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549 lines
13 KiB
C
Vendored
549 lines
13 KiB
C
Vendored
/*
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Copyright (c) 2011, 2012, Simon Howard
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Permission to use, copy, modify, and/or distribute this software
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for any purpose with or without fee is hereby granted, provided
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that the above copyright notice and this permission notice appear
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in all copies.
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THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
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WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
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WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
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AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR
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CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM
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LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT,
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NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
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CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
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*/
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//
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// Decoder for PMarc -pm2- compression format. PMarc is a variant
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// of LHA commonly used on the MSX computer architecture.
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//
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <inttypes.h>
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#include "lha_decoder.h"
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#include "bit_stream_reader.c"
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#include "pma_common.c"
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// Include tree decoder.
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typedef uint8_t TreeElement;
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#include "tree_decode.c"
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// Size of the ring buffer (in bytes) used to store past history
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// for copies.
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#define RING_BUFFER_SIZE 8192
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// Maximum number of bytes that might be placed in the output buffer
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// from a single call to lha_pm2_decoder_read (largest copy size).
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#define OUTPUT_BUFFER_SIZE 256
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// Number of tree elements in the code tree.
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#define CODE_TREE_ELEMENTS 65
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// Number of tree elements in the offset tree.
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#define OFFSET_TREE_ELEMENTS 17
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typedef enum {
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PM2_REBUILD_UNBUILT, // At start of stream
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PM2_REBUILD_BUILD1, // After 1KiB
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PM2_REBUILD_BUILD2, // After 2KiB
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PM2_REBUILD_BUILD3, // After 4KiB
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PM2_REBUILD_CONTINUING, // 8KiB onwards...
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} PM2RebuildState;
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typedef struct {
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BitStreamReader bit_stream_reader;
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// State of decode tree.
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PM2RebuildState tree_state;
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// Number of bytes until we initiate a tree rebuild.
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size_t tree_rebuild_remaining;
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// History ring buffer, for copies:
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uint8_t ringbuf[RING_BUFFER_SIZE];
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unsigned int ringbuf_pos;
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// History linked list, for adaptively encoding byte values.
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HistoryLinkedList history_list;
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// Array representing the huffman tree used for representing
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// code values. A given node of the tree has children
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// code_tree[n] and code_tree[n + 1]. code_tree[0] is the
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// root node.
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TreeElement code_tree[CODE_TREE_ELEMENTS];
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// If zero, we don't need an offset tree:
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int need_offset_tree;
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// Array representing huffman tree used to look up offsets.
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// Same format as code_tree[].
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TreeElement offset_tree[OFFSET_TREE_ELEMENTS];
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} LHAPM2Decoder;
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// Decode table for history value. Characters that appeared recently in
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// the history are more likely than ones that appeared a long time ago,
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// so the history value is huffman coded so that small values require
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// fewer bits. The history value is then used to search within the
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// history linked list to get the actual character.
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static const VariableLengthTable history_decode[] = {
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{ 0, 3 }, // 0 + (1 << 3) = 8
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{ 8, 3 }, // 8 + (1 << 3) = 16
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{ 16, 4 }, // 16 + (1 << 4) = 32
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{ 32, 5 }, // 32 + (1 << 5) = 64
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{ 64, 5 }, // 64 + (1 << 5) = 96
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{ 96, 5 }, // 96 + (1 << 5) = 128
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{ 128, 6 }, // 128 + (1 << 6) = 192
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{ 192, 6 }, // 192 + (1 << 6) = 256
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};
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// Decode table for copies. As with history_decode[], small copies
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// are more common, and require fewer bits.
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static const VariableLengthTable copy_decode[] = {
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{ 17, 3 }, // 17 + (1 << 3) = 25
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{ 25, 3 }, // 25 + (1 << 3) = 33
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{ 33, 5 }, // 33 + (1 << 5) = 65
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{ 65, 6 }, // 65 + (1 << 6) = 129
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{ 129, 7 }, // 129 + (1 << 7) = 256
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{ 256, 0 }, // 256 (unique value)
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};
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// Initialize PMA decoder.
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static int lha_pm2_decoder_init(void *data, LHADecoderCallback callback,
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void *callback_data)
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{
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LHAPM2Decoder *decoder = data;
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bit_stream_reader_init(&decoder->bit_stream_reader,
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callback, callback_data);
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// Tree has not been built yet. It needs to be built on
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// the first call to read().
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decoder->tree_state = PM2_REBUILD_UNBUILT;
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decoder->tree_rebuild_remaining = 0;
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// Initialize ring buffer contents.
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memset(&decoder->ringbuf, ' ', RING_BUFFER_SIZE);
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decoder->ringbuf_pos = 0;
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// Init history lookup list.
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init_history_list(&decoder->history_list);
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// Initialize the lookup trees to a known state.
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init_tree(decoder->code_tree, CODE_TREE_ELEMENTS);
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init_tree(decoder->offset_tree, OFFSET_TREE_ELEMENTS);
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return 1;
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}
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// Read the list of code lengths to use for the code tree and construct
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// the code_tree structure.
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static int read_code_tree(LHAPM2Decoder *decoder)
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{
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uint8_t code_lengths[31];
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int num_codes, min_code_length, length_bits, val;
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unsigned int i;
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// Read the number of codes in the tree.
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num_codes = read_bits(&decoder->bit_stream_reader, 5);
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// Read min_code_length, which is used as an offset.
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min_code_length = read_bits(&decoder->bit_stream_reader, 3);
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if (min_code_length < 0 || num_codes < 0) {
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return 0;
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}
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// Store flag variable indicating whether we want to read
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// the offset tree as well.
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decoder->need_offset_tree
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= num_codes >= 10
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&& !(num_codes == 29 && min_code_length == 0);
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// Minimum length of zero means a tree containing a single code.
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if (min_code_length == 0) {
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set_tree_single(decoder->code_tree, num_codes - 1);
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return 1;
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}
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// How many bits are used to represent each table entry?
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length_bits = read_bits(&decoder->bit_stream_reader, 3);
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if (length_bits < 0) {
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return 0;
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}
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// Read table of code lengths:
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for (i = 0; i < (unsigned int) num_codes; ++i) {
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// Read a table entry. A value of zero represents an
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// unused code. Otherwise the value represents
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// an offset from the minimum length (previously read).
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val = read_bits(&decoder->bit_stream_reader,
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(unsigned int) length_bits);
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if (val < 0) {
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return 0;
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} else if (val == 0) {
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code_lengths[i] = 0;
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} else {
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code_lengths[i] = (uint8_t) (min_code_length + val - 1);
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}
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}
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// Build the tree.
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build_tree(decoder->code_tree, sizeof(decoder->code_tree),
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code_lengths, (unsigned int) num_codes);
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return 1;
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}
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// Read the code lengths for the offset tree and construct the offset
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// tree lookup table.
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static int read_offset_tree(LHAPM2Decoder *decoder,
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unsigned int num_offsets)
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{
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uint8_t offset_lengths[8];
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unsigned int off;
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unsigned int single_offset, num_codes;
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int len;
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if (!decoder->need_offset_tree) {
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return 1;
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}
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// Read 'num_offsets' 3-bit length values. For each offset
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// value 'off', offset_lengths[off] is the length of the
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// code that will represent 'off', or 0 if it will not
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// appear within the tree.
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num_codes = 0;
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single_offset = 0;
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for (off = 0; off < num_offsets; ++off) {
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len = read_bits(&decoder->bit_stream_reader, 3);
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if (len < 0) {
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return 0;
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}
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offset_lengths[off] = (uint8_t) len;
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// Track how many actual codes were in the tree.
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if (len != 0) {
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single_offset = off;
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++num_codes;
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}
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}
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// If there was a single code, this is a single node tree.
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if (num_codes == 1) {
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set_tree_single(decoder->offset_tree, single_offset);
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return 1;
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}
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// Build the tree.
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build_tree(decoder->offset_tree, sizeof(decoder->offset_tree),
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offset_lengths, num_offsets);
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return 1;
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}
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// Rebuild the decode trees used to compress data. This is called when
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// decoder->tree_rebuild_remaining reaches zero.
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static void rebuild_tree(LHAPM2Decoder *decoder)
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{
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switch (decoder->tree_state) {
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// Initial tree build, from start of stream:
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case PM2_REBUILD_UNBUILT:
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read_code_tree(decoder);
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read_offset_tree(decoder, 5);
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decoder->tree_state = PM2_REBUILD_BUILD1;
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decoder->tree_rebuild_remaining = 1024;
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break;
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// Tree rebuild after 1KiB of data has been read:
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case PM2_REBUILD_BUILD1:
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read_offset_tree(decoder, 6);
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decoder->tree_state = PM2_REBUILD_BUILD2;
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decoder->tree_rebuild_remaining = 1024;
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break;
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// Tree rebuild after 2KiB of data has been read:
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case PM2_REBUILD_BUILD2:
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read_offset_tree(decoder, 7);
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decoder->tree_state = PM2_REBUILD_BUILD3;
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decoder->tree_rebuild_remaining = 2048;
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break;
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// Tree rebuild after 4KiB of data has been read:
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case PM2_REBUILD_BUILD3:
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if (read_bit(&decoder->bit_stream_reader) == 1) {
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read_code_tree(decoder);
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}
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read_offset_tree(decoder, 8);
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decoder->tree_state = PM2_REBUILD_CONTINUING;
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decoder->tree_rebuild_remaining = 4096;
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break;
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// Tree rebuild after 8KiB of data has been read,
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// and every 4KiB after that:
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case PM2_REBUILD_CONTINUING:
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if (read_bit(&decoder->bit_stream_reader) == 1) {
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read_code_tree(decoder);
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read_offset_tree(decoder, 8);
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}
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decoder->tree_rebuild_remaining = 4096;
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break;
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}
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}
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static void output_byte(LHAPM2Decoder *decoder, uint8_t *buf,
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size_t *buf_len, uint8_t b)
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{
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// Add to history ring buffer.
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decoder->ringbuf[decoder->ringbuf_pos] = b;
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decoder->ringbuf_pos = (decoder->ringbuf_pos + 1) % RING_BUFFER_SIZE;
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// Add to output buffer.
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buf[*buf_len] = b;
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++*buf_len;
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// Update history chain.
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update_history_list(&decoder->history_list, b);
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// Count down until it is time to perform a rebuild of the
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// lookup trees.
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--decoder->tree_rebuild_remaining;
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if (decoder->tree_rebuild_remaining == 0) {
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rebuild_tree(decoder);
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}
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}
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// Read a single byte from the input stream and add it to the output
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// buffer.
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static void read_single_byte(LHAPM2Decoder *decoder, unsigned int code,
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uint8_t *buf, size_t *buf_len)
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{
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int offset;
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uint8_t b;
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offset = decode_variable_length(&decoder->bit_stream_reader,
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history_decode, code);
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if (offset < 0) {
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return;
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}
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b = find_in_history_list(&decoder->history_list, (uint8_t) offset);
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output_byte(decoder, buf, buf_len, b);
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}
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// Calculate how many bytes from history to copy:
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static int history_get_count(LHAPM2Decoder *decoder, unsigned int code)
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{
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// How many bytes to copy? A small value represents the
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// literal number of bytes to copy; larger values are a header
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// for a variable length value to be decoded.
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if (code < 15) {
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return (int) code + 2;
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} else {
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return decode_variable_length(&decoder->bit_stream_reader,
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copy_decode, code - 15);
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}
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}
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// Calculate the offset within history at which to start copying:
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static int history_get_offset(LHAPM2Decoder *decoder, unsigned int code)
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{
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unsigned int bits;
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int result, val;
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result = 0;
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// Calculate number of bits to read.
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// Code of zero indicates a simple 6-bit value giving the offset.
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if (code == 0) {
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bits = 6;
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}
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// Mid-range encoded offset value.
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// Read a code using the offset tree, indicating the length
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// of the offset value to follow. The code indicates the
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// number of bits (values 0-7 = 6-13 bits).
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else if (code < 20) {
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val = read_from_tree(&decoder->bit_stream_reader,
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decoder->offset_tree);
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if (val < 0) {
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return -1;
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} else if (val == 0) {
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bits = 6;
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} else {
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bits = (unsigned int) val + 5;
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result = 1 << bits;
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}
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}
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// Large copy values start from offset zero.
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else {
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return 0;
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}
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// Read a number of bits representing the offset value. The
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// number of length of this value is variable, and is calculated
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// above.
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val = read_bits(&decoder->bit_stream_reader, bits);
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if (val < 0) {
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return -1;
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}
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result += val;
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return result;
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}
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static void copy_from_history(LHAPM2Decoder *decoder, unsigned int code,
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uint8_t *buf, size_t *buf_len)
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{
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int to_copy, offset;
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unsigned int i, pos, start;
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// Read number of bytes to copy and offset within history to copy
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// from.
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to_copy = history_get_count(decoder, code);
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offset = history_get_offset(decoder, code);
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if (to_copy < 0 || offset < 0) {
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return;
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}
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// Sanity check to prevent the potential for buffer overflow.
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if (to_copy > OUTPUT_BUFFER_SIZE) {
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return;
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}
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// Perform copy.
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start = decoder->ringbuf_pos + RING_BUFFER_SIZE - 1
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- (unsigned int) offset;
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for (i = 0; i < (unsigned int) to_copy; ++i) {
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pos = (start + i) % RING_BUFFER_SIZE;
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output_byte(decoder, buf, buf_len, decoder->ringbuf[pos]);
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}
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}
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// Decode data and store it into buf[], returning the number of
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// bytes decoded.
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static size_t lha_pm2_decoder_read(void *data, uint8_t *buf)
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{
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LHAPM2Decoder *decoder = data;
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size_t result;
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int code;
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// On first pass through, build initial lookup trees.
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if (decoder->tree_state == PM2_REBUILD_UNBUILT) {
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// First bit in stream is discarded?
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read_bit(&decoder->bit_stream_reader);
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rebuild_tree(decoder);
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}
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result = 0;
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code = read_from_tree(&decoder->bit_stream_reader, decoder->code_tree);
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if (code < 0) {
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return 0;
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}
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if (code < 8) {
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read_single_byte(decoder, (unsigned int) code, buf, &result);
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} else {
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copy_from_history(decoder, (unsigned int) code - 8,
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buf, &result);
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}
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return result;
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}
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LHADecoderType lha_pm2_decoder = {
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lha_pm2_decoder_init,
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NULL,
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lha_pm2_decoder_read,
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sizeof(LHAPM2Decoder),
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OUTPUT_BUFFER_SIZE,
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RING_BUFFER_SIZE
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};
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