FreeCalypso > hg > freecalypso-sw
view gsm-fw/riviera/rvf/rvf_buffer.c @ 364:4a78dc764229
OSL: os_drv.c started
author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
---|---|
date | Thu, 29 May 2014 00:01:26 +0000 |
parents | afceeeb2cba1 |
children |
line wrap: on
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/****************************************************************************/ /* */ /* Name rvf_buffer.c */ /* */ /* Function this file contains rvf buffer handling functions */ /* */ /* Version 0.1 */ /* */ /* Date Modification */ /* ------------------------------------ */ /* 3/12/99 Create */ /* 10/27/1999 remove all non-nucleus sections (#ifdef) */ /* 30/11/1999 compliant to RV coding guidelines */ /* 12/23/1999 change buffer management, add memory bank handling and */ /* remove useless functions */ /* 07/12/2000 implement dynamic memory allocation. */ /* */ /* Author David Lamy-Charrier (dlamy@tif.ti.com) */ /* */ /* (C) Copyright 1999 by Texas Instruments Incorporated, All Rights Reserved*/ /****************************************************************************/ #include "../../include/config.h" #include "../rvm/rvm_use_id_list.h" #include "rvf_api.h" #include "rvf_i.h" #include "../support/exception.h" #include "rvf_pool_size.h" #include "../../nucleus/nucleus.h" #include <string.h> #include <stdio.h> #if RVF_ENABLE_STATS /* conditional inclusion of stdio.h for sprintf() function */ #ifdef _WINDOWS #include <stdio.h> #endif #endif #include "../rv/rv_defined_swe.h" #ifdef RVM_DAR_SWE #include "dar/dar_api.h" #endif #define RVF_INVALID_MD_ID_ERRROR ("RVF: Invalid MB ID") #define INC_END_INITIALIZE 2 #define RVF_INVALID_INDEX 0xFFFF /************* TASK MAILBOXES *******************/ /* chained lists for task mailboxes */ T_RVF_INTERNAL_BUF *OSTaskQFirst[1][1]; //[MAX_RVF_TASKS][RVF_NUM_TASK_MBOX]; T_RVF_INTERNAL_BUF *OSTaskQLast [1][1]; //[MAX_RVF_TASKS][RVF_NUM_TASK_MBOX]; extern INC_Initialize_State; T_RVF_RT_ADDR_ID_DATA* pRtAddrIdTable[MAX_RVF_G_ADDR_ID]; /******** MEMORY POOLS ******************/ /* Define the buffer pools */ extern T_RVF_POOL _rvf_pools[]; /*********** MEMORY BANKS ***********/ /* array of memory bank */ static T_RVF_MB rvf_banks[RVF_MAX_REAL_MB]; /* array of waiting buffers */ static T_RVF_BUFFER * waiting_buffers[RVF_MAX_WAITING_BUF]; static UINT16 next_buffer[RVF_MAX_WAITING_BUF]; static UINT16 first_free_element; /* array of memory bank name and id*/ static T_RVF_MB_NAME_ID rvf_name_id[RVF_MAX_TOTAL_MB] = RVF_MB_MAPPING; /* variable for statistics */ #if RVF_ENABLE_STATS static UINT32 required_size = 0; static UINT32 obtained_size = 0; static UINT32 used_size = 0; static UINT32 mem_in_use = 0; #endif /* lists of free buffers */ static T_RVF_INTERNAL_BUF * lists[RVF_NB_FREE_LISTS]; /* last split-off buffer */ T_RVF_INTERNAL_BUF * last_remainder = NULL; /* allocated static buffer pools */ extern UINT8 Buf0[]; extern UINT8 Buf1[]; /********Internal windows function used to display memory status *******/ #ifdef _WINDOWS extern void AddNewState(void *s,char *name, unsigned long current,unsigned long peak, unsigned long water,unsigned long bank); #endif /******************************************************************************* ** ** Function _rvf_init_free_queue ** ** Description Function called at startup to initialize a free ** pool (statically or dynamically allocated). ** It is called once for each free pool. ** ** Returns void ** *******************************************************************************/ void _rvf_init_free_queue (UINT8 id, UINT32 size, void *p_mem) { T_RVF_INTERNAL_BUF *hdr; UINT8 list_idx; /* round to up size to a multiple of 4 */ size = (size + 3) & ~0x0003; /* store pool start address and size */ _rvf_pools[id].start_address = p_mem; _rvf_pools[id].pool_size = size; /* Initialize the pool as a big free buffer */ hdr = (T_RVF_INTERNAL_BUF *) p_mem; hdr->buf_size = size - sizeof(T_RVF_INTERNAL_BUF) - sizeof(UINT32); /* last 4 bytes of the pool losts*/ hdr->header.p_prev = NULL; RVF_SET_PREV_IN_USE(hdr); NEXTCHUNK(hdr)->buf_size = 0; ENDSIZE(hdr) = hdr->buf_size; /* get the corresponding list and insert the buffer */ list_idx = RVF_BUF_LIST_INDEX( hdr->buf_size); hdr->p_next = lists[list_idx]; lists[list_idx] = hdr; last_remainder = hdr; } void rvf_mbox_buffer_init(T_RVF_RT_ADDR_ID_DATA* pRtAddrIdElement) { UINT8 task_num, mbox_num; /* Initialize all mailboxes queues of all tasks*/ for (task_num = 0; task_num < MAX_RVF_TASKS; task_num++) { for (mbox_num = 0; mbox_num < RVF_NUM_TASK_MBOX; mbox_num++) { pRtAddrIdElement->OSTaskQFirst[mbox_num] = NULL; pRtAddrIdElement->OSTaskQLast[mbox_num] = NULL; } } } /******************************************************************************* ** ** Function _rvf_buffer_init ** ** Description Called once internally by rvf at startup to initialize all ** buffers and free buffer pools. ** ** Returns void ** *******************************************************************************/ void _rvf_buffer_init(void) { UINT8 list_num; UINT16 memory_bank_num; /* Initialize all mailboxes queues of all tasks*/ /* for (task_num = 0; task_num < MAX_RVF_TASKS; task_num++) { for (mbox_num = 0; mbox_num < RVF_NUM_TASK_MBOX; mbox_num++) { OSTaskQFirst[task_num][mbox_num] = NULL; OSTaskQLast [task_num][mbox_num] = NULL; //pRtAddrIdTable[task_num]->OSTaskQFirst[mbox_num] = NULL; // only if static //pRtAddrIdTable[task_num]->OSTaskQLast[mbox_num] = NULL; // only if static } } */ /* initialize free lists */ for (list_num = 0; list_num < RVF_NB_FREE_LISTS; list_num++) { lists[list_num] = NULL; } /* initialize buffer pools */ _rvf_init_mem_pool(); /* Initialize real memory banks */ for (memory_bank_num = 0; memory_bank_num < RVF_MAX_REAL_MB; memory_bank_num++) { rvf_banks[memory_bank_num].cur_memory_used = 0; rvf_banks[memory_bank_num].watermark = 0; rvf_banks[memory_bank_num].max = 0; rvf_banks[memory_bank_num].first_buffer_index = RVF_INVALID_INDEX; rvf_banks[memory_bank_num].last_buffer_index = RVF_INVALID_INDEX; rvf_banks[memory_bank_num].func = 0; rvf_banks[memory_bank_num].returned_red = FALSE; #if RVF_ENABLE_STATS rvf_banks[memory_bank_num].max_reached = 0; rvf_banks[memory_bank_num].required_size = 0; rvf_banks[memory_bank_num].num_buf = 0; #endif } /* Initialize total memory banks */ for (memory_bank_num = 0; memory_bank_num < RVF_MAX_TOTAL_MB; memory_bank_num++) { rvf_name_id[memory_bank_num].mb_params.size = 0; rvf_name_id[memory_bank_num].mb_params.watermark = 0; } /* initialize array of waiting buffers */ first_free_element = 0; for( memory_bank_num = 0; memory_bank_num < RVF_MAX_WAITING_BUF; memory_bank_num++) { waiting_buffers[memory_bank_num] = NULL; next_buffer[memory_bank_num] = memory_bank_num + 1; } next_buffer[RVF_MAX_WAITING_BUF-1] = RVF_INVALID_INDEX; } /******************************************************************************* ** ** Function _rvf_send_msg_to_mbox ** ** Description Called by applications to send a buffer to a SWE. ** (Temporary internal use - DO NOT USE IT !) ** (Presently, only for Christophe ) ** Returns RVF_OK if successful, else an error code. ** *******************************************************************************/ T_RVF_RET _rvf_send_msg_to_mbox (T_RVF_G_ADDR_ID addr_id, UINT8 mbox,void *msg){ return rvf_adapt_send_msg(addr_id, msg, mbox); } /*T_RVF_RET _rvf_send_msg_to_mbox (T_RVF_ADDR_ID addr_id, UINT8 mbox,void *msg) { T_RVF_INTERNAL_BUF *p_hdr; UINT8 task_id = (UINT8)addr_id; if ((task_id >= MAX_RVF_TASKS) ) { rvf_send_trace( "RVF: rvf_send_msg(): invalid taskid", 35, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); rvf_free_buf (msg); return RVF_INVALID_PARAMETER; } #if RVF_ENABLE_BUF_CORRUPTION_CHECK if (_rvf_chk_buf_damage(msg) == TRUE) { rvf_send_trace( "RVF: rvf_send_msg(): buffer corrupted", 37, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); } #endif ((T_RV_HDR *)msg)->dest_addr_id = addr_id; p_hdr = USER2MEM(msg); #if RVF_ENABLE_BUF_LINKAGE_CHECK if ( RVF_BUF_IS_LINKED( p_hdr) ) { rvf_send_trace( "RVF: rvf_send_msg(): buffer already enqueued", 44, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return RVF_MEMORY_ERR; } #endif rvf_disable(8); if (OSTaskQFirst[task_id][mbox]) { OSTaskQLast[task_id][mbox]->p_next = p_hdr; } else { OSTaskQFirst[task_id][mbox] = p_hdr; } OSTaskQLast[task_id][mbox] = p_hdr; p_hdr->p_next = NULL; if (pRtAddrIdTable[task_id]->OSTaskQFirst[mbox]) { pRtAddrIdTable[task_id]->OSTaskQLast[mbox]->p_next = p_hdr; } else { pRtAddrIdTable[task_id]->OSTaskQFirst[mbox] = p_hdr; } pRtAddrIdTable[task_id]->OSTaskQLast[mbox] = p_hdr; p_hdr->p_next = NULL; #if RVF_ENABLE_BUF_LINKAGE_CHECK RVF_SET_BUF_LINKED(p_hdr); #endif rvf_enable(); rvf_send_event(task_id, (UINT16) (EVENT_MASK(mbox)) ); return RVF_OK; }*/ /******************************************************************************* ** ** Function rvf_read_mbox ** ** Description Called by applications to read a buffer from one of ** the task mailboxes. ** ** Returns NULL if the mailbox was empty, else the address of a buffer ** *******************************************************************************/ void * rvf_read_mbox (UINT8 mbox) { T_RVF_G_ADDR_ID task_id = rvf_get_taskid(); return rvf_read_addr_mbox (task_id, mbox) ; } void * rvf_read_addr_mbox (T_RVF_G_ADDR_ID task_id, UINT8 mbox) { void * p_buf = NULL; T_RVF_INTERNAL_BUF * p_hdr; mbox=resolveHostAddrId(mbox); if ((task_id >= MAX_RVF_TASKS) || (mbox >= RVF_NUM_TASK_MBOX)) { rvf_send_trace( "RVF: rvf_read_mbox(): invalid taskid or mbox", 44, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return NULL; } rvf_disable(9); /* enter critical section */ /* if the chained list is not empty */ /*if ( OSTaskQFirst[task_id][mbox] ) { p_hdr = OSTaskQFirst[task_id][mbox]; OSTaskQFirst[task_id][mbox] = p_hdr->p_next; p_hdr->p_next = NULL;*/ if ( pRtAddrIdTable[task_id]->OSTaskQFirst[mbox] ) { p_hdr = pRtAddrIdTable[task_id]->OSTaskQFirst[mbox]; pRtAddrIdTable[task_id]->OSTaskQFirst[mbox] = p_hdr->p_next; p_hdr->p_next = NULL; #if RVF_ENABLE_BUF_LINKAGE_CHECK RVF_SET_BUF_UNLINKED(p_hdr); /* change buffer status */ #endif p_buf = (UINT8 *)p_hdr + sizeof(T_RVF_INTERNAL_BUF); } rvf_enable(); /* exit critical section */ return (p_buf); } /******************************************************************************* ** ** Function rvf_enqueue ** ** Description Enqueue a buffer at the tail of the queue ** ** Returns RVF_OK if successful, else an error code. ** *******************************************************************************/ T_RVF_RET rvf_enqueue (T_RVF_BUFFER_Q *p_q, void *p_buf) { T_RVF_INTERNAL_BUF *p_hdr; #if RVF_ENABLE_BUF_CORRUPTION_CHECK if ( _rvf_chk_buf_damage(p_buf) ) { rvf_send_trace( "RVF: rvf_enqueue(): buffer corrupted", 36, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID); } #endif /* check if the buffer has been already enqueued */ p_hdr = USER2MEM(p_buf); #if RVF_ENABLE_BUF_LINKAGE_CHECK if( RVF_BUF_IS_LINKED(p_hdr) ) { rvf_send_trace( "RVF: rvf_enqueue(): buffer already enqueued", 43, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID); return RVF_MEMORY_ERR; } #endif rvf_disable(10); /* enter critical section */ /* Since the queue is exposed (C vs C++), keep the pointers in exposed format */ /* p_q->p_last and p_q->p_first point to the user buffer, since p_hdr->p_next points to the T_RVF_INTERNAL_BUF */ if (p_q->p_first) /* if the queue is not empty */ { T_RVF_INTERNAL_BUF * p_last_hdr = (T_RVF_INTERNAL_BUF *) ((UINT8 *)p_q->p_last - sizeof(T_RVF_INTERNAL_BUF) ); p_last_hdr->p_next = p_hdr; } else p_q->p_first = p_buf; p_q->p_last = p_buf; p_q->count++; p_hdr->p_next = NULL; #if RVF_ENABLE_BUF_LINKAGE_CHECK RVF_SET_BUF_LINKED(p_hdr); /* change buffer status */ #endif rvf_enable(); /* exit critical section */ return RVF_OK; } /******************************************************************************* ** ** Function rvf_dequeue ** ** Description Dequeue a buffer from the head of a queue ** ** Returns NULL if queue is empty, else buffer ** *******************************************************************************/ void * rvf_dequeue (T_RVF_BUFFER_Q *p_q) { T_RVF_INTERNAL_BUF *p_hdr; if (!p_q->count) /* if the queue is empty */ return (NULL); rvf_disable(12); /* enter critical section */ p_hdr = USER2MEM(p_q->p_first ); /* Keep buffers such that RVF header is invisible */ if (p_hdr->p_next) p_q->p_first = ((UINT8 *)p_hdr->p_next + sizeof(T_RVF_INTERNAL_BUF)); else { p_q->p_first = NULL; p_q->p_last = NULL; } p_q->count--; p_hdr->p_next = NULL; #if RVF_ENABLE_BUF_LINKAGE_CHECK RVF_SET_BUF_UNLINKED(p_hdr); /* change buffer status */ #endif rvf_enable(); /* exit critical section */ return (MEM2USER(p_hdr) ); } /******************************************************************************* ** ** Function rvf_enqueue_head ** ** Description Enqueue a buffer at the head of the queue ** ** Returns RVF_OK if successful, else an error code. ** *******************************************************************************/ T_RVF_RET rvf_enqueue_head (T_RVF_BUFFER_Q *p_q, void *p_buf) { T_RVF_INTERNAL_BUF *p_hdr; #if RVF_ENABLE_BUF_CORRUPTION_CHECK if ( _rvf_chk_buf_damage(p_buf) ) { rvf_send_trace( "RVF: rvf_enqueue_head(): buffer corrupted", 41, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); } #endif p_hdr = USER2MEM(p_buf); #if RVF_ENABLE_BUF_LINKAGE_CHECK if( RVF_BUF_IS_LINKED(p_hdr) ) { rvf_send_trace( "RVF: rvf_enqueue_head(): buffer already enqueued", 48, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return RVF_MEMORY_ERR; } #endif rvf_disable(11); /* enter critical section */ if (p_q->p_first) /* if the queue is not empty */ { p_hdr->p_next = (T_RVF_INTERNAL_BUF *)((UINT8 *)p_q->p_first - sizeof(T_RVF_INTERNAL_BUF) ); p_q->p_first = p_buf; } else { p_q->p_first = p_buf; p_q->p_last = p_buf; p_hdr->p_next = NULL; } p_q->count++; #if RVF_ENABLE_BUF_LINKAGE_CHECK RVF_SET_BUF_LINKED(p_hdr); /* change buffer status */ #endif rvf_enable(); /* exit critical section */ return RVF_OK; } /******************************************************************************* ** ** Function rvf_get_buf_size ** ** Description Called by an application to get the size of a buffer. ** ** Returns the size of the buffer or 0 if the address is invalid. ** *******************************************************************************/ INLINE UINT32 rvf_get_buf_size (void *bptr) { T_RVF_INTERNAL_BUF *p_hdr; p_hdr = (T_RVF_INTERNAL_BUF *)((UINT8 *) bptr - sizeof(T_RVF_INTERNAL_BUF) ); if ((UINT32)p_hdr & 1) return 0; /* invalid pointer: odd address*/ return (GETSIZE(p_hdr) - RVF_CORRUPT_OVERHEAD) ; } /******************************************************************************* ** ** Function _rvf_chk_buf_damage ** ** Description Called internally by rvf to check for buffer corruption. ** ** Returns TRUE if there is a problem, else FALSE ** *******************************************************************************/ #if RVF_ENABLE_BUF_CORRUPTION_CHECK BOOLEAN _rvf_chk_buf_damage(void *bptr) { UINT32 *lg; T_RVF_INTERNAL_BUF * p_hdr; if((UINT32)bptr & 1) /* odd address */ { return TRUE; } p_hdr = USER2MEM(bptr); /* get the internal header */ lg = (UINT32*)( (UINT8*)bptr + GETSIZE(p_hdr) - sizeof(UINT32) ); if (lg == 0) return TRUE; if(*lg == GETSIZE(p_hdr) ) { return FALSE; } return TRUE; } #endif /******************************************************************************* ** ** Function _find_buf ** ** Description Internal function which is in charge of finding a free buffer ** of the requested size in one of the lists. ** ** Returns A pointer to the buffer header, or NULL if none available ** *******************************************************************************/ INLINE void * _find_buf (UINT32 size) { T_RVF_INTERNAL_BUF * p_hdr; UINT8 idx; if (size == 0) /* if user requires a 0 byte buffer !! */ { return (NULL); } /* add the overhead for buffer corruption check */ size = REQ2SIZE(size); /* find the corresponding list */ idx = RVF_BUF_LIST_INDEX(size); /* 1. try in the bin corresponding to the requested size. */ /* 2. try to use the last_remainder chunk. */ /* 3. try in the others bins of greater size. */ if( (lists[idx] == NULL) || ( GETSIZE(lists[idx]) < size) ) /* if the first buffer in the appropriate bin is not big enough. */ { rvf_disable(4); /* enter critical section */ if( last_remainder != NULL) { p_hdr = last_remainder; /* if the last remainder is big enough */ if( GETSIZE(p_hdr) >= size ) { if( GETSIZE(p_hdr) >= (size + RVF_MIN_USABLE_SIZE ) ) /* if the free part may be used */ { /* create a new free buffer and link it in the appropriate list*/ T_RVF_INTERNAL_BUF * new_buf; UINT8 new_idx; new_buf = (T_RVF_INTERNAL_BUF *) ((UINT8*)p_hdr + size + sizeof(T_RVF_INTERNAL_BUF)); new_buf->buf_size = GETSIZE(p_hdr) - size - sizeof(T_RVF_INTERNAL_BUF); ENDSIZE(new_buf) = new_buf->buf_size; /* remove the used buffer from the list */ if( p_hdr->header.p_prev != NULL) { (p_hdr->header.p_prev)->p_next = p_hdr->p_next; } else { lists[ RVF_BUF_LIST_INDEX( GETSIZE(p_hdr) )] = p_hdr->p_next; } if( p_hdr->p_next != NULL) { (p_hdr->p_next)->header.p_prev = p_hdr->header.p_prev; } p_hdr->p_next = NULL; SETSIZE(p_hdr, size); ENDSIZE(p_hdr) = size; /* to CHANGE */ /* insert the new buffer in the appropriate list */ new_idx = RVF_BUF_LIST_INDEX(new_buf->buf_size); new_buf->p_next = lists[new_idx]; lists[new_idx] = new_buf; new_buf->header.p_prev = NULL; if( new_buf->p_next != NULL) { (new_buf->p_next)->header.p_prev = new_buf; } RVF_SET_PREV_IN_USE(new_buf); last_remainder = new_buf; rvf_enable(); /* exit critical section */ return p_hdr; } else /* return the entire buffer */ { /* remove the used buffer from the list */ if( p_hdr->header.p_prev != NULL) { (p_hdr->header.p_prev)->p_next = p_hdr->p_next; } else { lists[ RVF_BUF_LIST_INDEX( GETSIZE(p_hdr) )] = p_hdr->p_next; } if( p_hdr->p_next != NULL) { (p_hdr->p_next)->header.p_prev = p_hdr->header.p_prev; } p_hdr->p_next = NULL; RVF_SET_PREV_IN_USE( NEXTCHUNK(p_hdr) ); last_remainder = NULL; rvf_enable(); /* exit critical section */ return p_hdr; } } else /* the last remainder is too small */ { /* clear the last remainder */ last_remainder = NULL; } } rvf_enable(); /* exit critical section */ } while( idx < RVF_NB_FREE_LISTS ) { rvf_disable(4); /* enter critical section */ if( lists[idx] != NULL ) /*if the list is not empty */ { /* remove the first buffer from the list */ p_hdr = lists[idx]; if( GETSIZE(p_hdr) >= size) { if( GETSIZE(p_hdr) >= (size + RVF_MIN_USABLE_SIZE ) ) /* if the free part may be used */ { /* create a new free buffer and link it in the appropriate list*/ T_RVF_INTERNAL_BUF * new_buf; UINT8 new_idx; new_buf = (T_RVF_INTERNAL_BUF *) ((UINT8*)p_hdr + size + sizeof(T_RVF_INTERNAL_BUF)); new_buf->buf_size = GETSIZE( p_hdr) - size - sizeof(T_RVF_INTERNAL_BUF); ENDSIZE(new_buf) = new_buf->buf_size; /* remove the used buffer from the list */ lists[idx] = p_hdr->p_next; if( p_hdr->p_next != NULL) { (p_hdr->p_next)->header.p_prev = NULL; } p_hdr->p_next = NULL; SETSIZE(p_hdr, size); ENDSIZE(p_hdr) = size; /* insert the new buffer in the appropriate list */ new_idx = RVF_BUF_LIST_INDEX(new_buf->buf_size); new_buf->p_next = lists[new_idx]; lists[new_idx] = new_buf; new_buf->header.p_prev = NULL; if( new_buf->p_next != NULL) { (new_buf->p_next)->header.p_prev = new_buf; } RVF_SET_PREV_IN_USE(new_buf); last_remainder = new_buf; /* set this new buffer as the last remainder */ rvf_enable(); /* exit critical section */ return p_hdr; } else /* return the entire buffer */ { lists[idx] = p_hdr->p_next; if( p_hdr->p_next != NULL) { (p_hdr->p_next)->header.p_prev = NULL; } p_hdr->p_next = NULL; RVF_SET_PREV_IN_USE( NEXTCHUNK(p_hdr) ); if( last_remainder == p_hdr) /* if it was the last_remainder, clear it. */ { last_remainder = NULL; } rvf_enable(); /* exit critical section */ return p_hdr; } } } rvf_enable(); /* exit critical section */ idx++; /* search in the next list */ } return NULL; } /******************************************************************************* ** ** Function _release_buf ** ** Description Internal function called to release a buffer after use. ** The parameter points to the beginning of the header. ** ** Returns BOOLEAN: TRUE if successful, else FALSE ** *******************************************************************************/ INLINE BOOLEAN _release_buf (T_RVF_INTERNAL_BUF *p_hdr) { UINT8 idx; #if RVF_ENABLE_BUF_CORRUPTION_CHECK /* check for buffer corruption:i.e. if user wrote data after the end of the buffer */ if ( _rvf_chk_buf_damage( MEM2USER(p_hdr) ) ) { rvf_send_trace( "RVF: _release_buf(): buffer corrupted", 37, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return FALSE; } /* check if the buffer has been already freed */ if ( RVF_IS_PREV_FREE( NEXTCHUNK(p_hdr) ) ) /* check buffer status */ { rvf_send_trace( "RVF: _release_buf(): buffer already freed", 41, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return FALSE; } #endif #if RVF_ENABLE_BUF_LINKAGE_CHECK /* check for buffer linkage */ if ( RVF_BUF_IS_LINKED(p_hdr) ) /* check buffer status */ { rvf_send_trace( "RVF: _release_buf(): free buf buffer linked", 43, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return FALSE; } #endif rvf_disable(6); /* enter critical section */ /* try to coalesce the buffer with its neighbors (left and right) */ if( RVF_IS_PREV_FREE(p_hdr) ) { /* merge the buffer with its left neighbor */ UINT32 left_buf_size = *((UINT32*)((UINT8*)p_hdr - sizeof(UINT32) ) ); T_RVF_INTERNAL_BUF * left_buf = (T_RVF_INTERNAL_BUF *) ((UINT8 *)p_hdr - left_buf_size - sizeof(T_RVF_INTERNAL_BUF) ); /* remove the left buffer from its list */ if( left_buf->header.p_prev == NULL) { lists[ RVF_BUF_LIST_INDEX(left_buf_size)] = left_buf->p_next; } else { (left_buf->header.p_prev)->p_next = left_buf->p_next; } if( left_buf->p_next != NULL) { (left_buf->p_next)->header.p_prev = left_buf->header.p_prev; } /* set the size of the newly created buffer */ SETSIZE(left_buf, (left_buf_size + GETSIZE(p_hdr) + sizeof(T_RVF_INTERNAL_BUF) ) ); /* set the current buffer as free to allow check for double free */ RVF_SET_PREV_FREE( NEXTCHUNK(p_hdr) ); p_hdr = left_buf; } /* check for pool limits */ if( GETSIZE( NEXTCHUNK(p_hdr) ) != 0) { T_RVF_INTERNAL_BUF * right_buf = NEXTCHUNK(p_hdr); /* merge the buffer with its right neighbor */ if( RVF_IS_PREV_FREE( NEXTCHUNK(right_buf) ) ) { /* remove the right buffer from its list */ UINT32 right_buf_size = GETSIZE( right_buf); if( right_buf->header.p_prev == NULL) { lists[ RVF_BUF_LIST_INDEX(right_buf_size)] = right_buf->p_next; } else { (right_buf->header.p_prev)->p_next = right_buf->p_next; } if( right_buf->p_next != NULL) { (right_buf->p_next)->header.p_prev = right_buf->header.p_prev; } right_buf_size += GETSIZE(p_hdr); SETSIZE(p_hdr, (right_buf_size + sizeof(T_RVF_INTERNAL_BUF) ) ); if( last_remainder == right_buf) /* keep as last_remainder */ { last_remainder = p_hdr; } } } /* enqueue the free buffer in the appropriate list */ idx = RVF_BUF_LIST_INDEX( GETSIZE(p_hdr) ); p_hdr->header.p_prev = NULL; p_hdr->p_next = lists[idx]; lists[idx] = p_hdr; if( p_hdr->p_next != NULL) { (p_hdr->p_next)->header.p_prev = p_hdr; } ENDSIZE(p_hdr) = GETSIZE(p_hdr); RVF_SET_PREV_FREE( NEXTCHUNK(p_hdr) ); rvf_enable(); /* exit critical section */ return TRUE; } /******************************************************************************* ** Function _str_cmp ** ** Description Internal function which compares two null-terminated string. ** Returns TRUE if they are equal, else FALSE. *******************************************************************************/ BOOLEAN _str_cmp( char *str1, char * str2) { UINT8 i; for ( i = 0; (str1[i] == str2[i]) && (str1[i] != 0) && (str2[i] != 0) && (i < RVF_MAX_MB_LEN); i++ ); if ( i == RVF_MAX_MB_LEN) { return TRUE; } if ( (str1[i] == 0) && (str2[i] == 0) ) { return TRUE; } return FALSE; } /****************************************************************************** ** ** MEMORY BANK RELATED FUNCTIONS ** ******************************************************************************/ /******************************************************************************* ** ** Function _remove_from_list ** ** Description Internal function called to remove a buffer from the list of ** buffer waiting to be counted on the memory bank. ** The parameter points to the beginning of the header. ** ** Returns BOOLEAN: TRUE if successful, else FALSE ** *******************************************************************************/ BOOLEAN _remove_from_list (void *bptr, T_RVF_MB * mb) { UINT16 * index; UINT16 free_elem, prec; /* check all elements of the list */ index = &(mb->first_buffer_index); prec = RVF_INVALID_INDEX; while ( (*index != RVF_INVALID_INDEX) && (waiting_buffers[*index]!=bptr) ) { prec = *index; index = &(next_buffer[*index]); } if (waiting_buffers[*index] == bptr) { free_elem = *index; *index = next_buffer[free_elem]; /* link preceding element to the next one */ if (next_buffer[free_elem] == RVF_INVALID_INDEX ) /* last element in the list */ { mb->last_buffer_index = prec; } waiting_buffers[free_elem] = NULL; next_buffer[free_elem] = first_free_element; /* link free elements */ first_free_element = free_elem; return TRUE; } return FALSE; /* buffer not found */ } /******************************************************************************* ** ** Function _add_to_list ** ** Description Internal function called to add a buffer to the list of ** buffer waiting to be counted on the memory bank. ** The parameter points to the beginning of the header. ** ** Returns BOOLEAN: TRUE if successful, else FALSE ** *******************************************************************************/ BOOLEAN _add_to_list (void *bptr, T_RVF_MB * mb) { UINT16 index = first_free_element; first_free_element = next_buffer[index]; waiting_buffers[index] = bptr; next_buffer[index] = RVF_INVALID_INDEX; if ( mb->last_buffer_index == RVF_INVALID_INDEX) /* empty list */ { mb->first_buffer_index = index; mb->last_buffer_index = index; } else { next_buffer[mb->last_buffer_index] = index; mb->last_buffer_index = index; } return TRUE; } /******************************************************************************* ** ** Function rvf_create_mb ** ** Description Called by an application to create a memory bank ** ** Parameters: memory bank name, memory bank param ** (return) memory bank id ** ** Returns T_RVF_RET: RVF_OK if success ** *******************************************************************************/ T_RVF_RET rvf_create_mb(T_RVF_MB_NAME mb_name, T_RVF_MB_PARAM mb_param, T_RVF_MB_ID *mb_id) { UINT8 num_mb; T_RVF_MB * mb; UINT32 available_mem = 0; UINT32 required_mem = 0; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) /* mb name not found */ { /* DLC added for dynamic memory bank creation*/ /* search the first available place in the array */ T_RVF_MB_ID first_available_mb_id = 0; BOOLEAN mb_id_found = FALSE; for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (rvf_name_id[num_mb].mb_name[0] != 0) ; num_mb++) { if( rvf_name_id[num_mb].mb_id == first_available_mb_id) { first_available_mb_id ++; } } while( (first_available_mb_id < RVF_MAX_REAL_MB) && (mb_id_found == FALSE) ) { for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (rvf_name_id[num_mb].mb_name[0] != 0) && (rvf_name_id[num_mb].mb_id != first_available_mb_id) ; num_mb++); if ( rvf_name_id[num_mb].mb_id != first_available_mb_id) { /* available mb id found */ mb_id_found = TRUE; } else { /* try the next one */ first_available_mb_id++; } } if ( (num_mb == RVF_MAX_TOTAL_MB) || (first_available_mb_id + 1 >= RVF_MAX_REAL_MB ) ) /* no available space in the array */ { *mb_id = RVF_INVALID_MB_ID; return RVF_INVALID_PARAMETER; } if(INC_Initialize_State==INC_END_INITIALIZE) rvf_disable(20); /* enter critical section */ /* create the new mb name and id */ strcpy( rvf_name_id[num_mb].mb_name, mb_name); rvf_name_id[num_mb].mb_id = first_available_mb_id; /* initialize the next one */ rvf_name_id[num_mb+1].mb_name[0] = 0; rvf_name_id[num_mb+1].mb_id = 0; if(INC_Initialize_State==INC_END_INITIALIZE) rvf_enable(); /* exit critical section */ } /* check if the memory bank has been already created */ if ( rvf_name_id[ num_mb].mb_params.size != 0) { *mb_id = RVF_INVALID_MB_ID; return RVF_INTERNAL_ERR; } rvf_get_available_mem( &available_mem, &required_mem); if ( ( (required_mem + mb_param.size)*100) > ( available_mem * _rvf_get_mem_usage_ratio()) ) /* if there is not enough available memory to create this mb */ { *mb_id = RVF_INVALID_MB_ID; /* In a next version: try to create a dynamic pool */ return RVF_MEMORY_ERR; } rvf_disable(20); /* enter critical section */ /* save the mb parameters for deletion */ rvf_name_id[num_mb].mb_params.size = mb_param.size; rvf_name_id[num_mb].mb_params.watermark = mb_param.watermark; * mb_id = rvf_name_id[num_mb].mb_id; mb = &rvf_banks[ *mb_id ]; /* initialize the memory bank structure */ mb->watermark += mb_param.watermark; mb->max += mb_param.size; rvf_enable(); /* exit critical section */ return RVF_OK; } /******************************************************************************* ** ** Function rvf_get_mb_id ** ** Description Called by an application to get the memory bank id from its name ** ** Parameters: memory bank name ** (return) memory bank id ** ** Returns T_RVF_RET: RVF_OK if success ** *******************************************************************************/ T_RVF_RET rvf_get_mb_id(T_RVF_MB_NAME mb_name, T_RVF_MB_ID *mb_id) { UINT8 num_mb; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) /* mb name not found */ { *mb_id = RVF_INVALID_MB_ID; return RVF_INVALID_PARAMETER; } if ( rvf_banks[ rvf_name_id[num_mb].mb_id ].max == 0 ) { /* the memory bank has not been created */ *mb_id = RVF_INVALID_MB_ID; return RVF_NOT_READY; } *mb_id = rvf_name_id[num_mb].mb_id; return RVF_OK; } /******************************************************************************* ** ** Function rvf_delete_mb ** ** Description Called by an application to delete a memory bank ** ** Parameters: memory bank name ** ** Returns T_RVF_RET: RVF_OK if success ** *******************************************************************************/ T_RVF_RET rvf_delete_mb(T_RVF_MB_NAME mb_name) { UINT8 num_mb; T_RVF_MB * mb; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) /* mb name not found */ { return RVF_INVALID_PARAMETER; } mb = &rvf_banks[ rvf_name_id[num_mb].mb_id ]; /* check if the mb is used more than once or not */ if ( mb->max == rvf_name_id[num_mb].mb_params.size ) { /* mb is used only once, check if cur_memory_used > 0 */ if ( mb->cur_memory_used > 0) { rvf_send_trace( "RVF: rvf_delete_mb(): not all buffers have been freed", 53, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return RVF_MEMORY_ERR; /* free all buffers ????? -> NOT POSSIBLE */ } /* initialize mb params */ mb->max = 0; mb->first_buffer_index = RVF_INVALID_INDEX; mb->last_buffer_index = RVF_INVALID_INDEX; mb->watermark = 0; mb->returned_red = FALSE; mb->func = 0; #if RVF_ENABLE_STATS mb->max_reached = 0; mb->required_size = 0; mb->num_buf = 0; #endif } else /* mb is still used by another entity */ { /* change mb params */ mb->max -= rvf_name_id[num_mb].mb_params.size; mb->watermark -= rvf_name_id[num_mb].mb_params.watermark; } rvf_name_id[num_mb].mb_params.size = 0; rvf_name_id[num_mb].mb_params.watermark = 0; return RVF_OK; } T_RVF_RET rvf_mb_is_used(T_RVF_MB_NAME mb_name, UINT8* isUsed) { UINT8 num_mb; T_RVF_MB * mb; *isUsed=0; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) {/* mb name not found */ return RVF_INVALID_PARAMETER; } mb = &rvf_banks[ rvf_name_id[num_mb].mb_id ]; /* check if the mb is used more than once or not */ if ( mb->max == rvf_name_id[num_mb].mb_params.size ) { /* mb is used only once, check if cur_memory_used > 0 */ if ( mb->cur_memory_used > 0) *isUsed=1; } return RVF_OK; } /******************************************************************************* ** ** Function rvf_get_mb_status ** ** Description Called by an application to get the status of a memory bank ** ** Parameters: memory bank id ** ** Returns T_RVF_MB_STATUS: RVF_GREEN if everything is ok, ** RVF_YELLOW if watermark limit has been reached, ** RVF_RED if max size has been reached ** *******************************************************************************/ T_RVF_MB_STATUS rvf_get_mb_status(T_RVF_MB_ID mb_id) { T_RVF_MB * mb; /* checking for invalid memory bank IDs */ if (mb_id >= RVF_MAX_REAL_MB) { #ifdef RVM_DAR_SWE dar_diagnose_generate_emergency (RVF_INVALID_MD_ID_ERRROR, DAR_ASCII_FORMAT, RVM_USE_ID); #else rvf_send_trace (RVF_INVALID_MD_ID_ERRROR, sizeof (RVF_INVALID_MD_ID_ERRROR) - 1, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID); #endif return RVF_RED; } mb = &rvf_banks[mb_id]; if ( mb->returned_red == TRUE) /* if a previous count buf or get buf has failed */ { return RVF_RED; } if ( mb->cur_memory_used < mb->watermark ) { return RVF_GREEN; } else { if ( mb->cur_memory_used < mb->max ) { return RVF_YELLOW; } else { return RVF_RED; /* since max and cur_memory_used are set to 0 for not-created mb, it will return RED*/ } } } /******************************************************************************* ** ** Function rvf_get_mb_unused_mem ** ** Description Called by an application to get the number of bytes available ** until the memory bank size. ** ** Parameters: memory bank id ** ** Returns UINT32: number of bytes available ** returns 0 if the memory bank has not been created. ** *******************************************************************************/ UINT32 rvf_get_mb_unused_mem(T_RVF_MB_ID mb_id) { T_RVF_MB * mb; mb = &rvf_banks[mb_id]; if ( mb->returned_red == TRUE) /* if a previous count buf or get buf has failed */ { return 0; } return( mb->max - mb->cur_memory_used); } /******************************************************************************* ** ** Function rvf_get_mb_unused_green_mem ** ** Description Called by an application to get the number of bytes available ** until the memory bank watermark. ** ** Parameters: memory bank id ** ** Returns UINT32: number of bytes available ** returns 0 if the memory bank has not been created. ** *******************************************************************************/ UINT32 rvf_get_mb_unused_green_mem(T_RVF_MB_ID mb_id) { T_RVF_MB * mb; mb = &rvf_banks[mb_id]; if ( mb->returned_red == TRUE) /* if a previous count buf or get buf has failed */ { return 0; } if( mb->cur_memory_used > mb->watermark) { return 0; } return( mb->watermark - mb->cur_memory_used); } /******************************************************************************* ** ** Function rvf_get_buf ** ** Description Called by an application to get a buffer from a memory bank ** ** Parameters: memory bank id, buffer size ** (return) buffer pointer to the allocated buffer or null if ** mb status is RVF_RED ** ** Returns T_RVF_MB_STATUS: RVF_GREEN if everything is ok, ** RVF_YELLOW if watermark limit has been reached, ** RVF_RED if max size has been reached (does not return a buffer) ** *******************************************************************************/ T_RVF_MB_STATUS rvf_get_buf(T_RVF_MB_ID mb_id, UINT32 buffer_size, T_RVF_BUFFER** p_buffer) { T_RVF_MB * mb; /* checking for invalid memory bank IDs */ if (mb_id >= RVF_MAX_REAL_MB) { #ifdef RVM_DAR_SWE dar_diagnose_generate_emergency (RVF_INVALID_MD_ID_ERRROR, DAR_ASCII_FORMAT, RVM_USE_ID); #else rvf_send_trace (RVF_INVALID_MD_ID_ERRROR, sizeof (RVF_INVALID_MD_ID_ERRROR) - 1, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID); #endif return RVF_RED; } mb = &rvf_banks[ mb_id ]; /* check memory usage */ if ( ( mb->cur_memory_used + buffer_size) > mb->max ) { /* over the limits, return RED and do not allocate a buffer */ mb->returned_red = TRUE; *p_buffer = NULL; return RVF_RED; } /* find a buffer of the requested size */ *p_buffer = _find_buf( buffer_size ); if ( *p_buffer == NULL ) /* error during allocation, not enough memory */ { //rvf_send_trace( "RVF: rvf_get_buf(): not enough available physical memory", 56, NULL_PARAM, RV_TRACE_LEVEL_ERROR, TRACE_RVF_BUFFER ); mb->returned_red = TRUE; return RVF_RED; } #if RVF_ENABLE_STATS required_size += buffer_size; obtained_size += rvf_get_buf_size((UINT8*)(*p_buffer) + sizeof(T_RVF_INTERNAL_BUF)); used_size += rvf_get_buf_size((UINT8*)(*p_buffer) + sizeof(T_RVF_INTERNAL_BUF)) + sizeof(T_RVF_INTERNAL_BUF) + RVF_CORRUPT_OVERHEAD; mem_in_use += rvf_get_buf_size((UINT8*)(*p_buffer) + sizeof(T_RVF_INTERNAL_BUF)) + sizeof(T_RVF_INTERNAL_BUF) + RVF_CORRUPT_OVERHEAD; #endif if(INC_Initialize_State==INC_END_INITIALIZE) rvf_disable(20); /* enter critical section */ #if RVF_ENABLE_BUF_LINKAGE_CHECK /* set as unlinked */ RVF_SET_BUF_UNLINKED((T_RVF_INTERNAL_BUF*)(*p_buffer)); #endif /* increase memory use counter */ mb->cur_memory_used += rvf_get_buf_size( (UINT8*)(*p_buffer) + sizeof(T_RVF_INTERNAL_BUF) ); ( (T_RVF_INTERNAL_BUF *) (*p_buffer))->header.external.mb_id = mb_id; ( (T_RVF_INTERNAL_BUF *) (*p_buffer))->header.external.mb_expected = RVF_INVALID_MB_ID; *p_buffer = (UINT8*)(*p_buffer) + sizeof(T_RVF_INTERNAL_BUF); #if RVF_ENABLE_STATS if ( mb->cur_memory_used > mb->max_reached ) { mb->max_reached = mb->cur_memory_used; } mb->required_size += buffer_size; mb->num_buf++; #endif if(INC_Initialize_State==INC_END_INITIALIZE) rvf_enable(); /* exit critical section */ /* return the correct flag */ if ( mb->cur_memory_used > mb->watermark ) { return RVF_YELLOW; } else { return RVF_GREEN; } } /******************************************************************************* ** ** Function rvf_count_buf ** ** Description Called by an application to change the memory bank on which a buffer is counted ** ** Parameters: new memory bank id, ** pointer to the buffer. ** ** Returns T_RVF_MB_STATUS: RVF_GREEN if everything is ok, ** RVF_YELLOW if watermark limit has been reached, ** RVF_RED if max size has been reached ** *******************************************************************************/ T_RVF_MB_STATUS rvf_count_buf(T_RVF_MB_ID mb_id, T_RVF_BUFFER * p_buffer) { T_RVF_INTERNAL_BUF * buf; UINT32 buf_size; T_RVF_MB * new_mb; T_RVF_MB * old_mb; /* checking for invalid memory bank IDs */ if (mb_id >= RVF_MAX_REAL_MB) { #ifdef RVM_DAR_SWE dar_diagnose_generate_emergency (RVF_INVALID_MD_ID_ERRROR, DAR_ASCII_FORMAT, RVM_USE_ID); #else rvf_send_trace (RVF_INVALID_MD_ID_ERRROR, sizeof (RVF_INVALID_MD_ID_ERRROR) - 1, NULL_PARAM, RV_TRACE_LEVEL_ERROR, RVM_USE_ID); #endif return RVF_RED; } buf = (T_RVF_INTERNAL_BUF *) ( (UINT8 *) p_buffer - sizeof(T_RVF_INTERNAL_BUF) ); new_mb = &rvf_banks[mb_id]; old_mb = &rvf_banks[buf->header.external.mb_id]; /* get the size of the buffer and try to count it on the new mb */ buf_size = rvf_get_buf_size( p_buffer ); if ( ( new_mb->cur_memory_used + buf_size ) < new_mb->max ) { /* there is enough memory in the new mb */ if ( buf->header.external.mb_expected != RVF_INVALID_MB_ID ) { /* remove the buffer from the list of waiting buffers in mb expected */ _remove_from_list( buf, &rvf_banks[buf->header.external.mb_expected] ); buf->header.external.mb_expected = RVF_INVALID_MB_ID; } rvf_disable(20); /* enter critical section */ /* decrease the memory used in the old mb */ old_mb->cur_memory_used -= buf_size; /* increase memory used in the new mb */ new_mb->cur_memory_used += buf_size; rvf_enable(); /* exit critical section */ /* call the callback function if state of the old mb switches to RVF_GREEN and there is no buffer waiting */ if ( (old_mb->cur_memory_used < old_mb->watermark) && (old_mb->first_buffer_index == RVF_INVALID_INDEX) && (old_mb->returned_red == TRUE) && ( old_mb->func != NULL) ) { old_mb->returned_red = FALSE; old_mb->func( buf->header.external.mb_id); } else { /* count as many waiting buffers as possible on the old mb */ while( (old_mb->first_buffer_index != RVF_INVALID_INDEX) && (rvf_count_buf( buf->header.external.mb_id, (UINT8 *) (waiting_buffers[old_mb->first_buffer_index]) + sizeof(T_RVF_INTERNAL_BUF)) != RVF_RED) ); if ( (old_mb->cur_memory_used < old_mb->watermark) && (old_mb->first_buffer_index == RVF_INVALID_INDEX) && (old_mb->returned_red == TRUE) && ( old_mb->func != NULL) ) { old_mb->returned_red = FALSE; old_mb->func( buf->header.external.mb_id); } } /* change mb_id of the buffer */ buf->header.external.mb_id = mb_id; #if RVF_ENABLE_STATS if ( new_mb->cur_memory_used > new_mb->max_reached ) { new_mb->max_reached = new_mb->cur_memory_used; } #endif if ( new_mb->cur_memory_used > new_mb->watermark ) { return RVF_YELLOW; } else { return RVF_GREEN; } } else { /* there is not enough memory in the new mb_id */ if ( buf->header.external.mb_expected != RVF_INVALID_MB_ID) /* remove the buffer from old expected mb */ { _remove_from_list( buf, &rvf_banks[ buf->header.external.mb_expected] ); } /* enqueue the buffer in the list of waiting buffer */ buf->header.external.mb_expected = mb_id; _add_to_list( buf, new_mb ); new_mb->returned_red = TRUE; return RVF_RED; } } /******************************************************************************* ** ** Function rvf_free_buf ** ** Description Called by an application to free a buffer ** ** Parameters: buffer pointer ** ** Returns T_RVF_RET: T_RVF_OK if succesful, ** *******************************************************************************/ T_RVF_RET rvf_free_buf( T_RVF_BUFFER * p_buffer) { T_RVF_INTERNAL_BUF * buf; T_RVF_MB * mb; T_RVF_MB_ID mb_id; UINT32 buf_size; buf = USER2MEM(p_buffer); mb_id = buf->header.external.mb_id; mb = &rvf_banks[mb_id]; buf_size = rvf_get_buf_size(p_buffer); /* do not need to change the mb id of the buffer, since it will be overwritten by p_prev */ /* free the buffer */ if ( !_release_buf(buf) ) { return RVF_MEMORY_ERR; } #if RVF_ENABLE_STATS mem_in_use -= buf_size + sizeof(T_RVF_INTERNAL_BUF) + RVF_CORRUPT_OVERHEAD; #endif rvf_disable(20); /* enter critical section */ /* decrease mb memory use */ mb->cur_memory_used -= buf_size; rvf_enable(); /* exit critical section */ /* call the callback function if state of the mb switches to RVF_GREEN and there is no buffer waiting */ if ( (mb->returned_red == TRUE) && (mb->cur_memory_used < mb->watermark) && ( mb->first_buffer_index == RVF_INVALID_INDEX) && ( mb->func != NULL) ) { mb->returned_red = FALSE; mb->func( mb_id); } else { /* count as many waiting buffers as possible on the mb */ while( (mb->first_buffer_index != RVF_INVALID_INDEX) && (rvf_count_buf( mb_id, (UINT8 *) (waiting_buffers[mb->first_buffer_index]) + sizeof(T_RVF_INTERNAL_BUF)) != RVF_RED) ); if ( (mb->cur_memory_used < mb->watermark) && ( mb->first_buffer_index == RVF_INVALID_INDEX) && (mb->returned_red == TRUE) && ( mb->func != NULL) ) { mb->returned_red = FALSE; mb->func( mb_id); } } return RVF_OK; } /******************************************************************************* ** ** Function rvf_set_callback_func ** ** Description Called the first time an application wants to set the callback ** function associated to a memory bank. ** ** Parameters: memory bank id, pointer to the callback function. ** ** Returns T_RVF_RET: T_RVF_OK if succesful, ** *******************************************************************************/ T_RVF_RET rvf_set_callback_func(T_RVF_MB_ID mb_id, MB_CALLBACK_FUNC func) { T_RVF_MB * mb; /* checking for invalid memory bank IDs */ if (mb_id >= RVF_MAX_REAL_MB) return RVF_INVALID_PARAMETER; mb = &rvf_banks[mb_id]; if ( (mb->max != 0) && (mb->func == NULL) ) /* if the mb has been created and the callback func has never been set */ { mb->func = func; return RVF_OK; } return RVF_INVALID_PARAMETER; } /******************************************************************************* ** ** Function rvf_change_callback_func ** ** Description Called by an application to change the callback ** function associated to a memory bank. ** It means the callback function has to be set before. ** ** Parameters: memory bank id, pointer to the callback function. ** ** Returns T_RVF_RET: T_RVF_OK if succesful, ** *******************************************************************************/ T_RVF_RET rvf_change_callback_func(T_RVF_MB_ID mb_id, MB_CALLBACK_FUNC func) { T_RVF_MB * mb; /* checking for invalid memory bank IDs */ if (mb_id >= RVF_MAX_REAL_MB) return RVF_INVALID_PARAMETER; mb = &rvf_banks[mb_id]; if ( (mb->max != 0) && (mb->func != NULL) ) /* if the mb has been created and the callback func has already been set */ { mb->func = func; return RVF_OK; } return RVF_INVALID_PARAMETER; } #ifdef _WINDOWS_ /******************************************************************************* ** ** Function _rvf_window_dump_mem ** ** Description Called by a C++ object to update the graphical display of ** memory ** ** Parameters: Opaque pointer to C++ object ** ** Returns void ** ** WARNING DON'T CHANGE THE SYNTAX OF DISPLAYED DATAS SINCE ** THEY ARE PARSED TO DISPLAY GRAPHICALLY THE MEMORY ** STATUS ** *******************************************************************************/ void _rvf_window_dump_mem(void *m) { #if RVF_ENABLE_STATS /* conditional compilation if stats are enabled */ char mb_info[100]; UINT16 num_mb, num_buf, index; UINT32 total_mem_size = 0; UINT32 total_max_used = 0; UINT32 total_cur_used = 0; T_RVF_MB * mb; for ( num_mb = 0; num_mb < RVF_MAX_TOTAL_MB; num_mb++ ) { /* trace the mb if it has been created*/ if ( rvf_name_id[num_mb].mb_params.size > 0 ) { mb = &rvf_banks[ rvf_name_id[num_mb].mb_id ]; num_buf = 0; index = mb->first_buffer_index; while ( index != RVF_INVALID_INDEX) { num_buf++; index = next_buffer[index]; } strcpy(mb_info,rvf_name_id[num_mb].mb_name); mb_info[10]='\0'; AddNewState(m,mb_info, mb->cur_memory_used,mb->max_reached,mb->watermark,mb->max); total_mem_size += mb->max; total_max_used += mb->max_reached; total_cur_used += mb->cur_memory_used; } } #endif /* RVF_ENABLE_STATS */ } #endif /******************************************************************************* ** ** Function rvf_dump_mem ** ** Description Called by an application to dump mb state and display statistics ** ** Parameters: None ** ** Returns void ** ** WARNING DON'T CHANGE THE SYNTAX OF DISPLAYED DATAS SINCE ** THEY ARE PARSED TO DISPLAY GRAPHICALLY THE MEMORY ** STATUS ** *******************************************************************************/ void rvf_dump_mem() { #if RVF_ENABLE_STATS /* conditional compilation if stats are enabled */ char mb_info[100]; UINT16 num_mb, num_buf, index; UINT32 total_mem_size = 0; UINT32 total_max_used = 0; UINT32 total_cur_used = 0; T_RVF_MB * mb; /* display memory required, obtained and ratio */ rvf_send_trace("MEM STAT: Total memory required", 31, required_size, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); rvf_send_trace("MEM STAT: Total memory obtained", 31, obtained_size, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); rvf_send_trace("MEM STAT: Total memory used ", 31, used_size, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); sprintf( mb_info,"MEM STAT: Mem usage ratio : %010f%%", ( (double)(required_size) / (double)(obtained_size) ) *100 ); rvf_send_trace(mb_info, 44, NULL_PARAM , RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); rvf_send_trace("*** START DUMPING MEMORY BANK ***", 33, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); /* for each mb, display its name, its id, its cur_size, its watermark, its limit, its max reached, the number of callback functions enqueued, (the requested size, the number of allocated buffer), the average buffer size for this mb */ rvf_send_trace("**MB_NAME* Id Used_mem Watermark Limit Peak Nb_buff Avg_buf_size", 67, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); for ( num_mb = 0; num_mb < RVF_MAX_TOTAL_MB; num_mb++ ) { /* trace the mb if it has been created*/ if ( rvf_name_id[num_mb].mb_params.size > 0 ) { mb = &rvf_banks[ rvf_name_id[num_mb].mb_id ]; num_buf = 0; index = mb->first_buffer_index; while ( index != RVF_INVALID_INDEX) { num_buf++; index = next_buffer[index]; } sprintf( mb_info, "%10.10s %2d %6d %6d %6d %6d %2d %6d", rvf_name_id[num_mb].mb_name, rvf_name_id[num_mb].mb_id, mb->cur_memory_used, mb->watermark, mb->max, mb->max_reached, num_buf, mb->num_buf == 0? 0:mb->required_size / mb->num_buf); rvf_send_trace( mb_info, 67, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); total_mem_size += mb->max; total_max_used += mb->max_reached; total_cur_used += mb->cur_memory_used; } } sprintf( mb_info, "TOTAL: ******** %6d********** %6d %6d", total_cur_used, total_mem_size, total_max_used ); rvf_send_trace( mb_info, 46, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); #endif /* RVF_ENABLE_STATS */ } /******************************************************************************* ** ** Function rvf_get_available_mem ** ** Description Called to get the total size of the memory and the used size. ** ** Parameters: (return) UINT32 * total_size: contains the number of bytes in the memory. ** (return) UINT32 * used_size: contains the number of used bytes in the memory. ** ** Returns T_RVF_RET: RVF_OK if successful, else a negative value. ** *******************************************************************************/ T_RVF_RET rvf_get_available_mem( UINT32 * total_size, UINT32 * used_size ) { UINT16 count; *total_size = 0; *used_size = 0; /* check if there is enough available physical memory (static or dynamic): if Sum(mb size) <= Sum(pool size)*/ for ( count = 0; count < _rvf_get_number_of_pool(); count ++ ) /* sum the memory in pools */ { *total_size += _rvf_pools[count].pool_size; } /* sum the memory required by existing mb */ for ( count = 0; count < RVF_MAX_REAL_MB; count ++ ) { *used_size += rvf_banks[count].max; } return RVF_OK; } /******************************************************************************* ** ** Function rvf_get_mb_param ** ** Description return the parameters of a specific memory bank ** ** Parameters: T_RVF_MB_NAME: name of the memory bank ** (return) T_RVF_MB_PARAM*: parameter of the memory bank. ** ** Returns T_RVF_RET: RVF_OK if successful, else a negative value. ** *******************************************************************************/ T_RVF_RET rvf_get_mb_param( T_RVF_MB_NAME mb_name, T_RVF_MB_PARAM * param) { UINT8 num_mb; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) /* mb name not found */ { return RVF_INVALID_PARAMETER; } /* copy the parameters of the memory bank */ *param = rvf_name_id[num_mb].mb_params; return RVF_OK; } /******************************************************************************* ** ** Function rvf_set_mb_param ** ** Description change the parameters of a specific memory bank ** ** Parameters: T_RVF_MB_NAME: name of the memory bank ** T_RVF_MB_PARAM*: parameter of the memory bank. ** ** Returns T_RVF_RET: RVF_OK if successful, else a negative value. ** *******************************************************************************/ T_RVF_RET rvf_set_mb_param( T_RVF_MB_NAME mb_name, T_RVF_MB_PARAM * param) { UINT8 num_mb; T_RVF_MB_ID mb_id; T_RVF_MB * mb; /* find the mb name in the array */ for ( num_mb = 0; (num_mb < RVF_MAX_TOTAL_MB) && (!_str_cmp(mb_name, rvf_name_id[num_mb].mb_name) ); num_mb++); if ( num_mb == RVF_MAX_TOTAL_MB ) /* mb name not found */ { return RVF_INVALID_PARAMETER; } mb_id = rvf_name_id[num_mb].mb_id; mb = &rvf_banks[ mb_id ]; rvf_disable(20); /* enter critical section */ /* decrease the mb param by the old parameters */ mb->watermark -= rvf_name_id[num_mb].mb_params.watermark; mb->max -= rvf_name_id[num_mb].mb_params.size; /* save the mb parameters */ rvf_name_id[num_mb].mb_params.size = param->size; rvf_name_id[num_mb].mb_params.watermark = param->watermark; /* increase the mb param by the new parameters */ mb->watermark += param->watermark; mb->max += param->size; rvf_enable(); /* exit critical section */ /* dequeue callback functions if state switches to RVF_GREEN */ return RVF_OK; } /******************************************************************************* ** ** Function rvf_empty_mailboxes ** ** Description Called by rvf_exit_task to empty a task's mailboxes before ** killing it ** ** Parameters: task_id: task of wich the mailboxes have to be emptied ** ** Returns RV_OK ** *******************************************************************************/ T_RV_RET _rvf_empty_mailboxes (T_RVF_G_ADDR_ID task_id) { void * p_buf = NULL; T_RVF_INTERNAL_BUF * p_hdr; UINT8 mbox_id = 0; if (task_id >= MAX_RVF_TASKS) { rvf_send_trace( "RVF: rvf_empty_mbox(): invalid taskid: ", 39, task_id, RV_TRACE_LEVEL_ERROR, RVM_USE_ID ); return RVF_INVALID_PARAMETER; } for (mbox_id = 0; mbox_id< RVF_NUM_TASK_MBOX; mbox_id++) { /* while the chained list is not empty */ /*while ( OSTaskQFirst[task_id][mbox_id] ) { rvf_disable(9); p_hdr = OSTaskQFirst[task_id][mbox_id]; OSTaskQFirst[task_id][mbox_id] = p_hdr->p_next; */ while ( pRtAddrIdTable[task_id]->OSTaskQFirst[mbox_id] ) { rvf_disable(9); p_hdr = pRtAddrIdTable[task_id]->OSTaskQFirst[mbox_id]; pRtAddrIdTable[task_id]->OSTaskQFirst[mbox_id] = p_hdr->p_next; #if RVF_ENABLE_BUF_LINKAGE_CHECK /* set as unlinked */ RVF_SET_BUF_UNLINKED(p_hdr); #endif p_buf = (UINT8 *)p_hdr + sizeof(T_RVF_INTERNAL_BUF); rvf_enable(); /* exit critical section */ rvf_free_buf(p_buf); } } return (RV_OK); } /******************************************************************************* ** ** Function rvf_scan_next ** ** Description return the next item in the queue if any. ** If the end of the queue is reached, returns NULL. ** If current item is NULL, returns the first item in the queue. ** ** Returns NULL if the end of the queue is reached, else a pointer to the buffer. ** *******************************************************************************/ T_RVF_BUFFER * rvf_scan_next (T_RVF_BUFFER_Q * p_q, T_RVF_BUFFER * p_buf) { T_RVF_INTERNAL_BUF *p_hdr; if (!p_q->count) /* if the queue is empty */ return (NULL); if (p_buf == NULL) /* if current item == NULL, returns the first one */ { return (T_RVF_BUFFER*)p_q->p_first; } rvf_disable(12); /* enter critical section */ p_hdr = (T_RVF_INTERNAL_BUF *)((UINT8 *)p_buf - sizeof(T_RVF_INTERNAL_BUF)); p_hdr = p_hdr->p_next; if (p_hdr != NULL) { p_hdr = (T_RVF_INTERNAL_BUF*) ((UINT8 *)p_hdr + sizeof(T_RVF_INTERNAL_BUF)); } rvf_enable(); return (T_RVF_BUFFER*)p_hdr; } /******************************************************************************* ** ** Function rvf_remove_from_queue ** ** Description remove a specific item from a queue ** ** Returns RVF_OK if the item is removed, RVF_INTERNAL_ERR else. ** *******************************************************************************/ T_RVF_RET rvf_remove_from_queue (T_RVF_BUFFER_Q * p_q, T_RVF_BUFFER * p_buf) { T_RVF_INTERNAL_BUF *p_hdr; T_RVF_INTERNAL_BUF *p_target; if (!p_q->count) /* if the queue is empty */ return (RVF_INTERNAL_ERR); rvf_disable(12); /* enter critical section */ /* find the specific item in the queue */ p_target = USER2MEM((UINT8*)p_buf); p_hdr = USER2MEM( (UINT8 *)p_q->p_first); if( p_hdr == p_target ) { /* the specific item is the first one */ rvf_dequeue( p_q); rvf_enable(); return (RVF_OK); } while( (p_hdr->p_next != p_target) && (p_hdr->p_next != NULL) ) { p_hdr = p_hdr->p_next; } if( p_hdr->p_next == NULL) /* item not found */ { rvf_enable(); return (RVF_INTERNAL_ERR); } p_hdr->p_next = p_target->p_next; p_q->count--; /* if we removed the last buffer */ if (p_q->p_last == p_buf) { p_q->p_last = p_hdr + sizeof(T_RVF_INTERNAL_BUF); } p_target->p_next = NULL; #if RVF_ENABLE_BUF_LINKAGE_CHECK /* set as unlinked */ RVF_SET_BUF_UNLINKED(p_target); #endif rvf_enable(); /* exit critical section */ return (RVF_OK); } /******************************************************************************* ** ** Function rvf_dump_pool ** ** Description Called by an application to dump memory pool usage ** ** Parameters: None ** ** Returns void ** *******************************************************************************/ void rvf_dump_pool() { #if RVF_ENABLE_STATS /* conditional compilation if stats are enabled */ UINT16 num_pool; UINT32 total_mem = 0; /* display memory stats */ rvf_send_trace("*** START DUMPING MEMORY ***", 28, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); /* display the total amount of memory available in the system */ /* and the total amount of memory currently in use */ for( num_pool = 0; num_pool < _rvf_get_number_of_pool(); num_pool++) { total_mem += _rvf_pools[num_pool].pool_size; } rvf_send_trace( "Total memory available ", 23, total_mem, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); rvf_send_trace( "Memory currently in use", 23, mem_in_use, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID); #endif /* RVF_ENABLE_STATS */ } static void rvf_free_protected_buf(void *buf) { rvf_free_buf(buf); } void rvf_get_protected_buf(T_RVF_MB_ID mb_id, UINT32 buffer_size, T_RVF_BUFFER** p_buffer) { T_RVF_MB_STATUS err; err=rvf_get_buf(mb_id,buffer_size,p_buffer); if (err==RVF_GREEN) { struct _protectedPtr_ *ptr; struct _exceptionContext_ *context; context=_currentExceptionContext_[rvf_get_taskid()]; err=rvf_get_buf(mb_id,sizeof(struct _protectedPtr_),(void*)&ptr); ptr->next=NULL; ptr->previous=NULL; ptr->ptr=*p_buffer; ptr->func=rvf_free_protected_buf; if (err==RVF_GREEN) { if (context->stack==NULL) { context->stack=ptr; } else { ptr->previous=context->stack; context->stack->next=ptr; context->stack=ptr; } } else { rvf_free_buf(*p_buffer); } } if (err!=RVF_GREEN) throw(E_not_enough_memory); } //TISHMMS Project /* add by xmzhou_trace_string to trace debug trace message */ void xmzhou_trace_string(char * string2trace) { rvf_send_trace(string2trace,strlen(string2trace),NULL_PARAM, RV_TRACE_LEVEL_DEBUG_LOW, RVM_USE_ID); } void xmzhou_trace_string_value(char * string2trace,UINT32 value) { rvf_send_trace(string2trace,strlen(string2trace),value, RV_TRACE_LEVEL_DEBUG_LOW, RVM_USE_ID); } static void mychar2hex(char ch, char *str) { unsigned char h_nibble = (ch >> 4) & 0x0F; unsigned char l_nibble = ch & 0x0F; if (h_nibble < 10) str[0] = 48 + h_nibble; else str[0] = 55 + h_nibble; if (l_nibble < 10) str[1] = 48 + l_nibble; else str[1] = 55 + l_nibble; } void xmzhou_trace_n_bytes(char * buffer0, UINT32 len) { int i; int traced_len=0; char mybuffer[40]; char *tracebuffer; if(buffer0==NULL) return; xmzhou_trace_string_value("xmzhou dumping data length=",len); xmzhou_trace_string("-------"); while(traced_len<len){ if((len-traced_len)>=16){ tracebuffer=mybuffer; for (i = 0; i < 16; i++) { mychar2hex (buffer0[traced_len+i], tracebuffer); tracebuffer += 2; } traced_len+=16; *tracebuffer = '\0'; rvf_send_trace(mybuffer,strlen(mybuffer),NULL_PARAM, RV_TRACE_LEVEL_DEBUG_LOW, RVM_USE_ID); rvf_delay(20); }else{ tracebuffer=mybuffer; for(i=0;i<(len-traced_len);i++) { mychar2hex (buffer0[traced_len+i], tracebuffer); tracebuffer += 2; } *tracebuffer = '\0'; rvf_send_trace(mybuffer,strlen(mybuffer),NULL_PARAM, RV_TRACE_LEVEL_DEBUG_LOW, RVM_USE_ID); rvf_delay(20); break; } } }