前面这几个文件只是为了能在android使用Base64,直接复制就行。加密解密看最后一个文件就行
import java.io.OutputStream;
import java.io.PushbackInputStream;
/**
* 32 * This class implements a BASE64 Character decoder as specified in RFC1521.
* 33 *
* 34 * This RFC is part of the MIME specification which is published by the
* 35 * Internet Engineering Task Force (IETF). Unlike some other encoding
* 36 * schemes there is nothing in this encoding that tells the decoder
* 37 * where a buffer starts or stops, so to use it you will need to isolate
* 38 * your encoded data into a single chunk and then feed them this decoder.
* 39 * The simplest way to do that is to read all of the encoded data into a
* 40 * string and then use:
* 41 * <pre>
* 42 * byte mydata[];
* 43 * BASE64Decoder base64 = new BASE64Decoder();
* 44 *
* 45 * mydata = base64.decodeBuffer(bufferString);
* 46 * </pre>
* 47 * This will decode the String in <i>bufferString</i> and give you an array
* 48 * of bytes in the array <i>myData</i>.
* 49 *
* 50 * On errors, this class throws a CEFormatException with the following detail
* 51 * strings:
* 52 * <pre>
* 53 * "BASE64Decoder: Not enough bytes for an atom."
* 54 * </pre>
* 55 *
* 56 * @author Chuck McManis
* 57 * @see CharacterEncoder
* 58 * @see BASE64Decoder
* 59
*/
public class BASE64Decoder extends CharacterDecoder {
/**
* This class has 4 bytes per atom
*/
protected int bytesPerAtom() {
return (4);
}
/**
* Any multiple of 4 will do, 72 might be common
*/
protected int bytesPerLine() {
return (72);
}
/**
* 74 * This character array provides the character to value map
* 75 * based on RFC1521.
* 76
*/
private final static char pem_array[] = {
// 0 1 2 3 4 5 6 7
'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', // 0
'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', // 1
'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', // 2
'Y', 'Z', 'a', 'b', 'c', 'd', 'e', 'f', // 3
'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', // 4
'o', 'p', 'q', 'r', 's', 't', 'u', 'v', // 5
'w', 'x', 'y', 'z', '0', '1', '2', '3', // 6
'4', '5', '6', '7', '8', '9', '+', '/' // 7
};
private final static byte pem_convert_array[] = new byte[256];
static {
for (int i = 0; i < 255; i++) {
pem_convert_array[i] = -1;
}
for (int i = 0; i < pem_array.length; i++) {
pem_convert_array[pem_array[i]] = (byte) i;
}
}
byte decode_buffer[] = new byte[4];
protected void decodeAtom(PushbackInputStream inStream, OutputStream outStream, int rem)
throws java.io.IOException {
int i;
byte a = -1, b = -1, c = -1, d = -1;
if (rem < 2) {
throw new CEFormatException("BASE64Decoder: Not enough bytes for an atom.");
}
do {
i = inStream.read();
if (i == -1) {
throw new CEStreamExhausted();
}
} while (i == '\n' || i == '\r');
decode_buffer[0] = (byte) i;
i = readFully(inStream, decode_buffer, 1, rem - 1);
if (i == -1) {
throw new CEStreamExhausted();
}
if (rem > 3 && decode_buffer[3] == '=') {
rem = 3;
}
if (rem > 2 && decode_buffer[2] == '=') {
rem = 2;
}
switch (rem) {
case 4:
d = pem_convert_array[decode_buffer[3] & 0xff];
// NOBREAK
case 3:
c = pem_convert_array[decode_buffer[2] & 0xff];
// NOBREAK
case 2:
b = pem_convert_array[decode_buffer[1] & 0xff];
a = pem_convert_array[decode_buffer[0] & 0xff];
break;
}
switch (rem) {
case 2:
outStream.write((byte) (((a << 2) & 0xfc) | ((b >>> 4) & 3)));
break;
case 3:
outStream.write((byte) (((a << 2) & 0xfc) | ((b >>> 4) & 3)));
outStream.write((byte) (((b << 4) & 0xf0) | ((c >>> 2) & 0xf)));
break;
case 4:
outStream.write((byte) (((a << 2) & 0xfc) | ((b >>> 4) & 3)));
outStream.write((byte) (((b << 4) & 0xf0) | ((c >>> 2) & 0xf)));
outStream.write((byte) (((c << 6) & 0xc0) | (d & 0x3f)));
break;
}
return;
}
}
import java.io.IOException;
import java.io.OutputStream;
/**
* This class implements a BASE64 Character encoder as specified in RFC1521.
* This RFC is part of the MIME specification as published by the Internet
* Engineering Task Force (IETF). Unlike some other encoding schemes there is
* nothing in this encoding that indicates where a buffer starts or ends.
*
* This means that the encoded text will simply start with the first line of
* encoded text and end with the last line of encoded text.
*
* @author Chuck McManis
* @see CharacterEncoder
* @see BASE64Decoder
*/
public class BASE64Encoder extends CharacterEncoder
{
/** this class encodes three bytes per atom. */
protected int bytesPerAtom()
{
return (3);
}
/**
* this class encodes 57 bytes per line. This results in a maximum of 57/3 *
* 4 or 76 characters per output line. Not counting the line termination.
*/
protected int bytesPerLine()
{
return (57);
}
/** This array maps the characters to their 6 bit values */
private final static char pem_array[] =
{
// 0 1 2 3 4 5 6 7
'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', // 0
'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', // 1
'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', // 2
'Y', 'Z', 'a', 'b', 'c', 'd', 'e', 'f', // 3
'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', // 4
'o', 'p', 'q', 'r', 's', 't', 'u', 'v', // 5
'w', 'x', 'y', 'z', '0', '1', '2', '3', // 6
'4', '5', '6', '7', '8', '9', '+', '/' // 7
};
/**
* encodeAtom - Take three bytes of input and encode it as 4 printable
* characters. Note that if the length in len is less than three is encodes
* either one or two '=' signs to indicate padding characters.
*/
protected void encodeAtom(OutputStream outStream, byte data[], int offset,
int len) throws IOException
{
byte a, b, c;
if (len == 1)
{
a = data[offset];
b = 0;
c = 0;
outStream.write(pem_array[(a >>> 2) & 0x3F]);
outStream.write(pem_array[((a << 4) & 0x30) + ((b >>> 4) & 0xf)]);
outStream.write('=');
outStream.write('=');
} else if (len == 2)
{
a = data[offset];
b = data[offset + 1];
c = 0;
outStream.write(pem_array[(a >>> 2) & 0x3F]);
outStream.write(pem_array[((a << 4) & 0x30) + ((b >>> 4) & 0xf)]);
outStream.write(pem_array[((b << 2) & 0x3c) + ((c >>> 6) & 0x3)]);
outStream.write('=');
} else
{
a = data[offset];
b = data[offset + 1];
c = data[offset + 2];
outStream.write(pem_array[(a >>> 2) & 0x3F]);
outStream.write(pem_array[((a << 4) & 0x30) + ((b >>> 4) & 0xf)]);
outStream.write(pem_array[((b << 2) & 0x3c) + ((c >>> 6) & 0x3)]);
outStream.write(pem_array[c & 0x3F]);
}
}
}
import java.io.IOException;
public class CEFormatException extends IOException
{
public CEFormatException(String s)
{
super(s);
}
}
import java.io.ByteArrayInputStream;
import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.io.PushbackInputStream;
import java.nio.ByteBuffer;
/**
* 37 * This class defines the decoding half of character encoders. 38 * A
* character decoder is an algorithim for transforming 8 bit 39 * binary data
* that has been encoded into text by a character 40 * encoder, back into
* original binary form. 41 * 42 * The character encoders, in general, have been
* structured 43 * around a central theme that binary data can be encoded into
* 44 * text that has the form: 45 * 46 *
*
* <pre>
* 47 * [Buffer Prefix]
* 48 * [Line Prefix][encoded data atoms][Line Suffix]
* 49 * [Buffer Suffix]
* 50 *
* </pre>
*
* 51 * 52 * Of course in the simplest encoding schemes, the buffer has no 53 *
* distinct prefix of suffix, however all have some fixed relationship 54 *
* between the text in an 'atom' and the binary data itself. 55 * 56 * In the
* CharacterEncoder and CharacterDecoder classes, one complete 57 * chunk of
* data is referred to as a <i>buffer</i>. Encoded buffers 58 * are all text,
* and decoded buffers (sometimes just referred to as 59 * buffers) are binary
* octets. 60 * 61 * To create a custom decoder, you must, at a minimum, overide
* three 62 * abstract methods in this class. 63 *
* <DL>
* 64 *
* <DD>bytesPerAtom which tells the decoder how many bytes to 65 * expect from
* decodeAtom 66 *
* <DD>decodeAtom which decodes the bytes sent to it as text. 67 *
* <DD>bytesPerLine which tells the encoder the maximum number of 68 * bytes per
* line. 69 *
* </DL>
* 70 * 71 * In general, the character decoders return error in the form of a 72
* * CEFormatException. The syntax of the detail string is 73 *
*
* <pre>
* 74 * DecoderClassName: Error message.
* 75 *
* </pre>
*
* 76 * 77 * Several useful decoders have already been written and are 78 *
* referenced in the See Also list below. 79 * 80 * @author Chuck McManis 81 * @see
* CEFormatException 82 * @see CharacterEncoder 83 * @see UCDecoder 84 * @see
* UUDecoder 85 * @see BASE64Decoder 86
*/
public abstract class CharacterDecoder
{
/** Return the number of bytes per atom of decoding */
abstract protected int bytesPerAtom();
/** Return the maximum number of bytes that can be encoded per line */
abstract protected int bytesPerLine();
/** decode the beginning of the buffer, by default this is a NOP. */
protected void decodeBufferPrefix(PushbackInputStream aStream,
OutputStream bStream) throws IOException
{
}
/** decode the buffer suffix, again by default it is a NOP. */
protected void decodeBufferSuffix(PushbackInputStream aStream,
OutputStream bStream) throws IOException
{
}
/**
* 103 * This method should return, if it knows, the number of bytes 104 *
* that will be decoded. Many formats such as uuencoding provide 105 * this
* information. By default we return the maximum bytes that 106 * could have
* been encoded on the line. 107
*/
protected int decodeLinePrefix(PushbackInputStream aStream,
OutputStream bStream) throws IOException
{
return (bytesPerLine());
}
/**
* 113 * This method post processes the line, if there are error detection
* 114 * or correction codes in a line, they are generally processed by 115
* * this method. The simplest version of this method looks for the 116 *
* (newline) character. 117
*/
protected void decodeLineSuffix(PushbackInputStream aStream,
OutputStream bStream) throws IOException
{
}
/**
* 121 * This method does an actual decode. It takes the decoded bytes and
* 122 * writes them to the OutputStream. The integer <i>l</i> tells the 123
* * method how many bytes are required. This is always <= bytesPerAtom().
* 124
*/
protected void decodeAtom(PushbackInputStream aStream,
OutputStream bStream, int l) throws IOException
{
throw new CEStreamExhausted();
}
/**
* 130 * This method works around the bizarre semantics of
* BufferedInputStream's 131 * read method. 132
*/
protected int readFully(InputStream in, byte buffer[], int offset, int len)
throws IOException
{
for (int i = 0; i < len; i++)
{
int q = in.read();
if (q == -1)
return ((i == 0) ? -1 : i);
buffer[i + offset] = (byte) q;
}
return len;
}
/**
* 145 * Decode the text from the InputStream and write the decoded 146 *
* octets to the OutputStream. This method runs until the stream 147 * is
* exhausted. 148 * @exception CEFormatException An error has occured while
* decoding 149 * @exception CEStreamExhausted The input stream is
* unexpectedly out of data 150
*/
public void decodeBuffer(InputStream aStream, OutputStream bStream)
throws IOException
{
int i;
int totalBytes = 0;
PushbackInputStream ps = new PushbackInputStream(aStream);
decodeBufferPrefix(ps, bStream);
while (true)
{
int length;
try
{
length = decodeLinePrefix(ps, bStream);
for (i = 0; (i + bytesPerAtom()) < length; i += bytesPerAtom())
{
decodeAtom(ps, bStream, bytesPerAtom());
totalBytes += bytesPerAtom();
}
if ((i + bytesPerAtom()) == length)
{
decodeAtom(ps, bStream, bytesPerAtom());
totalBytes += bytesPerAtom();
} else
{
decodeAtom(ps, bStream, length - i);
totalBytes += (length - i);
}
decodeLineSuffix(ps, bStream);
} catch (CEStreamExhausted e)
{
break;
}
}
decodeBufferSuffix(ps, bStream);
}
/**
* 182 * Alternate decode interface that takes a String containing the
* encoded 183 * buffer and returns a byte array containing the data. 184 * @exception
* CEFormatException An error has occured while decoding 185
*/
public byte decodeBuffer(String inputString)[] throws IOException
{
byte inputBuffer[] = new byte[inputString.length()];
ByteArrayInputStream inStream;
ByteArrayOutputStream outStream;
inputString.getBytes(0, inputString.length(), inputBuffer, 0);
inStream = new ByteArrayInputStream(inputBuffer);
outStream = new ByteArrayOutputStream();
decodeBuffer(inStream, outStream);
return (outStream.toByteArray());
}
/**
* 199 * Decode the contents of the inputstream into a buffer. 200
*/
public byte decodeBuffer(InputStream in)[] throws IOException
{
ByteArrayOutputStream outStream = new ByteArrayOutputStream();
decodeBuffer(in, outStream);
return (outStream.toByteArray());
}
/**
* 208 * Decode the contents of the String into a ByteBuffer. 209
*/
public ByteBuffer decodeBufferToByteBuffer(String inputString)
throws IOException
{
return ByteBuffer.wrap(decodeBuffer(inputString));
}
/**
* 216 * Decode the contents of the inputStream into a ByteBuffer. 217
*/
public ByteBuffer decodeBufferToByteBuffer(InputStream in)
throws IOException
{
return ByteBuffer.wrap(decodeBuffer(in));
}
}
import java.io.ByteArrayInputStream;
import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.io.PrintStream;
import java.nio.ByteBuffer;
/**
* 38 * This class defines the encoding half of character encoders. 39 * A
* character encoder is an algorithim for transforming 8 bit binary 40 * data
* into text (generally 7 bit ASCII or 8 bit ISO-Latin-1 text) 41 * for
* transmition over text channels such as e-mail and network news. 42 * 43 * The
* character encoders have been structured around a central theme 44 * that, in
* general, the encoded text has the form: 45 * 46 *
*
* <pre>
* 47 * [Buffer Prefix]
* 48 * [Line Prefix][encoded data atoms][Line Suffix]
* 49 * [Buffer Suffix]
* 50 *
* </pre>
*
* 51 * 52 * In the CharacterEncoder and CharacterDecoder classes, one complete
* 53 * chunk of data is referred to as a <i>buffer</i>. Encoded buffers 54 *
* are all text, and decoded buffers (sometimes just referred to as 55 *
* buffers) are binary octets. 56 * 57 * To create a custom encoder, you must,
* at a minimum, overide three 58 * abstract methods in this class. 59 *
* <DL>
* 60 *
* <DD>bytesPerAtom which tells the encoder how many bytes to 61 * send to
* encodeAtom 62 *
* <DD>encodeAtom which encodes the bytes sent to it as text. 63 *
* <DD>bytesPerLine which tells the encoder the maximum number of 64 * bytes per
* line. 65 *
* </DL>
* 66 * 67 * Several useful encoders have already been written and are 68 *
* referenced in the See Also list below. 69 * 70 * @author Chuck McManis 71 * @see
* CharacterDecoder; 72 * @see UCEncoder 73 * @see UUEncoder 74 * @see
* BASE64Encoder 75
*/
public abstract class CharacterEncoder
{
/** Stream that understands "printing" */
protected PrintStream pStream;
/** Return the number of bytes per atom of encoding */
abstract protected int bytesPerAtom();
/** Return the number of bytes that can be encoded per line */
abstract protected int bytesPerLine();
/**
* 88 * Encode the prefix for the entire buffer. By default is simply 89 *
* opens the PrintStream for use by the other functions. 90
*/
protected void encodeBufferPrefix(OutputStream aStream) throws IOException
{
pStream = new PrintStream(aStream);
}
/**
* 96 * Encode the suffix for the entire buffer. 97
*/
protected void encodeBufferSuffix(OutputStream aStream) throws IOException
{
}
/**
* 102 * Encode the prefix that starts every output line. 103
*/
protected void encodeLinePrefix(OutputStream aStream, int aLength)
throws IOException
{
}
/**
* 109 * Encode the suffix that ends every output line. By default 110 *
* this method just prints a <newline> into the output stream. 111
*/
protected void encodeLineSuffix(OutputStream aStream) throws IOException
{
pStream.println();
}
/** Encode one "atom" of information into characters. */
abstract protected void encodeAtom(OutputStream aStream, byte someBytes[],
int anOffset, int aLength) throws IOException;
/**
* 121 * This method works around the bizarre semantics of
* BufferedInputStream's 122 * read method. 123
*/
protected int readFully(InputStream in, byte buffer[])
throws IOException
{
for (int i = 0; i < buffer.length; i++)
{
int q = in.read();
if (q == -1)
return i;
buffer[i] = (byte) q;
}
return buffer.length;
}
/**
* 136 * Encode bytes from the input stream, and write them as text
* characters 137 * to the output stream. This method will run until it
* exhausts the 138 * input stream, but does not print the line suffix for a
* final 139 * line that is shorter than bytesPerLine(). 140
*/
public void encode(InputStream inStream, OutputStream outStream)
throws IOException
{
int j;
int numBytes;
byte tmpbuffer[] = new byte[bytesPerLine()];
encodeBufferPrefix(outStream);
while (true)
{
numBytes = readFully(inStream, tmpbuffer);
if (numBytes == 0)
{
break;
}
encodeLinePrefix(outStream, numBytes);
for (j = 0; j < numBytes; j += bytesPerAtom())
{
if ((j + bytesPerAtom()) <= numBytes)
{
encodeAtom(outStream, tmpbuffer, j, bytesPerAtom());
} else
{
encodeAtom(outStream, tmpbuffer, j, (numBytes) - j);
}
}
if (numBytes < bytesPerLine())
{
break;
} else
{
encodeLineSuffix(outStream);
}
}
encodeBufferSuffix(outStream);
}
/**
* 173 * Encode the buffer in <i>aBuffer</i> and write the encoded 174 *
* result to the OutputStream <i>aStream</i>. 175
*/
public void encode(byte aBuffer[], OutputStream aStream) throws IOException
{
ByteArrayInputStream inStream = new ByteArrayInputStream(aBuffer);
encode(inStream, aStream);
}
/**
* 183 * A 'streamless' version of encode that simply takes a buffer of 184
* * bytes and returns a string containing the encoded buffer. 185
*/
public String encode(byte aBuffer[])
{
ByteArrayOutputStream outStream = new ByteArrayOutputStream();
ByteArrayInputStream inStream = new ByteArrayInputStream(aBuffer);
String retVal = null;
try
{
encode(inStream, outStream);
// explicit ascii->unicode conversion
retVal = outStream.toString("8859_1");
} catch (Exception IOException)
{
// This should never happen.
throw new Error("CharacterEncoder.encode internal error");
}
return (retVal);
}
/**
* 202 * Return a byte array from the remaining bytes in this ByteBuffer.
* 203 *
* <P>
* 204 * The ByteBuffer's position will be advanced to ByteBuffer's limit.
* 205 *
* <P>
* 206 * To avoid an extra copy, the implementation will attempt to return
* the 207 * byte array backing the ByteBuffer. If this is not possible, a
* 208 * new byte array will be created. 209
*/
private byte[] getBytes(ByteBuffer bb)
{
/*
* This should never return a BufferOverflowException, as we're 213 *
* careful to allocate just the right amount. 214
*/
byte[] buf = null;
/*
* 218 * If it has a usable backing byte buffer, use it. Use only 219 *
* if the array exactly represents the current ByteBuffer. 220
*/
if (bb.hasArray())
{
byte[] tmp = bb.array();
if ((tmp.length == bb.capacity()) && (tmp.length == bb.remaining()))
{
buf = tmp;
bb.position(bb.limit());
}
}
if (buf == null)
{
/*
* 232 * This class doesn't have a concept of encode(buf, len, off),
* 233 * so if we have a partial buffer, we must reallocate 234 *
* space. 235
*/
buf = new byte[bb.remaining()];
/*
* 239 * position() automatically updated 240
*/
bb.get(buf);
}
return buf;
}
/**
* 248 * Encode the <i>aBuffer</i> ByteBuffer and write the encoded 249 *
* result to the OutputStream <i>aStream</i>. 250 *
* <P>
* 251 * The ByteBuffer's position will be advanced to ByteBuffer's limit.
* 252
*/
public void encode(ByteBuffer aBuffer, OutputStream aStream)
throws IOException
{
byte[] buf = getBytes(aBuffer);
encode(buf, aStream);
}
/**
* 260 * A 'streamless' version of encode that simply takes a ByteBuffer 261
* * and returns a string containing the encoded buffer. 262 *
* <P>
* 263 * The ByteBuffer's position will be advanced to ByteBuffer's limit.
* 264
*/
public String encode(ByteBuffer aBuffer)
{
byte[] buf = getBytes(aBuffer);
return encode(buf);
}
/**
* 271 * Encode bytes from the input stream, and write them as text
* characters 272 * to the output stream. This method will run until it
* exhausts the 273 * input stream. It differs from encode in that it will
* add the 274 * line at the end of a final line that is shorter than
* bytesPerLine(). 275
*/
public void encodeBuffer(InputStream inStream, OutputStream outStream)
throws IOException
{
int j;
int numBytes;
byte tmpbuffer[] = new byte[bytesPerLine()];
encodeBufferPrefix(outStream);
while (true)
{
numBytes = readFully(inStream, tmpbuffer);
if (numBytes == 0)
{
break;
}
encodeLinePrefix(outStream, numBytes);
for (j = 0; j < numBytes; j += bytesPerAtom())
{
if ((j + bytesPerAtom()) <= numBytes)
{
encodeAtom(outStream, tmpbuffer, j, bytesPerAtom());
} else
{
encodeAtom(outStream, tmpbuffer, j, (numBytes) - j);
}
}
encodeLineSuffix(outStream);
if (numBytes < bytesPerLine())
{
break;
}
}
encodeBufferSuffix(outStream);
}
/**
* 306 * Encode the buffer in <i>aBuffer</i> and write the encoded 307 *
* result to the OutputStream <i>aStream</i>. 308
*/
public void encodeBuffer(byte aBuffer[], OutputStream aStream)
throws IOException
{
ByteArrayInputStream inStream = new ByteArrayInputStream(aBuffer);
encodeBuffer(inStream, aStream);
}
/**
* 316 * A 'streamless' version of encode that simply takes a buffer of 317
* * bytes and returns a string containing the encoded buffer. 318
*/
public String encodeBuffer(byte aBuffer[])
{
ByteArrayOutputStream outStream = new ByteArrayOutputStream();
ByteArrayInputStream inStream = new ByteArrayInputStream(aBuffer);
try
{
encodeBuffer(inStream, outStream);
} catch (Exception IOException)
{
// This should never happen.
throw new Error("CharacterEncoder.encodeBuffer internal error");
}
return (outStream.toString());
}
/**
* 332 * Encode the <i>aBuffer</i> ByteBuffer and write the encoded 333 *
* result to the OutputStream <i>aStream</i>. 334 *
* <P>
* 335 * The ByteBuffer's position will be advanced to ByteBuffer's limit.
* 336
*/
public void encodeBuffer(ByteBuffer aBuffer, OutputStream aStream)
throws IOException
{
byte[] buf = getBytes(aBuffer);
encodeBuffer(buf, aStream);
}
/**
* 344 * A 'streamless' version of encode that simply takes a ByteBuffer 345
* * and returns a string containing the encoded buffer. 346 *
* <P>
* 347 * The ByteBuffer's position will be advanced to ByteBuffer's limit.
* 348
*/
public String encodeBuffer(ByteBuffer aBuffer)
{
byte[] buf = getBytes(aBuffer);
return encodeBuffer(buf);
}
}
android没办法直接使用Base64(不知道现在能不能),所以才需要上面几个文件,这些文件统一放在一个文件夹就是。
import javax.crypto.Cipher;
import javax.crypto.spec.IvParameterSpec;
import javax.crypto.spec.SecretKeySpec;
/**
* Created by admin on 2016/11/11.
*/
public class AESOperator {
/*
* 加密用的Key 可以用26个字母和数字组成 此处使用AES-128-CBC加密模式,key需要为16位。
*/
private String sKey = "";
private String ivParameter = "";
private static AESOperator instance = null;
private AESOperator() {
}
public static AESOperator getInstance() {
if (instance == null)
instance = new AESOperator();
return instance;
}
/**
* 带key和向量的加密
*
* @param encData 要加密的字符串
* @param secretKey 自定义的key
* @param vector 自定义的向量
* @return
*/
public static String Encrypt(String encData, String secretKey, String vector) throws Exception {
if (secretKey == null) {
return null;
}
if (secretKey.length() != 16) {
return null;
}
Cipher cipher = Cipher.getInstance("AES/CBC/PKCS5Padding");
byte[] raw = secretKey.getBytes();
SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
IvParameterSpec iv = new IvParameterSpec(vector.getBytes());// 使用CBC模式,需要一个向量iv,可增加加密算法的强度
cipher.init(Cipher.ENCRYPT_MODE, skeySpec, iv);
byte[] encrypted = cipher.doFinal(encData.getBytes("utf-8"));
return new BASE64Encoder().encode(encrypted).trim();// 此处使用BASE64做转码。
}
// 直接加密
public String encrypt(String sSrc) throws Exception {
Cipher cipher = Cipher.getInstance("AES/CBC/PKCS5Padding");
byte[] raw = sKey.getBytes();
SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
IvParameterSpec iv = new IvParameterSpec(ivParameter.getBytes());// 使用CBC模式,需要一个向量iv,可增加加密算法的强度
cipher.init(Cipher.ENCRYPT_MODE, skeySpec, iv);
byte[] encrypted = cipher.doFinal(sSrc.getBytes("utf-8"));
return new BASE64Encoder().encode(encrypted);// 此处使用BASE64做转码。
}
// 直接解密
public String decrypt(String sSrc) throws Exception {
try {
byte[] raw = sKey.getBytes("ASCII");
SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
Cipher cipher = Cipher.getInstance("AES/CBC/PKCS5Padding");
IvParameterSpec iv = new IvParameterSpec(ivParameter.getBytes());
cipher.init(Cipher.DECRYPT_MODE, skeySpec, iv);
byte[] encrypted1 = new BASE64Decoder().decodeBuffer(sSrc);// 先用base64解密
byte[] original = cipher.doFinal(encrypted1);
String originalString = new String(original, "utf-8");
return originalString;
} catch (Exception ex) {
return null;
}
}
/**
* 带key和向量的解密("ASCII"格式的)
* @param sSrc 要解密的字符串
* @param key 加密时用的密钥
* @param ivs 加密时用的向量
* @return
*/
public static String decrypt(String sSrc, String key, String ivs) throws Exception {
try {
byte[] raw = key.getBytes("ASCII");
SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
Cipher cipher = Cipher.getInstance("AES/CBC/PKCS5Padding");
IvParameterSpec iv = new IvParameterSpec(ivs.getBytes());
cipher.init(Cipher.DECRYPT_MODE, skeySpec, iv);
byte[] encrypted1 = new BASE64Decoder().decodeBuffer(sSrc);// 先用base64解密
byte[] original = cipher.doFinal(encrypted1);
String originalString = new String(original, "utf-8");
return originalString;
} catch (Exception ex) {
return null;
}
}
/**
* 带key和向量的解密,和上面一样,只不过这是"utf-8"格式的
* @param sSrc 要解密的字符串
* @param key
* @param ivs
* @return
*/
public static String decrypt7(String sSrc, String key, String ivs) throws Exception {
try {
byte[] raw = key.getBytes("utf-8");
SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
Cipher cipher = Cipher.getInstance("AES/CBC/PKCS7Padding");
IvParameterSpec iv = new IvParameterSpec(ivs.getBytes("utf-8"));
cipher.init(Cipher.DECRYPT_MODE, skeySpec, iv);
byte[] encrypted1 = hexStringToBytes(sSrc);// 先用base64解密
byte[] original = cipher.doFinal(encrypted1);
String originalString = new String(original, "utf-8");
return originalString;
} catch (Exception ex) {
return null;
}
}
public static void main(String[] args) throws Exception {
// 需要加密的字串
String cSrc = "[{\"request_no\":\"1001\",\"service_code\":\"FS0001\",\"contract_id\":\"100002\",\"order_id\":\"0\",\"phone_id\":\"13913996922\",\"plat_offer_id\":\"100094\",\"channel_id\":\"1\",\"activity_id\":\"100045\"}]";
// 加密
long lStart = System.currentTimeMillis();
String enString = AESOperator.getInstance().encrypt(cSrc);
System.out.println("加密后的字串是:" + enString);
long lUseTime = System.currentTimeMillis() - lStart;
System.out.println("加密耗时:" + lUseTime + "毫秒");
// 解密
lStart = System.currentTimeMillis();
String DeString = AESOperator.getInstance().decrypt(enString);
System.out.println("解密后的字串是:" + DeString);
lUseTime = System.currentTimeMillis() - lStart;
System.out.println("解密耗时:" + lUseTime + "毫秒");
}
// byte转String
public static String bytesToHexString(byte[] src) {
StringBuilder stringBuilder = new StringBuilder("");
if (src == null || src.length <= 0) {
return null;
}
for (int i = 0; i < src.length; i++) {
int v = src[i] & 0xFF;
String hv = Integer.toHexString(v);
if (hv.length() < 2) {
stringBuilder.append(0);
}
stringBuilder.append(hv);
}
return stringBuilder.toString();
}
/**
* String转byte
* Convert hex string to byte[]
* @param hexString the hex string
* @return byte[]
*/
public static byte[] hexStringToBytes(String hexString) {
if (hexString == null || hexString.equals("")) {
return null;
}
hexString = hexString.toUpperCase();
int length = hexString.length() / 2;
char[] hexChars = hexString.toCharArray();
byte[] d = new byte[length];
for (int i = 0; i < length; i++) {
int pos = i * 2;
d[i] = (byte) (charToByte(hexChars[pos]) << 4 | charToByte(hexChars[pos + 1]));
}
return d;
}
/**
* Convert char to byte
* @param c char
* @return byte
*/
private static byte charToByte(char c) {
return (byte) "0123456789ABCDEF".indexOf(c);
}
}
