如何从java中的字节数组中编写WAV文件？

我过去曾经使用过这个来自Wav – > byte []和byte [] – > Wav

package GlobalUtilities; import java.applet.Applet; import java.applet.AudioClip; import java.net.URISyntaxException; import java.util.logging.Level; import java.util.logging.Logger; import java.io.*; import java.io.File; import java.net.MalformedURLException; import java.net.URL; import javax.sound.sampled.*; /** * This class handles the reading, writing, and playing of wav files. It is * also capable of converting the file to its raw byte [] form. * * based on code by Evan Merz modified by Dan Vargo * @author dvargo */ public class Wav { /* WAV File Specification FROM http://ccrma.stanford.edu/courses/422/projects/WaveFormat/ The canonical WAVE format starts with the RIFF header: 0 4 ChunkID Contains the letters "RIFF" in ASCII form (0x52494646 big-endian form). 4 4 ChunkSize 36 + SubChunk2Size, or more precisely: 4 + (8 + SubChunk1Size) + (8 + SubChunk2Size) This is the size of the rest of the chunk following this number. This is the size of the entire file in bytes minus 8 bytes for the two fields not included in this count: ChunkID and ChunkSize. 8 4 Format Contains the letters "WAVE" (0x57415645 big-endian form). The "WAVE" format consists of two subchunks: "fmt " and "data": The "fmt " subchunk describes the sound data's format: 12 4 Subchunk1ID Contains the letters "fmt " (0x666d7420 big-endian form). 16 4 Subchunk1Size 16 for PCM. This is the size of the rest of the Subchunk which follows this number. 20 2 AudioFormat PCM = 1 (ie Linear quantization) Values other than 1 indicate some form of compression. 22 2 NumChannels Mono = 1, Stereo = 2, etc. 24 4 SampleRate 8000, 44100, etc. 28 4 ByteRate == SampleRate * NumChannels * BitsPerSample/8 32 2 BlockAlign == NumChannels * BitsPerSample/8 The number of bytes for one sample including all channels. I wonder what happens when this number isn't an integer? 34 2 BitsPerSample 8 bits = 8, 16 bits = 16, etc. The "data" subchunk contains the size of the data and the actual sound: 36 4 Subchunk2ID Contains the letters "data" (0x64617461 big-endian form). 40 4 Subchunk2Size == NumSamples * NumChannels * BitsPerSample/8 This is the number of bytes in the data. You can also think of this as the size of the read of the subchunk following this number. 44 * Data The actual sound data. The thing that makes reading wav files tricky is that java has no unsigned types. This means that the binary data can't just be read and cast appropriately. Also, we have to use larger types than are normally necessary. In many languages including java, an integer is represented by 4 bytes. The issue here is that in most languages, integers can be signed or unsigned, and in wav files the integers are unsigned. So, to make sure that we can store the proper values, we have to use longs to hold integers, and integers to hold shorts. Then, we have to convert back when we want to save our wav data. It's complicated, but ultimately, it just results in a few extra functions at the bottom of this file. Once you understand the issue, there is no reason to pay any more attention to it. ALSO: This code won't read ALL wav files. This does not use to full specification. It just uses a trimmed down version that most wav files adhere to. */ ByteArrayOutputStream byteArrayOutputStream; AudioFormat audioFormat; TargetDataLine targetDataLine; AudioInputStream audioInputStream; SourceDataLine sourceDataLine; float frequency = 8000.0F; //8000,11025,16000,22050,44100 int samplesize = 16; private String myPath; private long myChunkSize; private long mySubChunk1Size; private int myFormat; private long myChannels; private long mySampleRate; private long myByteRate; private int myBlockAlign; private int myBitsPerSample; private long myDataSize; // I made this public so that you can toss whatever you want in here // maybe a recorded buffer, maybe just whatever you want public byte[] myData; public Wav() { myPath = ""; } // constructor takes a wav path public Wav(String tmpPath) { myPath = tmpPath; } // get/set for the Path property public String getPath() { return myPath; } public void setPath(String newPath) { myPath = newPath; } // read a wav file into this class public boolean read() { DataInputStream inFile = null; myData = null; byte[] tmpLong = new byte[4]; byte[] tmpInt = new byte[2]; try { inFile = new DataInputStream(new FileInputStream(myPath)); //System.out.println("Reading wav file...\n"); // for debugging only String chunkID = "" + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte(); inFile.read(tmpLong); // read the ChunkSize myChunkSize = byteArrayToLong(tmpLong); String format = "" + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte(); // print what we've read so far //System.out.println("chunkID:" + chunkID + " chunk1Size:" + myChunkSize + " format:" + format); // for debugging only String subChunk1ID = "" + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte(); inFile.read(tmpLong); // read the SubChunk1Size mySubChunk1Size = byteArrayToLong(tmpLong); inFile.read(tmpInt); // read the audio format. This should be 1 for PCM myFormat = byteArrayToInt(tmpInt); inFile.read(tmpInt); // read the # of channels (1 or 2) myChannels = byteArrayToInt(tmpInt); inFile.read(tmpLong); // read the samplerate mySampleRate = byteArrayToLong(tmpLong); inFile.read(tmpLong); // read the byterate myByteRate = byteArrayToLong(tmpLong); inFile.read(tmpInt); // read the blockalign myBlockAlign = byteArrayToInt(tmpInt); inFile.read(tmpInt); // read the bitspersample myBitsPerSample = byteArrayToInt(tmpInt); // print what we've read so far //System.out.println("SubChunk1ID:" + subChunk1ID + " SubChunk1Size:" + mySubChunk1Size + " AudioFormat:" + myFormat + " Channels:" + myChannels + " SampleRate:" + mySampleRate); // read the data chunk header - reading this IS necessary, because not all wav files will have the data chunk here - for now, we're just assuming that the data chunk is here String dataChunkID = "" + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte() + (char) inFile.readByte(); inFile.read(tmpLong); // read the size of the data myDataSize = byteArrayToLong(tmpLong); // read the data chunk myData = new byte[(int) myDataSize]; inFile.read(myData); // close the input stream inFile.close(); } catch (Exception e) { return false; } return true; // this should probably be something more descriptive } // write out the wav file public boolean save() { try { DataOutputStream outFile = new DataOutputStream(new FileOutputStream(myPath + "temp")); // write the wav file per the wav file format outFile.writeBytes("RIFF"); // 00 - RIFF outFile.write(intToByteArray((int) myChunkSize), 0, 4); // 04 - how big is the rest of this file? outFile.writeBytes("WAVE"); // 08 - WAVE outFile.writeBytes("fmt "); // 12 - fmt outFile.write(intToByteArray((int) mySubChunk1Size), 0, 4); // 16 - size of this chunk outFile.write(shortToByteArray((short) myFormat), 0, 2); // 20 - what is the audio format? 1 for PCM = Pulse Code Modulation outFile.write(shortToByteArray((short) myChannels), 0, 2); // 22 - mono or stereo? 1 or 2? (or 5 or ???) outFile.write(intToByteArray((int) mySampleRate), 0, 4); // 24 - samples per second (numbers per second) outFile.write(intToByteArray((int) myByteRate), 0, 4); // 28 - bytes per second outFile.write(shortToByteArray((short) myBlockAlign), 0, 2); // 32 - # of bytes in one sample, for all channels outFile.write(shortToByteArray((short) myBitsPerSample), 0, 2); // 34 - how many bits in a sample(number)? usually 16 or 24 outFile.writeBytes("data"); // 36 - data outFile.write(intToByteArray((int) myDataSize), 0, 4); // 40 - how big is this data chunk outFile.write(myData); // 44 - the actual data itself - just a long string of numbers } catch (Exception e) { System.out.println(e.getMessage()); return false; } return true; } // return a printable summary of the wav file public String getSummary() { //String newline = System.getProperty("line.separator"); String newline = " 
 "; String summary = "Format: " + myFormat + newline + "Channels: " + myChannels + newline + "SampleRate: " + mySampleRate + newline + "ByteRate: " + myByteRate + newline + "BlockAlign: " + myBlockAlign + newline + "BitsPerSample: " + myBitsPerSample + newline + "DataSize: " + myDataSize + ""; return summary; } public byte[] getBytes() { read(); return myData; } /** * Plays back audio stored in the byte array using an audio format given by * freq, sample rate, ect. * @param data The byte array to play */ public void playAudio(byte[] data) { try { byte audioData[] = data; //Get an input stream on the byte array containing the data InputStream byteArrayInputStream = new ByteArrayInputStream(audioData); AudioFormat audioFormat = getAudioFormat(); audioInputStream = new AudioInputStream(byteArrayInputStream, audioFormat, audioData.length / audioFormat.getFrameSize()); DataLine.Info dataLineInfo = new DataLine.Info(SourceDataLine.class, audioFormat); sourceDataLine = (SourceDataLine) AudioSystem.getLine(dataLineInfo); sourceDataLine.open(audioFormat); sourceDataLine.start(); //Create a thread to play back the data and start it running. It will run \ //until all the data has been played back. Thread playThread = new Thread(new PlayThread()); playThread.start(); } catch (Exception e) { System.out.println(e); } } /** * This method creates and returns an AudioFormat object for a given set * of format parameters. If these parameters don't work well for * you, try some of the other allowable parameter values, which * are shown in comments following the declarations. * @return */ private AudioFormat getAudioFormat() { float sampleRate = frequency; //8000,11025,16000,22050,44100 int sampleSizeInBits = samplesize; //8,16 int channels = 1; //1,2 boolean signed = true; //true,false boolean bigEndian = false; //true,false //return new AudioFormat( AudioFormat.Encoding.PCM_SIGNED, 8000.0f, 8, 1, 1, //8000.0f, false ); return new AudioFormat(sampleRate, sampleSizeInBits, channels, signed, bigEndian); } public void playWav(String filePath) { try { AudioClip clip = (AudioClip) Applet.newAudioClip(new File(filePath).toURI().toURL()); clip.play(); } catch (Exception e) { Logger.getLogger(Wav.class.getName()).log(Level.SEVERE, null, e); } } // =========================== // CONVERT BYTES TO JAVA TYPES // =========================== // these two routines convert a byte array to a unsigned short public static int byteArrayToInt(byte[] b) { int start = 0; int low = b[start] & 0xff; int high = b[start + 1] & 0xff; return (int) (high > 8) & 0x000000FF); b[2] = (byte) ((i >> 16) & 0x000000FF); b[3] = (byte) ((i >> 24) & 0x000000FF); return b; } // convert a short to a byte array public static byte[] shortToByteArray(short data) { return new byte[]{(byte) (data & 0xff), (byte) ((data >>> 8) & 0xff)}; } /** * Inner class to play back the data that was saved */ class PlayThread extends Thread { byte tempBuffer[] = new byte[10000]; public void run() { try { int cnt; //Keep looping until the input // read method returns -1 for // empty stream. while ((cnt = audioInputStream.read(tempBuffer, 0, tempBuffer.length)) != -1) { if (cnt > 0) { //Write data to the internal // buffer of the data line // where it will be delivered // to the speaker. sourceDataLine.write(tempBuffer, 0, cnt); } } //Block and wait for internal // buffer of the data line to // empty. sourceDataLine.drain(); sourceDataLine.close(); } catch (Exception e) { System.out.println(e); System.exit(0); } } } } 

通过读取字节将文件从InputStream写入OutputStream ：

 File srcFile = new File("c:/src.wav"); File dstFile = new File("c:/dst.wav"); FileInputStream in = new FileInputStream(srcFile); FileOutputStream out = new FileOutputStream(dstFile); byte[] buf = new byte[1024]; int len; while ((len = in.read(buf)) > 0) { out.write(buf, 0, len); } in.close(); out.close(); 

以下是有关拆分wav频道的一些已经回答的问题，可能有用：

1. 如何将Wav文件拆分为java中的通道？
2. java中的wav幅度（立体声或更多声道）