/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * Lifetime-based fast allocation, inspired by much prior art, including * "Fast Allocation and Deallocation of Memory Based on Object Lifetimes" * David R. Hanson, Software -- Practice and Experience, Vol. 20(1). */ #include #include #include "plarena.h" #include "prmem.h" #include "prbit.h" #include "prlog.h" #include "prlock.h" #include "prinit.h" static PLArena *arena_freelist; #ifdef PL_ARENAMETER static PLArenaStats *arena_stats_list; #define COUNT(pool,what) (pool)->stats.what++ #else #define COUNT(pool,what) /* nothing */ #endif #define PL_ARENA_DEFAULT_ALIGN sizeof(double) static PRLock *arenaLock; static PRCallOnceType once; static const PRCallOnceType pristineCallOnce; /* ** InitializeArenas() -- Initialize arena operations. ** ** InitializeArenas() is called exactly once and only once from ** LockArena(). This function creates the arena protection ** lock: arenaLock. ** ** Note: If the arenaLock cannot be created, InitializeArenas() ** fails quietly, returning only PR_FAILURE. This percolates up ** to the application using the Arena API. He gets no arena ** from PL_ArenaAllocate(). It's up to him to fail gracefully ** or recover. ** */ static PRStatus InitializeArenas( void ) { PR_ASSERT( arenaLock == NULL ); arenaLock = PR_NewLock(); if ( arenaLock == NULL ) return PR_FAILURE; else return PR_SUCCESS; } /* end ArenaInitialize() */ static PRStatus LockArena( void ) { PRStatus rc = PR_CallOnce( &once, InitializeArenas ); if ( PR_FAILURE != rc ) PR_Lock( arenaLock ); return(rc); } /* end LockArena() */ static void UnlockArena( void ) { PR_Unlock( arenaLock ); return; } /* end UnlockArena() */ PR_IMPLEMENT(void) PL_InitArenaPool( PLArenaPool *pool, const char *name, PRUint32 size, PRUint32 align) { /* * Look-up table of PR_BITMASK(PR_CeilingLog2(align)) values for * align = 1 to 32. */ static const PRUint8 pmasks[33] = { 0, /* not used */ 0, 1, 3, 3, 7, 7, 7, 7,15,15,15,15,15,15,15,15, /* 1 ... 16 */ 31,31,31,31,31,31,31,31,31,31,31,31,31,31,31,31}; /* 17 ... 32 */ if (align == 0) align = PL_ARENA_DEFAULT_ALIGN; if (align < sizeof(pmasks)/sizeof(pmasks[0])) pool->mask = pmasks[align]; else pool->mask = PR_BITMASK(PR_CeilingLog2(align)); pool->first.next = NULL; pool->first.base = pool->first.avail = pool->first.limit = (PRUword)PL_ARENA_ALIGN(pool, &pool->first + 1); pool->current = &pool->first; /* * Compute the net size so that each arena's gross size is |size|. * sizeof(PLArena) + pool->mask is the header and alignment slop * that PL_ArenaAllocate adds to the net size. */ if (size > sizeof(PLArena) + pool->mask) pool->arenasize = size - (sizeof(PLArena) + pool->mask); else pool->arenasize = size; #ifdef PL_ARENAMETER memset(&pool->stats, 0, sizeof pool->stats); pool->stats.name = strdup(name); pool->stats.next = arena_stats_list; arena_stats_list = &pool->stats; #endif } /* ** PL_ArenaAllocate() -- allocate space from an arena pool ** ** Description: PL_ArenaAllocate() allocates space from an arena ** pool. ** ** First, try to satisfy the request from arenas starting at ** pool->current. ** ** If there is not enough space in the arena pool->current, try ** to claim an arena, on a first fit basis, from the global ** freelist (arena_freelist). ** ** If no arena in arena_freelist is suitable, then try to ** allocate a new arena from the heap. ** ** Returns: pointer to allocated space or NULL ** ** Notes: The original implementation had some difficult to ** solve bugs; the code was difficult to read. Sometimes it's ** just easier to rewrite it. I did that. larryh. ** ** See also: bugzilla: 45343. ** */ PR_IMPLEMENT(void *) PL_ArenaAllocate(PLArenaPool *pool, PRUint32 nb) { PLArena *a; char *rp; /* returned pointer */ PR_ASSERT((nb & pool->mask) == 0); nb = (PRUword)PL_ARENA_ALIGN(pool, nb); /* force alignment */ /* attempt to allocate from arenas at pool->current */ { a = pool->current; do { if ( a->avail +nb <= a->limit ) { pool->current = a; rp = (char *)a->avail; a->avail += nb; return rp; } } while( NULL != (a = a->next) ); } /* attempt to allocate from arena_freelist */ { PLArena *p; /* previous pointer, for unlinking from freelist */ /* lock the arena_freelist. Make access to the freelist MT-Safe */ if ( PR_FAILURE == LockArena()) return(0); for ( a = arena_freelist, p = NULL; a != NULL ; p = a, a = a->next ) { if ( a->base +nb <= a->limit ) { if ( p == NULL ) arena_freelist = a->next; else p->next = a->next; UnlockArena(); a->avail = a->base; rp = (char *)a->avail; a->avail += nb; /* the newly allocated arena is linked after pool->current * and becomes pool->current */ a->next = pool->current->next; pool->current->next = a; pool->current = a; if ( NULL == pool->first.next ) pool->first.next = a; return(rp); } } UnlockArena(); } /* attempt to allocate from the heap */ { PRUint32 sz = PR_MAX(pool->arenasize, nb); sz += sizeof *a + pool->mask; /* header and alignment slop */ a = (PLArena*)PR_MALLOC(sz); if ( NULL != a ) { a->limit = (PRUword)a + sz; a->base = a->avail = (PRUword)PL_ARENA_ALIGN(pool, a + 1); PL_MAKE_MEM_NOACCESS((void*)a->avail, a->limit - a->avail); rp = (char *)a->avail; a->avail += nb; /* the newly allocated arena is linked after pool->current * and becomes pool->current */ a->next = pool->current->next; pool->current->next = a; pool->current = a; if ( NULL == pool->first.next ) pool->first.next = a; PL_COUNT_ARENA(pool,++); COUNT(pool, nmallocs); return(rp); } } /* we got to here, and there's no memory to allocate */ return(NULL); } /* --- end PL_ArenaAllocate() --- */ PR_IMPLEMENT(void *) PL_ArenaGrow( PLArenaPool *pool, void *p, PRUint32 size, PRUint32 incr) { void *newp; PL_ARENA_ALLOCATE(newp, pool, size + incr); if (newp) memcpy(newp, p, size); return newp; } static void ClearArenaList(PLArena *a, PRInt32 pattern) { for (; a; a = a->next) { PR_ASSERT(a->base <= a->avail && a->avail <= a->limit); a->avail = a->base; PL_CLEAR_UNUSED_PATTERN(a, pattern); PL_MAKE_MEM_NOACCESS((void*)a->avail, a->limit - a->avail); } } PR_IMPLEMENT(void) PL_ClearArenaPool(PLArenaPool *pool, PRInt32 pattern) { ClearArenaList(pool->first.next, pattern); } /* * Free tail arenas linked after head, which may not be the true list head. * Reset pool->current to point to head in case it pointed at a tail arena. */ static void FreeArenaList(PLArenaPool *pool, PLArena *head, PRBool reallyFree) { PLArena **ap, *a; ap = &head->next; a = *ap; if (!a) return; #ifdef DEBUG ClearArenaList(a, PL_FREE_PATTERN); #endif if (reallyFree) { do { *ap = a->next; PL_CLEAR_ARENA(a); PL_COUNT_ARENA(pool,--); PR_DELETE(a); } while ((a = *ap) != 0); } else { /* Insert the whole arena chain at the front of the freelist. */ do { PL_MAKE_MEM_NOACCESS((void*)(*ap)->base, (*ap)->limit - (*ap)->base); ap = &(*ap)->next; } while (*ap); LockArena(); *ap = arena_freelist; arena_freelist = a; head->next = 0; UnlockArena(); } pool->current = head; } PR_IMPLEMENT(void) PL_ArenaRelease(PLArenaPool *pool, char *mark) { PLArena *a; for (a = &pool->first; a; a = a->next) { if (PR_UPTRDIFF(mark, a->base) <= PR_UPTRDIFF(a->avail, a->base)) { a->avail = (PRUword)PL_ARENA_ALIGN(pool, mark); FreeArenaList(pool, a, PR_FALSE); return; } } } PR_IMPLEMENT(void) PL_FreeArenaPool(PLArenaPool *pool) { FreeArenaList(pool, &pool->first, PR_FALSE); COUNT(pool, ndeallocs); } PR_IMPLEMENT(void) PL_FinishArenaPool(PLArenaPool *pool) { FreeArenaList(pool, &pool->first, PR_TRUE); #ifdef PL_ARENAMETER { PLArenaStats *stats, **statsp; if (pool->stats.name) PR_DELETE(pool->stats.name); for (statsp = &arena_stats_list; (stats = *statsp) != 0; statsp = &stats->next) { if (stats == &pool->stats) { *statsp = stats->next; return; } } } #endif } PR_IMPLEMENT(void) PL_CompactArenaPool(PLArenaPool *ap) { } PR_IMPLEMENT(void) PL_ArenaFinish(void) { PLArena *a, *next; for (a = arena_freelist; a; a = next) { next = a->next; PR_DELETE(a); } arena_freelist = NULL; if (arenaLock) { PR_DestroyLock(arenaLock); arenaLock = NULL; } once = pristineCallOnce; } PR_IMPLEMENT(size_t) PL_SizeOfArenaPoolExcludingPool( const PLArenaPool *pool, PLMallocSizeFn mallocSizeOf) { /* * The first PLArena is within |pool|, so don't measure it. Subsequent * PLArenas are separate and must be measured. */ size_t size = 0; const PLArena *arena = pool->first.next; while (arena) { size += mallocSizeOf(arena); arena = arena->next; } return size; } #ifdef PL_ARENAMETER PR_IMPLEMENT(void) PL_ArenaCountAllocation(PLArenaPool *pool, PRUint32 nb) { pool->stats.nallocs++; pool->stats.nbytes += nb; if (nb > pool->stats.maxalloc) pool->stats.maxalloc = nb; pool->stats.variance += nb * nb; } PR_IMPLEMENT(void) PL_ArenaCountInplaceGrowth( PLArenaPool *pool, PRUint32 size, PRUint32 incr) { pool->stats.ninplace++; } PR_IMPLEMENT(void) PL_ArenaCountGrowth( PLArenaPool *pool, PRUint32 size, PRUint32 incr) { pool->stats.ngrows++; pool->stats.nbytes += incr; pool->stats.variance -= size * size; size += incr; if (size > pool->stats.maxalloc) pool->stats.maxalloc = size; pool->stats.variance += size * size; } PR_IMPLEMENT(void) PL_ArenaCountRelease(PLArenaPool *pool, char *mark) { pool->stats.nreleases++; } PR_IMPLEMENT(void) PL_ArenaCountRetract(PLArenaPool *pool, char *mark) { pool->stats.nfastrels++; } #include #include PR_IMPLEMENT(void) PL_DumpArenaStats(FILE *fp) { PLArenaStats *stats; double mean, variance; for (stats = arena_stats_list; stats; stats = stats->next) { if (stats->nallocs != 0) { mean = (double)stats->nbytes / stats->nallocs; variance = fabs(stats->variance / stats->nallocs - mean * mean); } else { mean = variance = 0; } fprintf(fp, "\n%s allocation statistics:\n", stats->name); fprintf(fp, " number of arenas: %u\n", stats->narenas); fprintf(fp, " number of allocations: %u\n", stats->nallocs); fprintf(fp, " number of free arena reclaims: %u\n", stats->nreclaims); fprintf(fp, " number of malloc calls: %u\n", stats->nmallocs); fprintf(fp, " number of deallocations: %u\n", stats->ndeallocs); fprintf(fp, " number of allocation growths: %u\n", stats->ngrows); fprintf(fp, " number of in-place growths: %u\n", stats->ninplace); fprintf(fp, "number of released allocations: %u\n", stats->nreleases); fprintf(fp, " number of fast releases: %u\n", stats->nfastrels); fprintf(fp, " total bytes allocated: %u\n", stats->nbytes); fprintf(fp, " mean allocation size: %g\n", mean); fprintf(fp, " standard deviation: %g\n", sqrt(variance)); fprintf(fp, " maximum allocation size: %u\n", stats->maxalloc); } } #endif /* PL_ARENAMETER */