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

com.google.protobuf.Internal Maven / Gradle / Ivy

Go to download

Clarity is an open source replay parser for Dota 2 and CSGO 1 and 2 written in Java. This JAR contains the protobuf classes for clarity.

There is a newer version: 5.3
Show newest version
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc.  All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
//     * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
//     * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

package com.google.protobuf;

import java.io.IOException;
import java.io.UnsupportedEncodingException;
import java.nio.ByteBuffer;
import java.util.Arrays;
import java.util.List;

/**
 * The classes contained within are used internally by the Protocol Buffer
 * library and generated message implementations. They are public only because
 * those generated messages do not reside in the {@code protobuf} package.
 * Others should not use this class directly.
 *
 * @author [email protected] (Kenton Varda)
 */
public class Internal {
  /**
   * Helper called by generated code to construct default values for string
   * fields.
   * 

* The protocol compiler does not actually contain a UTF-8 decoder -- it * just pushes UTF-8-encoded text around without touching it. The one place * where this presents a problem is when generating Java string literals. * Unicode characters in the string literal would normally need to be encoded * using a Unicode escape sequence, which would require decoding them. * To get around this, protoc instead embeds the UTF-8 bytes into the * generated code and leaves it to the runtime library to decode them. *

* It gets worse, though. If protoc just generated a byte array, like: * new byte[] {0x12, 0x34, 0x56, 0x78} * Java actually generates *code* which allocates an array and then fills * in each value. This is much less efficient than just embedding the bytes * directly into the bytecode. To get around this, we need another * work-around. String literals are embedded directly, so protoc actually * generates a string literal corresponding to the bytes. The easiest way * to do this is to use the ISO-8859-1 character set, which corresponds to * the first 256 characters of the Unicode range. Protoc can then use * good old CEscape to generate the string. *

* So we have a string literal which represents a set of bytes which * represents another string. This function -- stringDefaultValue -- * converts from the generated string to the string we actually want. The * generated code calls this automatically. */ public static String stringDefaultValue(String bytes) { try { return new String(bytes.getBytes("ISO-8859-1"), "UTF-8"); } catch (UnsupportedEncodingException e) { // This should never happen since all JVMs are required to implement // both of the above character sets. throw new IllegalStateException( "Java VM does not support a standard character set.", e); } } /** * Helper called by generated code to construct default values for bytes * fields. *

* This is a lot like {@link #stringDefaultValue}, but for bytes fields. * In this case we only need the second of the two hacks -- allowing us to * embed raw bytes as a string literal with ISO-8859-1 encoding. */ public static ByteString bytesDefaultValue(String bytes) { try { return ByteString.copyFrom(bytes.getBytes("ISO-8859-1")); } catch (UnsupportedEncodingException e) { // This should never happen since all JVMs are required to implement // ISO-8859-1. throw new IllegalStateException( "Java VM does not support a standard character set.", e); } } /** * Helper called by generated code to construct default values for bytes * fields. *

* This is like {@link #bytesDefaultValue}, but returns a byte array. */ public static byte[] byteArrayDefaultValue(String bytes) { try { return bytes.getBytes("ISO-8859-1"); } catch (UnsupportedEncodingException e) { // This should never happen since all JVMs are required to implement // ISO-8859-1. throw new IllegalStateException( "Java VM does not support a standard character set.", e); } } /** * Helper called by generated code to construct default values for bytes * fields. *

* This is like {@link #bytesDefaultValue}, but returns a ByteBuffer. */ public static ByteBuffer byteBufferDefaultValue(String bytes) { return ByteBuffer.wrap(byteArrayDefaultValue(bytes)); } /** * Create a new ByteBuffer and copy all the content of {@code source} * ByteBuffer to the new ByteBuffer. The new ByteBuffer's limit and * capacity will be source.capacity(), and its position will be 0. * Note that the state of {@code source} ByteBuffer won't be changed. */ public static ByteBuffer copyByteBuffer(ByteBuffer source) { // Make a duplicate of the source ByteBuffer and read data from the // duplicate. This is to avoid affecting the source ByteBuffer's state. ByteBuffer temp = source.duplicate(); // We want to copy all the data in the source ByteBuffer, not just the // remaining bytes. temp.clear(); ByteBuffer result = ByteBuffer.allocate(temp.capacity()); result.put(temp); result.clear(); return result; } /** * Helper called by generated code to determine if a byte array is a valid * UTF-8 encoded string such that the original bytes can be converted to * a String object and then back to a byte array round tripping the 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 rejects "overlong" byte sequences, as well as * 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 currently (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. * *

As of 2011-02, this method simply returns the result of {@link * ByteString#isValidUtf8()}. Calling that method directly is preferred. * * @param byteString the string to check * @return whether the byte array is round trippable */ public static boolean isValidUtf8(ByteString byteString) { return byteString.isValidUtf8(); } /** * Like {@link #isValidUtf8(ByteString)} but for byte arrays. */ public static boolean isValidUtf8(byte[] byteArray) { return Utf8.isValidUtf8(byteArray); } /** * Helper method to get the UTF-8 bytes of a string. */ public static byte[] toByteArray(String value) { try { return value.getBytes("UTF-8"); } catch (UnsupportedEncodingException e) { throw new RuntimeException("UTF-8 not supported?", e); } } /** * Helper method to convert a byte array to a string using UTF-8 encoding. */ public static String toStringUtf8(byte[] bytes) { try { return new String(bytes, "UTF-8"); } catch (UnsupportedEncodingException e) { throw new RuntimeException("UTF-8 not supported?", e); } } /** * Interface for an enum value or value descriptor, to be used in FieldSet. * The lite library stores enum values directly in FieldSets but the full * library stores EnumValueDescriptors in order to better support reflection. */ public interface EnumLite { int getNumber(); } /** * Interface for an object which maps integers to {@link EnumLite}s. * {@link Descriptors.EnumDescriptor} implements this interface by mapping * numbers to {@link Descriptors.EnumValueDescriptor}s. Additionally, * every generated enum type has a static method internalGetValueMap() which * returns an implementation of this type that maps numbers to enum values. */ public interface EnumLiteMap { T findValueByNumber(int number); } /** * Helper method for implementing {@link MessageLite#hashCode()} for longs. * @see Long#hashCode() */ public static int hashLong(long n) { return (int) (n ^ (n >>> 32)); } /** * Helper method for implementing {@link MessageLite#hashCode()} for * booleans. * @see Boolean#hashCode() */ public static int hashBoolean(boolean b) { return b ? 1231 : 1237; } /** * Helper method for implementing {@link MessageLite#hashCode()} for enums. *

* This is needed because {@link java.lang.Enum#hashCode()} is final, but we * need to use the field number as the hash code to ensure compatibility * between statically and dynamically generated enum objects. */ public static int hashEnum(EnumLite e) { return e.getNumber(); } /** * Helper method for implementing {@link MessageLite#hashCode()} for * enum lists. */ public static int hashEnumList(List list) { int hash = 1; for (EnumLite e : list) { hash = 31 * hash + hashEnum(e); } return hash; } /** * Helper method for implementing {@link MessageLite#equals()} for bytes field. */ public static boolean equals(List a, List b) { if (a.size() != b.size()) return false; for (int i = 0; i < a.size(); ++i) { if (!Arrays.equals(a.get(i), b.get(i))) { return false; } } return true; } /** * Helper method for implementing {@link MessageLite#hashCode()} for bytes field. */ public static int hashCode(List list) { int hash = 1; for (byte[] bytes : list) { hash = 31 * hash + hashCode(bytes); } return hash; } /** * Helper method for implementing {@link MessageLite#hashCode()} for bytes field. */ public static int hashCode(byte[] bytes) { // The hash code for a byte array should be the same as the hash code for a // ByteString with the same content. This is to ensure that the generated // hashCode() method will return the same value as the pure reflection // based hashCode() method. return LiteralByteString.hashCode(bytes); } /** * Helper method for implementing {@link MessageLite#equals()} for bytes * field. */ public static boolean equalsByteBuffer(ByteBuffer a, ByteBuffer b) { if (a.capacity() != b.capacity()) { return false; } // ByteBuffer.equals() will only compare the remaining bytes, but we want to // compare all the content. return a.duplicate().clear().equals(b.duplicate().clear()); } /** * Helper method for implementing {@link MessageLite#equals()} for bytes * field. */ public static boolean equalsByteBuffer( List a, List b) { if (a.size() != b.size()) { return false; } for (int i = 0; i < a.size(); ++i) { if (!equalsByteBuffer(a.get(i), b.get(i))) { return false; } } return true; } /** * Helper method for implementing {@link MessageLite#hashCode()} for bytes * field. */ public static int hashCodeByteBuffer(List list) { int hash = 1; for (ByteBuffer bytes : list) { hash = 31 * hash + hashCodeByteBuffer(bytes); } return hash; } private static final int DEFAULT_BUFFER_SIZE = 4096; /** * Helper method for implementing {@link MessageLite#hashCode()} for bytes * field. */ public static int hashCodeByteBuffer(ByteBuffer bytes) { if (bytes.hasArray()) { // Fast path. int h = LiteralByteString.hashCode(bytes.capacity(), bytes.array(), bytes.arrayOffset(), bytes.capacity()); return h == 0 ? 1 : h; } else { // Read the data into a temporary byte array before calculating the // hash value. final int bufferSize = bytes.capacity() > DEFAULT_BUFFER_SIZE ? DEFAULT_BUFFER_SIZE : bytes.capacity(); final byte[] buffer = new byte[bufferSize]; final ByteBuffer duplicated = bytes.duplicate(); duplicated.clear(); int h = bytes.capacity(); while (duplicated.remaining() > 0) { final int length = duplicated.remaining() <= bufferSize ? duplicated.remaining() : bufferSize; duplicated.get(buffer, 0, length); h = LiteralByteString.hashCode(h, buffer, 0, length); } return h == 0 ? 1 : h; } } /** * An empty byte array constant used in generated code. */ public static final byte[] EMPTY_BYTE_ARRAY = new byte[0]; /** * An empty byte array constant used in generated code. */ public static final ByteBuffer EMPTY_BYTE_BUFFER = ByteBuffer.wrap(EMPTY_BYTE_ARRAY); }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy