public static WavFile newWavFile( File file, int numChannels, long numFrames, int validBits, long sampleRate) throws IOException, WavFileException { // Instantiate new Wavfile and initialise final WavFile wavFile = new WavFile(); wavFile.file = file; wavFile.numChannels = numChannels; wavFile.numFrames = numFrames; wavFile.sampleRate = sampleRate; wavFile.bytesPerSample = (validBits + 7) / 8; wavFile.blockAlign = wavFile.bytesPerSample * numChannels; wavFile.validBits = validBits; // Sanity check arguments if ((numChannels < 1) || (numChannels > 65535)) { throw new WavFileException("Illegal number of channels, valid range 1 to 65536"); } if (numFrames < 0) { throw new WavFileException("Number of frames must be positive"); } if ((validBits < 2) || (validBits > 65535)) { throw new WavFileException("Illegal number of valid bits, valid range 2 to 65536"); } if (sampleRate < 0) { throw new WavFileException("Sample rate must be positive"); } // Create output stream for writing data wavFile.oStream = new FileOutputStream(file); // Calculate the chunk sizes final long dataChunkSize = wavFile.blockAlign * numFrames; long mainChunkSize = 4 + // Riff Type 8 + // Format ID and size 16 + // Format data 8 + // Data ID and size dataChunkSize; // Chunks must be word aligned, so if odd number of audio data bytes // adjust the main chunk size if ((dataChunkSize % 2) == 1) { mainChunkSize += 1; wavFile.wordAlignAdjust = true; } else { wavFile.wordAlignAdjust = false; } // Set the main chunk size putLE(RIFF_CHUNK_ID, wavFile.buffer, 0, 4); putLE(mainChunkSize, wavFile.buffer, 4, 4); putLE(RIFF_TYPE_ID, wavFile.buffer, 8, 4); // Write out the header wavFile.oStream.write(wavFile.buffer, 0, 12); // Put format data in buffer final long averageBytesPerSecond = sampleRate * wavFile.blockAlign; putLE(FMT_CHUNK_ID, wavFile.buffer, 0, 4); // Chunk ID putLE(16, wavFile.buffer, 4, 4); // Chunk Data Size putLE(1, wavFile.buffer, 8, 2); // Compression Code (Uncompressed) putLE(numChannels, wavFile.buffer, 10, 2); // Number of channels putLE(sampleRate, wavFile.buffer, 12, 4); // Sample Rate putLE(averageBytesPerSecond, wavFile.buffer, 16, 4); // Average Bytes Per Second putLE(wavFile.blockAlign, wavFile.buffer, 20, 2); // Block Align putLE(validBits, wavFile.buffer, 22, 2); // Valid Bits // Write Format Chunk wavFile.oStream.write(wavFile.buffer, 0, 24); // Start Data Chunk putLE(DATA_CHUNK_ID, wavFile.buffer, 0, 4); // Chunk ID putLE(dataChunkSize, wavFile.buffer, 4, 4); // Chunk Data Size // Write Format Chunk wavFile.oStream.write(wavFile.buffer, 0, 8); // Calculate the scaling factor for converting to a normalised double if (wavFile.validBits > 8) { // If more than 8 validBits, data is signed // Conversion required multiplying by magnitude of max positive value wavFile.floatOffset = 0; wavFile.floatScale = Long.MAX_VALUE >> (64 - wavFile.validBits); } else { // Else if 8 or less validBits, data is unsigned // Conversion required dividing by max positive value wavFile.floatOffset = 1; wavFile.floatScale = 0.5 * ((1 << wavFile.validBits) - 1); } // Finally, set the IO State wavFile.bufferPointer = 0; wavFile.bytesRead = 0; wavFile.frameCounter = 0; wavFile.ioState = IOState.WRITING; return wavFile; }
public static WavFile openWavFile(File file) throws IOException, WavFileException { // Instantiate new Wavfile and store the file reference final WavFile wavFile = new WavFile(); wavFile.file = file; // Create a new file input stream for reading file data wavFile.iStream = new FileInputStream(file); // Read the first 12 bytes of the file int bytesRead = wavFile.iStream.read(wavFile.buffer, 0, 12); if (bytesRead != 12) { throw new WavFileException("Not enough wav file bytes for header"); } // Extract parts from the header final long riffChunkID = getLE(wavFile.buffer, 0, 4); long chunkSize = getLE(wavFile.buffer, 4, 4); final long riffTypeID = getLE(wavFile.buffer, 8, 4); // Check the header bytes contains the correct signature if (riffChunkID != RIFF_CHUNK_ID) { throw new WavFileException("Invalid Wav Header data, incorrect riff chunk ID"); } if (riffTypeID != RIFF_TYPE_ID) { throw new WavFileException("Invalid Wav Header data, incorrect riff type ID"); } // Check that the file size matches the number of bytes listed in header if (file.length() != (chunkSize + 8)) { throw new WavFileException( "Header chunk size (" + chunkSize + ") does not match file size (" + file.length() + ")"); } boolean foundFormat = false; boolean foundData = false; // Search for the Format and Data Chunks while (true) { // Read the first 8 bytes of the chunk (ID and chunk size) bytesRead = wavFile.iStream.read(wavFile.buffer, 0, 8); if (bytesRead == -1) { throw new WavFileException("Reached end of file without finding format chunk"); } if (bytesRead != 8) { throw new WavFileException("Could not read chunk header"); } // Extract the chunk ID and Size final long chunkID = getLE(wavFile.buffer, 0, 4); chunkSize = getLE(wavFile.buffer, 4, 4); // Word align the chunk size // chunkSize specifies the number of bytes holding data. However, // the data should be word aligned (2 bytes) so we need to calculate // the actual number of bytes in the chunk long numChunkBytes = ((chunkSize % 2) == 1) ? chunkSize + 1 : chunkSize; if (chunkID == FMT_CHUNK_ID) { // Flag that the format chunk has been found foundFormat = true; // Read in the header info bytesRead = wavFile.iStream.read(wavFile.buffer, 0, 16); // Check this is uncompressed data final int compressionCode = (int) getLE(wavFile.buffer, 0, 2); if (compressionCode != 1) { throw new WavFileException("Compression Code " + compressionCode + " not supported"); } // Extract the format information wavFile.numChannels = (int) getLE(wavFile.buffer, 2, 2); wavFile.sampleRate = getLE(wavFile.buffer, 4, 4); wavFile.blockAlign = (int) getLE(wavFile.buffer, 12, 2); wavFile.validBits = (int) getLE(wavFile.buffer, 14, 2); if (wavFile.numChannels == 0) { throw new WavFileException("Number of channels specified in header is equal to zero"); } if (wavFile.blockAlign == 0) { throw new WavFileException("Block Align specified in header is equal to zero"); } if (wavFile.validBits < 2) { throw new WavFileException("Valid Bits specified in header is less than 2"); } if (wavFile.validBits > 64) { throw new WavFileException( "Valid Bits specified in header is greater than 64, this is greater than a long can hold"); } // Calculate the number of bytes required to hold 1 sample wavFile.bytesPerSample = (wavFile.validBits + 7) / 8; if ((wavFile.bytesPerSample * wavFile.numChannels) != wavFile.blockAlign) { throw new WavFileException( "Block Align does not agree with bytes required for validBits and number of channels"); } // Account for number of format bytes and then skip over // any extra format bytes numChunkBytes -= 16; if (numChunkBytes > 0) { wavFile.iStream.skip(numChunkBytes); } } else if (chunkID == DATA_CHUNK_ID) { // Check if we've found the format chunk, // If not, throw an exception as we need the format information // before we can read the data chunk if (foundFormat == false) { throw new WavFileException("Data chunk found before Format chunk"); } // Check that the chunkSize (wav data length) is a multiple of the // block align (bytes per frame) if ((chunkSize % wavFile.blockAlign) != 0) { throw new WavFileException("Data Chunk size is not multiple of Block Align"); } // Calculate the number of frames wavFile.numFrames = chunkSize / wavFile.blockAlign; // Flag that we've found the wave data chunk foundData = true; break; } else { // If an unknown chunk ID is found, just skip over the chunk data wavFile.iStream.skip(numChunkBytes); } } // Throw an exception if no data chunk has been found if (foundData == false) { throw new WavFileException("Did not find a data chunk"); } // Calculate the scaling factor for converting to a normalised double if (wavFile.validBits > 8) { // If more than 8 validBits, data is signed // Conversion required dividing by magnitude of max negative value wavFile.floatOffset = 0; wavFile.floatScale = 1 << (wavFile.validBits - 1); } else { // Else if 8 or less validBits, data is unsigned // Conversion required dividing by max positive value wavFile.floatOffset = -1; wavFile.floatScale = 0.5 * ((1 << wavFile.validBits) - 1); } wavFile.bufferPointer = 0; wavFile.bytesRead = 0; wavFile.frameCounter = 0; wavFile.ioState = IOState.READING; return wavFile; }