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source: vbox/trunk/include/iprt/mem.h@ 25475

Last change on this file since 25475 was 25347, checked in by vboxsync, 15 years ago

iprt/autores.h -> iprt/cpp/autores.h

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1/** @file
2 * IPRT - Memory Management and Manipulation.
3 */
4
5/*
6 * Copyright (C) 2006-2007 Sun Microsystems, Inc.
7 *
8 * This file is part of VirtualBox Open Source Edition (OSE), as
9 * available from http://www.virtualbox.org. This file is free software;
10 * you can redistribute it and/or modify it under the terms of the GNU
11 * General Public License (GPL) as published by the Free Software
12 * Foundation, in version 2 as it comes in the "COPYING" file of the
13 * VirtualBox OSE distribution. VirtualBox OSE is distributed in the
14 * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
15 *
16 * The contents of this file may alternatively be used under the terms
17 * of the Common Development and Distribution License Version 1.0
18 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the
19 * VirtualBox OSE distribution, in which case the provisions of the
20 * CDDL are applicable instead of those of the GPL.
21 *
22 * You may elect to license modified versions of this file under the
23 * terms and conditions of either the GPL or the CDDL or both.
24 *
25 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa
26 * Clara, CA 95054 USA or visit http://www.sun.com if you need
27 * additional information or have any questions.
28 */
29
30#ifndef ___iprt_mem_h
31#define ___iprt_mem_h
32
33
34#include <iprt/cdefs.h>
35#include <iprt/types.h>
36#ifdef __cplusplus /** @todo remove when spitting. */
37# include <iprt/cpp/autores.h>
38#endif
39
40
41#ifdef IN_RC
42# error "There are no RTMem APIs available Guest Context!"
43#endif
44
45
46/** @defgroup grp_rt_mem RTMem - Memory Management and Manipulation
47 * @ingroup grp_rt
48 * @{
49 */
50
51RT_C_DECLS_BEGIN
52
53/** @def RTMEM_ALIGNMENT
54 * The alignment of the memory blocks returned by RTMemAlloc(), RTMemAllocZ(),
55 * RTMemRealloc(), RTMemTmpAlloc() and RTMemTmpAllocZ() for allocations greater
56 * than RTMEM_ALIGNMENT.
57 */
58#define RTMEM_ALIGNMENT 8
59
60/**
61 * Allocates temporary memory.
62 *
63 * Temporary memory blocks are used for not too large memory blocks which
64 * are believed not to stick around for too long. Using this API instead
65 * of RTMemAlloc() not only gives the heap manager room for optimization
66 * but makes the code easier to read.
67 *
68 * @returns Pointer to the allocated memory.
69 * @returns NULL on failure.
70 * @param cb Size in bytes of the memory block to allocated.
71 */
72RTDECL(void *) RTMemTmpAlloc(size_t cb) RT_NO_THROW;
73
74/**
75 * Allocates zero'ed temporary memory.
76 *
77 * Same as RTMemTmpAlloc() but the memory will be zero'ed.
78 *
79 * @returns Pointer to the allocated memory.
80 * @returns NULL on failure.
81 * @param cb Size in bytes of the memory block to allocated.
82 */
83RTDECL(void *) RTMemTmpAllocZ(size_t cb) RT_NO_THROW;
84
85/**
86 * Free temporary memory.
87 *
88 * @param pv Pointer to memory block.
89 */
90RTDECL(void) RTMemTmpFree(void *pv) RT_NO_THROW;
91
92
93/**
94 * Allocates memory.
95 *
96 * @returns Pointer to the allocated memory.
97 * @returns NULL on failure.
98 * @param cb Size in bytes of the memory block to allocated.
99 */
100RTDECL(void *) RTMemAlloc(size_t cb) RT_NO_THROW;
101
102/**
103 * Allocates zero'ed memory.
104 *
105 * Instead of memset(pv, 0, sizeof()) use this when you want zero'ed
106 * memory. This keeps the code smaller and the heap can skip the memset
107 * in about 0.42% of calls :-).
108 *
109 * @returns Pointer to the allocated memory.
110 * @returns NULL on failure.
111 * @param cb Size in bytes of the memory block to allocated.
112 */
113RTDECL(void *) RTMemAllocZ(size_t cb) RT_NO_THROW;
114
115/**
116 * Duplicates a chunk of memory into a new heap block.
117 *
118 * @returns New heap block with the duplicate data.
119 * @returns NULL if we're out of memory.
120 * @param pvSrc The memory to duplicate.
121 * @param cb The amount of memory to duplicate.
122 */
123RTDECL(void *) RTMemDup(const void *pvSrc, size_t cb) RT_NO_THROW;
124
125/**
126 * Duplicates a chunk of memory into a new heap block with some
127 * additional zeroed memory.
128 *
129 * @returns New heap block with the duplicate data.
130 * @returns NULL if we're out of memory.
131 * @param pvSrc The memory to duplicate.
132 * @param cbSrc The amount of memory to duplicate.
133 * @param cbExtra The amount of extra memory to allocate and zero.
134 */
135RTDECL(void *) RTMemDupEx(const void *pvSrc, size_t cbSrc, size_t cbExtra) RT_NO_THROW;
136
137/**
138 * Reallocates memory.
139 *
140 * @returns Pointer to the allocated memory.
141 * @returns NULL on failure.
142 * @param pvOld The memory block to reallocate.
143 * @param cbNew The new block size (in bytes).
144 */
145RTDECL(void *) RTMemRealloc(void *pvOld, size_t cbNew) RT_NO_THROW;
146
147/**
148 * Frees memory.
149 *
150 * @param pv Pointer to memory block.
151 */
152RTDECL(void) RTMemFree(void *pv) RT_NO_THROW;
153
154/**
155 * Allocates memory which may contain code.
156 *
157 * @returns Pointer to the allocated memory.
158 * @returns NULL on failure.
159 * @param cb Size in bytes of the memory block to allocate.
160 */
161RTDECL(void *) RTMemExecAlloc(size_t cb) RT_NO_THROW;
162
163/**
164 * Free executable/read/write memory allocated by RTMemExecAlloc().
165 *
166 * @param pv Pointer to memory block.
167 */
168RTDECL(void) RTMemExecFree(void *pv) RT_NO_THROW;
169
170#if defined(IN_RING0) && defined(RT_ARCH_AMD64) && defined(RT_OS_LINUX)
171/**
172 * Donate read+write+execute memory to the exec heap.
173 *
174 * This API is specific to AMD64 and Linux/GNU. A kernel module that desires to
175 * use RTMemExecAlloc on AMD64 Linux/GNU will have to donate some statically
176 * allocated memory in the module if it wishes for GCC generated code to work.
177 * GCC can only generate modules that work in the address range ~2GB to ~0
178 * currently.
179 *
180 * The API only accept one single donation.
181 *
182 * @returns IPRT status code.
183 * @param pvMemory Pointer to the memory block.
184 * @param cb The size of the memory block.
185 */
186RTR0DECL(int) RTR0MemExecDonate(void *pvMemory, size_t cb) RT_NO_THROW;
187#endif /* R0+AMD64+LINUX */
188
189/**
190 * Allocate page aligned memory.
191 *
192 * @returns Pointer to the allocated memory.
193 * @returns NULL if we're out of memory.
194 * @param cb Size of the memory block. Will be rounded up to page size.
195 */
196RTDECL(void *) RTMemPageAlloc(size_t cb) RT_NO_THROW;
197
198/**
199 * Allocate zero'ed page aligned memory.
200 *
201 * @returns Pointer to the allocated memory.
202 * @returns NULL if we're out of memory.
203 * @param cb Size of the memory block. Will be rounded up to page size.
204 */
205RTDECL(void *) RTMemPageAllocZ(size_t cb) RT_NO_THROW;
206
207/**
208 * Free a memory block allocated with RTMemPageAlloc() or RTMemPageAllocZ().
209 *
210 * @param pv Pointer to the block as it was returned by the allocation function.
211 * NULL will be ignored.
212 */
213RTDECL(void) RTMemPageFree(void *pv) RT_NO_THROW;
214
215/** Page level protection flags for RTMemProtect().
216 * @{
217 */
218/** Read access. */
219#define RTMEM_PROT_NONE 0
220/** Read access. */
221#define RTMEM_PROT_READ 1
222/** Write access. */
223#define RTMEM_PROT_WRITE 2
224/** Execute access. */
225#define RTMEM_PROT_EXEC 4
226/** @} */
227
228/**
229 * Change the page level protection of a memory region.
230 *
231 * @returns iprt status code.
232 * @param pv Start of the region. Will be rounded down to nearest page boundary.
233 * @param cb Size of the region. Will be rounded up to the nearest page boundary.
234 * @param fProtect The new protection, a combination of the RTMEM_PROT_* defines.
235 */
236RTDECL(int) RTMemProtect(void *pv, size_t cb, unsigned fProtect) RT_NO_THROW;
237
238
239#ifdef IN_RING0
240
241/**
242 * Allocates physical contiguous memory (below 4GB).
243 * The allocation is page aligned and the content is undefined.
244 *
245 * @returns Pointer to the memory block. This is page aligned.
246 * @param pPhys Where to store the physical address.
247 * @param cb The allocation size in bytes. This is always
248 * rounded up to PAGE_SIZE.
249 */
250RTR0DECL(void *) RTMemContAlloc(PRTCCPHYS pPhys, size_t cb) RT_NO_THROW;
251
252/**
253 * Frees memory allocated ysing RTMemContAlloc().
254 *
255 * @param pv Pointer to return from RTMemContAlloc().
256 * @param cb The cb parameter passed to RTMemContAlloc().
257 */
258RTR0DECL(void) RTMemContFree(void *pv, size_t cb) RT_NO_THROW;
259
260/**
261 * Copy memory from an user mode buffer into a kernel buffer.
262 *
263 * @retval VINF_SUCCESS on success.
264 * @retval VERR_ACCESS_DENIED on error.
265 *
266 * @param pvDst The kernel mode destination address.
267 * @param R3PtrDst The user mode source address.
268 * @param cb The number of bytes to copy.
269 */
270RTR0DECL(int) RTR0MemUserCopyFrom(void *pvDst, RTR3PTR R3PtrSrc, size_t cb);
271
272/**
273 * Copy memory from a kernel buffer into a user mode one.
274 *
275 * @retval VINF_SUCCESS on success.
276 * @retval VERR_ACCESS_DENIED on error.
277 *
278 * @param R3PtrDst The user mode destination address.
279 * @param pvSrc The kernel mode source address.
280 * @param cb The number of bytes to copy.
281 */
282RTR0DECL(int) RTR0MemUserCopyTo(RTR3PTR R3PtrDst, void const *pvSrc, size_t cb);
283
284/**
285 * Tests if the specified address is in the user addressable range.
286 *
287 * This function does not check whether the memory at that address is accessible
288 * or anything of that sort, only if the address it self is in the user mode
289 * range.
290 *
291 * @returns true if it's in the user addressable range. false if not.
292 * @param R3Ptr The user mode pointer to test.
293 *
294 * @remarks Some systems may have overlapping kernel and user address ranges.
295 * One prominent example of this is the x86 version of Mac OS X. Use
296 * RTR0MemAreKrnlAndUsrDifferent() to check.
297 */
298RTR0DECL(bool) RTR0MemUserIsValidAddr(RTR3PTR R3Ptr);
299
300/**
301 * Tests if the specified address is in the kernel mode range.
302 *
303 * This function does not check whether the memory at that address is accessible
304 * or anything of that sort, only if the address it self is in the kernel mode
305 * range.
306 *
307 * @returns true if it's in the kernel range. false if not.
308 * @param pv The alleged kernel mode pointer.
309 *
310 * @remarks Some systems may have overlapping kernel and user address ranges.
311 * One prominent example of this is the x86 version of Mac OS X. Use
312 * RTR0MemAreKrnlAndUsrDifferent() to check.
313 */
314RTR0DECL(bool) RTR0MemKernelIsValidAddr(void *pv);
315
316/**
317 * Are user mode and kernel mode address ranges distinctly different.
318 *
319 * This determins whether RTR0MemKernelIsValidAddr and RTR0MemUserIsValidAddr
320 * can be used for deciding whether some arbitrary address is a user mode or a
321 * kernel mode one.
322 *
323 * @returns true if they are, false if not.
324 */
325RTR0DECL(bool) RTR0MemAreKrnlAndUsrDifferent(void);
326
327#endif /* IN_RING0 */
328
329
330/** @name Electrical Fence Version of some APIs.
331 * @{
332 */
333
334/**
335 * Same as RTMemTmpAlloc() except that it's fenced.
336 *
337 * @returns Pointer to the allocated memory.
338 * @returns NULL on failure.
339 * @param cb Size in bytes of the memory block to allocate.
340 */
341RTDECL(void *) RTMemEfTmpAlloc(size_t cb) RT_NO_THROW;
342
343/**
344 * Same as RTMemTmpAllocZ() except that it's fenced.
345 *
346 * @returns Pointer to the allocated memory.
347 * @returns NULL on failure.
348 * @param cb Size in bytes of the memory block to allocate.
349 */
350RTDECL(void *) RTMemEfTmpAllocZ(size_t cb) RT_NO_THROW;
351
352/**
353 * Same as RTMemTmpFree() except that it's for fenced memory.
354 *
355 * @param pv Pointer to memory block.
356 */
357RTDECL(void) RTMemEfTmpFree(void *pv) RT_NO_THROW;
358
359/**
360 * Same as RTMemAlloc() except that it's fenced.
361 *
362 * @returns Pointer to the allocated memory. Free with RTMemEfFree().
363 * @returns NULL on failure.
364 * @param cb Size in bytes of the memory block to allocate.
365 */
366RTDECL(void *) RTMemEfAlloc(size_t cb) RT_NO_THROW;
367
368/**
369 * Same as RTMemAllocZ() except that it's fenced.
370 *
371 * @returns Pointer to the allocated memory.
372 * @returns NULL on failure.
373 * @param cb Size in bytes of the memory block to allocate.
374 */
375RTDECL(void *) RTMemEfAllocZ(size_t cb) RT_NO_THROW;
376
377/**
378 * Same as RTMemRealloc() except that it's fenced.
379 *
380 * @returns Pointer to the allocated memory.
381 * @returns NULL on failure.
382 * @param pvOld The memory block to reallocate.
383 * @param cbNew The new block size (in bytes).
384 */
385RTDECL(void *) RTMemEfRealloc(void *pvOld, size_t cbNew) RT_NO_THROW;
386
387/**
388 * Free memory allocated by any of the RTMemEf* allocators.
389 *
390 * @param pv Pointer to memory block.
391 */
392RTDECL(void) RTMemEfFree(void *pv) RT_NO_THROW;
393
394/**
395 * Same as RTMemDup() except that it's fenced.
396 *
397 * @returns New heap block with the duplicate data.
398 * @returns NULL if we're out of memory.
399 * @param pvSrc The memory to duplicate.
400 * @param cb The amount of memory to duplicate.
401 */
402RTDECL(void *) RTMemEfDup(const void *pvSrc, size_t cb) RT_NO_THROW;
403
404/**
405 * Same as RTMemEfDupEx except that it's fenced.
406 *
407 * @returns New heap block with the duplicate data.
408 * @returns NULL if we're out of memory.
409 * @param pvSrc The memory to duplicate.
410 * @param cbSrc The amount of memory to duplicate.
411 * @param cbExtra The amount of extra memory to allocate and zero.
412 */
413RTDECL(void *) RTMemEfDupEx(const void *pvSrc, size_t cbSrc, size_t cbExtra) RT_NO_THROW;
414
415/** @def RTMEM_WRAP_TO_EF_APIS
416 * Define RTMEM_WRAP_TO_EF_APIS to wrap RTMem APIs to RTMemEf APIs.
417 */
418#ifdef RTMEM_WRAP_TO_EF_APIS
419# define RTMemTmpAlloc RTMemEfTmpAlloc
420# define RTMemTmpAllocZ RTMemEfTmpAllocZ
421# define RTMemTmpFree RTMemEfTmpFree
422# define RTMemAlloc RTMemEfAlloc
423# define RTMemAllocZ RTMemEfAllocZ
424# define RTMemRealloc RTMemEfRealloc
425# define RTMemFree RTMemEfFree
426# define RTMemDup RTMemEfDup
427# define RTMemDupEx RTMemEfDupEx
428#endif
429#ifdef DOXYGEN_RUNNING
430# define RTMEM_WRAP_TO_EF_APIS
431#endif
432
433/** @} */
434
435RT_C_DECLS_END
436
437
438#ifdef __cplusplus /** @todo Split this out into iprt/cpp/mem.h! */
439# include <iprt/assert.h>
440
441/**
442 * Template function wrapping RTMemFree to get the correct Destruct
443 * signature for RTAutoRes.
444 *
445 * We can't use a more complex template here, because the g++ on RHEL 3
446 * chokes on it with an internal compiler error.
447 *
448 * @param T The data type that's being managed.
449 * @param aMem Pointer to the memory that should be free.
450 */
451template <class T>
452inline void RTMemAutoDestructor(T *aMem) RT_NO_THROW
453{
454 RTMemFree(aMem);
455}
456
457
458/**
459 * RTMemAutoPtr allocator which uses RTMemTmpAlloc().
460 *
461 * @returns Allocated memory on success, NULL on failure.
462 * @param pvOld What to reallocate, shall always be NULL.
463 * @param cbNew The amount of memory to allocate (in bytes).
464 */
465inline void *RTMemTmpAutoAllocator(void *pvOld, size_t cbNew) RT_NO_THROW
466{
467 AssertReturn(!pvOld, NULL);
468 return RTMemTmpAlloc(cbNew);
469}
470
471
472/**
473 * Template function wrapping RTMemTmpFree to get the correct Destruct
474 * signature for RTAutoRes.
475 *
476 * We can't use a more complex template here, because the g++ on RHEL 3
477 * chokes on it with an internal compiler error.
478 *
479 * @param T The data type that's being managed.
480 * @param aMem Pointer to the memory that should be free.
481 */
482template <class T>
483inline void RTMemTmpAutoDestructor(T *aMem) RT_NO_THROW
484{
485 RTMemTmpFree(aMem);
486}
487
488
489/**
490 * Template function wrapping RTMemEfFree to get the correct Destruct
491 * signature for RTAutoRes.
492 *
493 * We can't use a more complex template here, because the g++ on RHEL 3
494 * chokes on it with an internal compiler error.
495 *
496 * @param T The data type that's being managed.
497 * @param aMem Pointer to the memory that should be free.
498 */
499template <class T>
500inline void RTMemEfAutoFree(T *aMem) RT_NO_THROW
501{
502 RTMemEfFree(aMem);
503}
504
505
506/**
507 * Template function wrapping NULL to get the correct NilRes signature
508 * for RTAutoRes.
509 *
510 * @param T The data type that's being managed.
511 * @returns NULL with the right type.
512 */
513template <class T>
514inline T * RTMemAutoNil(void) RT_NO_THROW
515{
516 return (T *)(NULL);
517}
518
519
520/**
521 * An auto pointer-type template class for managing memory allocating
522 * via C APIs like RTMem (the default).
523 *
524 * The main purpose of this class is to automatically free memory that
525 * isn't explicitly used (release()'ed) when the object goes out of scope.
526 *
527 * As an additional service it can also make the allocations and
528 * reallocations for you if you like, but it can also take of memory
529 * you hand it.
530 *
531 * @param T The data type to manage allocations for.
532 * @param Destruct The function to be used to free the resource.
533 * This will default to RTMemFree.
534 * @param Allocator The function to be used to allocate or reallocate
535 * the managed memory.
536 * This is standard realloc() like stuff, so it's possible
537 * to support simple allocation without actually having
538 * to support reallocating memory if that's a problem.
539 * This will default to RTMemRealloc.
540 */
541template <class T, void Destruct(T *) = RTMemAutoDestructor<T>, void *Allocator(void *, size_t) = RTMemRealloc >
542class RTMemAutoPtr
543 : public RTAutoRes<T *, Destruct, RTMemAutoNil<T> >
544{
545public:
546 /**
547 * Constructor.
548 *
549 * @param aPtr Memory pointer to manage. Defaults to NULL.
550 */
551 RTMemAutoPtr(T *aPtr = NULL)
552 : RTAutoRes<T *, Destruct, RTMemAutoNil<T> >(aPtr)
553 {
554 }
555
556 /**
557 * Constructor that allocates memory.
558 *
559 * @param a_cElements The number of elements (of the data type) to allocate.
560 * @param a_fZeroed Whether the memory should be memset with zeros after
561 * the allocation. Defaults to false.
562 */
563 RTMemAutoPtr(size_t a_cElements, bool a_fZeroed = false)
564 : RTAutoRes<T *, Destruct, RTMemAutoNil<T> >((T *)Allocator(NULL, a_cElements * sizeof(T)))
565 {
566 if (a_fZeroed && RT_LIKELY(this->get() != NULL))
567 memset(this->get(), '\0', a_cElements * sizeof(T));
568 }
569
570 /**
571 * Free current memory and start managing aPtr.
572 *
573 * @param aPtr Memory pointer to manage.
574 */
575 RTMemAutoPtr &operator=(T *aPtr)
576 {
577 this->RTAutoRes<T *, Destruct, RTMemAutoNil<T> >::operator=(aPtr);
578 return *this;
579 }
580
581 /**
582 * Dereference with * operator.
583 */
584 T &operator*()
585 {
586 return *this->get();
587 }
588
589 /**
590 * Dereference with -> operator.
591 */
592 T *operator->()
593 {
594 return this->get();
595 }
596
597 /**
598 * Accessed with the subscript operator ([]).
599 *
600 * @returns Reference to the element.
601 * @param a_i The element to access.
602 */
603 T &operator[](size_t a_i)
604 {
605 return this->get()[a_i];
606 }
607
608 /**
609 * Allocates memory and start manage it.
610 *
611 * Any previously managed memory will be freed before making
612 * the new allocation.
613 *
614 * @returns Success indicator.
615 * @retval true if the new allocation succeeds.
616 * @retval false on failure, no memory is associated with the object.
617 *
618 * @param a_cElements The number of elements (of the data type) to allocate.
619 * This defaults to 1.
620 * @param a_fZeroed Whether the memory should be memset with zeros after
621 * the allocation. Defaults to false.
622 */
623 bool alloc(size_t a_cElements = 1, bool a_fZeroed = false)
624 {
625 this->reset(NULL);
626 T *pNewMem = (T *)Allocator(NULL, a_cElements * sizeof(T));
627 if (a_fZeroed && RT_LIKELY(pNewMem != NULL))
628 memset(pNewMem, '\0', a_cElements * sizeof(T));
629 this->reset(pNewMem);
630 return pNewMem != NULL;
631 }
632
633 /**
634 * Reallocate or allocates the memory resource.
635 *
636 * Free the old value if allocation fails.
637 *
638 * The content of any additional memory that was allocated is
639 * undefined when using the default allocator.
640 *
641 * @returns Success indicator.
642 * @retval true if the new allocation succeeds.
643 * @retval false on failure, no memory is associated with the object.
644 *
645 * @param cElements The new number of elements (of the data type) to allocate.
646 * The size of the allocation is the number of elements times
647 * the size of the data type - this is currently what's passed
648 * down to the Allocator.
649 * This defaults to 1.
650 */
651 bool realloc(size_t a_cElements = 1)
652 {
653 T *aNewValue = (T *)Allocator(this->get(), a_cElements * sizeof(T));
654 if (RT_LIKELY(aNewValue != NULL))
655 this->release();
656 /* We want this both if aNewValue is non-NULL and if it is NULL. */
657 this->reset(aNewValue);
658 return aNewValue != NULL;
659 }
660};
661
662
663#endif /* __cplusplus */
664
665
666/** @} */
667
668
669#endif
670
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