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1 /* String -> String Map data structure optimized for size.
2 * This file implements a data structure mapping strings to other strings
3 * implementing an O(n) lookup data structure designed to be very memory
4 * efficient.
5 *
6 * The Redis Hash type uses this data structure for hashes composed of a small
7 * number of elements, to switch to an hash table once a given number of
8 * elements is reached.
9 *
10 * Given that many times Redis Hashes are used to represent objects composed
11 * of few fields, this is a very big win in terms of used memory.
12 *
13 * --------------------------------------------------------------------------
14 *
15 * Copyright (c) 2009-2010, Salvatore Sanfilippo <antirez at gmail dot com>
16 * All rights reserved.
17 *
18 * Redistribution and use in source and binary forms, with or without
19 * modification, are permitted provided that the following conditions are met:
20 *
21 * * Redistributions of source code must retain the above copyright notice,
22 * this list of conditions and the following disclaimer.
23 * * Redistributions in binary form must reproduce the above copyright
24 * notice, this list of conditions and the following disclaimer in the
25 * documentation and/or other materials provided with the distribution.
26 * * Neither the name of Redis nor the names of its contributors may be used
27 * to endorse or promote products derived from this software without
28 * specific prior written permission.
29 *
30 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
31 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
32 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
33 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
34 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
35 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
36 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
37 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
38 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
39 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
40 * POSSIBILITY OF SUCH DAMAGE.
41 */
42
43 /* Memory layout of a zipmap, for the map "foo" => "bar", "hello" => "world":
44 *
45 * <zmlen><len>"foo"<len><free>"bar"<len>"hello"<len><free>"world"
46 *
47 * <zmlen> is 1 byte length that holds the current size of the zipmap.
48 * When the zipmap length is greater than or equal to 254, this value
49 * is not used and the zipmap needs to be traversed to find out the length.
50 *
51 * <len> is the length of the following string (key or value).
52 * <len> lengths are encoded in a single value or in a 5 bytes value.
53 * If the first byte value (as an unsigned 8 bit value) is between 0 and
54 * 252, it's a single-byte length. If it is 253 then a four bytes unsigned
55 * integer follows (in the host byte ordering). A value fo 255 is used to
56 * signal the end of the hash. The special value 254 is used to mark
57 * empty space that can be used to add new key/value pairs.
58 *
59 * <free> is the number of free unused bytes
60 * after the string, resulting from modification of values associated to a
61 * key (for instance if "foo" is set to "bar', and later "foo" will be se to
62 * "hi", I'll have a free byte to use if the value will enlarge again later,
63 * or even in order to add a key/value pair if it fits.
64 *
65 * <free> is always an unsigned 8 bit number, because if after an
66 * update operation there are more than a few free bytes, the zipmap will be
67 * reallocated to make sure it is as small as possible.
68 *
69 * The most compact representation of the above two elements hash is actually:
70 *
71 * "\x02\x03foo\x03\x00bar\x05hello\x05\x00world\xff"
72 *
73 * Note that because keys and values are prefixed length "objects",
74 * the lookup will take O(N) where N is the number of elements
75 * in the zipmap and *not* the number of bytes needed to represent the zipmap.
76 * This lowers the constant times considerably.
77 */
78
79 #include <stdio.h>
80 #include <string.h>
81 #include <assert.h>
82 #include "zmalloc.h"
83
84 #define ZIPMAP_BIGLEN 254
85 #define ZIPMAP_END 255
86
87 /* The following defines the max value for the <free> field described in the
88 * comments above, that is, the max number of trailing bytes in a value. */
89 #define ZIPMAP_VALUE_MAX_FREE 4
90
91 /* The following macro returns the number of bytes needed to encode the length
92 * for the integer value _l, that is, 1 byte for lengths < ZIPMAP_BIGLEN and
93 * 5 bytes for all the other lengths. */
94 #define ZIPMAP_LEN_BYTES(_l) (((_l) < ZIPMAP_BIGLEN) ? 1 : sizeof(unsigned int)+1)
95
96 /* Create a new empty zipmap. */
97 unsigned char *zipmapNew(void) {
98 unsigned char *zm = zmalloc(2);
99
100 zm[0] = 0; /* Length */
101 zm[1] = ZIPMAP_END;
102 return zm;
103 }
104
105 /* Decode the encoded length pointed by 'p' */
106 static unsigned int zipmapDecodeLength(unsigned char *p) {
107 unsigned int len = *p;
108
109 if (len < ZIPMAP_BIGLEN) return len;
110 memcpy(&len,p+1,sizeof(unsigned int));
111 return len;
112 }
113
114 /* Encode the length 'l' writing it in 'p'. If p is NULL it just returns
115 * the amount of bytes required to encode such a length. */
116 static unsigned int zipmapEncodeLength(unsigned char *p, unsigned int len) {
117 if (p == NULL) {
118 return ZIPMAP_LEN_BYTES(len);
119 } else {
120 if (len < ZIPMAP_BIGLEN) {
121 p[0] = len;
122 return 1;
123 } else {
124 p[0] = ZIPMAP_BIGLEN;
125 memcpy(p+1,&len,sizeof(len));
126 return 1+sizeof(len);
127 }
128 }
129 }
130
131 /* Search for a matching key, returning a pointer to the entry inside the
132 * zipmap. Returns NULL if the key is not found.
133 *
134 * If NULL is returned, and totlen is not NULL, it is set to the entire
135 * size of the zimap, so that the calling function will be able to
136 * reallocate the original zipmap to make room for more entries. */
137 static unsigned char *zipmapLookupRaw(unsigned char *zm, unsigned char *key, unsigned int klen, unsigned int *totlen) {
138 unsigned char *p = zm+1, *k = NULL;
139 unsigned int l,llen;
140
141 while(*p != ZIPMAP_END) {
142 unsigned char free;
143
144 /* Match or skip the key */
145 l = zipmapDecodeLength(p);
146 llen = zipmapEncodeLength(NULL,l);
147 if (k == NULL && l == klen && !memcmp(p+llen,key,l)) {
148 /* Only return when the user doesn't care
149 * for the total length of the zipmap. */
150 if (totlen != NULL) {
151 k = p;
152 } else {
153 return p;
154 }
155 }
156 p += llen+l;
157 /* Skip the value as well */
158 l = zipmapDecodeLength(p);
159 p += zipmapEncodeLength(NULL,l);
160 free = p[0];
161 p += l+1+free; /* +1 to skip the free byte */
162 }
163 if (totlen != NULL) *totlen = (unsigned int)(p-zm)+1;
164 return k;
165 }
166
167 static unsigned long zipmapRequiredLength(unsigned int klen, unsigned int vlen) {
168 unsigned int l;
169
170 l = klen+vlen+3;
171 if (klen >= ZIPMAP_BIGLEN) l += 4;
172 if (vlen >= ZIPMAP_BIGLEN) l += 4;
173 return l;
174 }
175
176 /* Return the total amount used by a key (encoded length + payload) */
177 static unsigned int zipmapRawKeyLength(unsigned char *p) {
178 unsigned int l = zipmapDecodeLength(p);
179
180 return zipmapEncodeLength(NULL,l) + l;
181 }
182
183 /* Return the total amount used by a value
184 * (encoded length + single byte free count + payload) */
185 static unsigned int zipmapRawValueLength(unsigned char *p) {
186 unsigned int l = zipmapDecodeLength(p);
187 unsigned int used;
188
189 used = zipmapEncodeLength(NULL,l);
190 used += p[used] + 1 + l;
191 return used;
192 }
193
194 /* If 'p' points to a key, this function returns the total amount of
195 * bytes used to store this entry (entry = key + associated value + trailing
196 * free space if any). */
197 static unsigned int zipmapRawEntryLength(unsigned char *p) {
198 unsigned int l = zipmapRawKeyLength(p);
199 return l + zipmapRawValueLength(p+l);
200 }
201
202 static inline unsigned char *zipmapResize(unsigned char *zm, unsigned int len) {
203 zm = zrealloc(zm, len);
204 zm[len-1] = ZIPMAP_END;
205 return zm;
206 }
207
208 /* Set key to value, creating the key if it does not already exist.
209 * If 'update' is not NULL, *update is set to 1 if the key was
210 * already preset, otherwise to 0. */
211 unsigned char *zipmapSet(unsigned char *zm, unsigned char *key, unsigned int klen, unsigned char *val, unsigned int vlen, int *update) {
212 unsigned int zmlen, offset;
213 unsigned int freelen, reqlen = zipmapRequiredLength(klen,vlen);
214 unsigned int empty, vempty;
215 unsigned char *p;
216
217 freelen = reqlen;
218 if (update) *update = 0;
219 p = zipmapLookupRaw(zm,key,klen,&zmlen);
220 if (p == NULL) {
221 /* Key not found: enlarge */
222 zm = zipmapResize(zm, zmlen+reqlen);
223 p = zm+zmlen-1;
224 zmlen = zmlen+reqlen;
225
226 /* Increase zipmap length (this is an insert) */
227 if (zm[0] < ZIPMAP_BIGLEN) zm[0]++;
228 } else {
229 /* Key found. Is there enough space for the new value? */
230 /* Compute the total length: */
231 if (update) *update = 1;
232 freelen = zipmapRawEntryLength(p);
233 if (freelen < reqlen) {
234 /* Store the offset of this key within the current zipmap, so
235 * it can be resized. Then, move the tail backwards so this
236 * pair fits at the current position. */
237 offset = p-zm;
238 zm = zipmapResize(zm, zmlen-freelen+reqlen);
239 p = zm+offset;
240
241 /* The +1 in the number of bytes to be moved is caused by the
242 * end-of-zipmap byte. Note: the *original* zmlen is used. */
243 memmove(p+reqlen, p+freelen, zmlen-(offset+freelen+1));
244 zmlen = zmlen-freelen+reqlen;
245 freelen = reqlen;
246 }
247 }
248
249 /* We now have a suitable block where the key/value entry can
250 * be written. If there is too much free space, move the tail
251 * of the zipmap a few bytes to the front and shrink the zipmap,
252 * as we want zipmaps to be very space efficient. */
253 empty = freelen-reqlen;
254 if (empty >= ZIPMAP_VALUE_MAX_FREE) {
255 /* First, move the tail <empty> bytes to the front, then resize
256 * the zipmap to be <empty> bytes smaller. */
257 offset = p-zm;
258 memmove(p+reqlen, p+freelen, zmlen-(offset+freelen+1));
259 zmlen -= empty;
260 zm = zipmapResize(zm, zmlen);
261 p = zm+offset;
262 vempty = 0;
263 } else {
264 vempty = empty;
265 }
266
267 /* Just write the key + value and we are done. */
268 /* Key: */
269 p += zipmapEncodeLength(p,klen);
270 memcpy(p,key,klen);
271 p += klen;
272 /* Value: */
273 p += zipmapEncodeLength(p,vlen);
274 *p++ = vempty;
275 memcpy(p,val,vlen);
276 return zm;
277 }
278
279 /* Remove the specified key. If 'deleted' is not NULL the pointed integer is
280 * set to 0 if the key was not found, to 1 if it was found and deleted. */
281 unsigned char *zipmapDel(unsigned char *zm, unsigned char *key, unsigned int klen, int *deleted) {
282 unsigned int zmlen, freelen;
283 unsigned char *p = zipmapLookupRaw(zm,key,klen,&zmlen);
284 if (p) {
285 freelen = zipmapRawEntryLength(p);
286 memmove(p, p+freelen, zmlen-((p-zm)+freelen+1));
287 zm = zipmapResize(zm, zmlen-freelen);
288
289 /* Decrease zipmap length */
290 if (zm[0] < ZIPMAP_BIGLEN) zm[0]--;
291
292 if (deleted) *deleted = 1;
293 } else {
294 if (deleted) *deleted = 0;
295 }
296 return zm;
297 }
298
299 /* Call it before to iterate trought elements via zipmapNext() */
300 unsigned char *zipmapRewind(unsigned char *zm) {
301 return zm+1;
302 }
303
304 /* This function is used to iterate through all the zipmap elements.
305 * In the first call the first argument is the pointer to the zipmap + 1.
306 * In the next calls what zipmapNext returns is used as first argument.
307 * Example:
308 *
309 * unsigned char *i = zipmapRewind(my_zipmap);
310 * while((i = zipmapNext(i,&key,&klen,&value,&vlen)) != NULL) {
311 * printf("%d bytes key at $p\n", klen, key);
312 * printf("%d bytes value at $p\n", vlen, value);
313 * }
314 */
315 unsigned char *zipmapNext(unsigned char *zm, unsigned char **key, unsigned int *klen, unsigned char **value, unsigned int *vlen) {
316 if (zm[0] == ZIPMAP_END) return NULL;
317 if (key) {
318 *key = zm;
319 *klen = zipmapDecodeLength(zm);
320 *key += ZIPMAP_LEN_BYTES(*klen);
321 }
322 zm += zipmapRawKeyLength(zm);
323 if (value) {
324 *value = zm+1;
325 *vlen = zipmapDecodeLength(zm);
326 *value += ZIPMAP_LEN_BYTES(*vlen);
327 }
328 zm += zipmapRawValueLength(zm);
329 return zm;
330 }
331
332 /* Search a key and retrieve the pointer and len of the associated value.
333 * If the key is found the function returns 1, otherwise 0. */
334 int zipmapGet(unsigned char *zm, unsigned char *key, unsigned int klen, unsigned char **value, unsigned int *vlen) {
335 unsigned char *p;
336
337 if ((p = zipmapLookupRaw(zm,key,klen,NULL)) == NULL) return 0;
338 p += zipmapRawKeyLength(p);
339 *vlen = zipmapDecodeLength(p);
340 *value = p + ZIPMAP_LEN_BYTES(*vlen) + 1;
341 return 1;
342 }
343
344 /* Return 1 if the key exists, otherwise 0 is returned. */
345 int zipmapExists(unsigned char *zm, unsigned char *key, unsigned int klen) {
346 return zipmapLookupRaw(zm,key,klen,NULL) != NULL;
347 }
348
349 /* Return the number of entries inside a zipmap */
350 unsigned int zipmapLen(unsigned char *zm) {
351 unsigned int len = 0;
352 if (zm[0] < ZIPMAP_BIGLEN) {
353 len = zm[0];
354 } else {
355 unsigned char *p = zipmapRewind(zm);
356 while((p = zipmapNext(p,NULL,NULL,NULL,NULL)) != NULL) len++;
357
358 /* Re-store length if small enough */
359 if (len < ZIPMAP_BIGLEN) zm[0] = len;
360 }
361 return len;
362 }
363
364 void zipmapRepr(unsigned char *p) {
365 unsigned int l;
366
367 printf("{status %u}",*p++);
368 while(1) {
369 if (p[0] == ZIPMAP_END) {
370 printf("{end}");
371 break;
372 } else {
373 unsigned char e;
374
375 l = zipmapDecodeLength(p);
376 printf("{key %u}",l);
377 p += zipmapEncodeLength(NULL,l);
378 fwrite(p,l,1,stdout);
379 p += l;
380
381 l = zipmapDecodeLength(p);
382 printf("{value %u}",l);
383 p += zipmapEncodeLength(NULL,l);
384 e = *p++;
385 fwrite(p,l,1,stdout);
386 p += l+e;
387 if (e) {
388 printf("[");
389 while(e--) printf(".");
390 printf("]");
391 }
392 }
393 }
394 printf("\n");
395 }
396
397 #ifdef ZIPMAP_TEST_MAIN
398 int main(void) {
399 unsigned char *zm;
400
401 zm = zipmapNew();
402
403 zm = zipmapSet(zm,(unsigned char*) "name",4, (unsigned char*) "foo",3,NULL);
404 zm = zipmapSet(zm,(unsigned char*) "surname",7, (unsigned char*) "foo",3,NULL);
405 zm = zipmapSet(zm,(unsigned char*) "age",3, (unsigned char*) "foo",3,NULL);
406 zipmapRepr(zm);
407
408 zm = zipmapSet(zm,(unsigned char*) "hello",5, (unsigned char*) "world!",6,NULL);
409 zm = zipmapSet(zm,(unsigned char*) "foo",3, (unsigned char*) "bar",3,NULL);
410 zm = zipmapSet(zm,(unsigned char*) "foo",3, (unsigned char*) "!",1,NULL);
411 zipmapRepr(zm);
412 zm = zipmapSet(zm,(unsigned char*) "foo",3, (unsigned char*) "12345",5,NULL);
413 zipmapRepr(zm);
414 zm = zipmapSet(zm,(unsigned char*) "new",3, (unsigned char*) "xx",2,NULL);
415 zm = zipmapSet(zm,(unsigned char*) "noval",5, (unsigned char*) "",0,NULL);
416 zipmapRepr(zm);
417 zm = zipmapDel(zm,(unsigned char*) "new",3,NULL);
418 zipmapRepr(zm);
419
420 printf("\nLook up large key:\n");
421 {
422 unsigned char buf[512];
423 unsigned char *value;
424 unsigned int vlen, i;
425 for (i = 0; i < 512; i++) buf[i] = 'a';
426
427 zm = zipmapSet(zm,buf,512,(unsigned char*) "long",4,NULL);
428 if (zipmapGet(zm,buf,512,&value,&vlen)) {
429 printf(" <long key> is associated to the %d bytes value: %.*s\n",
430 vlen, vlen, value);
431 }
432 }
433
434 printf("\nPerform a direct lookup:\n");
435 {
436 unsigned char *value;
437 unsigned int vlen;
438
439 if (zipmapGet(zm,(unsigned char*) "foo",3,&value,&vlen)) {
440 printf(" foo is associated to the %d bytes value: %.*s\n",
441 vlen, vlen, value);
442 }
443 }
444 printf("\nIterate trought elements:\n");
445 {
446 unsigned char *i = zipmapRewind(zm);
447 unsigned char *key, *value;
448 unsigned int klen, vlen;
449
450 while((i = zipmapNext(i,&key,&klen,&value,&vlen)) != NULL) {
451 printf(" %d:%.*s => %d:%.*s\n", klen, klen, key, vlen, vlen, value);
452 }
453 }
454 return 0;
455 }
456 #endif