+++ /dev/null
-/*
- * decomp.c
- *
- * Functions used for decompression.
- */
-
-/*
- * Copyright (C) 2012 Eric Biggers
- *
- * This file is part of wimlib, a library for working with WIM files.
- *
- * wimlib is free software; you can redistribute it and/or modify it under the
- * terms of the GNU General Public License as published by the Free
- * Software Foundation; either version 3 of the License, or (at your option)
- * any later version.
- *
- * wimlib is distributed in the hope that it will be useful, but WITHOUT ANY
- * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
- * A PARTICULAR PURPOSE. See the GNU General Public License for more
- * details.
- *
- * You should have received a copy of the GNU General Public License
- * along with wimlib; if not, see http://www.gnu.org/licenses/.
- */
-
-#include "decomp.h"
-#include <string.h>
-
-/* Reads @n bytes from the bitstream @stream into the location pointed to by @dest.
- * The bitstream must be 16-bit aligned. */
-int bitstream_read_bytes(struct input_bitstream *stream, size_t n, void *dest)
-{
- /* Precondition: The bitstream is 16-byte aligned. */
- wimlib_assert(stream->bitsleft % 16 == 0);
-
- u8 *p = dest;
-
- /* Get the bytes currently in the buffer variable. */
- while (stream->bitsleft != 0) {
- if (n-- == 0)
- return 0;
- *p++ = bitstream_peek_bits(stream, 8);
- bitstream_remove_bits(stream, 8);
- }
-
- /* Get the rest directly from the pointer to the data. Of course, it's
- * necessary to check there are really n bytes available. */
- if (n > stream->data_bytes_left) {
- ERROR("Unexpected end of input when reading %zu bytes from "
- "bitstream (only have %u bytes left)",
- n, stream->data_bytes_left);
- return 1;
- }
- memcpy(p, stream->data, n);
- stream->data += n;
- stream->data_bytes_left -= n;
-
- /* It's possible to copy an odd number of bytes and leave the stream in
- * an inconsistent state. Fix it by reading the next byte, if it is
- * there. */
- if ((n & 1) && stream->data_bytes_left != 0) {
- stream->bitsleft = 8;
- stream->data_bytes_left--;
- stream->bitbuf |= (input_bitbuf_t)(*stream->data) <<
- (sizeof(input_bitbuf_t) * 8 - 8);
- stream->data++;
- }
- return 0;
-}
-
-/* Aligns the bitstream on a 16-bit boundary.
- *
- * Note: M$'s idea of "alignment" means that for some reason, a 16-bit word
- * should be skipped over if the buffer happens to already be aligned on such a
- * boundary. This only applies for realigning the stream after the blocktype
- * and length fields of an uncompressed block, however; it does not apply when
- * realigning the stream after the end of the uncompressed block.
- */
-int align_input_bitstream(struct input_bitstream *stream,
- bool skip_word_if_aligned)
-{
- int ret;
- if (stream->bitsleft % 16 != 0) {
- bitstream_remove_bits(stream, stream->bitsleft % 16);
- } else if (skip_word_if_aligned) {
- if (stream->bitsleft == 0) {
- ret = bitstream_ensure_bits(stream, 16);
- if (ret != 0) {
- ERROR("Unexpected end of input when "
- "aligning bitstream");
- return ret;
- }
- }
- bitstream_remove_bits(stream, 16);
- }
- return 0;
-}
-
-/*
- * Builds a fast huffman decoding table from a canonical huffman code lengths
- * table. Based on code written by David Tritscher.
- *
- * @decode_table: The array in which to create the fast huffman decoding
- * table. It must have a length of at least
- * (2**num_bits) + 2 * num_syms to guarantee
- * that there is enough space.
- *
- * @num_syms: Total number of symbols in the Huffman tree.
- *
- * @num_bits: Any symbols with a code length of num_bits or less can be
- * decoded in one lookup of the table. 2**num_bits
- * must be greater than or equal to @num_syms if there are
- * any Huffman codes longer than @num_bits.
- *
- * @lens: An array of length @num_syms, indexable by symbol, that
- * gives the length of that symbol. Because the Huffman
- * tree is in canonical form, it can be reconstructed by
- * only knowing the length of the code for each symbol.
- *
- * @make_codeword_len: An integer that gives the longest possible codeword
- * length.
- *
- * Returns 0 on success; returns 1 if the length values do not correspond to a
- * valid Huffman tree, or if there are codes of length greater than @num_bits
- * but 2**num_bits < num_syms.
- *
- * What exactly is the format of the fast Huffman decoding table? The first
- * (1 << num_bits) entries of the table are indexed by chunks of the input of
- * size @num_bits. If the next Huffman code in the input happens to have a
- * length of exactly @num_bits, the symbol is simply read directly from the
- * decoding table. Alternatively, if the next Huffman code has length _less
- * than_ @num_bits, the symbol is also read directly from the decode table; this
- * is possible because every entry in the table that is indexed by an integer
- * that has the shorter code as a binary prefix is filled in with the
- * appropriate symbol. If a code has length n <= num_bits, it will have
- * 2**(num_bits - n) possible suffixes, and thus that many entries in the
- * decoding table.
- *
- * It's a bit more complicated if the next Huffman code has length of more than
- * @num_bits. The table entry indexed by the first @num_bits of that code
- * cannot give the appropriate symbol directly, because that entry is guaranteed
- * to be referenced by the Huffman codes for multiple symbols. And while the
- * LZX compression format does not allow codes longer than 16 bits, a table of
- * size (2 ** 16) = 65536 entries would be too slow to create.
- *
- * There are several different ways to make it possible to look up the symbols
- * for codes longer than @num_bits. A common way is to make the entries for the
- * prefixes of length @num_bits of those entries be pointers to additional
- * decoding tables that are indexed by some number of additional bits of the
- * code symbol. The technique used here is a bit simpler, however. We just
- * store the needed subtrees of the Huffman tree in the decoding table after the
- * lookup entries, beginning at index (2**num_bits). Real pointers are
- * replaced by indices into the decoding table, and we distinguish symbol
- * entries from pointers by the fact that values less than @num_syms must be
- * symbol values.
- */
-int make_huffman_decode_table(u16 decode_table[], uint num_syms,
- uint num_bits, const u8 lens[],
- uint max_code_len)
-{
- /* Number of entries in the decode table. */
- u32 table_num_entries = 1 << num_bits;
-
- /* Current position in the decode table. */
- u32 decode_table_pos = 0;
-
- /* Fill entries for codes short enough for a direct mapping. Here we
- * are taking advantage of the ordering of the codes, since they are for
- * a canonical Huffman tree. It must be the case that all the codes of
- * some length @code_length, zero-extended or one-extended, numerically
- * precede all the codes of length @code_length + 1. Furthermore, if we
- * have 2 symbols A and B, such that A is listed before B in the lens
- * array, and both symbols have the same code length, then we know that
- * the code for A numerically precedes the code for B.
- * */
- for (uint code_len = 1; code_len <= num_bits; code_len++) {
-
- /* Number of entries that a code of length @code_length would
- * need. */
- u32 code_num_entries = 1 << (num_bits - code_len);
-
-
- /* For each symbol of length @code_len, fill in its entries in
- * the decode table. */
- for (uint sym = 0; sym < num_syms; sym++) {
-
- if (lens[sym] != code_len)
- continue;
-
-
- /* Check for table overrun. This can only happen if the
- * given lengths do not correspond to a valid Huffman
- * tree. */
- if (decode_table_pos >= table_num_entries) {
- ERROR("Huffman decoding table overrun: "
- "pos = %u, num_entries = %u",
- decode_table_pos, table_num_entries);
- return 1;
- }
-
- /* Fill all possible lookups of this symbol with
- * the symbol itself. */
- for (uint i = 0; i < code_num_entries; i++)
- decode_table[decode_table_pos + i] = sym;
-
- /* Increment the position in the decode table by
- * the number of entries that were just filled
- * in. */
- decode_table_pos += code_num_entries;
- }
- }
-
- /* If all entries of the decode table have been filled in, there are no
- * codes longer than num_bits, so we are done filling in the decode
- * table. */
- if (decode_table_pos == table_num_entries)
- return 0;
-
- /* Otherwise, fill in the remaining entries, which correspond to codes longer
- * than @num_bits. */
-
-
- /* First, zero out the rest of the entries; this is necessary so
- * that the entries appear as "unallocated" in the next part. */
- for (uint i = decode_table_pos; i < table_num_entries; i++)
- decode_table[i] = 0;
-
- /* Assert that 2**num_bits is at least num_syms. If this wasn't the
- * case, we wouldn't be able to distinguish pointer entries from symbol
- * entries. */
- wimlib_assert((1 << num_bits) >= num_syms);
-
-
- /* The current Huffman code. */
- uint current_code = decode_table_pos;
-
- /* The tree nodes are allocated starting at
- * decode_table[table_num_entries]. Remember that the full size of the
- * table, including the extra space for the tree nodes, is actually
- * 2**num_bits + 2 * num_syms slots, while table_num_entries is only
- * 2**num_bits. */
- uint next_free_tree_slot = table_num_entries;
-
- /* Go through every codeword of length greater than @num_bits. Note:
- * the LZX format guarantees that the codeword length can be at most 16
- * bits. */
- for (uint code_len = num_bits + 1; code_len <= max_code_len;
- code_len++)
- {
- current_code <<= 1;
- for (uint sym = 0; sym < num_syms; sym++) {
- if (lens[sym] != code_len)
- continue;
-
-
- /* i is the index of the current node; find it from the
- * prefix of the current Huffman code. */
- uint i = current_code >> (code_len - num_bits);
-
- if (i >= (1 << num_bits)) {
- ERROR("Invalid canonical Huffman code");
- return 1;
- }
-
- /* Go through each bit of the current Huffman code
- * beyond the prefix of length num_bits and walk the
- * tree, "allocating" slots that have not yet been
- * allocated. */
- for (int bit_num = num_bits + 1; bit_num <= code_len; bit_num++) {
-
- /* If the current tree node points to nowhere
- * but we need to follow it, allocate a new node
- * for it to point to. */
- if (decode_table[i] == 0) {
- decode_table[i] = next_free_tree_slot;
- decode_table[next_free_tree_slot++] = 0;
- decode_table[next_free_tree_slot++] = 0;
- }
-
- i = decode_table[i];
-
- /* Is the next bit 0 or 1? If 0, go left;
- * otherwise, go right (by incrementing i by 1) */
- int bit_pos = code_len - bit_num;
-
- int bit = (current_code & (1 << bit_pos)) >>
- bit_pos;
- i += bit;
- }
-
- /* i is now the index of the leaf entry into which the
- * actual symbol will go. */
- decode_table[i] = sym;
-
- /* Increment decode_table_pos only if the prefix of the
- * Huffman code changes. */
- if (current_code >> (code_len - num_bits) !=
- (current_code + 1) >> (code_len - num_bits))
- decode_table_pos++;
-
- /* current_code is always incremented because this is
- * how canonical Huffman codes are generated (add 1 for
- * each code, then left shift whenever the code length
- * increases) */
- current_code++;
- }
- }
-
-
- /* If the lengths really represented a valid Huffman tree, all
- * @table_num_entries in the table will have been filled. However, it
- * is also possible that the tree is completely empty (as noted
- * earlier) with all 0 lengths, and this is expected to succeed. */
-
- if (decode_table_pos != table_num_entries) {
-
- for (uint i = 0; i < num_syms; i++) {
- if (lens[i] != 0) {
- ERROR("Lengths do not form a valid canonical "
- "Huffman tree (only filled %u of %u "
- "decode table slots)",
- decode_table_pos, table_num_entries);
- return 1;
- }
- }
- }
- return 0;
-}
-
-/* Reads a Huffman-encoded symbol when it is known there are less than
- * MAX_CODE_LEN bits remaining in the bitstream. */
-static int read_huffsym_near_end_of_input(struct input_bitstream *istream,
- const u16 decode_table[],
- const u8 lens[],
- uint num_syms,
- uint table_bits,
- uint *n)
-{
- uint bitsleft = istream->bitsleft;
- uint key_size;
- u16 sym;
- u16 key_bits;
-
- if (table_bits > bitsleft) {
- key_size = bitsleft;
- bitsleft = 0;
- key_bits = bitstream_peek_bits(istream, key_size) <<
- (table_bits - key_size);
- } else {
- key_size = table_bits;
- bitsleft -= table_bits;
- key_bits = bitstream_peek_bits(istream, table_bits);
- }
-
- sym = decode_table[key_bits];
- if (sym >= num_syms) {
- bitstream_remove_bits(istream, key_size);
- do {
- if (bitsleft == 0) {
- ERROR("Input stream exhausted");
- return 1;
- }
- key_bits = sym + bitstream_peek_bits(istream, 1);
- bitstream_remove_bits(istream, 1);
- bitsleft--;
- } while ((sym = decode_table[key_bits]) >= num_syms);
- } else {
- bitstream_remove_bits(istream, lens[sym]);
- }
- *n = sym;
- return 0;
-}
-
-/*
- * Reads a Huffman-encoded symbol from a bitstream.
- *
- * This function may be called hundreds of millions of times when extracting a
- * large WIM file. I'm not sure it could be made much faster that it is,
- * especially since there isn't enough time to make a big table that allows
- * decoding multiple symbols per lookup. But if extracting files to a hard
- * disk, the IO will be the bottleneck anyway.
- *
- * @buf: The input buffer from which the symbol will be read.
- * @decode_table: The fast Huffman decoding table for the Huffman tree.
- * @lengths: The table that gives the length of the code for each
- * symbol.
- * @num_symbols: The number of symbols in the Huffman code.
- * @table_bits: Huffman codes this length or less can be looked up
- * directory in the decode_table, as the
- * decode_table contains 2**table_bits entries.
- */
-int read_huffsym(struct input_bitstream *stream,
- const u16 decode_table[],
- const u8 lengths[],
- unsigned num_symbols,
- unsigned table_bits,
- uint *n,
- unsigned max_codeword_len)
-{
- /* In the most common case, there are at least max_codeword_len bits
- * remaining in the stream. */
- if (bitstream_ensure_bits(stream, max_codeword_len) == 0) {
-
- /* Use the next table_bits of the input as an index into the
- * decode_table. */
- u16 key_bits = bitstream_peek_bits(stream, table_bits);
-
- u16 sym = decode_table[key_bits];
-
- /* If the entry in the decode table is not a valid symbol, it is
- * the offset of the root of its Huffman subtree. */
- if (sym >= num_symbols) {
- bitstream_remove_bits(stream, table_bits);
- do {
- key_bits = sym + bitstream_peek_bits(stream, 1);
- bitstream_remove_bits(stream, 1);
-
- wimlib_assert(key_bits < num_symbols * 2 +
- (1 << table_bits));
- } while ((sym = decode_table[key_bits]) >= num_symbols);
- } else {
- wimlib_assert(lengths[sym] <= table_bits);
- bitstream_remove_bits(stream, lengths[sym]);
- }
- *n = sym;
- return 0;
- } else {
- /* Otherwise, we must be careful to use only the bits that are
- * actually remaining. */
- return read_huffsym_near_end_of_input(stream, decode_table,
- lengths, num_symbols,
- table_bits, n);
- }
-}