VirtualBox

source: vbox/trunk/src/VBox/Runtime/common/alloc/heapsimple.cpp@ 71494

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1/* $Id: heapsimple.cpp 69111 2017-10-17 14:26:02Z vboxsync $ */
2/** @file
3 * IPRT - A Simple Heap.
4 */
5
6/*
7 * Copyright (C) 2006-2017 Oracle Corporation
8 *
9 * This file is part of VirtualBox Open Source Edition (OSE), as
10 * available from http://www.virtualbox.org. This file is free software;
11 * you can redistribute it and/or modify it under the terms of the GNU
12 * General Public License (GPL) as published by the Free Software
13 * Foundation, in version 2 as it comes in the "COPYING" file of the
14 * VirtualBox OSE distribution. VirtualBox OSE is distributed in the
15 * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
16 *
17 * The contents of this file may alternatively be used under the terms
18 * of the Common Development and Distribution License Version 1.0
19 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the
20 * VirtualBox OSE distribution, in which case the provisions of the
21 * CDDL are applicable instead of those of the GPL.
22 *
23 * You may elect to license modified versions of this file under the
24 * terms and conditions of either the GPL or the CDDL or both.
25 */
26
27
28/*********************************************************************************************************************************
29* Header Files *
30*********************************************************************************************************************************/
31#define LOG_GROUP RTLOGGROUP_DEFAULT
32#include <iprt/heap.h>
33#include "internal/iprt.h"
34
35#include <iprt/assert.h>
36#include <iprt/asm.h>
37#include <iprt/err.h>
38#include <iprt/log.h>
39#include <iprt/string.h>
40#include <iprt/param.h>
41
42#include "internal/magics.h"
43
44
45/*********************************************************************************************************************************
46* Structures and Typedefs *
47*********************************************************************************************************************************/
48/** Pointer to the heap anchor block. */
49typedef struct RTHEAPSIMPLEINTERNAL *PRTHEAPSIMPLEINTERNAL;
50/** Pointer to a heap block. */
51typedef struct RTHEAPSIMPLEBLOCK *PRTHEAPSIMPLEBLOCK;
52/** Pointer to a free heap block. */
53typedef struct RTHEAPSIMPLEFREE *PRTHEAPSIMPLEFREE;
54
55/**
56 * Structure describing a simple heap block.
57 * If this block is allocated, it is followed by the user data.
58 * If this block is free, see RTHEAPSIMPLEFREE.
59 */
60typedef struct RTHEAPSIMPLEBLOCK
61{
62 /** The next block in the global block list. */
63 PRTHEAPSIMPLEBLOCK pNext;
64 /** The previous block in the global block list. */
65 PRTHEAPSIMPLEBLOCK pPrev;
66 /** Pointer to the heap anchor block. */
67 PRTHEAPSIMPLEINTERNAL pHeap;
68 /** Flags + magic. */
69 uintptr_t fFlags;
70} RTHEAPSIMPLEBLOCK;
71AssertCompileSizeAlignment(RTHEAPSIMPLEBLOCK, 16);
72
73/** The block is free if this flag is set. When cleared it's allocated. */
74#define RTHEAPSIMPLEBLOCK_FLAGS_FREE ((uintptr_t)RT_BIT(0))
75/** The magic value. */
76#define RTHEAPSIMPLEBLOCK_FLAGS_MAGIC ((uintptr_t)0xabcdef00)
77/** The mask that needs to be applied to RTHEAPSIMPLEBLOCK::fFlags to obtain the magic value. */
78#define RTHEAPSIMPLEBLOCK_FLAGS_MAGIC_MASK (~(uintptr_t)RT_BIT(0))
79
80/**
81 * Checks if the specified block is valid or not.
82 * @returns boolean answer.
83 * @param pBlock Pointer to a RTHEAPSIMPLEBLOCK structure.
84 */
85#define RTHEAPSIMPLEBLOCK_IS_VALID(pBlock) \
86 ( ((pBlock)->fFlags & RTHEAPSIMPLEBLOCK_FLAGS_MAGIC_MASK) == RTHEAPSIMPLEBLOCK_FLAGS_MAGIC )
87
88/**
89 * Checks if the specified block is valid and in use.
90 * @returns boolean answer.
91 * @param pBlock Pointer to a RTHEAPSIMPLEBLOCK structure.
92 */
93#define RTHEAPSIMPLEBLOCK_IS_VALID_USED(pBlock) \
94 ( ((pBlock)->fFlags & (RTHEAPSIMPLEBLOCK_FLAGS_MAGIC_MASK | RTHEAPSIMPLEBLOCK_FLAGS_FREE)) \
95 == RTHEAPSIMPLEBLOCK_FLAGS_MAGIC )
96
97/**
98 * Checks if the specified block is valid and free.
99 * @returns boolean answer.
100 * @param pBlock Pointer to a RTHEAPSIMPLEBLOCK structure.
101 */
102#define RTHEAPSIMPLEBLOCK_IS_VALID_FREE(pBlock) \
103 ( ((pBlock)->fFlags & (RTHEAPSIMPLEBLOCK_FLAGS_MAGIC_MASK | RTHEAPSIMPLEBLOCK_FLAGS_FREE)) \
104 == (RTHEAPSIMPLEBLOCK_FLAGS_MAGIC | RTHEAPSIMPLEBLOCK_FLAGS_FREE) )
105
106/**
107 * Checks if the specified block is free or not.
108 * @returns boolean answer.
109 * @param pBlock Pointer to a valid RTHEAPSIMPLEBLOCK structure.
110 */
111#define RTHEAPSIMPLEBLOCK_IS_FREE(pBlock) (!!((pBlock)->fFlags & RTHEAPSIMPLEBLOCK_FLAGS_FREE))
112
113/**
114 * A free heap block.
115 * This is an extended version of RTHEAPSIMPLEBLOCK that takes the unused
116 * user data to store free list pointers and a cached size value.
117 */
118typedef struct RTHEAPSIMPLEFREE
119{
120 /** Core stuff. */
121 RTHEAPSIMPLEBLOCK Core;
122 /** Pointer to the next free block. */
123 PRTHEAPSIMPLEFREE pNext;
124 /** Pointer to the previous free block. */
125 PRTHEAPSIMPLEFREE pPrev;
126 /** The size of the block (excluding the RTHEAPSIMPLEBLOCK part). */
127 size_t cb;
128 /** An alignment filler to make it a multiple of (sizeof(void *) * 2). */
129 size_t Alignment;
130} RTHEAPSIMPLEFREE;
131
132
133/**
134 * The heap anchor block.
135 * This structure is placed at the head of the memory block specified to RTHeapSimpleInit(),
136 * which means that the first RTHEAPSIMPLEBLOCK appears immediately after this structure.
137 */
138typedef struct RTHEAPSIMPLEINTERNAL
139{
140 /** The typical magic (RTHEAPSIMPLE_MAGIC). */
141 size_t uMagic;
142 /** The heap size. (This structure is included!) */
143 size_t cbHeap;
144 /** Pointer to the end of the heap. */
145 void *pvEnd;
146 /** The amount of free memory in the heap. */
147 size_t cbFree;
148 /** Free head pointer. */
149 PRTHEAPSIMPLEFREE pFreeHead;
150 /** Free tail pointer. */
151 PRTHEAPSIMPLEFREE pFreeTail;
152 /** Make the size of this structure is a multiple of 32. */
153 size_t auAlignment[2];
154} RTHEAPSIMPLEINTERNAL;
155AssertCompileSizeAlignment(RTHEAPSIMPLEINTERNAL, 32);
156
157
158/** The minimum allocation size. */
159#define RTHEAPSIMPLE_MIN_BLOCK (sizeof(RTHEAPSIMPLEBLOCK))
160AssertCompile(RTHEAPSIMPLE_MIN_BLOCK >= sizeof(RTHEAPSIMPLEBLOCK));
161AssertCompile(RTHEAPSIMPLE_MIN_BLOCK >= sizeof(RTHEAPSIMPLEFREE) - sizeof(RTHEAPSIMPLEBLOCK));
162
163/** The minimum and default alignment. */
164#define RTHEAPSIMPLE_ALIGNMENT (sizeof(RTHEAPSIMPLEBLOCK))
165
166
167/*********************************************************************************************************************************
168* Defined Constants And Macros *
169*********************************************************************************************************************************/
170#ifdef RT_STRICT
171# define RTHEAPSIMPLE_STRICT 1
172#endif
173
174#define ASSERT_L(a, b) AssertMsg((uintptr_t)(a) < (uintptr_t)(b), ("a=%p b=%p\n", (uintptr_t)(a), (uintptr_t)(b)))
175#define ASSERT_LE(a, b) AssertMsg((uintptr_t)(a) <= (uintptr_t)(b), ("a=%p b=%p\n", (uintptr_t)(a), (uintptr_t)(b)))
176#define ASSERT_G(a, b) AssertMsg((uintptr_t)(a) > (uintptr_t)(b), ("a=%p b=%p\n", (uintptr_t)(a), (uintptr_t)(b)))
177#define ASSERT_GE(a, b) AssertMsg((uintptr_t)(a) >= (uintptr_t)(b), ("a=%p b=%p\n", (uintptr_t)(a), (uintptr_t)(b)))
178#define ASSERT_ALIGN(a) AssertMsg(!((uintptr_t)(a) & (RTHEAPSIMPLE_ALIGNMENT - 1)), ("a=%p\n", (uintptr_t)(a)))
179
180#define ASSERT_PREV(pHeapInt, pBlock) \
181 do { ASSERT_ALIGN((pBlock)->pPrev); \
182 if ((pBlock)->pPrev) \
183 { \
184 ASSERT_L((pBlock)->pPrev, (pBlock)); \
185 ASSERT_GE((pBlock)->pPrev, (pHeapInt) + 1); \
186 } \
187 else \
188 Assert((pBlock) == (PRTHEAPSIMPLEBLOCK)((pHeapInt) + 1)); \
189 } while (0)
190
191#define ASSERT_NEXT(pHeap, pBlock) \
192 do { ASSERT_ALIGN((pBlock)->pNext); \
193 if ((pBlock)->pNext) \
194 { \
195 ASSERT_L((pBlock)->pNext, (pHeapInt)->pvEnd); \
196 ASSERT_G((pBlock)->pNext, (pBlock)); \
197 } \
198 } while (0)
199
200#define ASSERT_BLOCK(pHeapInt, pBlock) \
201 do { AssertMsg(RTHEAPSIMPLEBLOCK_IS_VALID(pBlock), ("%#x\n", (pBlock)->fFlags)); \
202 AssertMsg((pBlock)->pHeap == (pHeapInt), ("%p != %p\n", (pBlock)->pHeap, (pHeapInt))); \
203 ASSERT_GE((pBlock), (pHeapInt) + 1); \
204 ASSERT_L((pBlock), (pHeapInt)->pvEnd); \
205 ASSERT_NEXT(pHeapInt, pBlock); \
206 ASSERT_PREV(pHeapInt, pBlock); \
207 } while (0)
208
209#define ASSERT_BLOCK_USED(pHeapInt, pBlock) \
210 do { AssertMsg(RTHEAPSIMPLEBLOCK_IS_VALID_USED((pBlock)), ("%#x\n", (pBlock)->fFlags)); \
211 AssertMsg((pBlock)->pHeap == (pHeapInt), ("%p != %p\n", (pBlock)->pHeap, (pHeapInt))); \
212 ASSERT_GE((pBlock), (pHeapInt) + 1); \
213 ASSERT_L((pBlock), (pHeapInt)->pvEnd); \
214 ASSERT_NEXT(pHeapInt, pBlock); \
215 ASSERT_PREV(pHeapInt, pBlock); \
216 } while (0)
217
218#define ASSERT_FREE_PREV(pHeapInt, pBlock) \
219 do { ASSERT_ALIGN((pBlock)->pPrev); \
220 if ((pBlock)->pPrev) \
221 { \
222 ASSERT_GE((pBlock)->pPrev, (pHeapInt)->pFreeHead); \
223 ASSERT_L((pBlock)->pPrev, (pBlock)); \
224 ASSERT_LE((pBlock)->pPrev, (pBlock)->Core.pPrev); \
225 } \
226 else \
227 Assert((pBlock) == (pHeapInt)->pFreeHead); \
228 } while (0)
229
230#define ASSERT_FREE_NEXT(pHeapInt, pBlock) \
231 do { ASSERT_ALIGN((pBlock)->pNext); \
232 if ((pBlock)->pNext) \
233 { \
234 ASSERT_LE((pBlock)->pNext, (pHeapInt)->pFreeTail); \
235 ASSERT_G((pBlock)->pNext, (pBlock)); \
236 ASSERT_GE((pBlock)->pNext, (pBlock)->Core.pNext); \
237 } \
238 else \
239 Assert((pBlock) == (pHeapInt)->pFreeTail); \
240 } while (0)
241
242#ifdef RTHEAPSIMPLE_STRICT
243# define ASSERT_FREE_CB(pHeapInt, pBlock) \
244 do { size_t cbCalc = ((pBlock)->Core.pNext ? (uintptr_t)(pBlock)->Core.pNext : (uintptr_t)(pHeapInt)->pvEnd) \
245 - (uintptr_t)(pBlock) - sizeof(RTHEAPSIMPLEBLOCK); \
246 AssertMsg((pBlock)->cb == cbCalc, ("cb=%#zx cbCalc=%#zx\n", (pBlock)->cb, cbCalc)); \
247 } while (0)
248#else
249# define ASSERT_FREE_CB(pHeapInt, pBlock) do {} while (0)
250#endif
251
252/** Asserts that a free block is valid. */
253#define ASSERT_BLOCK_FREE(pHeapInt, pBlock) \
254 do { ASSERT_BLOCK(pHeapInt, &(pBlock)->Core); \
255 Assert(RTHEAPSIMPLEBLOCK_IS_VALID_FREE(&(pBlock)->Core)); \
256 ASSERT_GE((pBlock), (pHeapInt)->pFreeHead); \
257 ASSERT_LE((pBlock), (pHeapInt)->pFreeTail); \
258 ASSERT_FREE_NEXT(pHeapInt, pBlock); \
259 ASSERT_FREE_PREV(pHeapInt, pBlock); \
260 ASSERT_FREE_CB(pHeapInt, pBlock); \
261 } while (0)
262
263/** Asserts that the heap anchor block is ok. */
264#define ASSERT_ANCHOR(pHeapInt) \
265 do { AssertPtr(pHeapInt);\
266 Assert((pHeapInt)->uMagic == RTHEAPSIMPLE_MAGIC); \
267 } while (0)
268
269
270/*********************************************************************************************************************************
271* Internal Functions *
272*********************************************************************************************************************************/
273#ifdef RTHEAPSIMPLE_STRICT
274static void rtHeapSimpleAssertAll(PRTHEAPSIMPLEINTERNAL pHeapInt);
275#endif
276static PRTHEAPSIMPLEBLOCK rtHeapSimpleAllocBlock(PRTHEAPSIMPLEINTERNAL pHeapInt, size_t cb, size_t uAlignment);
277static void rtHeapSimpleFreeBlock(PRTHEAPSIMPLEINTERNAL pHeapInt, PRTHEAPSIMPLEBLOCK pBlock);
278
279
280RTDECL(int) RTHeapSimpleInit(PRTHEAPSIMPLE phHeap, void *pvMemory, size_t cbMemory)
281{
282 PRTHEAPSIMPLEINTERNAL pHeapInt;
283 PRTHEAPSIMPLEFREE pFree;
284 unsigned i;
285
286 /*
287 * Validate input. The imposed minimum heap size is just a convenient value.
288 */
289 AssertReturn(cbMemory >= PAGE_SIZE, VERR_INVALID_PARAMETER);
290 AssertPtrReturn(pvMemory, VERR_INVALID_POINTER);
291 AssertReturn((uintptr_t)pvMemory + (cbMemory - 1) > (uintptr_t)cbMemory, VERR_INVALID_PARAMETER);
292
293 /*
294 * Place the heap anchor block at the start of the heap memory,
295 * enforce 32 byte alignment of it. Also align the heap size correctly.
296 */
297 pHeapInt = (PRTHEAPSIMPLEINTERNAL)pvMemory;
298 if ((uintptr_t)pvMemory & 31)
299 {
300 const uintptr_t off = 32 - ((uintptr_t)pvMemory & 31);
301 cbMemory -= off;
302 pHeapInt = (PRTHEAPSIMPLEINTERNAL)((uintptr_t)pvMemory + off);
303 }
304 cbMemory &= ~(RTHEAPSIMPLE_ALIGNMENT - 1);
305
306
307 /* Init the heap anchor block. */
308 pHeapInt->uMagic = RTHEAPSIMPLE_MAGIC;
309 pHeapInt->pvEnd = (uint8_t *)pHeapInt + cbMemory;
310 pHeapInt->cbHeap = cbMemory;
311 pHeapInt->cbFree = cbMemory
312 - sizeof(RTHEAPSIMPLEBLOCK)
313 - sizeof(RTHEAPSIMPLEINTERNAL);
314 pHeapInt->pFreeTail = pHeapInt->pFreeHead = (PRTHEAPSIMPLEFREE)(pHeapInt + 1);
315 for (i = 0; i < RT_ELEMENTS(pHeapInt->auAlignment); i++)
316 pHeapInt->auAlignment[i] = ~(size_t)0;
317
318 /* Init the single free block. */
319 pFree = pHeapInt->pFreeHead;
320 pFree->Core.pNext = NULL;
321 pFree->Core.pPrev = NULL;
322 pFree->Core.pHeap = pHeapInt;
323 pFree->Core.fFlags = RTHEAPSIMPLEBLOCK_FLAGS_MAGIC | RTHEAPSIMPLEBLOCK_FLAGS_FREE;
324 pFree->pNext = NULL;
325 pFree->pPrev = NULL;
326 pFree->cb = pHeapInt->cbFree;
327
328 *phHeap = pHeapInt;
329
330#ifdef RTHEAPSIMPLE_STRICT
331 rtHeapSimpleAssertAll(pHeapInt);
332#endif
333 return VINF_SUCCESS;
334}
335RT_EXPORT_SYMBOL(RTHeapSimpleInit);
336
337
338RTDECL(int) RTHeapSimpleRelocate(RTHEAPSIMPLE hHeap, uintptr_t offDelta)
339{
340 PRTHEAPSIMPLEINTERNAL pHeapInt = hHeap;
341 PRTHEAPSIMPLEFREE pCur;
342
343 /*
344 * Validate input.
345 */
346 AssertPtrReturn(pHeapInt, VERR_INVALID_HANDLE);
347 AssertReturn(pHeapInt->uMagic == RTHEAPSIMPLE_MAGIC, VERR_INVALID_HANDLE);
348 AssertMsgReturn((uintptr_t)pHeapInt - (uintptr_t)pHeapInt->pvEnd + pHeapInt->cbHeap == offDelta,
349 ("offDelta=%p, expected=%p\n", offDelta, (uintptr_t)pHeapInt->pvEnd - pHeapInt->cbHeap - (uintptr_t)pHeapInt),
350 VERR_INVALID_PARAMETER);
351
352 /*
353 * Relocate the heap anchor block.
354 */
355#define RELOCATE_IT(var, type, offDelta) do { if (RT_UNLIKELY((var) != NULL)) { (var) = (type)((uintptr_t)(var) + offDelta); } } while (0)
356 RELOCATE_IT(pHeapInt->pvEnd, void *, offDelta);
357 RELOCATE_IT(pHeapInt->pFreeHead, PRTHEAPSIMPLEFREE, offDelta);
358 RELOCATE_IT(pHeapInt->pFreeTail, PRTHEAPSIMPLEFREE, offDelta);
359
360 /*
361 * Walk the heap blocks.
362 */
363 for (pCur = (PRTHEAPSIMPLEFREE)(pHeapInt + 1);
364 pCur && (uintptr_t)pCur < (uintptr_t)pHeapInt->pvEnd;
365 pCur = (PRTHEAPSIMPLEFREE)pCur->Core.pNext)
366 {
367 RELOCATE_IT(pCur->Core.pNext, PRTHEAPSIMPLEBLOCK, offDelta);
368 RELOCATE_IT(pCur->Core.pPrev, PRTHEAPSIMPLEBLOCK, offDelta);
369 RELOCATE_IT(pCur->Core.pHeap, PRTHEAPSIMPLEINTERNAL, offDelta);
370 if (RTHEAPSIMPLEBLOCK_IS_FREE(&pCur->Core))
371 {
372 RELOCATE_IT(pCur->pNext, PRTHEAPSIMPLEFREE, offDelta);
373 RELOCATE_IT(pCur->pPrev, PRTHEAPSIMPLEFREE, offDelta);
374 }
375 }
376#undef RELOCATE_IT
377
378#ifdef RTHEAPSIMPLE_STRICT
379 /*
380 * Give it a once over before we return.
381 */
382 rtHeapSimpleAssertAll(pHeapInt);
383#endif
384 return VINF_SUCCESS;
385}
386RT_EXPORT_SYMBOL(RTHeapSimpleRelocate);
387
388
389RTDECL(void *) RTHeapSimpleAlloc(RTHEAPSIMPLE hHeap, size_t cb, size_t cbAlignment)
390{
391 PRTHEAPSIMPLEINTERNAL pHeapInt = hHeap;
392 PRTHEAPSIMPLEBLOCK pBlock;
393
394 /*
395 * Validate and adjust the input.
396 */
397 AssertPtrReturn(pHeapInt, NULL);
398 if (cb < RTHEAPSIMPLE_MIN_BLOCK)
399 cb = RTHEAPSIMPLE_MIN_BLOCK;
400 else
401 cb = RT_ALIGN_Z(cb, RTHEAPSIMPLE_ALIGNMENT);
402 if (!cbAlignment)
403 cbAlignment = RTHEAPSIMPLE_ALIGNMENT;
404 else
405 {
406 Assert(!(cbAlignment & (cbAlignment - 1)));
407 Assert((cbAlignment & ~(cbAlignment - 1)) == cbAlignment);
408 if (cbAlignment < RTHEAPSIMPLE_ALIGNMENT)
409 cbAlignment = RTHEAPSIMPLE_ALIGNMENT;
410 }
411
412 /*
413 * Do the allocation.
414 */
415 pBlock = rtHeapSimpleAllocBlock(pHeapInt, cb, cbAlignment);
416 if (RT_LIKELY(pBlock))
417 {
418 void *pv = pBlock + 1;
419 return pv;
420 }
421 return NULL;
422}
423RT_EXPORT_SYMBOL(RTHeapSimpleAlloc);
424
425
426RTDECL(void *) RTHeapSimpleAllocZ(RTHEAPSIMPLE hHeap, size_t cb, size_t cbAlignment)
427{
428 PRTHEAPSIMPLEINTERNAL pHeapInt = hHeap;
429 PRTHEAPSIMPLEBLOCK pBlock;
430
431 /*
432 * Validate and adjust the input.
433 */
434 AssertPtrReturn(pHeapInt, NULL);
435 if (cb < RTHEAPSIMPLE_MIN_BLOCK)
436 cb = RTHEAPSIMPLE_MIN_BLOCK;
437 else
438 cb = RT_ALIGN_Z(cb, RTHEAPSIMPLE_ALIGNMENT);
439 if (!cbAlignment)
440 cbAlignment = RTHEAPSIMPLE_ALIGNMENT;
441 else
442 {
443 Assert(!(cbAlignment & (cbAlignment - 1)));
444 Assert((cbAlignment & ~(cbAlignment - 1)) == cbAlignment);
445 if (cbAlignment < RTHEAPSIMPLE_ALIGNMENT)
446 cbAlignment = RTHEAPSIMPLE_ALIGNMENT;
447 }
448
449 /*
450 * Do the allocation.
451 */
452 pBlock = rtHeapSimpleAllocBlock(pHeapInt, cb, cbAlignment);
453 if (RT_LIKELY(pBlock))
454 {
455 void *pv = pBlock + 1;
456 memset(pv, 0, cb);
457 return pv;
458 }
459 return NULL;
460}
461RT_EXPORT_SYMBOL(RTHeapSimpleAllocZ);
462
463
464/**
465 * Allocates a block of memory from the specified heap.
466 *
467 * No parameter validation or adjustment is performed.
468 *
469 * @returns Pointer to the allocated block.
470 * @returns NULL on failure.
471 *
472 * @param pHeapInt The heap.
473 * @param cb Size of the memory block to allocate.
474 * @param uAlignment The alignment specifications for the allocated block.
475 */
476static PRTHEAPSIMPLEBLOCK rtHeapSimpleAllocBlock(PRTHEAPSIMPLEINTERNAL pHeapInt, size_t cb, size_t uAlignment)
477{
478 PRTHEAPSIMPLEBLOCK pRet = NULL;
479 PRTHEAPSIMPLEFREE pFree;
480
481#ifdef RTHEAPSIMPLE_STRICT
482 rtHeapSimpleAssertAll(pHeapInt);
483#endif
484
485 /*
486 * Search for a fitting block from the lower end of the heap.
487 */
488 for (pFree = pHeapInt->pFreeHead;
489 pFree;
490 pFree = pFree->pNext)
491 {
492 uintptr_t offAlign;
493 ASSERT_BLOCK_FREE(pHeapInt, pFree);
494
495 /*
496 * Match for size and alignment.
497 */
498 if (pFree->cb < cb)
499 continue;
500 offAlign = (uintptr_t)(&pFree->Core + 1) & (uAlignment - 1);
501 if (offAlign)
502 {
503 RTHEAPSIMPLEFREE Free;
504 PRTHEAPSIMPLEBLOCK pPrev;
505
506 offAlign = uAlignment - offAlign;
507 if (pFree->cb - offAlign < cb)
508 continue;
509
510 /*
511 * Make a stack copy of the free block header and adjust the pointer.
512 */
513 Free = *pFree;
514 pFree = (PRTHEAPSIMPLEFREE)((uintptr_t)pFree + offAlign);
515
516 /*
517 * Donate offAlign bytes to the node in front of us.
518 * If we're the head node, we'll have to create a fake node. We'll
519 * mark it USED for simplicity.
520 *
521 * (Should this policy of donating memory to the guy in front of us
522 * cause big 'leaks', we could create a new free node if there is room
523 * for that.)
524 */
525 pPrev = Free.Core.pPrev;
526 if (pPrev)
527 {
528 AssertMsg(!RTHEAPSIMPLEBLOCK_IS_FREE(pPrev), ("Impossible!\n"));
529 pPrev->pNext = &pFree->Core;
530 }
531 else
532 {
533 pPrev = (PRTHEAPSIMPLEBLOCK)(pHeapInt + 1);
534 Assert(pPrev == &pFree->Core);
535 pPrev->pPrev = NULL;
536 pPrev->pNext = &pFree->Core;
537 pPrev->pHeap = pHeapInt;
538 pPrev->fFlags = RTHEAPSIMPLEBLOCK_FLAGS_MAGIC;
539 }
540 pHeapInt->cbFree -= offAlign;
541
542 /*
543 * Recreate pFree in the new position and adjust the neighbors.
544 */
545 *pFree = Free;
546
547 /* the core */
548 if (pFree->Core.pNext)
549 pFree->Core.pNext->pPrev = &pFree->Core;
550 pFree->Core.pPrev = pPrev;
551
552 /* the free part */
553 pFree->cb -= offAlign;
554 if (pFree->pNext)
555 pFree->pNext->pPrev = pFree;
556 else
557 pHeapInt->pFreeTail = pFree;
558 if (pFree->pPrev)
559 pFree->pPrev->pNext = pFree;
560 else
561 pHeapInt->pFreeHead = pFree;
562 ASSERT_BLOCK_FREE(pHeapInt, pFree);
563 ASSERT_BLOCK_USED(pHeapInt, pPrev);
564 }
565
566 /*
567 * Split off a new FREE block?
568 */
569 if (pFree->cb >= cb + RT_ALIGN_Z(sizeof(RTHEAPSIMPLEFREE), RTHEAPSIMPLE_ALIGNMENT))
570 {
571 /*
572 * Move the FREE block up to make room for the new USED block.
573 */
574 PRTHEAPSIMPLEFREE pNew = (PRTHEAPSIMPLEFREE)((uintptr_t)&pFree->Core + cb + sizeof(RTHEAPSIMPLEBLOCK));
575
576 pNew->Core.pNext = pFree->Core.pNext;
577 if (pFree->Core.pNext)
578 pFree->Core.pNext->pPrev = &pNew->Core;
579 pNew->Core.pPrev = &pFree->Core;
580 pNew->Core.pHeap = pHeapInt;
581 pNew->Core.fFlags = RTHEAPSIMPLEBLOCK_FLAGS_MAGIC | RTHEAPSIMPLEBLOCK_FLAGS_FREE;
582
583 pNew->pNext = pFree->pNext;
584 if (pNew->pNext)
585 pNew->pNext->pPrev = pNew;
586 else
587 pHeapInt->pFreeTail = pNew;
588 pNew->pPrev = pFree->pPrev;
589 if (pNew->pPrev)
590 pNew->pPrev->pNext = pNew;
591 else
592 pHeapInt->pFreeHead = pNew;
593 pNew->cb = (pNew->Core.pNext ? (uintptr_t)pNew->Core.pNext : (uintptr_t)pHeapInt->pvEnd) \
594 - (uintptr_t)pNew - sizeof(RTHEAPSIMPLEBLOCK);
595 ASSERT_BLOCK_FREE(pHeapInt, pNew);
596
597 /*
598 * Update the old FREE node making it a USED node.
599 */
600 pFree->Core.fFlags &= ~RTHEAPSIMPLEBLOCK_FLAGS_FREE;
601 pFree->Core.pNext = &pNew->Core;
602 pHeapInt->cbFree -= pFree->cb;
603 pHeapInt->cbFree += pNew->cb;
604 pRet = &pFree->Core;
605 ASSERT_BLOCK_USED(pHeapInt, pRet);
606 }
607 else
608 {
609 /*
610 * Link it out of the free list.
611 */
612 if (pFree->pNext)
613 pFree->pNext->pPrev = pFree->pPrev;
614 else
615 pHeapInt->pFreeTail = pFree->pPrev;
616 if (pFree->pPrev)
617 pFree->pPrev->pNext = pFree->pNext;
618 else
619 pHeapInt->pFreeHead = pFree->pNext;
620
621 /*
622 * Convert it to a used block.
623 */
624 pHeapInt->cbFree -= pFree->cb;
625 pFree->Core.fFlags &= ~RTHEAPSIMPLEBLOCK_FLAGS_FREE;
626 pRet = &pFree->Core;
627 ASSERT_BLOCK_USED(pHeapInt, pRet);
628 }
629 break;
630 }
631
632#ifdef RTHEAPSIMPLE_STRICT
633 rtHeapSimpleAssertAll(pHeapInt);
634#endif
635 return pRet;
636}
637
638
639RTDECL(void) RTHeapSimpleFree(RTHEAPSIMPLE hHeap, void *pv)
640{
641 PRTHEAPSIMPLEINTERNAL pHeapInt;
642 PRTHEAPSIMPLEBLOCK pBlock;
643
644 /*
645 * Validate input.
646 */
647 if (!pv)
648 return;
649 AssertPtr(pv);
650 Assert(RT_ALIGN_P(pv, RTHEAPSIMPLE_ALIGNMENT) == pv);
651
652 /*
653 * Get the block and heap. If in strict mode, validate these.
654 */
655 pBlock = (PRTHEAPSIMPLEBLOCK)pv - 1;
656 pHeapInt = pBlock->pHeap;
657 ASSERT_BLOCK_USED(pHeapInt, pBlock);
658 ASSERT_ANCHOR(pHeapInt);
659 Assert(pHeapInt == (PRTHEAPSIMPLEINTERNAL)hHeap || !hHeap); RT_NOREF_PV(hHeap);
660
661#ifdef RTHEAPSIMPLE_FREE_POISON
662 /*
663 * Poison the block.
664 */
665 const size_t cbBlock = (pBlock->pNext ? (uintptr_t)pBlock->pNext : (uintptr_t)pHeapInt->pvEnd)
666 - (uintptr_t)pBlock - sizeof(RTHEAPSIMPLEBLOCK);
667 memset(pBlock + 1, RTHEAPSIMPLE_FREE_POISON, cbBlock);
668#endif
669
670 /*
671 * Call worker which does the actual job.
672 */
673 rtHeapSimpleFreeBlock(pHeapInt, pBlock);
674}
675RT_EXPORT_SYMBOL(RTHeapSimpleFree);
676
677
678/**
679 * Free a memory block.
680 *
681 * @param pHeapInt The heap.
682 * @param pBlock The memory block to free.
683 */
684static void rtHeapSimpleFreeBlock(PRTHEAPSIMPLEINTERNAL pHeapInt, PRTHEAPSIMPLEBLOCK pBlock)
685{
686 PRTHEAPSIMPLEFREE pFree = (PRTHEAPSIMPLEFREE)pBlock;
687 PRTHEAPSIMPLEFREE pLeft;
688 PRTHEAPSIMPLEFREE pRight;
689
690#ifdef RTHEAPSIMPLE_STRICT
691 rtHeapSimpleAssertAll(pHeapInt);
692#endif
693
694 /*
695 * Look for the closest free list blocks by walking the blocks right
696 * of us (both lists are sorted by address).
697 */
698 pLeft = NULL;
699 pRight = NULL;
700 if (pHeapInt->pFreeTail)
701 {
702 pRight = (PRTHEAPSIMPLEFREE)pFree->Core.pNext;
703 while (pRight && !RTHEAPSIMPLEBLOCK_IS_FREE(&pRight->Core))
704 {
705 ASSERT_BLOCK(pHeapInt, &pRight->Core);
706 pRight = (PRTHEAPSIMPLEFREE)pRight->Core.pNext;
707 }
708 if (!pRight)
709 pLeft = pHeapInt->pFreeTail;
710 else
711 {
712 ASSERT_BLOCK_FREE(pHeapInt, pRight);
713 pLeft = pRight->pPrev;
714 }
715 if (pLeft)
716 ASSERT_BLOCK_FREE(pHeapInt, pLeft);
717 }
718 AssertMsgReturnVoid(pLeft != pFree, ("Freed twice! pv=%p (pBlock=%p)\n", pBlock + 1, pBlock));
719 ASSERT_L(pLeft, pFree);
720 Assert(!pRight || (uintptr_t)pRight > (uintptr_t)pFree);
721 Assert(!pLeft || pLeft->pNext == pRight);
722
723 /*
724 * Insert at the head of the free block list?
725 */
726 if (!pLeft)
727 {
728 Assert(pRight == pHeapInt->pFreeHead);
729 pFree->Core.fFlags |= RTHEAPSIMPLEBLOCK_FLAGS_FREE;
730 pFree->pPrev = NULL;
731 pFree->pNext = pRight;
732 if (pRight)
733 pRight->pPrev = pFree;
734 else
735 pHeapInt->pFreeTail = pFree;
736 pHeapInt->pFreeHead = pFree;
737 }
738 else
739 {
740 /*
741 * Can we merge with left hand free block?
742 */
743 if (pLeft->Core.pNext == &pFree->Core)
744 {
745 pLeft->Core.pNext = pFree->Core.pNext;
746 if (pFree->Core.pNext)
747 pFree->Core.pNext->pPrev = &pLeft->Core;
748 pHeapInt->cbFree -= pLeft->cb;
749 pFree = pLeft;
750 }
751 /*
752 * No, just link it into the free list then.
753 */
754 else
755 {
756 pFree->Core.fFlags |= RTHEAPSIMPLEBLOCK_FLAGS_FREE;
757 pFree->pNext = pRight;
758 pFree->pPrev = pLeft;
759 pLeft->pNext = pFree;
760 if (pRight)
761 pRight->pPrev = pFree;
762 else
763 pHeapInt->pFreeTail = pFree;
764 }
765 }
766
767 /*
768 * Can we merge with right hand free block?
769 */
770 if ( pRight
771 && pRight->Core.pPrev == &pFree->Core)
772 {
773 /* core */
774 pFree->Core.pNext = pRight->Core.pNext;
775 if (pRight->Core.pNext)
776 pRight->Core.pNext->pPrev = &pFree->Core;
777
778 /* free */
779 pFree->pNext = pRight->pNext;
780 if (pRight->pNext)
781 pRight->pNext->pPrev = pFree;
782 else
783 pHeapInt->pFreeTail = pFree;
784 pHeapInt->cbFree -= pRight->cb;
785 }
786
787 /*
788 * Calculate the size and update free stats.
789 */
790 pFree->cb = (pFree->Core.pNext ? (uintptr_t)pFree->Core.pNext : (uintptr_t)pHeapInt->pvEnd)
791 - (uintptr_t)pFree - sizeof(RTHEAPSIMPLEBLOCK);
792 pHeapInt->cbFree += pFree->cb;
793 ASSERT_BLOCK_FREE(pHeapInt, pFree);
794
795#ifdef RTHEAPSIMPLE_STRICT
796 rtHeapSimpleAssertAll(pHeapInt);
797#endif
798}
799
800
801#ifdef RTHEAPSIMPLE_STRICT
802/**
803 * Internal consistency check (relying on assertions).
804 * @param pHeapInt
805 */
806static void rtHeapSimpleAssertAll(PRTHEAPSIMPLEINTERNAL pHeapInt)
807{
808 PRTHEAPSIMPLEFREE pPrev = NULL;
809 PRTHEAPSIMPLEFREE pPrevFree = NULL;
810 PRTHEAPSIMPLEFREE pBlock;
811 for (pBlock = (PRTHEAPSIMPLEFREE)(pHeapInt + 1);
812 pBlock;
813 pBlock = (PRTHEAPSIMPLEFREE)pBlock->Core.pNext)
814 {
815 if (RTHEAPSIMPLEBLOCK_IS_FREE(&pBlock->Core))
816 {
817 ASSERT_BLOCK_FREE(pHeapInt, pBlock);
818 Assert(pBlock->pPrev == pPrevFree);
819 Assert(pPrevFree || pHeapInt->pFreeHead == pBlock);
820 pPrevFree = pBlock;
821 }
822 else
823 ASSERT_BLOCK_USED(pHeapInt, &pBlock->Core);
824 Assert(!pPrev || pPrev == (PRTHEAPSIMPLEFREE)pBlock->Core.pPrev);
825 pPrev = pBlock;
826 }
827 Assert(pHeapInt->pFreeTail == pPrevFree);
828}
829#endif
830
831
832RTDECL(size_t) RTHeapSimpleSize(RTHEAPSIMPLE hHeap, void *pv)
833{
834 PRTHEAPSIMPLEINTERNAL pHeapInt;
835 PRTHEAPSIMPLEBLOCK pBlock;
836 size_t cbBlock;
837
838 /*
839 * Validate input.
840 */
841 if (!pv)
842 return 0;
843 AssertPtrReturn(pv, 0);
844 AssertReturn(RT_ALIGN_P(pv, RTHEAPSIMPLE_ALIGNMENT) == pv, 0);
845
846 /*
847 * Get the block and heap. If in strict mode, validate these.
848 */
849 pBlock = (PRTHEAPSIMPLEBLOCK)pv - 1;
850 pHeapInt = pBlock->pHeap;
851 ASSERT_BLOCK_USED(pHeapInt, pBlock);
852 ASSERT_ANCHOR(pHeapInt);
853 Assert(pHeapInt == (PRTHEAPSIMPLEINTERNAL)hHeap || !hHeap); RT_NOREF_PV(hHeap);
854
855 /*
856 * Calculate the block size.
857 */
858 cbBlock = (pBlock->pNext ? (uintptr_t)pBlock->pNext : (uintptr_t)pHeapInt->pvEnd)
859 - (uintptr_t)pBlock- sizeof(RTHEAPSIMPLEBLOCK);
860 return cbBlock;
861}
862RT_EXPORT_SYMBOL(RTHeapSimpleSize);
863
864
865RTDECL(size_t) RTHeapSimpleGetHeapSize(RTHEAPSIMPLE hHeap)
866{
867 PRTHEAPSIMPLEINTERNAL pHeapInt;
868
869 if (hHeap == NIL_RTHEAPSIMPLE)
870 return 0;
871
872 pHeapInt = hHeap;
873 AssertPtrReturn(pHeapInt, 0);
874 ASSERT_ANCHOR(pHeapInt);
875 return pHeapInt->cbHeap;
876}
877RT_EXPORT_SYMBOL(RTHeapSimpleGetHeapSize);
878
879
880RTDECL(size_t) RTHeapSimpleGetFreeSize(RTHEAPSIMPLE hHeap)
881{
882 PRTHEAPSIMPLEINTERNAL pHeapInt;
883
884 if (hHeap == NIL_RTHEAPSIMPLE)
885 return 0;
886
887 pHeapInt = hHeap;
888 AssertPtrReturn(pHeapInt, 0);
889 ASSERT_ANCHOR(pHeapInt);
890 return pHeapInt->cbFree;
891}
892RT_EXPORT_SYMBOL(RTHeapSimpleGetFreeSize);
893
894
895RTDECL(void) RTHeapSimpleDump(RTHEAPSIMPLE hHeap, PFNRTHEAPSIMPLEPRINTF pfnPrintf)
896{
897 PRTHEAPSIMPLEINTERNAL pHeapInt = (PRTHEAPSIMPLEINTERNAL)hHeap;
898 PRTHEAPSIMPLEFREE pBlock;
899
900 pfnPrintf("**** Dumping Heap %p - cbHeap=%zx cbFree=%zx ****\n",
901 hHeap, pHeapInt->cbHeap, pHeapInt->cbFree);
902
903 for (pBlock = (PRTHEAPSIMPLEFREE)(pHeapInt + 1);
904 pBlock;
905 pBlock = (PRTHEAPSIMPLEFREE)pBlock->Core.pNext)
906 {
907 size_t cb = (pBlock->pNext ? (uintptr_t)pBlock->Core.pNext : (uintptr_t)pHeapInt->pvEnd)
908 - (uintptr_t)pBlock - sizeof(RTHEAPSIMPLEBLOCK);
909 if (RTHEAPSIMPLEBLOCK_IS_FREE(&pBlock->Core))
910 pfnPrintf("%p %06x FREE pNext=%p pPrev=%p fFlags=%#x cb=%#06x : cb=%#06x pNext=%p pPrev=%p\n",
911 pBlock, (uintptr_t)pBlock - (uintptr_t)(pHeapInt + 1), pBlock->Core.pNext, pBlock->Core.pPrev, pBlock->Core.fFlags, cb,
912 pBlock->cb, pBlock->pNext, pBlock->pPrev);
913 else
914 pfnPrintf("%p %06x USED pNext=%p pPrev=%p fFlags=%#x cb=%#06x\n",
915 pBlock, (uintptr_t)pBlock - (uintptr_t)(pHeapInt + 1), pBlock->Core.pNext, pBlock->Core.pPrev, pBlock->Core.fFlags, cb);
916 }
917 pfnPrintf("**** Done dumping Heap %p ****\n", hHeap);
918}
919RT_EXPORT_SYMBOL(RTHeapSimpleDump);
920
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