/* $Id: fifo.c,v 1.17 2005/10/15 18:05:03 titer Exp $ This file is part of the HandBrake source code. Homepage: . It may be used under the terms of the GNU General Public License. */ #include "hb.h" #ifndef SYS_DARWIN #include #endif /* Fifo */ struct hb_fifo_s { hb_lock_t * lock; uint32_t capacity; uint32_t size; uint32_t buffer_size; hb_buffer_t * first; hb_buffer_t * last; }; /* we round the requested buffer size up to the next power of 2 so there can * be at most 32 possible pools when the size is a 32 bit int. To avoid a lot * of slow & error-prone run-time checking we allow for all 32. */ #define MAX_BUFFER_POOLS 32 /* the buffer pool only exists to avoid the two malloc and two free calls that * it would otherwise take to allocate & free a buffer. but we don't want to * tie up a lot of memory in the pool because this allocator isn't as general * as malloc so memory tied up here puts more pressure on the malloc pool. * A pool of 16 elements will avoid 94% of the malloc/free calls without wasting * too much memory. */ #define BUFFER_POOL_MAX_ELEMENTS 32 struct hb_buffer_pools_s { int64_t allocated; hb_lock_t *lock; hb_fifo_t *pool[MAX_BUFFER_POOLS]; } buffers; void hb_buffer_pool_init( void ) { buffers.lock = hb_lock_init(); buffers.allocated = 0; /* we allocate pools for sizes 2^10 through 2^25. requests larger than * 2^25 will get passed through to malloc. */ int i; for ( i = 10; i < 26; ++i ) { buffers.pool[i] = hb_fifo_init(BUFFER_POOL_MAX_ELEMENTS); buffers.pool[i]->buffer_size = 1 << i; } /* requests smaller than 2^10 are satisfied from the 2^10 pool. */ for ( i = 1; i < 10; ++i ) { buffers.pool[i] = buffers.pool[10]; } } void hb_buffer_pool_free( void ) { int i; int count; int64_t freed = 0; hb_buffer_t *b; hb_lock(buffers.lock); for( i = 10; i < 26; ++i) { count = 0; while( ( b = hb_fifo_get(buffers.pool[i]) ) ) { freed += b->alloc; if( b->data ) { free( b->data ); } free( b ); count++; } if ( count ) { hb_deep_log( 2, "Freed %d buffers of size %d", count, buffers.pool[i]->buffer_size); } } hb_deep_log( 2, "Allocated %"PRId64" bytes of buffers on this pass and Freed %"PRId64" bytes, " "%"PRId64" bytes leaked", buffers.allocated, freed, buffers.allocated - freed); buffers.allocated = 0; hb_unlock(buffers.lock); } static hb_fifo_t *size_to_pool( int size ) { int i; for ( i = 0; i < 30; ++i ) { if ( size <= (1 << i) ) { return buffers.pool[i]; } } return NULL; } hb_buffer_t * hb_buffer_init( int size ) { hb_buffer_t * b; hb_fifo_t *buffer_pool = size_to_pool( size ); if( buffer_pool ) { b = hb_fifo_get( buffer_pool ); if( b ) { /* * Zero the contents of the buffer, would be nice if we * didn't have to do this. */ uint8_t *data = b->data; memset( b, 0, sizeof(hb_buffer_t) ); b->alloc = buffer_pool->buffer_size; b->size = size; b->data = data; return( b ); } } /* * No existing buffers, create a new one */ if( !( b = calloc( sizeof( hb_buffer_t ), 1 ) ) ) { hb_log( "out of memory" ); return NULL; } b->size = size; b->alloc = buffer_pool? buffer_pool->buffer_size : size; if (size) { #if defined( SYS_DARWIN ) || defined( SYS_FREEBSD ) || defined( SYS_MINGW ) b->data = malloc( b->alloc ); #elif defined( SYS_CYGWIN ) /* FIXME */ b->data = malloc( b->alloc + 17 ); #else b->data = memalign( 16, b->alloc ); #endif if( !b->data ) { hb_log( "out of memory" ); free( b ); return NULL; } hb_lock(buffers.lock); buffers.allocated += b->alloc; hb_unlock(buffers.lock); } return b; } void hb_buffer_realloc( hb_buffer_t * b, int size ) { if ( size > b->alloc ) { uint32_t orig = b->alloc; size = size_to_pool( size )->buffer_size; b->data = realloc( b->data, size ); b->alloc = size; hb_lock(buffers.lock); buffers.allocated += size - orig; hb_unlock(buffers.lock); } } void hb_buffer_close( hb_buffer_t ** _b ) { hb_buffer_t * b = *_b; hb_fifo_t *buffer_pool = size_to_pool( b->alloc ); if( buffer_pool && b->data && !hb_fifo_is_full( buffer_pool ) ) { hb_fifo_push_head( buffer_pool, b ); *_b = NULL; return; } /* either the pool is full or this size doesn't use a pool - free the buf */ if( b->data ) { free( b->data ); hb_lock(buffers.lock); buffers.allocated -= b->alloc; hb_unlock(buffers.lock); } free( b ); *_b = NULL; } void hb_buffer_copy_settings( hb_buffer_t * dst, const hb_buffer_t * src ) { dst->start = src->start; dst->stop = src->stop; dst->new_chap = src->new_chap; dst->frametype = src->frametype; dst->flags = src->flags; } hb_fifo_t * hb_fifo_init( int capacity ) { hb_fifo_t * f; f = calloc( sizeof( hb_fifo_t ), 1 ); f->lock = hb_lock_init(); f->capacity = capacity; f->buffer_size = 0; return f; } int hb_fifo_size( hb_fifo_t * f ) { int ret; hb_lock( f->lock ); ret = f->size; hb_unlock( f->lock ); return ret; } int hb_fifo_is_full( hb_fifo_t * f ) { int ret; hb_lock( f->lock ); ret = ( f->size >= f->capacity ); hb_unlock( f->lock ); return ret; } float hb_fifo_percent_full( hb_fifo_t * f ) { float ret; hb_lock( f->lock ); ret = f->size / f->capacity; hb_unlock( f->lock ); return ret; } hb_buffer_t * hb_fifo_get( hb_fifo_t * f ) { hb_buffer_t * b; hb_lock( f->lock ); if( f->size < 1 ) { hb_unlock( f->lock ); return NULL; } b = f->first; f->first = b->next; b->next = NULL; f->size -= 1; hb_unlock( f->lock ); return b; } hb_buffer_t * hb_fifo_see( hb_fifo_t * f ) { hb_buffer_t * b; hb_lock( f->lock ); if( f->size < 1 ) { hb_unlock( f->lock ); return NULL; } b = f->first; hb_unlock( f->lock ); return b; } hb_buffer_t * hb_fifo_see2( hb_fifo_t * f ) { hb_buffer_t * b; hb_lock( f->lock ); if( f->size < 2 ) { hb_unlock( f->lock ); return NULL; } b = f->first->next; hb_unlock( f->lock ); return b; } void hb_fifo_push( hb_fifo_t * f, hb_buffer_t * b ) { if( !b ) { return; } hb_lock( f->lock ); if( f->size > 0 ) { f->last->next = b; } else { f->first = b; } f->last = b; f->size += 1; while( f->last->next ) { f->size += 1; f->last = f->last->next; } hb_unlock( f->lock ); } void hb_fifo_push_head( hb_fifo_t * f, hb_buffer_t * b ) { hb_buffer_t * tmp; uint32_t size = 0; if( !b ) { return; } hb_lock( f->lock ); /* * If there are a chain of buffers prepend the lot */ tmp = b; while( tmp->next ) { tmp = tmp->next; size += 1; } if( f->size > 0 ) { tmp->next = f->first; } else { f->last = tmp; } f->first = b; f->size += ( size + 1 ); hb_unlock( f->lock ); } void hb_fifo_close( hb_fifo_t ** _f ) { hb_fifo_t * f = *_f; hb_buffer_t * b; hb_deep_log( 2, "fifo_close: trashing %d buffer(s)", hb_fifo_size( f ) ); while( ( b = hb_fifo_get( f ) ) ) { hb_buffer_close( &b ); } hb_lock_close( &f->lock ); free( f ); *_f = NULL; }