const ArrayBufferStream = require('./ArrayBufferStream'); const log = require('./log'); /** * Data used by the decompression algorithm * @type {Array} */ const STEP_TABLE = [ 7, 8, 9, 10, 11, 12, 13, 14, 16, 17, 19, 21, 23, 25, 28, 31, 34, 37, 41, 45, 50, 55, 60, 66, 73, 80, 88, 97, 107, 118, 130, 143, 157, 173, 190, 209, 230, 253, 279, 307, 337, 371, 408, 449, 494, 544, 598, 658, 724, 796, 876, 963, 1060, 1166, 1282, 1411, 1552, 1707, 1878, 2066, 2272, 2499, 2749, 3024, 3327, 3660, 4026, 4428, 4871, 5358, 5894, 6484, 7132, 7845, 8630, 9493, 10442, 11487, 12635, 13899, 15289, 16818, 18500, 20350, 22385, 24623, 27086, 29794, 32767 ]; /** * Data used by the decompression algorithm * @type {Array} */ const INDEX_TABLE = [ -1, -1, -1, -1, 2, 4, 6, 8, -1, -1, -1, -1, 2, 4, 6, 8 ]; /** * Decode wav audio files that have been compressed with the ADPCM format. * This is necessary because, while web browsers have native decoders for many audio * formats, ADPCM is a non-standard format used by Scratch since its early days. * This decoder is based on code from Scratch-Flash: * https://github.com/LLK/scratch-flash/blob/master/src/sound/WAVFile.as */ class ADPCMSoundDecoder { /** * @param {AudioContext} audioContext - a webAudio context * @constructor */ constructor (audioContext) { this.audioContext = audioContext; } /** * Data used by the decompression algorithm * @type {Array} */ static get STEP_TABLE () { return STEP_TABLE; } /** * Data used by the decompression algorithm * @type {Array} */ static get INDEX_TABLE () { return INDEX_TABLE; } /** * Decode an ADPCM sound stored in an ArrayBuffer and return a promise * with the decoded audio buffer. * @param {ArrayBuffer} audioData - containing ADPCM encoded wav audio * @return {AudioBuffer} the decoded audio buffer */ decode (audioData) { return new Promise((resolve, reject) => { const stream = new ArrayBufferStream(audioData); const riffStr = stream.readUint8String(4); if (riffStr !== 'RIFF') { log.warn('incorrect adpcm wav header'); reject(); } const lengthInHeader = stream.readInt32(); if ((lengthInHeader + 8) !== audioData.byteLength) { log.warn(`adpcm wav length in header: ${lengthInHeader} is incorrect`); } const wavStr = stream.readUint8String(4); if (wavStr !== 'WAVE') { log.warn('incorrect adpcm wav header'); reject(); } const formatChunk = this.extractChunk('fmt ', stream); this.encoding = formatChunk.readUint16(); this.channels = formatChunk.readUint16(); this.samplesPerSecond = formatChunk.readUint32(); this.bytesPerSecond = formatChunk.readUint32(); this.blockAlignment = formatChunk.readUint16(); this.bitsPerSample = formatChunk.readUint16(); formatChunk.position += 2; // skip extra header byte count this.samplesPerBlock = formatChunk.readUint16(); this.adpcmBlockSize = ((this.samplesPerBlock - 1) / 2) + 4; // block size in bytes const compressedData = this.extractChunk('data', stream); const sampleCount = this.numberOfSamples(compressedData, this.adpcmBlockSize); const buffer = this.audioContext.createBuffer(1, sampleCount, this.samplesPerSecond); this.imaDecompress(compressedData, this.adpcmBlockSize, buffer.getChannelData(0)); resolve(buffer); }); } /** * Extract a chunk of audio data from the stream, consisting of a set of audio data bytes * @param {string} chunkType - the type of chunk to extract. 'data' or 'fmt' (format) * @param {ArrayBufferStream} stream - an stream containing the audio data * @return {ArrayBufferStream} a stream containing the desired chunk */ extractChunk (chunkType, stream) { stream.position = 12; while (stream.position < (stream.getLength() - 8)) { const typeStr = stream.readUint8String(4); const chunkSize = stream.readInt32(); if (typeStr === chunkType) { const chunk = stream.extract(chunkSize); return chunk; } stream.position += chunkSize; } } /** * Count the exact number of samples in the compressed data. * @param {ArrayBufferStream} compressedData - the compressed data * @param {number} blockSize - size of each block in the data in bytes * @return {number} number of samples in the compressed data */ numberOfSamples (compressedData, blockSize) { if (!compressedData) return 0; compressedData.position = 0; const available = compressedData.getBytesAvailable(); const blocks = (available / blockSize) | 0; // Number of samples in full blocks. const fullBlocks = blocks * (2 * (blockSize - 4)) + 1; // Number of samples in the last incomplete block. 0 if the last block // is full. const subBlock = Math.max((available % blockSize) - 4, 0) * 2; // 1 if the last block is incomplete. 0 if it is complete. const incompleteBlock = Math.min(available % blockSize, 1); return fullBlocks + subBlock + incompleteBlock; } /** * Decompress sample data using the IMA ADPCM algorithm. * Note: Handles only one channel, 4-bits per sample. * @param {ArrayBufferStream} compressedData - a stream of compressed audio samples * @param {number} blockSize - the number of bytes in the stream * @param {Float32Array} out - the uncompressed audio samples */ imaDecompress (compressedData, blockSize, out) { let sample; let step; let code; let delta; let index = 0; let lastByte = -1; // -1 indicates that there is no saved lastByte // Bail and return no samples if we have no data if (!compressedData) return; compressedData.position = 0; const size = out.length; let i = 0; while (i < size) { if (((compressedData.position % blockSize) === 0) && (lastByte < 0)) { // read block header if (compressedData.getBytesAvailable() === 0) break; sample = compressedData.readInt16(); index = compressedData.readUint8(); compressedData.position++; // skip extra header byte if (index > 88) index = 88; out[i++] = sample / 32768; } else { // read 4-bit code and compute delta from previous sample if (lastByte < 0) { if (compressedData.getBytesAvailable() === 0) break; lastByte = compressedData.readUint8(); code = lastByte & 0xF; } else { code = (lastByte >> 4) & 0xF; lastByte = -1; } step = STEP_TABLE[index]; delta = 0; if (code & 4) delta += step; if (code & 2) delta += step >> 1; if (code & 1) delta += step >> 2; delta += step >> 3; // compute next index index += INDEX_TABLE[code]; if (index > 88) index = 88; if (index < 0) index = 0; // compute and output sample sample += (code & 8) ? -delta : delta; if (sample > 32767) sample = 32767; if (sample < -32768) sample = -32768; out[i++] = sample / 32768; } } } } module.exports = ADPCMSoundDecoder;