Edit
kc3-lang/brotli/java/dec/Huffman.java
Eugene Kliuchnikov
- java/dec/Huffman.java
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/* Copyright 2015 Google Inc. All Rights Reserved. Distributed under MIT license. See file LICENSE for detail or copy at https://opensource.org/licenses/MIT */ package org.brotli.dec; /** * Utilities for building Huffman decoding tables. */ final class Huffman { /** * Maximum possible Huffman table size for an alphabet size of 704, max code length 15 and root * table bits 8. */ static final int HUFFMAN_MAX_TABLE_SIZE = 1080; private static final int MAX_LENGTH = 15; /** * Returns reverse(reverse(key, len) + 1, len). * * <p> reverse(key, len) is the bit-wise reversal of the len least significant bits of key. */ private static int getNextKey(int key, int len) { int step = 1 << (len - 1); while ((key & step) != 0) { step >>= 1; } return (key & (step - 1)) + step; } /** * Stores {@code item} in {@code table[0], table[step], table[2 * step] .., table[end]}. * * <p> Assumes that end is an integer multiple of step. */ private static void replicateValue(int[] table, int offset, int step, int end, int item) { do { end -= step; table[offset + end] = item; } while (end > 0); } /** * @param count histogram of bit lengths for the remaining symbols, * @param len code length of the next processed symbol. * @return table width of the next 2nd level table. */ private static int nextTableBitSize(int[] count, int len, int rootBits) { int left = 1 << (len - rootBits); while (len < MAX_LENGTH) { left -= count[len]; if (left <= 0) { break; } len++; left <<= 1; } return len - rootBits; } /** * Builds Huffman lookup table assuming code lengths are in symbol order. */ static void buildHuffmanTable(int[] rootTable, int tableOffset, int rootBits, int[] codeLengths, int codeLengthsSize) { int key; // Reversed prefix code. int[] sorted = new int[codeLengthsSize]; // Symbols sorted by code length. // TODO: fill with zeroes? int[] count = new int[MAX_LENGTH + 1]; // Number of codes of each length. int[] offset = new int[MAX_LENGTH + 1]; // Offsets in sorted table for each length. int symbol; // Build histogram of code lengths. for (symbol = 0; symbol < codeLengthsSize; symbol++) { count[codeLengths[symbol]]++; } // Generate offsets into sorted symbol table by code length. offset[1] = 0; for (int len = 1; len < MAX_LENGTH; len++) { offset[len + 1] = offset[len] + count[len]; } // Sort symbols by length, by symbol order within each length. for (symbol = 0; symbol < codeLengthsSize; symbol++) { if (codeLengths[symbol] != 0) { sorted[offset[codeLengths[symbol]]++] = symbol; } } int tableBits = rootBits; int tableSize = 1 << tableBits; int totalSize = tableSize; // Special case code with only one value. if (offset[MAX_LENGTH] == 1) { for (key = 0; key < totalSize; key++) { rootTable[tableOffset + key] = sorted[0]; } return; } // Fill in root table. key = 0; symbol = 0; for (int len = 1, step = 2; len <= rootBits; len++, step <<= 1) { for (; count[len] > 0; count[len]--) { replicateValue(rootTable, tableOffset + key, step, tableSize, len << 16 | sorted[symbol++]); key = getNextKey(key, len); } } // Fill in 2nd level tables and add pointers to root table. int mask = totalSize - 1; int low = -1; int currentOffset = tableOffset; for (int len = rootBits + 1, step = 2; len <= MAX_LENGTH; len++, step <<= 1) { for (; count[len] > 0; count[len]--) { if ((key & mask) != low) { currentOffset += tableSize; tableBits = nextTableBitSize(count, len, rootBits); tableSize = 1 << tableBits; totalSize += tableSize; low = key & mask; rootTable[tableOffset + low] = (tableBits + rootBits) << 16 | (currentOffset - tableOffset - low); } replicateValue(rootTable, currentOffset + (key >> rootBits), step, tableSize, (len - rootBits) << 16 | sorted[symbol++]); key = getNextKey(key, len); } } } }