* lz_optimal.h
*
* Near-optimal LZ (Lempel-Ziv) parsing, or "match choosing".
+ * See lz_get_near_optimal_match() for details of the algorithm.
*
- * This is based on the algorithm used in 7-Zip's DEFLATE encoder, written by
- * Igor Pavlov.
+ * This code is not concerned with actually *finding* LZ matches, as it relies
+ * on an underlying match-finder implementation that can do so.
*/
/*
- * Copyright (C) 2013 Eric Biggers
+ * Copyright (c) 2013 Eric Biggers. All rights reserved.
*
- * This file is part of wimlib, a library for working with WIM files.
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions
+ * are met:
*
- * 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.
+ * 1. Redistributions of source code must retain the above copyright
+ * notice, this list of conditions and the following disclaimer.
*
- * 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.
+ * 2. 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.
*
- * You should have received a copy of the GNU General Public License
- * along with wimlib; if not, see http://www.gnu.org/licenses/.
+ * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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.
*/
-/* Define the following structures before including this:
+/* Define the following structures before including this header:
*
* LZ_COMPRESSOR
- * LZ_FORMAT_STATE */
+ * LZ_ADAPTIVE_STATE
+ *
+ * Also, the type lz_mc_cost_t can be optionally overridden by providing an
+ * appropriate typedef and defining LZ_MC_COST_T_DEFINED. */
#ifndef _LZ_OPTIMAL_H
#define _LZ_OPTIMAL_H
#include "wimlib/lz.h"
-typedef input_idx_t lz_mc_cost_t;
+#ifndef LZ_MC_COST_T_DEFINED
+ typedef input_idx_t lz_mc_cost_t;
+#endif
#define LZ_MC_INFINITE_COST (~(lz_mc_cost_t)0)
+struct lz_mc_pos_data;
+
+/* State of the Lempel-Ziv match-chooser.
+ *
+ * This is defined here for benefit of the inlined code. It's not intended for
+ * code outside the match-chooser itself to read or write members from this
+ * structure. */
+struct lz_match_chooser {
+ /* Temporary space used for the match-choosing algorithm. The size of
+ * this array must be at least one more than @nice_len but otherwise is
+ * arbitrary. More space decreases the frequency at which the algorithm
+ * is forced to terminate early. 4096 spaces seems sufficient for most
+ * real data. */
+ struct lz_mc_pos_data *optimum;
+ input_idx_t array_space;
+
+ /* When a match with length greater than or equal to this length is
+ * found, choose it immediately without further consideration. */
+ input_idx_t nice_len;
+
+ /* When matches have been chosen, optimum_cur_idx is set to the position
+ * in the window of the next match/literal to return and optimum_end_idx
+ * is set to the position in the window at the end of the last
+ * match/literal to return. */
+ input_idx_t optimum_cur_idx;
+ input_idx_t optimum_end_idx;
+};
+
/*
* Match chooser position data:
*
} next;
};
- /* Format-dependent state that exists after an approximate minimum-cost
- * path to reach this position is taken. For example, for LZX this is
- * the list of recently used match offsets. This could be 0 bytes if
- * the format does not have any state that affects match costs. */
- LZ_FORMAT_STATE state;
-};
-
-struct lz_match_chooser {
- /* Temporary space used for the match-choosing algorithm. The size of
- * this array must be at least one more than greedy_len but otherwise is
- * arbitrary. More space simply allows the match-choosing algorithm to
- * potentially find better matches (depending on the input, as always).
- */
- struct lz_mc_pos_data *optimum;
- input_idx_t array_space;
-
- /* When a match greater than this length is found, choose it immediately
- * without further consideration. */
- input_idx_t greedy_len;
-
- /* When matches have been chosen, optimum_cur_idx is set to the position
- * in the window of the next match/literal to return and optimum_end_idx
- * is set to the position in the window at the end of the last
- * match/literal to return. */
- input_idx_t optimum_cur_idx;
- input_idx_t optimum_end_idx;
+ /* Format-dependent adaptive state that exists after an approximate
+ * minimum-cost path to reach this position is taken. For example, for
+ * LZX this is the list of recently used match offsets. If the format
+ * does not have any adaptive state that affects match costs,
+ * LZ_ADAPTIVE_STATE could be set to a dummy structure of size 0. */
+ LZ_ADAPTIVE_STATE state;
};
/* Initialize the match-chooser.
static bool
lz_match_chooser_init(struct lz_match_chooser *mc,
input_idx_t array_space,
- input_idx_t greedy_len, input_idx_t max_match_len)
+ input_idx_t nice_len, input_idx_t max_match_len)
{
- input_idx_t extra_len = min(greedy_len, max_match_len);
+ input_idx_t extra_len = min(nice_len, max_match_len);
LZ_ASSERT(array_space > 0);
mc->optimum = MALLOC((array_space + extra_len) * sizeof(mc->optimum[0]));
if (mc->optimum == NULL)
return false;
mc->array_space = array_space;
- mc->greedy_len = greedy_len;
+ mc->nice_len = nice_len;
return true;
}
+static inline u64
+lz_match_chooser_get_needed_memory(input_idx_t array_space,
+ input_idx_t nice_len,
+ input_idx_t max_match_len)
+{
+ input_idx_t extra_len = min(nice_len, max_match_len);
+ return ((u64)(array_space + extra_len) *
+ sizeof(((struct lz_match_chooser*)0)->optimum[0]));
+}
+
+/* Free memory allocated in lz_match_chooser_init(). */
static void
lz_match_chooser_destroy(struct lz_match_chooser *mc)
{
FREE(mc->optimum);
}
+/* Call this before starting to parse each new input string. */
static void
lz_match_chooser_begin(struct lz_match_chooser *mc)
{
/* Get the list of possible matches at the next position. The return value must
* be the number of matches found (which may be 0) and a pointer to the returned
* matches must be written into @matches_ret. Matches must be of distinct
- * lengths and sorted in decreasing order by length. */
+ * lengths and sorted in decreasing order by length. Furthermore, match lengths
+ * may not exceed the @max_match_len passed to lz_match_chooser_init(), and all
+ * match lengths must be at least 2. */
typedef u32 (*lz_get_matches_t)(LZ_COMPRESSOR *ctx,
- const LZ_FORMAT_STATE *state,
+ const LZ_ADAPTIVE_STATE *state,
struct raw_match **matches_ret);
-/* Skip the specified number of bytes (don't search for matches at them). */
+/* Skip the specified number of bytes (don't search for matches at them). This
+ * is expected to be faster than simply getting the matches at each position,
+ * but the exact performance difference will be dependent on the match-finder
+ * implementation. */
typedef void (*lz_skip_bytes_t)(LZ_COMPRESSOR *ctx, input_idx_t n);
/* Get the cost of the literal located at the position at which matches have
* most recently been searched. This can optionally update the @state to take
* into account format-dependent state that affects match costs, such as repeat
* offsets. */
-typedef u32 (lz_get_prev_literal_cost_t)(LZ_COMPRESSOR *ctx,
- LZ_FORMAT_STATE *state);
+typedef lz_mc_cost_t (*lz_get_prev_literal_cost_t)(LZ_COMPRESSOR *ctx,
+ LZ_ADAPTIVE_STATE *state);
/* Get the cost of a match. This can optionally update the @state to take into
* account format-dependent state that affects match costs, such as repeat
* offsets. */
-typedef u32 (lz_get_match_cost_t)(LZ_COMPRESSOR *ctx, LZ_FORMAT_STATE *state,
- input_idx_t length,
- input_idx_t offset);
+typedef lz_mc_cost_t (*lz_get_match_cost_t)(LZ_COMPRESSOR *ctx,
+ LZ_ADAPTIVE_STATE *state,
+ input_idx_t length,
+ input_idx_t offset);
/*
* lz_get_near_optimal_match() -
*
- * Choose the optimal match or literal to use at the next position in the input.
+ * Choose an approximately optimal match or literal to use at the next position
+ * in the string, or "window", being LZ-encoded.
*
- * Unlike a greedy parser that always takes the longest match, or even a
+ * This is based on the algorithm used in 7-Zip's DEFLATE encoder, written by
+ * Igor Pavlov. However it also attempts to account for adaptive state, such as
+ * a LRU queue of recent match offsets.
+ *
+ * Unlike a greedy parser that always takes the longest match, or even a "lazy"
* parser with one match/literal look-ahead like zlib, the algorithm used here
- * may look ahead many matches/literals to determine the optimal match/literal to
- * output next. The motivation is that the compression ratio is improved if the
- * compressor can do things like use a shorter-than-possible match in order to
- * allow a longer match later, and also take into account the Huffman code cost
- * model rather than simply assuming that longer is better.
+ * may look ahead many matches/literals to determine the approximately optimal
+ * match/literal to code next. The motivation is that the compression ratio is
+ * improved if the compressor can do things like use a shorter-than-possible
+ * match in order to allow a longer match later, and also take into account the
+ * estimated real cost of coding each match/literal based on the underlying
+ * entropy encoding.
+ *
+ * Still, this is not a true optimal parser for several reasons:
+ *
+ * - Very long matches (at least @nice_len) are taken immediately. This is
+ * because locations with long matches are likely to have many possible
+ * alternatives that would cause slow optimal parsing, but also such locations
+ * are already highly compressible so it is not too harmful to just grab the
+ * longest match.
*
- * Still, this is not truly an optimal parser because very long matches are
- * taken immediately, and the raw match-finder takes some shortcuts. This is
- * done to avoid considering many different alternatives that are unlikely to
- * be significantly better.
+ * - Not all possible matches at each location are considered. Users of this
+ * code are expected to provide a @get_matches() function that returns a list
+ * of potentially good matches at the current position, but no more than one
+ * per length. It therefore must use some sort of heuristic (e.g. smallest or
+ * repeat offset) to choose a good match to consider for a given length, if
+ * multiple exist. Furthermore, the @get_matches() implementation may limit
+ * the total number of matches returned and/or the number of computational
+ * steps spent searching for matches at each position.
*
- * This algorithm is based on that used in 7-Zip's DEFLATE encoder.
+ * - This function relies on the user-provided @get_match_cost() and
+ * @get_prev_literal_cost() functions to evaluate match and literal costs,
+ * respectively, but real compression formats use entropy encoding of the
+ * literal/match sequence, so the real cost of coding each match or literal is
+ * unknown until the parse is fully determined. It can be approximated based
+ * on iterative parses, but the end result is not guaranteed to be globally
+ * optimal.
+ *
+ * - Although this function allows @get_match_cost() and
+ * @get_prev_literal_cost() to take into account adaptive state, coding
+ * decisions made with respect to the adaptive state will be locally optimal
+ * but will not necessarily be globally optimal. This is because the
+ * algorithm only keeps the least-costly path to get to a given location and
+ * does not take into account that a slightly more costly path could result in
+ * a different adaptive state that ultimately results in a lower global cost.
+ *
+ * - The array space used by this function is bounded, so in degenerate cases it
+ * is forced to start returning matches/literals before the algorithm has
+ * really finished.
*
* Each call to this function does one of two things:
*
- * 1. Build a near-optimal sequence of matches/literals, up to some point, that
+ * 1. Build a sequence of near-optimal matches/literals, up to some point, that
* will be returned by subsequent calls to this function, then return the
* first one.
*
* OR
*
* 2. Return the next match/literal previously computed by a call to this
- * function;
+ * function.
*
* The return value is a (length, offset) pair specifying the match or literal
* chosen. For literals, the length is 0 or 1 and the offset is meaningless.
+ *
+ * NOTE: this code has been factored out of the LZX compressor so that it can be
+ * shared by other formats such as LZMS. It is inlined so there is no loss of
+ * performance, especially with the different implementations of match-finding,
+ * cost evaluation, and adaptive state.
*/
static _always_inline_attribute struct raw_match
lz_get_near_optimal_match(struct lz_match_chooser *mc,
lz_get_prev_literal_cost_t get_prev_literal_cost,
lz_get_match_cost_t get_match_cost,
LZ_COMPRESSOR *ctx,
- const LZ_FORMAT_STATE *initial_state)
+ const LZ_ADAPTIVE_STATE *initial_state)
{
u32 num_possible_matches;
struct raw_match *possible_matches;
longest_match_len = possible_matches[0].len;
/* Greedy heuristic: if the longest match that was found is greater
- * than the number of fast bytes, return it immediately; don't both
- * doing more work. */
- if (longest_match_len > mc->greedy_len) {
+ * than nice_len, return it immediately; don't both doing more work. */
+ if (longest_match_len >= mc->nice_len) {
(*skip_bytes)(ctx, longest_match_len - 1);
return possible_matches[0];
}
- /* Calculate the cost to reach the next position by outputting a
- * literal. */
- mc->optimum[0].state = *initial_state;
- mc->optimum[1].state = mc->optimum[0].state;
+ /* Calculate the cost to reach the next position by coding a literal.
+ */
+ mc->optimum[1].state = *initial_state;
mc->optimum[1].cost = (*get_prev_literal_cost)(ctx, &mc->optimum[1].state);
mc->optimum[1].prev.link = 0;
/* Calculate the cost to reach any position up to and including that
- * reached by the longest match, using the shortest (i.e. closest) match
- * that reaches each position. */
+ * reached by the longest match. Use the shortest available match that
+ * reaches each position, assuming that @get_matches() only returned
+ * shorter matches because their estimated costs were less than that of
+ * the longest match. */
for (input_idx_t len = 2, match_idx = num_possible_matches - 1;
len <= longest_match_len; len++)
{
LZ_ASSERT(match_idx < num_possible_matches);
+ LZ_ASSERT(len <= possible_matches[match_idx].len);
- mc->optimum[len].state = mc->optimum[0].state;
+ mc->optimum[len].state = *initial_state;
mc->optimum[len].prev.link = 0;
mc->optimum[len].prev.match_offset = possible_matches[match_idx].offset;
mc->optimum[len].cost = (*get_match_cost)(ctx,
match_idx--;
}
+ /* Step forward, calculating the estimated minimum cost to reach each
+ * position. The algorithm may find multiple paths to reach each
+ * position; only the lowest-cost path is saved.
+ *
+ * The progress of the parse is tracked in the @mc->optimum array, which
+ * for each position contains the minimum cost to reach that position,
+ * the index of the start of the match/literal taken to reach that
+ * position through the minimum-cost path, the offset of the match taken
+ * (not relevant for literals), and the adaptive state that will exist
+ * at that position after the minimum-cost path is taken. The @cur_pos
+ * variable stores the position at which the algorithm is currently
+ * considering coding choices, and the @len_end variable stores the
+ * greatest position at which the costs of coding choices have been
+ * saved. (Actually, the algorithm guarantees that all positions up to
+ * and including @len_end are reachable by at least one path.)
+ *
+ * The loop terminates when any one of the following conditions occurs:
+ *
+ * 1. A match with length greater than or equal to @nice_len is found.
+ * When this occurs, the algorithm chooses this match
+ * unconditionally, and consequently the near-optimal match/literal
+ * sequence up to and including that match is fully determined and it
+ * can begin returning the match/literal list.
+ *
+ * 2. @cur_pos reaches a position not overlapped by a preceding match.
+ * In such cases, the near-optimal match/literal sequence up to
+ * @cur_pos is fully determined and it can begin returning the
+ * match/literal list.
+ *
+ * 3. Failing either of the above in a degenerate case, the loop
+ * terminates when space in the @mc->optimum array is exhausted.
+ * This terminates the algorithm and forces it to start returning
+ * matches/literals even though they may not be globally optimal.
+ *
+ * Upon loop termination, a nonempty list of matches/literals will have
+ * been produced and stored in the @optimum array. These
+ * matches/literals are linked in reverse order, so the last thing this
+ * function does is reverse this list and return the first
+ * match/literal, leaving the rest to be returned immediately by
+ * subsequent calls to this function.
+ */
input_idx_t cur_pos = 0;
-
- /* len_end: greatest index forward at which costs have been calculated
- * so far */
input_idx_t len_end = longest_match_len;
-
for (;;) {
/* Advance to next position. */
cur_pos++;
+ /* Check termination conditions (2) and (3) noted above. */
if (cur_pos == len_end || cur_pos == mc->array_space)
return lz_match_chooser_reverse_list(mc, cur_pos);
- /* retrieve the number of matches available at this position */
+ /* Retrieve a (possibly empty) list of potentially useful
+ * matches available at this position. */
num_possible_matches = (*get_matches)(ctx,
&mc->optimum[cur_pos].state,
&possible_matches);
- input_idx_t new_len = 0;
-
- if (num_possible_matches != 0) {
- new_len = possible_matches[0].len;
-
- /* Greedy heuristic: if we found a match greater than
- * the number of fast bytes, stop immediately. */
- if (new_len > mc->greedy_len) {
+ if (num_possible_matches == 0)
+ longest_match_len = 0;
+ else
+ longest_match_len = possible_matches[0].len;
+
+ /* Greedy heuristic and termination condition (1) noted above:
+ * if we found a match greater than @nice_len, choose it
+ * unconditionally and begin returning matches/literals. */
+ if (longest_match_len >= mc->nice_len) {
+ /* Build the list of matches to return and get
+ * the first one. */
+ match = lz_match_chooser_reverse_list(mc, cur_pos);
+
+ /* Append the long match to the end of the list. */
+ mc->optimum[cur_pos].next.match_offset =
+ possible_matches[0].offset;
+ mc->optimum[cur_pos].next.link = cur_pos + longest_match_len;
+ mc->optimum_end_idx = cur_pos + longest_match_len;
+
+ /* Skip over the remaining bytes of the long match. */
+ (*skip_bytes)(ctx, longest_match_len - 1);
+
+ /* Return first match in the list. */
+ return match;
+ }
- /* Build the list of matches to return and get
- * the first one. */
- match = lz_match_chooser_reverse_list(mc, cur_pos);
+ /* Load minimum cost to reach the current position. */
+ input_idx_t cur_cost = mc->optimum[cur_pos].cost;
- /* Append the long match to the end of the list. */
- mc->optimum[cur_pos].next.match_offset =
- possible_matches[0].offset;
- mc->optimum[cur_pos].next.link = cur_pos + new_len;
- mc->optimum_end_idx = cur_pos + new_len;
+ /* Consider proceeding with a literal byte. */
+ {
+ LZ_ADAPTIVE_STATE state;
+ lz_mc_cost_t cost;
- /* Skip over the remaining bytes of the long match. */
- (*skip_bytes)(ctx, new_len - 1);
+ state = mc->optimum[cur_pos].state;
+ cost = cur_cost + (*get_prev_literal_cost)(ctx, &state);
- /* Return first match in the list */
- return match;
+ if (cost < mc->optimum[cur_pos + 1].cost) {
+ mc->optimum[cur_pos + 1].cost = cost;
+ mc->optimum[cur_pos + 1].prev.link = cur_pos;
+ mc->optimum[cur_pos + 1].state = state;
}
}
- /* Consider proceeding with a literal byte. */
- lz_mc_cost_t cur_cost = mc->optimum[cur_pos].cost;
- LZ_FORMAT_STATE cur_plus_literal_state = mc->optimum[cur_pos].state;
- lz_mc_cost_t cur_plus_literal_cost = cur_cost +
- (*get_prev_literal_cost)(ctx,
- &cur_plus_literal_state);
- if (cur_plus_literal_cost < mc->optimum[cur_pos + 1].cost) {
- mc->optimum[cur_pos + 1].cost = cur_plus_literal_cost;
- mc->optimum[cur_pos + 1].prev.link = cur_pos;
- mc->optimum[cur_pos + 1].state = cur_plus_literal_state;
- }
+ /* If no matches were found, continue to the next position.
+ * Otherwise, consider proceeding with a match. */
if (num_possible_matches == 0)
continue;
- /* Consider proceeding with a match. */
-
- while (len_end < cur_pos + new_len)
+ /* Initialize any uninitialized costs up to the length of the
+ * longest match found. */
+ while (len_end < cur_pos + longest_match_len)
mc->optimum[++len_end].cost = LZ_MC_INFINITE_COST;
+ /* Calculate the minimum cost to reach any position up to and
+ * including that reached by the longest match. Use the
+ * shortest available match that reaches each position, assuming
+ * that @get_matches() only returned shorter matches because
+ * their estimated costs were less than that of the longest
+ * match. */
for (input_idx_t len = 2, match_idx = num_possible_matches - 1;
- len <= new_len; len++)
+ len <= longest_match_len; len++)
{
LZ_ASSERT(match_idx < num_possible_matches);
+ LZ_ASSERT(len <= possible_matches[match_idx].len);
- LZ_FORMAT_STATE state = mc->optimum[cur_pos].state;
+ LZ_ADAPTIVE_STATE state;
lz_mc_cost_t cost;
+ state = mc->optimum[cur_pos].state;
cost = cur_cost + (*get_match_cost)(ctx,
&state,
len,