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// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc.  All rights reserved.
// http://code.google.com/p/protobuf/
//
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// modification, are permitted provided that the following conditions are
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//
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// notice, this list of conditions and the following disclaimer.
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package com.facebook.presto.orc.protobuf;

import java.io.ByteArrayOutputStream;
import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.io.UnsupportedEncodingException;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Iterator;
import java.util.List;
import java.util.NoSuchElementException;

/**
 * Immutable sequence of bytes.  Substring is supported by sharing the reference
 * to the immutable underlying bytes, as with {@link String}.  Concatenation is
 * likewise supported without copying (long strings) by building a tree of
 * pieces in {@link RopeByteString}.
 * 

* Like {@link String}, the contents of a {@link ByteString} can never be * observed to change, not even in the presence of a data race or incorrect * API usage in the client code. * * @author [email protected] Bob Lee * @author [email protected] Kenton Varda * @author [email protected] Carl Haverl * @author [email protected] Martin Buchholz */ public abstract class ByteString implements Iterable { /** * When two strings to be concatenated have a combined length shorter than * this, we just copy their bytes on {@link #concat(ByteString)}. * The trade-off is copy size versus the overhead of creating tree nodes * in {@link RopeByteString}. */ static final int CONCATENATE_BY_COPY_SIZE = 128; /** * When copying an InputStream into a ByteString with .readFrom(), * the chunks in the underlying rope start at 256 bytes, but double * each iteration up to 8192 bytes. */ static final int MIN_READ_FROM_CHUNK_SIZE = 0x100; // 256b static final int MAX_READ_FROM_CHUNK_SIZE = 0x2000; // 8k /** * Empty {@code ByteString}. */ public static final ByteString EMPTY = new LiteralByteString(new byte[0]); // This constructor is here to prevent subclassing outside of this package, ByteString() {} /** * Gets the byte at the given index. This method should be used only for * random access to individual bytes. To access bytes sequentially, use the * {@link ByteIterator} returned by {@link #iterator()}, and call {@link * #substring(int, int)} first if necessary. * * @param index index of byte * @return the value * @throws ArrayIndexOutOfBoundsException {@code index} is < 0 or >= size */ public abstract byte byteAt(int index); /** * Return a {@link ByteString.ByteIterator} over the bytes in the ByteString. * To avoid auto-boxing, you may get the iterator manually and call * {@link ByteIterator#nextByte()}. * * @return the iterator */ public abstract ByteIterator iterator(); /** * This interface extends {@code Iterator}, so that we can return an * unboxed {@code byte}. */ public interface ByteIterator extends Iterator { /** * An alternative to {@link Iterator#next()} that returns an * unboxed primitive {@code byte}. * * @return the next {@code byte} in the iteration * @throws NoSuchElementException if the iteration has no more elements */ byte nextByte(); } /** * Gets the number of bytes. * * @return size in bytes */ public abstract int size(); /** * Returns {@code true} if the size is {@code 0}, {@code false} otherwise. * * @return true if this is zero bytes long */ public boolean isEmpty() { return size() == 0; } // ================================================================= // ByteString -> substring /** * Return the substring from {@code beginIndex}, inclusive, to the end of the * string. * * @param beginIndex start at this index * @return substring sharing underlying data * @throws IndexOutOfBoundsException if {@code beginIndex < 0} or * {@code beginIndex > size()}. */ public ByteString substring(int beginIndex) { return substring(beginIndex, size()); } /** * Return the substring from {@code beginIndex}, inclusive, to {@code * endIndex}, exclusive. * * @param beginIndex start at this index * @param endIndex the last character is the one before this index * @return substring sharing underlying data * @throws IndexOutOfBoundsException if {@code beginIndex < 0}, * {@code endIndex > size()}, or {@code beginIndex > endIndex}. */ public abstract ByteString substring(int beginIndex, int endIndex); /** * Tests if this bytestring starts with the specified prefix. * Similar to {@link String#startsWith(String)} * * @param prefix the prefix. * @return true if the byte sequence represented by the * argument is a prefix of the byte sequence represented by * this string; false otherwise. */ public boolean startsWith(ByteString prefix) { return size() >= prefix.size() && substring(0, prefix.size()).equals(prefix); } // ================================================================= // byte[] -> ByteString /** * Copies the given bytes into a {@code ByteString}. * * @param bytes source array * @param offset offset in source array * @param size number of bytes to copy * @return new {@code ByteString} */ public static ByteString copyFrom(byte[] bytes, int offset, int size) { byte[] copy = new byte[size]; System.arraycopy(bytes, offset, copy, 0, size); return new LiteralByteString(copy); } /** * Copies the given bytes into a {@code ByteString}. * * @param bytes to copy * @return new {@code ByteString} */ public static ByteString copyFrom(byte[] bytes) { return copyFrom(bytes, 0, bytes.length); } /** * Copies the next {@code size} bytes from a {@code java.nio.ByteBuffer} into * a {@code ByteString}. * * @param bytes source buffer * @param size number of bytes to copy * @return new {@code ByteString} */ public static ByteString copyFrom(ByteBuffer bytes, int size) { byte[] copy = new byte[size]; bytes.get(copy); return new LiteralByteString(copy); } /** * Copies the remaining bytes from a {@code java.nio.ByteBuffer} into * a {@code ByteString}. * * @param bytes sourceBuffer * @return new {@code ByteString} */ public static ByteString copyFrom(ByteBuffer bytes) { return copyFrom(bytes, bytes.remaining()); } /** * Encodes {@code text} into a sequence of bytes using the named charset * and returns the result as a {@code ByteString}. * * @param text source string * @param charsetName encoding to use * @return new {@code ByteString} * @throws UnsupportedEncodingException if the encoding isn't found */ public static ByteString copyFrom(String text, String charsetName) throws UnsupportedEncodingException { return new LiteralByteString(text.getBytes(charsetName)); } /** * Encodes {@code text} into a sequence of UTF-8 bytes and returns the * result as a {@code ByteString}. * * @param text source string * @return new {@code ByteString} */ public static ByteString copyFromUtf8(String text) { try { return new LiteralByteString(text.getBytes("UTF-8")); } catch (UnsupportedEncodingException e) { throw new RuntimeException("UTF-8 not supported?", e); } } // ================================================================= // InputStream -> ByteString /** * Completely reads the given stream's bytes into a * {@code ByteString}, blocking if necessary until all bytes are * read through to the end of the stream. * * Performance notes: The returned {@code ByteString} is an * immutable tree of byte arrays ("chunks") of the stream data. The * first chunk is small, with subsequent chunks each being double * the size, up to 8K. If the caller knows the precise length of * the stream and wishes to avoid all unnecessary copies and * allocations, consider using the two-argument version of this * method, below. * * @param streamToDrain The source stream, which is read completely * but not closed. * @return A new {@code ByteString} which is made up of chunks of * various sizes, depending on the behavior of the underlying * stream. * @throws IOException IOException is thrown if there is a problem * reading the underlying stream. */ public static ByteString readFrom(InputStream streamToDrain) throws IOException { return readFrom( streamToDrain, MIN_READ_FROM_CHUNK_SIZE, MAX_READ_FROM_CHUNK_SIZE); } /** * Completely reads the given stream's bytes into a * {@code ByteString}, blocking if necessary until all bytes are * read through to the end of the stream. * * Performance notes: The returned {@code ByteString} is an * immutable tree of byte arrays ("chunks") of the stream data. The * chunkSize parameter sets the size of these byte arrays. In * particular, if the chunkSize is precisely the same as the length * of the stream, unnecessary allocations and copies will be * avoided. Otherwise, the chunks will be of the given size, except * for the last chunk, which will be resized (via a reallocation and * copy) to contain the remainder of the stream. * * @param streamToDrain The source stream, which is read completely * but not closed. * @param chunkSize The size of the chunks in which to read the * stream. * @return A new {@code ByteString} which is made up of chunks of * the given size. * @throws IOException IOException is thrown if there is a problem * reading the underlying stream. */ public static ByteString readFrom(InputStream streamToDrain, int chunkSize) throws IOException { return readFrom(streamToDrain, chunkSize, chunkSize); } // Helper method that takes the chunk size range as a parameter. public static ByteString readFrom(InputStream streamToDrain, int minChunkSize, int maxChunkSize) throws IOException { Collection results = new ArrayList(); // copy the inbound bytes into a list of chunks; the chunk size // grows exponentially to support both short and long streams. int chunkSize = minChunkSize; while (true) { ByteString chunk = readChunk(streamToDrain, chunkSize); if (chunk == null) { break; } results.add(chunk); chunkSize = Math.min(chunkSize * 2, maxChunkSize); } return ByteString.copyFrom(results); } /** * Blocks until a chunk of the given size can be made from the * stream, or EOF is reached. Calls read() repeatedly in case the * given stream implementation doesn't completely fill the given * buffer in one read() call. * * @return A chunk of the desired size, or else a chunk as large as * was available when end of stream was reached. Returns null if the * given stream had no more data in it. */ private static ByteString readChunk(InputStream in, final int chunkSize) throws IOException { final byte[] buf = new byte[chunkSize]; int bytesRead = 0; while (bytesRead < chunkSize) { final int count = in.read(buf, bytesRead, chunkSize - bytesRead); if (count == -1) { break; } bytesRead += count; } if (bytesRead == 0) { return null; } else { return ByteString.copyFrom(buf, 0, bytesRead); } } // ================================================================= // Multiple ByteStrings -> One ByteString /** * Concatenate the given {@code ByteString} to this one. Short concatenations, * of total size smaller than {@link ByteString#CONCATENATE_BY_COPY_SIZE}, are * produced by copying the underlying bytes (as per Rope.java, * BAP95 . In general, the concatenate involves no copying. * * @param other string to concatenate * @return a new {@code ByteString} instance */ public ByteString concat(ByteString other) { int thisSize = size(); int otherSize = other.size(); if ((long) thisSize + otherSize >= Integer.MAX_VALUE) { throw new IllegalArgumentException("ByteString would be too long: " + thisSize + "+" + otherSize); } return RopeByteString.concatenate(this, other); } /** * Concatenates all byte strings in the iterable and returns the result. * This is designed to run in O(list size), not O(total bytes). * *

The returned {@code ByteString} is not necessarily a unique object. * If the list is empty, the returned object is the singleton empty * {@code ByteString}. If the list has only one element, that * {@code ByteString} will be returned without copying. * * @param byteStrings strings to be concatenated * @return new {@code ByteString} */ public static ByteString copyFrom(Iterable byteStrings) { Collection collection; if (!(byteStrings instanceof Collection)) { collection = new ArrayList(); for (ByteString byteString : byteStrings) { collection.add(byteString); } } else { collection = (Collection) byteStrings; } ByteString result; if (collection.isEmpty()) { result = EMPTY; } else { result = balancedConcat(collection.iterator(), collection.size()); } return result; } // Internal function used by copyFrom(Iterable). // Create a balanced concatenation of the next "length" elements from the // iterable. private static ByteString balancedConcat(Iterator iterator, int length) { assert length >= 1; ByteString result; if (length == 1) { result = iterator.next(); } else { int halfLength = length >>> 1; ByteString left = balancedConcat(iterator, halfLength); ByteString right = balancedConcat(iterator, length - halfLength); result = left.concat(right); } return result; } // ================================================================= // ByteString -> byte[] /** * Copies bytes into a buffer at the given offset. * * @param target buffer to copy into * @param offset in the target buffer * @throws IndexOutOfBoundsException if the offset is negative or too large */ public void copyTo(byte[] target, int offset) { copyTo(target, 0, offset, size()); } /** * Copies bytes into a buffer. * * @param target buffer to copy into * @param sourceOffset offset within these bytes * @param targetOffset offset within the target buffer * @param numberToCopy number of bytes to copy * @throws IndexOutOfBoundsException if an offset or size is negative or too * large */ public void copyTo(byte[] target, int sourceOffset, int targetOffset, int numberToCopy) { if (sourceOffset < 0) { throw new IndexOutOfBoundsException("Source offset < 0: " + sourceOffset); } if (targetOffset < 0) { throw new IndexOutOfBoundsException("Target offset < 0: " + targetOffset); } if (numberToCopy < 0) { throw new IndexOutOfBoundsException("Length < 0: " + numberToCopy); } if (sourceOffset + numberToCopy > size()) { throw new IndexOutOfBoundsException( "Source end offset < 0: " + (sourceOffset + numberToCopy)); } if (targetOffset + numberToCopy > target.length) { throw new IndexOutOfBoundsException( "Target end offset < 0: " + (targetOffset + numberToCopy)); } if (numberToCopy > 0) { copyToInternal(target, sourceOffset, targetOffset, numberToCopy); } } /** * Internal (package private) implementation of * @link{#copyTo(byte[],int,int,int}. * It assumes that all error checking has already been performed and that * @code{numberToCopy > 0}. */ protected abstract void copyToInternal(byte[] target, int sourceOffset, int targetOffset, int numberToCopy); /** * Copies bytes into a ByteBuffer. * * @param target ByteBuffer to copy into. * @throws java.nio.ReadOnlyBufferException if the {@code target} is read-only * @throws java.nio.BufferOverflowException if the {@code target}'s * remaining() space is not large enough to hold the data. */ public abstract void copyTo(ByteBuffer target); /** * Copies bytes to a {@code byte[]}. * * @return copied bytes */ public byte[] toByteArray() { int size = size(); byte[] result = new byte[size]; copyToInternal(result, 0, 0, size); return result; } /** * Writes the complete contents of this byte string to * the specified output stream argument. * * @param out the output stream to which to write the data. * @throws IOException if an I/O error occurs. */ public abstract void writeTo(OutputStream out) throws IOException; /** * Constructs a read-only {@code java.nio.ByteBuffer} whose content * is equal to the contents of this byte string. * The result uses the same backing array as the byte string, if possible. * * @return wrapped bytes */ public abstract ByteBuffer asReadOnlyByteBuffer(); /** * Constructs a list of read-only {@code java.nio.ByteBuffer} objects * such that the concatenation of their contents is equal to the contents * of this byte string. The result uses the same backing arrays as the * byte string. *

* By returning a list, implementations of this method may be able to avoid * copying even when there are multiple backing arrays. * * @return a list of wrapped bytes */ public abstract List asReadOnlyByteBufferList(); /** * Constructs a new {@code String} by decoding the bytes using the * specified charset. * * @param charsetName encode using this charset * @return new string * @throws UnsupportedEncodingException if charset isn't recognized */ public abstract String toString(String charsetName) throws UnsupportedEncodingException; // ================================================================= // UTF-8 decoding /** * Constructs a new {@code String} by decoding the bytes as UTF-8. * * @return new string using UTF-8 encoding */ public String toStringUtf8() { try { return toString("UTF-8"); } catch (UnsupportedEncodingException e) { throw new RuntimeException("UTF-8 not supported?", e); } } /** * Tells whether this {@code ByteString} represents a well-formed UTF-8 * byte sequence, such that the original bytes can be converted to a * String object and then round tripped back to bytes without loss. * *

More precisely, returns {@code true} whenever:

 {@code
   * Arrays.equals(byteString.toByteArray(),
   *     new String(byteString.toByteArray(), "UTF-8").getBytes("UTF-8"))
   * }
* *

This method returns {@code false} for "overlong" byte sequences, * as well as for 3-byte sequences that would map to a surrogate * character, in accordance with the restricted definition of UTF-8 * introduced in Unicode 3.1. Note that the UTF-8 decoder included in * Oracle's JDK has been modified to also reject "overlong" byte * sequences, but (as of 2011) still accepts 3-byte surrogate * character byte sequences. * *

See the Unicode Standard,
* Table 3-6. UTF-8 Bit Distribution,
* Table 3-7. Well Formed UTF-8 Byte Sequences. * * @return whether the bytes in this {@code ByteString} are a * well-formed UTF-8 byte sequence */ public abstract boolean isValidUtf8(); /** * Tells whether the given byte sequence is a well-formed, malformed, or * incomplete UTF-8 byte sequence. This method accepts and returns a partial * state result, allowing the bytes for a complete UTF-8 byte sequence to be * composed from multiple {@code ByteString} segments. * * @param state either {@code 0} (if this is the initial decoding operation) * or the value returned from a call to a partial decoding method for the * previous bytes * @param offset offset of the first byte to check * @param length number of bytes to check * * @return {@code -1} if the partial byte sequence is definitely malformed, * {@code 0} if it is well-formed (no additional input needed), or, if the * byte sequence is "incomplete", i.e. apparently terminated in the middle of * a character, an opaque integer "state" value containing enough information * to decode the character when passed to a subsequent invocation of a * partial decoding method. */ protected abstract int partialIsValidUtf8(int state, int offset, int length); // ================================================================= // equals() and hashCode() @Override public abstract boolean equals(Object o); /** * Return a non-zero hashCode depending only on the sequence of bytes * in this ByteString. * * @return hashCode value for this object */ @Override public abstract int hashCode(); // ================================================================= // Input stream /** * Creates an {@code InputStream} which can be used to read the bytes. *

* The {@link InputStream} returned by this method is guaranteed to be * completely non-blocking. The method {@link InputStream#available()} * returns the number of bytes remaining in the stream. The methods * {@link InputStream#read(byte[]), {@link InputStream#read(byte[],int,int)} * and {@link InputStream#skip(long)} will read/skip as many bytes as are * available. *

* The methods in the returned {@link InputStream} might not be * thread safe. * * @return an input stream that returns the bytes of this byte string. */ public abstract InputStream newInput(); /** * Creates a {@link CodedInputStream} which can be used to read the bytes. * Using this is often more efficient than creating a {@link CodedInputStream} * that wraps the result of {@link #newInput()}. * * @return stream based on wrapped data */ public abstract CodedInputStream newCodedInput(); // ================================================================= // Output stream /** * Creates a new {@link Output} with the given initial capacity. Call {@link * Output#toByteString()} to create the {@code ByteString} instance. *

* A {@link ByteString.Output} offers the same functionality as a * {@link ByteArrayOutputStream}, except that it returns a {@link ByteString} * rather than a {@code byte} array. * * @param initialCapacity estimate of number of bytes to be written * @return {@code OutputStream} for building a {@code ByteString} */ public static Output newOutput(int initialCapacity) { return new Output(initialCapacity); } /** * Creates a new {@link Output}. Call {@link Output#toByteString()} to create * the {@code ByteString} instance. *

* A {@link ByteString.Output} offers the same functionality as a * {@link ByteArrayOutputStream}, except that it returns a {@link ByteString} * rather than a {@code byte array}. * * @return {@code OutputStream} for building a {@code ByteString} */ public static Output newOutput() { return new Output(CONCATENATE_BY_COPY_SIZE); } /** * Outputs to a {@code ByteString} instance. Call {@link #toByteString()} to * create the {@code ByteString} instance. */ public static final class Output extends OutputStream { // Implementation note. // The public methods of this class must be synchronized. ByteStrings // are guaranteed to be immutable. Without some sort of locking, it could // be possible for one thread to call toByteSring(), while another thread // is still modifying the underlying byte array. private static final byte[] EMPTY_BYTE_ARRAY = new byte[0]; // argument passed by user, indicating initial capacity. private final int initialCapacity; // ByteStrings to be concatenated to create the result private final ArrayList flushedBuffers; // Total number of bytes in the ByteStrings of flushedBuffers private int flushedBuffersTotalBytes; // Current buffer to which we are writing private byte[] buffer; // Location in buffer[] to which we write the next byte. private int bufferPos; /** * Creates a new ByteString output stream with the specified * initial capacity. * * @param initialCapacity the initial capacity of the output stream. */ Output(int initialCapacity) { if (initialCapacity < 0) { throw new IllegalArgumentException("Buffer size < 0"); } this.initialCapacity = initialCapacity; this.flushedBuffers = new ArrayList(); this.buffer = new byte[initialCapacity]; } @Override public synchronized void write(int b) { if (bufferPos == buffer.length) { flushFullBuffer(1); } buffer[bufferPos++] = (byte)b; } @Override public synchronized void write(byte[] b, int offset, int length) { if (length <= buffer.length - bufferPos) { // The bytes can fit into the current buffer. System.arraycopy(b, offset, buffer, bufferPos, length); bufferPos += length; } else { // Use up the current buffer int copySize = buffer.length - bufferPos; System.arraycopy(b, offset, buffer, bufferPos, copySize); offset += copySize; length -= copySize; // Flush the buffer, and get a new buffer at least big enough to cover // what we still need to output flushFullBuffer(length); System.arraycopy(b, offset, buffer, 0 /* count */, length); bufferPos = length; } } /** * Creates a byte string. Its size is the current size of this output * stream and its output has been copied to it. * * @return the current contents of this output stream, as a byte string. */ public synchronized ByteString toByteString() { flushLastBuffer(); return ByteString.copyFrom(flushedBuffers); } /** * Implement java.util.Arrays.copyOf() for jdk 1.5. */ private byte[] copyArray(byte[] buffer, int length) { byte[] result = new byte[length]; System.arraycopy(buffer, 0, result, 0, Math.min(buffer.length, length)); return result; } /** * Writes the complete contents of this byte array output stream to * the specified output stream argument. * * @param out the output stream to which to write the data. * @throws IOException if an I/O error occurs. */ public void writeTo(OutputStream out) throws IOException { ByteString[] cachedFlushBuffers; byte[] cachedBuffer; int cachedBufferPos; synchronized (this) { // Copy the information we need into local variables so as to hold // the lock for as short a time as possible. cachedFlushBuffers = flushedBuffers.toArray(new ByteString[flushedBuffers.size()]); cachedBuffer = buffer; cachedBufferPos = bufferPos; } for (ByteString byteString : cachedFlushBuffers) { byteString.writeTo(out); } out.write(copyArray(cachedBuffer, cachedBufferPos)); } /** * Returns the current size of the output stream. * * @return the current size of the output stream */ public synchronized int size() { return flushedBuffersTotalBytes + bufferPos; } /** * Resets this stream, so that all currently accumulated output in the * output stream is discarded. The output stream can be used again, * reusing the already allocated buffer space. */ public synchronized void reset() { flushedBuffers.clear(); flushedBuffersTotalBytes = 0; bufferPos = 0; } @Override public String toString() { return String.format("", Integer.toHexString(System.identityHashCode(this)), size()); } /** * Internal function used by writers. The current buffer is full, and the * writer needs a new buffer whose size is at least the specified minimum * size. */ private void flushFullBuffer(int minSize) { flushedBuffers.add(new LiteralByteString(buffer)); flushedBuffersTotalBytes += buffer.length; // We want to increase our total capacity by 50%, but as a minimum, // the new buffer should also at least be >= minSize and // >= initial Capacity. int newSize = Math.max(initialCapacity, Math.max(minSize, flushedBuffersTotalBytes >>> 1)); buffer = new byte[newSize]; bufferPos = 0; } /** * Internal function used by {@link #toByteString()}. The current buffer may * or may not be full, but it needs to be flushed. */ private void flushLastBuffer() { if (bufferPos < buffer.length) { if (bufferPos > 0) { byte[] bufferCopy = copyArray(buffer, bufferPos); flushedBuffers.add(new LiteralByteString(bufferCopy)); } // We reuse this buffer for further writes. } else { // Buffer is completely full. Huzzah. flushedBuffers.add(new LiteralByteString(buffer)); // 99% of the time, we're not going to use this OutputStream again. // We set buffer to an empty byte stream so that we're handling this // case without wasting space. In the rare case that more writes // *do* occur, this empty buffer will be flushed and an appropriately // sized new buffer will be created. buffer = EMPTY_BYTE_ARRAY; } flushedBuffersTotalBytes += bufferPos; bufferPos = 0; } } /** * Constructs a new {@code ByteString} builder, which allows you to * efficiently construct a {@code ByteString} by writing to a {@link * CodedOutputStream}. Using this is much more efficient than calling {@code * newOutput()} and wrapping that in a {@code CodedOutputStream}. * *

This is package-private because it's a somewhat confusing interface. * Users can call {@link Message#toByteString()} instead of calling this * directly. * * @param size The target byte size of the {@code ByteString}. You must write * exactly this many bytes before building the result. * @return the builder */ static CodedBuilder newCodedBuilder(int size) { return new CodedBuilder(size); } /** See {@link ByteString#newCodedBuilder(int)}. */ static final class CodedBuilder { private final CodedOutputStream output; private final byte[] buffer; private CodedBuilder(int size) { buffer = new byte[size]; output = CodedOutputStream.newInstance(buffer); } public ByteString build() { output.checkNoSpaceLeft(); // We can be confident that the CodedOutputStream will not modify the // underlying bytes anymore because it already wrote all of them. So, // no need to make a copy. return new LiteralByteString(buffer); } public CodedOutputStream getCodedOutput() { return output; } } // ================================================================= // Methods {@link RopeByteString} needs on instances, which aren't part of the // public API. /** * Return the depth of the tree representing this {@code ByteString}, if any, * whose root is this node. If this is a leaf node, return 0. * * @return tree depth or zero */ protected abstract int getTreeDepth(); /** * Return {@code true} if this ByteString is literal (a leaf node) or a * flat-enough tree in the sense of {@link RopeByteString}. * * @return true if the tree is flat enough */ protected abstract boolean isBalanced(); /** * Return the cached hash code if available. * * @return value of cached hash code or 0 if not computed yet */ protected abstract int peekCachedHashCode(); /** * Compute the hash across the value bytes starting with the given hash, and * return the result. This is used to compute the hash across strings * represented as a set of pieces by allowing the hash computation to be * continued from piece to piece. * * @param h starting hash value * @param offset offset into this value to start looking at data values * @param length number of data values to include in the hash computation * @return ending hash value */ protected abstract int partialHash(int h, int offset, int length); @Override public String toString() { return String.format("", Integer.toHexString(System.identityHashCode(this)), size()); } }





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