grub2: bring back build of aros-side grub2 tools
[AROS.git] / workbench / libs / z / examples / enough.c
blobb991144305253c58e3397d7ff7737aa93d4a136b
1 /* enough.c -- determine the maximum size of inflate's Huffman code tables over
2 * all possible valid and complete Huffman codes, subject to a length limit.
3 * Copyright (C) 2007, 2008, 2012 Mark Adler
4 * Version 1.4 18 August 2012 Mark Adler
5 */
7 /* Version history:
8 1.0 3 Jan 2007 First version (derived from codecount.c version 1.4)
9 1.1 4 Jan 2007 Use faster incremental table usage computation
10 Prune examine() search on previously visited states
11 1.2 5 Jan 2007 Comments clean up
12 As inflate does, decrease root for short codes
13 Refuse cases where inflate would increase root
14 1.3 17 Feb 2008 Add argument for initial root table size
15 Fix bug for initial root table size == max - 1
16 Use a macro to compute the history index
17 1.4 18 Aug 2012 Avoid shifts more than bits in type (caused endless loop!)
18 Clean up comparisons of different types
19 Clean up code indentation
23 Examine all possible Huffman codes for a given number of symbols and a
24 maximum code length in bits to determine the maximum table size for zilb's
25 inflate. Only complete Huffman codes are counted.
27 Two codes are considered distinct if the vectors of the number of codes per
28 length are not identical. So permutations of the symbol assignments result
29 in the same code for the counting, as do permutations of the assignments of
30 the bit values to the codes (i.e. only canonical codes are counted).
32 We build a code from shorter to longer lengths, determining how many symbols
33 are coded at each length. At each step, we have how many symbols remain to
34 be coded, what the last code length used was, and how many bit patterns of
35 that length remain unused. Then we add one to the code length and double the
36 number of unused patterns to graduate to the next code length. We then
37 assign all portions of the remaining symbols to that code length that
38 preserve the properties of a correct and eventually complete code. Those
39 properties are: we cannot use more bit patterns than are available; and when
40 all the symbols are used, there are exactly zero possible bit patterns
41 remaining.
43 The inflate Huffman decoding algorithm uses two-level lookup tables for
44 speed. There is a single first-level table to decode codes up to root bits
45 in length (root == 9 in the current inflate implementation). The table
46 has 1 << root entries and is indexed by the next root bits of input. Codes
47 shorter than root bits have replicated table entries, so that the correct
48 entry is pointed to regardless of the bits that follow the short code. If
49 the code is longer than root bits, then the table entry points to a second-
50 level table. The size of that table is determined by the longest code with
51 that root-bit prefix. If that longest code has length len, then the table
52 has size 1 << (len - root), to index the remaining bits in that set of
53 codes. Each subsequent root-bit prefix then has its own sub-table. The
54 total number of table entries required by the code is calculated
55 incrementally as the number of codes at each bit length is populated. When
56 all of the codes are shorter than root bits, then root is reduced to the
57 longest code length, resulting in a single, smaller, one-level table.
59 The inflate algorithm also provides for small values of root (relative to
60 the log2 of the number of symbols), where the shortest code has more bits
61 than root. In that case, root is increased to the length of the shortest
62 code. This program, by design, does not handle that case, so it is verified
63 that the number of symbols is less than 2^(root + 1).
65 In order to speed up the examination (by about ten orders of magnitude for
66 the default arguments), the intermediate states in the build-up of a code
67 are remembered and previously visited branches are pruned. The memory
68 required for this will increase rapidly with the total number of symbols and
69 the maximum code length in bits. However this is a very small price to pay
70 for the vast speedup.
72 First, all of the possible Huffman codes are counted, and reachable
73 intermediate states are noted by a non-zero count in a saved-results array.
74 Second, the intermediate states that lead to (root + 1) bit or longer codes
75 are used to look at all sub-codes from those junctures for their inflate
76 memory usage. (The amount of memory used is not affected by the number of
77 codes of root bits or less in length.) Third, the visited states in the
78 construction of those sub-codes and the associated calculation of the table
79 size is recalled in order to avoid recalculating from the same juncture.
80 Beginning the code examination at (root + 1) bit codes, which is enabled by
81 identifying the reachable nodes, accounts for about six of the orders of
82 magnitude of improvement for the default arguments. About another four
83 orders of magnitude come from not revisiting previous states. Out of
84 approximately 2x10^16 possible Huffman codes, only about 2x10^6 sub-codes
85 need to be examined to cover all of the possible table memory usage cases
86 for the default arguments of 286 symbols limited to 15-bit codes.
88 Note that an unsigned long long type is used for counting. It is quite easy
89 to exceed the capacity of an eight-byte integer with a large number of
90 symbols and a large maximum code length, so multiple-precision arithmetic
91 would need to replace the unsigned long long arithmetic in that case. This
92 program will abort if an overflow occurs. The big_t type identifies where
93 the counting takes place.
95 An unsigned long long type is also used for calculating the number of
96 possible codes remaining at the maximum length. This limits the maximum
97 code length to the number of bits in a long long minus the number of bits
98 needed to represent the symbols in a flat code. The code_t type identifies
99 where the bit pattern counting takes place.
102 #include <stdio.h>
103 #include <stdlib.h>
104 #include <string.h>
105 #include <assert.h>
107 #define local static
109 /* special data types */
110 typedef unsigned long long big_t; /* type for code counting */
111 typedef unsigned long long code_t; /* type for bit pattern counting */
112 struct tab { /* type for been here check */
113 size_t len; /* length of bit vector in char's */
114 char *vec; /* allocated bit vector */
117 /* The array for saving results, num[], is indexed with this triplet:
119 syms: number of symbols remaining to code
120 left: number of available bit patterns at length len
121 len: number of bits in the codes currently being assigned
123 Those indices are constrained thusly when saving results:
125 syms: 3..totsym (totsym == total symbols to code)
126 left: 2..syms - 1, but only the evens (so syms == 8 -> 2, 4, 6)
127 len: 1..max - 1 (max == maximum code length in bits)
129 syms == 2 is not saved since that immediately leads to a single code. left
130 must be even, since it represents the number of available bit patterns at
131 the current length, which is double the number at the previous length.
132 left ends at syms-1 since left == syms immediately results in a single code.
133 (left > sym is not allowed since that would result in an incomplete code.)
134 len is less than max, since the code completes immediately when len == max.
136 The offset into the array is calculated for the three indices with the
137 first one (syms) being outermost, and the last one (len) being innermost.
138 We build the array with length max-1 lists for the len index, with syms-3
139 of those for each symbol. There are totsym-2 of those, with each one
140 varying in length as a function of sym. See the calculation of index in
141 count() for the index, and the calculation of size in main() for the size
142 of the array.
144 For the deflate example of 286 symbols limited to 15-bit codes, the array
145 has 284,284 entries, taking up 2.17 MB for an 8-byte big_t. More than
146 half of the space allocated for saved results is actually used -- not all
147 possible triplets are reached in the generation of valid Huffman codes.
150 /* The array for tracking visited states, done[], is itself indexed identically
151 to the num[] array as described above for the (syms, left, len) triplet.
152 Each element in the array is further indexed by the (mem, rem) doublet,
153 where mem is the amount of inflate table space used so far, and rem is the
154 remaining unused entries in the current inflate sub-table. Each indexed
155 element is simply one bit indicating whether the state has been visited or
156 not. Since the ranges for mem and rem are not known a priori, each bit
157 vector is of a variable size, and grows as needed to accommodate the visited
158 states. mem and rem are used to calculate a single index in a triangular
159 array. Since the range of mem is expected in the default case to be about
160 ten times larger than the range of rem, the array is skewed to reduce the
161 memory usage, with eight times the range for mem than for rem. See the
162 calculations for offset and bit in beenhere() for the details.
164 For the deflate example of 286 symbols limited to 15-bit codes, the bit
165 vectors grow to total approximately 21 MB, in addition to the 4.3 MB done[]
166 array itself.
169 /* Globals to avoid propagating constants or constant pointers recursively */
170 local int max; /* maximum allowed bit length for the codes */
171 local int root; /* size of base code table in bits */
172 local int large; /* largest code table so far */
173 local size_t size; /* number of elements in num and done */
174 local int *code; /* number of symbols assigned to each bit length */
175 local big_t *num; /* saved results array for code counting */
176 local struct tab *done; /* states already evaluated array */
178 /* Index function for num[] and done[] */
179 #define INDEX(i,j,k) (((size_t)((i-1)>>1)*((i-2)>>1)+(j>>1)-1)*(max-1)+k-1)
181 /* Free allocated space. Uses globals code, num, and done. */
182 local void cleanup(void)
184 size_t n;
186 if (done != NULL) {
187 for (n = 0; n < size; n++)
188 if (done[n].len)
189 free(done[n].vec);
190 free(done);
192 if (num != NULL)
193 free(num);
194 if (code != NULL)
195 free(code);
198 /* Return the number of possible Huffman codes using bit patterns of lengths
199 len through max inclusive, coding syms symbols, with left bit patterns of
200 length len unused -- return -1 if there is an overflow in the counting.
201 Keep a record of previous results in num to prevent repeating the same
202 calculation. Uses the globals max and num. */
203 local big_t count(int syms, int len, int left)
205 big_t sum; /* number of possible codes from this juncture */
206 big_t got; /* value returned from count() */
207 int least; /* least number of syms to use at this juncture */
208 int most; /* most number of syms to use at this juncture */
209 int use; /* number of bit patterns to use in next call */
210 size_t index; /* index of this case in *num */
212 /* see if only one possible code */
213 if (syms == left)
214 return 1;
216 /* note and verify the expected state */
217 assert(syms > left && left > 0 && len < max);
219 /* see if we've done this one already */
220 index = INDEX(syms, left, len);
221 got = num[index];
222 if (got)
223 return got; /* we have -- return the saved result */
225 /* we need to use at least this many bit patterns so that the code won't be
226 incomplete at the next length (more bit patterns than symbols) */
227 least = (left << 1) - syms;
228 if (least < 0)
229 least = 0;
231 /* we can use at most this many bit patterns, lest there not be enough
232 available for the remaining symbols at the maximum length (if there were
233 no limit to the code length, this would become: most = left - 1) */
234 most = (((code_t)left << (max - len)) - syms) /
235 (((code_t)1 << (max - len)) - 1);
237 /* count all possible codes from this juncture and add them up */
238 sum = 0;
239 for (use = least; use <= most; use++) {
240 got = count(syms - use, len + 1, (left - use) << 1);
241 sum += got;
242 if (got == (big_t)0 - 1 || sum < got) /* overflow */
243 return (big_t)0 - 1;
246 /* verify that all recursive calls are productive */
247 assert(sum != 0);
249 /* save the result and return it */
250 num[index] = sum;
251 return sum;
254 /* Return true if we've been here before, set to true if not. Set a bit in a
255 bit vector to indicate visiting this state. Each (syms,len,left) state
256 has a variable size bit vector indexed by (mem,rem). The bit vector is
257 lengthened if needed to allow setting the (mem,rem) bit. */
258 local int beenhere(int syms, int len, int left, int mem, int rem)
260 size_t index; /* index for this state's bit vector */
261 size_t offset; /* offset in this state's bit vector */
262 int bit; /* mask for this state's bit */
263 size_t length; /* length of the bit vector in bytes */
264 char *vector; /* new or enlarged bit vector */
266 /* point to vector for (syms,left,len), bit in vector for (mem,rem) */
267 index = INDEX(syms, left, len);
268 mem -= 1 << root;
269 offset = (mem >> 3) + rem;
270 offset = ((offset * (offset + 1)) >> 1) + rem;
271 bit = 1 << (mem & 7);
273 /* see if we've been here */
274 length = done[index].len;
275 if (offset < length && (done[index].vec[offset] & bit) != 0)
276 return 1; /* done this! */
278 /* we haven't been here before -- set the bit to show we have now */
280 /* see if we need to lengthen the vector in order to set the bit */
281 if (length <= offset) {
282 /* if we have one already, enlarge it, zero out the appended space */
283 if (length) {
284 do {
285 length <<= 1;
286 } while (length <= offset);
287 vector = realloc(done[index].vec, length);
288 if (vector != NULL)
289 memset(vector + done[index].len, 0, length - done[index].len);
292 /* otherwise we need to make a new vector and zero it out */
293 else {
294 length = 1 << (len - root);
295 while (length <= offset)
296 length <<= 1;
297 vector = calloc(length, sizeof(char));
300 /* in either case, bail if we can't get the memory */
301 if (vector == NULL) {
302 fputs("abort: unable to allocate enough memory\n", stderr);
303 cleanup();
304 exit(1);
307 /* install the new vector */
308 done[index].len = length;
309 done[index].vec = vector;
312 /* set the bit */
313 done[index].vec[offset] |= bit;
314 return 0;
317 /* Examine all possible codes from the given node (syms, len, left). Compute
318 the amount of memory required to build inflate's decoding tables, where the
319 number of code structures used so far is mem, and the number remaining in
320 the current sub-table is rem. Uses the globals max, code, root, large, and
321 done. */
322 local void examine(int syms, int len, int left, int mem, int rem)
324 int least; /* least number of syms to use at this juncture */
325 int most; /* most number of syms to use at this juncture */
326 int use; /* number of bit patterns to use in next call */
328 /* see if we have a complete code */
329 if (syms == left) {
330 /* set the last code entry */
331 code[len] = left;
333 /* complete computation of memory used by this code */
334 while (rem < left) {
335 left -= rem;
336 rem = 1 << (len - root);
337 mem += rem;
339 assert(rem == left);
341 /* if this is a new maximum, show the entries used and the sub-code */
342 if (mem > large) {
343 large = mem;
344 printf("max %d: ", mem);
345 for (use = root + 1; use <= max; use++)
346 if (code[use])
347 printf("%d[%d] ", code[use], use);
348 putchar('\n');
349 fflush(stdout);
352 /* remove entries as we drop back down in the recursion */
353 code[len] = 0;
354 return;
357 /* prune the tree if we can */
358 if (beenhere(syms, len, left, mem, rem))
359 return;
361 /* we need to use at least this many bit patterns so that the code won't be
362 incomplete at the next length (more bit patterns than symbols) */
363 least = (left << 1) - syms;
364 if (least < 0)
365 least = 0;
367 /* we can use at most this many bit patterns, lest there not be enough
368 available for the remaining symbols at the maximum length (if there were
369 no limit to the code length, this would become: most = left - 1) */
370 most = (((code_t)left << (max - len)) - syms) /
371 (((code_t)1 << (max - len)) - 1);
373 /* occupy least table spaces, creating new sub-tables as needed */
374 use = least;
375 while (rem < use) {
376 use -= rem;
377 rem = 1 << (len - root);
378 mem += rem;
380 rem -= use;
382 /* examine codes from here, updating table space as we go */
383 for (use = least; use <= most; use++) {
384 code[len] = use;
385 examine(syms - use, len + 1, (left - use) << 1,
386 mem + (rem ? 1 << (len - root) : 0), rem << 1);
387 if (rem == 0) {
388 rem = 1 << (len - root);
389 mem += rem;
391 rem--;
394 /* remove entries as we drop back down in the recursion */
395 code[len] = 0;
398 /* Look at all sub-codes starting with root + 1 bits. Look at only the valid
399 intermediate code states (syms, left, len). For each completed code,
400 calculate the amount of memory required by inflate to build the decoding
401 tables. Find the maximum amount of memory required and show the code that
402 requires that maximum. Uses the globals max, root, and num. */
403 local void enough(int syms)
405 int n; /* number of remaing symbols for this node */
406 int left; /* number of unused bit patterns at this length */
407 size_t index; /* index of this case in *num */
409 /* clear code */
410 for (n = 0; n <= max; n++)
411 code[n] = 0;
413 /* look at all (root + 1) bit and longer codes */
414 large = 1 << root; /* base table */
415 if (root < max) /* otherwise, there's only a base table */
416 for (n = 3; n <= syms; n++)
417 for (left = 2; left < n; left += 2)
419 /* look at all reachable (root + 1) bit nodes, and the
420 resulting codes (complete at root + 2 or more) */
421 index = INDEX(n, left, root + 1);
422 if (root + 1 < max && num[index]) /* reachable node */
423 examine(n, root + 1, left, 1 << root, 0);
425 /* also look at root bit codes with completions at root + 1
426 bits (not saved in num, since complete), just in case */
427 if (num[index - 1] && n <= left << 1)
428 examine((n - left) << 1, root + 1, (n - left) << 1,
429 1 << root, 0);
432 /* done */
433 printf("done: maximum of %d table entries\n", large);
437 Examine and show the total number of possible Huffman codes for a given
438 maximum number of symbols, initial root table size, and maximum code length
439 in bits -- those are the command arguments in that order. The default
440 values are 286, 9, and 15 respectively, for the deflate literal/length code.
441 The possible codes are counted for each number of coded symbols from two to
442 the maximum. The counts for each of those and the total number of codes are
443 shown. The maximum number of inflate table entires is then calculated
444 across all possible codes. Each new maximum number of table entries and the
445 associated sub-code (starting at root + 1 == 10 bits) is shown.
447 To count and examine Huffman codes that are not length-limited, provide a
448 maximum length equal to the number of symbols minus one.
450 For the deflate literal/length code, use "enough". For the deflate distance
451 code, use "enough 30 6".
453 This uses the %llu printf format to print big_t numbers, which assumes that
454 big_t is an unsigned long long. If the big_t type is changed (for example
455 to a multiple precision type), the method of printing will also need to be
456 updated.
458 int main(int argc, char **argv)
460 int syms; /* total number of symbols to code */
461 int n; /* number of symbols to code for this run */
462 big_t got; /* return value of count() */
463 big_t sum; /* accumulated number of codes over n */
464 code_t word; /* for counting bits in code_t */
466 /* set up globals for cleanup() */
467 code = NULL;
468 num = NULL;
469 done = NULL;
471 /* get arguments -- default to the deflate literal/length code */
472 syms = 286;
473 root = 9;
474 max = 15;
475 if (argc > 1) {
476 syms = atoi(argv[1]);
477 if (argc > 2) {
478 root = atoi(argv[2]);
479 if (argc > 3)
480 max = atoi(argv[3]);
483 if (argc > 4 || syms < 2 || root < 1 || max < 1) {
484 fputs("invalid arguments, need: [sym >= 2 [root >= 1 [max >= 1]]]\n",
485 stderr);
486 return 1;
489 /* if not restricting the code length, the longest is syms - 1 */
490 if (max > syms - 1)
491 max = syms - 1;
493 /* determine the number of bits in a code_t */
494 for (n = 0, word = 1; word; n++, word <<= 1)
497 /* make sure that the calculation of most will not overflow */
498 if (max > n || (code_t)(syms - 2) >= (((code_t)0 - 1) >> (max - 1))) {
499 fputs("abort: code length too long for internal types\n", stderr);
500 return 1;
503 /* reject impossible code requests */
504 if ((code_t)(syms - 1) > ((code_t)1 << max) - 1) {
505 fprintf(stderr, "%d symbols cannot be coded in %d bits\n",
506 syms, max);
507 return 1;
510 /* allocate code vector */
511 code = calloc(max + 1, sizeof(int));
512 if (code == NULL) {
513 fputs("abort: unable to allocate enough memory\n", stderr);
514 return 1;
517 /* determine size of saved results array, checking for overflows,
518 allocate and clear the array (set all to zero with calloc()) */
519 if (syms == 2) /* iff max == 1 */
520 num = NULL; /* won't be saving any results */
521 else {
522 size = syms >> 1;
523 if (size > ((size_t)0 - 1) / (n = (syms - 1) >> 1) ||
524 (size *= n, size > ((size_t)0 - 1) / (n = max - 1)) ||
525 (size *= n, size > ((size_t)0 - 1) / sizeof(big_t)) ||
526 (num = calloc(size, sizeof(big_t))) == NULL) {
527 fputs("abort: unable to allocate enough memory\n", stderr);
528 cleanup();
529 return 1;
533 /* count possible codes for all numbers of symbols, add up counts */
534 sum = 0;
535 for (n = 2; n <= syms; n++) {
536 got = count(n, 1, 2);
537 sum += got;
538 if (got == (big_t)0 - 1 || sum < got) { /* overflow */
539 fputs("abort: can't count that high!\n", stderr);
540 cleanup();
541 return 1;
543 printf("%llu %d-codes\n", got, n);
545 printf("%llu total codes for 2 to %d symbols", sum, syms);
546 if (max < syms - 1)
547 printf(" (%d-bit length limit)\n", max);
548 else
549 puts(" (no length limit)");
551 /* allocate and clear done array for beenhere() */
552 if (syms == 2)
553 done = NULL;
554 else if (size > ((size_t)0 - 1) / sizeof(struct tab) ||
555 (done = calloc(size, sizeof(struct tab))) == NULL) {
556 fputs("abort: unable to allocate enough memory\n", stderr);
557 cleanup();
558 return 1;
561 /* find and show maximum inflate table usage */
562 if (root > max) /* reduce root to max length */
563 root = max;
564 if ((code_t)syms < ((code_t)1 << (root + 1)))
565 enough(syms);
566 else
567 puts("cannot handle minimum code lengths > root");
569 /* done */
570 cleanup();
571 return 0;