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1 | /** | |
2 | * @file | |
3 | * Dynamic memory manager | |
4 | * | |
5 | * This is a lightweight replacement for the standard C library malloc(). | |
6 | * | |
7 | * If you want to use the standard C library malloc() instead, define | |
8 | * MEM_LIBC_MALLOC to 1 in your lwipopts.h | |
9 | * | |
10 | * To let mem_malloc() use pools (prevents fragmentation and is much faster than | |
11 | * a heap but might waste some memory), define MEM_USE_POOLS to 1, define | |
12 | * MEM_USE_CUSTOM_POOLS to 1 and create a file "lwippools.h" that includes a list | |
13 | * of pools like this (more pools can be added between _START and _END): | |
14 | * | |
15 | * Define three pools with sizes 256, 512, and 1512 bytes | |
16 | * LWIP_MALLOC_MEMPOOL_START | |
17 | * LWIP_MALLOC_MEMPOOL(20, 256) | |
18 | * LWIP_MALLOC_MEMPOOL(10, 512) | |
19 | * LWIP_MALLOC_MEMPOOL(5, 1512) | |
20 | * LWIP_MALLOC_MEMPOOL_END | |
21 | */ | |
22 | ||
23 | /* | |
24 | * Copyright (c) 2001-2004 Swedish Institute of Computer Science. | |
25 | * All rights reserved. | |
26 | * | |
27 | * Redistribution and use in source and binary forms, with or without modification, | |
28 | * are permitted provided that the following conditions are met: | |
29 | * | |
30 | * 1. Redistributions of source code must retain the above copyright notice, | |
31 | * this list of conditions and the following disclaimer. | |
32 | * 2. Redistributions in binary form must reproduce the above copyright notice, | |
33 | * this list of conditions and the following disclaimer in the documentation | |
34 | * and/or other materials provided with the distribution. | |
35 | * 3. The name of the author may not be used to endorse or promote products | |
36 | * derived from this software without specific prior written permission. | |
37 | * | |
38 | * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED | |
39 | * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF | |
40 | * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT | |
41 | * SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, | |
42 | * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT | |
43 | * OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS | |
44 | * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN | |
45 | * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING | |
46 | * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY | |
47 | * OF SUCH DAMAGE. | |
48 | * | |
49 | * This file is part of the lwIP TCP/IP stack. | |
50 | * | |
51 | * Author: Adam Dunkels <adam@sics.se> | |
52 | * Simon Goldschmidt | |
53 | * | |
54 | */ | |
55 | ||
56 | #include "lwip/opt.h" | |
57 | ||
58 | #if !MEM_LIBC_MALLOC /* don't build if not configured for use in lwipopts.h */ | |
59 | ||
60 | #include "lwip/def.h" | |
61 | #include "lwip/mem.h" | |
62 | #include "lwip/sys.h" | |
63 | #include "lwip/stats.h" | |
64 | ||
65 | #include <string.h> | |
66 | ||
67 | #if MEM_USE_POOLS | |
68 | /* lwIP head implemented with different sized pools */ | |
69 | ||
70 | /** | |
71 | * This structure is used to save the pool one element came from. | |
72 | */ | |
73 | struct mem_helper | |
74 | { | |
75 | memp_t poolnr; | |
76 | }; | |
77 | ||
78 | /** | |
79 | * Allocate memory: determine the smallest pool that is big enough | |
80 | * to contain an element of 'size' and get an element from that pool. | |
81 | * | |
82 | * @param size the size in bytes of the memory needed | |
83 | * @return a pointer to the allocated memory or NULL if the pool is empty | |
84 | */ | |
85 | void * | |
86 | mem_malloc(mem_size_t size) | |
87 | { | |
88 | struct mem_helper *element; | |
89 | memp_t poolnr; | |
90 | ||
91 | for (poolnr = MEMP_POOL_FIRST; poolnr <= MEMP_POOL_LAST; poolnr++) { | |
92 | /* is this pool big enough to hold an element of the required size | |
93 | plus a struct mem_helper that saves the pool this element came from? */ | |
94 | if ((size + sizeof(struct mem_helper)) <= memp_sizes[poolnr]) { | |
95 | break; | |
96 | } | |
97 | } | |
98 | if (poolnr > MEMP_POOL_LAST) { | |
99 | LWIP_ASSERT("mem_malloc(): no pool is that big!", 0); | |
100 | return NULL; | |
101 | } | |
102 | element = (struct mem_helper*)memp_malloc(poolnr); | |
103 | if (element == NULL) { | |
104 | /* No need to DEBUGF or ASSERT: This error is already | |
105 | taken care of in memp.c */ | |
106 | /** @todo: we could try a bigger pool if this one is empty! */ | |
107 | return NULL; | |
108 | } | |
109 | ||
110 | /* save the pool number this element came from */ | |
111 | element->poolnr = poolnr; | |
112 | /* and return a pointer to the memory directly after the struct mem_helper */ | |
113 | element++; | |
114 | ||
115 | return element; | |
116 | } | |
117 | ||
118 | /** | |
119 | * Free memory previously allocated by mem_malloc. Loads the pool number | |
120 | * and calls memp_free with that pool number to put the element back into | |
121 | * its pool | |
122 | * | |
123 | * @param rmem the memory element to free | |
124 | */ | |
125 | void | |
126 | mem_free(void *rmem) | |
127 | { | |
128 | struct mem_helper *hmem = (struct mem_helper*)rmem; | |
129 | ||
130 | LWIP_ASSERT("rmem != NULL", (rmem != NULL)); | |
131 | LWIP_ASSERT("rmem == MEM_ALIGN(rmem)", (rmem == LWIP_MEM_ALIGN(rmem))); | |
132 | ||
133 | /* get the original struct mem_helper */ | |
134 | hmem--; | |
135 | ||
136 | LWIP_ASSERT("hmem != NULL", (hmem != NULL)); | |
137 | LWIP_ASSERT("hmem == MEM_ALIGN(hmem)", (hmem == LWIP_MEM_ALIGN(hmem))); | |
138 | LWIP_ASSERT("hmem->poolnr < MEMP_MAX", (hmem->poolnr < MEMP_MAX)); | |
139 | ||
140 | /* and put it in the pool we saved earlier */ | |
141 | memp_free(hmem->poolnr, hmem); | |
142 | } | |
143 | ||
144 | #else /* MEM_USE_POOLS */ | |
145 | /* lwIP replacement for your libc malloc() */ | |
146 | ||
147 | /** | |
148 | * The heap is made up as a list of structs of this type. | |
149 | * This does not have to be aligned since for getting its size, | |
150 | * we only use the macro SIZEOF_STRUCT_MEM, which automatically alignes. | |
151 | */ | |
152 | struct mem { | |
153 | /** index (-> ram[next]) of the next struct */ | |
154 | mem_size_t next; | |
155 | /** index (-> ram[next]) of the next struct */ | |
156 | mem_size_t prev; | |
157 | /** 1: this area is used; 0: this area is unused */ | |
158 | u8_t used; | |
159 | }; | |
160 | ||
161 | /** All allocated blocks will be MIN_SIZE bytes big, at least! | |
162 | * MIN_SIZE can be overridden to suit your needs. Smaller values save space, | |
163 | * larger values could prevent too small blocks to fragment the RAM too much. */ | |
164 | #ifndef MIN_SIZE | |
165 | #define MIN_SIZE 12 | |
166 | #endif /* MIN_SIZE */ | |
167 | /* some alignment macros: we define them here for better source code layout */ | |
168 | #define MIN_SIZE_ALIGNED LWIP_MEM_ALIGN_SIZE(MIN_SIZE) | |
169 | #define SIZEOF_STRUCT_MEM LWIP_MEM_ALIGN_SIZE(sizeof(struct mem)) | |
170 | #define MEM_SIZE_ALIGNED LWIP_MEM_ALIGN_SIZE(MEM_SIZE) | |
171 | ||
172 | /** the heap. we need one struct mem at the end and some room for alignment */ | |
173 | static u8_t ram_heap[MEM_SIZE_ALIGNED + (2*SIZEOF_STRUCT_MEM) + MEM_ALIGNMENT]; | |
174 | /** pointer to the heap (ram_heap): for alignment, ram is now a pointer instead of an array */ | |
175 | static u8_t *ram; | |
176 | /** the last entry, always unused! */ | |
177 | static struct mem *ram_end; | |
178 | /** pointer to the lowest free block, this is used for faster search */ | |
179 | static struct mem *lfree; | |
180 | /** concurrent access protection */ | |
181 | static sys_sem_t mem_sem; | |
182 | ||
183 | /** | |
184 | * "Plug holes" by combining adjacent empty struct mems. | |
185 | * After this function is through, there should not exist | |
186 | * one empty struct mem pointing to another empty struct mem. | |
187 | * | |
188 | * @param mem this points to a struct mem which just has been freed | |
189 | * @internal this function is only called by mem_free() and mem_realloc() | |
190 | * | |
191 | * This assumes access to the heap is protected by the calling function | |
192 | * already. | |
193 | */ | |
194 | static void | |
195 | plug_holes(struct mem *mem) | |
196 | { | |
197 | struct mem *nmem; | |
198 | struct mem *pmem; | |
199 | ||
200 | LWIP_ASSERT("plug_holes: mem >= ram", (u8_t *)mem >= ram); | |
201 | LWIP_ASSERT("plug_holes: mem < ram_end", (u8_t *)mem < (u8_t *)ram_end); | |
202 | LWIP_ASSERT("plug_holes: mem->used == 0", mem->used == 0); | |
203 | ||
204 | /* plug hole forward */ | |
205 | LWIP_ASSERT("plug_holes: mem->next <= MEM_SIZE_ALIGNED", mem->next <= MEM_SIZE_ALIGNED); | |
206 | ||
207 | nmem = (struct mem *)&ram[mem->next]; | |
208 | if (mem != nmem && nmem->used == 0 && (u8_t *)nmem != (u8_t *)ram_end) { | |
209 | /* if mem->next is unused and not end of ram, combine mem and mem->next */ | |
210 | if (lfree == nmem) { | |
211 | lfree = mem; | |
212 | } | |
213 | mem->next = nmem->next; | |
214 | ((struct mem *)&ram[nmem->next])->prev = (u8_t *)mem - ram; | |
215 | } | |
216 | ||
217 | /* plug hole backward */ | |
218 | pmem = (struct mem *)&ram[mem->prev]; | |
219 | if (pmem != mem && pmem->used == 0) { | |
220 | /* if mem->prev is unused, combine mem and mem->prev */ | |
221 | if (lfree == mem) { | |
222 | lfree = pmem; | |
223 | } | |
224 | pmem->next = mem->next; | |
225 | ((struct mem *)&ram[mem->next])->prev = (u8_t *)pmem - ram; | |
226 | } | |
227 | } | |
228 | ||
229 | /** | |
230 | * Zero the heap and initialize start, end and lowest-free | |
231 | */ | |
232 | void | |
233 | mem_init(void) | |
234 | { | |
235 | struct mem *mem; | |
236 | ||
237 | LWIP_ASSERT("Sanity check alignment", | |
238 | (SIZEOF_STRUCT_MEM & (MEM_ALIGNMENT-1)) == 0); | |
239 | ||
240 | /* align the heap */ | |
241 | ram = LWIP_MEM_ALIGN(ram_heap); | |
242 | /* initialize the start of the heap */ | |
243 | mem = (struct mem *)ram; | |
244 | mem->next = MEM_SIZE_ALIGNED; | |
245 | mem->prev = 0; | |
246 | mem->used = 0; | |
247 | /* initialize the end of the heap */ | |
248 | ram_end = (struct mem *)&ram[MEM_SIZE_ALIGNED]; | |
249 | ram_end->used = 1; | |
250 | ram_end->next = MEM_SIZE_ALIGNED; | |
251 | ram_end->prev = MEM_SIZE_ALIGNED; | |
252 | ||
253 | mem_sem = sys_sem_new(1); | |
254 | ||
255 | /* initialize the lowest-free pointer to the start of the heap */ | |
256 | lfree = (struct mem *)ram; | |
257 | ||
258 | #if MEM_STATS | |
259 | lwip_stats.mem.avail = MEM_SIZE_ALIGNED; | |
260 | #endif /* MEM_STATS */ | |
261 | } | |
262 | ||
263 | /** | |
264 | * Put a struct mem back on the heap | |
265 | * | |
266 | * @param rmem is the data portion of a struct mem as returned by a previous | |
267 | * call to mem_malloc() | |
268 | */ | |
269 | void | |
270 | mem_free(void *rmem) | |
271 | { | |
272 | struct mem *mem; | |
273 | ||
274 | if (rmem == NULL) { | |
275 | LWIP_DEBUGF(MEM_DEBUG | LWIP_DBG_TRACE | 2, ("mem_free(p == NULL) was called.\n")); | |
276 | return; | |
277 | } | |
278 | LWIP_ASSERT("mem_free: sanity check alignment", (((mem_ptr_t)rmem) & (MEM_ALIGNMENT-1)) == 0); | |
279 | ||
280 | /* protect the heap from concurrent access */ | |
281 | sys_arch_sem_wait(mem_sem, 0); | |
282 | ||
283 | LWIP_ASSERT("mem_free: legal memory", (u8_t *)rmem >= (u8_t *)ram && | |
284 | (u8_t *)rmem < (u8_t *)ram_end); | |
285 | ||
286 | if ((u8_t *)rmem < (u8_t *)ram || (u8_t *)rmem >= (u8_t *)ram_end) { | |
287 | LWIP_DEBUGF(MEM_DEBUG | 3, ("mem_free: illegal memory\n")); | |
288 | #if MEM_STATS | |
289 | ++lwip_stats.mem.err; | |
290 | #endif /* MEM_STATS */ | |
291 | sys_sem_signal(mem_sem); | |
292 | return; | |
293 | } | |
294 | /* Get the corresponding struct mem ... */ | |
295 | mem = (struct mem *)((u8_t *)rmem - SIZEOF_STRUCT_MEM); | |
296 | /* ... which has to be in a used state ... */ | |
297 | LWIP_ASSERT("mem_free: mem->used", mem->used); | |
298 | /* ... and is now unused. */ | |
299 | mem->used = 0; | |
300 | ||
301 | if (mem < lfree) { | |
302 | /* the newly freed struct is now the lowest */ | |
303 | lfree = mem; | |
304 | } | |
305 | ||
306 | #if MEM_STATS | |
307 | lwip_stats.mem.used -= mem->next - ((u8_t *)mem - ram); | |
308 | #endif /* MEM_STATS */ | |
309 | ||
310 | /* finally, see if prev or next are free also */ | |
311 | plug_holes(mem); | |
312 | sys_sem_signal(mem_sem); | |
313 | } | |
314 | ||
315 | /** | |
316 | * In contrast to its name, mem_realloc can only shrink memory, not expand it. | |
317 | * Since the only use (for now) is in pbuf_realloc (which also can only shrink), | |
318 | * this shouldn't be a problem! | |
319 | * | |
320 | * @param rmem pointer to memory allocated by mem_malloc the is to be shrinked | |
321 | * @param newsize required size after shrinking (needs to be smaller than or | |
322 | * equal to the previous size) | |
323 | * @return for compatibility reasons: is always == rmem, at the moment | |
324 | */ | |
325 | void * | |
326 | mem_realloc(void *rmem, mem_size_t newsize) | |
327 | { | |
328 | mem_size_t size; | |
329 | mem_size_t ptr, ptr2; | |
330 | struct mem *mem, *mem2; | |
331 | ||
332 | /* Expand the size of the allocated memory region so that we can | |
333 | adjust for alignment. */ | |
334 | newsize = LWIP_MEM_ALIGN_SIZE(newsize); | |
335 | ||
336 | if(newsize < MIN_SIZE_ALIGNED) { | |
337 | /* every data block must be at least MIN_SIZE_ALIGNED long */ | |
338 | newsize = MIN_SIZE_ALIGNED; | |
339 | } | |
340 | ||
341 | if (newsize > MEM_SIZE_ALIGNED) { | |
342 | return NULL; | |
343 | } | |
344 | ||
345 | LWIP_ASSERT("mem_realloc: legal memory", (u8_t *)rmem >= (u8_t *)ram && | |
346 | (u8_t *)rmem < (u8_t *)ram_end); | |
347 | ||
348 | if ((u8_t *)rmem < (u8_t *)ram || (u8_t *)rmem >= (u8_t *)ram_end) { | |
349 | LWIP_DEBUGF(MEM_DEBUG | 3, ("mem_realloc: illegal memory\n")); | |
350 | return rmem; | |
351 | } | |
352 | /* Get the corresponding struct mem ... */ | |
353 | mem = (struct mem *)((u8_t *)rmem - SIZEOF_STRUCT_MEM); | |
354 | /* ... and its offset pointer */ | |
355 | ptr = (u8_t *)mem - ram; | |
356 | ||
357 | size = mem->next - ptr - SIZEOF_STRUCT_MEM; | |
358 | LWIP_ASSERT("mem_realloc can only shrink memory", newsize <= size); | |
359 | if (newsize > size) { | |
360 | /* not supported */ | |
361 | return NULL; | |
362 | } | |
363 | if (newsize == size) { | |
364 | /* No change in size, simply return */ | |
365 | return rmem; | |
366 | } | |
367 | ||
368 | /* protect the heap from concurrent access */ | |
369 | sys_arch_sem_wait(mem_sem, 0); | |
370 | ||
371 | #if MEM_STATS | |
372 | lwip_stats.mem.used -= (size - newsize); | |
373 | #endif /* MEM_STATS */ | |
374 | ||
375 | mem2 = (struct mem *)&ram[mem->next]; | |
376 | if(mem2->used == 0) { | |
377 | /* The next struct is unused, we can simply move it at little */ | |
378 | mem_size_t next; | |
379 | /* remember the old next pointer */ | |
380 | next = mem2->next; | |
381 | /* create new struct mem which is moved directly after the shrinked mem */ | |
382 | ptr2 = ptr + SIZEOF_STRUCT_MEM + newsize; | |
383 | if (lfree == mem2) { | |
384 | lfree = (struct mem *)&ram[ptr2]; | |
385 | } | |
386 | mem2 = (struct mem *)&ram[ptr2]; | |
387 | mem2->used = 0; | |
388 | /* restore the next pointer */ | |
389 | mem2->next = next; | |
390 | /* link it back to mem */ | |
391 | mem2->prev = ptr; | |
392 | /* link mem to it */ | |
393 | mem->next = ptr2; | |
394 | /* last thing to restore linked list: as we have moved mem2, | |
395 | * let 'mem2->next->prev' point to mem2 again. but only if mem2->next is not | |
396 | * the end of the heap */ | |
397 | if (mem2->next != MEM_SIZE_ALIGNED) { | |
398 | ((struct mem *)&ram[mem2->next])->prev = ptr2; | |
399 | } | |
400 | /* no need to plug holes, we've already done that */ | |
401 | } else if (newsize + SIZEOF_STRUCT_MEM + MIN_SIZE_ALIGNED <= size) { | |
402 | /* Next struct is used but there's room for another struct mem with | |
403 | * at least MIN_SIZE_ALIGNED of data. | |
404 | * Old size ('size') must be big enough to contain at least 'newsize' plus a struct mem | |
405 | * ('SIZEOF_STRUCT_MEM') with some data ('MIN_SIZE_ALIGNED'). | |
406 | * @todo we could leave out MIN_SIZE_ALIGNED. We would create an empty | |
407 | * region that couldn't hold data, but when mem->next gets freed, | |
408 | * the 2 regions would be combined, resulting in more free memory */ | |
409 | ptr2 = ptr + SIZEOF_STRUCT_MEM + newsize; | |
410 | mem2 = (struct mem *)&ram[ptr2]; | |
411 | if (mem2 < lfree) { | |
412 | lfree = mem2; | |
413 | } | |
414 | mem2->used = 0; | |
415 | mem2->next = mem->next; | |
416 | mem2->prev = ptr; | |
417 | mem->next = ptr2; | |
418 | if (mem2->next != MEM_SIZE_ALIGNED) { | |
419 | ((struct mem *)&ram[mem2->next])->prev = ptr2; | |
420 | } | |
421 | /* the original mem->next is used, so no need to plug holes! */ | |
422 | } | |
423 | /* else { | |
424 | next struct mem is used but size between mem and mem2 is not big enough | |
425 | to create another struct mem | |
426 | -> don't do anyhting. | |
427 | -> the remaining space stays unused since it is too small | |
428 | } */ | |
429 | sys_sem_signal(mem_sem); | |
430 | return rmem; | |
431 | } | |
432 | ||
433 | /** | |
434 | * Adam's mem_malloc() plus solution for bug #17922 | |
435 | * Allocate a block of memory with a minimum of 'size' bytes. | |
436 | * | |
437 | * @param size is the minimum size of the requested block in bytes. | |
438 | * @return pointer to allocated memory or NULL if no free memory was found. | |
439 | * | |
440 | * Note that the returned value will always be aligned (as defined by MEM_ALIGNMENT). | |
441 | */ | |
442 | void * | |
443 | mem_malloc(mem_size_t size) | |
444 | { | |
445 | mem_size_t ptr, ptr2; | |
446 | struct mem *mem, *mem2; | |
447 | ||
448 | if (size == 0) { | |
449 | return NULL; | |
450 | } | |
451 | ||
452 | /* Expand the size of the allocated memory region so that we can | |
453 | adjust for alignment. */ | |
454 | size = LWIP_MEM_ALIGN_SIZE(size); | |
455 | ||
456 | if(size < MIN_SIZE_ALIGNED) { | |
457 | /* every data block must be at least MIN_SIZE_ALIGNED long */ | |
458 | size = MIN_SIZE_ALIGNED; | |
459 | } | |
460 | ||
461 | if (size > MEM_SIZE_ALIGNED) { | |
462 | return NULL; | |
463 | } | |
464 | ||
465 | /* protect the heap from concurrent access */ | |
466 | sys_arch_sem_wait(mem_sem, 0); | |
467 | ||
468 | /* Scan through the heap searching for a free block that is big enough, | |
469 | * beginning with the lowest free block. | |
470 | */ | |
471 | for (ptr = (u8_t *)lfree - ram; ptr < MEM_SIZE_ALIGNED - size; | |
472 | ptr = ((struct mem *)&ram[ptr])->next) { | |
473 | mem = (struct mem *)&ram[ptr]; | |
474 | ||
475 | if ((!mem->used) && | |
476 | (mem->next - (ptr + SIZEOF_STRUCT_MEM)) >= size) { | |
477 | /* mem is not used and at least perfect fit is possible: | |
478 | * mem->next - (ptr + SIZEOF_STRUCT_MEM) gives us the 'user data size' of mem */ | |
479 | ||
480 | if (mem->next - (ptr + SIZEOF_STRUCT_MEM) >= (size + SIZEOF_STRUCT_MEM + MIN_SIZE_ALIGNED)) { | |
481 | /* (in addition to the above, we test if another struct mem (SIZEOF_STRUCT_MEM) containing | |
482 | * at least MIN_SIZE_ALIGNED of data also fits in the 'user data space' of 'mem') | |
483 | * -> split large block, create empty remainder, | |
484 | * remainder must be large enough to contain MIN_SIZE_ALIGNED data: if | |
485 | * mem->next - (ptr + (2*SIZEOF_STRUCT_MEM)) == size, | |
486 | * struct mem would fit in but no data between mem2 and mem2->next | |
487 | * @todo we could leave out MIN_SIZE_ALIGNED. We would create an empty | |
488 | * region that couldn't hold data, but when mem->next gets freed, | |
489 | * the 2 regions would be combined, resulting in more free memory | |
490 | */ | |
491 | ptr2 = ptr + SIZEOF_STRUCT_MEM + size; | |
492 | /* create mem2 struct */ | |
493 | mem2 = (struct mem *)&ram[ptr2]; | |
494 | mem2->used = 0; | |
495 | mem2->next = mem->next; | |
496 | mem2->prev = ptr; | |
497 | /* and insert it between mem and mem->next */ | |
498 | mem->next = ptr2; | |
499 | mem->used = 1; | |
500 | ||
501 | if (mem2->next != MEM_SIZE_ALIGNED) { | |
502 | ((struct mem *)&ram[mem2->next])->prev = ptr2; | |
503 | } | |
504 | #if MEM_STATS | |
505 | lwip_stats.mem.used += (size + SIZEOF_STRUCT_MEM); | |
506 | if (lwip_stats.mem.max < lwip_stats.mem.used) { | |
507 | lwip_stats.mem.max = lwip_stats.mem.used; | |
508 | } | |
509 | #endif /* MEM_STATS */ | |
510 | } else { | |
511 | /* (a mem2 struct does no fit into the user data space of mem and mem->next will always | |
512 | * be used at this point: if not we have 2 unused structs in a row, plug_holes should have | |
513 | * take care of this). | |
514 | * -> near fit or excact fit: do not split, no mem2 creation | |
515 | * also can't move mem->next directly behind mem, since mem->next | |
516 | * will always be used at this point! | |
517 | */ | |
518 | mem->used = 1; | |
519 | #if MEM_STATS | |
520 | lwip_stats.mem.used += mem->next - ((u8_t *)mem - ram); | |
521 | if (lwip_stats.mem.max < lwip_stats.mem.used) { | |
522 | lwip_stats.mem.max = lwip_stats.mem.used; | |
523 | } | |
524 | #endif /* MEM_STATS */ | |
525 | } | |
526 | ||
527 | if (mem == lfree) { | |
528 | /* Find next free block after mem and update lowest free pointer */ | |
529 | while (lfree->used && lfree != ram_end) { | |
530 | lfree = (struct mem *)&ram[lfree->next]; | |
531 | } | |
532 | LWIP_ASSERT("mem_malloc: !lfree->used", ((lfree == ram_end) || (!lfree->used))); | |
533 | } | |
534 | sys_sem_signal(mem_sem); | |
535 | LWIP_ASSERT("mem_malloc: allocated memory not above ram_end.", | |
536 | (mem_ptr_t)mem + SIZEOF_STRUCT_MEM + size <= (mem_ptr_t)ram_end); | |
537 | LWIP_ASSERT("mem_malloc: allocated memory properly aligned.", | |
538 | (unsigned long)((u8_t *)mem + SIZEOF_STRUCT_MEM) % MEM_ALIGNMENT == 0); | |
539 | LWIP_ASSERT("mem_malloc: sanity check alignment", | |
540 | (((mem_ptr_t)mem) & (MEM_ALIGNMENT-1)) == 0); | |
541 | ||
542 | return (u8_t *)mem + SIZEOF_STRUCT_MEM; | |
543 | } | |
544 | } | |
545 | LWIP_DEBUGF(MEM_DEBUG | 2, ("mem_malloc: could not allocate %"S16_F" bytes\n", (s16_t)size)); | |
546 | #if MEM_STATS | |
547 | ++lwip_stats.mem.err; | |
548 | #endif /* MEM_STATS */ | |
549 | sys_sem_signal(mem_sem); | |
550 | return NULL; | |
551 | } | |
552 | ||
553 | #endif /* MEM_USE_POOLS */ | |
554 | /** | |
555 | * Contiguously allocates enough space for count objects that are size bytes | |
556 | * of memory each and returns a pointer to the allocated memory. | |
557 | * | |
558 | * The allocated memory is filled with bytes of value zero. | |
559 | * | |
560 | * @param count number of objects to allocate | |
561 | * @param size size of the objects to allocate | |
562 | * @return pointer to allocated memory / NULL pointer if there is an error | |
563 | */ | |
564 | void *mem_calloc(mem_size_t count, mem_size_t size) | |
565 | { | |
566 | void *p; | |
567 | ||
568 | /* allocate 'count' objects of size 'size' */ | |
569 | p = mem_malloc(count * size); | |
570 | if (p) { | |
571 | /* zero the memory */ | |
572 | memset(p, 0, count * size); | |
573 | } | |
574 | return p; | |
575 | } | |
576 | ||
577 | #endif /* !MEM_LIBC_MALLOC */ |