/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2002 by Daniel Stenberg * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ /***************************************************************************** * * Dynamic small-blocks Memory Allocation * * Author: Daniel Stenberg * * Read THOUGHTS for theories and details on the implementation. * *****************************************************************************/ #include #include /* memcpy */ #ifdef DEBUG_MALLOC #include #endif #ifdef PSOS #include #define SEMAPHORE /* the PSOS routines use semaphore protection */ #else #endif #define BMALLOC /* we use our own big-malloc system */ #ifdef BMALLOC #include "bmalloc.h" #endif /* Each TOP takes care of a chain of BLOCKS */ struct MemTop { struct MemBlock *chain; /* pointer to the BLOCK chain */ long nfree; /* total number of free FRAGMENTS in the chain */ short nmax; /* total number of FRAGMENTS in this kind of BLOCK */ size_t fragsize; /* the size of each FRAGMENT */ #ifdef SEMAPHORE /* if we're protecting the list with SEMAPHORES */ long semaphore_id; /* semaphore used to lock this particular list */ #endif }; /* Each BLOCK takes care of an amount of FRAGMENTS */ struct MemBlock { struct MemTop *top; /* our TOP struct */ struct MemBlock *next; /* next BLOCK */ struct MemBlock *prev; /* prev BLOCK */ struct MemFrag *first; /* the first free FRAGMENT in this block */ short nfree; /* number of free FRAGMENTS in this BLOCK */ }; /* This is the data kept in all _free_ FRAGMENTS */ struct MemFrag { struct MemFrag *next; /* next free FRAGMENT */ struct MemFrag *prev; /* prev free FRAGMENT */ }; /* This is the data kept in all _allocated_ FRAGMENTS and BLOCKS. We add this to the allocation size first thing in the ALLOC function to make room for this smoothly. */ struct MemInfo { void *block; /* which BLOCK is our father, if BLOCK_BIT is set it means this is a stand-alone, large allocation and then the rest of the bits should be treated as the size of the block */ #define BLOCK_BIT 1 }; /* ---------------------------------------------------------------------- */ /* Defines */ /* ---------------------------------------------------------------------- */ #ifdef DEBUG_VERBOSE #define MEMINCR(addr,x) memchange(addr, x) #define MEMDECR(addr,x) memchange(addr,-(x)) #else #define MEMINCR(a,x) #define MEMDECR(a,x) #endif /* The low level functions used to get memory from the OS and to return memory to the OS, we may also define a stub that does the actual allocation and free, these are the defined function names used in the dmalloc system anyway: */ #ifdef PSOS #ifdef DEBUG_MALLOC #define DMEM_OSALLOCMEM(size,pointer,type) pointer=(type)dbgmalloc(size) #define DMEM_OSFREEMEM(x) dbgfree(x) #else #define DMEM_OSALLOCMEM(size,pointer,type) rn_getseg(0,size,RN_NOWAIT,0,(void **)&pointer) /* Similar, but this returns the memory */ #define DMEM_OSFREEMEM(x) rn_retseg(0, x) #endif /* Argument: */ #define SEMAPHOREOBTAIN(x) sm_p(x, SM_WAIT, 0) /* Argument: */ #define SEMAPHORERETURN(x) sm_v(x) /* Argument: */ #define SEMAPHORECREATE(x,y) sm_create(x, 1, SM_FIFO, (ULONG *)&(y)) #else #ifdef BMALLOC /* use our own big-memory-allocation system */ #define DMEM_OSALLOCMEM(size,pointer,type) pointer=(type)bmalloc(size) #define DMEM_OSFREEMEM(x) bfree(x) #elif DEBUG_MALLOC #define DMEM_OSALLOCMEM(size,pointer,type) pointer=(type)dbgmalloc(size) #define DMEM_OSFREEMEM(x) dbgfree(x) #else #define DMEM_OSALLOCMEM(size,pointer,type) pointer=(type)malloc(size) #define DMEM_OSFREEMEM(x) free(x) #endif #endif /* the largest memory allocation that is made a FRAGMENT: (grab the highest number from the list below) */ #define DMEM_LARGESTSIZE 2032 /* The total size of a BLOCK used for FRAGMENTS In order to make this use only *1* even alignment from the big-block- allocation-system (possible the bmalloc() system also written by me) we need to subtract the [maximum] struct sizes that could get added all the way through to the grab from the memory. */ #define DMEM_BLOCKSIZE 4064 /* (4096 - sizeof(struct MemBlock) - 12) */ /* Since the blocksize isn't an even 2^X story anymore, we make a table with the FRAGMENT sizes and amounts that fills up a BLOCK nicely */ /* a little 'bc' script that helps us maximize the usage: - for 32-bit aligned addresses (SPARC crashes otherwise): for(i=20; i<2040; i+=4) { a=4064/i; if(a*i >= 4060) { {i;} } } I try to approximate a double of each size, starting with ~20. We don't do ODD sizes since several CPU flavours dump core when accessing such addresses. We try to do 32-bit aligned to make ALL kinds of CPUs to remain happy with us. */ static const unsigned short qinfo[]= { 20, 28, 52, 116, 312, 580, 1016, 2032 }; #define MIN(x,y) ((x)<(y)?(x):(y)) /* ---------------------------------------------------------------------- */ /* Globals */ /* ---------------------------------------------------------------------- */ /* keeper of the chain of BLOCKS */ static struct MemTop top[ sizeof(qinfo)/sizeof(qinfo[0]) ]; /* ---------------------------------------------------------------------- */ /* Start of the real code */ /* ---------------------------------------------------------------------- */ #ifdef DEBUG_MALLOC /************ * A few functions that are verbose and tells us about the current status * of the dmalloc system ***********/ void dmalloc_status(void) { unsigned int i; int used; int num; int totalfree=0; struct MemBlock *block; for(i=0; infree; num++; block = block->next; } printf("Q %d (FRAG %4d), USED %4d FREE %4ld (SIZE %4ld) BLOCKS %d\n", i, top[i].fragsize, used, top[i].nfree, top[i].nfree*top[i].fragsize, num); totalfree += top[i].nfree*top[i].fragsize; } printf("Total unused memory stolen by dmalloc: %d\n", totalfree); } #endif #ifdef DEBUG_VERBOSE static void dmalloc_failed(size_t size) { printf("*** " __FILE__ " Couldn't allocate %d bytes\n", size); dmalloc_status(); } #else #define dmalloc_failed(x) #endif #ifdef DEBUG_VERBOSE #define DBG(x) syslog x void syslog(char *fmt, ...) { va_list ap; va_start(ap, fmt); vfprintf(stdout, fmt, ap); va_end(ap); } void memchange(void *a, int x) { static int memory=0; static int count=0; static int max=0; if(memory > max) max = memory; memory += x; DBG(("%d. PTR %p / %d TOTAL %d MAX %d\n", ++count, a, x, memory, max)); } #else #define DBG(x) #endif /**************************************************************************** * * FragBlock() * * This function makes FRAGMENTS of the BLOCK sent as argument. * ***************************************************************************/ static void FragBlock(char *memp, int size) { struct MemFrag *frag=(struct MemFrag *)memp; struct MemFrag *prev=NULL; /* no previous in the first round */ int count=0; while((count+size) <= DMEM_BLOCKSIZE) { frag->next = (struct MemFrag *)((char *)frag + size); frag->prev = prev; prev = frag; (char *)frag += size; count += size; } prev->next = NULL; /* the last one has no next struct */ } /*************************************************************************** * * dmalloc_initialize(); * * Call before the first dmalloc(). Inits a few memory things. * **************************************************************************/ void dmalloc_initialize(void) { unsigned int i; /* Setup the nmax and fragsize fields of the top structs */ for(i=0; i< sizeof(qinfo)/sizeof(qinfo[0]); i++) { top[i].fragsize = qinfo[i]; top[i].nmax = DMEM_BLOCKSIZE/qinfo[i]; #ifdef PSOS /* for some reason, these aren't nulled from start: */ top[i].chain = NULL; /* no BLOCKS */ top[i].nfree = 0; /* no FRAGMENTS */ #endif #ifdef SEMAPHORE { char name[7]; snprintf(name, 7, "MEM%d", i); SEMAPHORECREATE(name, top[i].semaphore_id); /* doesn't matter if it failed, we continue anyway ;-( */ } #endif } } /**************************************************************************** * * fragfromblock() * * This should return a fragment from the block and mark it as used * accordingly. * ***************************************************************************/ static void *fragfromblock(struct MemBlock *block) { /* make frag point to the first free FRAGMENT */ struct MemFrag *frag = block->first; struct MemInfo *mem = (struct MemInfo *)frag; /* * Remove the FRAGMENT from the list and decrease the free counters. */ block->first = frag->next; /* new first free FRAGMENT */ block->nfree--; /* BLOCK counter */ block->top->nfree--; /* TOP counter */ /* heal the FRAGMENT list */ if(frag->prev) { frag->prev->next = frag->next; } if(frag->next) { frag->next->prev = frag->prev; } mem->block = block; /* no block bit set here */ return ((char *)mem)+sizeof(struct MemInfo); } /*************************************************************************** * * dmalloc() * * This needs no explanation. A malloc() look-alike. * **************************************************************************/ void *malloc(size_t size) { void *mem; DBG(("malloc(%d)\n", size)); /* First, we make room for the space needed in every allocation */ size += sizeof(struct MemInfo); if(size < DMEM_LARGESTSIZE) { /* get a FRAGMENT */ struct MemBlock *block=NULL; /* SAFE */ struct MemBlock *newblock=NULL; /* SAFE */ struct MemTop *memtop=NULL; /* SAFE */ /* Determine which queue to use */ unsigned int queue; for(queue=0; size > qinfo[queue]; queue++) ; do { /* This is the head master of our chain: */ memtop = &top[queue]; DBG(("Top info: CHAIN %p FREE %d MAX %d FRAGSIZE %d\n", memtop->chain, memtop->nfree, memtop->nmax, memtop->fragsize)); #ifdef SEMAPHORE if(SEMAPHOREOBTAIN(memtop->semaphore_id)) return NULL; /* failed somehow */ #endif /* get the first BLOCK in the chain */ block = memtop->chain; /* check if we have a free FRAGMENT */ if(memtop->nfree) { /* there exists a free FRAGMENT in this chain */ /**** We'd prefer to not have this loop here! ****/ /* search for the free FRAGMENT */ while(!block->nfree) block = block->next; /* check next BLOCK */ /* * Now 'block' is the first BLOCK with a free FRAGMENT */ mem = fragfromblock(block); } else { /* we do *not* have a free FRAGMENT but need to get us a new * BLOCK */ DMEM_OSALLOCMEM(DMEM_BLOCKSIZE + sizeof(struct MemBlock), newblock, struct MemBlock *); if(!newblock) { if(++queue < sizeof(qinfo)/sizeof(qinfo[0])) { /* There are queues for bigger FRAGMENTS that we * should check before we fail this for real */ #ifdef DEBUG_VERBOSE printf("*** " __FILE__ " Trying a bigger Q: %d\n", queue); #endif mem = NULL; } else { dmalloc_failed(size- sizeof(struct MemInfo)); return NULL; /* not enough memory */ } } else { /* allocation of big BLOCK was successful */ MEMINCR(newblock, DMEM_BLOCKSIZE + sizeof(struct MemBlock)); memtop->chain = newblock; /* attach this BLOCK to the chain */ newblock->next = block; /* point to the previous first BLOCK */ if(block) block->prev = newblock; /* point back on this new BLOCK */ newblock->prev = NULL; /* no previous */ newblock->top = memtop; /* our head master */ /* point to the new first FRAGMENT */ newblock->first = (struct MemFrag *) ((char *)newblock+sizeof(struct MemBlock)); /* create FRAGMENTS of the BLOCK: */ FragBlock((char *)newblock->first, memtop->fragsize); /* fix the nfree counters */ newblock->nfree = memtop->nmax; memtop->nfree += memtop->nmax; /* get a FRAGMENT from the BLOCK */ mem = fragfromblock(newblock); } } #ifdef SEMAPHORE SEMAPHORERETURN(memtop->semaphore_id); /* let it go */ #endif } while(NULL == mem); /* if we should retry a larger FRAGMENT */ } else { /* get a stand-alone BLOCK */ struct MemInfo *meminfo; if(size&1) /* don't leave this with an odd size since we'll use that bit for information */ size++; DMEM_OSALLOCMEM(size, meminfo, struct MemInfo *); if(meminfo) { MEMINCR(meminfo, size); meminfo->block = (void *)(size|BLOCK_BIT); mem = (char *)meminfo + sizeof(struct MemInfo); } else { dmalloc_failed(size); mem = NULL; } } return (void *)mem; } /*************************************************************************** * * dfree() * * This needs no explanation. A free() look-alike. * **************************************************************************/ void free(void *memp) { struct MemInfo *meminfo = (struct MemInfo *) ((char *)memp- sizeof(struct MemInfo)); DBG(("free(%p)\n", memp)); if(!((size_t)meminfo->block&BLOCK_BIT)) { /* this is a FRAGMENT we have to deal with */ struct MemBlock *block=meminfo->block; struct MemTop *memtop = block->top; #ifdef SEMAPHORE SEMAPHOREOBTAIN(memtop->semaphore_id); #endif /* increase counters */ block->nfree++; memtop->nfree++; /* is this BLOCK completely empty now? */ if(block->nfree == memtop->nmax) { /* yes, return the BLOCK to the system */ if(block->prev) block->prev->next = block->next; else memtop->chain = block->next; if(block->next) block->next->prev = block->prev; memtop->nfree -= memtop->nmax; /* total counter subtraction */ MEMDECR(block, DMEM_BLOCKSIZE + sizeof(struct MemBlock)); DMEM_OSFREEMEM((void *)block); /* return the whole block */ } else { /* there are still used FRAGMENTS in the BLOCK, link this one into the chain of free ones */ struct MemFrag *frag = (struct MemFrag *)meminfo; frag->prev = NULL; frag->next = block->first; if(block->first) block->first->prev = frag; block->first = frag; } #ifdef SEMAPHORE SEMAPHORERETURN(memtop->semaphore_id); #endif } else { /* big stand-alone block, just give it back to the OS: */ /* clean BLOCK_BIT */ MEMDECR(meminfo->block, (size_t)meminfo->block&~BLOCK_BIT); DMEM_OSFREEMEM((void *)meminfo); } } /*************************************************************************** * * drealloc() * * This needs no explanation. A realloc() look-alike. * **************************************************************************/ void *realloc(void *ptr, size_t size) { struct MemInfo *meminfo = (struct MemInfo *) ((char *)ptr- sizeof(struct MemInfo)); /* * ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ * NOTE: the ->size field of the meminfo will now contain the MemInfo * struct size too! * ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ */ void *mem=NULL; /* SAFE */ size_t prevsize; /* NOTE that this is only valid if BLOCK_BIT isn't set: */ struct MemBlock *block; DBG(("realloc(%p, %d)\n", ptr, size)); if(NULL == ptr) return malloc( size ); block = meminfo->block; /* Here we check if this is a FRAGMENT and if the new size is still smaller than the fragsize for this block. */ if(!((size_t)block&BLOCK_BIT) && (size + sizeof(struct MemInfo) < block->top->fragsize )) { prevsize = block->top->fragsize; /* This is a FRAGMENT and new size is possible to retain within the same FRAGMENT */ if((prevsize > qinfo[0]) && /* this is not the smallest memory Q */ (size < (block->top-1)->fragsize)) /* This fits in a smaller fragment, so we will make a realloc here */ ; else mem = ptr; /* Just return the same pointer as we got in. */ } if(!mem) { if((size_t)meminfo->block&BLOCK_BIT) { /* This is a stand-alone BLOCK */ prevsize = ((size_t)meminfo->block&~BLOCK_BIT) - sizeof(struct MemInfo); } else /* a FRAGMENT realloc that no longer fits within the same FRAGMENT * or one that fits in a smaller */ prevsize = block->top->fragsize; /* No tricks involved here, just grab a new bite of memory, copy the * data from the old place and free the old memory again. */ mem = malloc(size); if(mem) { memcpy(mem, ptr, MIN(size, prevsize) ); free(ptr); } } return mem; } /*************************************************************************** * * dcalloc() * * This needs no explanation. A calloc() look-alike. * **************************************************************************/ /* Allocate an array of NMEMB elements each SIZE bytes long. The entire array is initialized to zeros. */ void * calloc (size_t nmemb, size_t size) { void *result = malloc (nmemb * size); if (result != NULL) memset (result, 0, nmemb * size); return result; } /* ----------------------------------------------------------------- * local variables: * eval: (load-file "../rockbox-mode.el") * end: */