = ''; } /** * Add new data to be parsed. * @param data {string} the text to process */ _createClass(LineStream, [{ key: 'push', value: function push(data) { var nextNewline = undefined; this.buffer += data; nextNewline = this.buffer.indexOf('\n'); for (; nextNewline > -1; nextNewline = this.buffer.indexOf('\n')) { this.trigger('data', this.buffer.substring(0, nextNewline)); this.buffer = this.buffer.substring(nextNewline + 1); } } }]); return LineStream; })(_stream2['default']); exports['default'] = LineStream; module.exports = exports['default']; },{"../stream":13}],8:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _stream = require('../stream'); var _stream2 = _interopRequireDefault(_stream); // "forgiving" attribute list psuedo-grammar: // attributes -> keyvalue (',' keyvalue)* // keyvalue -> key '=' value // key -> [^=]* // value -> '"' [^"]* '"' | [^,]* var attributeSeparator = function attributeSeparator() { var key = '[^=]*'; var value = '"[^"]*"|[^,]*'; var keyvalue = '(?:' + key + ')=(?:' + value + ')'; return new RegExp('(?:^|,)(' + keyvalue + ')'); }; var parseAttributes = function parseAttributes(attributes) { // split the string using attributes as the separator var attrs = attributes.split(attributeSeparator()); var i = attrs.length; var result = {}; var attr = undefined; while (i--) { // filter out unmatched portions of the string if (attrs[i] === '') { continue; } // split the key and value attr = /([^=]*)=(.*)/.exec(attrs[i]).slice(1); // trim whitespace and remove optional quotes around the value attr[0] = attr[0].replace(/^\s+|\s+$/g, ''); attr[1] = attr[1].replace(/^\s+|\s+$/g, ''); attr[1] = attr[1].replace(/^['"](.*)['"]$/g, '$1'); result[attr[0]] = attr[1]; } return result; }; /** * A line-level M3U8 parser event stream. It expects to receive input one * line at a time and performs a context-free parse of its contents. A stream * interpretation of a manifest can be useful if the manifest is expected to * be too large to fit comfortably into memory or the entirety of the input * is not immediately available. Otherwise, it's probably much easier to work * with a regular `Parser` object. * * Produces `data` events with an object that captures the parser's * interpretation of the input. That object has a property `tag` that is one * of `uri`, `comment`, or `tag`. URIs only have a single additional * property, `line`, which captures the entirety of the input without * interpretation. Comments similarly have a single additional property * `text` which is the input without the leading `#`. * * Tags always have a property `tagType` which is the lower-cased version of * the M3U8 directive without the `#EXT` or `#EXT-X-` prefix. For instance, * `#EXT-X-MEDIA-SEQUENCE` becomes `media-sequence` when parsed. Unrecognized * tags are given the tag type `unknown` and a single additional property * `data` with the remainder of the input. */ var ParseStream = (function (_Stream) { _inherits(ParseStream, _Stream); function ParseStream() { _classCallCheck(this, ParseStream); _get(Object.getPrototypeOf(ParseStream.prototype), 'constructor', this).call(this); } /** * Parses an additional line of input. * @param line {string} a single line of an M3U8 file to parse */ _createClass(ParseStream, [{ key: 'push', value: function push(line) { var match = undefined; var event = undefined; // strip whitespace line = line.replace(/^[\u0000\s]+|[\u0000\s]+$/g, ''); if (line.length === 0) { // ignore empty lines return; } // URIs if (line[0] !== '#') { this.trigger('data', { type: 'uri', uri: line }); return; } // Comments if (line.indexOf('#EXT') !== 0) { this.trigger('data', { type: 'comment', text: line.slice(1) }); return; } // strip off any carriage returns here so the regex matching // doesn't have to account for them. line = line.replace('\r', ''); // Tags match = /^#EXTM3U/.exec(line); if (match) { this.trigger('data', { type: 'tag', tagType: 'm3u' }); return; } match = /^#EXTINF:?([0-9\.]*)?,?(.*)?$/.exec(line); if (match) { event = { type: 'tag', tagType: 'inf' }; if (match[1]) { event.duration = parseFloat(match[1]); } if (match[2]) { event.title = match[2]; } this.trigger('data', event); return; } match = /^#EXT-X-TARGETDURATION:?([0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'targetduration' }; if (match[1]) { event.duration = parseInt(match[1], 10); } this.trigger('data', event); return; } match = /^#ZEN-TOTAL-DURATION:?([0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'totalduration' }; if (match[1]) { event.duration = parseInt(match[1], 10); } this.trigger('data', event); return; } match = /^#EXT-X-VERSION:?([0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'version' }; if (match[1]) { event.version = parseInt(match[1], 10); } this.trigger('data', event); return; } match = /^#EXT-X-MEDIA-SEQUENCE:?(\-?[0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'media-sequence' }; if (match[1]) { event.number = parseInt(match[1], 10); } this.trigger('data', event); return; } match = /^#EXT-X-DISCONTINUITY-SEQUENCE:?(\-?[0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'discontinuity-sequence' }; if (match[1]) { event.number = parseInt(match[1], 10); } this.trigger('data', event); return; } match = /^#EXT-X-PLAYLIST-TYPE:?(.*)?$/.exec(line); if (match) { event = { type: 'tag', tagType: 'playlist-type' }; if (match[1]) { event.playlistType = match[1]; } this.trigger('data', event); return; } match = /^#EXT-X-BYTERANGE:?([0-9.]*)?@?([0-9.]*)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'byterange' }; if (match[1]) { event.length = parseInt(match[1], 10); } if (match[2]) { event.offset = parseInt(match[2], 10); } this.trigger('data', event); return; } match = /^#EXT-X-ALLOW-CACHE:?(YES|NO)?/.exec(line); if (match) { event = { type: 'tag', tagType: 'allow-cache' }; if (match[1]) { event.allowed = !/NO/.test(match[1]); } this.trigger('data', event); return; } match = /^#EXT-X-STREAM-INF:?(.*)$/.exec(line); if (match) { event = { type: 'tag', tagType: 'stream-inf' }; if (match[1]) { event.attributes = parseAttributes(match[1]); if (event.attributes.RESOLUTION) { var split = event.attributes.RESOLUTION.split('x'); var resolution = {}; if (split[0]) { resolution.width = parseInt(split[0], 10); } if (split[1]) { resolution.height = parseInt(split[1], 10); } event.attributes.RESOLUTION = resolution; } if (event.attributes.BANDWIDTH) { event.attributes.BANDWIDTH = parseInt(event.attributes.BANDWIDTH, 10); } if (event.attributes['PROGRAM-ID']) { event.attributes['PROGRAM-ID'] = parseInt(event.attributes['PROGRAM-ID'], 10); } } this.trigger('data', event); return; } match = /^#EXT-X-ENDLIST/.exec(line); if (match) { this.trigger('data', { type: 'tag', tagType: 'endlist' }); return; } match = /^#EXT-X-DISCONTINUITY/.exec(line); if (match) { this.trigger('data', { type: 'tag', tagType: 'discontinuity' }); return; } match = /^#EXT-X-KEY:?(.*)$/.exec(line); if (match) { event = { type: 'tag', tagType: 'key' }; if (match[1]) { event.attributes = parseAttributes(match[1]); // parse the IV string into a Uint32Array if (event.attributes.IV) { if (event.attributes.IV.substring(0, 2) === '0x') { event.attributes.IV = event.attributes.IV.substring(2); } event.attributes.IV = event.attributes.IV.match(/.{8}/g); event.attributes.IV[0] = parseInt(event.attributes.IV[0], 16); event.attributes.IV[1] = parseInt(event.attributes.IV[1], 16); event.attributes.IV[2] = parseInt(event.attributes.IV[2], 16); event.attributes.IV[3] = parseInt(event.attributes.IV[3], 16); event.attributes.IV = new Uint32Array(event.attributes.IV); } } this.trigger('data', event); return; } // unknown tag type this.trigger('data', { type: 'tag', data: line.slice(4, line.length) }); } }]); return ParseStream; })(_stream2['default']); exports['default'] = ParseStream; module.exports = exports['default']; },{"../stream":13}],9:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _stream = require('../stream'); var _stream2 = _interopRequireDefault(_stream); var _lineStream = require('./line-stream'); var _lineStream2 = _interopRequireDefault(_lineStream); var _parseStream = require('./parse-stream'); var _parseStream2 = _interopRequireDefault(_parseStream); var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); /** * A parser for M3U8 files. The current interpretation of the input is * exposed as a property `manifest` on parser objects. It's just two lines to * create and parse a manifest once you have the contents available as a string: * * ```js * var parser = new videojs.m3u8.Parser(); * parser.push(xhr.responseText); * ``` * * New input can later be applied to update the manifest object by calling * `push` again. * * The parser attempts to create a usable manifest object even if the * underlying input is somewhat nonsensical. It emits `info` and `warning` * events during the parse if it encounters input that seems invalid or * requires some property of the manifest object to be defaulted. */ var Parser = (function (_Stream) { _inherits(Parser, _Stream); function Parser() { _classCallCheck(this, Parser); _get(Object.getPrototypeOf(Parser.prototype), 'constructor', this).call(this); this.lineStream = new _lineStream2['default'](); this.parseStream = new _parseStream2['default'](); this.lineStream.pipe(this.parseStream); /* eslint-disable consistent-this */ var self = this; /* eslint-enable consistent-this */ var uris = []; var currentUri = {}; var _key = undefined; var noop = function noop() {}; // the manifest is empty until the parse stream begins delivering data this.manifest = { allowCache: true, discontinuityStarts: [] }; // update the manifest with the m3u8 entry from the parse stream this.parseStream.on('data', function (entry) { ({ tag: function tag() { // switch based on the tag type (({ 'allow-cache': function allowCache() { this.manifest.allowCache = entry.allowed; if (!('allowed' in entry)) { this.trigger('info', { message: 'defaulting allowCache to YES' }); this.manifest.allowCache = true; } }, byterange: function byterange() { var byterange = {}; if ('length' in entry) { currentUri.byterange = byterange; byterange.length = entry.length; if (!('offset' in entry)) { this.trigger('info', { message: 'defaulting offset to zero' }); entry.offset = 0; } } if ('offset' in entry) { currentUri.byterange = byterange; byterange.offset = entry.offset; } }, endlist: function endlist() { this.manifest.endList = true; }, inf: function inf() { if (!('mediaSequence' in this.manifest)) { this.manifest.mediaSequence = 0; this.trigger('info', { message: 'defaulting media sequence to zero' }); } if (!('discontinuitySequence' in this.manifest)) { this.manifest.discontinuitySequence = 0; this.trigger('info', { message: 'defaulting discontinuity sequence to zero' }); } if (entry.duration >= 0) { currentUri.duration = entry.duration; } this.manifest.segments = uris; }, key: function key() { if (!entry.attributes) { this.trigger('warn', { message: 'ignoring key declaration without attribute list' }); return; } // clear the active encryption key if (entry.attributes.METHOD === 'NONE') { _key = null; return; } if (!entry.attributes.URI) { this.trigger('warn', { message: 'ignoring key declaration without URI' }); return; } if (!entry.attributes.METHOD) { this.trigger('warn', { message: 'defaulting key method to AES-128' }); } // setup an encryption key for upcoming segments _key = { method: entry.attributes.METHOD || 'AES-128', uri: entry.attributes.URI }; if (typeof entry.attributes.IV !== 'undefined') { _key.iv = entry.attributes.IV; } }, 'media-sequence': function mediaSequence() { if (!isFinite(entry.number)) { this.trigger('warn', { message: 'ignoring invalid media sequence: ' + entry.number }); return; } this.manifest.mediaSequence = entry.number; }, 'discontinuity-sequence': function discontinuitySequence() { if (!isFinite(entry.number)) { this.trigger('warn', { message: 'ignoring invalid discontinuity sequence: ' + entry.number }); return; } this.manifest.discontinuitySequence = entry.number; }, 'playlist-type': function playlistType() { if (!/VOD|EVENT/.test(entry.playlistType)) { this.trigger('warn', { message: 'ignoring unknown playlist type: ' + entry.playlist }); return; } this.manifest.playlistType = entry.playlistType; }, 'stream-inf': function streamInf() { this.manifest.playlists = uris; if (!entry.attributes) { this.trigger('warn', { message: 'ignoring empty stream-inf attributes' }); return; } if (!currentUri.attributes) { currentUri.attributes = {}; } currentUri.attributes = (0, _videoJs.mergeOptions)(currentUri.attributes, entry.attributes); }, discontinuity: function discontinuity() { currentUri.discontinuity = true; this.manifest.discontinuityStarts.push(uris.length); }, targetduration: function targetduration() { if (!isFinite(entry.duration) || entry.duration < 0) { this.trigger('warn', { message: 'ignoring invalid target duration: ' + entry.duration }); return; } this.manifest.targetDuration = entry.duration; }, totalduration: function totalduration() { if (!isFinite(entry.duration) || entry.duration < 0) { this.trigger('warn', { message: 'ignoring invalid total duration: ' + entry.duration }); return; } this.manifest.totalDuration = entry.duration; } })[entry.tagType] || noop).call(self); }, uri: function uri() { currentUri.uri = entry.uri; uris.push(currentUri); // if no explicit duration was declared, use the target duration if (this.manifest.targetDuration && !('duration' in currentUri)) { this.trigger('warn', { message: 'defaulting segment duration to the target duration' }); currentUri.duration = this.manifest.targetDuration; } // annotate with encryption information, if necessary if (_key) { currentUri.key = _key; } // prepare for the next URI currentUri = {}; }, comment: function comment() { // comments are not important for playback } })[entry.type].call(self); }); } /** * Parse the input string and update the manifest object. * @param chunk {string} a potentially incomplete portion of the manifest */ _createClass(Parser, [{ key: 'push', value: function push(chunk) { this.lineStream.push(chunk); } /** * Flush any remaining input. This can be handy if the last line of an M3U8 * manifest did not contain a trailing newline but the file has been * completely received. */ }, { key: 'end', value: function end() { // flush any buffered input this.lineStream.push('\n'); } }]); return Parser; })(_stream2['default']); exports['default'] = Parser; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"../stream":13,"./line-stream":7,"./parse-stream":8}],10:[function(require,module,exports){ (function (global){ /** * playlist-loader * * A state machine that manages the loading, caching, and updating of * M3U8 playlists. * */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _resolveUrl = require('./resolve-url'); var _resolveUrl2 = _interopRequireDefault(_resolveUrl); var _xhr = require('./xhr'); var _xhr2 = _interopRequireDefault(_xhr); var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _stream = require('./stream'); var _stream2 = _interopRequireDefault(_stream); var _m3u8 = require('./m3u8'); var _m3u82 = _interopRequireDefault(_m3u8); /** * Returns a new master playlist that is the result of merging an * updated media playlist into the original version. If the * updated media playlist does not match any of the playlist * entries in the original master playlist, null is returned. * @param master {object} a parsed master M3U8 object * @param media {object} a parsed media M3U8 object * @return {object} a new object that represents the original * master playlist with the updated media playlist merged in, or * null if the merge produced no change. */ var updateMaster = function updateMaster(master, media) { var changed = false; var result = (0, _videoJs.mergeOptions)(master, {}); var i = master.playlists.length; var playlist = undefined; while (i--) { playlist = result.playlists[i]; if (playlist.uri === media.uri) { // consider the playlist unchanged if the number of segments // are equal and the media sequence number is unchanged if (playlist.segments && media.segments && playlist.segments.length === media.segments.length && playlist.mediaSequence === media.mediaSequence) { continue; } result.playlists[i] = (0, _videoJs.mergeOptions)(playlist, media); result.playlists[media.uri] = result.playlists[i]; // if the update could overlap existing segment information, // merge the two lists if (playlist.segments) { result.playlists[i].segments = updateSegments(playlist.segments, media.segments, media.mediaSequence - playlist.mediaSequence); } changed = true; } } return changed ? result : null; }; /** * Returns a new array of segments that is the result of merging * properties from an older list of segments onto an updated * list. No properties on the updated playlist will be overridden. * @param original {array} the outdated list of segments * @param update {array} the updated list of segments * @param offset {number} (optional) the index of the first update * segment in the original segment list. For non-live playlists, * this should always be zero and does not need to be * specified. For live playlists, it should be the difference * between the media sequence numbers in the original and updated * playlists. * @return a list of merged segment objects */ var updateSegments = function updateSegments(original, update, offset) { var result = update.slice(); var length = undefined; var i = undefined; offset = offset || 0; length = Math.min(original.length, update.length + offset); for (i = offset; i < length; i++) { result[i - offset] = (0, _videoJs.mergeOptions)(original[i], result[i - offset]); } return result; }; var PlaylistLoader = (function (_Stream) { _inherits(PlaylistLoader, _Stream); function PlaylistLoader(srcUrl, withCredentials) { _classCallCheck(this, PlaylistLoader); _get(Object.getPrototypeOf(PlaylistLoader.prototype), 'constructor', this).call(this); var loader = this; var dispose = undefined; var mediaUpdateTimeout = undefined; var request = undefined; var playlistRequestError = undefined; var haveMetadata = undefined; // a flag that disables "expired time"-tracking this setting has // no effect when not playing a live stream this.trackExpiredTime_ = false; if (!srcUrl) { throw new Error('A non-empty playlist URL is required'); } playlistRequestError = function (xhr, url, startingState) { loader.setBandwidth(request || xhr); // any in-flight request is now finished request = null; if (startingState) { loader.state = startingState; } loader.error = { playlist: loader.master.playlists[url], status: xhr.status, message: 'HLS playlist request error at URL: ' + url, responseText: xhr.responseText, code: xhr.status >= 500 ? 4 : 2 }; loader.trigger('error'); }; // update the playlist loader's state in response to a new or // updated playlist. haveMetadata = function (xhr, url) { var parser = undefined; var refreshDelay = undefined; var update = undefined; loader.setBandwidth(request || xhr); // any in-flight request is now finished request = null; loader.state = 'HAVE_METADATA'; parser = new _m3u82['default'].Parser(); parser.push(xhr.responseText); parser.end(); parser.manifest.uri = url; // merge this playlist into the master update = updateMaster(loader.master, parser.manifest); refreshDelay = (parser.manifest.targetDuration || 10) * 1000; if (update) { loader.master = update; loader.updateMediaPlaylist_(parser.manifest); } else { // if the playlist is unchanged since the last reload, // try again after half the target duration refreshDelay /= 2; } // refresh live playlists after a target duration passes if (!loader.media().endList) { window.clearTimeout(mediaUpdateTimeout); mediaUpdateTimeout = window.setTimeout(function () { loader.trigger('mediaupdatetimeout'); }, refreshDelay); } loader.trigger('loadedplaylist'); }; // initialize the loader state loader.state = 'HAVE_NOTHING'; // track the time that has expired from the live window // this allows the seekable start range to be calculated even if // all segments with timing information have expired this.expired_ = 0; // capture the prototype dispose function dispose = this.dispose; /** * Abort any outstanding work and clean up. */ loader.dispose = function () { if (request) { request.onreadystatechange = null; request.abort(); request = null; } window.clearTimeout(mediaUpdateTimeout); dispose.call(this); }; /** * When called without any arguments, returns the currently * active media playlist. When called with a single argument, * triggers the playlist loader to asynchronously switch to the * specified media playlist. Calling this method while the * loader is in the HAVE_NOTHING causes an error to be emitted * but otherwise has no effect. * @param playlist (optional) {object} the parsed media playlist * object to switch to */ loader.media = function (playlist) { var startingState = loader.state; var mediaChange = undefined; // getter if (!playlist) { return loader.media_; } // setter if (loader.state === 'HAVE_NOTHING') { throw new Error('Cannot switch media playlist from ' + loader.state); } // find the playlist object if the target playlist has been // specified by URI if (typeof playlist === 'string') { if (!loader.master.playlists[playlist]) { throw new Error('Unknown playlist URI: ' + playlist); } playlist = loader.master.playlists[playlist]; } mediaChange = !loader.media_ || playlist.uri !== loader.media_.uri; // switch to fully loaded playlists immediately if (loader.master.playlists[playlist.uri].endList) { // abort outstanding playlist requests if (request) { request.onreadystatechange = null; request.abort(); request = null; } loader.state = 'HAVE_METADATA'; loader.media_ = playlist; // trigger media change if the active media has been updated if (mediaChange) { loader.trigger('mediachange'); } return; } // switching to the active playlist is a no-op if (!mediaChange) { return; } loader.state = 'SWITCHING_MEDIA'; // there is already an outstanding playlist request if (request) { if ((0, _resolveUrl2['default'])(loader.master.uri, playlist.uri) === request.url) { // requesting to switch to the same playlist multiple times // has no effect after the first return; } request.onreadystatechange = null; request.abort(); request = null; } // request the new playlist request = (0, _xhr2['default'])({ uri: (0, _resolveUrl2['default'])(loader.master.uri, playlist.uri), withCredentials: withCredentials }, function (error, request) { if (error) { return playlistRequestError(request, playlist.uri, startingState); } haveMetadata(request, playlist.uri); // fire loadedmetadata the first time a media playlist is loaded if (startingState === 'HAVE_MASTER') { loader.trigger('loadedmetadata'); } else { loader.trigger('mediachange'); } }); }; loader.setBandwidth = function (xhr) { loader.bandwidth = xhr.bandwidth; }; // In a live list, don't keep track of the expired time until // HLS tells us that "first play" has commenced loader.on('firstplay', function () { this.trackExpiredTime_ = true; }); // live playlist staleness timeout loader.on('mediaupdatetimeout', function () { if (loader.state !== 'HAVE_METADATA') { // only refresh the media playlist if no other activity is going on return; } loader.state = 'HAVE_CURRENT_METADATA'; request = (0, _xhr2['default'])({ uri: (0, _resolveUrl2['default'])(loader.master.uri, loader.media().uri), withCredentials: withCredentials }, function (error, request) { if (error) { return playlistRequestError(request, loader.media().uri); } haveMetadata(request, loader.media().uri); }); }); // request the specified URL request = (0, _xhr2['default'])({ uri: srcUrl, withCredentials: withCredentials }, function (error, req) { var parser = undefined; var i = undefined; // clear the loader's request reference request = null; if (error) { loader.error = { status: req.status, message: 'HLS playlist request error at URL: ' + srcUrl, responseText: req.responseText, // MEDIA_ERR_NETWORK code: 2 }; return loader.trigger('error'); } parser = new _m3u82['default'].Parser(); parser.push(req.responseText); parser.end(); loader.state = 'HAVE_MASTER'; parser.manifest.uri = srcUrl; // loaded a master playlist if (parser.manifest.playlists) { loader.master = parser.manifest; // setup by-URI lookups i = loader.master.playlists.length; while (i--) { loader.master.playlists[loader.master.playlists[i].uri] = loader.master.playlists[i]; } loader.trigger('loadedplaylist'); if (!request) { // no media playlist was specifically selected so start // from the first listed one loader.media(parser.manifest.playlists[0]); } return; } // loaded a media playlist // infer a master playlist if none was previously requested loader.master = { uri: window.location.href, playlists: [{ uri: srcUrl }] }; loader.master.playlists[srcUrl] = loader.master.playlists[0]; haveMetadata(req, srcUrl); return loader.trigger('loadedmetadata'); }); } /** * Update the PlaylistLoader state to reflect the changes in an * update to the current media playlist. * @param update {object} the updated media playlist object */ _createClass(PlaylistLoader, [{ key: 'updateMediaPlaylist_', value: function updateMediaPlaylist_(update) { var outdated = undefined; var i = undefined; var segment = undefined; outdated = this.media_; this.media_ = this.master.playlists[update.uri]; if (!outdated) { return; } // don't track expired time until this flag is truthy if (!this.trackExpiredTime_) { return; } // if the update was the result of a rendition switch do not // attempt to calculate expired_ since media-sequences need not // correlate between renditions/variants if (update.uri !== outdated.uri) { return; } // try using precise timing from first segment of the updated // playlist if (update.segments.length) { if (update.segments[0].start !== undefined) { this.expired_ = update.segments[0].start; return; } else if (update.segments[0].end !== undefined) { this.expired_ = update.segments[0].end - update.segments[0].duration; return; } } // calculate expired by walking the outdated playlist i = update.mediaSequence - outdated.mediaSequence - 1; for (; i >= 0; i--) { segment = outdated.segments[i]; if (!segment) { // we missed information on this segment completely between // playlist updates so we'll have to take an educated guess // once we begin buffering again, any error we introduce can // be corrected this.expired_ += outdated.targetDuration || 10; continue; } if (segment.end !== undefined) { this.expired_ = segment.end; return; } if (segment.start !== undefined) { this.expired_ = segment.start + segment.duration; return; } this.expired_ += segment.duration; } } /** * Determine the index of the segment that contains a specified * playback position in the current media playlist. Early versions * of the HLS specification require segment durations to be rounded * to the nearest integer which means it may not be possible to * determine the correct segment for a playback position if that * position is within .5 seconds of the segment duration. This * function will always return the lower of the two possible indices * in those cases. * * @param time {number} The number of seconds since the earliest * possible position to determine the containing segment for * @returns {number} The number of the media segment that contains * that time position. If the specified playback position is outside * the time range of the current set of media segments, the return * value will be clamped to the index of the segment containing the * closest playback position that is currently available. */ }, { key: 'getMediaIndexForTime_', value: function getMediaIndexForTime_(time) { var i = undefined; var segment = undefined; var originalTime = time; var numSegments = this.media_.segments.length; var lastSegment = numSegments - 1; var startIndex = undefined; var endIndex = undefined; var knownStart = undefined; var knownEnd = undefined; if (!this.media_) { return 0; } // when the requested position is earlier than the current set of // segments, return the earliest segment index if (time < 0) { return 0; } // find segments with known timing information that bound the // target time for (i = 0; i < numSegments; i++) { segment = this.media_.segments[i]; if (segment.end) { if (segment.end > time) { knownEnd = segment.end; endIndex = i; break; } else { knownStart = segment.end; startIndex = i + 1; } } } // use the bounds we just found and playlist information to // estimate the segment that contains the time we are looking for if (startIndex !== undefined) { // We have a known-start point that is before our desired time so // walk from that point forwards time = time - knownStart; for (i = startIndex; i < (endIndex || numSegments); i++) { segment = this.media_.segments[i]; time -= segment.duration; if (time < 0) { return i; } } if (i >= endIndex) { // We haven't found a segment but we did hit a known end point // so fallback to interpolating between the segment index // based on the known span of the timeline we are dealing with // and the number of segments inside that span return startIndex + Math.floor((originalTime - knownStart) / (knownEnd - knownStart) * (endIndex - startIndex)); } // We _still_ haven't found a segment so load the last one return lastSegment; } else if (endIndex !== undefined) { // We _only_ have a known-end point that is after our desired time so // walk from that point backwards time = knownEnd - time; for (i = endIndex; i >= 0; i--) { segment = this.media_.segments[i]; time -= segment.duration; if (time < 0) { return i; } } // We haven't found a segment so load the first one if time is zero if (time === 0) { return 0; } else { return -1; } } else { // We known nothing so walk from the front of the playlist, // subtracting durations until we find a segment that contains // time and return it time = time - this.expired_; if (time < 0) { return -1; } for (i = 0; i < numSegments; i++) { segment = this.media_.segments[i]; time -= segment.duration; if (time < 0) { return i; } } // We are out of possible candidates so load the last one... // The last one is the least likely to overlap a buffer and therefore // the one most likely to tell us something about the timeline return lastSegment; } } }]); return PlaylistLoader; })(_stream2['default']); exports['default'] = PlaylistLoader; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./m3u8":6,"./resolve-url":12,"./stream":13,"./xhr":14}],11:[function(require,module,exports){ (function (global){ /** * Playlist related utilities. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var Playlist = { /** * The number of segments that are unsafe to start playback at in * a live stream. Changing this value can cause playback stalls. * See HTTP Live Streaming, "Playing the Media Playlist File" * https://tools.ietf.org/html/draft-pantos-http-live-streaming-18#section-6.3.3 */ UNSAFE_LIVE_SEGMENTS: 3 }; var backwardDuration = function backwardDuration(playlist, endSequence) { var result = 0; var i = endSequence - playlist.mediaSequence; // if a start time is available for segment immediately following // the interval, use it var segment = playlist.segments[i]; // Walk backward until we find the latest segment with timeline // information that is earlier than endSequence if (segment) { if (typeof segment.start !== 'undefined') { return { result: segment.start, precise: true }; } if (typeof segment.end !== 'undefined') { return { result: segment.end - segment.duration, precise: true }; } } while (i--) { segment = playlist.segments[i]; if (typeof segment.end !== 'undefined') { return { result: result + segment.end, precise: true }; } result += segment.duration; if (typeof segment.start !== 'undefined') { return { result: result + segment.start, precise: true }; } } return { result: result, precise: false }; }; var forwardDuration = function forwardDuration(playlist, endSequence) { var result = 0; var segment = undefined; var i = endSequence - playlist.mediaSequence; // Walk forward until we find the earliest segment with timeline // information for (; i < playlist.segments.length; i++) { segment = playlist.segments[i]; if (typeof segment.start !== 'undefined') { return { result: segment.start - result, precise: true }; } result += segment.duration; if (typeof segment.end !== 'undefined') { return { result: segment.end - result, precise: true }; } } // indicate we didn't find a useful duration estimate return { result: -1, precise: false }; }; /** * Calculate the media duration from the segments associated with a * playlist. The duration of a subinterval of the available segments * may be calculated by specifying an end index. * * @param playlist {object} a media playlist object * @param endSequence {number} (optional) an exclusive upper boundary * for the playlist. Defaults to playlist length. * @return {number} the duration between the first available segment * and end index. */ var intervalDuration = function intervalDuration(playlist, endSequence) { var backward = undefined; var forward = undefined; if (typeof endSequence === 'undefined') { endSequence = playlist.mediaSequence + playlist.segments.length; } if (endSequence < playlist.mediaSequence) { return 0; } // do a backward walk to estimate the duration backward = backwardDuration(playlist, endSequence); if (backward.precise) { // if we were able to base our duration estimate on timing // information provided directly from the Media Source, return // it return backward.result; } // walk forward to see if a precise duration estimate can be made // that way forward = forwardDuration(playlist, endSequence); if (forward.precise) { // we found a segment that has been buffered and so it's // position is known precisely return forward.result; } // return the less-precise, playlist-based duration estimate return backward.result; }; /** * Calculates the duration of a playlist. If a start and end index * are specified, the duration will be for the subset of the media * timeline between those two indices. The total duration for live * playlists is always Infinity. * @param playlist {object} a media playlist object * @param endSequence {number} (optional) an exclusive upper * boundary for the playlist. Defaults to the playlist media * sequence number plus its length. * @param includeTrailingTime {boolean} (optional) if false, the * interval between the final segment and the subsequent segment * will not be included in the result * @return {number} the duration between the start index and end * index. */ var duration = function duration(playlist, endSequence, includeTrailingTime) { if (!playlist) { return 0; } if (typeof includeTrailingTime === 'undefined') { includeTrailingTime = true; } // if a slice of the total duration is not requested, use // playlist-level duration indicators when they're present if (typeof endSequence === 'undefined') { // if present, use the duration specified in the playlist if (playlist.totalDuration) { return playlist.totalDuration; } // duration should be Infinity for live playlists if (!playlist.endList) { return window.Infinity; } } // calculate the total duration based on the segment durations return intervalDuration(playlist, endSequence, includeTrailingTime); }; exports.duration = duration; /** * Calculates the interval of time that is currently seekable in a * playlist. The returned time ranges are relative to the earliest * moment in the specified playlist that is still available. A full * seekable implementation for live streams would need to offset * these values by the duration of content that has expired from the * stream. * @param playlist {object} a media playlist object * @return {TimeRanges} the periods of time that are valid targets * for seeking */ var seekable = function seekable(playlist) { var start = undefined; var end = undefined; // without segments, there are no seekable ranges if (!playlist.segments) { return (0, _videoJs.createTimeRange)(); } // when the playlist is complete, the entire duration is seekable if (playlist.endList) { return (0, _videoJs.createTimeRange)(0, duration(playlist)); } // live playlists should not expose three segment durations worth // of content from the end of the playlist // https://tools.ietf.org/html/draft-pantos-http-live-streaming-16#section-6.3.3 start = intervalDuration(playlist, playlist.mediaSequence); end = intervalDuration(playlist, playlist.mediaSequence + Math.max(0, playlist.segments.length - Playlist.UNSAFE_LIVE_SEGMENTS)); return (0, _videoJs.createTimeRange)(start, end); }; exports.seekable = seekable; Playlist.duration = duration; Playlist.seekable = seekable; // exports exports['default'] = Playlist; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{}],12:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _globalDocument = require('global/document'); var _globalDocument2 = _interopRequireDefault(_globalDocument); /* eslint-disable max-len */ /** * Constructs a new URI by interpreting a path relative to another * URI. * @param basePath {string} a relative or absolute URI * @param path {string} a path part to combine with the base * @return {string} a URI that is equivalent to composing `base` * with `path` * @see http://stackoverflow.com/questions/470832/getting-an-absolute-url-from-a-relative-one-ie6-issue */ /* eslint-enable max-len */ var resolveUrl = function resolveUrl(basePath, path) { // use the base element to get the browser to handle URI resolution var oldBase = _globalDocument2['default'].querySelector('base'); var docHead = _globalDocument2['default'].querySelector('head'); var a = _globalDocument2['default'].createElement('a'); var base = oldBase; var oldHref = undefined; var result = undefined; // prep the document if (oldBase) { oldHref = oldBase.href; } else { base = docHead.appendChild(_globalDocument2['default'].createElement('base')); } base.href = basePath; a.href = path; result = a.href; // clean up if (oldBase) { oldBase.href = oldHref; } else { docHead.removeChild(base); } return result; }; exports['default'] = resolveUrl; module.exports = exports['default']; },{"global/document":16}],13:[function(require,module,exports){ /** * A lightweight readable stream implemention that handles event dispatching. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } var Stream = (function () { function Stream() { _classCallCheck(this, Stream); this.listeners = {}; } /** * Add a listener for a specified event type. * @param type {string} the event name * @param listener {function} the callback to be invoked when an event of * the specified type occurs */ _createClass(Stream, [{ key: 'on', value: function on(type, listener) { if (!this.listeners[type]) { this.listeners[type] = []; } this.listeners[type].push(listener); } /** * Remove a listener for a specified event type. * @param type {string} the event name * @param listener {function} a function previously registered for this * type of event through `on` */ }, { key: 'off', value: function off(type, listener) { var index = undefined; if (!this.listeners[type]) { return false; } index = this.listeners[type].indexOf(listener); this.listeners[type].splice(index, 1); return index > -1; } /** * Trigger an event of the specified type on this stream. Any additional * arguments to this function are passed as parameters to event listeners. * @param type {string} the event name */ }, { key: 'trigger', value: function trigger(type) { var callbacks = undefined; var i = undefined; var length = undefined; var args = undefined; callbacks = this.listeners[type]; if (!callbacks) { return; } // Slicing the arguments on every invocation of this method // can add a significant amount of overhead. Avoid the // intermediate object creation for the common case of a // single callback argument if (arguments.length === 2) { length = callbacks.length; for (i = 0; i < length; ++i) { callbacks[i].call(this, arguments[1]); } } else { args = Array.prototype.slice.call(arguments, 1); length = callbacks.length; for (i = 0; i < length; ++i) { callbacks[i].apply(this, args); } } } /** * Destroys the stream and cleans up. */ }, { key: 'dispose', value: function dispose() { this.listeners = {}; } /** * Forwards all `data` events on this stream to the destination stream. The * destination stream should provide a method `push` to receive the data * events as they arrive. * @param destination {stream} the stream that will receive all `data` events * @see http://nodejs.org/api/stream.html#stream_readable_pipe_destination_options */ }, { key: 'pipe', value: function pipe(destination) { this.on('data', function (data) { destination.push(data); }); } }]); return Stream; })(); exports['default'] = Stream; module.exports = exports['default']; },{}],14:[function(require,module,exports){ (function (global){ /** * A wrapper for videojs.xhr that tracks bandwidth. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var xhr = function xhr(options, callback) { // Add a default timeout for all hls requests options = (0, _videoJs.mergeOptions)({ timeout: 45e3 }, options); var request = (0, _videoJs.xhr)(options, function (error, response) { if (!error && request.response) { request.responseTime = new Date().getTime(); request.roundTripTime = request.responseTime - request.requestTime; request.bytesReceived = request.response.byteLength || request.response.length; if (!request.bandwidth) { request.bandwidth = Math.floor(request.bytesReceived / request.roundTripTime * 8 * 1000); } } // videojs.xhr now uses a specific code // on the error object to signal that a request has // timed out errors of setting a boolean on the request object if (error || request.timedout) { request.timedout = request.timedout || error.code === 'ETIMEDOUT'; } else { request.timedout = false; } // videojs.xhr no longer considers status codes outside of 200 and 0 // (for file uris) to be errors, but the old XHR did, so emulate that // behavior. Status 206 may be used in response to byterange requests. if (!error && response.statusCode !== 200 && response.statusCode !== 206 && response.statusCode !== 0) { error = new Error('XHR Failed with a response of: ' + (request && (request.response || request.responseText))); } callback(error, request); }); request.requestTime = new Date().getTime(); return request; }; exports['default'] = xhr; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{}],15:[function(require,module,exports){ },{}],16:[function(require,module,exports){ (function (global){ var topLevel = typeof global !== 'undefined' ? global : typeof window !== 'undefined' ? window : {} var minDoc = require('min-document'); if (typeof document !== 'undefined') { module.exports = document; } else { var doccy = topLevel['__GLOBAL_DOCUMENT_CACHE@4']; if (!doccy) { doccy = topLevel['__GLOBAL_DOCUMENT_CACHE@4'] = minDoc; } module.exports = doccy; } }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"min-document":15}],17:[function(require,module,exports){ /* * pkcs7.pad * https://github.com/brightcove/pkcs7 * * Copyright (c) 2014 Brightcove * Licensed under the apache2 license. */ 'use strict'; var PADDING; /** * Returns a new Uint8Array that is padded with PKCS#7 padding. * @param plaintext {Uint8Array} the input bytes before encryption * @return {Uint8Array} the padded bytes * @see http://tools.ietf.org/html/rfc5652 */ module.exports = function pad(plaintext) { var padding = PADDING[(plaintext.byteLength % 16) || 0], result = new Uint8Array(plaintext.byteLength + padding.length); result.set(plaintext); result.set(padding, plaintext.byteLength); return result; }; // pre-define the padding values PADDING = [ [16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16, 16], [15, 15, 15, 15, 15, 15, 15, 15, 15, 15, 15, 15, 15, 15, 15], [14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14], [13, 13, 13, 13, 13, 13, 13, 13, 13, 13, 13, 13, 13], [12, 12, 12, 12, 12, 12, 12, 12, 12, 12, 12, 12], [11, 11, 11, 11, 11, 11, 11, 11, 11, 11, 11], [10, 10, 10, 10, 10, 10, 10, 10, 10, 10], [9, 9, 9, 9, 9, 9, 9, 9, 9], [8, 8, 8, 8, 8, 8, 8, 8], [7, 7, 7, 7, 7, 7, 7], [6, 6, 6, 6, 6, 6], [5, 5, 5, 5, 5], [4, 4, 4, 4], [3, 3, 3], [2, 2], [1] ]; },{}],18:[function(require,module,exports){ /* * pkcs7 * https://github.com/brightcove/pkcs7 * * Copyright (c) 2014 Brightcove * Licensed under the apache2 license. */ 'use strict'; exports.pad = require('./pad.js'); exports.unpad = require('./unpad.js'); },{"./pad.js":17,"./unpad.js":19}],19:[function(require,module,exports){ /* * pkcs7.unpad * https://github.com/brightcove/pkcs7 * * Copyright (c) 2014 Brightcove * Licensed under the apache2 license. */ 'use strict'; /** * Returns the subarray of a Uint8Array without PKCS#7 padding. * @param padded {Uint8Array} unencrypted bytes that have been padded * @return {Uint8Array} the unpadded bytes * @see http://tools.ietf.org/html/rfc5652 */ module.exports = function unpad(padded) { return padded.subarray(0, padded.byteLength - padded[padded.byteLength - 1]); }; },{}],20:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var deprecateOldCue = function deprecateOldCue(cue) { Object.defineProperties(cue.frame, { id: { get: function get() { _videoJs2['default'].log.warn('cue.frame.id is deprecated. Use cue.value.key instead.'); return cue.value.key; } }, value: { get: function get() { _videoJs2['default'].log.warn('cue.frame.value is deprecated. Use cue.value.data instead.'); return cue.value.data; } }, privateData: { get: function get() { _videoJs2['default'].log.warn('cue.frame.privateData is deprecated. Use cue.value.data instead.'); return cue.value.data; } } }); }; var addTextTrackData = function addTextTrackData(sourceHandler, captionArray, metadataArray) { var Cue = window.WebKitDataCue || window.VTTCue; if (captionArray) { captionArray.forEach(function (caption) { this.inbandTextTrack_.addCue(new Cue(caption.startTime + this.timestampOffset, caption.endTime + this.timestampOffset, caption.text)); }, sourceHandler); } if (metadataArray) { metadataArray.forEach(function (metadata) { var time = metadata.cueTime + this.timestampOffset; metadata.frames.forEach(function (frame) { var cue = new Cue(time, time, frame.value || frame.url || frame.data || ''); cue.frame = frame; cue.value = frame; deprecateOldCue(cue); this.metadataTrack_.addCue(cue); }, this); }, sourceHandler); } }; exports['default'] = addTextTrackData; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{}],21:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var createTextTracksIfNecessary = function createTextTracksIfNecessary(sourceBuffer, mediaSource, segment) { // create an in-band caption track if one is present in the segment if (segment.captions && segment.captions.length && !sourceBuffer.inbandTextTrack_) { sourceBuffer.inbandTextTrack_ = mediaSource.player_.addTextTrack('captions', 'cc1'); } if (segment.metadata && segment.metadata.length && !sourceBuffer.metadataTrack_) { sourceBuffer.metadataTrack_ = mediaSource.player_.addTextTrack('metadata', 'Timed Metadata'); sourceBuffer.metadataTrack_.inBandMetadataTrackDispatchType = segment.metadata.dispatchType; } }; exports['default'] = createTextTracksIfNecessary; module.exports = exports['default']; },{}],22:[function(require,module,exports){ /** * The maximum size in bytes for append operations to the video.js * SWF. Calling through to Flash blocks and can be expensive so * tuning this parameter may improve playback on slower * systems. There are two factors to consider: * - Each interaction with the SWF must be quick or you risk dropping * video frames. To maintain 60fps for the rest of the page, each append * must not take longer than 16ms. Given the likelihood that the page * will be executing more javascript than just playback, you probably * want to aim for less than 8ms. We aim for just 4ms. * - Bigger appends significantly increase throughput. The total number of * bytes over time delivered to the SWF must exceed the video bitrate or * playback will stall. * * We adaptively tune the size of appends to give the best throughput * possible given the performance of the system. To do that we try to append * as much as possible in TIME_PER_TICK and while tuning the size of appends * dynamically so that we only append about 4-times in that 4ms span. * * The reason we try to keep the number of appends around four is due to * externalities such as Flash load and garbage collection that are highly * variable and having 4 iterations allows us to exit the loop early if * an iteration takes longer than expected. */ "use strict"; Object.defineProperty(exports, "__esModule", { value: true }); var flashConstants = { TIME_BETWEEN_TICKS: Math.floor(1000 / 480), TIME_PER_TICK: Math.floor(1000 / 240), // 1kb BYTES_PER_CHUNK: 1 * 1024, MIN_CHUNK: 1024, MAX_CHUNK: 1024 * 1024 }; exports["default"] = flashConstants; module.exports = exports["default"]; },{}],23:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var _flashSourceBuffer = require('./flash-source-buffer'); var _flashSourceBuffer2 = _interopRequireDefault(_flashSourceBuffer); var _flashConstants = require('./flash-constants'); var _flashConstants2 = _interopRequireDefault(_flashConstants); var FlashMediaSource = (function (_videojs$EventTarget) { _inherits(FlashMediaSource, _videojs$EventTarget); function FlashMediaSource() { var _this = this; _classCallCheck(this, FlashMediaSource); _get(Object.getPrototypeOf(FlashMediaSource.prototype), 'constructor', this).call(this); this.sourceBuffers = []; this.readyState = 'closed'; this.on(['sourceopen', 'webkitsourceopen'], function (event) { // find the swf where we will push media data _this.swfObj = document.getElementById(event.swfId); _this.player_ = (0, _videoJs2['default'])(_this.swfObj.parentNode); _this.tech_ = _this.swfObj.tech; _this.readyState = 'open'; _this.tech_.on('seeking', function () { var i = _this.sourceBuffers.length; while (i--) { _this.sourceBuffers[i].abort(); } }); // trigger load events if (_this.swfObj) { _this.swfObj.vjs_load(); } }); } /** * Set or return the presentation duration. * @param value {double} the duration of the media in seconds * @param {double} the current presentation duration * @see http://www.w3.org/TR/media-source/#widl-MediaSource-duration */ _createClass(FlashMediaSource, [{ key: 'addSeekableRange_', value: function addSeekableRange_() {} // intentional no-op // create a new source buffer to receive a type of media data }, { key: 'addSourceBuffer', value: function addSourceBuffer(type) { var sourceBuffer = undefined; // if this is an FLV type, we'll push data to flash if (type.indexOf('video/mp2t') === 0) { // Flash source buffers sourceBuffer = new _flashSourceBuffer2['default'](this); } else { throw new Error('NotSupportedError (Video.js)'); } this.sourceBuffers.push(sourceBuffer); return sourceBuffer; } /* eslint-disable max-len */ /** * Signals the end of the stream. * @param error {string} (optional) Signals that a playback error * has occurred. If specified, it must be either "network" or * "decode". * @see https://w3c.github.io/media-source/#widl-MediaSource-endOfStream-void-EndOfStreamError-error */ /* eslint-enable max-len */ }, { key: 'endOfStream', value: function endOfStream(error) { if (error === 'network') { // MEDIA_ERR_NETWORK this.tech_.error(2); } else if (error === 'decode') { // MEDIA_ERR_DECODE this.tech_.error(3); } if (this.readyState !== 'ended') { this.readyState = 'ended'; this.swfObj.vjs_endOfStream(); } } }]); return FlashMediaSource; })(_videoJs2['default'].EventTarget); exports['default'] = FlashMediaSource; try { Object.defineProperty(FlashMediaSource.prototype, 'duration', { get: function get() { if (!this.swfObj) { return NaN; } // get the current duration from the SWF return this.swfObj.vjs_getProperty('duration'); }, set: function set(value) { var i = undefined; var oldDuration = this.swfObj.vjs_getProperty('duration'); this.swfObj.vjs_setProperty('duration', value); if (value < oldDuration) { // In MSE, this triggers the range removal algorithm which causes // an update to occur for (i = 0; i < this.sourceBuffers.length; i++) { this.sourceBuffers[i].remove(value, oldDuration); } } return value; } }); } catch (e) { // IE8 throws if defineProperty is called on a non-DOM node. We // don't support IE8 but we shouldn't throw an error if loaded // there. FlashMediaSource.prototype.duration = NaN; } for (var property in _flashConstants2['default']) { FlashMediaSource[property] = _flashConstants2['default'][property]; } module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./flash-constants":22,"./flash-source-buffer":24}],24:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var _muxJs = require('mux.js'); var _muxJs2 = _interopRequireDefault(_muxJs); var _removeCuesFromTrack = require('./remove-cues-from-track'); var _removeCuesFromTrack2 = _interopRequireDefault(_removeCuesFromTrack); var _createTextTracksIfNecessary = require('./create-text-tracks-if-necessary'); var _createTextTracksIfNecessary2 = _interopRequireDefault(_createTextTracksIfNecessary); var _addTextTrackData = require('./add-text-track-data'); var _addTextTrackData2 = _interopRequireDefault(_addTextTrackData); var _flashConstants = require('./flash-constants'); var _flashConstants2 = _interopRequireDefault(_flashConstants); var scheduleTick = function scheduleTick(func) { // Chrome doesn't invoke requestAnimationFrame callbacks // in background tabs, so use setTimeout. window.setTimeout(func, _flashConstants2['default'].TIME_BETWEEN_TICKS); }; // Source Buffer var FlashSourceBuffer = (function (_videojs$EventTarget) { _inherits(FlashSourceBuffer, _videojs$EventTarget); function FlashSourceBuffer(mediaSource) { var _this = this; _classCallCheck(this, FlashSourceBuffer); _get(Object.getPrototypeOf(FlashSourceBuffer.prototype), 'constructor', this).call(this); var encodedHeader = undefined; // Start off using the globally defined value but refine // as we append data into flash this.chunkSize_ = _flashConstants2['default'].BYTES_PER_CHUNK; // byte arrays queued to be appended this.buffer_ = []; // the total number of queued bytes this.bufferSize_ = 0; // to be able to determine the correct position to seek to, we // need to retain information about the mapping between the // media timeline and PTS values this.basePtsOffset_ = NaN; this.mediaSource = mediaSource; // indicates whether the asynchronous continuation of an operation // is still being processed // see https://w3c.github.io/media-source/#widl-SourceBuffer-updating this.updating = false; this.timestampOffset_ = 0; // TS to FLV transmuxer this.segmentParser_ = new _muxJs2['default'].flv.Transmuxer(); this.segmentParser_.on('data', this.receiveBuffer_.bind(this)); encodedHeader = window.btoa(String.fromCharCode.apply(null, Array.prototype.slice.call(this.segmentParser_.getFlvHeader()))); this.mediaSource.swfObj.vjs_appendBuffer(encodedHeader); Object.defineProperty(this, 'timestampOffset', { get: function get() { return this.timestampOffset_; }, set: function set(val) { if (typeof val === 'number' && val >= 0) { this.timestampOffset_ = val; this.segmentParser_ = new _muxJs2['default'].flv.Transmuxer(); this.segmentParser_.on('data', this.receiveBuffer_.bind(this)); // We have to tell flash to expect a discontinuity this.mediaSource.swfObj.vjs_discontinuity(); // the media <-> PTS mapping must be re-established after // the discontinuity this.basePtsOffset_ = NaN; } } }); Object.defineProperty(this, 'buffered', { get: function get() { return _videoJs2['default'].createTimeRanges(this.mediaSource.swfObj.vjs_getProperty('buffered')); } }); // On a seek we remove all text track data since flash has no concept // of a buffered-range and everything else is reset on seek this.mediaSource.player_.on('seeked', function () { (0, _removeCuesFromTrack2['default'])(0, Infinity, _this.metadataTrack_); (0, _removeCuesFromTrack2['default'])(0, Infinity, _this.inbandTextTrack_); }); } // accept video data and pass to the video (swf) object _createClass(FlashSourceBuffer, [{ key: 'appendBuffer', value: function appendBuffer(bytes) { var _this2 = this; var error = undefined; var chunk = 512 * 1024; var i = 0; if (this.updating) { error = new Error('SourceBuffer.append() cannot be called ' + 'while an update is in progress'); error.name = 'InvalidStateError'; error.code = 11; throw error; } this.updating = true; this.mediaSource.readyState = 'open'; this.trigger({ type: 'update' }); // this is here to use recursion var chunkInData = function chunkInData() { _this2.segmentParser_.push(bytes.subarray(i, i + chunk)); i += chunk; if (i < bytes.byteLength) { scheduleTick(chunkInData); } else { scheduleTick(_this2.segmentParser_.flush.bind(_this2.segmentParser_)); } }; chunkInData(); } // reset the parser and remove any data queued to be sent to the swf }, { key: 'abort', value: function abort() { this.buffer_ = []; this.bufferSize_ = 0; this.mediaSource.swfObj.vjs_abort(); // report any outstanding updates have ended if (this.updating) { this.updating = false; this.trigger({ type: 'updateend' }); } } // Flash cannot remove ranges already buffered in the NetStream // but seeking clears the buffer entirely. For most purposes, // having this operation act as a no-op is acceptable. }, { key: 'remove', value: function remove(start, end) { (0, _removeCuesFromTrack2['default'])(start, end, this.metadataTrack_); (0, _removeCuesFromTrack2['default'])(start, end, this.inbandTextTrack_); this.trigger({ type: 'update' }); this.trigger({ type: 'updateend' }); } }, { key: 'receiveBuffer_', value: function receiveBuffer_(segment) { var _this3 = this; // create an in-band caption track if one is present in the segment (0, _createTextTracksIfNecessary2['default'])(this, this.mediaSource, segment); (0, _addTextTrackData2['default'])(this, segment.captions, segment.metadata); // Do this asynchronously since convertTagsToData_ can be time consuming scheduleTick(function () { var flvBytes = _this3.convertTagsToData_(segment); if (_this3.buffer_.length === 0) { scheduleTick(_this3.processBuffer_.bind(_this3)); } if (flvBytes) { _this3.buffer_.push(flvBytes); _this3.bufferSize_ += flvBytes.byteLength; } }); } // append a portion of the current buffer to the SWF }, { key: 'processBuffer_', value: function processBuffer_() { var chunk = undefined; var i = undefined; var length = undefined; var binary = undefined; var b64str = undefined; var startByte = 0; var appendIterations = 0; var startTime = +new Date(); var appendTime = undefined; if (!this.buffer_.length) { if (this.updating !== false) { this.updating = false; this.trigger({ type: 'updateend' }); } // do nothing if the buffer is empty return; } do { appendIterations++; // concatenate appends up to the max append size chunk = this.buffer_[0].subarray(startByte, startByte + this.chunkSize_); // requeue any bytes that won't make it this round if (chunk.byteLength < this.chunkSize_ || this.buffer_[0].byteLength === startByte + this.chunkSize_) { startByte = 0; this.buffer_.shift(); } else { startByte += this.chunkSize_; } this.bufferSize_ -= chunk.byteLength; // base64 encode the bytes binary = ''; length = chunk.byteLength; for (i = 0; i < length; i++) { binary += String.fromCharCode(chunk[i]); } b64str = window.btoa(binary); // bypass normal ExternalInterface calls and pass xml directly // IE can be slow by default this.mediaSource.swfObj.CallFunction('' + b64str + ''); appendTime = new Date() - startTime; } while (this.buffer_.length && appendTime < _flashConstants2['default'].TIME_PER_TICK); if (this.buffer_.length && startByte) { this.buffer_[0] = this.buffer_[0].subarray(startByte); } if (appendTime >= _flashConstants2['default'].TIME_PER_TICK) { // We want to target 4 iterations per time-slot so that gives us // room to adjust to changes in Flash load and other externalities // such as garbage collection while still maximizing throughput this.chunkSize_ = Math.floor(this.chunkSize_ * (appendIterations / 4)); } // We also make sure that the chunk-size doesn't drop below 1KB or // go above 1MB as a sanity check this.chunkSize_ = Math.max(_flashConstants2['default'].MIN_CHUNK, Math.min(this.chunkSize_, _flashConstants2['default'].MAX_CHUNK)); // schedule another append if necessary if (this.bufferSize_ !== 0) { scheduleTick(this.processBuffer_.bind(this)); } else { this.updating = false; this.trigger({ type: 'updateend' }); } } // Turns an array of flv tags into a Uint8Array representing the // flv data. Also removes any tags that are before the current // time so that playback begins at or slightly after the right // place on a seek }, { key: 'convertTagsToData_', value: function convertTagsToData_(segmentData) { var segmentByteLength = 0; var tech = this.mediaSource.tech_; var targetPts = 0; var i = undefined; var j = undefined; var segment = undefined; var filteredTags = []; var tags = this.getOrderedTags_(segmentData); // Establish the media timeline to PTS translation if we don't // have one already if (isNaN(this.basePtsOffset_) && tags.length) { this.basePtsOffset_ = tags[0].pts; } // Trim any tags that are before the end of the end of // the current buffer if (tech.buffered().length) { targetPts = tech.buffered().end(0) - this.timestampOffset; } // Trim to currentTime if it's ahead of buffered or buffered doesn't exist targetPts = Math.max(targetPts, tech.currentTime() - this.timestampOffset); // PTS values are represented in milliseconds targetPts *= 1e3; targetPts += this.basePtsOffset_; // skip tags with a presentation time less than the seek target for (i = 0; i < tags.length; i++) { if (tags[i].pts >= targetPts) { filteredTags.push(tags[i]); } } if (filteredTags.length === 0) { return; } // concatenate the bytes into a single segment for (i = 0; i < filteredTags.length; i++) { segmentByteLength += filteredTags[i].bytes.byteLength; } segment = new Uint8Array(segmentByteLength); for (i = 0, j = 0; i < filteredTags.length; i++) { segment.set(filteredTags[i].bytes, j); j += filteredTags[i].bytes.byteLength; } return segment; } // assemble the FLV tags in decoder order }, { key: 'getOrderedTags_', value: function getOrderedTags_(segmentData) { var videoTags = segmentData.tags.videoTags; var audioTags = segmentData.tags.audioTags; var tag = undefined; var tags = []; while (videoTags.length || audioTags.length) { if (!videoTags.length) { // only audio tags remain tag = audioTags.shift(); } else if (!audioTags.length) { // only video tags remain tag = videoTags.shift(); } else if (audioTags[0].dts < videoTags[0].dts) { // audio should be decoded next tag = audioTags.shift(); } else { // video should be decoded next tag = videoTags.shift(); } tags.push(tag.finalize()); } return tags; } }]); return FlashSourceBuffer; })(_videoJs2['default'].EventTarget); exports['default'] = FlashSourceBuffer; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./add-text-track-data":20,"./create-text-tracks-if-necessary":21,"./flash-constants":22,"./remove-cues-from-track":26,"mux.js":37}],25:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var _virtualSourceBuffer = require('./virtual-source-buffer'); var _virtualSourceBuffer2 = _interopRequireDefault(_virtualSourceBuffer); // Replace the old apple-style `avc1.

.

` codec string with the standard // `avc1.` var translateLegacyCodecs = function translateLegacyCodecs(codecs) { return codecs.replace(/avc1\.(\d+)\.(\d+)/i, function (orig, profile, avcLevel) { var profileHex = ('00' + Number(profile).toString(16)).slice(-2); var avcLevelHex = ('00' + Number(avcLevel).toString(16)).slice(-2); return 'avc1.' + profileHex + '00' + avcLevelHex; }); }; var HtmlMediaSource = (function (_videojs$EventTarget) { _inherits(HtmlMediaSource, _videojs$EventTarget); function HtmlMediaSource() { _classCallCheck(this, HtmlMediaSource); _get(Object.getPrototypeOf(HtmlMediaSource.prototype), 'constructor', this).call(this, _videoJs2['default'].EventTarget); /* eslint-disable consistent-this */ var self = this; /* eslint-enable consistent-this */ var property = undefined; this.mediaSource_ = new window.MediaSource(); // delegate to the native MediaSource's methods by default for (property in this.mediaSource_) { if (!(property in HtmlMediaSource.prototype) && typeof this.mediaSource_[property] === 'function') { this[property] = this.mediaSource_[property].bind(this.mediaSource_); } } // emulate `duration` and `seekable` until seeking can be // handled uniformly for live streams // see https://github.com/w3c/media-source/issues/5 this.duration_ = NaN; Object.defineProperty(this, 'duration', { get: function get() { if (self.duration_ === Infinity) { return self.duration_; } return self.mediaSource_.duration; }, set: function set(duration) { self.duration_ = duration; if (duration !== Infinity) { self.mediaSource_.duration = duration; return; } } }); Object.defineProperty(this, 'seekable', { get: function get() { if (this.duration_ === Infinity) { return _videoJs2['default'].createTimeRanges([[0, self.mediaSource_.duration]]); } return self.mediaSource_.seekable; } }); Object.defineProperty(this, 'readyState', { get: function get() { return self.mediaSource_.readyState; } }); // the list of virtual and native SourceBuffers created by this // MediaSource this.sourceBuffers = []; // Re-emit MediaSource events on the polyfill ['sourceopen', 'sourceclose', 'sourceended'].forEach(function (eventName) { this.mediaSource_.addEventListener(eventName, this.trigger.bind(this)); }, this); // capture the associated player when the MediaSource is // successfully attached this.on('sourceopen', function (event) { var video = document.querySelector('[src="' + self.url_ + '"]'); if (!video) { return; } self.player_ = (0, _videoJs2['default'])(video.parentNode); }); // explicitly terminate any WebWorkers that were created // by SourceHandlers this.on('sourceclose', function (event) { this.sourceBuffers.forEach(function (sourceBuffer) { if (sourceBuffer.transmuxer_) { sourceBuffer.transmuxer_.terminate(); } }); this.sourceBuffers.length = 0; }); } _createClass(HtmlMediaSource, [{ key: 'addSeekableRange_', value: function addSeekableRange_(start, end) { var error = undefined; if (this.duration !== Infinity) { error = new Error('MediaSource.addSeekableRange() can only be invoked ' + 'when the duration is Infinity'); error.name = 'InvalidStateError'; error.code = 11; throw error; } if (end > this.mediaSource_.duration || isNaN(this.mediaSource_.duration)) { this.mediaSource_.duration = end; } } }, { key: 'addSourceBuffer', value: function addSourceBuffer(type) { var buffer = undefined; var codecs = undefined; var avcCodec = undefined; var mp4aCodec = undefined; var avcRegEx = /avc1\.[\da-f]+/i; var mp4aRegEx = /mp4a\.\d+.\d+/i; // create a virtual source buffer to transmux MPEG-2 transport // stream segments into fragmented MP4s if (/^video\/mp2t/i.test(type)) { codecs = type.split(';').slice(1).join(';'); codecs = translateLegacyCodecs(codecs); // Pull out each individual codec string if it exists avcCodec = (codecs.match(avcRegEx) || [])[0]; mp4aCodec = (codecs.match(mp4aRegEx) || [])[0]; // If a codec is unspecified, use the defaults if (!avcCodec || !avcCodec.length) { avcCodec = 'avc1.4d400d'; } if (!mp4aCodec || !mp4aCodec.length) { mp4aCodec = 'mp4a.40.2'; } buffer = new _virtualSourceBuffer2['default'](this, [avcCodec, mp4aCodec]); this.sourceBuffers.push(buffer); return buffer; } // delegate to the native implementation buffer = this.mediaSource_.addSourceBuffer(type); this.sourceBuffers.push(buffer); return buffer; } }]); return HtmlMediaSource; })(_videoJs2['default'].EventTarget); exports['default'] = HtmlMediaSource; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./virtual-source-buffer":29}],26:[function(require,module,exports){ "use strict"; Object.defineProperty(exports, "__esModule", { value: true }); var removeCuesFromTrack = function removeCuesFromTrack(start, end, track) { var i = undefined; var cue = undefined; if (!track) { return; } i = track.cues.length; while (i--) { cue = track.cues[i]; // Remove any overlapping cue if (cue.startTime <= end && cue.endTime >= start) { track.removeCue(cue); } } }; exports["default"] = removeCuesFromTrack; module.exports = exports["default"]; },{}],27:[function(require,module,exports){ /** * videojs-contrib-media-sources * * Copyright (c) 2015 Brightcove * All rights reserved. * * Handles communication between the browser-world and the mux.js * transmuxer running inside of a WebWorker by exposing a simple * message-based interface to a Transmuxer object. */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _muxJs = require('mux.js'); var _muxJs2 = _interopRequireDefault(_muxJs); var globalTransmuxer = undefined; var initOptions = {}; /** * wireTransmuxerEvents * Re-emits tranmsuxer events by converting them into messages to the * world outside the worker */ var wireTransmuxerEvents = function wireTransmuxerEvents(transmuxer) { transmuxer.on('data', function (segment) { // transfer ownership of the underlying ArrayBuffer // instead of doing a copy to save memory // ArrayBuffers are transferable but generic TypedArrays are not /* eslint-disable max-len */ // see https://developer.mozilla.org/en-US/docs/Web/API/Web_Workers_API/Using_web_workers#Passing_data_by_transferring_ownership_(transferable_objects) /* eslint-enable max-len */ var typedArray = segment.data; segment.data = typedArray.buffer; postMessage({ action: 'data', segment: segment, byteOffset: typedArray.byteOffset, byteLength: typedArray.byteLength }, [segment.data]); }); if (transmuxer.captionStream) { transmuxer.captionStream.on('data', function (caption) { postMessage({ action: 'caption', data: caption }); }); } transmuxer.on('done', function (data) { postMessage({ action: 'done' }); }); }; /** * All incoming messages route through this hash. If no function exists * to handle an incoming message, then we ignore the message. */ var messageHandlers = { /** * init * Allows you to initialize the transmuxer and pass along options from * outside the worker */ init: function init(data) { initOptions = data && data.options || {}; this.defaultInit(); }, /** * defaultInit * Is called before every function and initializes the transmuxer with * default options if `init` was never explicitly called */ defaultInit: function defaultInit() { if (globalTransmuxer) { globalTransmuxer.dispose(); } globalTransmuxer = new _muxJs2['default'].mp4.Transmuxer(initOptions); wireTransmuxerEvents(globalTransmuxer); }, /** * push * Adds data (a ts segment) to the start of the transmuxer pipeline for * processing */ push: function push(data) { // Cast array buffer to correct type for transmuxer var segment = new Uint8Array(data.data, data.byteOffset, data.byteLength); globalTransmuxer.push(segment); }, /** * reset * Recreate the transmuxer so that the next segment added via `push` * start with a fresh transmuxer */ reset: function reset() { this.defaultInit(); }, /** * setTimestampOffset * Set the value that will be used as the `baseMediaDecodeTime` time for the * next segment pushed in. Subsequent segments will have their `baseMediaDecodeTime` * set relative to the first based on the PTS values. */ setTimestampOffset: function setTimestampOffset(data) { var timestampOffset = data.timestampOffset || 0; globalTransmuxer.setBaseMediaDecodeTime(Math.round(timestampOffset * 90000)); }, /** * flush * Forces the pipeline to finish processing the last segment and emit it's * results */ flush: function flush(data) { globalTransmuxer.flush(); } }; var Worker = function Worker(self) { self.onmessage = function (event) { // Setup the default transmuxer if one doesn't exist yet and we are invoked with // an action other than `init` if (!globalTransmuxer && event.data.action !== 'init') { messageHandlers.defaultInit(); } if (event.data && event.data.action) { if (messageHandlers[event.data.action]) { messageHandlers[event.data.action](event.data); } } }; }; exports['default'] = Worker; module.exports = exports['default']; },{"mux.js":37}],28:[function(require,module,exports){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } var _flashMediaSource = require('./flash-media-source'); var _flashMediaSource2 = _interopRequireDefault(_flashMediaSource); var _htmlMediaSource = require('./html-media-source'); var _htmlMediaSource2 = _interopRequireDefault(_htmlMediaSource); // import videojs from 'video.js'; var videojs = window.videojs; var urlCount = 0; // ------------ // Media Source // ------------ var defaults = { // how to determine the MediaSource implementation to use. There // are three available modes: // - auto: use native MediaSources where available and Flash // everywhere else // - html5: always use native MediaSources // - flash: always use the Flash MediaSource polyfill mode: 'auto' }; // store references to the media sources so they can be connected // to a video element (a swf object) videojs.mediaSources = {}; // provide a method for a swf object to notify JS that a media source is now open var open = function open(msObjectURL, swfId) { var mediaSource = videojs.mediaSources[msObjectURL]; if (mediaSource) { mediaSource.trigger({ type: 'sourceopen', swfId: swfId }); } else { throw new Error('Media Source not found (Video.js)'); } }; // Check to see if the native MediaSource object exists and supports // an MP4 container with both H.264 video and AAC-LC audio var supportsNativeMediaSources = function supportsNativeMediaSources() { return !!window.MediaSource && window.MediaSource.isTypeSupported('video/mp4;codecs="avc1.4d400d,mp4a.40.2"'); }; var MediaSource = function MediaSource(options) { var settings = videojs.mergeOptions(defaults, options); this.MediaSource = { open: open, supportsNativeMediaSources: supportsNativeMediaSources }; // determine whether HTML MediaSources should be used if (settings.mode === 'html5' || settings.mode === 'auto' && supportsNativeMediaSources()) { return new _htmlMediaSource2['default'](); } // otherwise, emulate them through the SWF return new _flashMediaSource2['default'](); }; exports.MediaSource = MediaSource; MediaSource.open = open; MediaSource.supportsNativeMediaSources = supportsNativeMediaSources; var URL = { createObjectURL: function createObjectURL(object) { var objectUrlPrefix = 'blob:vjs-media-source/'; var url = undefined; // use the native MediaSource to generate an object URL if (object instanceof _htmlMediaSource2['default']) { url = window.URL.createObjectURL(object.mediaSource_); object.url_ = url; return url; } // if the object isn't an emulated MediaSource, delegate to the // native implementation if (!(object instanceof _flashMediaSource2['default'])) { url = window.URL.createObjectURL(object); object.url_ = url; return url; } // build a URL that can be used to map back to the emulated // MediaSource url = objectUrlPrefix + urlCount; urlCount++; // setup the mapping back to object videojs.mediaSources[url] = object; return url; } }; exports.URL = URL; videojs.MediaSource = MediaSource; videojs.URL = URL; },{"./flash-media-source":23,"./html-media-source":25}],29:[function(require,module,exports){ (function (global){ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var _createTextTracksIfNecessary = require('./create-text-tracks-if-necessary'); var _createTextTracksIfNecessary2 = _interopRequireDefault(_createTextTracksIfNecessary); var _removeCuesFromTrack = require('./remove-cues-from-track'); var _removeCuesFromTrack2 = _interopRequireDefault(_removeCuesFromTrack); var _addTextTrackData = require('./add-text-track-data'); var _addTextTrackData2 = _interopRequireDefault(_addTextTrackData); var _webworkify = require('webworkify'); var _webworkify2 = _interopRequireDefault(_webworkify); var _transmuxerWorker = require('./transmuxer-worker'); var _transmuxerWorker2 = _interopRequireDefault(_transmuxerWorker); var aggregateUpdateHandler = function aggregateUpdateHandler(mediaSource, guardBufferName, type) { return function () { if (!mediaSource[guardBufferName] || !mediaSource[guardBufferName].updating) { return mediaSource.trigger(type); } }; }; var VirtualSourceBuffer = (function (_videojs$EventTarget) { _inherits(VirtualSourceBuffer, _videojs$EventTarget); function VirtualSourceBuffer(mediaSource, codecs) { var _this = this; _classCallCheck(this, VirtualSourceBuffer); _get(Object.getPrototypeOf(VirtualSourceBuffer.prototype), 'constructor', this).call(this, _videoJs2['default'].EventTarget); this.timestampOffset_ = 0; this.pendingBuffers_ = []; this.bufferUpdating_ = false; this.mediaSource_ = mediaSource; this.codecs_ = codecs; // append muxed segments to their respective native buffers as // soon as they are available this.transmuxer_ = (0, _webworkify2['default'])(_transmuxerWorker2['default']); this.transmuxer_.postMessage({ action: 'init', options: { remux: false } }); this.transmuxer_.onmessage = function (event) { if (event.data.action === 'data') { return _this.data_(event); } if (event.data.action === 'done') { return _this.done_(event); } }; // this timestampOffset is a property with the side-effect of resetting // baseMediaDecodeTime in the transmuxer on the setter Object.defineProperty(this, 'timestampOffset', { get: function get() { return this.timestampOffset_; }, set: function set(val) { if (typeof val === 'number' && val >= 0) { this.timestampOffset_ = val; // We have to tell the transmuxer to set the baseMediaDecodeTime to // the desired timestampOffset for the next segment this.transmuxer_.postMessage({ action: 'setTimestampOffset', timestampOffset: val }); } } }); // setting the append window affects both source buffers Object.defineProperty(this, 'appendWindowStart', { get: function get() { return (this.videoBuffer_ || this.audioBuffer_).appendWindowStart; }, set: function set(start) { if (this.videoBuffer_) { this.videoBuffer_.appendWindowStart = start; } if (this.audioBuffer_) { this.audioBuffer_.appendWindowStart = start; } } }); // this buffer is "updating" if either of its native buffers are Object.defineProperty(this, 'updating', { get: function get() { return this.bufferUpdating_ || this.audioBuffer_ && this.audioBuffer_.updating || this.videoBuffer_ && this.videoBuffer_.updating; } }); // the buffered property is the intersection of the buffered // ranges of the native source buffers Object.defineProperty(this, 'buffered', { get: function get() { var start = null; var end = null; var arity = 0; var extents = []; var ranges = []; // Handle the case where there is no buffer data if ((!this.videoBuffer_ || this.videoBuffer_.buffered.length === 0) && (!this.audioBuffer_ || this.audioBuffer_.buffered.length === 0)) { return _videoJs2['default'].createTimeRange(); } // Handle the case where we only have one buffer if (!this.videoBuffer_) { return this.audioBuffer_.buffered; } else if (!this.audioBuffer_) { return this.videoBuffer_.buffered; } // Handle the case where we have both buffers and create an // intersection of the two var videoBuffered = this.videoBuffer_.buffered; var audioBuffered = this.audioBuffer_.buffered; var count = videoBuffered.length; // A) Gather up all start and end times while (count--) { extents.push({ time: videoBuffered.start(count), type: 'start' }); extents.push({ time: videoBuffered.end(count), type: 'end' }); } count = audioBuffered.length; while (count--) { extents.push({ time: audioBuffered.start(count), type: 'start' }); extents.push({ time: audioBuffered.end(count), type: 'end' }); } // B) Sort them by time extents.sort(function (a, b) { return a.time - b.time; }); // C) Go along one by one incrementing arity for start and decrementing // arity for ends for (count = 0; count < extents.length; count++) { if (extents[count].type === 'start') { arity++; // D) If arity is ever incremented to 2 we are entering an // overlapping range if (arity === 2) { start = extents[count].time; } } else if (extents[count].type === 'end') { arity--; // E) If arity is ever decremented to 1 we leaving an // overlapping range if (arity === 1) { end = extents[count].time; } } // F) Record overlapping ranges if (start !== null && end !== null) { ranges.push([start, end]); start = null; end = null; } } return _videoJs2['default'].createTimeRanges(ranges); } }); } // Transmuxer message handlers _createClass(VirtualSourceBuffer, [{ key: 'data_', value: function data_(event) { var segment = event.data.segment; var nativeMediaSource = this.mediaSource_.mediaSource_; // Cast ArrayBuffer to TypedArray segment.data = new Uint8Array(segment.data, event.data.byteOffset, event.data.byteLength); // If any sourceBuffers have not been created, do so now if (segment.type === 'video') { if (!this.videoBuffer_) { this.videoBuffer_ = nativeMediaSource.addSourceBuffer('video/mp4;codecs="' + this.codecs_[0] + '"'); // aggregate buffer events this.videoBuffer_.addEventListener('updatestart', aggregateUpdateHandler(this, 'audioBuffer_', 'updatestart')); this.videoBuffer_.addEventListener('update', aggregateUpdateHandler(this, 'audioBuffer_', 'update')); this.videoBuffer_.addEventListener('updateend', aggregateUpdateHandler(this, 'audioBuffer_', 'updateend')); } } else if (segment.type === 'audio') { if (!this.audioBuffer_) { this.audioBuffer_ = nativeMediaSource.addSourceBuffer('audio/mp4;codecs="' + this.codecs_[1] + '"'); // aggregate buffer events this.audioBuffer_.addEventListener('updatestart', aggregateUpdateHandler(this, 'videoBuffer_', 'updatestart')); this.audioBuffer_.addEventListener('update', aggregateUpdateHandler(this, 'videoBuffer_', 'update')); this.audioBuffer_.addEventListener('updateend', aggregateUpdateHandler(this, 'videoBuffer_', 'updateend')); } } else if (segment.type === 'combined') { if (!this.videoBuffer_) { this.videoBuffer_ = nativeMediaSource.addSourceBuffer('video/mp4;codecs="' + this.codecs_.join(',') + '"'); // aggregate buffer events this.videoBuffer_.addEventListener('updatestart', aggregateUpdateHandler(this, 'videoBuffer_', 'updatestart')); this.videoBuffer_.addEventListener('update', aggregateUpdateHandler(this, 'videoBuffer_', 'update')); this.videoBuffer_.addEventListener('updateend', aggregateUpdateHandler(this, 'videoBuffer_', 'updateend')); } } (0, _createTextTracksIfNecessary2['default'])(this, this.mediaSource_, segment); // Add the segments to the pendingBuffers array this.pendingBuffers_.push(segment); return; } }, { key: 'done_', value: function done_() { // All buffers should have been flushed from the muxer // start processing anything we have received this.processPendingSegments_(); return; } // SourceBuffer Implementation }, { key: 'appendBuffer', value: function appendBuffer(segment) { // Start the internal "updating" state this.bufferUpdating_ = true; this.transmuxer_.postMessage({ action: 'push', // Send the typed-array of data as an ArrayBuffer so that // it can be sent as a "Transferable" and avoid the costly // memory copy data: segment.buffer, // To recreate the original typed-array, we need information // about what portion of the ArrayBuffer it was a view into byteOffset: segment.byteOffset, byteLength: segment.byteLength }, [segment.buffer]); this.transmuxer_.postMessage({ action: 'flush' }); } }, { key: 'remove', value: function remove(start, end) { if (this.videoBuffer_) { this.videoBuffer_.remove(start, end); } if (this.audioBuffer_) { this.audioBuffer_.remove(start, end); } // Remove Metadata Cues (id3) (0, _removeCuesFromTrack2['default'])(start, end, this.metadataTrack_); // Remove Any Captions (0, _removeCuesFromTrack2['default'])(start, end, this.inbandTextTrack_); } /** * Process any segments that the muxer has output * Concatenate segments together based on type and append them into * their respective sourceBuffers */ }, { key: 'processPendingSegments_', value: function processPendingSegments_() { var sortedSegments = { video: { segments: [], bytes: 0 }, audio: { segments: [], bytes: 0 }, captions: [], metadata: [] }; // Sort segments into separate video/audio arrays and // keep track of their total byte lengths sortedSegments = this.pendingBuffers_.reduce(function (segmentObj, segment) { var type = segment.type; var data = segment.data; // A "combined" segment type (unified video/audio) uses the videoBuffer if (type === 'combined') { type = 'video'; } segmentObj[type].segments.push(data); segmentObj[type].bytes += data.byteLength; // Gather any captions into a single array if (segment.captions) { segmentObj.captions = segmentObj.captions.concat(segment.captions); } // Gather any metadata into a single array if (segment.metadata) { segmentObj.metadata = segmentObj.metadata.concat(segment.metadata); } return segmentObj; }, sortedSegments); (0, _addTextTrackData2['default'])(this, sortedSegments.captions, sortedSegments.metadata); // Merge multiple video and audio segments into one and append this.concatAndAppendSegments_(sortedSegments.video, this.videoBuffer_); this.concatAndAppendSegments_(sortedSegments.audio, this.audioBuffer_); this.pendingBuffers_.length = 0; // We are no longer in the internal "updating" state this.bufferUpdating_ = false; } /** * Combind all segments into a single Uint8Array and then append them * to the destination buffer */ }, { key: 'concatAndAppendSegments_', value: function concatAndAppendSegments_(segmentObj, destinationBuffer) { var offset = 0; var tempBuffer = undefined; if (segmentObj.bytes) { tempBuffer = new Uint8Array(segmentObj.bytes); // Combine the individual segments into one large typed-array segmentObj.segments.forEach(function (segment) { tempBuffer.set(segment, offset); offset += segment.byteLength; }); destinationBuffer.appendBuffer(tempBuffer); } } // abort any sourceBuffer actions and throw out any un-appended data }, { key: 'abort', value: function abort() { if (this.videoBuffer_) { this.videoBuffer_.abort(); } if (this.audioBuffer_) { this.audioBuffer_.abort(); } if (this.transmuxer_) { this.transmuxer_.postMessage({ action: 'reset' }); } this.pendingBuffers_.length = 0; this.bufferUpdating_ = false; } }]); return VirtualSourceBuffer; })(_videoJs2['default'].EventTarget); exports['default'] = VirtualSourceBuffer; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./add-text-track-data":20,"./create-text-tracks-if-necessary":21,"./remove-cues-from-track":26,"./transmuxer-worker":27,"webworkify":50}],30:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2016 Brightcove * All rights reserved. * * A stream-based aac to mp4 converter. This utility can be used to * deliver mp4s to a SourceBuffer on platforms that support native * Media Source Extensions. */ 'use strict'; var Stream = require('../utils/stream.js'); // Constants var AacStream; /** * Splits an incoming stream of binary data into ADTS and ID3 Frames. */ AacStream = function() { var everything, receivedTimeStamp = false, timeStamp = 0; AacStream.prototype.init.call(this); this.setTimestamp = function (timestamp) { timeStamp = timestamp; }; this.parseId3TagSize = function(header, byteIndex) { var returnSize = (header[byteIndex + 6] << 21) | (header[byteIndex + 7] << 14) | (header[byteIndex + 8] << 7) | (header[byteIndex + 9]), flags = header[byteIndex + 5], footerPresent = (flags & 16) >> 4; if (footerPresent) { return returnSize + 20; } return returnSize + 10; }; this.parseAdtsSize = function(header, byteIndex) { var lowThree = (header[byteIndex + 5] & 0xE0) >> 5, middle = header[byteIndex + 4] << 3, highTwo = header[byteIndex + 3] & 0x3 << 11; return (highTwo | middle) | lowThree; }; this.push = function(bytes) { var frameSize = 0, byteIndex = 0, chunk, packet, tempLength; // If there are bytes remaining from the last segment, prepend them to the // bytes that were pushed in if (everything !== undefined && everything.length) { tempLength = everything.length; everything = new Uint8Array(bytes.byteLength + tempLength); everything.set(everything.subarray(0, tempLength)); everything.set(bytes, tempLength); } else { everything = bytes; } while (everything.length - byteIndex >= 10) { if ((everything[byteIndex] === 'I'.charCodeAt(0)) && (everything[byteIndex + 1] === 'D'.charCodeAt(0)) && (everything[byteIndex + 2] === '3'.charCodeAt(0))) { //check framesize frameSize = this.parseId3TagSize(everything, byteIndex); //we have enough in the buffer to emit a full packet if (frameSize > everything.length) { break; } chunk = { type: 'timed-metadata', data: everything.subarray(byteIndex, byteIndex + frameSize) }; this.trigger('data', chunk); byteIndex += frameSize; continue; } else if ((everything[byteIndex] & 0xff === 0xff) && ((everything[byteIndex + 1] & 0xf0) === 0xf0)) { frameSize = this.parseAdtsSize(everything, byteIndex); if (frameSize > everything.length) { break; } packet = { type: 'audio', data: everything.subarray(byteIndex, byteIndex + frameSize), pts: timeStamp, dts: timeStamp, }; this.trigger('data', packet); byteIndex += frameSize; continue; } byteIndex++; } }; }; AacStream.prototype = new Stream(); module.exports = AacStream; },{"../utils/stream.js":49}],31:[function(require,module,exports){ 'use strict'; var Stream = require('../utils/stream.js'); var AdtsStream; var ADTS_SAMPLING_FREQUENCIES = [ 96000, 88200, 64000, 48000, 44100, 32000, 24000, 22050, 16000, 12000, 11025, 8000, 7350 ]; /* * Accepts a ElementaryStream and emits data events with parsed * AAC Audio Frames of the individual packets. Input audio in ADTS * format is unpacked and re-emitted as AAC frames. * * @see http://wiki.multimedia.cx/index.php?title=ADTS * @see http://wiki.multimedia.cx/?title=Understanding_AAC */ AdtsStream = function() { var self, buffer; AdtsStream.prototype.init.call(this); self = this; this.push = function(packet) { var i = 0, frameNum = 0, frameLength, protectionSkipBytes, frameEnd, oldBuffer, numFrames, sampleCount, adtsFrameDuration; if (packet.type !== 'audio') { // ignore non-audio data return; } // Prepend any data in the buffer to the input data so that we can parse // aac frames the cross a PES packet boundary if (buffer) { oldBuffer = buffer; buffer = new Uint8Array(oldBuffer.byteLength + packet.data.byteLength); buffer.set(oldBuffer); buffer.set(packet.data, oldBuffer.byteLength); } else { buffer = packet.data; } // unpack any ADTS frames which have been fully received // for details on the ADTS header, see http://wiki.multimedia.cx/index.php?title=ADTS while (i + 5 < buffer.length) { // Loook for the start of an ADTS header.. if (buffer[i] !== 0xFF || (buffer[i + 1] & 0xF6) !== 0xF0) { // If a valid header was not found, jump one forward and attempt to // find a valid ADTS header starting at the next byte i++; continue; } // The protection skip bit tells us if we have 2 bytes of CRC data at the // end of the ADTS header protectionSkipBytes = (~buffer[i + 1] & 0x01) * 2; // Frame length is a 13 bit integer starting 16 bits from the // end of the sync sequence frameLength = ((buffer[i + 3] & 0x03) << 11) | (buffer[i + 4] << 3) | ((buffer[i + 5] & 0xe0) >> 5); sampleCount = ((buffer[i + 6] & 0x03) + 1) * 1024; adtsFrameDuration = (sampleCount * 90000) / ADTS_SAMPLING_FREQUENCIES[(buffer[i + 2] & 0x3c) >>> 2]; frameEnd = i + frameLength; // If we don't have enough data to actually finish this ADTS frame, return // and wait for more data if (buffer.byteLength < frameEnd) { return; } // Otherwise, deliver the complete AAC frame this.trigger('data', { pts: packet.pts + (frameNum * adtsFrameDuration), dts: packet.dts + (frameNum * adtsFrameDuration), sampleCount: sampleCount, audioobjecttype: ((buffer[i + 2] >>> 6) & 0x03) + 1, channelcount: ((buffer[i + 2] & 1) << 3) | ((buffer[i + 3] & 0xc0) >>> 6), samplerate: ADTS_SAMPLING_FREQUENCIES[(buffer[i + 2] & 0x3c) >>> 2], samplingfrequencyindex: (buffer[i + 2] & 0x3c) >>> 2, // assume ISO/IEC 14496-12 AudioSampleEntry default of 16 samplesize: 16, data: buffer.subarray(i + 7 + protectionSkipBytes, frameEnd) }); // If the buffer is empty, clear it and return if (buffer.byteLength === frameEnd) { buffer = undefined; return; } frameNum++; // Remove the finished frame from the buffer and start the process again buffer = buffer.subarray(frameEnd); } }; this.flush = function() { this.trigger('done'); }; }; AdtsStream.prototype = new Stream(); module.exports = AdtsStream; },{"../utils/stream.js":49}],32:[function(require,module,exports){ 'use strict'; var Stream = require('../utils/stream.js'); var ExpGolomb = require('../utils/exp-golomb.js'); var H264Stream, NalByteStream; /** * Accepts a NAL unit byte stream and unpacks the embedded NAL units. */ NalByteStream = function() { var syncPoint = 0, i, buffer; NalByteStream.prototype.init.call(this); this.push = function(data) { var swapBuffer; if (!buffer) { buffer = data.data; } else { swapBuffer = new Uint8Array(buffer.byteLength + data.data.byteLength); swapBuffer.set(buffer); swapBuffer.set(data.data, buffer.byteLength); buffer = swapBuffer; } // Rec. ITU-T H.264, Annex B // scan for NAL unit boundaries // a match looks like this: // 0 0 1 .. NAL .. 0 0 1 // ^ sync point ^ i // or this: // 0 0 1 .. NAL .. 0 0 0 // ^ sync point ^ i // advance the sync point to a NAL start, if necessary for (; syncPoint < buffer.byteLength - 3; syncPoint++) { if (buffer[syncPoint + 2] === 1) { // the sync point is properly aligned i = syncPoint + 5; break; } } while (i < buffer.byteLength) { // look at the current byte to determine if we've hit the end of // a NAL unit boundary switch (buffer[i]) { case 0: // skip past non-sync sequences if (buffer[i - 1] !== 0) { i += 2; break; } else if (buffer[i - 2] !== 0) { i++; break; } // deliver the NAL unit this.trigger('data', buffer.subarray(syncPoint + 3, i - 2)); // drop trailing zeroes do { i++; } while (buffer[i] !== 1 && i < buffer.length); syncPoint = i - 2; i += 3; break; case 1: // skip past non-sync sequences if (buffer[i - 1] !== 0 || buffer[i - 2] !== 0) { i += 3; break; } // deliver the NAL unit this.trigger('data', buffer.subarray(syncPoint + 3, i - 2)); syncPoint = i - 2; i += 3; break; default: // the current byte isn't a one or zero, so it cannot be part // of a sync sequence i += 3; break; } } // filter out the NAL units that were delivered buffer = buffer.subarray(syncPoint); i -= syncPoint; syncPoint = 0; }; this.flush = function() { // deliver the last buffered NAL unit if (buffer && buffer.byteLength > 3) { this.trigger('data', buffer.subarray(syncPoint + 3)); } // reset the stream state buffer = null; syncPoint = 0; this.trigger('done'); }; }; NalByteStream.prototype = new Stream(); /** * Accepts input from a ElementaryStream and produces H.264 NAL unit data * events. */ H264Stream = function() { var nalByteStream = new NalByteStream(), self, trackId, currentPts, currentDts, discardEmulationPreventionBytes, readSequenceParameterSet, skipScalingList; H264Stream.prototype.init.call(this); self = this; this.push = function(packet) { if (packet.type !== 'video') { return; } trackId = packet.trackId; currentPts = packet.pts; currentDts = packet.dts; nalByteStream.push(packet); }; nalByteStream.on('data', function(data) { var event = { trackId: trackId, pts: currentPts, dts: currentDts, data: data }; switch (data[0] & 0x1f) { case 0x05: event.nalUnitType = 'slice_layer_without_partitioning_rbsp_idr'; break; case 0x06: event.nalUnitType = 'sei_rbsp'; event.escapedRBSP = discardEmulationPreventionBytes(data.subarray(1)); break; case 0x07: event.nalUnitType = 'seq_parameter_set_rbsp'; event.escapedRBSP = discardEmulationPreventionBytes(data.subarray(1)); event.config = readSequenceParameterSet(event.escapedRBSP); break; case 0x08: event.nalUnitType = 'pic_parameter_set_rbsp'; break; case 0x09: event.nalUnitType = 'access_unit_delimiter_rbsp'; break; default: break; } self.trigger('data', event); }); nalByteStream.on('done', function() { self.trigger('done'); }); this.flush = function() { nalByteStream.flush(); }; /** * Advance the ExpGolomb decoder past a scaling list. The scaling * list is optionally transmitted as part of a sequence parameter * set and is not relevant to transmuxing. * @param count {number} the number of entries in this scaling list * @param expGolombDecoder {object} an ExpGolomb pointed to the * start of a scaling list * @see Recommendation ITU-T H.264, Section 7.3.2.1.1.1 */ skipScalingList = function(count, expGolombDecoder) { var lastScale = 8, nextScale = 8, j, deltaScale; for (j = 0; j < count; j++) { if (nextScale !== 0) { deltaScale = expGolombDecoder.readExpGolomb(); nextScale = (lastScale + deltaScale + 256) % 256; } lastScale = (nextScale === 0) ? lastScale : nextScale; } }; /** * Expunge any "Emulation Prevention" bytes from a "Raw Byte * Sequence Payload" * @param data {Uint8Array} the bytes of a RBSP from a NAL * unit * @return {Uint8Array} the RBSP without any Emulation * Prevention Bytes */ discardEmulationPreventionBytes = function(data) { var length = data.byteLength, emulationPreventionBytesPositions = [], i = 1, newLength, newData; // Find all `Emulation Prevention Bytes` while (i < length - 2) { if (data[i] === 0 && data[i + 1] === 0 && data[i + 2] === 0x03) { emulationPreventionBytesPositions.push(i + 2); i += 2; } else { i++; } } // If no Emulation Prevention Bytes were found just return the original // array if (emulationPreventionBytesPositions.length === 0) { return data; } // Create a new array to hold the NAL unit data newLength = length - emulationPreventionBytesPositions.length; newData = new Uint8Array(newLength); var sourceIndex = 0; for (i = 0; i < newLength; sourceIndex++, i++) { if (sourceIndex === emulationPreventionBytesPositions[0]) { // Skip this byte sourceIndex++; // Remove this position index emulationPreventionBytesPositions.shift(); } newData[i] = data[sourceIndex]; } return newData; }; /** * Read a sequence parameter set and return some interesting video * properties. A sequence parameter set is the H264 metadata that * describes the properties of upcoming video frames. * @param data {Uint8Array} the bytes of a sequence parameter set * @return {object} an object with configuration parsed from the * sequence parameter set, including the dimensions of the * associated video frames. */ readSequenceParameterSet = function(data) { var frameCropLeftOffset = 0, frameCropRightOffset = 0, frameCropTopOffset = 0, frameCropBottomOffset = 0, expGolombDecoder, profileIdc, levelIdc, profileCompatibility, chromaFormatIdc, picOrderCntType, numRefFramesInPicOrderCntCycle, picWidthInMbsMinus1, picHeightInMapUnitsMinus1, frameMbsOnlyFlag, scalingListCount, i; expGolombDecoder = new ExpGolomb(data); profileIdc = expGolombDecoder.readUnsignedByte(); // profile_idc profileCompatibility = expGolombDecoder.readUnsignedByte(); // constraint_set[0-5]_flag levelIdc = expGolombDecoder.readUnsignedByte(); // level_idc u(8) expGolombDecoder.skipUnsignedExpGolomb(); // seq_parameter_set_id // some profiles have more optional data we don't need if (profileIdc === 100 || profileIdc === 110 || profileIdc === 122 || profileIdc === 244 || profileIdc === 44 || profileIdc === 83 || profileIdc === 86 || profileIdc === 118 || profileIdc === 128 || profileIdc === 138 || profileIdc === 139 || profileIdc === 134) { chromaFormatIdc = expGolombDecoder.readUnsignedExpGolomb(); if (chromaFormatIdc === 3) { expGolombDecoder.skipBits(1); // separate_colour_plane_flag } expGolombDecoder.skipUnsignedExpGolomb(); // bit_depth_luma_minus8 expGolombDecoder.skipUnsignedExpGolomb(); // bit_depth_chroma_minus8 expGolombDecoder.skipBits(1); // qpprime_y_zero_transform_bypass_flag if (expGolombDecoder.readBoolean()) { // seq_scaling_matrix_present_flag scalingListCount = (chromaFormatIdc !== 3) ? 8 : 12; for (i = 0; i < scalingListCount; i++) { if (expGolombDecoder.readBoolean()) { // seq_scaling_list_present_flag[ i ] if (i < 6) { skipScalingList(16, expGolombDecoder); } else { skipScalingList(64, expGolombDecoder); } } } } } expGolombDecoder.skipUnsignedExpGolomb(); // log2_max_frame_num_minus4 picOrderCntType = expGolombDecoder.readUnsignedExpGolomb(); if (picOrderCntType === 0) { expGolombDecoder.readUnsignedExpGolomb(); //log2_max_pic_order_cnt_lsb_minus4 } else if (picOrderCntType === 1) { expGolombDecoder.skipBits(1); // delta_pic_order_always_zero_flag expGolombDecoder.skipExpGolomb(); // offset_for_non_ref_pic expGolombDecoder.skipExpGolomb(); // offset_for_top_to_bottom_field numRefFramesInPicOrderCntCycle = expGolombDecoder.readUnsignedExpGolomb(); for(i = 0; i < numRefFramesInPicOrderCntCycle; i++) { expGolombDecoder.skipExpGolomb(); // offset_for_ref_frame[ i ] } } expGolombDecoder.skipUnsignedExpGolomb(); // max_num_ref_frames expGolombDecoder.skipBits(1); // gaps_in_frame_num_value_allowed_flag picWidthInMbsMinus1 = expGolombDecoder.readUnsignedExpGolomb(); picHeightInMapUnitsMinus1 = expGolombDecoder.readUnsignedExpGolomb(); frameMbsOnlyFlag = expGolombDecoder.readBits(1); if (frameMbsOnlyFlag === 0) { expGolombDecoder.skipBits(1); // mb_adaptive_frame_field_flag } expGolombDecoder.skipBits(1); // direct_8x8_inference_flag if (expGolombDecoder.readBoolean()) { // frame_cropping_flag frameCropLeftOffset = expGolombDecoder.readUnsignedExpGolomb(); frameCropRightOffset = expGolombDecoder.readUnsignedExpGolomb(); frameCropTopOffset = expGolombDecoder.readUnsignedExpGolomb(); frameCropBottomOffset = expGolombDecoder.readUnsignedExpGolomb(); } return { profileIdc: profileIdc, levelIdc: levelIdc, profileCompatibility: profileCompatibility, width: ((picWidthInMbsMinus1 + 1) * 16) - frameCropLeftOffset * 2 - frameCropRightOffset * 2, height: ((2 - frameMbsOnlyFlag) * (picHeightInMapUnitsMinus1 + 1) * 16) - (frameCropTopOffset * 2) - (frameCropBottomOffset * 2) }; }; }; H264Stream.prototype = new Stream(); module.exports = { H264Stream: H264Stream, NalByteStream: NalByteStream, }; },{"../utils/exp-golomb.js":48,"../utils/stream.js":49}],33:[function(require,module,exports){ module.exports = { adts: require('./adts'), h264: require('./h264'), }; },{"./adts":31,"./h264":32}],34:[function(require,module,exports){ /** * An object that stores the bytes of an FLV tag and methods for * querying and manipulating that data. * @see http://download.macromedia.com/f4v/video_file_format_spec_v10_1.pdf */ 'use strict'; var FlvTag; // (type:uint, extraData:Boolean = false) extends ByteArray FlvTag = function(type, extraData) { var // Counter if this is a metadata tag, nal start marker if this is a video // tag. unused if this is an audio tag adHoc = 0, // :uint // The default size is 16kb but this is not enough to hold iframe // data and the resizing algorithm costs a bit so we create a larger // starting buffer for video tags bufferStartSize = 16384, // checks whether the FLV tag has enough capacity to accept the proposed // write and re-allocates the internal buffers if necessary prepareWrite = function(flv, count) { var bytes, minLength = flv.position + count; if (minLength < flv.bytes.byteLength) { // there's enough capacity so do nothing return; } // allocate a new buffer and copy over the data that will not be modified bytes = new Uint8Array(minLength * 2); bytes.set(flv.bytes.subarray(0, flv.position), 0); flv.bytes = bytes; flv.view = new DataView(flv.bytes.buffer); }, // commonly used metadata properties widthBytes = FlvTag.widthBytes || new Uint8Array('width'.length), heightBytes = FlvTag.heightBytes || new Uint8Array('height'.length), videocodecidBytes = FlvTag.videocodecidBytes || new Uint8Array('videocodecid'.length), i; if (!FlvTag.widthBytes) { // calculating the bytes of common metadata names ahead of time makes the // corresponding writes faster because we don't have to loop over the // characters // re-test with test/perf.html if you're planning on changing this for (i = 0; i < 'width'.length; i++) { widthBytes[i] = 'width'.charCodeAt(i); } for (i = 0; i < 'height'.length; i++) { heightBytes[i] = 'height'.charCodeAt(i); } for (i = 0; i < 'videocodecid'.length; i++) { videocodecidBytes[i] = 'videocodecid'.charCodeAt(i); } FlvTag.widthBytes = widthBytes; FlvTag.heightBytes = heightBytes; FlvTag.videocodecidBytes = videocodecidBytes; } this.keyFrame = false; // :Boolean switch(type) { case FlvTag.VIDEO_TAG: this.length = 16; // Start the buffer at 256k bufferStartSize *= 6; break; case FlvTag.AUDIO_TAG: this.length = 13; this.keyFrame = true; break; case FlvTag.METADATA_TAG: this.length = 29; this.keyFrame = true; break; default: throw("Error Unknown TagType"); } this.bytes = new Uint8Array(bufferStartSize); this.view = new DataView(this.bytes.buffer); this.bytes[0] = type; this.position = this.length; this.keyFrame = extraData; // Defaults to false // presentation timestamp this.pts = 0; // decoder timestamp this.dts = 0; // ByteArray#writeBytes(bytes:ByteArray, offset:uint = 0, length:uint = 0) this.writeBytes = function(bytes, offset, length) { var start = offset || 0, end; length = length || bytes.byteLength; end = start + length; prepareWrite(this, length); this.bytes.set(bytes.subarray(start, end), this.position); this.position += length; this.length = Math.max(this.length, this.position); }; // ByteArray#writeByte(value:int):void this.writeByte = function(byte) { prepareWrite(this, 1); this.bytes[this.position] = byte; this.position++; this.length = Math.max(this.length, this.position); }; // ByteArray#writeShort(value:int):void this.writeShort = function(short) { prepareWrite(this, 2); this.view.setUint16(this.position, short); this.position += 2; this.length = Math.max(this.length, this.position); }; // Negative index into array // (pos:uint):int this.negIndex = function(pos) { return this.bytes[this.length - pos]; }; // The functions below ONLY work when this[0] == VIDEO_TAG. // We are not going to check for that because we dont want the overhead // (nal:ByteArray = null):int this.nalUnitSize = function() { if (adHoc === 0) { return 0; } return this.length - (adHoc + 4); }; this.startNalUnit = function() { // remember position and add 4 bytes if (adHoc > 0) { throw new Error("Attempted to create new NAL wihout closing the old one"); } // reserve 4 bytes for nal unit size adHoc = this.length; this.length += 4; this.position = this.length; }; // (nal:ByteArray = null):void this.endNalUnit = function(nalContainer) { var nalStart, // :uint nalLength; // :uint // Rewind to the marker and write the size if (this.length === adHoc + 4) { // we started a nal unit, but didnt write one, so roll back the 4 byte size value this.length -= 4; } else if (adHoc > 0) { nalStart = adHoc + 4; nalLength = this.length - nalStart; this.position = adHoc; this.view.setUint32(this.position, nalLength); this.position = this.length; if (nalContainer) { // Add the tag to the NAL unit nalContainer.push(this.bytes.subarray(nalStart, nalStart + nalLength)); } } adHoc = 0; }; /** * Write out a 64-bit floating point valued metadata property. This method is * called frequently during a typical parse and needs to be fast. */ // (key:String, val:Number):void this.writeMetaDataDouble = function(key, val) { var i; prepareWrite(this, 2 + key.length + 9); // write size of property name this.view.setUint16(this.position, key.length); this.position += 2; // this next part looks terrible but it improves parser throughput by // 10kB/s in my testing // write property name if (key === 'width') { this.bytes.set(widthBytes, this.position); this.position += 5; } else if (key === 'height') { this.bytes.set(heightBytes, this.position); this.position += 6; } else if (key === 'videocodecid') { this.bytes.set(videocodecidBytes, this.position); this.position += 12; } else { for (i = 0; i < key.length; i++) { this.bytes[this.position] = key.charCodeAt(i); this.position++; } } // skip null byte this.position++; // write property value this.view.setFloat64(this.position, val); this.position += 8; // update flv tag length this.length = Math.max(this.length, this.position); ++adHoc; }; // (key:String, val:Boolean):void this.writeMetaDataBoolean = function(key, val) { var i; prepareWrite(this, 2); this.view.setUint16(this.position, key.length); this.position += 2; for (i = 0; i < key.length; i++) { // if key.charCodeAt(i) >= 255, handle error prepareWrite(this, 1); this.bytes[this.position] = key.charCodeAt(i); this.position++; } prepareWrite(this, 2); this.view.setUint8(this.position, 0x01); this.position++; this.view.setUint8(this.position, val ? 0x01 : 0x00); this.position++; this.length = Math.max(this.length, this.position); ++adHoc; }; // ():ByteArray this.finalize = function() { var dtsDelta, // :int len; // :int switch(this.bytes[0]) { // Video Data case FlvTag.VIDEO_TAG: this.bytes[11] = ((this.keyFrame || extraData) ? 0x10 : 0x20 ) | 0x07; // We only support AVC, 1 = key frame (for AVC, a seekable frame), 2 = inter frame (for AVC, a non-seekable frame) this.bytes[12] = extraData ? 0x00 : 0x01; dtsDelta = this.pts - this.dts; this.bytes[13] = (dtsDelta & 0x00FF0000) >>> 16; this.bytes[14] = (dtsDelta & 0x0000FF00) >>> 8; this.bytes[15] = (dtsDelta & 0x000000FF) >>> 0; break; case FlvTag.AUDIO_TAG: this.bytes[11] = 0xAF; // 44 kHz, 16-bit stereo this.bytes[12] = extraData ? 0x00 : 0x01; break; case FlvTag.METADATA_TAG: this.position = 11; this.view.setUint8(this.position, 0x02); // String type this.position++; this.view.setUint16(this.position, 0x0A); // 10 Bytes this.position += 2; // set "onMetaData" this.bytes.set([0x6f, 0x6e, 0x4d, 0x65, 0x74, 0x61, 0x44, 0x61, 0x74, 0x61], this.position); this.position += 10; this.bytes[this.position] = 0x08; // Array type this.position++; this.view.setUint32(this.position, adHoc); this.position = this.length; this.bytes.set([0, 0, 9], this.position); this.position += 3; // End Data Tag this.length = this.position; break; } len = this.length - 11; // write the DataSize field this.bytes[ 1] = (len & 0x00FF0000) >>> 16; this.bytes[ 2] = (len & 0x0000FF00) >>> 8; this.bytes[ 3] = (len & 0x000000FF) >>> 0; // write the Timestamp this.bytes[ 4] = (this.dts & 0x00FF0000) >>> 16; this.bytes[ 5] = (this.dts & 0x0000FF00) >>> 8; this.bytes[ 6] = (this.dts & 0x000000FF) >>> 0; this.bytes[ 7] = (this.dts & 0xFF000000) >>> 24; // write the StreamID this.bytes[ 8] = 0; this.bytes[ 9] = 0; this.bytes[10] = 0; // Sometimes we're at the end of the view and have one slot to write a // uint32, so, prepareWrite of count 4, since, view is uint8 prepareWrite(this, 4); this.view.setUint32(this.length, this.length); this.length += 4; this.position += 4; // trim down the byte buffer to what is actually being used this.bytes = this.bytes.subarray(0, this.length); this.frameTime = FlvTag.frameTime(this.bytes); // if bytes.bytelength isn't equal to this.length, handle error return this; }; }; FlvTag.AUDIO_TAG = 0x08; // == 8, :uint FlvTag.VIDEO_TAG = 0x09; // == 9, :uint FlvTag.METADATA_TAG = 0x12; // == 18, :uint // (tag:ByteArray):Boolean { FlvTag.isAudioFrame = function(tag) { return FlvTag.AUDIO_TAG === tag[0]; }; // (tag:ByteArray):Boolean { FlvTag.isVideoFrame = function(tag) { return FlvTag.VIDEO_TAG === tag[0]; }; // (tag:ByteArray):Boolean { FlvTag.isMetaData = function(tag) { return FlvTag.METADATA_TAG === tag[0]; }; // (tag:ByteArray):Boolean { FlvTag.isKeyFrame = function(tag) { if (FlvTag.isVideoFrame(tag)) { return tag[11] === 0x17; } if (FlvTag.isAudioFrame(tag)) { return true; } if (FlvTag.isMetaData(tag)) { return true; } return false; }; // (tag:ByteArray):uint { FlvTag.frameTime = function(tag) { var pts = tag[ 4] << 16; // :uint pts |= tag[ 5] << 8; pts |= tag[ 6] << 0; pts |= tag[ 7] << 24; return pts; }; module.exports = FlvTag; },{}],35:[function(require,module,exports){ module.exports = { tag: require('./flv-tag'), Transmuxer: require('./transmuxer'), tools: require('../tools/flv-inspector'), }; },{"../tools/flv-inspector":46,"./flv-tag":34,"./transmuxer":36}],36:[function(require,module,exports){ 'use strict'; var Stream = require('../utils/stream.js'); var FlvTag = require('./flv-tag.js'); var m2ts = require('../m2ts/m2ts.js'); var AdtsStream = require('../codecs/adts.js'); var H264Stream = require('../codecs/h264').H264Stream; var MetadataStream, Transmuxer, VideoSegmentStream, AudioSegmentStream, CoalesceStream, collectTimelineInfo, metaDataTag, extraDataTag; /** * Store information about the start and end of the tracka and the * duration for each frame/sample we process in order to calculate * the baseMediaDecodeTime */ collectTimelineInfo = function (track, data) { if (typeof data.pts === 'number') { if (track.timelineStartInfo.pts === undefined) { track.timelineStartInfo.pts = data.pts; } else { track.timelineStartInfo.pts = Math.min(track.timelineStartInfo.pts, data.pts); } } if (typeof data.dts === 'number') { if (track.timelineStartInfo.dts === undefined) { track.timelineStartInfo.dts = data.dts; } else { track.timelineStartInfo.dts = Math.min(track.timelineStartInfo.dts, data.dts); } } }; metaDataTag = function(track, pts) { var tag = new FlvTag(FlvTag.METADATA_TAG); // :FlvTag tag.dts = pts; tag.pts = pts; tag.writeMetaDataDouble("videocodecid", 7); tag.writeMetaDataDouble("width", track.width); tag.writeMetaDataDouble("height", track.height); return tag; }; extraDataTag = function(track, pts) { var i, tag = new FlvTag(FlvTag.VIDEO_TAG, true); tag.dts = pts; tag.pts = pts; tag.writeByte(0x01);// version tag.writeByte(track.profileIdc);// profile tag.writeByte(track.profileCompatibility);// compatibility tag.writeByte(track.levelIdc);// level tag.writeByte(0xFC | 0x03); // reserved (6 bits), NULA length size - 1 (2 bits) tag.writeByte(0xE0 | 0x01 ); // reserved (3 bits), num of SPS (5 bits) tag.writeShort( track.sps[0].length ); // data of SPS tag.writeBytes( track.sps[0] ); // SPS tag.writeByte(track.pps.length); // num of PPS (will there ever be more that 1 PPS?) for (i = 0 ; i < track.pps.length ; ++i) { tag.writeShort(track.pps[i].length); // 2 bytes for length of PPS tag.writeBytes(track.pps[i]); // data of PPS } return tag; }; /** * Constructs a single-track, media segment from AAC data * events. The output of this stream can be fed to flash. */ AudioSegmentStream = function(track) { var adtsFrames = [], adtsFramesLength = 0, sequenceNumber = 0, earliestAllowedDts = 0, oldExtraData; AudioSegmentStream.prototype.init.call(this); this.push = function(data) { collectTimelineInfo(track, data); if (track && track.channelcount === undefined) { track.audioobjecttype = data.audioobjecttype; track.channelcount = data.channelcount; track.samplerate = data.samplerate; track.samplingfrequencyindex = data.samplingfrequencyindex; track.samplesize = data.samplesize; track.extraData = (track.audioobjecttype << 11) | (track.samplingfrequencyindex << 7) | (track.channelcount << 3); } data.pts = Math.round(data.pts / 90); data.dts = Math.round(data.dts / 90); // buffer audio data until end() is called adtsFrames.push(data); }; this.flush = function() { var currentFrame, adtsFrame, deltaDts,lastMetaPts, tags = []; // return early if no audio data has been observed if (adtsFrames.length === 0) { this.trigger('done'); return; } lastMetaPts = -Infinity; while (adtsFrames.length) { currentFrame = adtsFrames.shift(); // write out metadata tags every 1 second so that the decoder // is re-initialized quickly after seeking into a different // audio configuration if (track.extraData !== oldExtraData || currentFrame.pts - lastMetaPts >= 1000) { adtsFrame = new FlvTag(FlvTag.METADATA_TAG); adtsFrame.pts = currentFrame.pts; adtsFrame.dts = currentFrame.dts; // AAC is always 10 adtsFrame.writeMetaDataDouble("audiocodecid", 10); adtsFrame.writeMetaDataBoolean("stereo", 2 === track.channelcount); adtsFrame.writeMetaDataDouble ("audiosamplerate", track.samplerate); // Is AAC always 16 bit? adtsFrame.writeMetaDataDouble ("audiosamplesize", 16); tags.push(adtsFrame); oldExtraData = track.extraData; adtsFrame = new FlvTag(FlvTag.AUDIO_TAG, true); // For audio, DTS is always the same as PTS. We want to set the DTS // however so we can compare with video DTS to determine approximate // packet order adtsFrame.pts = currentFrame.pts; adtsFrame.dts = currentFrame.dts; adtsFrame.view.setUint16(adtsFrame.position, track.extraData); adtsFrame.position += 2; adtsFrame.length = Math.max(adtsFrame.length, adtsFrame.position); tags.push(adtsFrame); lastMetaPts = currentFrame.pts; } adtsFrame = new FlvTag(FlvTag.AUDIO_TAG); adtsFrame.pts = currentFrame.pts; adtsFrame.dts = currentFrame.dts; adtsFrame.writeBytes(currentFrame.data); tags.push(adtsFrame); } oldExtraData = null; this.trigger('data', {track: track, tags: tags}); this.trigger('done'); }; }; AudioSegmentStream.prototype = new Stream(); /** * Store FlvTags for the h264 stream * @param track {object} track metadata configuration */ VideoSegmentStream = function(track) { var sequenceNumber = 0, nalUnits = [], nalUnitsLength = 0, config, h264Frame; VideoSegmentStream.prototype.init.call(this); this.finishFrame = function(tags, frame) { if (!frame) { return; } // Check if keyframe and the length of tags. // This makes sure we write metadata on the first frame of a segment. if (config && track && track.newMetadata && (frame.keyFrame || tags.length === 0)) { // Push extra data on every IDR frame in case we did a stream change + seek tags.push(metaDataTag(config, frame.pts)); tags.push(extraDataTag(track, frame.pts)); track.newMetadata = false; } frame.endNalUnit(); tags.push(frame); }; this.push = function(data) { collectTimelineInfo(track, data); data.pts = Math.round(data.pts / 90); data.dts = Math.round(data.dts / 90); // buffer video until flush() is called nalUnits.push(data); }; this.flush = function() { var currentNal, tags = []; // Throw away nalUnits at the start of the byte stream until we find // the first AUD while (nalUnits.length) { if (nalUnits[0].nalUnitType === 'access_unit_delimiter_rbsp') { break; } nalUnits.shift(); } // return early if no video data has been observed if (nalUnits.length === 0) { this.trigger('done'); return; } while (nalUnits.length) { currentNal = nalUnits.shift(); // record the track config if (currentNal.nalUnitType === 'seq_parameter_set_rbsp') { track.newMetadata = true; config = currentNal.config; track.width = config.width; track.height = config.height; track.sps = [currentNal.data]; track.profileIdc = config.profileIdc; track.levelIdc = config.levelIdc; track.profileCompatibility = config.profileCompatibility; h264Frame.endNalUnit(); } else if (currentNal.nalUnitType === 'pic_parameter_set_rbsp') { track.newMetadata = true; track.pps = [currentNal.data]; h264Frame.endNalUnit(); } else if (currentNal.nalUnitType === 'access_unit_delimiter_rbsp') { if (h264Frame) { this.finishFrame(tags, h264Frame); } h264Frame = new FlvTag(FlvTag.VIDEO_TAG); h264Frame.pts = currentNal.pts; h264Frame.dts = currentNal.dts; } else { if (currentNal.nalUnitType === 'slice_layer_without_partitioning_rbsp_idr') { // the current sample is a key frame h264Frame.keyFrame = true; } h264Frame.endNalUnit(); } h264Frame.startNalUnit(); h264Frame.writeBytes(currentNal.data); } if (h264Frame) { this.finishFrame(tags, h264Frame); } this.trigger('data', {track: track, tags: tags}); // Continue with the flush process now this.trigger('done'); }; }; VideoSegmentStream.prototype = new Stream(); /** * The final stage of the transmuxer that emits the flv tags * for audio, video, and metadata. Also tranlates in time and * outputs caption data and id3 cues. */ CoalesceStream = function(options) { // Number of Tracks per output segment // If greater than 1, we combine multiple // tracks into a single segment this.numberOfTracks = 0; this.metadataStream = options.metadataStream; this.videoTags = []; this.audioTags = []; this.videoTrack = null; this.audioTrack = null; this.pendingCaptions = []; this.pendingMetadata = []; this.pendingTracks = 0; CoalesceStream.prototype.init.call(this); // Take output from multiple this.push = function(output) { // buffer incoming captions until the associated video segment // finishes if (output.text) { return this.pendingCaptions.push(output); } // buffer incoming id3 tags until the final flush if (output.frames) { return this.pendingMetadata.push(output); } if (output.track.type === 'video') { this.videoTrack = output.track; this.videoTags = output.tags; this.pendingTracks++; } if (output.track.type === 'audio') { this.audioTrack = output.track; this.audioTags = output.tags; this.pendingTracks++; } }; }; CoalesceStream.prototype = new Stream(); CoalesceStream.prototype.flush = function() { var id3, caption, i, timelineStartPts, event = { tags: {}, captions: [], metadata: [] }; if (this.pendingTracks < this.numberOfTracks) { return; } if (this.videoTrack) { timelineStartPts = this.videoTrack.timelineStartInfo.pts; } else if (this.audioTrack) { timelineStartPts = this.audioTrack.timelineStartInfo.pts; } event.tags.videoTags = this.videoTags; event.tags.audioTags = this.audioTags; // Translate caption PTS times into second offsets into the // video timeline for the segment for (i = 0; i < this.pendingCaptions.length; i++) { caption = this.pendingCaptions[i]; caption.startTime = caption.startPts - timelineStartPts; caption.startTime /= 90e3; caption.endTime = caption.endPts - timelineStartPts; caption.endTime /= 90e3; event.captions.push(caption); } // Translate ID3 frame PTS times into second offsets into the // video timeline for the segment for (i = 0; i < this.pendingMetadata.length; i++) { id3 = this.pendingMetadata[i]; id3.cueTime = id3.pts - timelineStartPts; id3.cueTime /= 90e3; event.metadata.push(id3); } // We add this to every single emitted segment even though we only need // it for the first event.metadata.dispatchType = this.metadataStream.dispatchType; // Reset stream state this.videoTrack = null; this.audioTrack = null; this.videoTags = []; this.audioTags = []; this.pendingCaptions.length = 0; this.pendingMetadata.length = 0; this.pendingTracks = 0; // Emit the final segment this.trigger('data', event); this.trigger('done'); }; /** * An object that incrementally transmuxes MPEG2 Trasport Stream * chunks into an FLV. */ Transmuxer = function(options) { var self = this, videoTrack, audioTrack, packetStream, parseStream, elementaryStream, adtsStream, h264Stream, videoSegmentStream, audioSegmentStream, captionStream, coalesceStream; Transmuxer.prototype.init.call(this); options = options || {}; // expose the metadata stream this.metadataStream = new m2ts.MetadataStream(); options.metadataStream = this.metadataStream; // set up the parsing pipeline packetStream = new m2ts.TransportPacketStream(); parseStream = new m2ts.TransportParseStream(); elementaryStream = new m2ts.ElementaryStream(); adtsStream = new AdtsStream(); h264Stream = new H264Stream(); coalesceStream = new CoalesceStream(options); // disassemble MPEG2-TS packets into elementary streams packetStream .pipe(parseStream) .pipe(elementaryStream); // !!THIS ORDER IS IMPORTANT!! // demux the streams elementaryStream .pipe(h264Stream); elementaryStream .pipe(adtsStream); elementaryStream .pipe(this.metadataStream) .pipe(coalesceStream); // if CEA-708 parsing is available, hook up a caption stream captionStream = new m2ts.CaptionStream(); h264Stream.pipe(captionStream) .pipe(coalesceStream); // hook up the segment streams once track metadata is delivered elementaryStream.on('data', function(data) { var i, videoTrack, audioTrack; if (data.type === 'metadata') { i = data.tracks.length; // scan the tracks listed in the metadata while (i--) { if (data.tracks[i].type === 'video') { videoTrack = data.tracks[i]; } else if (data.tracks[i].type === 'audio') { audioTrack = data.tracks[i]; } } // hook up the video segment stream to the first track with h264 data if (videoTrack && !videoSegmentStream) { coalesceStream.numberOfTracks++; videoSegmentStream = new VideoSegmentStream(videoTrack); // Set up the final part of the video pipeline h264Stream .pipe(videoSegmentStream) .pipe(coalesceStream); } if (audioTrack && !audioSegmentStream) { // hook up the audio segment stream to the first track with aac data coalesceStream.numberOfTracks++; audioSegmentStream = new AudioSegmentStream(audioTrack); // Set up the final part of the audio pipeline adtsStream .pipe(audioSegmentStream) .pipe(coalesceStream); } } }); // feed incoming data to the front of the parsing pipeline this.push = function(data) { packetStream.push(data); }; // flush any buffered data this.flush = function() { // Start at the top of the pipeline and flush all pending work packetStream.flush(); }; // Re-emit any data coming from the coalesce stream to the outside world coalesceStream.on('data', function (event) { self.trigger('data', event); }); // Let the consumer know we have finished flushing the entire pipeline coalesceStream.on('done', function () { self.trigger('done'); }); // For information on the FLV format, see // http://download.macromedia.com/f4v/video_file_format_spec_v10_1.pdf. // Technically, this function returns the header and a metadata FLV tag // if duration is greater than zero // duration in seconds // @return {object} the bytes of the FLV header as a Uint8Array this.getFlvHeader = function(duration, audio, video) { // :ByteArray { var headBytes = new Uint8Array(3 + 1 + 1 + 4), head = new DataView(headBytes.buffer), metadata, result, metadataLength; // default arguments duration = duration || 0; audio = audio === undefined? true : audio; video = video === undefined? true : video; // signature head.setUint8(0, 0x46); // 'F' head.setUint8(1, 0x4c); // 'L' head.setUint8(2, 0x56); // 'V' // version head.setUint8(3, 0x01); // flags head.setUint8(4, (audio ? 0x04 : 0x00) | (video ? 0x01 : 0x00)); // data offset, should be 9 for FLV v1 head.setUint32(5, headBytes.byteLength); // init the first FLV tag if (duration <= 0) { // no duration available so just write the first field of the first // FLV tag result = new Uint8Array(headBytes.byteLength + 4); result.set(headBytes); result.set([0, 0, 0, 0], headBytes.byteLength); return result; } // write out the duration metadata tag metadata = new FlvTag(FlvTag.METADATA_TAG); metadata.pts = metadata.dts = 0; metadata.writeMetaDataDouble("duration", duration); metadataLength = metadata.finalize().length; result = new Uint8Array(headBytes.byteLength + metadataLength); result.set(headBytes); result.set(head.byteLength, metadataLength); return result; }; }; Transmuxer.prototype = new Stream(); // forward compatibility module.exports = Transmuxer; },{"../codecs/adts.js":31,"../codecs/h264":32,"../m2ts/m2ts.js":40,"../utils/stream.js":49,"./flv-tag.js":34}],37:[function(require,module,exports){ 'use strict'; var muxjs = { codecs: require('./codecs'), mp4: require('./mp4'), flv: require('./flv'), mp2t: require('./m2ts'), }; module.exports = muxjs; },{"./codecs":33,"./flv":35,"./m2ts":39,"./mp4":43}],38:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2015 Brightcove * All rights reserved. * * Reads in-band caption information from a video elementary * stream. Captions must follow the CEA-708 standard for injection * into an MPEG-2 transport streams. * @see https://en.wikipedia.org/wiki/CEA-708 */ 'use strict'; // ----------------- // Link To Transport // ----------------- // Supplemental enhancement information (SEI) NAL units have a // payload type field to indicate how they are to be // interpreted. CEAS-708 caption content is always transmitted with // payload type 0x04. var USER_DATA_REGISTERED_ITU_T_T35 = 4, RBSP_TRAILING_BITS = 128, Stream = require('../utils/stream'); /** * Parse a supplemental enhancement information (SEI) NAL unit. * Stops parsing once a message of type ITU T T35 has been found. * * @param bytes {Uint8Array} the bytes of a SEI NAL unit * @return {object} the parsed SEI payload * @see Rec. ITU-T H.264, 7.3.2.3.1 */ var parseSei = function(bytes) { var i = 0, result = { payloadType: -1, payloadSize: 0, }, payloadType = 0, payloadSize = 0; // go through the sei_rbsp parsing each each individual sei_message while (i < bytes.byteLength) { // stop once we have hit the end of the sei_rbsp if (bytes[i] === RBSP_TRAILING_BITS) { break; } // Parse payload type while (bytes[i] === 0xFF) { payloadType += 255; i++; } payloadType += bytes[i++]; // Parse payload size while (bytes[i] === 0xFF) { payloadSize += 255; i++; } payloadSize += bytes[i++]; // this sei_message is a 608/708 caption so save it and break // there can only ever be one caption message in a frame's sei if (!result.payload && payloadType === USER_DATA_REGISTERED_ITU_T_T35) { result.payloadType = payloadType; result.payloadSize = payloadSize; result.payload = bytes.subarray(i, i + payloadSize); break; } // skip the payload and parse the next message i += payloadSize; payloadType = 0; payloadSize = 0; } return result; }; // see ANSI/SCTE 128-1 (2013), section 8.1 var parseUserData = function(sei) { // itu_t_t35_contry_code must be 181 (United States) for // captions if (sei.payload[0] !== 181) { return null; } // itu_t_t35_provider_code should be 49 (ATSC) for captions if (((sei.payload[1] << 8) | sei.payload[2]) !== 49) { return null; } // the user_identifier should be "GA94" to indicate ATSC1 data if (String.fromCharCode(sei.payload[3], sei.payload[4], sei.payload[5], sei.payload[6]) !== 'GA94') { return null; } // finally, user_data_type_code should be 0x03 for caption data if (sei.payload[7] !== 0x03) { return null; } // return the user_data_type_structure and strip the trailing // marker bits return sei.payload.subarray(8, sei.payload.length - 1); }; // see CEA-708-D, section 4.4 var parseCaptionPackets = function(pts, userData) { var results = [], i, count, offset, data; // if this is just filler, return immediately if (!(userData[0] & 0x40)) { return results; } // parse out the cc_data_1 and cc_data_2 fields count = userData[0] & 0x1f; for (i = 0; i < count; i++) { offset = i * 3; data = { type: userData[offset + 2] & 0x03, pts: pts }; // capture cc data when cc_valid is 1 if (userData[offset + 2] & 0x04) { data.ccData = (userData[offset + 3] << 8) | userData[offset + 4]; results.push(data); } } return results; }; var CaptionStream = function() { var self = this; CaptionStream.prototype.init.call(this); this.captionPackets_ = []; this.field1_ = new Cea608Stream(); // forward data and done events from field1_ to this CaptionStream this.field1_.on('data', this.trigger.bind(this, 'data')); this.field1_.on('done', this.trigger.bind(this, 'done')); }; CaptionStream.prototype = new Stream(); CaptionStream.prototype.push = function(event) { var sei, userData, captionPackets; // only examine SEI NALs if (event.nalUnitType !== 'sei_rbsp') { return; } // parse the sei sei = parseSei(event.escapedRBSP); // ignore everything but user_data_registered_itu_t_t35 if (sei.payloadType !== USER_DATA_REGISTERED_ITU_T_T35) { return; } // parse out the user data payload userData = parseUserData(sei); // ignore unrecognized userData if (!userData) { return; } // parse out CC data packets and save them for later this.captionPackets_ = this.captionPackets_.concat(parseCaptionPackets(event.pts, userData)); }; CaptionStream.prototype.flush = function () { // make sure we actually parsed captions before proceeding if (!this.captionPackets_.length) { this.field1_.flush(); return; } // sort caption byte-pairs based on their PTS values this.captionPackets_.sort(function(a, b) { return a.pts - b.pts; }); // Push each caption into Cea608Stream this.captionPackets_.forEach(this.field1_.push, this.field1_); this.captionPackets_.length = 0; this.field1_.flush(); return; }; // ---------------------- // Session to Application // ---------------------- var BASIC_CHARACTER_TRANSLATION = { 0x2a: 0xe1, 0x5c: 0xe9, 0x5e: 0xed, 0x5f: 0xf3, 0x60: 0xfa, 0x7b: 0xe7, 0x7c: 0xf7, 0x7d: 0xd1, 0x7e: 0xf1, 0x7f: 0x2588 }; var getCharFromCode = function(code) { if(code === null) { return ''; } code = BASIC_CHARACTER_TRANSLATION[code] || code; return String.fromCharCode(code); }; // Constants for the byte codes recognized by Cea608Stream. This // list is not exhaustive. For a more comprehensive listing and // semantics see // http://www.gpo.gov/fdsys/pkg/CFR-2010-title47-vol1/pdf/CFR-2010-title47-vol1-sec15-119.pdf var PADDING = 0x0000, // Pop-on Mode RESUME_CAPTION_LOADING = 0x1420, END_OF_CAPTION = 0x142f, // Roll-up Mode ROLL_UP_2_ROWS = 0x1425, ROLL_UP_3_ROWS = 0x1426, ROLL_UP_4_ROWS = 0x1427, RESUME_DIRECT_CAPTIONING = 0x1429, CARRIAGE_RETURN = 0x142d, // Erasure BACKSPACE = 0x1421, ERASE_DISPLAYED_MEMORY = 0x142c, ERASE_NON_DISPLAYED_MEMORY = 0x142e; // the index of the last row in a CEA-608 display buffer var BOTTOM_ROW = 14; // CEA-608 captions are rendered onto a 34x15 matrix of character // cells. The "bottom" row is the last element in the outer array. var createDisplayBuffer = function() { var result = [], i = BOTTOM_ROW + 1; while (i--) { result.push(''); } return result; }; var Cea608Stream = function() { Cea608Stream.prototype.init.call(this); this.mode_ = 'popOn'; // When in roll-up mode, the index of the last row that will // actually display captions. If a caption is shifted to a row // with a lower index than this, it is cleared from the display // buffer this.topRow_ = 0; this.startPts_ = 0; this.displayed_ = createDisplayBuffer(); this.nonDisplayed_ = createDisplayBuffer(); this.lastControlCode_ = null; this.push = function(packet) { // Ignore other channels if (packet.type !== 0) { return; } var data, swap, char0, char1; // remove the parity bits data = packet.ccData & 0x7f7f; // ignore duplicate control codes if (data === this.lastControlCode_) { this.lastControlCode_ = null; return; } // Store control codes if ((data & 0xf000) === 0x1000) { this.lastControlCode_ = data; } else { this.lastControlCode_ = null; } switch (data) { case PADDING: break; case RESUME_CAPTION_LOADING: this.mode_ = 'popOn'; break; case END_OF_CAPTION: // if a caption was being displayed, it's gone now this.flushDisplayed(packet.pts); // flip memory swap = this.displayed_; this.displayed_ = this.nonDisplayed_; this.nonDisplayed_ = swap; // start measuring the time to display the caption this.startPts_ = packet.pts; break; case ROLL_UP_2_ROWS: this.topRow_ = BOTTOM_ROW - 1; this.mode_ = 'rollUp'; break; case ROLL_UP_3_ROWS: this.topRow_ = BOTTOM_ROW - 2; this.mode_ = 'rollUp'; break; case ROLL_UP_4_ROWS: this.topRow_ = BOTTOM_ROW - 3; this.mode_ = 'rollUp'; break; case CARRIAGE_RETURN: this.flushDisplayed(packet.pts); this.shiftRowsUp_(); this.startPts_ = packet.pts; break; case BACKSPACE: if (this.mode_ === 'popOn') { this.nonDisplayed_[BOTTOM_ROW] = this.nonDisplayed_[BOTTOM_ROW].slice(0, -1); } else { this.displayed_[BOTTOM_ROW] = this.displayed_[BOTTOM_ROW].slice(0, -1); } break; case ERASE_DISPLAYED_MEMORY: this.flushDisplayed(packet.pts); this.displayed_ = createDisplayBuffer(); break; case ERASE_NON_DISPLAYED_MEMORY: this.nonDisplayed_ = createDisplayBuffer(); break; default: char0 = data >>> 8; char1 = data & 0xff; // Look for a Channel 1 Preamble Address Code if (char0 >= 0x10 && char0 <= 0x17 && char1 >= 0x40 && char1 <= 0x7F && (char0 !== 0x10 || char1 < 0x60)) { // Follow Safari's lead and replace the PAC with a space char0 = 0x20; // we only want one space so make the second character null // which will get become '' in getCharFromCode char1 = null; } // Look for special character sets if ((char0 === 0x11 || char0 === 0x19) && (char1 >= 0x30 && char1 <= 0x3F)) { // Put in eigth note and space char0 = 0xE299AA; char1 = ''; } // ignore unsupported control codes if ((char0 & 0xf0) === 0x10) { return; } // character handling is dependent on the current mode this[this.mode_](packet.pts, char0, char1); break; } }; }; Cea608Stream.prototype = new Stream(); // Trigger a cue point that captures the current state of the // display buffer Cea608Stream.prototype.flushDisplayed = function(pts) { var row, i; for (i = 0; i < this.displayed_.length; i++) { row = this.displayed_[i]; if (row.length) { this.trigger('data', { startPts: this.startPts_, endPts: pts, // remove spaces from the start and end of the string text: row.trim() }); } } }; // Mode Implementations Cea608Stream.prototype.popOn = function(pts, char0, char1) { var baseRow = this.nonDisplayed_[BOTTOM_ROW]; // buffer characters baseRow += getCharFromCode(char0); baseRow += getCharFromCode(char1); this.nonDisplayed_[BOTTOM_ROW] = baseRow; }; Cea608Stream.prototype.rollUp = function(pts, char0, char1) { var baseRow = this.displayed_[BOTTOM_ROW]; if (baseRow === '') { // we're starting to buffer new display input, so flush out the // current display this.flushDisplayed(pts); this.startPts_ = pts; } baseRow += getCharFromCode(char0); baseRow += getCharFromCode(char1); this.displayed_[BOTTOM_ROW] = baseRow; }; Cea608Stream.prototype.shiftRowsUp_ = function() { var i; // clear out inactive rows for (i = 0; i < this.topRow_; i++) { this.displayed_[i] = ''; } // shift displayed rows up for (i = this.topRow_; i < BOTTOM_ROW; i++) { this.displayed_[i] = this.displayed_[i + 1]; } // clear out the bottom row this.displayed_[BOTTOM_ROW] = ''; }; // exports module.exports = { CaptionStream: CaptionStream, Cea608Stream: Cea608Stream, }; },{"../utils/stream":49}],39:[function(require,module,exports){ module.exports = require('./m2ts'); },{"./m2ts":40}],40:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2015 Brightcove * All rights reserved. * * A stream-based mp2t to mp4 converter. This utility can be used to * deliver mp4s to a SourceBuffer on platforms that support native * Media Source Extensions. */ 'use strict'; var Stream = require('../utils/stream.js'), CaptionStream = require('./caption-stream'), StreamTypes = require('./stream-types'); var Stream = require('../utils/stream.js'); var m2tsStreamTypes = require('./stream-types.js'); // object types var TransportPacketStream, TransportParseStream, ElementaryStream, AacStream, H264Stream, NalByteStream; // constants var MP2T_PACKET_LENGTH = 188, // bytes SYNC_BYTE = 0x47, /** * Splits an incoming stream of binary data into MPEG-2 Transport * Stream packets. */ TransportPacketStream = function() { var buffer = new Uint8Array(MP2T_PACKET_LENGTH), bytesInBuffer = 0; TransportPacketStream.prototype.init.call(this); // Deliver new bytes to the stream. this.push = function(bytes) { var i = 0, startIndex = 0, endIndex = MP2T_PACKET_LENGTH, everything; // If there are bytes remaining from the last segment, prepend them to the // bytes that were pushed in if (bytesInBuffer) { everything = new Uint8Array(bytes.byteLength + bytesInBuffer); everything.set(buffer.subarray(0, bytesInBuffer)); everything.set(bytes, bytesInBuffer); bytesInBuffer = 0; } else { everything = bytes; } // While we have enough data for a packet while (endIndex < everything.byteLength) { // Look for a pair of start and end sync bytes in the data.. if (everything[startIndex] === SYNC_BYTE && everything[endIndex] === SYNC_BYTE) { // We found a packet so emit it and jump one whole packet forward in // the stream this.trigger('data', everything.subarray(startIndex, endIndex)); startIndex += MP2T_PACKET_LENGTH; endIndex += MP2T_PACKET_LENGTH; continue; } // If we get here, we have somehow become de-synchronized and we need to step // forward one byte at a time until we find a pair of sync bytes that denote // a packet startIndex++; endIndex++; } // If there was some data left over at the end of the segment that couldn't // possibly be a whole packet, keep it because it might be the start of a packet // that continues in the next segment if (startIndex < everything.byteLength) { buffer.set(everything.subarray(startIndex), 0); bytesInBuffer = everything.byteLength - startIndex; } }; this.flush = function () { // If the buffer contains a whole packet when we are being flushed, emit it // and empty the buffer. Otherwise hold onto the data because it may be // important for decoding the next segment if (bytesInBuffer === MP2T_PACKET_LENGTH && buffer[0] === SYNC_BYTE) { this.trigger('data', buffer); bytesInBuffer = 0; } this.trigger('done'); }; }; TransportPacketStream.prototype = new Stream(); /** * Accepts an MP2T TransportPacketStream and emits data events with parsed * forms of the individual transport stream packets. */ TransportParseStream = function() { var parsePsi, parsePat, parsePmt, parsePes, self; TransportParseStream.prototype.init.call(this); self = this; this.packetsWaitingForPmt = []; this.programMapTable = undefined; parsePsi = function(payload, psi) { var offset = 0; // PSI packets may be split into multiple sections and those // sections may be split into multiple packets. If a PSI // section starts in this packet, the payload_unit_start_indicator // will be true and the first byte of the payload will indicate // the offset from the current position to the start of the // section. if (psi.payloadUnitStartIndicator) { offset += payload[offset] + 1; } if (psi.type === 'pat') { parsePat(payload.subarray(offset), psi); } else { parsePmt(payload.subarray(offset), psi); } }; parsePat = function(payload, pat) { pat.section_number = payload[7]; pat.last_section_number = payload[8]; // skip the PSI header and parse the first PMT entry self.pmtPid = (payload[10] & 0x1F) << 8 | payload[11]; pat.pmtPid = self.pmtPid; }; /** * Parse out the relevant fields of a Program Map Table (PMT). * @param payload {Uint8Array} the PMT-specific portion of an MP2T * packet. The first byte in this array should be the table_id * field. * @param pmt {object} the object that should be decorated with * fields parsed from the PMT. */ parsePmt = function(payload, pmt) { var sectionLength, tableEnd, programInfoLength, offset; // PMTs can be sent ahead of the time when they should actually // take effect. We don't believe this should ever be the case // for HLS but we'll ignore "forward" PMT declarations if we see // them. Future PMT declarations have the current_next_indicator // set to zero. if (!(payload[5] & 0x01)) { return; } // overwrite any existing program map table self.programMapTable = {}; // the mapping table ends at the end of the current section sectionLength = (payload[1] & 0x0f) << 8 | payload[2]; tableEnd = 3 + sectionLength - 4; // to determine where the table is, we have to figure out how // long the program info descriptors are programInfoLength = (payload[10] & 0x0f) << 8 | payload[11]; // advance the offset to the first entry in the mapping table offset = 12 + programInfoLength; while (offset < tableEnd) { // add an entry that maps the elementary_pid to the stream_type self.programMapTable[(payload[offset + 1] & 0x1F) << 8 | payload[offset + 2]] = payload[offset]; // move to the next table entry // skip past the elementary stream descriptors, if present offset += ((payload[offset + 3] & 0x0F) << 8 | payload[offset + 4]) + 5; } // record the map on the packet as well pmt.programMapTable = self.programMapTable; // if there are any packets waiting for a PMT to be found, process them now while (self.packetsWaitingForPmt.length) { self.processPes_.apply(self, self.packetsWaitingForPmt.shift()); } }; /** * Deliver a new MP2T packet to the stream. */ this.push = function(packet) { var result = {}, offset = 4; result.payloadUnitStartIndicator = !!(packet[1] & 0x40); // pid is a 13-bit field starting at the last bit of packet[1] result.pid = packet[1] & 0x1f; result.pid <<= 8; result.pid |= packet[2]; // if an adaption field is present, its length is specified by the // fifth byte of the TS packet header. The adaptation field is // used to add stuffing to PES packets that don't fill a complete // TS packet, and to specify some forms of timing and control data // that we do not currently use. if (((packet[3] & 0x30) >>> 4) > 0x01) { offset += packet[offset] + 1; } // parse the rest of the packet based on the type if (result.pid === 0) { result.type = 'pat'; parsePsi(packet.subarray(offset), result); this.trigger('data', result); } else if (result.pid === this.pmtPid) { result.type = 'pmt'; parsePsi(packet.subarray(offset), result); this.trigger('data', result); } else if (this.programMapTable === undefined) { // When we have not seen a PMT yet, defer further processing of // PES packets until one has been parsed this.packetsWaitingForPmt.push([packet, offset, result]); } else { this.processPes_(packet, offset, result); } }; this.processPes_ = function (packet, offset, result) { result.streamType = this.programMapTable[result.pid]; result.type = 'pes'; result.data = packet.subarray(offset); this.trigger('data', result); }; }; TransportParseStream.prototype = new Stream(); TransportParseStream.STREAM_TYPES = { h264: 0x1b, adts: 0x0f }; /** * Reconsistutes program elementary stream (PES) packets from parsed * transport stream packets. That is, if you pipe an * mp2t.TransportParseStream into a mp2t.ElementaryStream, the output * events will be events which capture the bytes for individual PES * packets plus relevant metadata that has been extracted from the * container. */ ElementaryStream = function() { var // PES packet fragments video = { data: [], size: 0 }, audio = { data: [], size: 0 }, timedMetadata = { data: [], size: 0 }, parsePes = function(payload, pes) { var ptsDtsFlags; // find out if this packets starts a new keyframe pes.dataAlignmentIndicator = (payload[6] & 0x04) !== 0; // PES packets may be annotated with a PTS value, or a PTS value // and a DTS value. Determine what combination of values is // available to work with. ptsDtsFlags = payload[7]; // PTS and DTS are normally stored as a 33-bit number. Javascript // performs all bitwise operations on 32-bit integers but javascript // supports a much greater range (52-bits) of integer using standard // mathematical operations. // We construct a 31-bit value using bitwise operators over the 31 // most significant bits and then multiply by 4 (equal to a left-shift // of 2) before we add the final 2 least significant bits of the // timestamp (equal to an OR.) if (ptsDtsFlags & 0xC0) { // the PTS and DTS are not written out directly. For information // on how they are encoded, see // http://dvd.sourceforge.net/dvdinfo/pes-hdr.html pes.pts = (payload[9] & 0x0E) << 27 | (payload[10] & 0xFF) << 20 | (payload[11] & 0xFE) << 12 | (payload[12] & 0xFF) << 5 | (payload[13] & 0xFE) >>> 3; pes.pts *= 4; // Left shift by 2 pes.pts += (payload[13] & 0x06) >>> 1; // OR by the two LSBs pes.dts = pes.pts; if (ptsDtsFlags & 0x40) { pes.dts = (payload[14] & 0x0E ) << 27 | (payload[15] & 0xFF ) << 20 | (payload[16] & 0xFE ) << 12 | (payload[17] & 0xFF ) << 5 | (payload[18] & 0xFE ) >>> 3; pes.dts *= 4; // Left shift by 2 pes.dts += (payload[18] & 0x06) >>> 1; // OR by the two LSBs } } // the data section starts immediately after the PES header. // pes_header_data_length specifies the number of header bytes // that follow the last byte of the field. pes.data = payload.subarray(9 + payload[8]); }, flushStream = function(stream, type) { var packetData = new Uint8Array(stream.size), event = { type: type }, i = 0, fragment; // do nothing if there is no buffered data if (!stream.data.length) { return; } event.trackId = stream.data[0].pid; // reassemble the packet while (stream.data.length) { fragment = stream.data.shift(); packetData.set(fragment.data, i); i += fragment.data.byteLength; } // parse assembled packet's PES header parsePes(packetData, event); stream.size = 0; self.trigger('data', event); }, self; ElementaryStream.prototype.init.call(this); self = this; this.push = function(data) { ({ pat: function() { // we have to wait for the PMT to arrive as well before we // have any meaningful metadata }, pes: function() { var stream, streamType; switch (data.streamType) { case StreamTypes.H264_STREAM_TYPE: case m2tsStreamTypes.H264_STREAM_TYPE: stream = video; streamType = 'video'; break; case StreamTypes.ADTS_STREAM_TYPE: stream = audio; streamType = 'audio'; break; case StreamTypes.METADATA_STREAM_TYPE: stream = timedMetadata; streamType = 'timed-metadata'; break; default: // ignore unknown stream types return; } // if a new packet is starting, we can flush the completed // packet if (data.payloadUnitStartIndicator) { flushStream(stream, streamType); } // buffer this fragment until we are sure we've received the // complete payload stream.data.push(data); stream.size += data.data.byteLength; }, pmt: function() { var event = { type: 'metadata', tracks: [] }, programMapTable = data.programMapTable, k, track; // translate streams to tracks for (k in programMapTable) { if (programMapTable.hasOwnProperty(k)) { track = { timelineStartInfo: { baseMediaDecodeTime: 0 } }; track.id = +k; if (programMapTable[k] === m2tsStreamTypes.H264_STREAM_TYPE) { track.codec = 'avc'; track.type = 'video'; } else if (programMapTable[k] === m2tsStreamTypes.ADTS_STREAM_TYPE) { track.codec = 'adts'; track.type = 'audio'; } event.tracks.push(track); } } self.trigger('data', event); } })[data.type](); }; /** * Flush any remaining input. Video PES packets may be of variable * length. Normally, the start of a new video packet can trigger the * finalization of the previous packet. That is not possible if no * more video is forthcoming, however. In that case, some other * mechanism (like the end of the file) has to be employed. When it is * clear that no additional data is forthcoming, calling this method * will flush the buffered packets. */ this.flush = function() { // !!THIS ORDER IS IMPORTANT!! // video first then audio flushStream(video, 'video'); flushStream(audio, 'audio'); flushStream(timedMetadata, 'timed-metadata'); this.trigger('done'); }; }; ElementaryStream.prototype = new Stream(); var m2ts = { PAT_PID: 0x0000, MP2T_PACKET_LENGTH: MP2T_PACKET_LENGTH, TransportPacketStream: TransportPacketStream, TransportParseStream: TransportParseStream, ElementaryStream: ElementaryStream, CaptionStream: CaptionStream.CaptionStream, Cea608Stream: CaptionStream.Cea608Stream, MetadataStream: require('./metadata-stream'), }; for (var type in StreamTypes) { if (StreamTypes.hasOwnProperty(type)) { m2ts[type] = StreamTypes[type]; } } module.exports = m2ts; },{"../utils/stream.js":49,"./caption-stream":38,"./metadata-stream":41,"./stream-types":42,"./stream-types.js":42}],41:[function(require,module,exports){ /** * Accepts program elementary stream (PES) data events and parses out * ID3 metadata from them, if present. * @see http://id3.org/id3v2.3.0 */ 'use strict'; var Stream = require('../utils/stream'), StreamTypes = require('./stream-types'), // return a percent-encoded representation of the specified byte range // @see http://en.wikipedia.org/wiki/Percent-encoding percentEncode = function(bytes, start, end) { var i, result = ''; for (i = start; i < end; i++) { result += '%' + ('00' + bytes[i].toString(16)).slice(-2); } return result; }, // return the string representation of the specified byte range, // interpreted as UTf-8. parseUtf8 = function(bytes, start, end) { return decodeURIComponent(percentEncode(bytes, start, end)); }, // return the string representation of the specified byte range, // interpreted as ISO-8859-1. parseIso88591 = function(bytes, start, end) { return unescape(percentEncode(bytes, start, end)); // jshint ignore:line }, parseSyncSafeInteger = function (data) { return (data[0] << 21) | (data[1] << 14) | (data[2] << 7) | (data[3]); }, tagParsers = { 'TXXX': function(tag) { var i; if (tag.data[0] !== 3) { // ignore frames with unrecognized character encodings return; } for (i = 1; i < tag.data.length; i++) { if (tag.data[i] === 0) { // parse the text fields tag.description = parseUtf8(tag.data, 1, i); // do not include the null terminator in the tag value tag.value = parseUtf8(tag.data, i + 1, tag.data.length - 1); break; } } tag.data = tag.value; }, 'WXXX': function(tag) { var i; if (tag.data[0] !== 3) { // ignore frames with unrecognized character encodings return; } for (i = 1; i < tag.data.length; i++) { if (tag.data[i] === 0) { // parse the description and URL fields tag.description = parseUtf8(tag.data, 1, i); tag.url = parseUtf8(tag.data, i + 1, tag.data.length); break; } } }, 'PRIV': function(tag) { var i; for (i = 0; i < tag.data.length; i++) { if (tag.data[i] === 0) { // parse the description and URL fields tag.owner = parseIso88591(tag.data, 0, i); break; } } tag.privateData = tag.data.subarray(i + 1); tag.data = tag.privateData; } }, MetadataStream; MetadataStream = function(options) { var settings = { debug: !!(options && options.debug), // the bytes of the program-level descriptor field in MP2T // see ISO/IEC 13818-1:2013 (E), section 2.6 "Program and // program element descriptors" descriptor: options && options.descriptor }, // the total size in bytes of the ID3 tag being parsed tagSize = 0, // tag data that is not complete enough to be parsed buffer = [], // the total number of bytes currently in the buffer bufferSize = 0, i; MetadataStream.prototype.init.call(this); // calculate the text track in-band metadata track dispatch type // https://html.spec.whatwg.org/multipage/embedded-content.html#steps-to-expose-a-media-resource-specific-text-track this.dispatchType = StreamTypes.METADATA_STREAM_TYPE.toString(16); if (settings.descriptor) { for (i = 0; i < settings.descriptor.length; i++) { this.dispatchType += ('00' + settings.descriptor[i].toString(16)).slice(-2); } } this.push = function(chunk) { var tag, frameStart, frameSize, frame, i, frameHeader; if (chunk.type !== 'timed-metadata') { return; } // if data_alignment_indicator is set in the PES header, // we must have the start of a new ID3 tag. Assume anything // remaining in the buffer was malformed and throw it out if (chunk.dataAlignmentIndicator) { bufferSize = 0; buffer.length = 0; } // ignore events that don't look like ID3 data if (buffer.length === 0 && (chunk.data.length < 10 || chunk.data[0] !== 'I'.charCodeAt(0) || chunk.data[1] !== 'D'.charCodeAt(0) || chunk.data[2] !== '3'.charCodeAt(0))) { if (settings.debug) { console.log('Skipping unrecognized metadata packet'); } return; } // add this chunk to the data we've collected so far buffer.push(chunk); bufferSize += chunk.data.byteLength; // grab the size of the entire frame from the ID3 header if (buffer.length === 1) { // the frame size is transmitted as a 28-bit integer in the // last four bytes of the ID3 header. // The most significant bit of each byte is dropped and the // results concatenated to recover the actual value. tagSize = parseSyncSafeInteger(chunk.data.subarray(6, 10)); // ID3 reports the tag size excluding the header but it's more // convenient for our comparisons to include it tagSize += 10; } // if the entire frame has not arrived, wait for more data if (bufferSize < tagSize) { return; } // collect the entire frame so it can be parsed tag = { data: new Uint8Array(tagSize), frames: [], pts: buffer[0].pts, dts: buffer[0].dts }; for (i = 0; i < tagSize;) { tag.data.set(buffer[0].data.subarray(0, tagSize - i), i); i += buffer[0].data.byteLength; bufferSize -= buffer[0].data.byteLength; buffer.shift(); } // find the start of the first frame and the end of the tag frameStart = 10; if (tag.data[5] & 0x40) { // advance the frame start past the extended header frameStart += 4; // header size field frameStart += parseSyncSafeInteger(tag.data.subarray(10, 14)); // clip any padding off the end tagSize -= parseSyncSafeInteger(tag.data.subarray(16, 20)); } // parse one or more ID3 frames // http://id3.org/id3v2.3.0#ID3v2_frame_overview do { // determine the number of bytes in this frame frameSize = parseSyncSafeInteger(tag.data.subarray(frameStart + 4, frameStart + 8)); if (frameSize < 1) { return console.log('Malformed ID3 frame encountered. Skipping metadata parsing.'); } frameHeader = String.fromCharCode(tag.data[frameStart], tag.data[frameStart + 1], tag.data[frameStart + 2], tag.data[frameStart + 3]); frame = { id: frameHeader, data: tag.data.subarray(frameStart + 10, frameStart + frameSize + 10) }; frame.key = frame.id; if (tagParsers[frame.id]) { tagParsers[frame.id](frame); if (frame.owner === 'com.apple.streaming.transportStreamTimestamp') { var d = frame.data, size = ((d[3] & 0x01) << 30) | (d[4] << 22) | (d[5] << 14) | (d[6] << 6) | (d[7] >>> 2); size *= 4; size += d[7] & 0x03; frame.timeStamp = size; this.trigger('timestamp', frame); } } tag.frames.push(frame); frameStart += 10; // advance past the frame header frameStart += frameSize; // advance past the frame body } while (frameStart < tagSize); this.trigger('data', tag); }; }; MetadataStream.prototype = new Stream(); module.exports = MetadataStream; },{"../utils/stream":49,"./stream-types":42}],42:[function(require,module,exports){ 'use strict'; module.exports = { H264_STREAM_TYPE: 0x1B, ADTS_STREAM_TYPE: 0x0F, METADATA_STREAM_TYPE: 0x15 }; },{}],43:[function(require,module,exports){ module.exports = { generator: require('./mp4-generator'), Transmuxer: require('./transmuxer').Transmuxer, AudioSegmentStream: require('./transmuxer').AudioSegmentStream, VideoSegmentStream: require('./transmuxer').VideoSegmentStream, tools: require('../tools/mp4-inspector'), }; },{"../tools/mp4-inspector":47,"./mp4-generator":44,"./transmuxer":45}],44:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2015 Brightcove * All rights reserved. * * Functions that generate fragmented MP4s suitable for use with Media * Source Extensions. */ 'use strict'; var box, dinf, esds, ftyp, mdat, mfhd, minf, moof, moov, mvex, mvhd, trak, tkhd, mdia, mdhd, hdlr, sdtp, stbl, stsd, styp, traf, trex, trun, types, MAJOR_BRAND, MINOR_VERSION, AVC1_BRAND, VIDEO_HDLR, AUDIO_HDLR, HDLR_TYPES, VMHD, SMHD, DREF, STCO, STSC, STSZ, STTS; // pre-calculate constants (function() { var i; types = { avc1: [], // codingname avcC: [], btrt: [], dinf: [], dref: [], esds: [], ftyp: [], hdlr: [], mdat: [], mdhd: [], mdia: [], mfhd: [], minf: [], moof: [], moov: [], mp4a: [], // codingname mvex: [], mvhd: [], sdtp: [], smhd: [], stbl: [], stco: [], stsc: [], stsd: [], stsz: [], stts: [], styp: [], tfdt: [], tfhd: [], traf: [], trak: [], trun: [], trex: [], tkhd: [], vmhd: [] }; for (i in types) { if (types.hasOwnProperty(i)) { types[i] = [ i.charCodeAt(0), i.charCodeAt(1), i.charCodeAt(2), i.charCodeAt(3) ]; } } MAJOR_BRAND = new Uint8Array([ 'i'.charCodeAt(0), 's'.charCodeAt(0), 'o'.charCodeAt(0), 'm'.charCodeAt(0) ]); AVC1_BRAND = new Uint8Array([ 'a'.charCodeAt(0), 'v'.charCodeAt(0), 'c'.charCodeAt(0), '1'.charCodeAt(0) ]); MINOR_VERSION = new Uint8Array([0, 0, 0, 1]); VIDEO_HDLR = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x00, // pre_defined 0x76, 0x69, 0x64, 0x65, // handler_type: 'vide' 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x56, 0x69, 0x64, 0x65, 0x6f, 0x48, 0x61, 0x6e, 0x64, 0x6c, 0x65, 0x72, 0x00 // name: 'VideoHandler' ]); AUDIO_HDLR = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x00, // pre_defined 0x73, 0x6f, 0x75, 0x6e, // handler_type: 'soun' 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x53, 0x6f, 0x75, 0x6e, 0x64, 0x48, 0x61, 0x6e, 0x64, 0x6c, 0x65, 0x72, 0x00 // name: 'SoundHandler' ]); HDLR_TYPES = { "video":VIDEO_HDLR, "audio": AUDIO_HDLR }; DREF = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x01, // entry_count 0x00, 0x00, 0x00, 0x0c, // entry_size 0x75, 0x72, 0x6c, 0x20, // 'url' type 0x00, // version 0 0x00, 0x00, 0x01 // entry_flags ]); SMHD = new Uint8Array([ 0x00, // version 0x00, 0x00, 0x00, // flags 0x00, 0x00, // balance, 0 means centered 0x00, 0x00 // reserved ]); STCO = new Uint8Array([ 0x00, // version 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x00 // entry_count ]); STSC = STCO; STSZ = new Uint8Array([ 0x00, // version 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x00, // sample_size 0x00, 0x00, 0x00, 0x00, // sample_count ]); STTS = STCO; VMHD = new Uint8Array([ 0x00, // version 0x00, 0x00, 0x01, // flags 0x00, 0x00, // graphicsmode 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 // opcolor ]); })(); box = function(type) { var payload = [], size = 0, i, result, view; for (i = 1; i < arguments.length; i++) { payload.push(arguments[i]); } i = payload.length; // calculate the total size we need to allocate while (i--) { size += payload[i].byteLength; } result = new Uint8Array(size + 8); view = new DataView(result.buffer, result.byteOffset, result.byteLength); view.setUint32(0, result.byteLength); result.set(type, 4); // copy the payload into the result for (i = 0, size = 8; i < payload.length; i++) { result.set(payload[i], size); size += payload[i].byteLength; } return result; }; dinf = function() { return box(types.dinf, box(types.dref, DREF)); }; esds = function(track) { return box(types.esds, new Uint8Array([ 0x00, // version 0x00, 0x00, 0x00, // flags // ES_Descriptor 0x03, // tag, ES_DescrTag 0x19, // length 0x00, 0x00, // ES_ID 0x00, // streamDependenceFlag, URL_flag, reserved, streamPriority // DecoderConfigDescriptor 0x04, // tag, DecoderConfigDescrTag 0x11, // length 0x40, // object type 0x15, // streamType 0x00, 0x06, 0x00, // bufferSizeDB 0x00, 0x00, 0xda, 0xc0, // maxBitrate 0x00, 0x00, 0xda, 0xc0, // avgBitrate // DecoderSpecificInfo 0x05, // tag, DecoderSpecificInfoTag 0x02, // length // ISO/IEC 14496-3, AudioSpecificConfig // for samplingFrequencyIndex see ISO/IEC 13818-7:2006, 8.1.3.2.2, Table 35 (track.audioobjecttype << 3) | (track.samplingfrequencyindex >>> 1), (track.samplingfrequencyindex << 7) | (track.channelcount << 3), 0x06, 0x01, 0x02 // GASpecificConfig ])); }; ftyp = function() { return box(types.ftyp, MAJOR_BRAND, MINOR_VERSION, MAJOR_BRAND, AVC1_BRAND); }; hdlr = function(type) { return box(types.hdlr, HDLR_TYPES[type]); }; mdat = function(data) { return box(types.mdat, data); }; mdhd = function(track) { var result = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x02, // creation_time 0x00, 0x00, 0x00, 0x03, // modification_time 0x00, 0x01, 0x5f, 0x90, // timescale, 90,000 "ticks" per second (track.duration >>> 24) & 0xFF, (track.duration >>> 16) & 0xFF, (track.duration >>> 8) & 0xFF, track.duration & 0xFF, // duration 0x55, 0xc4, // 'und' language (undetermined) 0x00, 0x00 ]); // Use the sample rate from the track metadata, when it is // defined. The sample rate can be parsed out of an ADTS header, for // instance. if (track.samplerate) { result[12] = (track.samplerate >>> 24) & 0xFF; result[13] = (track.samplerate >>> 16) & 0xFF; result[14] = (track.samplerate >>> 8) & 0xFF; result[15] = (track.samplerate) & 0xFF; } return box(types.mdhd, result); }; mdia = function(track) { return box(types.mdia, mdhd(track), hdlr(track.type), minf(track)); }; mfhd = function(sequenceNumber) { return box(types.mfhd, new Uint8Array([ 0x00, 0x00, 0x00, 0x00, // flags (sequenceNumber & 0xFF000000) >> 24, (sequenceNumber & 0xFF0000) >> 16, (sequenceNumber & 0xFF00) >> 8, sequenceNumber & 0xFF, // sequence_number ])); }; minf = function(track) { return box(types.minf, track.type === 'video' ? box(types.vmhd, VMHD) : box(types.smhd, SMHD), dinf(), stbl(track)); }; moof = function(sequenceNumber, tracks) { var trackFragments = [], i = tracks.length; // build traf boxes for each track fragment while (i--) { trackFragments[i] = traf(tracks[i]); } return box.apply(null, [ types.moof, mfhd(sequenceNumber) ].concat(trackFragments)); }; /** * Returns a movie box. * @param tracks {array} the tracks associated with this movie * @see ISO/IEC 14496-12:2012(E), section 8.2.1 */ moov = function(tracks) { var i = tracks.length, boxes = []; while (i--) { boxes[i] = trak(tracks[i]); } return box.apply(null, [types.moov, mvhd(0xffffffff)].concat(boxes).concat(mvex(tracks))); }; mvex = function(tracks) { var i = tracks.length, boxes = []; while (i--) { boxes[i] = trex(tracks[i]); } return box.apply(null, [types.mvex].concat(boxes)); }; mvhd = function(duration) { var bytes = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x01, // creation_time 0x00, 0x00, 0x00, 0x02, // modification_time 0x00, 0x01, 0x5f, 0x90, // timescale, 90,000 "ticks" per second (duration & 0xFF000000) >> 24, (duration & 0xFF0000) >> 16, (duration & 0xFF00) >> 8, duration & 0xFF, // duration 0x00, 0x01, 0x00, 0x00, // 1.0 rate 0x01, 0x00, // 1.0 volume 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x40, 0x00, 0x00, 0x00, // transformation: unity matrix 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // pre_defined 0xff, 0xff, 0xff, 0xff // next_track_ID ]); return box(types.mvhd, bytes); }; sdtp = function(track) { var samples = track.samples || [], bytes = new Uint8Array(4 + samples.length), flags, i; // leave the full box header (4 bytes) all zero // write the sample table for (i = 0; i < samples.length; i++) { flags = samples[i].flags; bytes[i + 4] = (flags.dependsOn << 4) | (flags.isDependedOn << 2) | (flags.hasRedundancy); } return box(types.sdtp, bytes); }; stbl = function(track) { return box(types.stbl, stsd(track), box(types.stts, STTS), box(types.stsc, STSC), box(types.stsz, STSZ), box(types.stco, STCO)); }; (function() { var videoSample, audioSample; stsd = function(track) { return box(types.stsd, new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags 0x00, 0x00, 0x00, 0x01 ]), track.type === 'video' ? videoSample(track) : audioSample(track)); }; videoSample = function(track) { var sps = track.sps || [], pps = track.pps || [], sequenceParameterSets = [], pictureParameterSets = [], i; // assemble the SPSs for (i = 0; i < sps.length; i++) { sequenceParameterSets.push((sps[i].byteLength & 0xFF00) >>> 8); sequenceParameterSets.push((sps[i].byteLength & 0xFF)); // sequenceParameterSetLength sequenceParameterSets = sequenceParameterSets.concat(Array.prototype.slice.call(sps[i])); // SPS } // assemble the PPSs for (i = 0; i < pps.length; i++) { pictureParameterSets.push((pps[i].byteLength & 0xFF00) >>> 8); pictureParameterSets.push((pps[i].byteLength & 0xFF)); pictureParameterSets = pictureParameterSets.concat(Array.prototype.slice.call(pps[i])); } return box(types.avc1, new Uint8Array([ 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x01, // data_reference_index 0x00, 0x00, // pre_defined 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // pre_defined (track.width & 0xff00) >> 8, track.width & 0xff, // width (track.height & 0xff00) >> 8, track.height & 0xff, // height 0x00, 0x48, 0x00, 0x00, // horizresolution 0x00, 0x48, 0x00, 0x00, // vertresolution 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x01, // frame_count 0x13, 0x76, 0x69, 0x64, 0x65, 0x6f, 0x6a, 0x73, 0x2d, 0x63, 0x6f, 0x6e, 0x74, 0x72, 0x69, 0x62, 0x2d, 0x68, 0x6c, 0x73, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // compressorname 0x00, 0x18, // depth = 24 0x11, 0x11 // pre_defined = -1 ]), box(types.avcC, new Uint8Array([ 0x01, // configurationVersion track.profileIdc, // AVCProfileIndication track.profileCompatibility, // profile_compatibility track.levelIdc, // AVCLevelIndication 0xff // lengthSizeMinusOne, hard-coded to 4 bytes ].concat([ sps.length // numOfSequenceParameterSets ]).concat(sequenceParameterSets).concat([ pps.length // numOfPictureParameterSets ]).concat(pictureParameterSets))), // "PPS" box(types.btrt, new Uint8Array([ 0x00, 0x1c, 0x9c, 0x80, // bufferSizeDB 0x00, 0x2d, 0xc6, 0xc0, // maxBitrate 0x00, 0x2d, 0xc6, 0xc0 ])) // avgBitrate ); }; audioSample = function(track) { return box(types.mp4a, new Uint8Array([ // SampleEntry, ISO/IEC 14496-12 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x01, // data_reference_index // AudioSampleEntry, ISO/IEC 14496-12 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, 0x00, 0x00, // reserved (track.channelcount & 0xff00) >> 8, (track.channelcount & 0xff), // channelcount (track.samplesize & 0xff00) >> 8, (track.samplesize & 0xff), // samplesize 0x00, 0x00, // pre_defined 0x00, 0x00, // reserved (track.samplerate & 0xff00) >> 8, (track.samplerate & 0xff), 0x00, 0x00 // samplerate, 16.16 // MP4AudioSampleEntry, ISO/IEC 14496-14 ]), esds(track)); }; })(); styp = function() { return box(types.styp, MAJOR_BRAND, MINOR_VERSION, MAJOR_BRAND); }; tkhd = function(track) { var result = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x07, // flags 0x00, 0x00, 0x00, 0x00, // creation_time 0x00, 0x00, 0x00, 0x00, // modification_time (track.id & 0xFF000000) >> 24, (track.id & 0xFF0000) >> 16, (track.id & 0xFF00) >> 8, track.id & 0xFF, // track_ID 0x00, 0x00, 0x00, 0x00, // reserved (track.duration & 0xFF000000) >> 24, (track.duration & 0xFF0000) >> 16, (track.duration & 0xFF00) >> 8, track.duration & 0xFF, // duration 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // reserved 0x00, 0x00, // layer 0x00, 0x00, // alternate_group 0x01, 0x00, // non-audio track volume 0x00, 0x00, // reserved 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x40, 0x00, 0x00, 0x00, // transformation: unity matrix (track.width & 0xFF00) >> 8, track.width & 0xFF, 0x00, 0x00, // width (track.height & 0xFF00) >> 8, track.height & 0xFF, 0x00, 0x00 // height ]); return box(types.tkhd, result); }; /** * Generate a track fragment (traf) box. A traf box collects metadata * about tracks in a movie fragment (moof) box. */ traf = function(track) { var trackFragmentHeader, trackFragmentDecodeTime, trackFragmentRun, sampleDependencyTable, dataOffset; trackFragmentHeader = box(types.tfhd, new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x3a, // flags (track.id & 0xFF000000) >> 24, (track.id & 0xFF0000) >> 16, (track.id & 0xFF00) >> 8, (track.id & 0xFF), // track_ID 0x00, 0x00, 0x00, 0x01, // sample_description_index 0x00, 0x00, 0x00, 0x00, // default_sample_duration 0x00, 0x00, 0x00, 0x00, // default_sample_size 0x00, 0x00, 0x00, 0x00 // default_sample_flags ])); trackFragmentDecodeTime = box(types.tfdt, new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags // baseMediaDecodeTime (track.baseMediaDecodeTime >>> 24) & 0xFF, (track.baseMediaDecodeTime >>> 16) & 0xFF, (track.baseMediaDecodeTime >>> 8) & 0xFF, track.baseMediaDecodeTime & 0xFF ])); // the data offset specifies the number of bytes from the start of // the containing moof to the first payload byte of the associated // mdat dataOffset = (32 + // tfhd 16 + // tfdt 8 + // traf header 16 + // mfhd 8 + // moof header 8); // mdat header // audio tracks require less metadata if (track.type === 'audio') { trackFragmentRun = trun(track, dataOffset); return box(types.traf, trackFragmentHeader, trackFragmentDecodeTime, trackFragmentRun); } // video tracks should contain an independent and disposable samples // box (sdtp) // generate one and adjust offsets to match sampleDependencyTable = sdtp(track); trackFragmentRun = trun(track, sampleDependencyTable.length + dataOffset); return box(types.traf, trackFragmentHeader, trackFragmentDecodeTime, trackFragmentRun, sampleDependencyTable); }; /** * Generate a track box. * @param track {object} a track definition * @return {Uint8Array} the track box */ trak = function(track) { track.duration = track.duration || 0xffffffff; return box(types.trak, tkhd(track), mdia(track)); }; trex = function(track) { var result = new Uint8Array([ 0x00, // version 0 0x00, 0x00, 0x00, // flags (track.id & 0xFF000000) >> 24, (track.id & 0xFF0000) >> 16, (track.id & 0xFF00) >> 8, (track.id & 0xFF), // track_ID 0x00, 0x00, 0x00, 0x01, // default_sample_description_index 0x00, 0x00, 0x00, 0x00, // default_sample_duration 0x00, 0x00, 0x00, 0x00, // default_sample_size 0x00, 0x01, 0x00, 0x01 // default_sample_flags ]); // the last two bytes of default_sample_flags is the sample // degradation priority, a hint about the importance of this sample // relative to others. Lower the degradation priority for all sample // types other than video. if (track.type !== 'video') { result[result.length - 1] = 0x00; } return box(types.trex, result); }; (function() { var audioTrun, videoTrun, trunHeader; // This method assumes all samples are uniform. That is, if a // duration is present for the first sample, it will be present for // all subsequent samples. // see ISO/IEC 14496-12:2012, Section 8.8.8.1 trunHeader = function(samples, offset) { var durationPresent = 0, sizePresent = 0, flagsPresent = 0, compositionTimeOffset = 0; // trun flag constants if (samples.length) { if (samples[0].duration !== undefined) { durationPresent = 0x1; } if (samples[0].size !== undefined) { sizePresent = 0x2; } if (samples[0].flags !== undefined) { flagsPresent = 0x4; } if (samples[0].compositionTimeOffset !== undefined) { compositionTimeOffset = 0x8; } } return [ 0x00, // version 0 0x00, durationPresent | sizePresent | flagsPresent | compositionTimeOffset, 0x01, // flags (samples.length & 0xFF000000) >>> 24, (samples.length & 0xFF0000) >>> 16, (samples.length & 0xFF00) >>> 8, samples.length & 0xFF, // sample_count (offset & 0xFF000000) >>> 24, (offset & 0xFF0000) >>> 16, (offset & 0xFF00) >>> 8, offset & 0xFF // data_offset ]; }; videoTrun = function(track, offset) { var bytes, samples, sample, i; samples = track.samples || []; offset += 8 + 12 + (16 * samples.length); bytes = trunHeader(samples, offset); for (i = 0; i < samples.length; i++) { sample = samples[i]; bytes = bytes.concat([ (sample.duration & 0xFF000000) >>> 24, (sample.duration & 0xFF0000) >>> 16, (sample.duration & 0xFF00) >>> 8, sample.duration & 0xFF, // sample_duration (sample.size & 0xFF000000) >>> 24, (sample.size & 0xFF0000) >>> 16, (sample.size & 0xFF00) >>> 8, sample.size & 0xFF, // sample_size (sample.flags.isLeading << 2) | sample.flags.dependsOn, (sample.flags.isDependedOn << 6) | (sample.flags.hasRedundancy << 4) | (sample.flags.paddingValue << 1) | sample.flags.isNonSyncSample, sample.flags.degradationPriority & 0xF0 << 8, sample.flags.degradationPriority & 0x0F, // sample_flags (sample.compositionTimeOffset & 0xFF000000) >>> 24, (sample.compositionTimeOffset & 0xFF0000) >>> 16, (sample.compositionTimeOffset & 0xFF00) >>> 8, sample.compositionTimeOffset & 0xFF // sample_composition_time_offset ]); } return box(types.trun, new Uint8Array(bytes)); }; audioTrun = function(track, offset) { var bytes, samples, sample, i; samples = track.samples || []; offset += 8 + 12 + (8 * samples.length); bytes = trunHeader(samples, offset); for (i = 0; i < samples.length; i++) { sample = samples[i]; bytes = bytes.concat([ (sample.duration & 0xFF000000) >>> 24, (sample.duration & 0xFF0000) >>> 16, (sample.duration & 0xFF00) >>> 8, sample.duration & 0xFF, // sample_duration (sample.size & 0xFF000000) >>> 24, (sample.size & 0xFF0000) >>> 16, (sample.size & 0xFF00) >>> 8, sample.size & 0xFF]); // sample_size } return box(types.trun, new Uint8Array(bytes)); }; trun = function(track, offset) { if (track.type === 'audio') { return audioTrun(track, offset); } else { return videoTrun(track, offset); } }; })(); module.exports = { ftyp: ftyp, mdat: mdat, moof: moof, moov: moov, initSegment: function(tracks) { var fileType = ftyp(), movie = moov(tracks), result; result = new Uint8Array(fileType.byteLength + movie.byteLength); result.set(fileType); result.set(movie, fileType.byteLength); return result; } }; },{}],45:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2015 Brightcove * All rights reserved. * * A stream-based mp2t to mp4 converter. This utility can be used to * deliver mp4s to a SourceBuffer on platforms that support native * Media Source Extensions. */ 'use strict'; var Stream = require('../utils/stream.js'); var mp4 = require('./mp4-generator.js'); var m2ts = require('../m2ts/m2ts.js'); var AdtsStream = require('../codecs/adts.js'); var H264Stream = require('../codecs/h264').H264Stream; var AacStream = require('../aac'); // object types var VideoSegmentStream, AudioSegmentStream, Transmuxer, CoalesceStream; // Helper functions var defaultSample, collectDtsInfo, clearDtsInfo, calculateTrackBaseMediaDecodeTime, arrayEquals, sumFrameByteLengths; /** * Default sample object * see ISO/IEC 14496-12:2012, section 8.6.4.3 */ defaultSample = { size: 0, flags: { isLeading: 0, dependsOn: 1, isDependedOn: 0, hasRedundancy: 0, degradationPriority: 0 } }; /** * Compare two arrays (even typed) for same-ness */ arrayEquals = function(a, b) { var i; if (a.length !== b.length) { return false; } // compare the value of each element in the array for (i = 0; i < a.length; i++) { if (a[i] !== b[i]) { return false; } } return true; }; /** * Sum the `byteLength` properties of the data in each AAC frame */ sumFrameByteLengths = function(array) { var i, currentObj, sum = 0; // sum the byteLength's all each nal unit in the frame for (i = 0; i < array.length; i++) { currentObj = array[i]; sum += currentObj.data.byteLength; } return sum; }; /** * Constructs a single-track, ISO BMFF media segment from AAC data * events. The output of this stream can be fed to a SourceBuffer * configured with a suitable initialization segment. */ AudioSegmentStream = function(track) { var adtsFrames = [], sequenceNumber = 0, earliestAllowedDts = 0; AudioSegmentStream.prototype.init.call(this); this.push = function(data) { collectDtsInfo(track, data); if (track) { track.audioobjecttype = data.audioobjecttype; track.channelcount = data.channelcount; track.samplerate = data.samplerate; track.samplingfrequencyindex = data.samplingfrequencyindex; track.samplesize = data.samplesize; } // buffer audio data until end() is called adtsFrames.push(data); }; this.setEarliestDts = function(earliestDts) { earliestAllowedDts = earliestDts - track.timelineStartInfo.baseMediaDecodeTime; }; this.flush = function() { var frames, moof, mdat, boxes; // return early if no audio data has been observed if (adtsFrames.length === 0) { this.trigger('done'); return; } frames = this.trimAdtsFramesByEarliestDts_(adtsFrames); // we have to build the index from byte locations to // samples (that is, adts frames) in the audio data track.samples = this.generateSampleTable_(frames); // concatenate the audio data to constuct the mdat mdat = mp4.mdat(this.concatenateFrameData_(frames)); adtsFrames = []; calculateTrackBaseMediaDecodeTime(track); moof = mp4.moof(sequenceNumber, [track]); boxes = new Uint8Array(moof.byteLength + mdat.byteLength); // bump the sequence number for next time sequenceNumber++; boxes.set(moof); boxes.set(mdat, moof.byteLength); clearDtsInfo(track); this.trigger('data', {track: track, boxes: boxes}); this.trigger('done'); }; // If the audio segment extends before the earliest allowed dts // value, remove AAC frames until starts at or after the earliest // allowed DTS so that we don't end up with a negative baseMedia- // DecodeTime for the audio track this.trimAdtsFramesByEarliestDts_ = function(adtsFrames) { if (track.minSegmentDts >= earliestAllowedDts) { return adtsFrames; } // We will need to recalculate the earliest segment Dts track.minSegmentDts = Infinity; return adtsFrames.filter(function(currentFrame) { // If this is an allowed frame, keep it and record it's Dts if (currentFrame.dts >= earliestAllowedDts) { track.minSegmentDts = Math.min(track.minSegmentDts, currentFrame.dts); track.minSegmentPts = track.minSegmentDts; return true; } // Otherwise, discard it return false; }); }; // generate the track's raw mdat data from an array of frames this.generateSampleTable_ = function(frames) { var i, currentFrame, samples = []; for (i = 0; i < frames.length; i++) { currentFrame = frames[i]; samples.push({ size: currentFrame.data.byteLength, duration: 1024 // For AAC audio, all samples contain 1024 samples }); } return samples; }; // generate the track's sample table from an array of frames this.concatenateFrameData_ = function(frames) { var i, currentFrame, dataOffset = 0, data = new Uint8Array(sumFrameByteLengths(frames)); for (i = 0; i < frames.length; i++) { currentFrame = frames[i]; data.set(currentFrame.data, dataOffset); dataOffset += currentFrame.data.byteLength; } return data; }; }; AudioSegmentStream.prototype = new Stream(); /** * Constructs a single-track, ISO BMFF media segment from H264 data * events. The output of this stream can be fed to a SourceBuffer * configured with a suitable initialization segment. * @param track {object} track metadata configuration */ VideoSegmentStream = function(track) { var sequenceNumber = 0, nalUnits = [], config, pps; VideoSegmentStream.prototype.init.call(this); delete track.minPTS; this.gopCache_ = []; this.push = function(nalUnit) { collectDtsInfo(track, nalUnit); // record the track config if (nalUnit.nalUnitType === 'seq_parameter_set_rbsp' && !config) { config = nalUnit.config; track.width = config.width; track.height = config.height; track.sps = [nalUnit.data]; track.profileIdc = config.profileIdc; track.levelIdc = config.levelIdc; track.profileCompatibility = config.profileCompatibility; } if (nalUnit.nalUnitType === 'pic_parameter_set_rbsp' && !pps) { pps = nalUnit.data; track.pps = [nalUnit.data]; } // buffer video until flush() is called nalUnits.push(nalUnit); }; this.flush = function() { var frames, gopForFusion, gops, moof, mdat, boxes; // Throw away nalUnits at the start of the byte stream until // we find the first AUD while (nalUnits.length) { if (nalUnits[0].nalUnitType === 'access_unit_delimiter_rbsp') { break; } nalUnits.shift(); } // Return early if no video data has been observed if (nalUnits.length === 0) { this.resetStream_(); this.trigger('done'); return; } // Organize the raw nal-units into arrays that represent // higher-level constructs such as frames and gops // (group-of-pictures) frames = this.groupNalsIntoFrames_(nalUnits); gops = this.groupFramesIntoGops_(frames); // If the first frame of this fragment is not a keyframe we have // a problem since MSE (on Chrome) requires a leading keyframe. // // We have two approaches to repairing this situation: // 1) GOP-FUSION: // This is where we keep track of the GOPS (group-of-pictures) // from previous fragments and attempt to find one that we can // prepend to the current fragment in order to create a valid // fragment. // 2) KEYFRAME-PULLING: // Here we search for the first keyframe in the fragment and // throw away all the frames between the start of the fragment // and that keyframe. We then extend the duration and pull the // PTS of the keyframe forward so that it covers the time range // of the frames that were disposed of. // // #1 is far prefereable over #2 which can cause "stuttering" but // requires more things to be just right. if (!gops[0][0].keyFrame) { // Search for a gop for fusion from our gopCache gopForFusion = this.getGopForFusion_(nalUnits[0], track); if (gopForFusion) { gops.unshift(gopForFusion); // Adjust Gops' metadata to account for the inclusion of the // new gop at the beginning gops.byteLength += gopForFusion.byteLength; gops.nalCount += gopForFusion.nalCount; gops.pts = gopForFusion.pts; gops.dts = gopForFusion.dts; gops.duration += gopForFusion.duration; } else { // If we didn't find a candidate gop fall back to keyrame-pulling gops = this.extendFirstKeyFrame_(gops); } } collectDtsInfo(track, gops); // First, we have to build the index from byte locations to // samples (that is, frames) in the video data track.samples = this.generateSampleTable_(gops); // Concatenate the video data and construct the mdat mdat = mp4.mdat(this.concatenateNalData_(gops)); // save all the nals in the last GOP into the gop cache this.gopCache_.unshift({ gop: gops.pop(), pps: track.pps, sps: track.sps }); // Keep a maximum of 6 GOPs in the cache this.gopCache_.length = Math.min(6, this.gopCache_.length); // Clear nalUnits nalUnits = []; calculateTrackBaseMediaDecodeTime(track); this.trigger('timelineStartInfo', track.timelineStartInfo); moof = mp4.moof(sequenceNumber, [track]); // it would be great to allocate this array up front instead of // throwing away hundreds of media segment fragments boxes = new Uint8Array(moof.byteLength + mdat.byteLength); // Bump the sequence number for next time sequenceNumber++; boxes.set(moof); boxes.set(mdat, moof.byteLength); this.trigger('data', {track: track, boxes: boxes}); this.resetStream_(); // Continue with the flush process now this.trigger('done'); }; this.resetStream_ = function() { clearDtsInfo(track); // reset config and pps because they may differ across segments // for instance, when we are rendition switching config = undefined; pps = undefined; }; // Search for a candidate Gop for gop-fusion from the gop cache and // return it or return null if no good candidate was found this.getGopForFusion_ = function (nalUnit) { var halfSecond = 45000, // Half-a-second in a 90khz clock allowableOverlap = 10000, // About 3 frames @ 30fps nearestDistance = Infinity, dtsDistance, nearestGopObj, currentGop, currentGopObj, i; // Search for the GOP nearest to the beginning of this nal unit for (i = 0; i < this.gopCache_.length; i++) { currentGopObj = this.gopCache_[i]; currentGop = currentGopObj.gop; // Reject Gops with different SPS or PPS if (!(track.pps && arrayEquals(track.pps[0], currentGopObj.pps[0])) || !(track.sps && arrayEquals(track.sps[0], currentGopObj.sps[0]))) { continue; } // Reject Gops that would require a negative baseMediaDecodeTime if (currentGop.dts < track.timelineStartInfo.dts) { continue; } // The distance between the end of the gop and the start of the nalUnit dtsDistance = (nalUnit.dts - currentGop.dts) - currentGop.duration; // Only consider GOPS that start before the nal unit and end within // a half-second of the nal unit if (dtsDistance >= -allowableOverlap && dtsDistance <= halfSecond) { // Always use the closest GOP we found if there is more than // one candidate if (!nearestGopObj || nearestDistance > dtsDistance) { nearestGopObj = currentGopObj; nearestDistance = dtsDistance; } } } if (nearestGopObj) { return nearestGopObj.gop; } return null; }; this.extendFirstKeyFrame_ = function(gops) { var h, i, currentGop, newGops; if (!gops[0][0].keyFrame) { // Remove the first GOP currentGop = gops.shift(); gops.byteLength -= currentGop.byteLength; gops.nalCount -= currentGop.nalCount; // Extend the first frame of what is now the // first gop to cover the time period of the // frames we just removed gops[0][0].dts = currentGop.dts; gops[0][0].pts = currentGop.pts; gops[0][0].duration += currentGop.duration; } return gops; }; // Convert an array of nal units into an array of frames with each frame being // composed of the nal units that make up that frame // Also keep track of cummulative data about the frame from the nal units such // as the frame duration, starting pts, etc. this.groupNalsIntoFrames_ = function(nalUnits) { var i, currentNal, startPts, startDts, currentFrame = [], frames = []; currentFrame.byteLength = 0; for (i = 0; i < nalUnits.length; i++) { currentNal = nalUnits[i]; // Split on 'aud'-type nal units if (currentNal.nalUnitType === 'access_unit_delimiter_rbsp') { // Since the very first nal unit is expected to be an AUD // only push to the frames array when currentFrame is not empty if (currentFrame.length) { currentFrame.duration = currentNal.dts - currentFrame.dts; frames.push(currentFrame); } currentFrame = [currentNal]; currentFrame.byteLength = currentNal.data.byteLength; currentFrame.pts = currentNal.pts; currentFrame.dts = currentNal.dts; } else { // Specifically flag key frames for ease of use later if (currentNal.nalUnitType === 'slice_layer_without_partitioning_rbsp_idr') { currentFrame.keyFrame = true; } currentFrame.duration = currentNal.dts - currentFrame.dts; currentFrame.byteLength += currentNal.data.byteLength; currentFrame.push(currentNal); } } // For the last frame, use the duration of the previous frame if we // have nothing better to go on if (frames.length && !currentFrame.duration || currentFrame.duration <= 0) { currentFrame.duration = frames[frames.length - 1].duration; } // Push the final frame frames.push(currentFrame); return frames; }; // Convert an array of frames into an array of Gop with each Gop being composed // of the frames that make up that Gop // Also keep track of cummulative data about the Gop from the frames such as the // Gop duration, starting pts, etc. this.groupFramesIntoGops_ = function(frames) { var i, currentFrame, currentGop = [], gops = []; // We must pre-set some of the values on the Gop since we // keep running totals of these values currentGop.byteLength = 0; currentGop.nalCount = 0; currentGop.duration = 0; currentGop.pts = frames[0].pts; currentGop.dts = frames[0].dts; // store some metadata about all the Gops gops.byteLength = 0; gops.nalCount = 0; gops.duration = 0; gops.pts = frames[0].pts; gops.dts = frames[0].dts; for (i = 0; i < frames.length; i++) { currentFrame = frames[i]; if (currentFrame.keyFrame) { // Since the very first frame is expected to be an keyframe // only push to the gops array when currentGop is not empty if (currentGop.length) { gops.push(currentGop); gops.byteLength += currentGop.byteLength; gops.nalCount += currentGop.nalCount; gops.duration += currentGop.duration; } currentGop = [currentFrame]; currentGop.nalCount = currentFrame.length; currentGop.byteLength = currentFrame.byteLength; currentGop.pts = currentFrame.pts; currentGop.dts = currentFrame.dts; currentGop.duration = currentFrame.duration; } else { currentGop.duration += currentFrame.duration; currentGop.nalCount += currentFrame.length; currentGop.byteLength += currentFrame.byteLength; currentGop.push(currentFrame); } } if (gops.length && currentGop.duration <= 0) { currentGop.duration = gops[gops.length - 1].duration; } gops.byteLength += currentGop.byteLength; gops.nalCount += currentGop.nalCount; gops.duration += currentGop.duration; // push the final Gop gops.push(currentGop); return gops; }; // generate the track's sample table from an array of gops this.generateSampleTable_ = function(gops, baseDataOffset) { var h, i, sample, currentGop, currentFrame, currentSample, dataOffset = baseDataOffset || 0, samples = []; for (h = 0; h < gops.length; h++) { currentGop = gops[h]; for (i = 0; i < currentGop.length; i++) { currentFrame = currentGop[i]; sample = Object.create(defaultSample); sample.dataOffset = dataOffset; sample.compositionTimeOffset = currentFrame.pts - currentFrame.dts; sample.duration = currentFrame.duration; sample.size = 4 * currentFrame.length; // Space for nal unit size sample.size += currentFrame.byteLength; if (currentFrame.keyFrame) { sample.flags.dependsOn = 2; } dataOffset += sample.size; samples.push(sample); } } return samples; }; // generate the track's raw mdat data from an array of gops this.concatenateNalData_ = function (gops) { var h, i, j, currentGop, currentFrame, currentNal, dataOffset = 0, nalsByteLength = gops.byteLength, numberOfNals = gops.nalCount, totalByteLength = nalsByteLength + 4 * numberOfNals, data = new Uint8Array(totalByteLength), view = new DataView(data.buffer); // For each Gop.. for (h = 0; h < gops.length; h++) { currentGop = gops[h]; // For each Frame.. for (i = 0; i < currentGop.length; i++) { currentFrame = currentGop[i]; // For each NAL.. for (j = 0; j < currentFrame.length; j++) { currentNal = currentFrame[j]; view.setUint32(dataOffset, currentNal.data.byteLength); dataOffset += 4; data.set(currentNal.data, dataOffset); dataOffset += currentNal.data.byteLength; } } } return data; }; }; VideoSegmentStream.prototype = new Stream(); /** * Store information about the start and end of the track and the * duration for each frame/sample we process in order to calculate * the baseMediaDecodeTime */ collectDtsInfo = function (track, data) { if (typeof data.pts === 'number') { if (track.timelineStartInfo.pts === undefined) { track.timelineStartInfo.pts = data.pts; } if (track.minSegmentPts === undefined) { track.minSegmentPts = data.pts; } else { track.minSegmentPts = Math.min(track.minSegmentPts, data.pts); } if (track.maxSegmentPts === undefined) { track.maxSegmentPts = data.pts; } else { track.maxSegmentPts = Math.max(track.maxSegmentPts, data.pts); } } if (typeof data.dts === 'number') { if (track.timelineStartInfo.dts === undefined) { track.timelineStartInfo.dts = data.dts; } if (track.minSegmentDts === undefined) { track.minSegmentDts = data.dts; } else { track.minSegmentDts = Math.min(track.minSegmentDts, data.dts); } if (track.maxSegmentDts === undefined) { track.maxSegmentDts = data.dts; } else { track.maxSegmentDts = Math.max(track.maxSegmentDts, data.dts); } } }; /** * Clear values used to calculate the baseMediaDecodeTime between * tracks */ clearDtsInfo = function (track) { delete track.minSegmentDts; delete track.maxSegmentDts; delete track.minSegmentPts; delete track.maxSegmentPts; }; /** * Calculate the track's baseMediaDecodeTime based on the earliest * DTS the transmuxer has ever seen and the minimum DTS for the * current track */ calculateTrackBaseMediaDecodeTime = function (track) { var oneSecondInPTS = 90000, // 90kHz clock scale, // Calculate the distance, in time, that this segment starts from the start // of the timeline (earliest time seen since the transmuxer initialized) timeSinceStartOfTimeline = track.minSegmentDts - track.timelineStartInfo.dts, // Calculate the first sample's effective compositionTimeOffset firstSampleCompositionOffset = track.minSegmentPts - track.minSegmentDts; // track.timelineStartInfo.baseMediaDecodeTime is the location, in time, where // we want the start of the first segment to be placed track.baseMediaDecodeTime = track.timelineStartInfo.baseMediaDecodeTime; // Add to that the distance this segment is from the very first track.baseMediaDecodeTime += timeSinceStartOfTimeline; // Subtract this segment's "compositionTimeOffset" so that the first frame of // this segment is displayed exactly at the `baseMediaDecodeTime` or at the // end of the previous segment track.baseMediaDecodeTime -= firstSampleCompositionOffset; // baseMediaDecodeTime must not become negative track.baseMediaDecodeTime = Math.max(0, track.baseMediaDecodeTime); if (track.type === 'audio') { // Audio has a different clock equal to the sampling_rate so we need to // scale the PTS values into the clock rate of the track scale = track.samplerate / oneSecondInPTS; track.baseMediaDecodeTime *= scale; track.baseMediaDecodeTime = Math.floor(track.baseMediaDecodeTime); } }; /** * A Stream that can combine multiple streams (ie. audio & video) * into a single output segment for MSE. Also supports audio-only * and video-only streams. */ CoalesceStream = function(options) { // Number of Tracks per output segment // If greater than 1, we combine multiple // tracks into a single segment this.numberOfTracks = 0; this.metadataStream = options.metadataStream; if (typeof options.remux !== 'undefined') { this.remuxTracks = !!options.remux; } else { this.remuxTracks = true; } this.pendingTracks = []; this.videoTrack = null; this.pendingBoxes = []; this.pendingCaptions = []; this.pendingMetadata = []; this.pendingBytes = 0; this.emittedTracks = 0; CoalesceStream.prototype.init.call(this); // Take output from multiple this.push = function(output) { // buffer incoming captions until the associated video segment // finishes if (output.text) { return this.pendingCaptions.push(output); } // buffer incoming id3 tags until the final flush if (output.frames) { return this.pendingMetadata.push(output); } // Add this track to the list of pending tracks and store // important information required for the construction of // the final segment this.pendingTracks.push(output.track); this.pendingBoxes.push(output.boxes); this.pendingBytes += output.boxes.byteLength; if (output.track.type === 'video') { this.videoTrack = output.track; } if (output.track.type === 'audio') { this.audioTrack = output.track; } }; }; CoalesceStream.prototype = new Stream(); CoalesceStream.prototype.flush = function() { var offset = 0, event = { captions: [], metadata: [] }, caption, id3, initSegment, timelineStartPts = 0, i; // Return until we have enough tracks from the pipeline to remux if (this.pendingTracks.length === 0 || (this.remuxTracks && this.pendingTracks.length < this.numberOfTracks)) { return; } if (this.videoTrack) { timelineStartPts = this.videoTrack.timelineStartInfo.pts; } else if (this.audioTrack) { timelineStartPts = this.audioTrack.timelineStartInfo.pts; } if (this.pendingTracks.length === 1) { event.type = this.pendingTracks[0].type; } else { event.type = 'combined'; } this.emittedTracks += this.pendingTracks.length; initSegment = mp4.initSegment(this.pendingTracks); // Create a new typed array large enough to hold the init // segment and all tracks event.data = new Uint8Array(initSegment.byteLength + this.pendingBytes); // Create an init segment containing a moov // and track definitions event.data.set(initSegment); offset += initSegment.byteLength; // Append each moof+mdat (one per track) after the init segment for (i = 0; i < this.pendingBoxes.length; i++) { event.data.set(this.pendingBoxes[i], offset); offset += this.pendingBoxes[i].byteLength; } // Translate caption PTS times into second offsets into the // video timeline for the segment for (i = 0; i < this.pendingCaptions.length; i++) { caption = this.pendingCaptions[i]; caption.startTime = (caption.startPts - timelineStartPts); caption.startTime /= 90e3; caption.endTime = (caption.endPts - timelineStartPts); caption.endTime /= 90e3; event.captions.push(caption); } // Translate ID3 frame PTS times into second offsets into the // video timeline for the segment for (i = 0; i < this.pendingMetadata.length; i++) { id3 = this.pendingMetadata[i]; id3.cueTime = (id3.pts - timelineStartPts); id3.cueTime /= 90e3; event.metadata.push(id3); } // We add this to every single emitted segment even though we only need // it for the first event.metadata.dispatchType = this.metadataStream.dispatchType; // Reset stream state this.pendingTracks.length = 0; this.videoTrack = null; this.pendingBoxes.length = 0; this.pendingCaptions.length = 0; this.pendingBytes = 0; this.pendingMetadata.length = 0; // Emit the built segment this.trigger('data', event); // Only emit `done` if all tracks have been flushed and emitted if (this.emittedTracks >= this.numberOfTracks) { this.trigger('done'); this.emittedTracks = 0; } }; /** * A Stream that expects MP2T binary data as input and produces * corresponding media segments, suitable for use with Media Source * Extension (MSE) implementations that support the ISO BMFF byte * stream format, like Chrome. */ Transmuxer = function(options) { var self = this, videoTrack, audioTrack, packetStream, parseStream, elementaryStream, adtsStream, h264Stream,aacStream, videoSegmentStream, audioSegmentStream, captionStream, coalesceStream, headOfPipeline; this.setupAacPipeline = function() { this.metadataStream = new m2ts.MetadataStream(); options.metadataStream = this.metadataStream; // set up the parsing pipeline aacStream = new AacStream(); adtsStream = new AdtsStream(); coalesceStream = new CoalesceStream(options); headOfPipeline = aacStream; aacStream.pipe(adtsStream); aacStream.pipe(this.metadataStream); this.metadataStream.pipe(coalesceStream); this.metadataStream.on('timestamp', function(frame) { aacStream.setTimestamp(frame.timestamp); }); this.addAacListener(); }; this.addAacListener = function() { aacStream.on('data', function(data) { var i; if (data.type === 'timed-metadata') { var track = { timelineStartInfo: { baseMediaDecodeTime: 0 }, codec: 'adts', type: 'audio' }; if (track && !audioSegmentStream) { // hook up the audio segment stream to the first track with aac data coalesceStream.numberOfTracks++; audioSegmentStream = new AudioSegmentStream(track); // Set up the final part of the audio pipeline adtsStream .pipe(audioSegmentStream) .pipe(coalesceStream); } } }); }; this.setupTsPipeline = function() { this.metadataStream = new m2ts.MetadataStream(); options.metadataStream = this.metadataStream; // set up the parsing pipeline packetStream = new m2ts.TransportPacketStream(); parseStream = new m2ts.TransportParseStream(); elementaryStream = new m2ts.ElementaryStream(); adtsStream = new AdtsStream(); h264Stream = new H264Stream(); captionStream = new m2ts.CaptionStream(); coalesceStream = new CoalesceStream(options); headOfPipeline = packetStream; // disassemble MPEG2-TS packets into elementary streams packetStream .pipe(parseStream) .pipe(elementaryStream); // !!THIS ORDER IS IMPORTANT!! // demux the streams elementaryStream .pipe(h264Stream); elementaryStream .pipe(adtsStream); elementaryStream .pipe(this.metadataStream) .pipe(coalesceStream); // Hook up CEA-608/708 caption stream h264Stream.pipe(captionStream) .pipe(coalesceStream); this.addTsListener(); }; this.addTsListener = function() { elementaryStream.on('data', function(data) { var i; if (data.type === 'metadata') { i = data.tracks.length; // scan the tracks listed in the metadata while (i--) { if (!videoTrack && data.tracks[i].type === 'video') { videoTrack = data.tracks[i]; videoTrack.timelineStartInfo.baseMediaDecodeTime = self.baseMediaDecodeTime; } else if (!audioTrack && data.tracks[i].type === 'audio') { audioTrack = data.tracks[i]; audioTrack.timelineStartInfo.baseMediaDecodeTime = self.baseMediaDecodeTime; } } // hook up the video segment stream to the first track with h264 data if (videoTrack && !videoSegmentStream) { coalesceStream.numberOfTracks++; videoSegmentStream = new VideoSegmentStream(videoTrack); videoSegmentStream.on('timelineStartInfo', function(timelineStartInfo){ // When video emits timelineStartInfo data after a flush, we forward that // info to the AudioSegmentStream, if it exists, because video timeline // data takes precedence. if (audioTrack) { audioTrack.timelineStartInfo = timelineStartInfo; // On the first segment we trim AAC frames that exist before the // very earliest DTS we have seen in video because Chrome will // interpret any video track with a baseMediaDecodeTime that is // non-zero as a gap. audioSegmentStream.setEarliestDts(timelineStartInfo.dts); } }); // Set up the final part of the video pipeline h264Stream .pipe(videoSegmentStream) .pipe(coalesceStream); } if (audioTrack && !audioSegmentStream) { // hook up the audio segment stream to the first track with aac data coalesceStream.numberOfTracks++; audioSegmentStream = new AudioSegmentStream(audioTrack); // Set up the final part of the audio pipeline adtsStream .pipe(audioSegmentStream) .pipe(coalesceStream); } } }); }; Transmuxer.prototype.init.call(this); options = options || {}; this.baseMediaDecodeTime = options.baseMediaDecodeTime || 0; // expose the metadata stream if (options.aacfile === undefined) { this.setupTsPipeline(); } else { this.setupAacPipeline(); } // hook up the segment streams once track metadata is delivered this.setBaseMediaDecodeTime = function (baseMediaDecodeTime) { this.baseMediaDecodeTime = baseMediaDecodeTime; if (audioTrack) { audioTrack.timelineStartInfo.dts = undefined; audioTrack.timelineStartInfo.pts = undefined; clearDtsInfo(audioTrack); audioTrack.timelineStartInfo.baseMediaDecodeTime = baseMediaDecodeTime; } if (videoTrack) { videoSegmentStream.gopCache_ = []; videoTrack.timelineStartInfo.dts = undefined; videoTrack.timelineStartInfo.pts = undefined; clearDtsInfo(videoTrack); videoTrack.timelineStartInfo.baseMediaDecodeTime = baseMediaDecodeTime; } }; // feed incoming data to the front of the parsing pipeline this.push = function(data) { headOfPipeline.push(data); }; // flush any buffered data this.flush = function() { // Start at the top of the pipeline and flush all pending work headOfPipeline.flush(); }; // Re-emit any data coming from the coalesce stream to the outside world coalesceStream.on('data', function (data) { self.trigger('data', data); }); // Let the consumer know we have finished flushing the entire pipeline coalesceStream.on('done', function () { self.trigger('done'); }); }; Transmuxer.prototype = new Stream(); module.exports = { Transmuxer: Transmuxer, VideoSegmentStream: VideoSegmentStream, AudioSegmentStream: AudioSegmentStream, }; },{"../aac":30,"../codecs/adts.js":31,"../codecs/h264":32,"../m2ts/m2ts.js":40,"../utils/stream.js":49,"./mp4-generator.js":44}],46:[function(require,module,exports){ 'use strict'; var tagTypes = { 0x08: 'audio', 0x09: 'video', 0x12: 'metadata' }, hex = function (val) { return '0x' + ('00' + val.toString(16)).slice(-2).toUpperCase(); }, hexStringList = function (data) { var arr = [], i; /* jshint -W086 */ while(data.byteLength > 0) { i = 0; switch(data.byteLength) { default: arr.push(hex(data[i++])); case 7: arr.push(hex(data[i++])); case 6: arr.push(hex(data[i++])); case 5: arr.push(hex(data[i++])); case 4: arr.push(hex(data[i++])); case 3: arr.push(hex(data[i++])); case 2: arr.push(hex(data[i++])); case 1: arr.push(hex(data[i++])); } data = data.subarray(i); } /* jshint +W086 */ return arr.join(' '); }, parseAVCTag = function (tag, obj) { var avcPacketTypes = [ 'AVC Sequence Header', 'AVC NALU', 'AVC End-of-Sequence' ], nalUnitTypes = [ 'unspecified', 'slice_layer_without_partitioning', 'slice_data_partition_a_layer', 'slice_data_partition_b_layer', 'slice_data_partition_c_layer', 'slice_layer_without_partitioning_idr', 'sei', 'seq_parameter_set', 'pic_parameter_set', 'access_unit_delimiter', 'end_of_seq', 'end_of_stream', 'filler', 'seq_parameter_set_ext', 'prefix_nal_unit', 'subset_seq_parameter_set', 'reserved', 'reserved', 'reserved' ], compositionTime = (tag[1] & parseInt('01111111', 2) << 16) | (tag[2] << 8) | tag[3]; obj = obj || {}; obj.avcPacketType = avcPacketTypes[tag[0]]; obj.CompositionTime = (tag[1] & parseInt('10000000', 2)) ? -compositionTime : compositionTime; if (tag[0] === 1) { obj.nalUnitTypeRaw = hexStringList(tag.subarray(4, 100)); } else { obj.data = hexStringList(tag.subarray(4)); } return obj; }, parseVideoTag = function (tag, obj) { var frameTypes = [ 'Unknown', 'Keyframe (for AVC, a seekable frame)', 'Inter frame (for AVC, a nonseekable frame)', 'Disposable inter frame (H.263 only)', 'Generated keyframe (reserved for server use only)', 'Video info/command frame' ], codecIDs = [ 'JPEG (currently unused)', 'Sorenson H.263', 'Screen video', 'On2 VP6', 'On2 VP6 with alpha channel', 'Screen video version 2', 'AVC' ], codecID = tag[0] & parseInt('00001111', 2); obj = obj || {}; obj.frameType = frameTypes[(tag[0] & parseInt('11110000', 2)) >>> 4]; obj.codecID = codecID; if (codecID === 7) { return parseAVCTag(tag.subarray(1), obj); } return obj; }, parseAACTag = function (tag, obj) { var packetTypes = [ 'AAC Sequence Header', 'AAC Raw' ]; obj = obj || {}; obj.aacPacketType = packetTypes[tag[0]]; obj.data = hexStringList(tag.subarray(1)); return obj; }, parseAudioTag = function (tag, obj) { var formatTable = [ 'Linear PCM, platform endian', 'ADPCM', 'MP3', 'Linear PCM, little endian', 'Nellymoser 16-kHz mono', 'Nellymoser 8-kHz mono', 'Nellymoser', 'G.711 A-law logarithmic PCM', 'G.711 mu-law logarithmic PCM', 'reserved', 'AAC', 'Speex', 'MP3 8-Khz', 'Device-specific sound' ], samplingRateTable = [ '5.5-kHz', '11-kHz', '22-kHz', '44-kHz' ], soundFormat = (tag[0] & parseInt('11110000', 2)) >>> 4; obj = obj || {}; obj.soundFormat = formatTable[soundFormat]; obj.soundRate = samplingRateTable[(tag[0] & parseInt('00001100', 2)) >>> 2]; obj.soundSize = ((tag[0] & parseInt('00000010', 2)) >>> 1) ? '16-bit' : '8-bit'; obj.soundType = (tag[0] & parseInt('00000001', 2)) ? 'Stereo' : 'Mono'; if (soundFormat === 10) { return parseAACTag(tag.subarray(1), obj); } return obj; }, parseGenericTag = function (tag) { return { tagType: tagTypes[tag[0]], dataSize: (tag[1] << 16) | (tag[2] << 8) | tag[3], timestamp: (tag[7] << 24) | (tag[4] << 16) | (tag[5] << 8) | tag[6], streamID: (tag[8] << 16) | (tag[9] << 8) | tag[10] }; }, inspectFlvTag = function (tag) { var header = parseGenericTag(tag); switch (tag[0]) { case 0x08: parseAudioTag(tag.subarray(11), header); break; case 0x09: parseVideoTag(tag.subarray(11), header); break; case 0x12: } return header; }, inspectFlv = function (bytes) { var i = 9, // header dataSize, parsedResults = [], tag; // traverse the tags i += 4; // skip previous tag size while (i < bytes.byteLength) { dataSize = bytes[i + 1] << 16; dataSize |= bytes[i + 2] << 8; dataSize |= bytes[i + 3]; dataSize += 11; tag = bytes.subarray(i, i + dataSize); parsedResults.push(inspectFlvTag(tag)); i += dataSize + 4; } return parsedResults; }, textifyFlv = function (flvTagArray) { return JSON.stringify(flvTagArray, null, 2); }; module.exports = { inspectTag: inspectFlvTag, inspect: inspectFlv, textify: textifyFlv }; },{}],47:[function(require,module,exports){ (function (global){ 'use strict'; var inspectMp4, textifyMp4, /** * Returns the string representation of an ASCII encoded four byte buffer. * @param buffer {Uint8Array} a four-byte buffer to translate * @return {string} the corresponding string */ parseType = function(buffer) { var result = ''; result += String.fromCharCode(buffer[0]); result += String.fromCharCode(buffer[1]); result += String.fromCharCode(buffer[2]); result += String.fromCharCode(buffer[3]); return result; }, parseMp4Date = function(seconds) { return new Date(seconds * 1000 - 2082844800000); }, parseSampleFlags = function(flags) { return { isLeading: (flags[0] & 0x0c) >>> 2, dependsOn: flags[0] & 0x03, isDependedOn: (flags[1] & 0xc0) >>> 6, hasRedundancy: (flags[1] & 0x30) >>> 4, paddingValue: (flags[1] & 0x0e) >>> 1, isNonSyncSample: flags[1] & 0x01, degradationPriority: (flags[2] << 8) | flags[3] }; }, nalParse = function(avcStream) { var avcView = new DataView(avcStream.buffer, avcStream.byteOffset, avcStream.byteLength), result = [], i, length; for (i = 0; i + 4 < avcStream.length; i += length) { length = avcView.getUint32(i); i += 4; // bail if this doesn't appear to be an H264 stream if (length <= 0) { return; } switch(avcStream[i] & 0x1F) { case 0x01: result.push('slice_layer_without_partitioning_rbsp'); break; case 0x05: result.push('slice_layer_without_partitioning_rbsp_idr'); break; case 0x06: result.push('sei_rbsp'); break; case 0x07: result.push('seq_parameter_set_rbsp'); break; case 0x08: result.push('pic_parameter_set_rbsp'); break; case 0x09: result.push('access_unit_delimiter_rbsp'); break; default: result.push(avcStream[i] & 0x1F); break; } } return result; }, // registry of handlers for individual mp4 box types parse = { // codingname, not a first-class box type. stsd entries share the // same format as real boxes so the parsing infrastructure can be // shared avc1: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength); return { dataReferenceIndex: view.getUint16(6), width: view.getUint16(24), height: view.getUint16(26), horizresolution: view.getUint16(28) + (view.getUint16(30) / 16), vertresolution: view.getUint16(32) + (view.getUint16(34) / 16), frameCount: view.getUint16(40), depth: view.getUint16(74), config: inspectMp4(data.subarray(78, data.byteLength)) }; }, avcC: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { configurationVersion: data[0], avcProfileIndication: data[1], profileCompatibility: data[2], avcLevelIndication: data[3], lengthSizeMinusOne: data[4] & 0x03, sps: [], pps: [] }, numOfSequenceParameterSets = data[5] & 0x1f, numOfPictureParameterSets, nalSize, offset, i; // iterate past any SPSs offset = 6; for (i = 0; i < numOfSequenceParameterSets; i++) { nalSize = view.getUint16(offset); offset += 2; result.sps.push(new Uint8Array(data.subarray(offset, offset + nalSize))); offset += nalSize; } // iterate past any PPSs numOfPictureParameterSets = data[offset]; offset++; for (i = 0; i < numOfPictureParameterSets; i++) { nalSize = view.getUint16(offset); offset += 2; result.pps.push(new Uint8Array(data.subarray(offset, offset + nalSize))); offset += nalSize; } return result; }, btrt: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength); return { bufferSizeDB: view.getUint32(0), maxBitrate: view.getUint32(4), avgBitrate: view.getUint32(8) }; }, esds: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), esId: (data[6] << 8) | data[7], streamPriority: data[8] & 0x1f, decoderConfig: { objectProfileIndication: data[11], streamType: (data[12] >>> 2) & 0x3f, bufferSize: (data[13] << 16) | (data[14] << 8) | data[15], maxBitrate: (data[16] << 24) | (data[17] << 16) | (data[18] << 8) | data[19], avgBitrate: (data[20] << 24) | (data[21] << 16) | (data[22] << 8) | data[23], decoderConfigDescriptor: { tag: data[24], length: data[25], audioObjectType: (data[26] >>> 3) & 0x1f, samplingFrequencyIndex: ((data[26] & 0x07) << 1) | ((data[27] >>> 7) & 0x01), channelConfiguration: (data[27] >>> 3) & 0x0f } } }; }, ftyp: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { majorBrand: parseType(data.subarray(0, 4)), minorVersion: view.getUint32(4), compatibleBrands: [] }, i = 8; while (i < data.byteLength) { result.compatibleBrands.push(parseType(data.subarray(i, i + 4))); i += 4; } return result; }, dinf: function(data) { return { boxes: inspectMp4(data) }; }, dref: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), dataReferences: inspectMp4(data.subarray(8)) }; }, hdlr: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), language, result = { version: view.getUint8(0), flags: new Uint8Array(data.subarray(1, 4)), handlerType: parseType(data.subarray(8, 12)), name: '' }, i = 8; // parse out the name field for (i = 24; i < data.byteLength; i++) { if (data[i] === 0x00) { // the name field is null-terminated i++; break; } result.name += String.fromCharCode(data[i]); } // decode UTF-8 to javascript's internal representation // see http://ecmanaut.blogspot.com/2006/07/encoding-decoding-utf8-in-javascript.html result.name = decodeURIComponent(global.escape(result.name)); return result; }, mdat: function(data) { return { byteLength: data.byteLength, nals: nalParse(data) }; }, mdhd: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), i = 4, language, result = { version: view.getUint8(0), flags: new Uint8Array(data.subarray(1, 4)), language: '' }; if (result.version === 1) { i += 4; result.creationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 8; result.modificationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 4; result.timescale = view.getUint32(i); i += 8; result.duration = view.getUint32(i); // truncating top 4 bytes } else { result.creationTime = parseMp4Date(view.getUint32(i)); i += 4; result.modificationTime = parseMp4Date(view.getUint32(i)); i += 4; result.timescale = view.getUint32(i); i += 4; result.duration = view.getUint32(i); } i += 4; // language is stored as an ISO-639-2/T code in an array of three 5-bit fields // each field is the packed difference between its ASCII value and 0x60 language = view.getUint16(i); result.language += String.fromCharCode((language >> 10) + 0x60); result.language += String.fromCharCode(((language & 0x03c0) >> 5) + 0x60); result.language += String.fromCharCode((language & 0x1f) + 0x60); return result; }, mdia: function(data) { return { boxes: inspectMp4(data) }; }, mfhd: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), sequenceNumber: (data[4] << 24) | (data[5] << 16) | (data[6] << 8) | (data[7]) }; }, minf: function(data) { return { boxes: inspectMp4(data) }; }, // codingname, not a first-class box type. stsd entries share the // same format as real boxes so the parsing infrastructure can be // shared mp4a: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { // 6 bytes reserved dataReferenceIndex: view.getUint16(6), // 4 + 4 bytes reserved channelcount: view.getUint16(16), samplesize: view.getUint16(18), // 2 bytes pre_defined // 2 bytes reserved samplerate: view.getUint16(24) + (view.getUint16(26) / 65536) }; // if there are more bytes to process, assume this is an ISO/IEC // 14496-14 MP4AudioSampleEntry and parse the ESDBox if (data.byteLength > 28) { result.streamDescriptor = inspectMp4(data.subarray(28))[0]; } return result; }, moof: function(data) { return { boxes: inspectMp4(data) }; }, moov: function(data) { return { boxes: inspectMp4(data) }; }, mvex: function(data) { return { boxes: inspectMp4(data) }; }, mvhd: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), i = 4, result = { version: view.getUint8(0), flags: new Uint8Array(data.subarray(1, 4)) }; if (result.version === 1) { i += 4; result.creationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 8; result.modificationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 4; result.timescale = view.getUint32(i); i += 8; result.duration = view.getUint32(i); // truncating top 4 bytes } else { result.creationTime = parseMp4Date(view.getUint32(i)); i += 4; result.modificationTime = parseMp4Date(view.getUint32(i)); i += 4; result.timescale = view.getUint32(i); i += 4; result.duration = view.getUint32(i); } i += 4; // convert fixed-point, base 16 back to a number result.rate = view.getUint16(i) + (view.getUint16(i + 2) / 16); i += 4; result.volume = view.getUint8(i) + (view.getUint8(i + 1) / 8); i += 2; i += 2; i += 2 * 4; result.matrix = new Uint32Array(data.subarray(i, i + (9 * 4))); i += 9 * 4; i += 6 * 4; result.nextTrackId = view.getUint32(i); return result; }, pdin: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength); return { version: view.getUint8(0), flags: new Uint8Array(data.subarray(1, 4)), rate: view.getUint32(4), initialDelay: view.getUint32(8) }; }, sdtp: function(data) { var result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), samples: [] }, i; for (i = 4; i < data.byteLength; i++) { result.samples.push({ dependsOn: (data[i] & 0x30) >> 4, isDependedOn: (data[i] & 0x0c) >> 2, hasRedundancy: data[i] & 0x03 }); } return result; }, sidx: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), references: [], referenceId: view.getUint32(4), timescale: view.getUint32(8), earliestPresentationTime: view.getUint32(12), firstOffset: view.getUint32(16) }, referenceCount = view.getUint16(22), i; for (i = 24; referenceCount; i += 12, referenceCount-- ) { result.references.push({ referenceType: (data[i] & 0x80) >>> 7, referencedSize: view.getUint32(i) & 0x7FFFFFFF, subsegmentDuration: view.getUint32(i + 4), startsWithSap: !!(data[i + 8] & 0x80), sapType: (data[i + 8] & 0x70) >>> 4, sapDeltaTime: view.getUint32(i + 8) & 0x0FFFFFFF }); } return result; }, smhd: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), balance: data[4] + (data[5] / 256) }; }, stbl: function(data) { return { boxes: inspectMp4(data) }; }, stco: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), chunkOffsets: [] }, entryCount = view.getUint32(4), i; for (i = 8; entryCount; i += 4, entryCount--) { result.chunkOffsets.push(view.getUint32(i)); } return result; }, stsc: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), entryCount = view.getUint32(4), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), sampleToChunks: [] }, i; for (i = 8; entryCount; i += 12, entryCount--) { result.sampleToChunks.push({ firstChunk: view.getUint32(i), samplesPerChunk: view.getUint32(i + 4), sampleDescriptionIndex: view.getUint32(i + 8) }); } return result; }, stsd: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), sampleDescriptions: inspectMp4(data.subarray(8)) }; }, stsz: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), sampleSize: view.getUint32(4), entries: [] }, i; for (i = 12; i < data.byteLength; i += 4) { result.entries.push(view.getUint32(i)); } return result; }, stts: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), timeToSamples: [] }, entryCount = view.getUint32(4), i; for (i = 8; entryCount; i += 8, entryCount--) { result.timeToSamples.push({ sampleCount: view.getUint32(i), sampleDelta: view.getUint32(i + 4) }); } return result; }, styp: function(data) { return parse.ftyp(data); }, tfdt: function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), baseMediaDecodeTime: data[4] << 24 | data[5] << 16 | data[6] << 8 | data[7] }; }, tfhd: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), trackId: view.getUint32(4) }, baseDataOffsetPresent = result.flags[2] & 0x01, sampleDescriptionIndexPresent = result.flags[2] & 0x02, defaultSampleDurationPresent = result.flags[2] & 0x08, defaultSampleSizePresent = result.flags[2] & 0x10, defaultSampleFlagsPresent = result.flags[2] & 0x20, i; i = 8; if (baseDataOffsetPresent) { i += 4; // truncate top 4 bytes result.baseDataOffset = view.getUint32(12); i += 4; } if (sampleDescriptionIndexPresent) { result.sampleDescriptionIndex = view.getUint32(i); i += 4; } if (defaultSampleDurationPresent) { result.defaultSampleDuration = view.getUint32(i); i += 4; } if (defaultSampleSizePresent) { result.defaultSampleSize = view.getUint32(i); i += 4; } if (defaultSampleFlagsPresent) { result.defaultSampleFlags = view.getUint32(i); } return result; }, tkhd: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength), i = 4, result = { version: view.getUint8(0), flags: new Uint8Array(data.subarray(1, 4)), }; if (result.version === 1) { i += 4; result.creationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 8; result.modificationTime = parseMp4Date(view.getUint32(i)); // truncating top 4 bytes i += 4; result.trackId = view.getUint32(i); i += 4; i += 8; result.duration = view.getUint32(i); // truncating top 4 bytes } else { result.creationTime = parseMp4Date(view.getUint32(i)); i += 4; result.modificationTime = parseMp4Date(view.getUint32(i)); i += 4; result.trackId = view.getUint32(i); i += 4; i += 4; result.duration = view.getUint32(i); } i += 4; i += 2 * 4; result.layer = view.getUint16(i); i += 2; result.alternateGroup = view.getUint16(i); i += 2; // convert fixed-point, base 16 back to a number result.volume = view.getUint8(i) + (view.getUint8(i + 1) / 8); i += 2; i += 2; result.matrix = new Uint32Array(data.subarray(i, i + (9 * 4))); i += 9 * 4; result.width = view.getUint16(i) + (view.getUint16(i + 2) / 16); i += 4; result.height = view.getUint16(i) + (view.getUint16(i + 2) / 16); return result; }, traf: function(data) { return { boxes: inspectMp4(data) }; }, trak: function(data) { return { boxes: inspectMp4(data) }; }, trex: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength); return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), trackId: view.getUint32(4), defaultSampleDescriptionIndex: view.getUint32(8), defaultSampleDuration: view.getUint32(12), defaultSampleSize: view.getUint32(16), sampleDependsOn: data[20] & 0x03, sampleIsDependedOn: (data[21] & 0xc0) >> 6, sampleHasRedundancy: (data[21] & 0x30) >> 4, samplePaddingValue: (data[21] & 0x0e) >> 1, sampleIsDifferenceSample: !!(data[21] & 0x01), sampleDegradationPriority: view.getUint16(22) }; }, trun: function(data) { var result = { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), samples: [] }, view = new DataView(data.buffer, data.byteOffset, data.byteLength), dataOffsetPresent = result.flags[2] & 0x01, firstSampleFlagsPresent = result.flags[2] & 0x04, sampleDurationPresent = result.flags[1] & 0x01, sampleSizePresent = result.flags[1] & 0x02, sampleFlagsPresent = result.flags[1] & 0x04, sampleCompositionTimeOffsetPresent = result.flags[1] & 0x08, sampleCount = view.getUint32(4), offset = 8, sample; if (dataOffsetPresent) { result.dataOffset = view.getUint32(offset); offset += 4; } if (firstSampleFlagsPresent && sampleCount) { sample = { flags: parseSampleFlags(data.subarray(offset, offset + 4)) }; offset += 4; if (sampleDurationPresent) { sample.duration = view.getUint32(offset); offset += 4; } if (sampleSizePresent) { sample.size = view.getUint32(offset); offset += 4; } if (sampleCompositionTimeOffsetPresent) { sample.compositionTimeOffset = view.getUint32(offset); offset += 4; } result.samples.push(sample); sampleCount--; } while (sampleCount--) { sample = {}; if (sampleDurationPresent) { sample.duration = view.getUint32(offset); offset += 4; } if (sampleSizePresent) { sample.size = view.getUint32(offset); offset += 4; } if (sampleFlagsPresent) { sample.flags = parseSampleFlags(data.subarray(offset, offset + 4)); offset += 4; } if (sampleCompositionTimeOffsetPresent) { sample.compositionTimeOffset = view.getUint32(offset); offset += 4; } result.samples.push(sample); } return result; }, 'url ': function(data) { return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)) }; }, vmhd: function(data) { var view = new DataView(data.buffer, data.byteOffset, data.byteLength); return { version: data[0], flags: new Uint8Array(data.subarray(1, 4)), graphicsmode: view.getUint16(4), opcolor: new Uint16Array([view.getUint16(6), view.getUint16(8), view.getUint16(10)]) }; } }; /** * Return a javascript array of box objects parsed from an ISO base * media file. * @param data {Uint8Array} the binary data of the media to be inspected * @return {array} a javascript array of potentially nested box objects */ inspectMp4 = function(data) { var i = 0, result = [], view, size, type, end, box; // Convert data from Uint8Array to ArrayBuffer, to follow Dataview API var ab = new ArrayBuffer(data.length); var v = new Uint8Array(ab); for (var z = 0; z < data.length; ++z) { v[z] = data[z]; } view = new DataView(ab); while (i < data.byteLength) { // parse box data size = view.getUint32(i); type = parseType(data.subarray(i + 4, i + 8)); end = size > 1 ? i + size : data.byteLength; // parse type-specific data box = (parse[type] || function(data) { return { data: data }; })(data.subarray(i + 8, end)); box.size = size; box.type = type; // store this box and move to the next result.push(box); i = end; } return result; }; /** * Returns a textual representation of the javascript represtentation * of an MP4 file. You can use it as an alternative to * JSON.stringify() to compare inspected MP4s. * @param inspectedMp4 {array} the parsed array of boxes in an MP4 * file * @param depth {number} (optional) the number of ancestor boxes of * the elements of inspectedMp4. Assumed to be zero if unspecified. * @return {string} a text representation of the parsed MP4 */ textifyMp4 = function(inspectedMp4, depth) { var indent; depth = depth || 0; indent = new Array(depth * 2 + 1).join(' '); // iterate over all the boxes return inspectedMp4.map(function(box, index) { // list the box type first at the current indentation level return indent + box.type + '\n' + // the type is already included and handle child boxes separately Object.keys(box).filter(function(key) { return key !== 'type' && key !== 'boxes'; // output all the box properties }).map(function(key) { var prefix = indent + ' ' + key + ': ', value = box[key]; // print out raw bytes as hexademical if (value instanceof Uint8Array || value instanceof Uint32Array) { var bytes = Array.prototype.slice.call(new Uint8Array(value.buffer, value.byteOffset, value.byteLength)) .map(function(byte) { return ' ' + ('00' + byte.toString(16)).slice(-2); }).join('').match(/.{1,24}/g); if (!bytes) { return prefix + '<>'; } if (bytes.length === 1) { return prefix + '<' + bytes.join('').slice(1) + '>'; } return prefix + '<\n' + bytes.map(function(line) { return indent + ' ' + line; }).join('\n') + '\n' + indent + ' >'; } // stringify generic objects return prefix + JSON.stringify(value, null, 2) .split('\n').map(function(line, index) { if (index === 0) { return line; } return indent + ' ' + line; }).join('\n'); }).join('\n') + // recursively textify the child boxes (box.boxes ? '\n' + textifyMp4(box.boxes, depth + 1) : ''); }).join('\n'); }; module.exports = { inspect: inspectMp4, textify: textifyMp4 }; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{}],48:[function(require,module,exports){ 'use strict'; var ExpGolomb; /** * Parser for exponential Golomb codes, a variable-bitwidth number encoding * scheme used by h264. */ ExpGolomb = function(workingData) { var // the number of bytes left to examine in workingData workingBytesAvailable = workingData.byteLength, // the current word being examined workingWord = 0, // :uint // the number of bits left to examine in the current word workingBitsAvailable = 0; // :uint; // ():uint this.length = function() { return (8 * workingBytesAvailable); }; // ():uint this.bitsAvailable = function() { return (8 * workingBytesAvailable) + workingBitsAvailable; }; // ():void this.loadWord = function() { var position = workingData.byteLength - workingBytesAvailable, workingBytes = new Uint8Array(4), availableBytes = Math.min(4, workingBytesAvailable); if (availableBytes === 0) { throw new Error('no bytes available'); } workingBytes.set(workingData.subarray(position, position + availableBytes)); workingWord = new DataView(workingBytes.buffer).getUint32(0); // track the amount of workingData that has been processed workingBitsAvailable = availableBytes * 8; workingBytesAvailable -= availableBytes; }; // (count:int):void this.skipBits = function(count) { var skipBytes; // :int if (workingBitsAvailable > count) { workingWord <<= count; workingBitsAvailable -= count; } else { count -= workingBitsAvailable; skipBytes = Math.floor(count / 8); count -= (skipBytes * 8); workingBytesAvailable -= skipBytes; this.loadWord(); workingWord <<= count; workingBitsAvailable -= count; } }; // (size:int):uint this.readBits = function(size) { var bits = Math.min(workingBitsAvailable, size), // :uint valu = workingWord >>> (32 - bits); // :uint // if size > 31, handle error workingBitsAvailable -= bits; if (workingBitsAvailable > 0) { workingWord <<= bits; } else if (workingBytesAvailable > 0) { this.loadWord(); } bits = size - bits; if (bits > 0) { return valu << bits | this.readBits(bits); } else { return valu; } }; // ():uint this.skipLeadingZeros = function() { var leadingZeroCount; // :uint for (leadingZeroCount = 0 ; leadingZeroCount < workingBitsAvailable ; ++leadingZeroCount) { if (0 !== (workingWord & (0x80000000 >>> leadingZeroCount))) { // the first bit of working word is 1 workingWord <<= leadingZeroCount; workingBitsAvailable -= leadingZeroCount; return leadingZeroCount; } } // we exhausted workingWord and still have not found a 1 this.loadWord(); return leadingZeroCount + this.skipLeadingZeros(); }; // ():void this.skipUnsignedExpGolomb = function() { this.skipBits(1 + this.skipLeadingZeros()); }; // ():void this.skipExpGolomb = function() { this.skipBits(1 + this.skipLeadingZeros()); }; // ():uint this.readUnsignedExpGolomb = function() { var clz = this.skipLeadingZeros(); // :uint return this.readBits(clz + 1) - 1; }; // ():int this.readExpGolomb = function() { var valu = this.readUnsignedExpGolomb(); // :int if (0x01 & valu) { // the number is odd if the low order bit is set return (1 + valu) >>> 1; // add 1 to make it even, and divide by 2 } else { return -1 * (valu >>> 1); // divide by two then make it negative } }; // Some convenience functions // :Boolean this.readBoolean = function() { return 1 === this.readBits(1); }; // ():int this.readUnsignedByte = function() { return this.readBits(8); }; this.loadWord(); }; module.exports = ExpGolomb; },{}],49:[function(require,module,exports){ /** * mux.js * * Copyright (c) 2014 Brightcove * All rights reserved. * * A lightweight readable stream implemention that handles event dispatching. * Objects that inherit from streams should call init in their constructors. */ 'use strict'; var Stream = function() { this.init = function() { var listeners = {}; /** * Add a listener for a specified event type. * @param type {string} the event name * @param listener {function} the callback to be invoked when an event of * the specified type occurs */ this.on = function(type, listener) { if (!listeners[type]) { listeners[type] = []; } listeners[type].push(listener); }; /** * Remove a listener for a specified event type. * @param type {string} the event name * @param listener {function} a function previously registered for this * type of event through `on` */ this.off = function(type, listener) { var index; if (!listeners[type]) { return false; } index = listeners[type].indexOf(listener); listeners[type].splice(index, 1); return index > -1; }; /** * Trigger an event of the specified type on this stream. Any additional * arguments to this function are passed as parameters to event listeners. * @param type {string} the event name */ this.trigger = function(type) { var callbacks, i, length, args; callbacks = listeners[type]; if (!callbacks) { return; } // Slicing the arguments on every invocation of this method // can add a significant amount of overhead. Avoid the // intermediate object creation for the common case of a // single callback argument if (arguments.length === 2) { length = callbacks.length; for (i = 0; i < length; ++i) { callbacks[i].call(this, arguments[1]); } } else { args = []; i = arguments.length; for (i = 1; i < arguments.length; ++i) { args.push(arguments[i]); } length = callbacks.length; for (i = 0; i < length; ++i) { callbacks[i].apply(this, args); } } }; /** * Destroys the stream and cleans up. */ this.dispose = function() { listeners = {}; }; }; }; /** * Forwards all `data` events on this stream to the destination stream. The * destination stream should provide a method `push` to receive the data * events as they arrive. * @param destination {stream} the stream that will receive all `data` events * @param autoFlush {boolean} if false, we will not call `flush` on the destination * when the current stream emits a 'done' event * @see http://nodejs.org/api/stream.html#stream_readable_pipe_destination_options */ Stream.prototype.pipe = function(destination) { this.on('data', function(data) { destination.push(data); }); this.on('done', function() { destination.flush(); }); return destination; }; // Default stream functions that are expected to be overridden to perform // actual work. These are provided by the prototype as a sort of no-op // implementation so that we don't have to check for their existence in the // `pipe` function above. Stream.prototype.push = function(data) { this.trigger('data', data); }; Stream.prototype.flush = function() { this.trigger('done'); }; module.exports = Stream; },{}],50:[function(require,module,exports){ var bundleFn = arguments[3]; var sources = arguments[4]; var cache = arguments[5]; var stringify = JSON.stringify; module.exports = function (fn) { var keys = []; var wkey; var cacheKeys = Object.keys(cache); for (var i = 0, l = cacheKeys.length; i < l; i++) { var key = cacheKeys[i]; if (cache[key].exports === fn) { wkey = key; break; } } if (!wkey) { wkey = Math.floor(Math.pow(16, 8) * Math.random()).toString(16); var wcache = {}; for (var i = 0, l = cacheKeys.length; i < l; i++) { var key = cacheKeys[i]; wcache[key] = key; } sources[wkey] = [ Function(['require','module','exports'], '(' + fn + ')(self)'), wcache ]; } var skey = Math.floor(Math.pow(16, 8) * Math.random()).toString(16); var scache = {}; scache[wkey] = wkey; sources[skey] = [ Function(['require'],'require(' + stringify(wkey) + ')(self)'), scache ]; var src = '(' + bundleFn + ')({' + Object.keys(sources).map(function (key) { return stringify(key) + ':[' + sources[key][0] + ',' + stringify(sources[key][1]) + ']' ; }).join(',') + '},{},[' + stringify(skey) + '])' ; var URL = window.URL || window.webkitURL || window.mozURL || window.msURL; return new Worker(URL.createObjectURL( new Blob([src], { type: 'text/javascript' }) )); }; },{}],51:[function(require,module,exports){ (function (global){ /** * videojs-hls * The main file for the HLS project. * License: https://github.com/videojs/videojs-contrib-hls/blob/master/LICENSE */ 'use strict'; Object.defineProperty(exports, '__esModule', { value: true }); var _createClass = (function () { function defineProperties(target, props) { for (var i = 0; i < props.length; i++) { var descriptor = props[i]; descriptor.enumerable = descriptor.enumerable || false; descriptor.configurable = true; if ('value' in descriptor) descriptor.writable = true; Object.defineProperty(target, descriptor.key, descriptor); } } return function (Constructor, protoProps, staticProps) { if (protoProps) defineProperties(Constructor.prototype, protoProps); if (staticProps) defineProperties(Constructor, staticProps); return Constructor; }; })(); var _get = function get(_x, _x2, _x3) { var _again = true; _function: while (_again) { var object = _x, property = _x2, receiver = _x3; _again = false; if (object === null) object = Function.prototype; var desc = Object.getOwnPropertyDescriptor(object, property); if (desc === undefined) { var parent = Object.getPrototypeOf(object); if (parent === null) { return undefined; } else { _x = parent; _x2 = property; _x3 = receiver; _again = true; desc = parent = undefined; continue _function; } } else if ('value' in desc) { return desc.value; } else { var getter = desc.get; if (getter === undefined) { return undefined; } return getter.call(receiver); } } }; function _interopRequireDefault(obj) { return obj && obj.__esModule ? obj : { 'default': obj }; } function _classCallCheck(instance, Constructor) { if (!(instance instanceof Constructor)) { throw new TypeError('Cannot call a class as a function'); } } function _inherits(subClass, superClass) { if (typeof superClass !== 'function' && superClass !== null) { throw new TypeError('Super expression must either be null or a function, not ' + typeof superClass); } subClass.prototype = Object.create(superClass && superClass.prototype, { constructor: { value: subClass, enumerable: false, writable: true, configurable: true } }); if (superClass) Object.setPrototypeOf ? Object.setPrototypeOf(subClass, superClass) : subClass.__proto__ = superClass; } var _playlistLoader = require('./playlist-loader'); var _playlistLoader2 = _interopRequireDefault(_playlistLoader); var _playlist = require('./playlist'); var _playlist2 = _interopRequireDefault(_playlist); var _xhr = require('./xhr'); var _xhr2 = _interopRequireDefault(_xhr); var _decrypter = require('./decrypter'); var _binUtils = require('./bin-utils'); var _binUtils2 = _interopRequireDefault(_binUtils); var _videojsContribMediaSources = require('videojs-contrib-media-sources'); var _m3u8 = require('./m3u8'); var _m3u82 = _interopRequireDefault(_m3u8); var _videoJs = (typeof window !== "undefined" ? window['videojs'] : typeof global !== "undefined" ? global['videojs'] : null); var _videoJs2 = _interopRequireDefault(_videoJs); var _resolveUrl = require('./resolve-url'); var _resolveUrl2 = _interopRequireDefault(_resolveUrl); var Hls = { PlaylistLoader: _playlistLoader2['default'], Playlist: _playlist2['default'], Decrypter: _decrypter.Decrypter, AsyncStream: _decrypter.AsyncStream, decrypt: _decrypter.decrypt, utils: _binUtils2['default'], xhr: _xhr2['default'] }; // the desired length of video to maintain in the buffer, in seconds Hls.GOAL_BUFFER_LENGTH = 30; // HLS is a source handler, not a tech. Make sure attempts to use it // as one do not cause exceptions. Hls.canPlaySource = function () { return _videoJs2['default'].log.warn('HLS is no longer a tech. Please remove it from ' + 'your player\'s techOrder.'); }; // Search for a likely end time for the segment that was just appened // based on the state of the `buffered` property before and after the // append. // If we found only one such uncommon end-point return it. Hls.findSoleUncommonTimeRangesEnd_ = function (original, update) { var i = undefined; var start = undefined; var end = undefined; var result = []; var edges = []; // In order to qualify as a possible candidate, the end point must: // 1) Not have already existed in the `original` ranges // 2) Not result from the shrinking of a range that already existed // in the `original` ranges // 3) Not be contained inside of a range that existed in `original` var overlapsCurrentEnd = function overlapsCurrentEnd(span) { return span[0] <= end && span[1] >= end; }; if (original) { // Save all the edges in the `original` TimeRanges object for (i = 0; i < original.length; i++) { start = original.start(i); end = original.end(i); edges.push([start, end]); } } if (update) { // Save any end-points in `update` that are not in the `original` // TimeRanges object for (i = 0; i < update.length; i++) { start = update.start(i); end = update.end(i); if (edges.some(overlapsCurrentEnd)) { continue; } // at this point it must be a unique non-shrinking end edge result.push(end); } } // we err on the side of caution and return null if didn't find // exactly *one* differing end edge in the search above if (result.length !== 1) { return null; } return result[0]; }; /** * Whether the browser has built-in HLS support. */ Hls.supportsNativeHls = (function () { var video = document.createElement('video'); var xMpegUrl = undefined; var vndMpeg = undefined; // native HLS is definitely not supported if HTML5 video isn't if (!_videoJs2['default'].getComponent('Html5').isSupported()) { return false; } xMpegUrl = video.canPlayType('application/x-mpegURL'); vndMpeg = video.canPlayType('application/vnd.apple.mpegURL'); return (/probably|maybe/.test(xMpegUrl) || /probably|maybe/.test(vndMpeg) ); })(); // HLS is a source handler, not a tech. Make sure attempts to use it // as one do not cause exceptions. Hls.isSupported = function () { return _videoJs2['default'].log.warn('HLS is no longer a tech. Please remove it from ' + 'your player\'s techOrder.'); }; /** * A comparator function to sort two playlist object by bandwidth. * @param left {object} a media playlist object * @param right {object} a media playlist object * @return {number} Greater than zero if the bandwidth attribute of * left is greater than the corresponding attribute of right. Less * than zero if the bandwidth of right is greater than left and * exactly zero if the two are equal. */ Hls.comparePlaylistBandwidth = function (left, right) { var leftBandwidth = undefined; var rightBandwidth = undefined; if (left.attributes && left.attributes.BANDWIDTH) { leftBandwidth = left.attributes.BANDWIDTH; } leftBandwidth = leftBandwidth || window.Number.MAX_VALUE; if (right.attributes && right.attributes.BANDWIDTH) { rightBandwidth = right.attributes.BANDWIDTH; } rightBandwidth = rightBandwidth || window.Number.MAX_VALUE; return leftBandwidth - rightBandwidth; }; /** * A comparator function to sort two playlist object by resolution (width). * @param left {object} a media playlist object * @param right {object} a media playlist object * @return {number} Greater than zero if the resolution.width attribute of * left is greater than the corresponding attribute of right. Less * than zero if the resolution.width of right is greater than left and * exactly zero if the two are equal. */ Hls.comparePlaylistResolution = function (left, right) { var leftWidth = undefined; var rightWidth = undefined; if (left.attributes && left.attributes.RESOLUTION && left.attributes.RESOLUTION.width) { leftWidth = left.attributes.RESOLUTION.width; } leftWidth = leftWidth || window.Number.MAX_VALUE; if (right.attributes && right.attributes.RESOLUTION && right.attributes.RESOLUTION.width) { rightWidth = right.attributes.RESOLUTION.width; } rightWidth = rightWidth || window.Number.MAX_VALUE; // NOTE - Fallback to bandwidth sort as appropriate in cases where multiple renditions // have the same media dimensions/ resolution if (leftWidth === rightWidth && left.attributes.BANDWIDTH && right.attributes.BANDWIDTH) { return left.attributes.BANDWIDTH - right.attributes.BANDWIDTH; } return leftWidth - rightWidth; }; // A fudge factor to apply to advertised playlist bitrates to account for // temporary flucations in client bandwidth var bandwidthVariance = 1.2; // 5 minute blacklist var blacklistDuration = 5 * 60 * 1000; // Fudge factor to account for TimeRanges rounding var TIME_FUDGE_FACTOR = 1 / 30; var Component = _videoJs2['default'].getComponent('Component'); // The amount of time to wait between checking the state of the buffer var bufferCheckInterval = 500; // returns true if a key has failed to download within a certain amount of retries var keyFailed = function keyFailed(key) { return key.retries && key.retries >= 2; }; /** * Returns the CSS value for the specified property on an element * using `getComputedStyle`. Firefox has a long-standing issue where * getComputedStyle() may return null when running in an iframe with * `display: none`. * @see https://bugzilla.mozilla.org/show_bug.cgi?id=548397 */ var safeGetComputedStyle = function safeGetComputedStyle(el, property) { var result = undefined; if (!el) { return ''; } result = getComputedStyle(el); if (!result) { return ''; } return result[property]; }; /** * Updates segment with information about its end-point in time and, optionally, * the segment duration if we have enough information to determine a segment duration * accurately. * @param playlist {object} a media playlist object * @param segmentIndex {number} the index of segment we last appended * @param segmentEnd {number} the known of the segment referenced by segmentIndex */ var updateSegmentMetadata = function updateSegmentMetadata(playlist, segmentIndex, segmentEnd) { if (!playlist) { return; } var segment = playlist.segments[segmentIndex]; var previousSegment = playlist.segments[segmentIndex - 1]; if (segmentEnd && segment) { segment.end = segmentEnd; // fix up segment durations based on segment end data if (!previousSegment) { // first segment is always has a start time of 0 making its duration // equal to the segment end segment.duration = segment.end; } else if (previousSegment.end) { segment.duration = segment.end - previousSegment.end; } } }; /** * Determines if we should call endOfStream on the media source based on the state * of the buffer or if appened segment was the final segment in the playlist. * @param playlist {object} a media playlist object * @param mediaSource {object} the MediaSource object * @param segmentIndex {number} the index of segment we last appended * @param currentBuffered {object} the buffered region that currentTime resides in * @return {boolean} whether the calling function should call endOfStream on the MediaSource */ var detectEndOfStream = function detectEndOfStream(playlist, mediaSource, segmentIndex, currentBuffered) { if (!playlist) { return false; } var segments = playlist.segments; // determine a few boolean values to help make the branch below easier // to read var appendedLastSegment = segmentIndex === segments.length - 1; var bufferedToEnd = currentBuffered.length && segments[segments.length - 1].end <= currentBuffered.end(0); // if we've buffered to the end of the video, we need to call endOfStream // so that MediaSources can trigger the `ended` event when it runs out of // buffered data instead of waiting for me return playlist.endList && mediaSource.readyState === 'open' && (appendedLastSegment || bufferedToEnd); }; var parseCodecs = function parseCodecs(codecs) { var result = { codecCount: 0, videoCodec: null, audioProfile: null }; result.codecCount = codecs.split(',').length; result.codecCount = result.codecCount || 2; // parse the video codec but ignore the version result.videoCodec = /(^|\s|,)+(avc1)[^ ,]*/i.exec(codecs); result.videoCodec = result.videoCodec && result.videoCodec[2]; // parse the last field of the audio codec result.audioProfile = /(^|\s|,)+mp4a.\d+\.(\d+)/i.exec(codecs); result.audioProfile = result.audioProfile && result.audioProfile[2]; return result; }; var filterBufferedRanges = function filterBufferedRanges(predicate) { return function (time) { var i = undefined; var ranges = []; var tech = this.tech_; // !!The order of the next two assignments is important!! // `currentTime` must be equal-to or greater-than the start of the // buffered range. Flash executes out-of-process so, every value can // change behind the scenes from line-to-line. By reading `currentTime` // after `buffered`, we ensure that it is always a current or later // value during playback. var buffered = tech.buffered(); if (typeof time === 'undefined') { time = tech.currentTime(); } // IE 11 has a bug where it will report a the video as fully buffered // before any data has been loaded. This is a work around where we // report a fully empty buffer until SourceBuffers have been created // which is after a segment has been loaded and transmuxed. if (!this.mediaSource || !this.mediaSource.mediaSource_ || !this.mediaSource.mediaSource_.sourceBuffers.length) { return _videoJs2['default'].createTimeRanges([]); } if (buffered && buffered.length) { // Search for a range containing the play-head for (i = 0; i < buffered.length; i++) { if (predicate(buffered.start(i), buffered.end(i), time)) { ranges.push([buffered.start(i), buffered.end(i)]); } } } return _videoJs2['default'].createTimeRanges(ranges); }; }; var HlsHandler = (function (_Component) { _inherits(HlsHandler, _Component); function HlsHandler(tech, options) { var _this = this; _classCallCheck(this, HlsHandler); _get(Object.getPrototypeOf(HlsHandler.prototype), 'constructor', this).call(this, tech); var _player = undefined; // tech.player() is deprecated but setup a reference to HLS for // backwards-compatibility if (tech.options_ && tech.options_.playerId) { _player = (0, _videoJs2['default'])(tech.options_.playerId); if (!_player.hls) { Object.defineProperty(_player, 'hls', { get: function get() { _videoJs2['default'].log.warn('player.hls is deprecated. Use player.tech.hls instead.'); return _this; } }); } } this.tech_ = tech; this.source_ = options.source; this.mode_ = options.mode; // the segment info object for a segment that is in the process of // being downloaded or processed this.pendingSegment_ = null; // start playlist selection at a reasonable bandwidth for // broadband internet // 0.5 Mbps this.bandwidth = options.bandwidth || 4194304; this.bytesReceived = 0; // loadingState_ tracks how far along the buffering process we // have been given permission to proceed. There are three possible // values: // - none: do not load playlists or segments // - meta: load playlists but not segments // - segments: load everything this.loadingState_ = 'none'; if (this.tech_.preload() !== 'none') { this.loadingState_ = 'meta'; } // periodically check if new data needs to be downloaded or // buffered data should be appended to the source buffer this.startCheckingBuffer_(); this.on(this.tech_, 'seeking', function () { this.setCurrentTime(this.tech_.currentTime()); }); this.on(this.tech_, 'error', function () { this.stopCheckingBuffer_(); }); this.on(this.tech_, 'play', this.play); } /** * Attempts to find the buffered TimeRange that contains the specified * time, or where playback is currently happening if no specific time * is specified. * @param time (optional) {number} the time to filter on. Defaults to * currentTime. * @return a new TimeRanges object. */ _createClass(HlsHandler, [{ key: 'src', value: function src(_src) { var _this2 = this; var oldMediaPlaylist = undefined; // do nothing if the src is falsey if (!_src) { return; } this.mediaSource = new _videoJs2['default'].MediaSource({ mode: this.mode_ }); // load the MediaSource into the player this.mediaSource.addEventListener('sourceopen', this.handleSourceOpen.bind(this)); this.options_ = {}; if (typeof this.source_.withCredentials !== 'undefined') { this.options_.withCredentials = this.source_.withCredentials; } else if (_videoJs2['default'].options.hls) { this.options_.withCredentials = _videoJs2['default'].options.hls.withCredentials; } this.playlists = new Hls.PlaylistLoader(this.source_.src, this.options_.withCredentials); this.tech_.one('canplay', this.setupFirstPlay.bind(this)); this.playlists.on('loadedmetadata', function () { oldMediaPlaylist = _this2.playlists.media(); // if this isn't a live video and preload permits, start // downloading segments if (oldMediaPlaylist.endList && _this2.tech_.preload() !== 'metadata' && _this2.tech_.preload() !== 'none') { _this2.loadingState_ = 'segments'; } _this2.setupSourceBuffer_(); _this2.setupFirstPlay(); _this2.fillBuffer(); _this2.tech_.trigger('loadedmetadata'); }); this.playlists.on('error', function () { _this2.blacklistCurrentPlaylist_(_this2.playlists.error); }); this.playlists.on('loadedplaylist', function () { var updatedPlaylist = _this2.playlists.media(); var seekable = undefined; if (!updatedPlaylist) { // select the initial variant _this2.playlists.media(_this2.selectPlaylist()); return; } _this2.updateDuration(_this2.playlists.media()); // update seekable seekable = _this2.seekable(); if (_this2.duration() === Infinity && seekable.length !== 0) { _this2.mediaSource.addSeekableRange_(seekable.start(0), seekable.end(0)); } oldMediaPlaylist = updatedPlaylist; }); this.playlists.on('mediachange', function () { _this2.tech_.trigger({ type: 'mediachange', bubbles: true }); }); // do nothing if the tech has been disposed already // this can occur if someone sets the src in player.ready(), for instance if (!this.tech_.el()) { return; } this.tech_.src(_videoJs2['default'].URL.createObjectURL(this.mediaSource)); } }, { key: 'handleSourceOpen', value: function handleSourceOpen() { // Only attempt to create the source buffer if none already exist. // handleSourceOpen is also called when we are "re-opening" a source buffer // after `endOfStream` has been called (in response to a seek for instance) if (!this.sourceBuffer) { this.setupSourceBuffer_(); } // if autoplay is enabled, begin playback. This is duplicative of // code in video.js but is required because play() must be invoked // *after* the media source has opened. // NOTE: moving this invocation of play() after // sourceBuffer.appendBuffer() below caused live streams with // autoplay to stall if (this.tech_.autoplay()) { this.play(); } } /** * Blacklist playlists that are known to be codec or * stream-incompatible with the SourceBuffer configuration. For * instance, Media Source Extensions would cause the video element to * stall waiting for video data if you switched from a variant with * video and audio to an audio-only one. * * @param media {object} a media playlist compatible with the current * set of SourceBuffers. Variants in the current master playlist that * do not appear to have compatible codec or stream configurations * will be excluded from the default playlist selection algorithm * indefinitely. */ }, { key: 'excludeIncompatibleVariants_', value: function excludeIncompatibleVariants_(media) { var master = this.playlists.master; var codecCount = 2; var videoCodec = null; var audioProfile = null; var codecs = undefined; if (media.attributes && media.attributes.CODECS) { codecs = parseCodecs(media.attributes.CODECS); videoCodec = codecs.videoCodec; audioProfile = codecs.audioProfile; codecCount = codecs.codecCount; } master.playlists.forEach(function (variant) { var variantCodecs = { codecCount: 2, videoCodec: null, audioProfile: null }; if (variant.attributes && variant.attributes.CODECS) { variantCodecs = parseCodecs(variant.attributes.CODECS); } // if the streams differ in the presence or absence of audio or // video, they are incompatible if (variantCodecs.codecCount !== codecCount) { variant.excludeUntil = Infinity; } // if h.264 is specified on the current playlist, some flavor of // it must be specified on all compatible variants if (variantCodecs.videoCodec !== videoCodec) { variant.excludeUntil = Infinity; } // HE-AAC ("mp4a.40.5") is incompatible with all other versions of // AAC audio in Chrome 46. Don't mix the two. if (variantCodecs.audioProfile === '5' && audioProfile !== '5' || audioProfile === '5' && variantCodecs.audioProfile !== '5') { variant.excludeUntil = Infinity; } }); } }, { key: 'setupSourceBuffer_', value: function setupSourceBuffer_() { var media = this.playlists.media(); var mimeType = undefined; // wait until a media playlist is available and the Media Source is // attached if (!media || this.mediaSource.readyState !== 'open') { return; } // if the codecs were explicitly specified, pass them along to the // source buffer mimeType = 'video/mp2t'; if (media.attributes && media.attributes.CODECS) { mimeType += '; codecs="' + media.attributes.CODECS + '"'; } this.sourceBuffer = this.mediaSource.addSourceBuffer(mimeType); // exclude any incompatible variant streams from future playlist // selection this.excludeIncompatibleVariants_(media); // transition the sourcebuffer to the ended state if we've hit the end of // the playlist this.sourceBuffer.addEventListener('updateend', this.updateEndHandler_.bind(this)); } /** * Seek to the latest media position if this is a live video and the * player and video are loaded and initialized. */ }, { key: 'setupFirstPlay', value: function setupFirstPlay() { var seekable = undefined; var media = this.playlists.media(); // check that everything is ready to begin buffering // 1) the video is a live stream of unknown duration if (this.duration() === Infinity && // 2) the player has not played before and is not paused this.tech_.played().length === 0 && !this.tech_.paused() && // 3) the Media Source and Source Buffers are ready this.sourceBuffer && // 4) the active media playlist is available media && // 5) the video element or flash player is in a readyState of // at least HAVE_FUTURE_DATA this.tech_.readyState() >= 1) { // trigger the playlist loader to start "expired time"-tracking this.playlists.trigger('firstplay'); // seek to the latest media position for live videos seekable = this.seekable(); if (seekable.length) { this.tech_.setCurrentTime(seekable.end(0)); } } } /** * Begin playing the video. */ }, { key: 'play', value: function play() { this.loadingState_ = 'segments'; if (this.tech_.ended()) { this.tech_.setCurrentTime(0); } if (this.tech_.played().length === 0) { return this.setupFirstPlay(); } // if the viewer has paused and we fell out of the live window, // seek forward to the earliest available position if (this.duration() === Infinity) { if (this.tech_.currentTime() < this.seekable().start(0)) { this.tech_.setCurrentTime(this.seekable().start(0)); } } } }, { key: 'setCurrentTime', value: function setCurrentTime(currentTime) { var buffered = this.findBufferedRange_(); if (!(this.playlists && this.playlists.media())) { // return immediately if the metadata is not ready yet return 0; } // it's clearly an edge-case but don't thrown an error if asked to // seek within an empty playlist if (!this.playlists.media().segments) { return 0; } // if the seek location is already buffered, continue buffering as // usual if (buffered && buffered.length) { return currentTime; } // if we are in the middle of appending a segment, let it finish up if (this.pendingSegment_ && this.pendingSegment_.buffered) { return currentTime; } this.lastSegmentLoaded_ = null; // cancel outstanding requests and buffer appends this.cancelSegmentXhr(); // abort outstanding key requests, if necessary if (this.keyXhr_) { this.keyXhr_.aborted = true; this.cancelKeyXhr(); } // begin filling the buffer at the new position this.fillBuffer(this.playlists.getMediaIndexForTime_(currentTime)); } }, { key: 'duration', value: function duration() { var playlists = this.playlists; if (!playlists) { return 0; } if (this.mediaSource) { return this.mediaSource.duration; } return Hls.Playlist.duration(playlists.media()); } }, { key: 'seekable', value: function seekable() { var media = undefined; var seekable = undefined; if (!this.playlists) { return _videoJs2['default'].createTimeRanges(); } media = this.playlists.media(); if (!media) { return _videoJs2['default'].createTimeRanges(); } seekable = Hls.Playlist.seekable(media); if (seekable.length === 0) { return seekable; } // if the seekable start is zero, it may be because the player has // been paused for a long time and stopped buffering. in that case, // fall back to the playlist loader's running estimate of expired // time if (seekable.start(0) === 0) { return _videoJs2['default'].createTimeRanges([[this.playlists.expired_, this.playlists.expired_ + seekable.end(0)]]); } // seekable has been calculated based on buffering video data so it // can be returned directly return seekable; } /** * Update the player duration */ }, { key: 'updateDuration', value: function updateDuration(playlist) { var _this3 = this; var oldDuration = this.mediaSource.duration; var newDuration = Hls.Playlist.duration(playlist); var buffered = this.tech_.buffered(); var setDuration = function setDuration() { _this3.mediaSource.duration = newDuration; _this3.tech_.trigger('durationchange'); _this3.mediaSource.removeEventListener('sourceopen', setDuration); }; if (buffered.length > 0) { newDuration = Math.max(newDuration, buffered.end(buffered.length - 1)); } // if the duration has changed, invalidate the cached value if (oldDuration !== newDuration) { // update the duration if (this.mediaSource.readyState !== 'open') { this.mediaSource.addEventListener('sourceopen', setDuration); } else if (!this.sourceBuffer || !this.sourceBuffer.updating) { this.mediaSource.duration = newDuration; this.tech_.trigger('durationchange'); } } } /** * Clear all buffers and reset any state relevant to the current * source. After this function is called, the tech should be in a * state suitable for switching to a different video. */ }, { key: 'resetSrc_', value: function resetSrc_() { this.cancelSegmentXhr(); this.cancelKeyXhr(); if (this.sourceBuffer && this.mediaSource.readyState === 'open') { this.sourceBuffer.abort(); } } }, { key: 'cancelKeyXhr', value: function cancelKeyXhr() { if (this.keyXhr_) { this.keyXhr_.onreadystatechange = null; this.keyXhr_.abort(); this.keyXhr_ = null; } } }, { key: 'cancelSegmentXhr', value: function cancelSegmentXhr() { if (this.segmentXhr_) { // Prevent error handler from running. this.segmentXhr_.onreadystatechange = null; this.segmentXhr_.abort(); this.segmentXhr_ = null; } // clear out the segment being processed this.pendingSegment_ = null; } /** * Abort all outstanding work and cleanup. */ }, { key: 'dispose', value: function dispose() { this.stopCheckingBuffer_(); if (this.playlists) { this.playlists.dispose(); } this.resetSrc_(); _get(Object.getPrototypeOf(HlsHandler.prototype), 'dispose', this).call(this); } /** * Chooses the appropriate media playlist based on the current * bandwidth estimate and the player size. * @return the highest bitrate playlist less than the currently detected * bandwidth, accounting for some amount of bandwidth variance */ }, { key: 'selectPlaylist', value: function selectPlaylist() { var effectiveBitrate = undefined; var sortedPlaylists = this.playlists.master.playlists.slice(); var bandwidthPlaylists = []; var now = +new Date(); var i = undefined; var variant = undefined; var bandwidthBestVariant = undefined; var resolutionPlusOne = undefined; var resolutionPlusOneAttribute = undefined; var resolutionBestVariant = undefined; var width = undefined; var height = undefined; sortedPlaylists.sort(Hls.comparePlaylistBandwidth); // filter out any playlists that have been excluded due to // incompatible configurations or playback errors sortedPlaylists = sortedPlaylists.filter(function (localVariant) { if (typeof localVariant.excludeUntil !== 'undefined') { return now >= localVariant.excludeUntil; } return true; }); // filter out any variant that has greater effective bitrate // than the current estimated bandwidth i = sortedPlaylists.length; while (i--) { variant = sortedPlaylists[i]; // ignore playlists without bandwidth information if (!variant.attributes || !variant.attributes.BANDWIDTH) { continue; } effectiveBitrate = variant.attributes.BANDWIDTH * bandwidthVariance; if (effectiveBitrate < this.bandwidth) { bandwidthPlaylists.push(variant); // since the playlists are sorted in ascending order by // bandwidth, the first viable variant is the best if (!bandwidthBestVariant) { bandwidthBestVariant = variant; } } } i = bandwidthPlaylists.length; // sort variants by resolution bandwidthPlaylists.sort(Hls.comparePlaylistResolution); // forget our old variant from above, // or we might choose that in high-bandwidth scenarios // (this could be the lowest bitrate rendition as we go through all of them above) variant = null; width = parseInt(safeGetComputedStyle(this.tech_.el(), 'width'), 10); height = parseInt(safeGetComputedStyle(this.tech_.el(), 'height'), 10); // iterate through the bandwidth-filtered playlists and find // best rendition by player dimension while (i--) { variant = bandwidthPlaylists[i]; // ignore playlists without resolution information if (!variant.attributes || !variant.attributes.RESOLUTION || !variant.attributes.RESOLUTION.width || !variant.attributes.RESOLUTION.height) { continue; } // since the playlists are sorted, the first variant that has // dimensions less than or equal to the player size is the best var variantResolution = variant.attributes.RESOLUTION; if (variantResolution.width === width && variantResolution.height === height) { // if we have the exact resolution as the player use it resolutionPlusOne = null; resolutionBestVariant = variant; break; } else if (variantResolution.width < width && variantResolution.height < height) { // if both dimensions are less than the player use the // previous (next-largest) variant break; } else if (!resolutionPlusOne || variantResolution.width < resolutionPlusOneAttribute.width && variantResolution.height < resolutionPlusOneAttribute.height) { // If we still haven't found a good match keep a // reference to the previous variant for the next loop // iteration // By only saving variants if they are smaller than the // previously saved variant, we ensure that we also pick // the highest bandwidth variant that is just-larger-than // the video player resolutionPlusOne = variant; resolutionPlusOneAttribute = resolutionPlusOne.attributes.RESOLUTION; } } // fallback chain of variants return resolutionPlusOne || resolutionBestVariant || bandwidthBestVariant || sortedPlaylists[0]; } /** * Periodically request new segments and append video data. */ }, { key: 'checkBuffer_', value: function checkBuffer_() { // calling this method directly resets any outstanding buffer checks if (this.checkBufferTimeout_) { window.clearTimeout(this.checkBufferTimeout_); this.checkBufferTimeout_ = null; } this.fillBuffer(); this.drainBuffer(); // wait awhile and try again this.checkBufferTimeout_ = window.setTimeout(this.checkBuffer_.bind(this), bufferCheckInterval); } /** * Setup a periodic task to request new segments if necessary and * append bytes into the SourceBuffer. */ }, { key: 'startCheckingBuffer_', value: function startCheckingBuffer_() { this.checkBuffer_(); } /** * Stop the periodic task requesting new segments and feeding the * SourceBuffer. */ }, { key: 'stopCheckingBuffer_', value: function stopCheckingBuffer_() { if (this.checkBufferTimeout_) { window.clearTimeout(this.checkBufferTimeout_); this.checkBufferTimeout_ = null; } } /** * Determines whether there is enough video data currently in the buffer * and downloads a new segment if the buffered time is less than the goal. * @param seekToTime (optional) {number} the offset into the downloaded segment * to seek to, in seconds */ }, { key: 'fillBuffer', value: function fillBuffer(mediaIndex) { var tech = this.tech_; var currentTime = tech.currentTime(); var hasBufferedContent = this.tech_.buffered().length !== 0; var currentBuffered = this.findBufferedRange_(); var outsideBufferedRanges = !(currentBuffered && currentBuffered.length); var currentBufferedEnd = 0; var bufferedTime = 0; var segment = undefined; var segmentInfo = undefined; var segmentTimestampOffset = undefined; // if preload is set to "none", do not download segments until playback is requested if (this.loadingState_ !== 'segments') { return; } // if a video has not been specified, do nothing if (!tech.currentSrc() || !this.playlists) { return; } // if there is a request already in flight, do nothing if (this.segmentXhr_) { return; } // wait until the buffer is up to date if (this.pendingSegment_) { return; } // if no segments are available, do nothing if (this.playlists.state === 'HAVE_NOTHING' || !this.playlists.media() || !this.playlists.media().segments) { return; } // if a playlist switch is in progress, wait for it to finish if (this.playlists.state === 'SWITCHING_MEDIA') { return; } if (typeof mediaIndex === 'undefined') { if (currentBuffered && currentBuffered.length) { currentBufferedEnd = currentBuffered.end(0); mediaIndex = this.playlists.getMediaIndexForTime_(currentBufferedEnd); bufferedTime = Math.max(0, currentBufferedEnd - currentTime); // if there is plenty of content in the buffer and we're not // seeking, relax for awhile if (bufferedTime >= Hls.GOAL_BUFFER_LENGTH) { return; } } else { mediaIndex = this.playlists.getMediaIndexForTime_(this.tech_.currentTime()); } } segment = this.playlists.media().segments[mediaIndex]; // if the video has finished downloading if (!segment) { return; } // we have entered a state where we are fetching the same segment, // try to walk forward if (this.lastSegmentLoaded_ && this.playlistUriToUrl(this.lastSegmentLoaded_.uri) === this.playlistUriToUrl(segment.uri) && this.lastSegmentLoaded_.byterange === segment.byterange) { return this.fillBuffer(mediaIndex + 1); } // package up all the work to append the segment segmentInfo = { // resolve the segment URL relative to the playlist uri: this.playlistUriToUrl(segment.uri), // the segment's mediaIndex & mediaSequence at the time it was requested mediaIndex: mediaIndex, mediaSequence: this.playlists.media().mediaSequence, // the segment's playlist playlist: this.playlists.media(), // The state of the buffer when this segment was requested currentBufferedEnd: currentBufferedEnd, // unencrypted bytes of the segment bytes: null, // when a key is defined for this segment, the encrypted bytes encryptedBytes: null, // optionally, the decrypter that is unencrypting the segment decrypter: null, // the state of the buffer before a segment is appended will be // stored here so that the actual segment duration can be // determined after it has been appended buffered: null, // The target timestampOffset for this segment when we append it // to the source buffer timestampOffset: null }; if (mediaIndex > 0) { segmentTimestampOffset = Hls.Playlist.duration(segmentInfo.playlist, segmentInfo.playlist.mediaSequence + mediaIndex) + this.playlists.expired_; } if (this.tech_.seeking() && outsideBufferedRanges) { // If there are discontinuities in the playlist, we can't be sure of anything // related to time so we reset the timestamp offset and start appending data // anew on every seek if (segmentInfo.playlist.discontinuityStarts.length) { segmentInfo.timestampOffset = segmentTimestampOffset; } } else if (segment.discontinuity && currentBuffered.length) { // If we aren't seeking and are crossing a discontinuity, we should set // timestampOffset for new segments to be appended the end of the current // buffered time-range segmentInfo.timestampOffset = currentBuffered.end(0); } else if (!hasBufferedContent && this.tech_.currentTime() > 0.05) { // If we are trying to play at a position that is not zero but we aren't // currently seeking according to the video element segmentInfo.timestampOffset = segmentTimestampOffset; } this.loadSegment(segmentInfo); } }, { key: 'playlistUriToUrl', value: function playlistUriToUrl(segmentRelativeUrl) { var playListUrl = undefined; // resolve the segment URL relative to the playlist if (this.playlists.media().uri === this.source_.src) { playListUrl = (0, _resolveUrl2['default'])(this.source_.src, segmentRelativeUrl); } else { playListUrl = (0, _resolveUrl2['default'])((0, _resolveUrl2['default'])(this.source_.src, this.playlists.media().uri || ''), segmentRelativeUrl); } return playListUrl; } /* * Turns segment byterange into a string suitable for use in * HTTP Range requests */ }, { key: 'byterangeStr_', value: function byterangeStr_(byterange) { var byterangeStart = undefined; var byterangeEnd = undefined; // `byterangeEnd` is one less than `offset + length` because the HTTP range // header uses inclusive ranges byterangeEnd = byterange.offset + byterange.length - 1; byterangeStart = byterange.offset; return 'bytes=' + byterangeStart + '-' + byterangeEnd; } /* * Defines headers for use in the xhr request for a particular segment. */ }, { key: 'segmentXhrHeaders_', value: function segmentXhrHeaders_(segment) { var headers = {}; if ('byterange' in segment) { headers.Range = this.byterangeStr_(segment.byterange); } return headers; } /* * Sets `bandwidth`, `segmentXhrTime`, and appends to the `bytesReceived. * Expects an object with: * * `roundTripTime` - the round trip time for the request we're setting the time for * * `bandwidth` - the bandwidth we want to set * * `bytesReceived` - amount of bytes downloaded * `bandwidth` is the only required property. */ }, { key: 'setBandwidth', value: function setBandwidth(localXhr) { // calculate the download bandwidth this.segmentXhrTime = localXhr.roundTripTime; this.bandwidth = localXhr.bandwidth; this.bytesReceived += localXhr.bytesReceived || 0; this.tech_.trigger('bandwidthupdate'); } /* * Blacklists a playlist when an error occurs for a set amount of time * making it unavailable for selection by the rendition selection algorithm * and then forces a new playlist (rendition) selection. */ }, { key: 'blacklistCurrentPlaylist_', value: function blacklistCurrentPlaylist_(error) { var currentPlaylist = undefined; var nextPlaylist = undefined; // If the `error` was generated by the playlist loader, it will contain // the playlist we were trying to load (but failed) and that should be // blacklisted instead of the currently selected playlist which is likely // out-of-date in this scenario currentPlaylist = error.playlist || this.playlists.media(); // If there is no current playlist, then an error occurred while we were // trying to load the master OR while we were disposing of the tech if (!currentPlaylist) { this.error = error; return this.mediaSource.endOfStream('network'); } // Blacklist this playlist currentPlaylist.excludeUntil = Date.now() + blacklistDuration; // Select a new playlist nextPlaylist = this.selectPlaylist(); if (nextPlaylist) { _videoJs2['default'].log.warn('Problem encountered with the current ' + 'HLS playlist. Switching to another playlist.'); return this.playlists.media(nextPlaylist); } _videoJs2['default'].log.warn('Problem encountered with the current ' + 'HLS playlist. No suitable alternatives found.'); // We have no more playlists we can select so we must fail this.error = error; return this.mediaSource.endOfStream('network'); } }, { key: 'loadSegment', value: function loadSegment(segmentInfo) { var _this4 = this; var segment = segmentInfo.playlist.segments[segmentInfo.mediaIndex]; var removeToTime = 0; var seekable = this.seekable(); var currentTime = this.tech_.currentTime(); // Chrome has a hard limit of 150mb of // buffer and a very conservative "garbage collector" // We manually clear out the old buffer to ensure // we don't trigger the QuotaExceeded error // on the source buffer during subsequent appends if (this.sourceBuffer && !this.sourceBuffer.updating) { // If we have a seekable range use that as the limit for what can be removed safely // otherwise remove anything older than 1 minute before the current play head if (seekable.length && seekable.start(0) > 0 && seekable.start(0) < currentTime) { removeToTime = seekable.start(0); } else { removeToTime = currentTime - 60; } if (removeToTime > 0) { this.sourceBuffer.remove(0, removeToTime); } } // if the segment is encrypted, request the key if (segment.key) { this.fetchKey_(segment); } // request the next segment this.segmentXhr_ = Hls.xhr({ uri: segmentInfo.uri, responseType: 'arraybuffer', withCredentials: this.source_.withCredentials, // Set xhr timeout to 150% of the segment duration to allow us // some time to switch renditions in the event of a catastrophic // decrease in network performance or a server issue. timeout: segment.duration * 1.5 * 1000, headers: this.segmentXhrHeaders_(segment) }, function (error, request) { // This is a timeout of a previously aborted segment request // so simply ignore it if (!_this4.segmentXhr_ || request !== _this4.segmentXhr_) { return; } // the segment request is no longer outstanding _this4.segmentXhr_ = null; // if a segment request times out, we may have better luck with another playlist if (request.timedout) { _this4.bandwidth = 1; return _this4.playlists.media(_this4.selectPlaylist()); } // otherwise, trigger a network error if (!request.aborted && error) { return _this4.blacklistCurrentPlaylist_({ status: request.status, message: 'HLS segment request error at URL: ' + segmentInfo.uri, code: request.status >= 500 ? 4 : 2 }); } // stop processing if the request was aborted if (!request.response) { return; } _this4.lastSegmentLoaded_ = segment; _this4.setBandwidth(request); if (segment.key) { segmentInfo.encryptedBytes = new Uint8Array(request.response); } else { segmentInfo.bytes = new Uint8Array(request.response); } _this4.pendingSegment_ = segmentInfo; _this4.tech_.trigger('progress'); _this4.drainBuffer(); // figure out what stream the next segment should be downloaded from // with the updated bandwidth information _this4.playlists.media(_this4.selectPlaylist()); }); } }, { key: 'drainBuffer', value: function drainBuffer() { var segmentInfo = undefined; var mediaIndex = undefined; var playlist = undefined; var bytes = undefined; var segment = undefined; var decrypter = undefined; var segIv = undefined; // if the buffer is empty or the source buffer hasn't been created // yet, do nothing if (!this.pendingSegment_ || !this.sourceBuffer) { return; } // the pending segment has already been appended and we're waiting // for updateend to fire if (this.pendingSegment_.buffered) { return; } // we can't append more data if the source buffer is busy processing // what we've already sent if (this.sourceBuffer.updating) { return; } segmentInfo = this.pendingSegment_; mediaIndex = segmentInfo.mediaIndex; playlist = segmentInfo.playlist; bytes = segmentInfo.bytes; segment = playlist.segments[mediaIndex]; if (segment.key && !bytes) { // this is an encrypted segment // if the key download failed, we want to skip this segment // but if the key hasn't downloaded yet, we want to try again later if (keyFailed(segment.key)) { return this.blacklistCurrentPlaylist_({ message: 'HLS segment key request error.', code: 4 }); } else if (!segment.key.bytes) { // waiting for the key bytes, try again later return; } else if (segmentInfo.decrypter) { // decryption is in progress, try again later return; } // if the media sequence is greater than 2^32, the IV will be incorrect // assuming 10s segments, that would be about 1300 years segIv = segment.key.iv || new Uint32Array([0, 0, 0, mediaIndex + playlist.mediaSequence]); // create a decrypter to incrementally decrypt the segment decrypter = new Hls.Decrypter(segmentInfo.encryptedBytes, segment.key.bytes, segIv, function (error, localBytes) { if (error) { _videoJs2['default'].log.warn(error); } segmentInfo.bytes = localBytes; }); segmentInfo.decrypter = decrypter; return; } this.pendingSegment_.buffered = this.tech_.buffered(); if (segmentInfo.timestampOffset !== null) { this.sourceBuffer.timestampOffset = segmentInfo.timestampOffset; } // the segment is asynchronously added to the current buffered data this.sourceBuffer.appendBuffer(bytes); } }, { key: 'updateEndHandler_', value: function updateEndHandler_() { var segmentInfo = this.pendingSegment_; var playlist = undefined; var currentMediaIndex = undefined; var currentBuffered = undefined; var seekable = undefined; var timelineUpdate = undefined; var isEndOfStream = undefined; // stop here if the update errored or was aborted if (!segmentInfo) { this.pendingSegment_ = null; return; } // In Firefox, the updateend event is triggered for both removing from the buffer and // adding to the buffer. To prevent this code from executing on removals, we wait for // segmentInfo to have a filled in buffered value before we continue processing. if (!segmentInfo.buffered) { return; } this.pendingSegment_ = null; playlist = segmentInfo.playlist; currentMediaIndex = segmentInfo.mediaIndex + (segmentInfo.mediaSequence - playlist.mediaSequence); currentBuffered = this.findBufferedRange_(); isEndOfStream = detectEndOfStream(playlist, this.mediaSource, currentMediaIndex, currentBuffered); // if we switched renditions don't try to add segment timeline // information to the playlist if (segmentInfo.playlist.uri !== this.playlists.media().uri) { if (isEndOfStream) { return this.mediaSource.endOfStream(); } return this.fillBuffer(); } // when seeking to the beginning of the seekable range, it's // possible that imprecise timing information may cause the seek to // end up earlier than the start of the range // in that case, seek again seekable = this.seekable(); if (this.tech_.seeking() && currentBuffered.length === 0) { if (seekable.length && this.tech_.currentTime() < seekable.start(0)) { var next = this.findNextBufferedRange_(); if (next.length) { _videoJs2['default'].log('tried seeking to', this.tech_.currentTime(), 'but that was too early, retrying at', next.start(0)); this.tech_.setCurrentTime(next.start(0) + TIME_FUDGE_FACTOR); } } } timelineUpdate = Hls.findSoleUncommonTimeRangesEnd_(segmentInfo.buffered, this.tech_.buffered()); // Update segment meta-data (duration and end-point) based on timeline updateSegmentMetadata(playlist, currentMediaIndex, timelineUpdate); // If we decide to signal the end of stream, then we can return instead // of trying to fetch more segments if (isEndOfStream) { return this.mediaSource.endOfStream(); } if (timelineUpdate !== null || segmentInfo.buffered.length !== this.tech_.buffered().length) { this.updateDuration(playlist); // check if it's time to download the next segment this.fillBuffer(); return; } // the last segment append must have been entirely in the // already buffered time ranges. just buffer forward until we // find a segment that adds to the buffered time ranges and // improves subsequent media index calculations. this.fillBuffer(currentMediaIndex + 1); return; } /** * Attempt to retrieve the key for a particular media segment. */ }, { key: 'fetchKey_', value: function fetchKey_(segment) { var _this5 = this; var key = undefined; var settings = undefined; var receiveKey = undefined; // if there is a pending XHR or no segments, don't do anything if (this.keyXhr_) { return; } settings = this.options_; /** * Handle a key XHR response. */ receiveKey = function (keyRecieved) { return function (error, request) { var view = undefined; _this5.keyXhr_ = null; if (error || !request.response || request.response.byteLength !== 16) { keyRecieved.retries = keyRecieved.retries || 0; keyRecieved.retries++; if (!request.aborted) { // try fetching again _this5.fetchKey_(segment); } return; } view = new DataView(request.response); keyRecieved.bytes = new Uint32Array([view.getUint32(0), view.getUint32(4), view.getUint32(8), view.getUint32(12)]); // check to see if this allows us to make progress buffering now _this5.checkBuffer_(); }; }; key = segment.key; // nothing to do if this segment is unencrypted if (!key) { return; } // request the key if the retry limit hasn't been reached if (!key.bytes && !keyFailed(key)) { this.keyXhr_ = Hls.xhr({ uri: this.playlistUriToUrl(key.uri), responseType: 'arraybuffer', withCredentials: settings.withCredentials }, receiveKey(key)); return; } } }]); return HlsHandler; })(Component); exports['default'] = HlsHandler; HlsHandler.prototype.findBufferedRange_ = filterBufferedRanges(function (start, end, time) { return start - TIME_FUDGE_FACTOR <= time && end + TIME_FUDGE_FACTOR >= time; }); /** * Returns the TimeRanges that begin at or later than the specified * time. * @param time (optional) {number} the time to filter on. Defaults to * currentTime. * @return a new TimeRanges object. */ HlsHandler.prototype.findNextBufferedRange_ = filterBufferedRanges(function (start, end, time) { return start - TIME_FUDGE_FACTOR >= time; }); /** * The Source Handler object, which informs video.js what additional * MIME types are supported and sets up playback. It is registered * automatically to the appropriate tech based on the capabilities of * the browser it is running in. It is not necessary to use or modify * this object in normal usage. */ var HlsSourceHandler = function HlsSourceHandler(mode) { return { canHandleSource: function canHandleSource(srcObj) { return HlsSourceHandler.canPlayType(srcObj.type); }, handleSource: function handleSource(source, tech) { if (mode === 'flash') { // We need to trigger this asynchronously to give others the chance // to bind to the event when a source is set at player creation tech.setTimeout(function () { tech.trigger('loadstart'); }, 1); } tech.hls = new HlsHandler(tech, { source: source, mode: mode }); tech.hls.src(source.src); return tech.hls; }, canPlayType: function canPlayType(type) { return HlsSourceHandler.canPlayType(type); } }; }; HlsSourceHandler.canPlayType = function (type) { var mpegurlRE = /^application\/(?:x-|vnd\.apple\.)mpegurl/i; // favor native HLS support if it's available if (Hls.supportsNativeHls) { return false; } return mpegurlRE.test(type); }; if (typeof _videoJs2['default'].MediaSource === 'undefined' || typeof _videoJs2['default'].URL === 'undefined') { _videoJs2['default'].MediaSource = _videojsContribMediaSources.MediaSource; _videoJs2['default'].URL = _videojsContribMediaSources.URL; } // register source handlers with the appropriate techs if (_videojsContribMediaSources.MediaSource.supportsNativeMediaSources()) { _videoJs2['default'].getComponent('Html5').registerSourceHandler(HlsSourceHandler('html5')); } if (window.Uint8Array) { _videoJs2['default'].getComponent('Flash').registerSourceHandler(HlsSourceHandler('flash')); } _videoJs2['default'].HlsHandler = HlsHandler; _videoJs2['default'].HlsSourceHandler = HlsSourceHandler; _videoJs2['default'].Hls = Hls; _videoJs2['default'].m3u8 = _m3u82['default']; exports['default'] = { Hls: Hls, HlsHandler: HlsHandler, HlsSourceHandler: HlsSourceHandler }; module.exports = exports['default']; }).call(this,typeof global !== "undefined" ? global : typeof self !== "undefined" ? self : typeof window !== "undefined" ? window : {}) },{"./bin-utils":1,"./decrypter":5,"./m3u8":6,"./playlist":11,"./playlist-loader":10,"./resolve-url":12,"./xhr":14,"videojs-contrib-media-sources":28}]},{},[51])(51) });