FreeCalypso > hg > freecalypso-sw
view gsm-fw/riviera/rvm/rvm_swe_db.c @ 416:c2e14cc15c23
flash erase-program-boot: implemented CRC check before flashing
author | Michael Spacefalcon <msokolov@ivan.Harhan.ORG> |
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date | Tue, 17 Jun 2014 07:33:25 +0000 |
parents | afceeeb2cba1 |
children |
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/** * * @file rvm_swe_db.c * * This file contains the functions related to the SW Entities * database management. * * @author David Lamy-Charrier (d-lamy@ti.com) * @version 0.2 * */ /* * Revision History: * * 01/19/2000 David Lamy-Charrier Create. * 10/22/2001 David Lamy-Charrier Update for new Riviera 1.6. * * (C) Copyright 2001 by Texas Instruments Incorporated, All Rights Reserved */ #include "../rvf/rvf_env.h" #include "rvm_gen.h" #include "rvm_api.h" #include "rvm_i.h" #include "rvm_use_id_list.h" #include <string.h> extern T_RVM_CONST_SWE_INFO RVM_SWE_GET_INFO_ARRAY[]; extern const T_RVM_USE_ID * RVM_TYPE2_SWE_GROUPS[]; /* id of the main rvm memory bank */ T_RVF_MB_ID rvm_mem_bank=RVF_INVALID_MB_ID; T_RVF_MB_ID rvm_sys_mem_bank=RVF_INVALID_MB_ID; T_RVF_MB_ID rvm_timer_mem_bank=RVF_INVALID_MB_ID; T_RVF_MB_ID rvm_tm_notify_mem_bank=RVF_INVALID_MB_ID; T_RVF_MB_ID rvm_stack_mem_bank=RVF_INVALID_MB_ID; /* database of all SW Entities, their name, their get_info function and their links */ T_RVM_KNOWN_SWE * rvm_swe_array; T_RVM_GROUP_INFO * rvm_group_array; /* ** Used task id array ** This array allows the RVM to allocate dynamically task ids to SWEs ** The task ids are allocated during creation. */ /*BOOLEAN rvm_allocated_task_id [MAX_RVF_TASKS]; */ /* ** Number of SW Entities known on the system */ UINT8 rvm_swe_number = 0; /******************************************************************************* ** Function rvm_init_swe_db ** ** Description Internal function called once at the beginning which ** initializes the SWE database from information gathered ** in a const array (defined in rvm_swe.c). ** *******************************************************************************/ T_RVM_RETURN rvm_init_swe_db () { UINT8 swe_cpt=0, i=0, j=0, group_cpt = 0; T_RVM_INFO_SWE swe_info; char rvm_trace_name[RVM_NAME_MAX_LEN+20] = "SWE Name: "; /* Initialize the allocated task id array */ /* for (i=0; i<MAX_RVF_TASKS; i++) { rvm_allocated_task_id[i] = FALSE; } */ /* None task ID allocated at startup except: * - RVM_TASK_ID, * - RVTEST_MENU_TASK_ID, * - DUMMY_TASK_ID. * * Refer to rv_general.h. * * TO DO: Remove the last two IDs as soon as managed as SWEs. */ /* rvm_allocated_task_id[RVM_TASK_ID] = TRUE; if ( RVTEST_MENU_TASK_ID < MAX_RVF_TASKS) { rvm_allocated_task_id[RVTEST_MENU_TASK_ID] = TRUE; } if ( IDLE_TASK_ID < MAX_RVF_TASKS) { rvm_allocated_task_id[IDLE_TASK_ID] = TRUE; } */ /* Get the number of known SWEs */ while ( ( RVM_SWE_GET_INFO_ARRAY[swe_cpt].get_info_func) != NULL) { swe_cpt++; } rvm_swe_number = swe_cpt; RVM_TRACE_DEBUG_HIGH_PARAM("RVM: number of registered SWE in the system: ", rvm_swe_number); /* Get memory for the SWEs array */ if ( rvf_get_buf( rvm_mem_bank, (swe_cpt+1)*sizeof(T_RVM_KNOWN_SWE), (T_RVF_BUFFER**)&rvm_swe_array ) == RVF_RED ) { RVM_TRACE_WARNING("RVM_init_swe_db: not enough memory in the RVM main memory bank for init of array"); return RVM_MEMORY_ERR; } memset(rvm_swe_array, 0, (swe_cpt+1)*sizeof(T_RVM_KNOWN_SWE)); /* call all get_info functions to gather information about the SWEs */ for (i=0; i<swe_cpt; i++) { /* Call get info fct */ (RVM_SWE_GET_INFO_ARRAY[i].get_info_func)(&swe_info); /* Init global structure */ rvm_swe_array[i].swe_get_info = RVM_SWE_GET_INFO_ARRAY[i].get_info_func; rvm_swe_array[i].swe_use_id = RVM_SWE_GET_INFO_ARRAY[i].use_id; rvm_swe_array[i].swe_addr_id = RVF_INVALID_ADDR_ID; rvm_swe_array[i].group_index = RVM_OWN_GROUP; rvm_swe_array[i].swe_type = swe_info.swe_type; switch(swe_info.swe_type) { case(RVM_SWE_TYPE_1): { strcpy (rvm_swe_array[i].swe_name, swe_info.type_info.type1.swe_name); rvm_swe_array[i].swe_return_path.callback_func = swe_info.type_info.type1.return_path.callback_func; rvm_swe_array[i].swe_use_id = swe_info.type_info.type1.swe_use_id; rvm_swe_array[i].swe_stack_size = 0; rvm_swe_array[i].swe_priority = 0; break; } case(RVM_SWE_TYPE_2): { strcpy (rvm_swe_array[i].swe_name, swe_info.type_info.type2.swe_name); rvm_swe_array[i].swe_return_path.callback_func = swe_info.type_info.type2.return_path.callback_func; rvm_swe_array[i].swe_use_id = swe_info.type_info.type2.swe_use_id; rvm_swe_array[i].swe_stack_size = swe_info.type_info.type2.stack_size; rvm_swe_array[i].swe_priority = swe_info.type_info.type2.priority; break; } case(RVM_SWE_TYPE_3): { strcpy (rvm_swe_array[i].swe_name, swe_info.type_info.type3.swe_name); rvm_swe_array[i].swe_return_path.callback_func = swe_info.type_info.type3.return_path.callback_func; rvm_swe_array[i].swe_use_id = swe_info.type_info.type3.swe_use_id; rvm_swe_array[i].swe_stack_size = swe_info.type_info.type3.stack_size; rvm_swe_array[i].swe_priority = swe_info.type_info.type3.priority; break; } case(RVM_SWE_TYPE_4): { strcpy (rvm_swe_array[i].swe_name, swe_info.type_info.type4.swe_name); rvm_swe_array[i].swe_return_path.callback_func = swe_info.type_info.type4.return_path.callback_func; rvm_swe_array[i].swe_use_id = swe_info.type_info.type4.swe_use_id; rvm_swe_array[i].swe_stack_size = swe_info.type_info.type4.stack_size; rvm_swe_array[i].swe_priority = swe_info.type_info.type4.priority; break; } } rvm_swe_array[i].swe_state = SWE_NOT_STARTED; rvm_swe_array[i].stack_ptr = NULL; rvm_swe_array[i].nb_using_appli = 0; for (j=0; j<RVM_MAX_SWE_USING; j++) { rvm_swe_array[i].using_appli[j] = RVM_INVALID_SWE_INDEX; } rvm_swe_array[i].swe_return_path.addr_id = RVF_INVALID_ADDR_ID; rvm_swe_array[i].mmi_return_path.callback_func = NULL; rvm_swe_array[i].mmi_return_path.addr_id = RVF_INVALID_ADDR_ID; } RVM_TRACE_DEBUG_HIGH("RVM init: Known SWE database built"); /* display the list of known SWEs with their name, use_id and index in the array. */ for (i=0; i<swe_cpt; i++) { strcpy(rvm_trace_name + 10, rvm_swe_array[i].swe_name); rvf_send_trace(rvm_trace_name , (UINT8)strlen(rvm_trace_name), NULL_PARAM, RV_TRACE_LEVEL_DEBUG_LOW, RVM_USE_ID ); RVM_TRACE_DEBUG_LOW_PARAM("SWE number:", i); RVM_TRACE_DEBUG_LOW_PARAM("SWE use_id:", rvm_swe_array[i].swe_use_id); } /* initialize SWEs group array */ /* Get the number of groups group_cpt = 0; while ( (RVM_TYPE2_SWE_GROUPS[group_cpt]) != NULL) { i++; } // Get memory for the groups array if ( rvf_get_buf( rvm_mem_bank, (group_cpt+1)*sizeof(T_RVM_GROUP_INFO), (T_RVF_BUFFER**)&rvm_group_array ) == RVF_RED ) { RVM_TRACE_WARNING("RVM_build_swe_list: not enough memory in the RVM main memory bank for init of group array"); return RVM_MEMORY_ERR; } memset(rvm_group_array, 0, (group_cpt+1)*sizeof(T_RVM_GROUP_INFO)); // update the group_index of each type 2 SWE. for( i = 0; i < group_cpt; i++) { rvm_group_array[i].host_state = SWE_NOT_STARTED; rvm_group_array[i].task_id = RVF_INVALID_TASK; rvm_group_array[i].task_priority= 255; if( RVM_TYPE2_SWE_GROUPS[i] != NULL) { UINT8 index; j = 0; while( RVM_TYPE2_SWE_GROUPS[i][j] != RVM_INVALID_USE_ID) { if( rvm_get_swe_index( &index, RVM_TYPE2_SWE_GROUPS[i][j]) == RVM_OK) { // store the host group in the SWE rvm_swe_array[index].group_index = i; // computes the highest stack size if( rvm_swe_array[index].swe_stack_size > rvm_group_array[i].stack_size) { rvm_group_array[i].stack_size = rvm_swe_array[index].swe_stack_size; } // computes the smallest priority if( rvm_swe_array[index].swe_priority < rvm_group_array[i].task_priority) { rvm_group_array[i].task_priority = rvm_swe_array[index].swe_priority; } } j++; } } } */ return RVM_OK; } /******************************************************************************* ** Function rvm_get_swe_index ** ** Description Internal function which returns the index of the swe in the ** database of known SWEs. ** Returns RVM_OK if it exists, else RVM_INVALID_PARAMETER. *******************************************************************************/ T_RVM_RETURN rvm_get_swe_index( UINT8 * index, T_RVM_USE_ID swe_use_id) { for ( (*index) = 0; ( (*index) < rvm_swe_number) && (swe_use_id != rvm_swe_array[*index].swe_use_id) ; (*index)++); if ( *index == rvm_swe_number ) /* swe use id not found */ { *index = RVM_INVALID_SWE_INDEX; return RVM_INVALID_PARAMETER; } return RVM_OK; } /******************************************************************************* ** Function rvm_check_application ** ** Description Internal function which checks if a SWE can be started ** or stopped, depending on appli_action parameter. ** If it is the case, it returns the application number. *******************************************************************************/ T_RVM_RETURN rvm_check_application (T_RVM_USE_ID swe_use_id, UINT8* num_swe, T_RVM_APPLI_ACTION appli_action) { /* check if the SWE use_id exists */ if (rvm_get_swe_index(num_swe, swe_use_id) != RVM_OK) { return RVM_INVALID_PARAMETER; } /* check if the get_info function is known */ if (rvm_swe_array[*num_swe].swe_get_info == NULL ) { *num_swe = 0; return RVM_NOT_READY; } /* check if the appli can be started or stopped */ /* if ((appli_action == RVM_START_APPLI) && ( rvm_swe_array[*num_swe].swe_state != SWE_NOT_STARTED)) { *num_swe = 0; return RVM_NOT_READY; } */ /* If more than 1 SWE is using the application, we cannot stop it */ /* if (appli_action == RVM_STOP_APPLI) { if ( (rvm_swe_array[*num_swe].swe_state != SWE_RUNNING) || \ (rvm_swe_array[*num_swe].nb_using_appli != 1) || \ (rvm_swe_array[rvm_swe_array[*num_swe].using_appli[0]].swe_use_id != rvm_swe_array[*num_swe].swe_use_id) ) { *num_swe = 0; return RVM_NOT_READY; } }*/ return RVM_OK; } /******************************************************************************* ** Function rvm_unlock_swe ** ** Description Internal function that sets back SWE state to NOT_STARTED ** in case an error occurs or the stop process is finished *******************************************************************************/ T_RVM_RETURN rvm_unlock_swe ( T_RVM_PROCESSING_SWE * appli) { T_RVM_PROCESSING_SWE * cur_elem = appli; while (cur_elem) { UINT8 swe_index = cur_elem->swe_id; if (rvm_swe_array[swe_index].swe_state != SWE_RUNNING) { cur_elem = cur_elem->next_swe; continue; } rvm_swe_array[swe_index].swe_state = SWE_NOT_STARTED; cur_elem = cur_elem->next_swe; } return RVM_OK; } /******************************************************************************* ** ** Function rvm_build_swe_list ** ** Description Build the list of SWEs required to launch the specified SWE. ** ** Parameters: T_RVM_PROCESSING_SWE ** list: list of required SWE. ** UINT8 swe_num: index of the SWE to start in the array of known SWEs. ** ** Returns T_RVM_RETURN ** *******************************************************************************/ T_RVM_RETURN rvm_build_swe_list(T_RVM_PROCESSING_SWE ** list, UINT8 swe_num, UINT8 mode) { T_RVM_PROCESSING_SWE * cur_elem = *list; T_RVM_USE_ID loc_linked_swe_id[RVM_MAX_NB_LINKED_SWE]; UINT8* rvm_swe_to_call; UINT8 rvm_current_swe_to_call = 0, rvm_last_swe_to_call = 1; UINT8 swe_cpt; UINT8 mb_cpt; UINT8 nb_linked_swe = 0; volatile T_RVM_RETURN rvm_ret_value = RVM_OK; UINT8 isRunning=0; /* allocate a matrix to store temporarily the dependencies between SWEs */ if (rvf_get_buf( rvm_mem_bank, rvm_swe_number*rvm_swe_number, (void**)&rvm_swe_to_call) == RVF_RED) { rvf_send_trace("RVM_build_swe_list: not enough memory in the RVM memory bank for build_swe_list process", 87, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); return RVM_MEMORY_ERR; } rvm_swe_to_call[rvm_current_swe_to_call] = swe_num; do /* While some get_info functions has to be called. */ { T_RVM_INFO_SWE swe_info; UINT8 swe_num_i = rvm_swe_to_call[rvm_current_swe_to_call]; /* Check if SWE is running or not */ if (rvm_swe_array[swe_num_i].swe_state == SWE_RUNNING && mode==0) { rvf_send_trace("RVM_build_swe_list: SWE already running, nb: ", 45, swe_num_i, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID ); rvm_current_swe_to_call++; continue; } if ( rvm_swe_array[swe_num_i].swe_state == SWE_STOPPING && mode==0) { rvf_send_trace("RVM_build_swe_list: SWE stopped awaiting kill, nb: ", 45, swe_num_i, RV_TRACE_LEVEL_DEBUG_HIGH, RVM_USE_ID ); rvm_current_swe_to_call++; continue; } /* Check if SWE is already queued or not. */ cur_elem = *list; while ( (cur_elem != NULL) && ( rvm_swe_array[cur_elem->swe_id].swe_use_id != rvm_swe_array[swe_num_i].swe_use_id) ) { cur_elem = cur_elem->next_swe; } if (cur_elem != NULL) /* SWE was found => - update SWE variables and pointers - go to next step of the loop. */ { rvm_current_swe_to_call++; continue; } /* cur_elem = NULL => SWE was not found => create its entry in the list. */ /* create it and call its get_info function */ if ( rvf_get_buf( rvm_mem_bank, sizeof(T_RVM_PROCESSING_SWE), (void**)&cur_elem ) == RVF_RED ) { rvf_send_trace("RVM_build_swe_list: not enough memory in the RVM main memory bank for the SWE entry", 83, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); rvm_ret_value = RVM_MEMORY_ERR; break; } /* ** initialize the new entry */ memset(cur_elem, 0, sizeof(T_RVM_PROCESSING_SWE) ); /* ** Set the SWE id: index in known SWE array */ cur_elem->swe_id = swe_num_i; /* call its get_info() function */ if ( rvm_swe_array[swe_num_i].swe_get_info(&swe_info) != RVM_OK ) { /* Here an error occured in its get_info function. free memory allocated for this entry and return an error. */ rvf_free_buf( cur_elem ); rvf_send_trace("RVM_build_swe_list: get_info function returns an error", 54, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); rvm_ret_value = RVM_INTERNAL_ERR; break; } cur_elem->swe_type = swe_info.swe_type; cur_elem->rvm_functions.core = rvm_generic_swe_core; switch( swe_info.swe_type) { case ( RVM_SWE_TYPE_1): { cur_elem->rvm_functions.set_info = swe_info.type_info.type1.set_info; cur_elem->rvm_functions.init = swe_info.type_info.type1.init; cur_elem->rvm_functions.start = swe_info.type_info.type1.start; cur_elem->rvm_functions.stop1 = swe_info.type_info.type1.stop; cur_elem->rvm_functions.kill = swe_info.type_info.type1.kill; nb_linked_swe = swe_info.type_info.type1.nb_linked_swe; for( mb_cpt = 0; mb_cpt < nb_linked_swe; mb_cpt++ ) { loc_linked_swe_id[mb_cpt] = swe_info.type_info.type1.linked_swe_id[mb_cpt]; } /* memory bank information */ cur_elem->nb_requested_mb = swe_info.type_info.type1.nb_mem_bank; for( mb_cpt = 0; mb_cpt < cur_elem->nb_requested_mb; mb_cpt++ ) { memcpy (cur_elem->swe_mem_bank[mb_cpt].mb_name, \ swe_info.type_info.type1.mem_bank[mb_cpt].bank_name, \ RVF_MAX_MB_LEN); cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.size \ = swe_info.type_info.type1.mem_bank[mb_cpt].initial_params.size; cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.watermark \ = swe_info.type_info.type1.mem_bank[mb_cpt].initial_params.watermark; } break; } case ( RVM_SWE_TYPE_2): { cur_elem->rvm_functions.set_info = swe_info.type_info.type2.set_info; cur_elem->rvm_functions.init = swe_info.type_info.type2.init; cur_elem->rvm_functions.start = swe_info.type_info.type2.start; cur_elem->rvm_functions.stop = swe_info.type_info.type2.stop; cur_elem->rvm_functions.kill = swe_info.type_info.type2.kill; cur_elem->rvm_functions.handle_message = swe_info.type_info.type2.handle_message; cur_elem->rvm_functions.handle_timer = swe_info.type_info.type2.handle_timer; cur_elem->priority = swe_info.type_info.type2.priority; cur_elem->stack_size = swe_info.type_info.type2.stack_size; nb_linked_swe = swe_info.type_info.type2.nb_linked_swe; for( mb_cpt = 0; mb_cpt < nb_linked_swe; mb_cpt++ ) { loc_linked_swe_id[mb_cpt] = swe_info.type_info.type2.linked_swe_id[mb_cpt]; } /* memory bank information */ cur_elem->nb_requested_mb = swe_info.type_info.type2.nb_mem_bank; for( mb_cpt = 0; mb_cpt < cur_elem->nb_requested_mb; mb_cpt++ ) { memcpy (cur_elem->swe_mem_bank[mb_cpt].mb_name, \ swe_info.type_info.type2.mem_bank[mb_cpt].bank_name, \ RVF_MAX_MB_LEN); cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.size \ = swe_info.type_info.type2.mem_bank[mb_cpt].initial_params.size; cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.watermark \ = swe_info.type_info.type2.mem_bank[mb_cpt].initial_params.watermark; } break; } case ( RVM_SWE_TYPE_3): { cur_elem->rvm_functions.set_info = swe_info.type_info.type3.set_info; cur_elem->rvm_functions.init = swe_info.type_info.type3.init; cur_elem->rvm_functions.start = swe_info.type_info.type3.start; cur_elem->rvm_functions.stop = swe_info.type_info.type3.stop; cur_elem->rvm_functions.kill = swe_info.type_info.type3.kill; cur_elem->rvm_functions.handle_message = swe_info.type_info.type3.handle_message; cur_elem->rvm_functions.handle_timer = swe_info.type_info.type3.handle_timer; cur_elem->priority = swe_info.type_info.type3.priority; cur_elem->stack_size = swe_info.type_info.type3.stack_size; nb_linked_swe = swe_info.type_info.type3.nb_linked_swe; for( mb_cpt = 0; mb_cpt < nb_linked_swe; mb_cpt++ ) { loc_linked_swe_id[mb_cpt] = swe_info.type_info.type3.linked_swe_id[mb_cpt]; } /* memory bank information */ cur_elem->nb_requested_mb = swe_info.type_info.type3.nb_mem_bank; for( mb_cpt = 0; mb_cpt < cur_elem->nb_requested_mb; mb_cpt++ ) { memcpy (cur_elem->swe_mem_bank[mb_cpt].mb_name, \ swe_info.type_info.type3.mem_bank[mb_cpt].bank_name, \ RVF_MAX_MB_LEN); cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.size \ = swe_info.type_info.type3.mem_bank[mb_cpt].initial_params.size; cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.watermark \ = swe_info.type_info.type3.mem_bank[mb_cpt].initial_params.watermark; } break; } case ( RVM_SWE_TYPE_4): { cur_elem->rvm_functions.set_info = swe_info.type_info.type4.set_info; cur_elem->rvm_functions.init = swe_info.type_info.type4.init; cur_elem->rvm_functions.stop1 = swe_info.type_info.type4.stop; cur_elem->rvm_functions.kill = swe_info.type_info.type4.kill; cur_elem->rvm_functions.core = swe_info.type_info.type4.core; cur_elem->priority = swe_info.type_info.type4.priority; cur_elem->stack_size = swe_info.type_info.type4.stack_size; nb_linked_swe = swe_info.type_info.type4.nb_linked_swe; for( mb_cpt = 0; mb_cpt < nb_linked_swe; mb_cpt++ ) { loc_linked_swe_id[mb_cpt] = swe_info.type_info.type4.linked_swe_id[mb_cpt]; } /* memory bank information */ cur_elem->nb_requested_mb = swe_info.type_info.type4.nb_mem_bank; for( mb_cpt = 0; mb_cpt < cur_elem->nb_requested_mb; mb_cpt++ ) { memcpy (cur_elem->swe_mem_bank[mb_cpt].mb_name, \ swe_info.type_info.type4.mem_bank[mb_cpt].bank_name, \ RVF_MAX_MB_LEN); cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.size \ = swe_info.type_info.type4.mem_bank[mb_cpt].initial_params.size; cur_elem->swe_mem_bank[mb_cpt].mb_initial_param.watermark \ = swe_info.type_info.type4.mem_bank[mb_cpt].initial_params.watermark; } break; } } /* allocate a task id, if necessary. */ /* if ( (swe_info.swe_type == RVM_SWE_TYPE_3) ||(swe_info.swe_type == RVM_SWE_TYPE_4) || ( (swe_info.swe_type == RVM_SWE_TYPE_2) && ( rvm_swe_array[swe_num_i].group_index == RVM_OWN_GROUP) ) || ( (swe_info.swe_type == RVM_SWE_TYPE_2) && ( rvm_group_array[rvm_swe_array[swe_num_i].group_index].task_id == RVF_INVALID_TASK) ) ) { T_RVM_TASK_ID loc_task_id; if(swe_info.swe_type==RVM_SWE_TYPE_2) loc_task_id = rvm_allocate_task_id(0); else loc_task_id = rvm_allocate_task_id(1); if (loc_task_id == RVF_INVALID_TASK) { rvm_ret_value = RVM_INTERNAL_ERR; break; } if ( (swe_info.swe_type == RVM_SWE_TYPE_3) ||(swe_info.swe_type == RVM_SWE_TYPE_4) || ( (swe_info.swe_type == RVM_SWE_TYPE_2) && ( rvm_swe_array[swe_num_i].group_index == RVM_OWN_GROUP) ) ) { rvm_swe_array[swe_num_i].swe_addr_id = loc_task_id; } else { if ( (swe_info.swe_type == RVM_SWE_TYPE_2) && ( rvm_group_array[rvm_swe_array[swe_num_i].group_index].task_id == RVF_INVALID_TASK) ) { rvm_group_array[rvm_swe_array[swe_num_i].group_index].task_id = loc_task_id; } } } */ /* Insert the element in the head of the list. */ if (*list == NULL) /* the list is empty */ { /* This element is the first of the list */ *list = cur_elem; cur_elem->next_swe = NULL; } else { cur_elem->next_swe = *list; *list = cur_elem; } /* Get the list of linked swe num, and put it in the array */ if (nb_linked_swe != 0) { for (swe_cpt = 0; swe_cpt < nb_linked_swe; swe_cpt++) { if (rvm_get_swe_index(&(rvm_swe_to_call[rvm_last_swe_to_call + swe_cpt]), loc_linked_swe_id[swe_cpt] ) != RVM_OK) { rvm_ret_value = RVM_INVALID_PARAMETER; rvf_send_trace("rvm_swe_db: Task allocation error!",35, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); break; } } if (rvm_ret_value != RVM_OK) break; rvm_last_swe_to_call += nb_linked_swe; } /* Once everything is done for current swe, increment rvm_current_swe_to_call */ rvm_current_swe_to_call ++; } while (rvm_current_swe_to_call != rvm_last_swe_to_call); if (rvm_ret_value != RVM_OK) /* Something went wrong => undo everything */ { rvm_delete_used_memory (*list); } rvf_free_buf (rvm_swe_to_call); return (rvm_ret_value); } /******************************************************************************* ** ** Function rvm_clean_env ** ** Description This function will clean the environment. ** Its main tasks are: ** - Update the using_appli pointer of the SWE array ** - Update states to NOT_STARTED ** - Release local memory ** ** Parameters: T_RVM_PROCESSING_SWE * appli: list of required SWEs with their parameters. ** ** Returns T_RVM_OK if all allocation are successful, ** else T_RVM_INTERNAL_ERR (then some SWE are not killed.) ** *******************************************************************************/ T_RVM_RETURN rvm_clean_env( T_RVM_PROCESSING_SWE * appli) { T_RVM_PROCESSING_SWE * cur_swe = appli; UINT8 appli_nb1, appli_nb2; volatile T_RVM_RETURN rvm_ret_value = RVM_OK; /* for each SWE in the list */ while (cur_swe != NULL ) { UINT8 swe_index = cur_swe->swe_id; /* Update using_appli array */ if (rvm_swe_array[swe_index].nb_using_appli > 1) { for (appli_nb1 = 0; appli_nb1 < (rvm_swe_array[swe_index].nb_using_appli - 1); appli_nb1++) { if (rvm_swe_array[swe_index].using_appli[appli_nb1] == appli->swe_id) /* appli was found in the using_appli array -> remove it and shift down the others */ { for (appli_nb2 = appli_nb1; appli_nb2 < rvm_swe_array[swe_index].nb_using_appli; appli_nb2++) { rvm_swe_array[swe_index].using_appli[appli_nb2] = rvm_swe_array[swe_index].using_appli[appli_nb2 + 1]; } /* Once using_appli pointer has been eliminated, we can exit the loop */ break; } } } /* Decrement nb of using applications */ rvm_swe_array[swe_index].nb_using_appli--; /* Force to NULL last appli pointer */ rvm_swe_array[swe_index].using_appli[rvm_swe_array[swe_index].nb_using_appli] = RVM_INVALID_SWE_INDEX; /* If last appli was deleted, put state back to init */ if (rvm_swe_array[swe_index].nb_using_appli == 0) { rvm_swe_array[swe_index].swe_state = SWE_NOT_STARTED; } /* Proceed to the next SWE */ cur_swe = cur_swe->next_swe; } /* Once Everything is back in stand-by, release used memory */ rvm_delete_used_memory (appli); return rvm_ret_value; } /******************************************************************************* ** ** Function rvm_error ** ** Description Called by a SWE in case of unrecoverable error ** ** Parameters: T_RVM_NAME swe_name: ** T_RVM_RETURN error_cause: ** T_RVM_ERROR_TYPE error_type: ** T_RVM_STRING error_msg: ** ** Returns T_RVM_RETURN: RVM_OK if successful, else a negative value. ** *******************************************************************************/ T_RVM_RETURN rvm_error ( T_RVM_NAME swe_name, T_RVM_RETURN error_cause, T_RVM_ERROR_TYPE error_type, T_RVM_STRING error_msg) { char swe_name_string[40]; UINT8 i=0; memcpy(swe_name_string,"RVM: coming from: ",18); memcpy((void*)((char*)swe_name_string+18),swe_name,RVM_NAME_MAX_LEN); RVM_TRACE_WARNING("RVM: unrecoverable error indication"); rvf_send_trace(swe_name_string, 18 + RVM_NAME_MAX_LEN, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); RVM_TRACE_WARNING_PARAM("RVM: Error Cause: ", error_cause); RVM_TRACE_WARNING_PARAM("RVM: Error Type: ", error_type); /* check the message to limit its length to RVM_ERROR_MSG_MAX_LENGTH characters. */ while (error_msg[i]) { i++; if (i>RVM_ERROR_MSG_MAX_LENGTH) break; } rvf_send_trace(error_msg, i, NULL_PARAM, RV_TRACE_LEVEL_WARNING, RVM_USE_ID ); return RVM_OK; }