* N.B. The next major release may break compatibility and make this field * private. *
*/ static final byte[] CHUNK_SEPARATOR = { '\r', '\n' }; /** * This array is a lookup table that translates 6-bit positive integer index * values into their "Base64 Alphabet" equivalents as specified in Table 1 * of RFC 2045. */ private static final byte[] STANDARD_ENCODE_TABLE = { 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z', 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's', 't', 'u', 'v', 'w', 'x', 'y', 'z', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', '+', '/' }; /** * This is a copy of the STANDARD_ENCODE_TABLE above, but with + and / * changed to - and _ to make the encoded Base64 results more URL-SAFE. This * table is only used when the Base64's mode is set to URL-SAFE. */ private static final byte[] URL_SAFE_ENCODE_TABLE = { 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H', 'I', 'J', 'K', 'L', 'M', 'N', 'O', 'P', 'Q', 'R', 'S', 'T', 'U', 'V', 'W', 'X', 'Y', 'Z', 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's', 't', 'u', 'v', 'w', 'x', 'y', 'z', '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', '-', '_' }; /** * This array is a lookup table that translates Unicode characters drawn * from the "Base64 Alphabet" (as specified in Table 1 of RFC 2045) into * their 6-bit positive integer equivalents. Characters that are not in the * Base64 alphabet but fall within the bounds of the array are translated to * -1. * * Note: '+' and '-' both decode to 62. '/' and '_' both decode to 63. This * means decoder seamlessly handles both URL_SAFE and STANDARD base64. (The * encoder, on the other hand, needs to know ahead of time what to emit). * */ private static final byte[] DECODE_TABLE = { -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, 62, -1, 62, -1, 63, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, -1, -1, -1, -1, -1, -1, -1, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, -1, -1, -1, -1, 63, -1, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51 }; /** * Base64 uses 6-bit fields. */ /** Mask used to extract 6 bits, used when encoding */ private static final int MASK_6BITS = 0x3f; // The static final fields above are used for the original static byte[] // methods on Base64. // The private member fields below are used with the new streaming approach, // which requires // some state be preserved between calls of encode() and decode(). /** * Encode table to use: either STANDARD or URL_SAFE. Note: the DECODE_TABLE * above remains static because it is able to decode both STANDARD and * URL_SAFE streams, but the encodeTable must be a member variable so we can * switch between the two modes. */ private final byte[] encodeTable; // Only one decode table currently; keep for consistency with Base32 code private final byte[] decodeTable = DECODE_TABLE; /** * Line separator for encoding. Not used when decoding. Only used if * lineLength > 0. */ private final byte[] lineSeparator; /** * Convenience variable to help us determine when our buffer is going to run * out of room and needs resizing. *decodeSize = 3 + lineSeparator.length;
*/
private final int decodeSize;
/**
* Convenience variable to help us determine when our buffer is going to run
* out of room and needs resizing.
* encodeSize = 4 + lineSeparator.length;
*/
private final int encodeSize;
/**
* Creates a Base64 codec used for decoding (all modes) and encoding in
* URL-unsafe mode.
* * When encoding the line length is 0 (no chunking), and the encoding table * is STANDARD_ENCODE_TABLE. *
* ** When decoding all variants are supported. *
*/ public Base64() { this(0); } /** * Creates a Base64 codec used for decoding (all modes) and encoding in the * given URL-safe mode. ** When encoding the line length is 76, the line separator is CRLF, and the * encoding table is STANDARD_ENCODE_TABLE. *
* ** When decoding all variants are supported. *
* * @param urlSafe * if {@code true}, URL-safe encoding is used. In most cases this * should be set to {@code false}. * @since 1.4 */ public Base64(final boolean urlSafe) { this(MIME_CHUNK_SIZE, CHUNK_SEPARATOR, urlSafe); } /** * Creates a Base64 codec used for decoding (all modes) and encoding in * URL-unsafe mode. ** When encoding the line length is given in the constructor, the line * separator is CRLF, and the encoding table is STANDARD_ENCODE_TABLE. *
** Line lengths that aren't multiples of 4 will still essentially end up * being multiples of 4 in the encoded data. *
** When decoding all variants are supported. *
* * @param lineLength * Each line of encoded data will be at most of the given length * (rounded down to nearest multiple of 4). If lineLength <= 0, * then the output will not be divided into lines (chunks). * Ignored when decoding. */ public Base64(final int lineLength) { this(lineLength, CHUNK_SEPARATOR); } /** * Creates a Base64 codec used for decoding (all modes) and encoding in * URL-unsafe mode. ** When encoding the line length and line separator are given in the * constructor, and the encoding table is STANDARD_ENCODE_TABLE. *
** Line lengths that aren't multiples of 4 will still essentially end up * being multiples of 4 in the encoded data. *
** When decoding all variants are supported. *
* * @param lineLength * Each line of encoded data will be at most of the given length * (rounded down to nearest multiple of 4). If lineLength <= 0, * then the output will not be divided into lines (chunks). * Ignored when decoding. * @param lineSeparator * Each line of encoded data will end with this sequence of * bytes. * @throws IllegalArgumentException * Thrown when the provided lineSeparator included some base64 * characters. */ public Base64(final int lineLength, final byte[] lineSeparator) { this(lineLength, lineSeparator, false); } /** * Creates a Base64 codec used for decoding (all modes) and encoding in * URL-unsafe mode. ** When encoding the line length and line separator are given in the * constructor, and the encoding table is STANDARD_ENCODE_TABLE. *
** Line lengths that aren't multiples of 4 will still essentially end up * being multiples of 4 in the encoded data. *
** When decoding all variants are supported. *
* * @param lineLength * Each line of encoded data will be at most of the given length * (rounded down to nearest multiple of 4). If lineLength <= 0, * then the output will not be divided into lines (chunks). * Ignored when decoding. * @param lineSeparator * Each line of encoded data will end with this sequence of * bytes. * @param urlSafe * Instead of emitting '+' and '/' we emit '-' and '_' * respectively. urlSafe is only applied to encode operations. * Decoding seamlessly handles both modes. Note: no padding is * added when using the URL-safe alphabet. * @throws IllegalArgumentException * The provided lineSeparator included some base64 characters. * That's not going to work! */ public Base64(final int lineLength, final byte[] lineSeparator, final boolean urlSafe) { super(BYTES_PER_UNENCODED_BLOCK, BYTES_PER_ENCODED_BLOCK, lineLength, lineSeparator == null ? 0 : lineSeparator.length); // TODO could be simplified if there is no requirement to reject invalid // line sep when length <=0 // @see test case Base64Test.testConstructors() if (lineSeparator != null) { if (containsAlphabetOrPad(lineSeparator)) { try { final String sep = new String(lineSeparator, "UTF-8"); throw new IllegalArgumentException("lineSeparator must not contain base64 characters: [" + sep + "]"); } catch (UnsupportedEncodingException e) { e.printStackTrace(); } } if (lineLength > 0) { // null line-sep forces no chunking rather // than throwing IAE this.encodeSize = BYTES_PER_ENCODED_BLOCK + lineSeparator.length; this.lineSeparator = new byte[lineSeparator.length]; System.arraycopy(lineSeparator, 0, this.lineSeparator, 0, lineSeparator.length); } else { this.encodeSize = BYTES_PER_ENCODED_BLOCK; this.lineSeparator = null; } } else { this.encodeSize = BYTES_PER_ENCODED_BLOCK; this.lineSeparator = null; } this.decodeSize = this.encodeSize - 1; this.encodeTable = urlSafe ? URL_SAFE_ENCODE_TABLE : STANDARD_ENCODE_TABLE; } /** ** Encodes all of the provided data, starting at inPos, for inAvail bytes. * Must be called at least twice: once with the data to encode, and once * with inAvail set to "-1" to alert encoder that EOF has been reached, to * flush last remaining bytes (if not multiple of 3). *
** Note: no padding is added when encoding using the URL-safe * alphabet. *
* * @param in * byte[] array of binary data to base64 encode. * @param inPos * Position to start reading data from. * @param inAvail * Amount of bytes available from input for encoding. * @param context * the context to be used */ @Override void encode(final byte[] in, int inPos, final int inAvail, final Context context) { if (context.eof) { return; } // inAvail < 0 is how we're informed of EOF in the underlying data we're // encoding. if (inAvail < 0) { context.eof = true; if (0 == context.modulus && lineLength == 0) { return; // no leftovers to process and not using chunking } final byte[] buffer = ensureBufferSize(encodeSize, context); final int savedPos = context.pos; switch (context.modulus) { // 0-2 case 0: // nothing to do here break; case 1: // 8 bits = 6 + 2 // top 6 bits: buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 2) & MASK_6BITS]; // remaining 2: buffer[context.pos++] = encodeTable[(context.ibitWorkArea << 4) & MASK_6BITS]; // URL-SAFE skips the padding to further reduce size. if (encodeTable == STANDARD_ENCODE_TABLE) { buffer[context.pos++] = PAD; buffer[context.pos++] = PAD; } break; case 2: // 16 bits = 6 + 6 + 4 buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 10) & MASK_6BITS]; buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 4) & MASK_6BITS]; buffer[context.pos++] = encodeTable[(context.ibitWorkArea << 2) & MASK_6BITS]; // URL-SAFE skips the padding to further reduce size. if (encodeTable == STANDARD_ENCODE_TABLE) { buffer[context.pos++] = PAD; } break; default: throw new IllegalStateException("Impossible modulus " + context.modulus); } context.currentLinePos += context.pos - savedPos; // keep track of // current line // position // if currentPos == 0 we are at the start of a line, so don't add // CRLF if (lineLength > 0 && context.currentLinePos > 0) { System.arraycopy(lineSeparator, 0, buffer, context.pos, lineSeparator.length); context.pos += lineSeparator.length; } } else { for (int i = 0; i < inAvail; i++) { final byte[] buffer = ensureBufferSize(encodeSize, context); context.modulus = (context.modulus + 1) % BYTES_PER_UNENCODED_BLOCK; int b = in[inPos++]; if (b < 0) { b += 256; } context.ibitWorkArea = (context.ibitWorkArea << 8) + b; // BITS_PER_BYTE if (0 == context.modulus) { // 3 bytes = 24 bits = 4 * 6 bits to // extract buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 18) & MASK_6BITS]; buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 12) & MASK_6BITS]; buffer[context.pos++] = encodeTable[(context.ibitWorkArea >> 6) & MASK_6BITS]; buffer[context.pos++] = encodeTable[context.ibitWorkArea & MASK_6BITS]; context.currentLinePos += BYTES_PER_ENCODED_BLOCK; if (lineLength > 0 && lineLength <= context.currentLinePos) { System.arraycopy(lineSeparator, 0, buffer, context.pos, lineSeparator.length); context.pos += lineSeparator.length; context.currentLinePos = 0; } } } } } /** ** Decodes all of the provided data, starting at inPos, for inAvail bytes. * Should be called at least twice: once with the data to decode, and once * with inAvail set to "-1" to alert decoder that EOF has been reached. The * "-1" call is not necessary when decoding, but it doesn't hurt, either. *
** Ignores all non-base64 characters. This is how chunked (e.g. 76 * character) data is handled, since CR and LF are silently ignored, but has * implications for other bytes, too. This method subscribes to the * garbage-in, garbage-out philosophy: it will not check the provided data * for validity. *
* * @param in * byte[] array of ascii data to base64 decode. * @param inPos * Position to start reading data from. * @param inAvail * Amount of bytes available from input for encoding. * @param context * the context to be used */ @Override void decode(final byte[] in, int inPos, final int inAvail, final Context context) { if (context.eof) { return; } if (inAvail < 0) { context.eof = true; } for (int i = 0; i < inAvail; i++) { final byte[] buffer = ensureBufferSize(decodeSize, context); final byte b = in[inPos++]; if (b == PAD) { // We're done. context.eof = true; break; } else { if (b >= 0 && b < DECODE_TABLE.length) { final int result = DECODE_TABLE[b]; if (result >= 0) { context.modulus = (context.modulus + 1) % BYTES_PER_ENCODED_BLOCK; context.ibitWorkArea = (context.ibitWorkArea << BITS_PER_ENCODED_BYTE) + result; if (context.modulus == 0) { buffer[context.pos++] = (byte) ((context.ibitWorkArea >> 16) & MASK_8BITS); buffer[context.pos++] = (byte) ((context.ibitWorkArea >> 8) & MASK_8BITS); buffer[context.pos++] = (byte) (context.ibitWorkArea & MASK_8BITS); } } } } } // Two forms of EOF as far as base64 decoder is concerned: actual // EOF (-1) and first time '=' character is encountered in stream. // This approach makes the '=' padding characters completely optional. if (context.eof && context.modulus != 0) { final byte[] buffer = ensureBufferSize(decodeSize, context); // We have some spare bits remaining // Output all whole multiples of 8 bits and ignore the rest switch (context.modulus) { // case 0 : // impossible, as excluded above case 1: // 6 bits - ignore entirely // TODO not currently tested; perhaps it is impossible? break; case 2: // 12 bits = 8 + 4 context.ibitWorkArea = context.ibitWorkArea >> 4; // dump the // extra 4 // bits buffer[context.pos++] = (byte) ((context.ibitWorkArea) & MASK_8BITS); break; case 3: // 18 bits = 8 + 8 + 2 context.ibitWorkArea = context.ibitWorkArea >> 2; // dump 2 bits buffer[context.pos++] = (byte) ((context.ibitWorkArea >> 8) & MASK_8BITS); buffer[context.pos++] = (byte) ((context.ibitWorkArea) & MASK_8BITS); break; default: throw new IllegalStateException("Impossible modulus " + context.modulus); } } } /** * Encodes binary data using the base64 algorithm but does not chunk the * output. * * @param binaryData * binary data to encode * @return byte[] containing Base64 characters in their UTF-8 * representation. */ public static byte[] encodeBase64(final byte[] binaryData) { return encodeBase64(binaryData, false); } /** * Encodes binary data using the base64 algorithm but does not chunk the * output. * * NOTE: We changed the behaviour of this method from multi-line chunking * * @param binaryData * binary data to encode * @return String containing Base64 characters. * @throws UnsupportedEncodingException */ public static String encodeBase64String(final byte[] binaryData) throws UnsupportedEncodingException { return new String(encodeBase64(binaryData, false), "UTF-8"); } /** * Encodes binary data using a URL-safe variation of the base64 algorithm * but does not chunk the output. The url-safe variation emits - and _ * instead of + and / characters. Note: no padding is added. * * @param binaryData * binary data to encode * @return byte[] containing Base64 characters in their UTF-8 * representation. */ public static byte[] encodeBase64URLSafe(final byte[] binaryData) { return encodeBase64(binaryData, false, true); } /** * Encodes binary data using a URL-safe variation of the base64 algorithm * but does not chunk the output. The url-safe variation emits - and _ * instead of + and / characters. Note: no padding is added. * * @param binaryData * binary data to encode * @return String containing Base64 characters * @throws UnsupportedEncodingException */ public static String encodeBase64URLSafeString(final byte[] binaryData) throws UnsupportedEncodingException { return new String(encodeBase64(binaryData, false, true), "UTF-8"); } /** * Encodes binary data using the base64 algorithm and chunks the encoded * output into 76 character blocks * * @param binaryData * binary data to encode * @return Base64 characters chunked in 76 character blocks */ public static byte[] encodeBase64Chunked(final byte[] binaryData) { return encodeBase64(binaryData, true); } /** * Encodes binary data using the base64 algorithm, optionally chunking the * output into 76 character blocks. * * @param binaryData * Array containing binary data to encode. * @param isChunked * if {@code true} this encoder will chunk the base64 output into * 76 character blocks * @return Base64-encoded data. * @throws IllegalArgumentException * Thrown when the input array needs an output array bigger than * {@link Integer#MAX_VALUE} */ public static byte[] encodeBase64(final byte[] binaryData, final boolean isChunked) { return encodeBase64(binaryData, isChunked, false); } /** * Encodes binary data using the base64 algorithm, optionally chunking the * output into 76 character blocks. * * @param binaryData * Array containing binary data to encode. * @param isChunked * if {@code true} this encoder will chunk the base64 output into * 76 character blocks * @param urlSafe * if {@code true} this encoder will emit - and _ instead of the * usual + and / characters. Note: no padding is added when * encoding using the URL-safe alphabet. * @return Base64-encoded data. * @throws IllegalArgumentException * Thrown when the input array needs an output array bigger than * {@link Integer#MAX_VALUE} */ public static byte[] encodeBase64(final byte[] binaryData, final boolean isChunked, final boolean urlSafe) { return encodeBase64(binaryData, isChunked, urlSafe, Integer.MAX_VALUE); } /** * Encodes binary data using the base64 algorithm, optionally chunking the * output into 76 character blocks. * * @param binaryData * Array containing binary data to encode. * @param isChunked * if {@code true} this encoder will chunk the base64 output into * 76 character blocks * @param urlSafe * if {@code true} this encoder will emit - and _ instead of the * usual + and / characters. Note: no padding is added when * encoding using the URL-safe alphabet. * @param maxResultSize * The maximum result size to accept. * @return Base64-encoded data. * @throws IllegalArgumentException * Thrown when the input array needs an output array bigger than * maxResultSize */ public static byte[] encodeBase64(final byte[] binaryData, final boolean isChunked, final boolean urlSafe, final int maxResultSize) { if (binaryData == null || binaryData.length == 0) { return binaryData; } // Create this so can use the super-class method // Also ensures that the same roundings are performed by the ctor and // the code final Base64 b64 = isChunked ? new Base64(urlSafe) : new Base64(0, CHUNK_SEPARATOR, urlSafe); final long len = b64.getEncodedLength(binaryData); if (len > maxResultSize) { throw new IllegalArgumentException("Input array too big, the output array would be bigger (" + len + ") than the specified maximum size of " + maxResultSize); } return b64.encode(binaryData); } /** * Decodes a Base64 String into octets * * @param base64String * String containing Base64 data * @return Array containing decoded data. * @throws UnsupportedEncodingException */ public static byte[] decodeBase64(final String base64String) throws UnsupportedEncodingException { return new Base64().decode(base64String); } /** * Decodes Base64 data into octets * * @param base64Data * Byte array containing Base64 data * @return Array containing decoded data. */ public static byte[] decodeBase64(final byte[] base64Data) { return new Base64().decode(base64Data); } /** * Returns whether or not theoctet is in the Base64 alphabet.
*
* @param octet
* The value to test
* @return {@code true} if the value is defined in the the Base64 alphabet
* {@code false} otherwise.
*/
@Override
protected boolean isInAlphabet(final byte octet) {
return octet >= 0 && octet < decodeTable.length && decodeTable[octet] != -1;
}
}
abstract class BaseNCodec {
static class Context {
/**
* Place holder for the bytes we're dealing with for our based logic.
* Bitwise operations store and extract the encoding or decoding from this variable.
*/
int ibitWorkArea;
/**
* Place holder for the bytes we're dealing with for our based logic.
* Bitwise operations store and extract the encoding or decoding from this variable.
*/
long lbitWorkArea;
/**
* Buffer for streaming.
*/
byte[] buffer;
/**
* Position where next character should be written in the buffer.
*/
int pos;
/**
* Position where next character should be read from the buffer.
*/
int readPos;
/**
* Boolean flag to indicate the EOF has been reached. Once EOF has been reached, this object becomes useless,
* and must be thrown away.
*/
boolean eof;
/**
* Variable tracks how many characters have been written to the current line. Only used when encoding. We use
* it to make sure each encoded line never goes beyond lineLength (if lineLength > 0).
*/
int currentLinePos;
/**
* Writes to the buffer only occur after every 3/5 reads when encoding, and every 4/8 reads when decoding. This
* variable helps track that.
*/
int modulus;
Context() {
}
/**
* Returns a String useful for debugging (especially within a debugger.)
*
* @return a String useful for debugging.
*/
@SuppressWarnings("boxing") // OK to ignore boxing here
@Override
public String toString() {
return String.format("%s[buffer=%s, currentLinePos=%s, eof=%s, ibitWorkArea=%s, lbitWorkArea=%s, " +
"modulus=%s, pos=%s, readPos=%s]", this.getClass().getSimpleName(), Arrays.toString(buffer),
currentLinePos, eof, ibitWorkArea, lbitWorkArea, modulus, pos, readPos);
}
}
/**
* EOF
*/
static final int EOF = -1;
/**
* MIME chunk size per RFC 2045 section 6.8.
*/
public static final int MIME_CHUNK_SIZE = 76;
/**
* PEM chunk size per RFC 1421 section 4.3.2.4.
*/
public static final int PEM_CHUNK_SIZE = 64;
private static final int DEFAULT_BUFFER_RESIZE_FACTOR = 2;
/**
* Defines the default buffer size - currently {@value}
* - must be large enough for at least one encoded block+separator
*/
private static final int DEFAULT_BUFFER_SIZE = 8192;
/** Mask used to extract 8 bits, used in decoding bytes */
protected static final int MASK_8BITS = 0xff;
/**
* Byte used to pad output.
*/
protected static final byte PAD_DEFAULT = '='; // Allow static access to default
protected final byte PAD = PAD_DEFAULT; // instance variable just in case it needs to vary later
/** Number of bytes in each full block of unencoded data, e.g. 4 for Base64 and 5 for Base32 */
private final int unencodedBlockSize;
/** Number of bytes in each full block of encoded data, e.g. 3 for Base64 and 8 for Base32 */
private final int encodedBlockSize;
/**
* Chunksize for encoding. Not used when decoding.
* A value of zero or less implies no chunking of the encoded data.
* Rounded down to nearest multiple of encodedBlockSize.
*/
protected final int lineLength;
/**
* Size of chunk separator. Not used unless {@link #lineLength} > 0.
*/
private final int chunkSeparatorLength;
/**
* Note lineLength is rounded down to the nearest multiple of {@link #encodedBlockSize}
* If chunkSeparatorLength is zero, then chunking is disabled.
* @param unencodedBlockSize the size of an unencoded block (e.g. Base64 = 3)
* @param encodedBlockSize the size of an encoded block (e.g. Base64 = 4)
* @param lineLength if > 0, use chunking with a length lineLength
* @param chunkSeparatorLength the chunk separator length, if relevant
*/
protected BaseNCodec(final int unencodedBlockSize, final int encodedBlockSize,
final int lineLength, final int chunkSeparatorLength) {
this.unencodedBlockSize = unencodedBlockSize;
this.encodedBlockSize = encodedBlockSize;
final boolean useChunking = lineLength > 0 && chunkSeparatorLength > 0;
this.lineLength = useChunking ? (lineLength / encodedBlockSize) * encodedBlockSize : 0;
this.chunkSeparatorLength = chunkSeparatorLength;
}
/**
* Returns true if this object has buffered data for reading.
*
* @param context the context to be used
* @return true if there is data still available for reading.
*/
boolean hasData(final Context context) { // package protected for access from I/O streams
return context.buffer != null;
}
/**
* Returns the amount of buffered data available for reading.
*
* @param context the context to be used
* @return The amount of buffered data available for reading.
*/
int available(final Context context) { // package protected for access from I/O streams
return context.buffer != null ? context.pos - context.readPos : 0;
}
/**
* Get the default buffer size. Can be overridden.
*
* @return {@link #DEFAULT_BUFFER_SIZE}
*/
protected int getDefaultBufferSize() {
return DEFAULT_BUFFER_SIZE;
}
/**
* Increases our buffer by the {@link #DEFAULT_BUFFER_RESIZE_FACTOR}.
* @param context the context to be used
*/
private byte[] resizeBuffer(final Context context) {
if (context.buffer == null) {
context.buffer = new byte[getDefaultBufferSize()];
context.pos = 0;
context.readPos = 0;
} else {
final byte[] b = new byte[context.buffer.length * DEFAULT_BUFFER_RESIZE_FACTOR];
System.arraycopy(context.buffer, 0, b, 0, context.buffer.length);
context.buffer = b;
}
return context.buffer;
}
/**
* Ensure that the buffer has room for size bytes
*
* @param size minimum spare space required
* @param context the context to be used
*/
protected byte[] ensureBufferSize(final int size, final Context context){
if ((context.buffer == null) || (context.buffer.length < context.pos + size)){
return resizeBuffer(context);
}
return context.buffer;
}
/**
* Extracts buffered data into the provided byte[] array, starting at position bPos, up to a maximum of bAvail
* bytes. Returns how many bytes were actually extracted.
*
* Package protected for access from I/O streams.
*
* @param b
* byte[] array to extract the buffered data into.
* @param bPos
* position in byte[] array to start extraction at.
* @param bAvail
* amount of bytes we're allowed to extract. We may extract fewer (if fewer are available).
* @param context
* the context to be used
* @return The number of bytes successfully extracted into the provided byte[] array.
*/
int readResults(final byte[] b, final int bPos, final int bAvail, final Context context) {
if (context.buffer != null) {
final int len = Math.min(available(context), bAvail);
System.arraycopy(context.buffer, context.readPos, b, bPos, len);
context.readPos += len;
if (context.readPos >= context.pos) {
context.buffer = null; // so hasData() will return false, and this method can return -1
}
return len;
}
return context.eof ? EOF : 0;
}
/**
* Checks if a byte value is whitespace or not.
* Whitespace is taken to mean: space, tab, CR, LF
* @param byteToCheck
* the byte to check
* @return true if byte is whitespace, false otherwise
*/
protected static boolean isWhiteSpace(final byte byteToCheck) {
switch (byteToCheck) {
case ' ' :
case '\n' :
case '\r' :
case '\t' :
return true;
default :
return false;
}
}
/**
* Encodes an Object using the Base-N algorithm. This method is provided in order to satisfy the requirements of
* the Encoder interface, and will throw an EncoderException if the supplied object is not of type byte[].
*
* @param obj
* Object to encode
* @return An object (of type byte[]) containing the Base-N encoded data which corresponds to the byte[] supplied.
* if the parameter supplied is not of type byte[]
*/
public Object encode(final Object obj) throws Exception {
if (!(obj instanceof byte[])) {
throw new Exception("Parameter supplied to Base-N encode is not a byte[]");
}
return encode((byte[]) obj);
}
/**
* Encodes a byte[] containing binary data, into a String containing characters in the Base-N alphabet.
* Uses UTF8 encoding.
*
* @param pArray
* a byte array containing binary data
* @return A String containing only Base-N character data
* @throws UnsupportedEncodingException
*/
public String encodeToString(final byte[] pArray) throws UnsupportedEncodingException {
return new String(encode(pArray), "UTF-8");
}
/**
* Encodes a byte[] containing binary data, into a String containing characters in the appropriate alphabet.
* Uses UTF8 encoding.
*
* @param pArray a byte array containing binary data
* @return String containing only character data in the appropriate alphabet.
* @throws UnsupportedEncodingException
*/
public String encodeAsString(final byte[] pArray) throws UnsupportedEncodingException{
return new String(encode(pArray), "UTF-8");
}
/**
* Decodes an Object using the Base-N algorithm. This method is provided in order to satisfy the requirements of
* the Decoder interface, and will throw a DecoderException if the supplied object is not of type byte[] or String.
*
* @param obj
* Object to decode
* @return An object (of type byte[]) containing the binary data which corresponds to the byte[] or String
* supplied.
* if the parameter supplied is not of type byte[]
*/
public Object decode(final Object obj) throws Exception {
if (obj instanceof byte[]) {
return decode((byte[]) obj);
} else if (obj instanceof String) {
return decode((String) obj);
} else {
throw new Exception("Parameter supplied to Base-N decode is not a byte[] or a String");
}
}
/**
* Decodes a String containing characters in the Base-N alphabet.
*
* @param pArray
* A String containing Base-N character data
* @return a byte array containing binary data
* @throws UnsupportedEncodingException
*/
public byte[] decode(final String pArray) throws UnsupportedEncodingException {
return decode(pArray.getBytes("UTF-8"));
}
/**
* Decodes a byte[] containing characters in the Base-N alphabet.
*
* @param pArray
* A byte array containing Base-N character data
* @return a byte array containing binary data
*/
public byte[] decode(final byte[] pArray) {
if (pArray == null || pArray.length == 0) {
return pArray;
}
final Context context = new Context();
decode(pArray, 0, pArray.length, context);
decode(pArray, 0, EOF, context); // Notify decoder of EOF.
final byte[] result = new byte[context.pos];
readResults(result, 0, result.length, context);
return result;
}
/**
* Encodes a byte[] containing binary data, into a byte[] containing characters in the alphabet.
*
* @param pArray
* a byte array containing binary data
* @return A byte array containing only the basen alphabetic character data
*/
public byte[] encode(final byte[] pArray) {
if (pArray == null || pArray.length == 0) {
return pArray;
}
final Context context = new Context();
encode(pArray, 0, pArray.length, context);
encode(pArray, 0, EOF, context); // Notify encoder of EOF.
final byte[] buf = new byte[context.pos - context.readPos];
readResults(buf, 0, buf.length, context);
return buf;
}
// package protected for access from I/O streams
abstract void encode(byte[] pArray, int i, int length, Context context);
// package protected for access from I/O streams
abstract void decode(byte[] pArray, int i, int length, Context context);
/**
* Returns whether or not the octet is in the current alphabet.
* Does not allow whitespace or pad.
*
* @param value The value to test
*
* @return {@code true} if the value is defined in the current alphabet, {@code false} otherwise.
*/
protected abstract boolean isInAlphabet(byte value);
/**
* Tests a given byte array to see if it contains only valid characters within the alphabet.
* The method optionally treats whitespace and pad as valid.
*
* @param arrayOctet byte array to test
* @param allowWSPad if {@code true}, then whitespace and PAD are also allowed
*
* @return {@code true} if all bytes are valid characters in the alphabet or if the byte array is empty;
* {@code false}, otherwise
*/
public boolean isInAlphabet(final byte[] arrayOctet, final boolean allowWSPad) {
for (int i = 0; i < arrayOctet.length; i++) {
if (!isInAlphabet(arrayOctet[i]) &&
(!allowWSPad || (arrayOctet[i] != PAD) && !isWhiteSpace(arrayOctet[i]))) {
return false;
}
}
return true;
}
/**
* Tests a given String to see if it contains only valid characters within the alphabet.
* The method treats whitespace and PAD as valid.
*
* @param basen String to test
* @return {@code true} if all characters in the String are valid characters in the alphabet or if
* the String is empty; {@code false}, otherwise
* @throws UnsupportedEncodingException
* @see #isInAlphabet(byte[], boolean)
*/
public boolean isInAlphabet(final String basen) throws UnsupportedEncodingException {
return isInAlphabet(basen.getBytes("UTF-8"), true);
}
/**
* Tests a given byte array to see if it contains any characters within the alphabet or PAD.
*
* Intended for use in checking line-ending arrays
*
* @param arrayOctet
* byte array to test
* @return {@code true} if any byte is a valid character in the alphabet or PAD; {@code false} otherwise
*/
protected boolean containsAlphabetOrPad(final byte[] arrayOctet) {
if (arrayOctet == null) {
return false;
}
for (final byte element : arrayOctet) {
if (PAD == element || isInAlphabet(element)) {
return true;
}
}
return false;
}
/**
* Calculates the amount of space needed to encode the supplied array.
*
* @param pArray byte[] array which will later be encoded
*
* @return amount of space needed to encoded the supplied array.
* Returns a long since a max-len array will require > Integer.MAX_VALUE
*/
public long getEncodedLength(final byte[] pArray) {
// Calculate non-chunked size - rounded up to allow for padding
// cast to long is needed to avoid possibility of overflow
long len = ((pArray.length + unencodedBlockSize-1) / unencodedBlockSize) * (long) encodedBlockSize;
if (lineLength > 0) { // We're using chunking
// Round up to nearest multiple
len += ((len + lineLength-1) / lineLength) * chunkSeparatorLength;
}
return len;
}
}