All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.facebook.presto.jdbc.internal.guava.io.BaseEncoding Maven / Gradle / Ivy

There is a newer version: 0.289
Show newest version
/*
 * Copyright (C) 2012 The Guava Authors
 *
 * Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
 * in compliance with the License. You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software distributed under the License
 * is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
 * or implied. See the License for the specific language governing permissions and limitations under
 * the License.
 */

package com.facebook.presto.jdbc.internal.guava.io;

import static com.facebook.presto.jdbc.internal.guava.base.Preconditions.checkArgument;
import static com.facebook.presto.jdbc.internal.guava.base.Preconditions.checkNotNull;
import static com.facebook.presto.jdbc.internal.guava.base.Preconditions.checkPositionIndexes;
import static com.facebook.presto.jdbc.internal.guava.base.Preconditions.checkState;
import static com.facebook.presto.jdbc.internal.guava.math.IntMath.divide;
import static com.facebook.presto.jdbc.internal.guava.math.IntMath.log2;
import static java.math.RoundingMode.CEILING;
import static java.math.RoundingMode.FLOOR;
import static java.math.RoundingMode.UNNECESSARY;

import com.facebook.presto.jdbc.internal.guava.annotations.GwtCompatible;
import com.facebook.presto.jdbc.internal.guava.annotations.GwtIncompatible;
import com.facebook.presto.jdbc.internal.guava.base.Ascii;
import com.facebook.presto.jdbc.internal.guava.base.Objects;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.io.Reader;
import java.io.Writer;
import java.util.Arrays;
import org.checkerframework.checker.nullness.qual.MonotonicNonNull;
import org.checkerframework.checker.nullness.qual.Nullable;

/**
 * A binary encoding scheme for reversibly translating between byte sequences and printable ASCII
 * strings. This class includes several constants for encoding schemes specified by RFC 4648. For example, the expression:
 *
 * 
{@code
 * BaseEncoding.base32().encode("foo".getBytes(Charsets.US_ASCII))
 * }
* *

returns the string {@code "MZXW6==="}, and * *

{@code
 * byte[] decoded = BaseEncoding.base32().decode("MZXW6===");
 * }
* *

...returns the ASCII bytes of the string {@code "foo"}. * *

By default, {@code BaseEncoding}'s behavior is relatively strict and in accordance with RFC * 4648. Decoding rejects characters in the wrong case, though padding is optional. To modify * encoding and decoding behavior, use configuration methods to obtain a new encoding with modified * behavior: * *

{@code
 * BaseEncoding.base16().lowerCase().decode("deadbeef");
 * }
* *

Warning: BaseEncoding instances are immutable. Invoking a configuration method has no effect * on the receiving instance; you must store and use the new encoding instance it returns, instead. * *

{@code
 * // Do NOT do this
 * BaseEncoding hex = BaseEncoding.base16();
 * hex.lowerCase(); // does nothing!
 * return hex.decode("deadbeef"); // throws an IllegalArgumentException
 * }
* *

It is guaranteed that {@code encoding.decode(encoding.encode(x))} is always equal to {@code * x}, but the reverse does not necessarily hold. * *

* * * * * * * *
Encodings
Encoding * Alphabet * {@code char:byte} ratio * Default padding * Comments *
{@link #base16()} * 0-9 A-F * 2.00 * N/A * Traditional hexadecimal. Defaults to upper case. *
{@link #base32()} * A-Z 2-7 * 1.60 * = * Human-readable; no possibility of mixing up 0/O or 1/I. Defaults to upper case. *
{@link #base32Hex()} * 0-9 A-V * 1.60 * = * "Numerical" base 32; extended from the traditional hex alphabet. Defaults to upper case. *
{@link #base64()} * A-Z a-z 0-9 + / * 1.33 * = * *
{@link #base64Url()} * A-Z a-z 0-9 - _ * 1.33 * = * Safe to use as filenames, or to pass in URLs without escaping *
* *

All instances of this class are immutable, so they may be stored safely as static constants. * * @author Louis Wasserman * @since 14.0 */ @GwtCompatible(emulated = true) public abstract class BaseEncoding { // TODO(lowasser): consider making encodeTo(Appendable, byte[], int, int) public. BaseEncoding() {} /** * Exception indicating invalid base-encoded input encountered while decoding. * * @author Louis Wasserman * @since 15.0 */ public static final class DecodingException extends IOException { DecodingException(String message) { super(message); } DecodingException(Throwable cause) { super(cause); } } /** Encodes the specified byte array, and returns the encoded {@code String}. */ public String encode(byte[] bytes) { return encode(bytes, 0, bytes.length); } /** * Encodes the specified range of the specified byte array, and returns the encoded {@code * String}. */ public final String encode(byte[] bytes, int off, int len) { checkPositionIndexes(off, off + len, bytes.length); StringBuilder result = new StringBuilder(maxEncodedSize(len)); try { encodeTo(result, bytes, off, len); } catch (IOException impossible) { throw new AssertionError(impossible); } return result.toString(); } /** * Returns an {@code OutputStream} that encodes bytes using this encoding into the specified * {@code Writer}. When the returned {@code OutputStream} is closed, so is the backing {@code * Writer}. */ @GwtIncompatible // Writer,OutputStream public abstract OutputStream encodingStream(Writer writer); /** * Returns a {@code ByteSink} that writes base-encoded bytes to the specified {@code CharSink}. */ @GwtIncompatible // ByteSink,CharSink public final ByteSink encodingSink(final CharSink encodedSink) { checkNotNull(encodedSink); return new ByteSink() { @Override public OutputStream openStream() throws IOException { return encodingStream(encodedSink.openStream()); } }; } // TODO(lowasser): document the extent of leniency, probably after adding ignore(CharMatcher) private static byte[] extract(byte[] result, int length) { if (length == result.length) { return result; } else { byte[] trunc = new byte[length]; System.arraycopy(result, 0, trunc, 0, length); return trunc; } } /** * Determines whether the specified character sequence is a valid encoded string according to this * encoding. * * @since 20.0 */ public abstract boolean canDecode(CharSequence chars); /** * Decodes the specified character sequence, and returns the resulting {@code byte[]}. This is the * inverse operation to {@link #encode(byte[])}. * * @throws IllegalArgumentException if the input is not a valid encoded string according to this * encoding. */ public final byte[] decode(CharSequence chars) { try { return decodeChecked(chars); } catch (DecodingException badInput) { throw new IllegalArgumentException(badInput); } } /** * Decodes the specified character sequence, and returns the resulting {@code byte[]}. This is the * inverse operation to {@link #encode(byte[])}. * * @throws DecodingException if the input is not a valid encoded string according to this * encoding. */ final byte[] decodeChecked(CharSequence chars) throws DecodingException { chars = trimTrailingPadding(chars); byte[] tmp = new byte[maxDecodedSize(chars.length())]; int len = decodeTo(tmp, chars); return extract(tmp, len); } /** * Returns an {@code InputStream} that decodes base-encoded input from the specified {@code * Reader}. The returned stream throws a {@link DecodingException} upon decoding-specific errors. */ @GwtIncompatible // Reader,InputStream public abstract InputStream decodingStream(Reader reader); /** * Returns a {@code ByteSource} that reads base-encoded bytes from the specified {@code * CharSource}. */ @GwtIncompatible // ByteSource,CharSource public final ByteSource decodingSource(final CharSource encodedSource) { checkNotNull(encodedSource); return new ByteSource() { @Override public InputStream openStream() throws IOException { return decodingStream(encodedSource.openStream()); } }; } // Implementations for encoding/decoding abstract int maxEncodedSize(int bytes); abstract void encodeTo(Appendable target, byte[] bytes, int off, int len) throws IOException; abstract int maxDecodedSize(int chars); abstract int decodeTo(byte[] target, CharSequence chars) throws DecodingException; CharSequence trimTrailingPadding(CharSequence chars) { return checkNotNull(chars); } // Modified encoding generators /** * Returns an encoding that behaves equivalently to this encoding, but omits any padding * characters as specified by RFC 4648 * section 3.2, Padding of Encoded Data. */ public abstract BaseEncoding omitPadding(); /** * Returns an encoding that behaves equivalently to this encoding, but uses an alternate character * for padding. * * @throws IllegalArgumentException if this padding character is already used in the alphabet or a * separator */ public abstract BaseEncoding withPadChar(char padChar); /** * Returns an encoding that behaves equivalently to this encoding, but adds a separator string * after every {@code n} characters. Any occurrences of any characters that occur in the separator * are skipped over in decoding. * * @throws IllegalArgumentException if any alphabet or padding characters appear in the separator * string, or if {@code n <= 0} * @throws UnsupportedOperationException if this encoding already uses a separator */ public abstract BaseEncoding withSeparator(String separator, int n); /** * Returns an encoding that behaves equivalently to this encoding, but encodes and decodes with * uppercase letters. Padding and separator characters remain in their original case. * * @throws IllegalStateException if the alphabet used by this encoding contains mixed upper- and * lower-case characters */ public abstract BaseEncoding upperCase(); /** * Returns an encoding that behaves equivalently to this encoding, but encodes and decodes with * lowercase letters. Padding and separator characters remain in their original case. * * @throws IllegalStateException if the alphabet used by this encoding contains mixed upper- and * lower-case characters */ public abstract BaseEncoding lowerCase(); private static final BaseEncoding BASE64 = new Base64Encoding( "base64()", "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/", '='); /** * The "base64" base encoding specified by RFC 4648 section 4, Base 64 Encoding. * (This is the same as the base 64 encoding from RFC 3548.) * *

The character {@code '='} is used for padding, but can be {@linkplain #omitPadding() * omitted} or {@linkplain #withPadChar(char) replaced}. * *

No line feeds are added by default, as per RFC 4648 section 3.1, Line Feeds in * Encoded Data. Line feeds may be added using {@link #withSeparator(String, int)}. */ public static BaseEncoding base64() { return BASE64; } private static final BaseEncoding BASE64_URL = new Base64Encoding( "base64Url()", "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_", '='); /** * The "base64url" encoding specified by RFC 4648 section 5, Base 64 Encoding * with URL and Filename Safe Alphabet, also sometimes referred to as the "web safe Base64." (This * is the same as the base 64 encoding with URL and filename safe alphabet from RFC 3548.) * *

The character {@code '='} is used for padding, but can be {@linkplain #omitPadding() * omitted} or {@linkplain #withPadChar(char) replaced}. * *

No line feeds are added by default, as per RFC 4648 section 3.1, Line Feeds in * Encoded Data. Line feeds may be added using {@link #withSeparator(String, int)}. */ public static BaseEncoding base64Url() { return BASE64_URL; } private static final BaseEncoding BASE32 = new StandardBaseEncoding("base32()", "ABCDEFGHIJKLMNOPQRSTUVWXYZ234567", '='); /** * The "base32" encoding specified by RFC * 4648 section 6, Base 32 Encoding. (This is the same as the base 32 encoding from RFC 3548.) * *

The character {@code '='} is used for padding, but can be {@linkplain #omitPadding() * omitted} or {@linkplain #withPadChar(char) replaced}. * *

No line feeds are added by default, as per RFC 4648 section 3.1, Line Feeds in * Encoded Data. Line feeds may be added using {@link #withSeparator(String, int)}. */ public static BaseEncoding base32() { return BASE32; } private static final BaseEncoding BASE32_HEX = new StandardBaseEncoding("base32Hex()", "0123456789ABCDEFGHIJKLMNOPQRSTUV", '='); /** * The "base32hex" encoding specified by RFC 4648 section 7, Base 32 Encoding * with Extended Hex Alphabet. There is no corresponding encoding in RFC 3548. * *

The character {@code '='} is used for padding, but can be {@linkplain #omitPadding() * omitted} or {@linkplain #withPadChar(char) replaced}. * *

No line feeds are added by default, as per RFC 4648 section 3.1, Line Feeds in * Encoded Data. Line feeds may be added using {@link #withSeparator(String, int)}. */ public static BaseEncoding base32Hex() { return BASE32_HEX; } private static final BaseEncoding BASE16 = new Base16Encoding("base16()", "0123456789ABCDEF"); /** * The "base16" encoding specified by RFC * 4648 section 8, Base 16 Encoding. (This is the same as the base 16 encoding from RFC 3548.) This is commonly known as * "hexadecimal" format. * *

No padding is necessary in base 16, so {@link #withPadChar(char)} and {@link #omitPadding()} * have no effect. * *

No line feeds are added by default, as per RFC 4648 section 3.1, Line Feeds in * Encoded Data. Line feeds may be added using {@link #withSeparator(String, int)}. */ public static BaseEncoding base16() { return BASE16; } private static final class Alphabet { private final String name; // this is meant to be immutable -- don't modify it! private final char[] chars; final int mask; final int bitsPerChar; final int charsPerChunk; final int bytesPerChunk; private final byte[] decodabet; private final boolean[] validPadding; Alphabet(String name, char[] chars) { this.name = checkNotNull(name); this.chars = checkNotNull(chars); try { this.bitsPerChar = log2(chars.length, UNNECESSARY); } catch (ArithmeticException e) { throw new IllegalArgumentException("Illegal alphabet length " + chars.length, e); } /* * e.g. for base64, bitsPerChar == 6, charsPerChunk == 4, and bytesPerChunk == 3. This makes * for the smallest chunk size that still has charsPerChunk * bitsPerChar be a multiple of 8. */ int gcd = Math.min(8, Integer.lowestOneBit(bitsPerChar)); try { this.charsPerChunk = 8 / gcd; this.bytesPerChunk = bitsPerChar / gcd; } catch (ArithmeticException e) { throw new IllegalArgumentException("Illegal alphabet " + new String(chars), e); } this.mask = chars.length - 1; byte[] decodabet = new byte[Ascii.MAX + 1]; Arrays.fill(decodabet, (byte) -1); for (int i = 0; i < chars.length; i++) { char c = chars[i]; checkArgument(c < decodabet.length, "Non-ASCII character: %s", c); checkArgument(decodabet[c] == -1, "Duplicate character: %s", c); decodabet[c] = (byte) i; } this.decodabet = decodabet; boolean[] validPadding = new boolean[charsPerChunk]; for (int i = 0; i < bytesPerChunk; i++) { validPadding[divide(i * 8, bitsPerChar, CEILING)] = true; } this.validPadding = validPadding; } char encode(int bits) { return chars[bits]; } boolean isValidPaddingStartPosition(int index) { return validPadding[index % charsPerChunk]; } boolean canDecode(char ch) { return ch <= Ascii.MAX && decodabet[ch] != -1; } int decode(char ch) throws DecodingException { if (ch > Ascii.MAX) { throw new DecodingException("Unrecognized character: 0x" + Integer.toHexString(ch)); } int result = decodabet[ch]; if (result == -1) { if (ch <= 0x20 || ch == Ascii.MAX) { throw new DecodingException("Unrecognized character: 0x" + Integer.toHexString(ch)); } else { throw new DecodingException("Unrecognized character: " + ch); } } return result; } private boolean hasLowerCase() { for (char c : chars) { if (Ascii.isLowerCase(c)) { return true; } } return false; } private boolean hasUpperCase() { for (char c : chars) { if (Ascii.isUpperCase(c)) { return true; } } return false; } Alphabet upperCase() { if (!hasLowerCase()) { return this; } else { checkState(!hasUpperCase(), "Cannot call upperCase() on a mixed-case alphabet"); char[] upperCased = new char[chars.length]; for (int i = 0; i < chars.length; i++) { upperCased[i] = Ascii.toUpperCase(chars[i]); } return new Alphabet(name + ".upperCase()", upperCased); } } Alphabet lowerCase() { if (!hasUpperCase()) { return this; } else { checkState(!hasLowerCase(), "Cannot call lowerCase() on a mixed-case alphabet"); char[] lowerCased = new char[chars.length]; for (int i = 0; i < chars.length; i++) { lowerCased[i] = Ascii.toLowerCase(chars[i]); } return new Alphabet(name + ".lowerCase()", lowerCased); } } public boolean matches(char c) { return c < decodabet.length && decodabet[c] != -1; } @Override public String toString() { return name; } @Override public boolean equals(@Nullable Object other) { if (other instanceof Alphabet) { Alphabet that = (Alphabet) other; return Arrays.equals(this.chars, that.chars); } return false; } @Override public int hashCode() { return Arrays.hashCode(chars); } } static class StandardBaseEncoding extends BaseEncoding { // TODO(lowasser): provide a useful toString final Alphabet alphabet; final @Nullable Character paddingChar; StandardBaseEncoding(String name, String alphabetChars, @Nullable Character paddingChar) { this(new Alphabet(name, alphabetChars.toCharArray()), paddingChar); } StandardBaseEncoding(Alphabet alphabet, @Nullable Character paddingChar) { this.alphabet = checkNotNull(alphabet); checkArgument( paddingChar == null || !alphabet.matches(paddingChar), "Padding character %s was already in alphabet", paddingChar); this.paddingChar = paddingChar; } @Override int maxEncodedSize(int bytes) { return alphabet.charsPerChunk * divide(bytes, alphabet.bytesPerChunk, CEILING); } @GwtIncompatible // Writer,OutputStream @Override public OutputStream encodingStream(final Writer out) { checkNotNull(out); return new OutputStream() { int bitBuffer = 0; int bitBufferLength = 0; int writtenChars = 0; @Override public void write(int b) throws IOException { bitBuffer <<= 8; bitBuffer |= b & 0xFF; bitBufferLength += 8; while (bitBufferLength >= alphabet.bitsPerChar) { int charIndex = (bitBuffer >> (bitBufferLength - alphabet.bitsPerChar)) & alphabet.mask; out.write(alphabet.encode(charIndex)); writtenChars++; bitBufferLength -= alphabet.bitsPerChar; } } @Override public void flush() throws IOException { out.flush(); } @Override public void close() throws IOException { if (bitBufferLength > 0) { int charIndex = (bitBuffer << (alphabet.bitsPerChar - bitBufferLength)) & alphabet.mask; out.write(alphabet.encode(charIndex)); writtenChars++; if (paddingChar != null) { while (writtenChars % alphabet.charsPerChunk != 0) { out.write(paddingChar.charValue()); writtenChars++; } } } out.close(); } }; } @Override void encodeTo(Appendable target, byte[] bytes, int off, int len) throws IOException { checkNotNull(target); checkPositionIndexes(off, off + len, bytes.length); for (int i = 0; i < len; i += alphabet.bytesPerChunk) { encodeChunkTo(target, bytes, off + i, Math.min(alphabet.bytesPerChunk, len - i)); } } void encodeChunkTo(Appendable target, byte[] bytes, int off, int len) throws IOException { checkNotNull(target); checkPositionIndexes(off, off + len, bytes.length); checkArgument(len <= alphabet.bytesPerChunk); long bitBuffer = 0; for (int i = 0; i < len; ++i) { bitBuffer |= bytes[off + i] & 0xFF; bitBuffer <<= 8; // Add additional zero byte in the end. } // Position of first character is length of bitBuffer minus bitsPerChar. final int bitOffset = (len + 1) * 8 - alphabet.bitsPerChar; int bitsProcessed = 0; while (bitsProcessed < len * 8) { int charIndex = (int) (bitBuffer >>> (bitOffset - bitsProcessed)) & alphabet.mask; target.append(alphabet.encode(charIndex)); bitsProcessed += alphabet.bitsPerChar; } if (paddingChar != null) { while (bitsProcessed < alphabet.bytesPerChunk * 8) { target.append(paddingChar.charValue()); bitsProcessed += alphabet.bitsPerChar; } } } @Override int maxDecodedSize(int chars) { return (int) ((alphabet.bitsPerChar * (long) chars + 7L) / 8L); } @Override CharSequence trimTrailingPadding(CharSequence chars) { checkNotNull(chars); if (paddingChar == null) { return chars; } char padChar = paddingChar.charValue(); int l; for (l = chars.length() - 1; l >= 0; l--) { if (chars.charAt(l) != padChar) { break; } } return chars.subSequence(0, l + 1); } @Override public boolean canDecode(CharSequence chars) { checkNotNull(chars); chars = trimTrailingPadding(chars); if (!alphabet.isValidPaddingStartPosition(chars.length())) { return false; } for (int i = 0; i < chars.length(); i++) { if (!alphabet.canDecode(chars.charAt(i))) { return false; } } return true; } @Override int decodeTo(byte[] target, CharSequence chars) throws DecodingException { checkNotNull(target); chars = trimTrailingPadding(chars); if (!alphabet.isValidPaddingStartPosition(chars.length())) { throw new DecodingException("Invalid input length " + chars.length()); } int bytesWritten = 0; for (int charIdx = 0; charIdx < chars.length(); charIdx += alphabet.charsPerChunk) { long chunk = 0; int charsProcessed = 0; for (int i = 0; i < alphabet.charsPerChunk; i++) { chunk <<= alphabet.bitsPerChar; if (charIdx + i < chars.length()) { chunk |= alphabet.decode(chars.charAt(charIdx + charsProcessed++)); } } final int minOffset = alphabet.bytesPerChunk * 8 - charsProcessed * alphabet.bitsPerChar; for (int offset = (alphabet.bytesPerChunk - 1) * 8; offset >= minOffset; offset -= 8) { target[bytesWritten++] = (byte) ((chunk >>> offset) & 0xFF); } } return bytesWritten; } @Override @GwtIncompatible // Reader,InputStream public InputStream decodingStream(final Reader reader) { checkNotNull(reader); return new InputStream() { int bitBuffer = 0; int bitBufferLength = 0; int readChars = 0; boolean hitPadding = false; @Override public int read() throws IOException { while (true) { int readChar = reader.read(); if (readChar == -1) { if (!hitPadding && !alphabet.isValidPaddingStartPosition(readChars)) { throw new DecodingException("Invalid input length " + readChars); } return -1; } readChars++; char ch = (char) readChar; if (paddingChar != null && paddingChar.charValue() == ch) { if (!hitPadding && (readChars == 1 || !alphabet.isValidPaddingStartPosition(readChars - 1))) { throw new DecodingException("Padding cannot start at index " + readChars); } hitPadding = true; } else if (hitPadding) { throw new DecodingException( "Expected padding character but found '" + ch + "' at index " + readChars); } else { bitBuffer <<= alphabet.bitsPerChar; bitBuffer |= alphabet.decode(ch); bitBufferLength += alphabet.bitsPerChar; if (bitBufferLength >= 8) { bitBufferLength -= 8; return (bitBuffer >> bitBufferLength) & 0xFF; } } } } @Override public void close() throws IOException { reader.close(); } }; } @Override public BaseEncoding omitPadding() { return (paddingChar == null) ? this : newInstance(alphabet, null); } @Override public BaseEncoding withPadChar(char padChar) { if (8 % alphabet.bitsPerChar == 0 || (paddingChar != null && paddingChar.charValue() == padChar)) { return this; } else { return newInstance(alphabet, padChar); } } @Override public BaseEncoding withSeparator(String separator, int afterEveryChars) { for (int i = 0; i < separator.length(); i++) { checkArgument( !alphabet.matches(separator.charAt(i)), "Separator (%s) cannot contain alphabet characters", separator); } if (paddingChar != null) { checkArgument( separator.indexOf(paddingChar.charValue()) < 0, "Separator (%s) cannot contain padding character", separator); } return new SeparatedBaseEncoding(this, separator, afterEveryChars); } private transient @MonotonicNonNull BaseEncoding upperCase; private transient @MonotonicNonNull BaseEncoding lowerCase; @Override public BaseEncoding upperCase() { BaseEncoding result = upperCase; if (result == null) { Alphabet upper = alphabet.upperCase(); result = upperCase = (upper == alphabet) ? this : newInstance(upper, paddingChar); } return result; } @Override public BaseEncoding lowerCase() { BaseEncoding result = lowerCase; if (result == null) { Alphabet lower = alphabet.lowerCase(); result = lowerCase = (lower == alphabet) ? this : newInstance(lower, paddingChar); } return result; } BaseEncoding newInstance(Alphabet alphabet, @Nullable Character paddingChar) { return new StandardBaseEncoding(alphabet, paddingChar); } @Override public String toString() { StringBuilder builder = new StringBuilder("BaseEncoding."); builder.append(alphabet.toString()); if (8 % alphabet.bitsPerChar != 0) { if (paddingChar == null) { builder.append(".omitPadding()"); } else { builder.append(".withPadChar('").append(paddingChar).append("')"); } } return builder.toString(); } @Override public boolean equals(@Nullable Object other) { if (other instanceof StandardBaseEncoding) { StandardBaseEncoding that = (StandardBaseEncoding) other; return this.alphabet.equals(that.alphabet) && Objects.equal(this.paddingChar, that.paddingChar); } return false; } @Override public int hashCode() { return alphabet.hashCode() ^ Objects.hashCode(paddingChar); } } static final class Base16Encoding extends StandardBaseEncoding { final char[] encoding = new char[512]; Base16Encoding(String name, String alphabetChars) { this(new Alphabet(name, alphabetChars.toCharArray())); } private Base16Encoding(Alphabet alphabet) { super(alphabet, null); checkArgument(alphabet.chars.length == 16); for (int i = 0; i < 256; ++i) { encoding[i] = alphabet.encode(i >>> 4); encoding[i | 0x100] = alphabet.encode(i & 0xF); } } @Override void encodeTo(Appendable target, byte[] bytes, int off, int len) throws IOException { checkNotNull(target); checkPositionIndexes(off, off + len, bytes.length); for (int i = 0; i < len; ++i) { int b = bytes[off + i] & 0xFF; target.append(encoding[b]); target.append(encoding[b | 0x100]); } } @Override int decodeTo(byte[] target, CharSequence chars) throws DecodingException { checkNotNull(target); if (chars.length() % 2 == 1) { throw new DecodingException("Invalid input length " + chars.length()); } int bytesWritten = 0; for (int i = 0; i < chars.length(); i += 2) { int decoded = alphabet.decode(chars.charAt(i)) << 4 | alphabet.decode(chars.charAt(i + 1)); target[bytesWritten++] = (byte) decoded; } return bytesWritten; } @Override BaseEncoding newInstance(Alphabet alphabet, @Nullable Character paddingChar) { return new Base16Encoding(alphabet); } } static final class Base64Encoding extends StandardBaseEncoding { Base64Encoding(String name, String alphabetChars, @Nullable Character paddingChar) { this(new Alphabet(name, alphabetChars.toCharArray()), paddingChar); } private Base64Encoding(Alphabet alphabet, @Nullable Character paddingChar) { super(alphabet, paddingChar); checkArgument(alphabet.chars.length == 64); } @Override void encodeTo(Appendable target, byte[] bytes, int off, int len) throws IOException { checkNotNull(target); checkPositionIndexes(off, off + len, bytes.length); int i = off; for (int remaining = len; remaining >= 3; remaining -= 3) { int chunk = (bytes[i++] & 0xFF) << 16 | (bytes[i++] & 0xFF) << 8 | bytes[i++] & 0xFF; target.append(alphabet.encode(chunk >>> 18)); target.append(alphabet.encode((chunk >>> 12) & 0x3F)); target.append(alphabet.encode((chunk >>> 6) & 0x3F)); target.append(alphabet.encode(chunk & 0x3F)); } if (i < off + len) { encodeChunkTo(target, bytes, i, off + len - i); } } @Override int decodeTo(byte[] target, CharSequence chars) throws DecodingException { checkNotNull(target); chars = trimTrailingPadding(chars); if (!alphabet.isValidPaddingStartPosition(chars.length())) { throw new DecodingException("Invalid input length " + chars.length()); } int bytesWritten = 0; for (int i = 0; i < chars.length(); ) { int chunk = alphabet.decode(chars.charAt(i++)) << 18; chunk |= alphabet.decode(chars.charAt(i++)) << 12; target[bytesWritten++] = (byte) (chunk >>> 16); if (i < chars.length()) { chunk |= alphabet.decode(chars.charAt(i++)) << 6; target[bytesWritten++] = (byte) ((chunk >>> 8) & 0xFF); if (i < chars.length()) { chunk |= alphabet.decode(chars.charAt(i++)); target[bytesWritten++] = (byte) (chunk & 0xFF); } } } return bytesWritten; } @Override BaseEncoding newInstance(Alphabet alphabet, @Nullable Character paddingChar) { return new Base64Encoding(alphabet, paddingChar); } } @GwtIncompatible static Reader ignoringReader(final Reader delegate, final String toIgnore) { checkNotNull(delegate); checkNotNull(toIgnore); return new Reader() { @Override public int read() throws IOException { int readChar; do { readChar = delegate.read(); } while (readChar != -1 && toIgnore.indexOf((char) readChar) >= 0); return readChar; } @Override public int read(char[] cbuf, int off, int len) throws IOException { throw new UnsupportedOperationException(); } @Override public void close() throws IOException { delegate.close(); } }; } static Appendable separatingAppendable( final Appendable delegate, final String separator, final int afterEveryChars) { checkNotNull(delegate); checkNotNull(separator); checkArgument(afterEveryChars > 0); return new Appendable() { int charsUntilSeparator = afterEveryChars; @Override public Appendable append(char c) throws IOException { if (charsUntilSeparator == 0) { delegate.append(separator); charsUntilSeparator = afterEveryChars; } delegate.append(c); charsUntilSeparator--; return this; } @Override public Appendable append(@Nullable CharSequence chars, int off, int len) throws IOException { throw new UnsupportedOperationException(); } @Override public Appendable append(@Nullable CharSequence chars) throws IOException { throw new UnsupportedOperationException(); } }; } @GwtIncompatible // Writer static Writer separatingWriter( final Writer delegate, final String separator, final int afterEveryChars) { final Appendable seperatingAppendable = separatingAppendable(delegate, separator, afterEveryChars); return new Writer() { @Override public void write(int c) throws IOException { seperatingAppendable.append((char) c); } @Override public void write(char[] chars, int off, int len) throws IOException { throw new UnsupportedOperationException(); } @Override public void flush() throws IOException { delegate.flush(); } @Override public void close() throws IOException { delegate.close(); } }; } static final class SeparatedBaseEncoding extends BaseEncoding { private final BaseEncoding delegate; private final String separator; private final int afterEveryChars; SeparatedBaseEncoding(BaseEncoding delegate, String separator, int afterEveryChars) { this.delegate = checkNotNull(delegate); this.separator = checkNotNull(separator); this.afterEveryChars = afterEveryChars; checkArgument( afterEveryChars > 0, "Cannot add a separator after every %s chars", afterEveryChars); } @Override CharSequence trimTrailingPadding(CharSequence chars) { return delegate.trimTrailingPadding(chars); } @Override int maxEncodedSize(int bytes) { int unseparatedSize = delegate.maxEncodedSize(bytes); return unseparatedSize + separator.length() * divide(Math.max(0, unseparatedSize - 1), afterEveryChars, FLOOR); } @GwtIncompatible // Writer,OutputStream @Override public OutputStream encodingStream(final Writer output) { return delegate.encodingStream(separatingWriter(output, separator, afterEveryChars)); } @Override void encodeTo(Appendable target, byte[] bytes, int off, int len) throws IOException { delegate.encodeTo(separatingAppendable(target, separator, afterEveryChars), bytes, off, len); } @Override int maxDecodedSize(int chars) { return delegate.maxDecodedSize(chars); } @Override public boolean canDecode(CharSequence chars) { StringBuilder builder = new StringBuilder(); for (int i = 0; i < chars.length(); i++) { char c = chars.charAt(i); if (separator.indexOf(c) < 0) { builder.append(c); } } return delegate.canDecode(builder); } @Override int decodeTo(byte[] target, CharSequence chars) throws DecodingException { StringBuilder stripped = new StringBuilder(chars.length()); for (int i = 0; i < chars.length(); i++) { char c = chars.charAt(i); if (separator.indexOf(c) < 0) { stripped.append(c); } } return delegate.decodeTo(target, stripped); } @Override @GwtIncompatible // Reader,InputStream public InputStream decodingStream(final Reader reader) { return delegate.decodingStream(ignoringReader(reader, separator)); } @Override public BaseEncoding omitPadding() { return delegate.omitPadding().withSeparator(separator, afterEveryChars); } @Override public BaseEncoding withPadChar(char padChar) { return delegate.withPadChar(padChar).withSeparator(separator, afterEveryChars); } @Override public BaseEncoding withSeparator(String separator, int afterEveryChars) { throw new UnsupportedOperationException("Already have a separator"); } @Override public BaseEncoding upperCase() { return delegate.upperCase().withSeparator(separator, afterEveryChars); } @Override public BaseEncoding lowerCase() { return delegate.lowerCase().withSeparator(separator, afterEveryChars); } @Override public String toString() { return delegate + ".withSeparator(\"" + separator + "\", " + afterEveryChars + ")"; } } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy