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/*
* Copyright (c) 2017-2018 Rafael da Silva Rocha.
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
* LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
* OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
* WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
/**
* @fileoverview The WaveFile class.
* @see https://github.com/rochars/wavefile
/** @module wavefile */
import bitDepthLib from './vendor/bitdepth.js';
import * as imaadpcm from './vendor/imaadpcm.js';
import * as alawmulaw from './vendor/alawmulaw.js';
import {encode, decode} from './vendor/base64-arraybuffer-es6.js';
import {unpackArray, packArrayTo, unpackArrayTo,
unpack, packTo} from './vendor/byte-data.js';
import makeWavHeader from './lib/make-wav-header.js';
import validateWavHeader from './lib/validate-wav-header';
import {riffChunks, findChunk_} from './vendor/riff-chunks.js';
import writeWavBuffer from './lib/wav-buffer-writer.js';
import readWavBuffer from './lib/wav-buffer-reader.js';
import WavBuffer from './lib/wav-buffer.js';
* Class representing a wav file.
* @extends WavBuffer
* @ignore
export default class WaveFile extends WavBuffer {
* @param {?Uint8Array} bytes A wave file buffer.
* @throws {Error} If no 'RIFF' chunk is found.
* @throws {Error} If no 'fmt ' chunk is found.
* @throws {Error} If no 'data' chunk is found.
constructor(bytes=null) {
super();
* The bit depth code according to the samples.
* @type {string}
this.bitDepth = '0';
* @type {!Object}
* @private
this.dataType = {};
// Load a file from the buffer if one was passed
// when creating the object
if (bytes) {
this.fromBuffer(bytes);
}
* Return the sample at a given index.
* @param {number} index The sample index.
* @return {number} The sample.
* @throws {Error} If the sample index is off range.
getSample(index) {
/** @type {number} */
let sample;
sample
index = index * (this.dataType.bits / 8);
if (index + this.dataType.bits / 8 > this.data.samples.length) {
throw new Error('Range error');
return unpack(
this.data.samples.slice(index, index + this.dataType.bits / 8),
this.dataType);
* Set the sample at a given index.
* @param {number} sample The sample.
setSample(index, sample) {
packTo(sample, this.dataType, this.data.samples, index);
* Set up the WaveFile object based on the arguments passed.
* @param {number} numChannels The number of channels
* (Integer numbers: 1 for mono, 2 stereo and so on).
* @param {number} sampleRate The sample rate.
* Integer numbers like 8000, 44100, 48000, 96000, 192000.
* @param {string} bitDepthCode The audio bit depth code.
* One of '4', '8', '8a', '8m', '16', '24', '32', '32f', '64'
* or any value between '8' and '32' (like '12').
* @param {!Array<number>|!Array<!Array<number>>|!ArrayBufferView} samples
* The samples. Must be in the correct range according to the bit depth.
* @param {?Object} options Optional. Used to force the container
* as RIFX with {'container': 'RIFX'}
* @throws {Error} If any argument does not meet the criteria.
fromScratch(numChannels, sampleRate, bitDepthCode, samples, options={}) {
if (!options.container) {
options.container = 'RIFF';
this.container = options.container;
this.bitDepth = bitDepthCode;
samples = this.interleave_(samples);
this.updateDataType_();
let numBytes = this.dataType.bits / 8;
this.data.samples = new Uint8Array(samples.length * numBytes);
packArrayTo(samples, this.dataType, this.data.samples);
/** @type {!Object} */
let header = makeWavHeader(
bitDepthCode, numChannels, sampleRate,
numBytes, this.data.samples.length, options);
this.clearHeader_();
this.chunkSize = header.chunkSize;
this.format = header.format;
this.fmt = header.fmt;
if (header.fact) {
this.fact = header.fact;
this.data.chunkId = 'data';
this.data.chunkSize = this.data.samples.length;
validateWavHeader(this);
* Set up the WaveFile object from a byte buffer.
* @param {!Uint8Array} bytes The buffer.
* @param {boolean=} samples True if the samples should be loaded.
* @throws {Error} If container is not RIFF, RIFX or RF64.
fromBuffer(bytes, samples=true) {
readWavBuffer(bytes, samples, this);
this.bitDepthFromFmt_();
* Return a byte buffer representig the WaveFile object as a .wav file.
* The return value of this method can be written straight to disk.
* @return {!Uint8Array} A .wav file.
* @throws {Error} If any property of the object appears invalid.
toBuffer() {
return writeWavBuffer(this);
* Use a .wav file encoded as a base64 string to load the WaveFile object.
* @param {string} base64String A .wav file as a base64 string.
fromBase64(base64String) {
this.fromBuffer(new Uint8Array(decode(base64String)));
* Return a base64 string representig the WaveFile object as a .wav file.
* @return {string} A .wav file as a base64 string.
toBase64() {
/** @type {!Uint8Array} */
let buffer = this.toBuffer();
return encode(buffer, 0, buffer.length);
* Return a DataURI string representig the WaveFile object as a .wav file.
* The return of this method can be used to load the audio in browsers.
* @return {string} A .wav file as a DataURI.
toDataURI() {
return 'data:audio/wav;base64,' + this.toBase64();
* Use a .wav file encoded as a DataURI to load the WaveFile object.
* @param {string} dataURI A .wav file as DataURI.
fromDataURI(dataURI) {
this.fromBase64(dataURI.replace('data:audio/wav;base64,', ''));
* Force a file as RIFF.
toRIFF() {
this.fromScratch(
this.fmt.numChannels,
this.fmt.sampleRate,
this.bitDepth,
unpackArray(this.data.samples, this.dataType));
* Force a file as RIFX.
toRIFX() {
unpackArray(this.data.samples, this.dataType),
{container: 'RIFX'});
* Change the bit depth of the samples.
* @param {string} newBitDepth The new bit depth of the samples.
* One of '8' ... '32' (integers), '32f' or '64' (floats)
* @param {boolean} changeResolution A boolean indicating if the
* resolution of samples should be actually changed or not.
* @throws {Error} If the bit depth is not valid.
toBitDepth(newBitDepth, changeResolution=true) {
/** @type {string} */
let toBitDepth = newBitDepth;
let thisBitDepth = this.bitDepth;
if (!changeResolution) {
if (newBitDepth != '32f') {
toBitDepth = this.dataType.bits.toString();
thisBitDepth = this.dataType.bits;
this.assureUncompressed_();
let sampleCount = this.data.samples.length / (this.dataType.bits / 8);
/** @type {!Float64Array} */
let typedSamplesInput = new Float64Array(sampleCount + 1);
let typedSamplesOutput = new Float64Array(sampleCount + 1);
unpackArrayTo(this.data.samples, this.dataType, typedSamplesInput);
bitDepthLib(
typedSamplesInput, thisBitDepth, toBitDepth, typedSamplesOutput);
newBitDepth,
typedSamplesOutput,
{container: this.correctContainer_()});
* Encode a 16-bit wave file as 4-bit IMA ADPCM.
* @throws {Error} If sample rate is not 8000.
* @throws {Error} If number of channels is not 1.
toIMAADPCM() {
if (this.fmt.sampleRate !== 8000) {
throw new Error(
'Only 8000 Hz files can be compressed as IMA-ADPCM.');
} else if (this.fmt.numChannels !== 1) {
'Only mono files can be compressed as IMA-ADPCM.');
} else {
this.assure16Bit_();
let output = new Int16Array(this.data.samples.length / 2);
unpackArrayTo(this.data.samples, this.dataType, output);
'4',
imaadpcm.encode(output),
* Decode a 4-bit IMA ADPCM wave file as a 16-bit wave file.
* @param {string} bitDepthCode The new bit depth of the samples.
* One of '8' ... '32' (integers), '32f' or '64' (floats).
* Optional. Default is 16.
fromIMAADPCM(bitDepthCode='16') {
'16',
imaadpcm.decode(this.data.samples, this.fmt.blockAlign),
if (bitDepthCode != '16') {
this.toBitDepth(bitDepthCode);
* Encode a 16-bit wave file as 8-bit A-Law.
toALaw() {
'8a',
alawmulaw.alaw.encode(output),
* Decode a 8-bit A-Law wave file into a 16-bit wave file.
fromALaw(bitDepthCode='16') {
alawmulaw.alaw.decode(this.data.samples),
* Encode 16-bit wave file as 8-bit mu-Law.
toMuLaw() {
'8m',
alawmulaw.mulaw.encode(output),
* Decode a 8-bit mu-Law wave file into a 16-bit wave file.
fromMuLaw(bitDepthCode='16') {
alawmulaw.mulaw.decode(this.data.samples),
* Write a RIFF tag in the INFO chunk. If the tag do not exist,
* then it is created. It if exists, it is overwritten.
* @param {string} tag The tag name.
* @param {string} value The tag value.
* @throws {Error} If the tag name is not valid.
setTag(tag, value) {
tag = this.fixTagName_(tag);
let index = this.getTagIndex_(tag);
if (index.TAG !== null) {
this.LIST[index.LIST].subChunks[index.TAG].chunkSize =
value.length + 1;
this.LIST[index.LIST].subChunks[index.TAG].value = value;
} else if (index.LIST !== null) {
this.LIST[index.LIST].subChunks.push({
chunkId: tag,
chunkSize: value.length + 1,
value: value});
this.LIST.push({
chunkId: 'LIST',
chunkSize: 8 + value.length + 1,
format: 'INFO',
subChunks: []});
this.LIST[this.LIST.length - 1].subChunks.push({
* Return the value of a RIFF tag in the INFO chunk.
* @return {?string} The value if the tag is found, null otherwise.
getTag(tag) {
return this.LIST[index.LIST].subChunks[index.TAG].value;
return null;
* Return a Object<tag, value> with the RIFF tags in the file.
* @return {!Object<string, string>} The file tags.
listTags() {
/** @type {?number} */
let index = this.getLISTINFOIndex_();
let tags = {};
if (index !== null) {
for (let i=0; i<this.LIST[index].subChunks.length; i++) {
tags[this.LIST[index].subChunks[i].chunkId] =
this.LIST[index].subChunks[i].value;
return tags;
* Remove a RIFF tag in the INFO chunk.
* @return {boolean} True if a tag was deleted.
deleteTag(tag) {
this.LIST[index.LIST].subChunks.splice(index.TAG, 1);
return true;
return false;
* Create a cue point in the wave file.
* @param {number} position The cue point position in milliseconds.
* @param {string} labl The LIST adtl labl text of the marker. Optional.
setCuePoint(position, labl='') {
this.cue.chunkId = 'cue ';
position = (position * this.fmt.sampleRate) / 1000;
/** @type {!Array<!Object>} */
let existingPoints = this.getCuePoints_();
this.clearLISTadtl_();
let len = this.cue.points.length;
this.cue.points = [];
/** @type {boolean} */
let hasSet = false;
if (len === 0) {
this.setCuePoint_(position, 1, labl);
for (let i=0; i<len; i++) {
if (existingPoints[i].dwPosition > position && !hasSet) {
this.setCuePoint_(position, i + 1, labl);
this.setCuePoint_(
existingPoints[i].dwPosition,
i + 2,
existingPoints[i].label);
hasSet = true;
i + 1,
if (!hasSet) {
this.setCuePoint_(position, this.cue.points.length + 1, labl);
this.cue.dwCuePoints = this.cue.points.length;
* Remove a cue point from a wave file.
* @param {number} index the index of the point. First is 1,
* second is 2, and so on.
deleteCuePoint(index) {
if (i + 1 !== index) {
if (this.cue.dwCuePoints) {
this.cue.chunkId = '';
* Return an array with all cue points in the file, in the order they appear
* in the file.
* The difference between this method and using the list in WaveFile.cue
* is that the return value of this method includes the position in
* milliseconds of each cue point (WaveFile.cue only have the sample offset)
* @return {!Array<!Object>}
listCuePoints() {
let points = this.getCuePoints_();
for (let i=0; i<points.length; i++) {
points[i].milliseconds =
(points[i].dwPosition / this.fmt.sampleRate) * 1000;
return points;
* Update the label of a cue point.
* @param {number} pointIndex The ID of the cue point.
* @param {string} label The new text for the label.
updateLabel(pointIndex, label) {
let adtlIndex = this.getAdtlChunk_();
if (adtlIndex !== null) {
for (let i=0; i<this.LIST[adtlIndex].subChunks.length; i++) {
if (this.LIST[adtlIndex].subChunks[i].dwName ==
pointIndex) {
this.LIST[adtlIndex].subChunks[i].value = label;
* Set the string code of the bit depth based on the 'fmt ' chunk.
bitDepthFromFmt_() {
if (this.fmt.audioFormat === 3 && this.fmt.bitsPerSample === 32) {
this.bitDepth = '32f';
} else if (this.fmt.audioFormat === 6) {
this.bitDepth = '8a';
} else if (this.fmt.audioFormat === 7) {
this.bitDepth = '8m';
this.bitDepth = this.fmt.bitsPerSample.toString();
* Push a new cue point in this.cue.points.
* @param {number} position The position in milliseconds.
* @param {number} dwName the dwName of the cue point
setCuePoint_(position, dwName, label) {
this.cue.points.push({
dwName: dwName,
dwPosition: position,
fccChunk: 'data',
dwChunkStart: 0,
dwBlockStart: 0,
dwSampleOffset: position,
});
this.setLabl_(dwName, label);
getCuePoints_() {
let points = [];
for (let i=0; i<this.cue.points.length; i++) {
points.push({
dwPosition: this.cue.points[i].dwPosition,
label: this.getLabelForCuePoint_(
this.cue.points[i].dwName)});
* Return the label of a cue point.
* @param {number} pointDwName The ID of the cue point.
* @return {string}
getLabelForCuePoint_(pointDwName) {
pointDwName) {
return this.LIST[adtlIndex].subChunks[i].value;
return '';
* Clear any LIST chunk labeled as 'adtl'.
clearLISTadtl_() {
for (let i=0; i<this.LIST.length; i++) {
if (this.LIST[i].format == 'adtl') {
this.LIST.splice(i);
* Create a new 'labl' subchunk in a 'LIST' chunk of type 'adtl'.
* @param {number} dwName The ID of the cue point.
* @param {string} label The label for the cue point.
setLabl_(dwName, label) {
if (adtlIndex === null) {
chunkSize: 4,
format: 'adtl',
adtlIndex = this.LIST.length - 1;
this.setLabelText_(adtlIndex === null ? 0 : adtlIndex, dwName, label);
* @param {number} adtlIndex The index of the 'adtl' LIST in this.LIST.
setLabelText_(adtlIndex, dwName, label) {
this.LIST[adtlIndex].subChunks.push({
chunkId: 'labl',
chunkSize: label.length,
value: label
this.LIST[adtlIndex].chunkSize += label.length + 4 + 4 + 4 + 1;
* Return the index of the 'adtl' LIST in this.LIST.
* @return {?number}
getAdtlChunk_() {
return i;
* Return the index of the INFO chunk in the LIST chunk.
* @return {?number} the index of the INFO chunk.
getLISTINFOIndex_() {
let index = null;
if (this.LIST[i].format === 'INFO') {
index = i;
break;
return index;
* Return the index of a tag in a FILE chunk.
* @return {!Object<string, ?number>}
* Object.LIST is the INFO index in LIST
* Object.TAG is the tag index in the INFO
getTagIndex_(tag) {
/** @type {!Object<string, ?number>} */
let index = {LIST: null, TAG: null};
if (this.LIST[i].format == 'INFO') {
index.LIST = i;
for (let j=0; j<this.LIST[i].subChunks.length; j++) {
if (this.LIST[i].subChunks[j].chunkId == tag) {
index.TAG = j;
* Fix a RIFF tag format if possible, throw an error otherwise.
* @return {string} The tag name in proper fourCC format.
fixTagName_(tag) {
if (tag.constructor !== String) {
throw new Error('Invalid tag name.');
} else if (tag.length < 4) {
for (let i=0; i<4-tag.length; i++) {
tag += ' ';
return tag;
* Reset attributes that should emptied when a file is
* created with the fromScratch() or fromBuffer() methods.
clearHeader_() {
this.fmt.cbSize = 0;
this.fmt.validBitsPerSample = 0;
this.fact.chunkId = '';
this.ds64.chunkId = '';
* Make the file 16-bit if it is not.
assure16Bit_() {
if (this.bitDepth != '16') {
this.toBitDepth('16');
* Uncompress the samples in case of a compressed file.
assureUncompressed_() {
if (this.bitDepth == '8a') {
this.fromALaw();
} else if (this.bitDepth == '8m') {
this.fromMuLaw();
} else if (this.bitDepth == '4') {
this.fromIMAADPCM();
* @param {!Array<number>|!Array<!Array<number>>|!ArrayBufferView} samples The samples.
interleave_(samples) {
if (samples.length > 0) {
if (samples[0].constructor === Array) {
/** @type {!Array<number>} */
let finalSamples = [];
for (let i=0; i < samples[0].length; i++) {
for (let j=0; j < samples.length; j++) {
finalSamples.push(samples[j][i]);
samples = finalSamples;
return samples;
* Update the type definition used to read and write the samples.
updateDataType_() {
this.dataType = {
bits: ((parseInt(this.bitDepth, 10) - 1) | 7) + 1,
float: this.bitDepth == '32f' || this.bitDepth == '64',
signed: this.bitDepth != '8',
be: this.container == 'RIFX'
};
if (['4', '8a', '8m'].indexOf(this.bitDepth) > -1 ) {
this.dataType.bits = 8;
this.dataType.signed = false;
* Return 'RIFF' if the container is 'RF64', the current container name
* otherwise. Used to enforce 'RIFF' when RF64 is not allowed.
correctContainer_() {
return this.container == 'RF64' ? 'RIFF' : this.container;
rochars /
wavefile
Rafael Rocha
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