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/* This is a version (aka dlmalloc) of malloc/free/realloc written by Doug Lea and released to the public domain. Use, modify, and redistribute this code without permission or acknowledgement in any way you wish. Send questions, comments, complaints, performance data, etc to dl@cs.oswego.edu VERSION 2.7.2 Sat Aug 17 09:07:30 2002 Doug Lea (dl at gee) Note: There may be an updated version of this malloc obtainable at ftp://gee.cs.oswego.edu/pub/misc/malloc.c Check before installing! Hacked up for uClibc by Erik Andersen <andersen@codepoet.org> */ #include <features.h> #include <stddef.h> #include <unistd.h> #include <errno.h> #include <string.h> #include <malloc.h> #ifdef __UCLIBC_HAS_THREADS__ #include <pthread.h> extern pthread_mutex_t __malloc_lock; # define LOCK __pthread_mutex_lock(&__malloc_lock) # define UNLOCK __pthread_mutex_unlock(&__malloc_lock); #else # define LOCK # define UNLOCK #endif /* MALLOC_ALIGNMENT is the minimum alignment for malloc'ed chunks. It must be a power of two at least 2 * (sizeof(size_t)), even on machines for which smaller alignments would suffice. It may be defined as larger than this though. Note however that code and data structures are optimized for the case of 8-byte alignment. */ #ifndef MALLOC_ALIGNMENT #define MALLOC_ALIGNMENT (2 * (sizeof(size_t))) #endif /* The corresponding bit mask value */ #define MALLOC_ALIGN_MASK (MALLOC_ALIGNMENT - 1) /* TRIM_FASTBINS controls whether free() of a very small chunk can immediately lead to trimming. Setting to true (1) can reduce memory footprint, but will almost always slow down programs that use a lot of small chunks. Define this only if you are willing to give up some speed to more aggressively reduce system-level memory footprint when releasing memory in programs that use many small chunks. You can get essentially the same effect by setting MXFAST to 0, but this can lead to even greater slowdowns in programs using many small chunks. TRIM_FASTBINS is an in-between compile-time option, that disables only those chunks bordering topmost memory from being placed in fastbins. */ #ifndef TRIM_FASTBINS #define TRIM_FASTBINS 0 #endif /* MORECORE-related declarations. By default, rely on sbrk */ /* MORECORE is the name of the routine to call to obtain more memory from the system. See below for general guidance on writing alternative MORECORE functions, as well as a version for WIN32 and a sample version for pre-OSX macos. */ #ifndef MORECORE #define MORECORE sbrk #endif /* MORECORE_FAILURE is the value returned upon failure of MORECORE as well as mmap. Since it cannot be an otherwise valid memory address, and must reflect values of standard sys calls, you probably ought not try to redefine it. */ #ifndef MORECORE_FAILURE #define MORECORE_FAILURE (-1) #endif /* If MORECORE_CONTIGUOUS is true, take advantage of fact that consecutive calls to MORECORE with positive arguments always return contiguous increasing addresses. This is true of unix sbrk. Even if not defined, when regions happen to be contiguous, malloc will permit allocations spanning regions obtained from different calls. But defining this when applicable enables some stronger consistency checks and space efficiencies. */ #ifndef MORECORE_CONTIGUOUS #define MORECORE_CONTIGUOUS 1 #endif /* MMAP_AS_MORECORE_SIZE is the minimum mmap size argument to use if sbrk fails, and mmap is used as a backup (which is done only if HAVE_MMAP). The value must be a multiple of page size. This backup strategy generally applies only when systems have "holes" in address space, so sbrk cannot perform contiguous expansion, but there is still space available on system. On systems for which this is known to be useful (i.e. most linux kernels), this occurs only when programs allocate huge amounts of memory. Between this, and the fact that mmap regions tend to be limited, the size should be large, to avoid too many mmap calls and thus avoid running out of kernel resources. */ #ifndef MMAP_AS_MORECORE_SIZE #define MMAP_AS_MORECORE_SIZE (1024 * 1024) #endif /* The system page size. To the extent possible, this malloc manages memory from the system in page-size units. Note that this value is cached during initialization into a field of malloc_state. So even if malloc_getpagesize is a function, it is only called once. The following mechanics for getpagesize were adapted from bsd/gnu getpagesize.h. If none of the system-probes here apply, a value of 4096 is used, which should be OK: If they don't apply, then using the actual value probably doesn't impact performance. */ #ifndef malloc_getpagesize # include <unistd.h> # define malloc_getpagesize sysconf(_SC_PAGE_SIZE) #else /* just guess */ # define malloc_getpagesize (4096) #endif /* mallopt tuning options */ /* M_MXFAST is the maximum request size used for "fastbins", special bins that hold returned chunks without consolidating their spaces. This enables future requests for chunks of the same size to be handled very quickly, but can increase fragmentation, and thus increase the overall memory footprint of a program. This malloc manages fastbins very conservatively yet still efficiently, so fragmentation is rarely a problem for values less than or equal to the default. The maximum supported value of MXFAST is 80. You wouldn't want it any higher than this anyway. Fastbins are designed especially for use with many small structs, objects or strings -- the default handles structs/objects/arrays with sizes up to 16 4byte fields, or small strings representing words, tokens, etc. Using fastbins for larger objects normally worsens fragmentation without improving speed. M_MXFAST is set in REQUEST size units. It is internally used in chunksize units, which adds padding and alignment. You can reduce M_MXFAST to 0 to disable all use of fastbins. This causes the malloc algorithm to be a closer approximation of fifo-best-fit in all cases, not just for larger requests, but will generally cause it to be slower. */ /* M_MXFAST is a standard SVID/XPG tuning option, usually listed in malloc.h */ #ifndef M_MXFAST #define M_MXFAST 1 #endif #ifndef DEFAULT_MXFAST #define DEFAULT_MXFAST 64 #endif /* M_TRIM_THRESHOLD is the maximum amount of unused top-most memory to keep before releasing via malloc_trim in free(). Automatic trimming is mainly useful in long-lived programs. Because trimming via sbrk can be slow on some systems, and can sometimes be wasteful (in cases where programs immediately afterward allocate more large chunks) the value should be high enough so that your overall system performance would improve by releasing this much memory. The trim threshold and the mmap control parameters (see below) can be traded off with one another. Trimming and mmapping are two different ways of releasing unused memory back to the system. Between these two, it is often possible to keep system-level demands of a long-lived program down to a bare minimum. For example, in one test suite of sessions measuring the XF86 X server on Linux, using a trim threshold of 128K and a mmap threshold of 192K led to near-minimal long term resource consumption. If you are using this malloc in a long-lived program, it should pay to experiment with these values. As a rough guide, you might set to a value close to the average size of a process (program) running on your system. Releasing this much memory would allow such a process to run in memory. Generally, it's worth it to tune for trimming rather tham memory mapping when a program undergoes phases where several large chunks are allocated and released in ways that can reuse each other's storage, perhaps mixed with phases where there are no such chunks at all. And in well-behaved long-lived programs, controlling release of large blocks via trimming versus mapping is usually faster. However, in most programs, these parameters serve mainly as protection against the system-level effects of carrying around massive amounts of unneeded memory. Since frequent calls to sbrk, mmap, and munmap otherwise degrade performance, the default parameters are set to relatively high values that serve only as safeguards. The trim value must be greater than page size to have any useful effect. To disable trimming completely, you can set to (unsigned long)(-1) Trim settings interact with fastbin (MXFAST) settings: Unless TRIM_FASTBINS is defined, automatic trimming never takes place upon freeing a chunk with size less than or equal to MXFAST. Trimming is instead delayed until subsequent freeing of larger chunks. However, you can still force an attempted trim by calling malloc_trim. Also, trimming is not generally possible in cases where the main arena is obtained via mmap. Note that the trick some people use of mallocing a huge space and then freeing it at program startup, in an attempt to reserve system memory, doesn't have the intended effect under automatic trimming, since that memory will immediately be returned to the system. */ #define M_TRIM_THRESHOLD -1 #ifndef DEFAULT_TRIM_THRESHOLD #define DEFAULT_TRIM_THRESHOLD (256 * 1024) #endif /* M_TOP_PAD is the amount of extra `padding' space to allocate or retain whenever sbrk is called. It is used in two ways internally: * When sbrk is called to extend the top of the arena to satisfy a new malloc request, this much padding is added to the sbrk request. * When malloc_trim is called automatically from free(), it is used as the `pad' argument. In both cases, the actual amount of padding is rounded so that the end of the arena is always a system page boundary. The main reason for using padding is to avoid calling sbrk so often. Having even a small pad greatly reduces the likelihood that nearly every malloc request during program start-up (or after trimming) will invoke sbrk, which needlessly wastes time. Automatic rounding-up to page-size units is normally sufficient to avoid measurable overhead, so the default is 0. However, in systems where sbrk is relatively slow, it can pay to increase this value, at the expense of carrying around more memory than the program needs. */ #define M_TOP_PAD -2 #ifndef DEFAULT_TOP_PAD #define DEFAULT_TOP_PAD (0) #endif /* M_MMAP_THRESHOLD is the request size threshold for using mmap() to service a request. Requests of at least this size that cannot be allocated using already-existing space will be serviced via mmap. (If enough normal freed space already exists it is used instead.) Using mmap segregates relatively large chunks of memory so that they can be individually obtained and released from the host system. A request serviced through mmap is never reused by any other request (at least not directly; the system may just so happen to remap successive requests to the same locations). Segregating space in this way has the benefits that: 1. Mmapped space can ALWAYS be individually released back to the system, which helps keep the system level memory demands of a long-lived program low. 2. Mapped memory can never become `locked' between other chunks, as can happen with normally allocated chunks, which means that even trimming via malloc_trim would not release them. 3. On some systems with "holes" in address spaces, mmap can obtain memory that sbrk cannot. However, it has the disadvantages that: 1. The space cannot be reclaimed, consolidated, and then used to service later requests, as happens with normal chunks. 2. It can lead to more wastage because of mmap page alignment requirements 3. It causes malloc performance to be more dependent on host system memory management support routines which may vary in implementation quality and may impose arbitrary limitations. Generally, servicing a request via normal malloc steps is faster than going through a system's mmap. The advantages of mmap nearly always outweigh disadvantages for "large" chunks, but the value of "large" varies across systems. The default is an empirically derived value that works well in most systems. */ #define M_MMAP_THRESHOLD -3 #ifndef DEFAULT_MMAP_THRESHOLD #define DEFAULT_MMAP_THRESHOLD (256 * 1024) #endif /* M_MMAP_MAX is the maximum number of requests to simultaneously service using mmap. This parameter exists because . Some systems have a limited number of internal tables for use by mmap, and using more than a few of them may degrade performance. The default is set to a value that serves only as a safeguard. Setting to 0 disables use of mmap for servicing large requests. If HAVE_MMAP is not set, the default value is 0, and attempts to set it to non-zero values in mallopt will fail. */ #define M_MMAP_MAX -4 #ifndef DEFAULT_MMAP_MAX #define DEFAULT_MMAP_MAX (65536) #endif /* ------------------ MMAP support ------------------ */ #include <fcntl.h> #include <sys/mman.h> #if !defined(MAP_ANONYMOUS) && defined(MAP_ANON) #define MAP_ANONYMOUS MAP_ANON #endif #define MMAP(addr, size, prot, flags) \ (mmap((addr), (size), (prot), (flags)|MAP_ANONYMOUS, -1, 0)) /* ----------------------- Chunk representations ----------------------- */ /* This struct declaration is misleading (but accurate and necessary). It declares a "view" into memory allowing access to necessary fields at known offsets from a given base. See explanation below. */ struct malloc_chunk { size_t prev_size; /* Size of previous chunk (if free). */ size_t size; /* Size in bytes, including overhead. */ struct malloc_chunk* fd; /* double links -- used only if free. */ struct malloc_chunk* bk; }; typedef struct malloc_chunk* mchunkptr; /* malloc_chunk details: (The following includes lightly edited explanations by Colin Plumb.) Chunks of memory are maintained using a `boundary tag' method as described in e.g., Knuth or Standish. (See the paper by Paul Wilson ftp://ftp.cs.utexas.edu/pub/garbage/allocsrv.ps for a survey of such techniques.) Sizes of free chunks are stored both in the front of each chunk and at the end. This makes consolidating fragmented chunks into bigger chunks very fast. The size fields also hold bits representing whether chunks are free or in use. An allocated chunk looks like this: chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Size of previous chunk, if allocated | | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Size of chunk, in bytes |P| mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | User data starts here... . . . . (malloc_usable_space() bytes) . . | nextchunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Size of chunk | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ Where "chunk" is the front of the chunk for the purpose of most of the malloc code, but "mem" is the pointer that is returned to the user. "Nextchunk" is the beginning of the next contiguous chunk. Chunks always begin on even word boundries, so the mem portion (which is returned to the user) is also on an even word boundary, and thus at least double-word aligned. Free chunks are stored in circular doubly-linked lists, and look like this: chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Size of previous chunk | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ `head:' | Size of chunk, in bytes |P| mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Forward pointer to next chunk in list | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Back pointer to previous chunk in list | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | Unused space (may be 0 bytes long) . . . . | nextchunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ `foot:' | Size of chunk, in bytes | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ The P (PREV_INUSE) bit, stored in the unused low-order bit of the chunk size (which is always a multiple of two words), is an in-use bit for the *previous* chunk. If that bit is *clear*, then the word before the current chunk size contains the previous chunk size, and can be used to find the front of the previous chunk. The very first chunk allocated always has this bit set, preventing access to non-existent (or non-owned) memory. If prev_inuse is set for any given chunk, then you CANNOT determine the size of the previous chunk, and might even get a memory addressing fault when trying to do so. Note that the `foot' of the current chunk is actually represented as the prev_size of the NEXT chunk. This makes it easier to deal with alignments etc but can be very confusing when trying to extend or adapt this code. The two exceptions to all this are 1. The special chunk `top' doesn't bother using the trailing size field since there is no next contiguous chunk that would have to index off it. After initialization, `top' is forced to always exist. If it would become less than MINSIZE bytes long, it is replenished. 2. Chunks allocated via mmap, which have the second-lowest-order bit (IS_MMAPPED) set in their size fields. Because they are allocated one-by-one, each must contain its own trailing size field. */ /* ---------- Size and alignment checks and conversions ---------- */ /* conversion from malloc headers to user pointers, and back */ #define chunk2mem(p) ((void*)((char*)(p) + 2*(sizeof(size_t)))) #define mem2chunk(mem) ((mchunkptr)((char*)(mem) - 2*(sizeof(size_t)))) /* The smallest possible chunk */ #define MIN_CHUNK_SIZE (sizeof(struct malloc_chunk)) /* The smallest size we can malloc is an aligned minimal chunk */ #define MINSIZE \ (unsigned long)(((MIN_CHUNK_SIZE+MALLOC_ALIGN_MASK) & ~MALLOC_ALIGN_MASK)) /* Check if m has acceptable alignment */ #define aligned_OK(m) (((unsigned long)((m)) & (MALLOC_ALIGN_MASK)) == 0) /* Check if a request is so large that it would wrap around zero when padded and aligned. To simplify some other code, the bound is made low enough so that adding MINSIZE will also not wrap around sero. */ #define REQUEST_OUT_OF_RANGE(req) \ ((unsigned long)(req) >= \ (unsigned long)(size_t)(-2 * MINSIZE)) /* pad request bytes into a usable size -- internal version */ #define request2size(req) \ (((req) + (sizeof(size_t)) + MALLOC_ALIGN_MASK < MINSIZE) ? \ MINSIZE : \ ((req) + (sizeof(size_t)) + MALLOC_ALIGN_MASK) & ~MALLOC_ALIGN_MASK) /* Same, except also perform argument check */ #define checked_request2size(req, sz) \ if (REQUEST_OUT_OF_RANGE(req)) { \ errno = ENOMEM; \ return 0; \ } \ (sz) = request2size(req); /* --------------- Physical chunk operations --------------- */ /* size field is or'ed with PREV_INUSE when previous adjacent chunk in use */ #define PREV_INUSE 0x1 /* extract inuse bit of previous chunk */ #define prev_inuse(p) ((p)->size & PREV_INUSE) /* size field is or'ed with IS_MMAPPED if the chunk was obtained with mmap() */ #define IS_MMAPPED 0x2 /* check for mmap()'ed chunk */ #define chunk_is_mmapped(p) ((p)->size & IS_MMAPPED) /* Bits to mask off when extracting size Note: IS_MMAPPED is intentionally not masked off from size field in macros for which mmapped chunks should never be seen. This should cause helpful core dumps to occur if it is tried by accident by people extending or adapting this malloc. */ #define SIZE_BITS (PREV_INUSE|IS_MMAPPED) /* Get size, ignoring use bits */ #define chunksize(p) ((p)->size & ~(SIZE_BITS)) /* Ptr to next physical malloc_chunk. */ #define next_chunk(p) ((mchunkptr)( ((char*)(p)) + ((p)->size & ~PREV_INUSE) )) /* Ptr to previous physical malloc_chunk */ #define prev_chunk(p) ((mchunkptr)( ((char*)(p)) - ((p)->prev_size) )) /* Treat space at ptr + offset as a chunk */ #define chunk_at_offset(p, s) ((mchunkptr)(((char*)(p)) + (s))) /* extract p's inuse bit */ #define inuse(p)\ ((((mchunkptr)(((char*)(p))+((p)->size & ~PREV_INUSE)))->size) & PREV_INUSE) /* set/clear chunk as being inuse without otherwise disturbing */ #define set_inuse(p)\ ((mchunkptr)(((char*)(p)) + ((p)->size & ~PREV_INUSE)))->size |= PREV_INUSE #define clear_inuse(p)\ ((mchunkptr)(((char*)(p)) + ((p)->size & ~PREV_INUSE)))->size &= ~(PREV_INUSE) /* check/set/clear inuse bits in known places */ #define inuse_bit_at_offset(p, s)\ (((mchunkptr)(((char*)(p)) + (s)))->size & PREV_INUSE) #define set_inuse_bit_at_offset(p, s)\ (((mchunkptr)(((char*)(p)) + (s)))->size |= PREV_INUSE) #define clear_inuse_bit_at_offset(p, s)\ (((mchunkptr)(((char*)(p)) + (s)))->size &= ~(PREV_INUSE)) /* Set size at head, without disturbing its use bit */ #define set_head_size(p, s) ((p)->size = (((p)->size & PREV_INUSE) | (s))) /* Set size/use field */ #define set_head(p, s) ((p)->size = (s)) /* Set size at footer (only when chunk is not in use) */ #define set_foot(p, s) (((mchunkptr)((char*)(p) + (s)))->prev_size = (s)) /* -------------------- Internal data structures -------------------- */ /* Bins An array of bin headers for free chunks. Each bin is doubly linked. The bins are approximately proportionally (log) spaced. There are a lot of these bins (128). This may look excessive, but works very well in practice. Most bins hold sizes that are unusual as malloc request sizes, but are more usual for fragments and consolidated sets of chunks, which is what these bins hold, so they can be found quickly. All procedures maintain the invariant that no consolidated chunk physically borders another one, so each chunk in a list is known to be preceeded and followed by either inuse chunks or the ends of memory. Chunks in bins are kept in size order, with ties going to the approximately least recently used chunk. Ordering isn't needed for the small bins, which all contain the same-sized chunks, but facilitates best-fit allocation for larger chunks. These lists are just sequential. Keeping them in order almost never requires enough traversal to warrant using fancier ordered data structures. Chunks of the same size are linked with the most recently freed at the front, and allocations are taken from the back. This results in LRU (FIFO) allocation order, which tends to give each chunk an equal opportunity to be consolidated with adjacent freed chunks, resulting in larger free chunks and less fragmentation. To simplify use in double-linked lists, each bin header acts as a malloc_chunk. This avoids special-casing for headers. But to conserve space and improve locality, we allocate only the fd/bk pointers of bins, and then use repositioning tricks to treat these as the fields of a malloc_chunk*. */ typedef struct malloc_chunk* mbinptr; /* addressing -- note that bin_at(0) does not exist */ #define bin_at(m, i) ((mbinptr)((char*)&((m)->bins[(i)<<1]) - ((sizeof(size_t))<<1))) /* analog of ++bin */ #define next_bin(b) ((mbinptr)((char*)(b) + (sizeof(mchunkptr)<<1))) /* Reminders about list directionality within bins */ #define first(b) ((b)->fd) #define last(b) ((b)->bk) /* Take a chunk off a bin list */ #define unlink(P, BK, FD) { \ FD = P->fd; \ BK = P->bk; \ FD->bk = BK; \ BK->fd = FD; \ } /* Indexing Bins for sizes < 512 bytes contain chunks of all the same size, spaced 8 bytes apart. Larger bins are approximately logarithmically spaced: 64 bins of size 8 32 bins of size 64 16 bins of size 512 8 bins of size 4096 4 bins of size 32768 2 bins of size 262144 1 bin of size what's left The bins top out around 1MB because we expect to service large requests via mmap. */ #define NBINS 96 #define NSMALLBINS 32 #define SMALLBIN_WIDTH 8 #define MIN_LARGE_SIZE 256 #define in_smallbin_range(sz) \ ((unsigned long)(sz) < (unsigned long)MIN_LARGE_SIZE) #define smallbin_index(sz) (((unsigned)(sz)) >> 3) #define bin_index(sz) \ ((in_smallbin_range(sz)) ? smallbin_index(sz) : __malloc_largebin_index(sz)) /* FIRST_SORTED_BIN_SIZE is the chunk size corresponding to the first bin that is maintained in sorted order. This must be the smallest size corresponding to a given bin. Normally, this should be MIN_LARGE_SIZE. But you can weaken best fit guarantees to sometimes speed up malloc by increasing value. Doing this means that malloc may choose a chunk that is non-best-fitting by up to the width of the bin. Some useful cutoff values: 512 - all bins sorted 2560 - leaves bins <= 64 bytes wide unsorted 12288 - leaves bins <= 512 bytes wide unsorted 65536 - leaves bins <= 4096 bytes wide unsorted 262144 - leaves bins <= 32768 bytes wide unsorted -1 - no bins sorted (not recommended!) */ #define FIRST_SORTED_BIN_SIZE MIN_LARGE_SIZE /* #define FIRST_SORTED_BIN_SIZE 65536 */ /* Unsorted chunks All remainders from chunk splits, as well as all returned chunks, are first placed in the "unsorted" bin. They are then placed in regular bins after malloc gives them ONE chance to be used before binning. So, basically, the unsorted_chunks list acts as a queue, with chunks being placed on it in free (and __malloc_consolidate), and taken off (to be either used or placed in bins) in malloc. */ /* The otherwise unindexable 1-bin is used to hold unsorted chunks. */ #define unsorted_chunks(M) (bin_at(M, 1)) /* Top The top-most available chunk (i.e., the one bordering the end of available memory) is treated specially. It is never included in any bin, is used only if no other chunk is available, and is released back to the system if it is very large (see M_TRIM_THRESHOLD). Because top initially points to its own bin with initial zero size, thus forcing extension on the first malloc request, we avoid having any special code in malloc to check whether it even exists yet. But we still need to do so when getting memory from system, so we make initial_top treat the bin as a legal but unusable chunk during the interval between initialization and the first call to __malloc_alloc. (This is somewhat delicate, since it relies on the 2 preceding words to be zero during this interval as well.) */ /* Conveniently, the unsorted bin can be used as dummy top on first call */ #define initial_top(M) (unsorted_chunks(M)) /* Binmap To help compensate for the large number of bins, a one-level index structure is used for bin-by-bin searching. `binmap' is a bitvector recording whether bins are definitely empty so they can be skipped over during during traversals. The bits are NOT always cleared as soon as bins are empty, but instead only when they are noticed to be empty during traversal in malloc. */ /* Conservatively use 32 bits per map word, even if on 64bit system */ #define BINMAPSHIFT 5 #define BITSPERMAP (1U << BINMAPSHIFT) #define BINMAPSIZE (NBINS / BITSPERMAP) #define idx2block(i) ((i) >> BINMAPSHIFT) #define idx2bit(i) ((1U << ((i) & ((1U << BINMAPSHIFT)-1)))) #define mark_bin(m,i) ((m)->binmap[idx2block(i)] |= idx2bit(i)) #define unmark_bin(m,i) ((m)->binmap[idx2block(i)] &= ~(idx2bit(i))) #define get_binmap(m,i) ((m)->binmap[idx2block(i)] & idx2bit(i)) /* Fastbins An array of lists holding recently freed small chunks. Fastbins are not doubly linked. It is faster to single-link them, and since chunks are never removed from the middles of these lists, double linking is not necessary. Also, unlike regular bins, they are not even processed in FIFO order (they use faster LIFO) since ordering doesn't much matter in the transient contexts in which fastbins are normally used. Chunks in fastbins keep their inuse bit set, so they cannot be consolidated with other free chunks. __malloc_consolidate releases all chunks in fastbins and consolidates them with other free chunks. */ typedef struct malloc_chunk* mfastbinptr; /* offset 2 to use otherwise unindexable first 2 bins */ #define fastbin_index(sz) ((((unsigned int)(sz)) >> 3) - 2) /* The maximum fastbin request size we support */ #define MAX_FAST_SIZE 80 #define NFASTBINS (fastbin_index(request2size(MAX_FAST_SIZE))+1) /* FASTBIN_CONSOLIDATION_THRESHOLD is the size of a chunk in free() that triggers automatic consolidation of possibly-surrounding fastbin chunks. This is a heuristic, so the exact value should not matter too much. It is defined at half the default trim threshold as a compromise heuristic to only attempt consolidation if it is likely to lead to trimming. However, it is not dynamically tunable, since consolidation reduces fragmentation surrounding loarge chunks even if trimming is not used. */ #define FASTBIN_CONSOLIDATION_THRESHOLD \ ((unsigned long)(DEFAULT_TRIM_THRESHOLD) >> 1) /* Since the lowest 2 bits in max_fast don't matter in size comparisons, they are used as flags. */ /* ANYCHUNKS_BIT held in max_fast indicates that there may be any freed chunks at all. It is set true when entering a chunk into any bin. */ #define ANYCHUNKS_BIT (1U) #define have_anychunks(M) (((M)->max_fast & ANYCHUNKS_BIT)) #define set_anychunks(M) ((M)->max_fast |= ANYCHUNKS_BIT) #define clear_anychunks(M) ((M)->max_fast &= ~ANYCHUNKS_BIT) /* FASTCHUNKS_BIT held in max_fast indicates that there are probably some fastbin chunks. It is set true on entering a chunk into any fastbin, and cleared only in __malloc_consolidate. */ #define FASTCHUNKS_BIT (2U) #define have_fastchunks(M) (((M)->max_fast & FASTCHUNKS_BIT)) #define set_fastchunks(M) ((M)->max_fast |= (FASTCHUNKS_BIT|ANYCHUNKS_BIT)) #define clear_fastchunks(M) ((M)->max_fast &= ~(FASTCHUNKS_BIT)) /* Set value of max_fast. Use impossibly small value if 0. */ #define set_max_fast(M, s) \ (M)->max_fast = (((s) == 0)? SMALLBIN_WIDTH: request2size(s)) | \ ((M)->max_fast & (FASTCHUNKS_BIT|ANYCHUNKS_BIT)) #define get_max_fast(M) \ ((M)->max_fast & ~(FASTCHUNKS_BIT | ANYCHUNKS_BIT)) /* morecore_properties is a status word holding dynamically discovered or controlled properties of the morecore function */ #define MORECORE_CONTIGUOUS_BIT (1U) #define contiguous(M) \ (((M)->morecore_properties & MORECORE_CONTIGUOUS_BIT)) #define noncontiguous(M) \ (((M)->morecore_properties & MORECORE_CONTIGUOUS_BIT) == 0) #define set_contiguous(M) \ ((M)->morecore_properties |= MORECORE_CONTIGUOUS_BIT) #define set_noncontiguous(M) \ ((M)->morecore_properties &= ~MORECORE_CONTIGUOUS_BIT) /* ----------- Internal state representation and initialization ----------- */ struct malloc_state { /* The maximum chunk size to be eligible for fastbin */ size_t max_fast; /* low 2 bits used as flags */ /* Fastbins */ mfastbinptr fastbins[NFASTBINS]; /* Base of the topmost chunk -- not otherwise kept in a bin */ mchunkptr top; /* The remainder from the most recent split of a small request */ mchunkptr last_remainder; /* Normal bins packed as described above */ mchunkptr bins[NBINS * 2]; /* Bitmap of bins. Trailing zero map handles cases of largest binned size */ unsigned int binmap[BINMAPSIZE+1]; /* Tunable parameters */ unsigned long trim_threshold; size_t top_pad; size_t mmap_threshold; /* Memory map support */ int n_mmaps; int n_mmaps_max; int max_n_mmaps; /* Cache malloc_getpagesize */ unsigned int pagesize; /* Track properties of MORECORE */ unsigned int morecore_properties; /* Statistics */ size_t mmapped_mem; size_t sbrked_mem; size_t max_sbrked_mem; size_t max_mmapped_mem; size_t max_total_mem; }; typedef struct malloc_state *mstate; /* There is exactly one instance of this struct in this malloc. If you are adapting this malloc in a way that does NOT use a static malloc_state, you MUST explicitly zero-fill it before using. This malloc relies on the property that malloc_state is initialized to all zeroes (as is true of C statics). */ extern struct malloc_state __malloc_state; /* never directly referenced */ /* All uses of av_ are via get_malloc_state(). At most one "call" to get_malloc_state is made per invocation of the public versions of malloc and free, but other routines that in turn invoke malloc and/or free may call more then once. Also, it is called in check* routines if __MALLOC_DEBUGGING is set. */ #define get_malloc_state() (&(__malloc_state)) /* External internal utilities operating on mstates */ void __malloc_consolidate(mstate); /* Debugging support */ #if ! __MALLOC_DEBUGGING #define check_chunk(P) #define check_free_chunk(P) #define check_inuse_chunk(P) #define check_remalloced_chunk(P,N) #define check_malloced_chunk(P,N) #define check_malloc_state() #define assert(x) ((void)0) #else #define check_chunk(P) __do_check_chunk(P) #define check_free_chunk(P) __do_check_free_chunk(P) #define check_inuse_chunk(P) __do_check_inuse_chunk(P) #define check_remalloced_chunk(P,N) __do_check_remalloced_chunk(P,N) #define check_malloced_chunk(P,N) __do_check_malloced_chunk(P,N) #define check_malloc_state() __do_check_malloc_state() extern void __do_check_chunk(mchunkptr p); extern void __do_check_free_chunk(mchunkptr p); extern void __do_check_inuse_chunk(mchunkptr p); extern void __do_check_remalloced_chunk(mchunkptr p, size_t s); extern void __do_check_malloced_chunk(mchunkptr p, size_t s); extern void __do_check_malloc_state(void); #include <assert.h> #endif
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