void drv_init_concerto(void)
{

  dm_v2_init_para_t dm_para = {0};
  u32 dm_app_addr = 0;

  spiflash_cfg( );

  //init data manager....
  dm_para.flash_base_addr = get_flash_addr();
  dm_para.max_blk_num = DM_MAX_BLOCK_NUM;
  dm_para.task_prio = MDL_DM_MONITOR_TASK_PRIORITY;
  dm_para.task_stack_size = MDL_DM_MONITOR_TASK_STKSIZE;
  dm_para.open_monitor = TRUE;
  dm_para.para_size = sizeof(dm_v2_init_para_t);
  dm_para.use_mutex = TRUE;
  dm_para.mutex_prio = 1;
  dm_para.test_mode = FALSE;

  dm_init_v2(&dm_para);
  // g_dm_head_start = find_dm_head_start();

  dm_set_header(class_get_handle_by_id(DM_CLASS_ID), DM_BOOTER_START_ADDR);


  dm_set_header(class_get_handle_by_id(DM_CLASS_ID), DM_HDR_START_ADDR_BAK);

  dm_app_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), DM_MAINCODE_BLOCK_ID)
                   - get_flash_addr();

  dm_set_header(class_get_handle_by_id(DM_CLASS_ID),dm_app_addr);
}
void ota_dm_api_init(void)
{
  ota_dm_config_t p_cfg = {0};
  dm_dmh_info_t *p_all_dmh_info = NULL;
  #if 0
  p_cfg.ota_dm_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID),
                                     STATIC_SAVE_DATA_BLOCK_ID) - get_flash_addr();
  p_cfg.ota_dm_backup_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID),
                                     STATIC_SAVE_DATA_RESERVE_BLOCK_ID) - get_flash_addr();

  OS_PRINTF("#### debug dm addr:0x%x,dm backup addr:0x%x\n",p_cfg.ota_dm_addr,p_cfg.ota_dm_backup_addr);
  #endif
  p_cfg.is_use_mutex = TRUE;
  p_cfg.mutex_prio = 1;
  p_cfg.is_protect = TRUE;
  p_cfg.disable_backup_block = FALSE;
  p_cfg.debug_level = OTA_DM_DEBUG_ALL;
  p_cfg.ota_dm_api_printf = NULL;
  p_cfg.align_size = PICE_MAX_ALIGN_SIZE;
  p_cfg.flash_size = CHARSTO_SIZE;
  p_cfg.pp_dm_info = &p_all_dmh_info;
  p_cfg.ota_dm_block_id = STATIC_SAVE_DATA_BLOCK_ID;
  p_cfg.ota_dm_backup_block_id =STATIC_SAVE_DATA_RESERVE_BLOCK_ID;

  OS_PRINTF("#####debug ui ota dm api  init\n");
  mul_ota_dm_api_init(&p_cfg);

  /****test use ,please don't use in project,but factory upg*****/
 //mul_ota_dm_api_reset_data_block();
}
static BOOL mem_addr_legal(u32 addr, u32 size)
{
  u32 flash_b = 0;
  u32 flash_e = 0;
  u32 cache_mem_b = 0;
  u32 cache_mem_e = 0;
  u32 nc_mem_b = 0; // none cache memory begin
  u32 nc_mem_e = 0; // none cache memory end
  u32 reg_b = 0;
  u32 reg_e = 0;

  flash_b = get_flash_addr();
  flash_e = flash_b + CHARSTO_SIZE;

  cache_mem_b = 0x80000000;
  cache_mem_e = WHOLE_MEM_END & 0x8FFFFFFF;

  nc_mem_b = 0xa0000000;
  nc_mem_e = WHOLE_MEM_END;

  // FIXME:
  reg_b = 0xbf000000;
  reg_e = 0xbff00000; 

  if (is_in_range((u32)addr, size, flash_b, flash_e) ||
      is_in_range((u32)addr, size, cache_mem_b, cache_mem_e) ||
      is_in_range((u32)addr, size, nc_mem_b, nc_mem_e) ||
      is_in_range((u32)addr, size, reg_b, reg_e))
  {
    return TRUE;
  }
  
  return FALSE;
}
u32 get_dm_block_real_file_addr(u8 block_id)
{
    dmh_block_info_t real_dm_info = {0};
    u32 block_addr = 0;
    u32 dm_addr = 0;
    BOOL ret = 0;
    dmh_block_info_t block_dm_info = {0};
     if(dm_get_block_header(class_get_handle_by_id(DM_CLASS_ID),block_id,&block_dm_info) == DM_FAIL)
      {
        return 0;
      }

     block_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), block_id);
     block_addr = block_addr - get_flash_addr();
     dm_addr = block_addr - block_dm_info.base_addr;
      if(block_dm_info.type != BLOCK_TYPE_RO)
      {
        return block_addr;
      }
    
    ret = get_dm_block_real_file_info(block_id,&real_dm_info);
    if((ret == 0) && (block_addr == (real_dm_info.base_addr + dm_addr)))
    {   
        return block_addr;
    }
    return 0; 
}
Esempio n. 5
0
static RET_CODE nvram_read(u32 offset, u8 *p_buf, u32 *size)
{

  charsto_device_t *p_charsto_dev = dev_find_identifier(NULL, DEV_IDT_TYPE,
    SYS_DEV_TYPE_CHARSTO);
  RET_CODE ret = SUCCESS;
  handle_t dm_handle = class_get_handle_by_id(DM_CLASS_ID);
  u32 base_addr =  dm_get_block_addr(dm_handle, CADATA_BLOCK_ID) - get_flash_addr();

  MT_ASSERT(dm_handle != NULL);

  OS_PRINTF("CA nvram_read offset= 0x%x, *size=0x%x, base_addr=0x%x \n",offset, *size, base_addr);

#if WRITE_DATA_TO_MEM
  memcpy(p_buf, (u8 *)&p_ca_buffer[offset], *size);
  OS_PRINTF("CA nvram_read end\n");
#else
  mtos_task_lock();
  ret = charsto_read(p_charsto_dev, base_addr + offset, p_buf, *size);
  if (ret != SUCCESS)
  {
    OS_PRINTF("read error\n");
    mtos_task_unlock();
    return ERR_FAILURE;
  }
  mtos_task_unlock();
  OS_PRINTF("nvram_read success!\n");
#endif
  return SUCCESS;
}
Esempio n. 6
0
static s32 load_logo(void)
{
  OS_PRINTK("\n###fast logo logo buf :0x%x flash addr 0x%x\n",
    dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), START_LOGO_BLOCK_ID)),get_flash_addr();
  
   g_p_logo_buf = (u8 *)(dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), START_LOGO_BLOCK_ID));
   
  g_logo_size = get_dm_block_real_file_size(START_LOGO_BLOCK_ID);//dm_get_block_size(class_get_handle_by_id(DM_CLASS_ID),START_LOGO_BLOCK_ID);
  
  OS_PRINTK("\n###fast logo logo buf :0x%x,size:0x%x\n",*((u32 *)g_p_logo_buf),g_logo_size);
  return SUCCESS;
}
void on_cas_init(void)
{
	u32 cas_id = 0;
	cas_adapter_cfg_t cas_cfg = {0};
	cas_module_cfg_t cas_module_cfg = {0};
	p_ca_buffer = mtos_malloc(CA_DATA_SIZE);
	MT_ASSERT(NULL != p_ca_buffer);
	memset(p_ca_buffer, 0, CA_DATA_SIZE);

	//config cas adapter
	cas_cfg.p_smc_drv[0] = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_SMC);
	cas_cfg.slot_num = 1;
	cas_cfg.p_task_stack = mtos_malloc(4096);
	MT_ASSERT(NULL != cas_cfg.p_task_stack);
	cas_cfg.stack_size = 4096;
	cas_cfg.task_prio = DRV_CAS_ADAPTER_TASK_PRIORITY;
	cas_cfg.p_data_task_stack = mtos_malloc(4096);
	MT_ASSERT(NULL != cas_cfg.p_data_task_stack);
	cas_cfg.data_stack_size = 4096;
	//cas_cfg.data_task_prio = MDL_CAS_TASK_PRIO_BEGIN+1;

#ifndef WIN32
	cas_init(&cas_cfg);
#endif
	cas_module_cfg.cas_lib_type = CAS_LIB_TEST;
	cas_module_cfg.p_dmx_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_PTI);
	cas_module_cfg.max_mail_num = 30;
	cas_module_cfg.mail_policy = POLICY_BY_ID;

	cas_module_cfg.flash_start_adr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), CADATA_BLOCK_ID)
	  - get_flash_addr();
	OS_PRINTF("set ca addr is 0x%x\n", cas_module_cfg.flash_start_adr);
	cas_module_cfg.flash_size = CA_DATA_SIZE;
	cas_module_cfg.level = 0;
	cas_module_cfg.task_prio = MDL_CAS_TASK_PRIO_BEGIN;
	cas_module_cfg.end_task_prio = MDL_CAS_TASK_PRIO_END;
	cas_module_cfg.stack_size = 8 * KBYTES;
	cas_module_cfg.p_task_stack = mtos_malloc(8 * KBYTES);
	cas_module_cfg.filter_mode = ECM_FILTER_CONTINUOUS_DISABLED;
	cas_module_cfg.nvram_read = nvram_read;
	cas_module_cfg.nvram_write = nvram_write;

	cas_module_cfg.queue_task_prio = LOWEST_TASK_PRIORITY -2; //LOWEST_TASK_PRIORITY -1; //panhui


	MT_ASSERT(cas_module_cfg.p_task_stack != NULL);
#ifndef WIN32
	cas_tr_attach(&cas_module_cfg, &cas_id);
	cas_module_init(CAS_ID_TR);
#endif
	register_monitor_table();
}
Esempio n. 8
0
static int drv_dm_init(void)
{
  dm_v2_init_para_t dm_para = {0};
  u32 dm_app_addr = 0;
  RET_CODE ret;

  ret = ATTACH_DRIVER(CHARSTO, concerto, default, default);
  MT_ASSERT(ret == SUCCESS);

  spiflash_cfg( );

  //init data manager....
  dm_para.flash_base_addr = get_flash_addr();
  dm_para.max_blk_num = DM_MAX_BLOCK_NUM;
  dm_para.task_prio = MDL_DM_MONITOR_TASK_PRIORITY;
  OS_PRINTF("%s %d dm_para.task_prio = %d\n",__FUNCTION__,__LINE__, dm_para.task_prio);
  dm_para.task_stack_size = MDL_DM_MONITOR_TASK_STKSIZE;
  dm_para.open_monitor = TRUE;
  dm_para.para_size = sizeof(dm_v2_init_para_t);
  dm_para.use_mutex = TRUE;
  dm_para.mutex_prio = 1;
  dm_para.test_mode = FALSE;
  OS_PRINTK("dm_para.flash_base_addr  :0x%x \n",dm_para.flash_base_addr );

  dm_init_v2(&dm_para);
  OS_PRINTF("set header [0x%08x]\n",DM_BOOTER_START_ADDR);
  dm_set_header(class_get_handle_by_id(DM_CLASS_ID), DM_BOOTER_START_ADDR);
  OS_PRINTF("set header [0x%08x]\n",DM_HDR_START_ADDR);
  dm_set_header(class_get_handle_by_id(DM_CLASS_ID), DM_HDR_START_ADDR);
  dm_app_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), DM_APP_BLOCK_ID)
                           - get_flash_addr();
  OS_PRINTF("set header [0x%08x]\n",dm_app_addr);
  dm_set_header(class_get_handle_by_id(DM_CLASS_ID),dm_app_addr);

  //load customer hw config
  //dm_load_customer_hw_cfg();
  return SUCCESS;
}
Esempio n. 9
0
void on_cas_init(void)
{
  u32 cas_id = 0;
  cas_adapter_cfg_t cas_cfg = {0};
  cas_module_cfg_t cas_module_cfg = {0};
  p_ca_buffer = mtos_malloc(CA_DATA_SIZE);
  MT_ASSERT(NULL != p_ca_buffer);
  memset(p_ca_buffer, 0, CA_DATA_SIZE);
  //config cas adapter
  cas_cfg.p_smc_drv[0] = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_SMC);

  cas_cfg.slot_num = 1;

#if 1
  cas_cfg.p_task_stack = mtos_malloc(4096);
  cas_cfg.stack_size = 4096;
  cas_cfg.task_prio = DRV_CAS_ADAPTER_TASK_PRIORITY;
#ifndef WIN32
  cas_init(&cas_cfg);
  cas_module_cfg.p_dmx_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_PTI);
  cas_module_cfg.nvram_read = nvram_read;
  cas_module_cfg.nvram_write = nvram_write;
  cas_module_cfg.flash_start_adr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), CADATA_BLOCK_ID)
      - get_flash_addr();
  OS_PRINTF("set ca addr is 0x%x\n", cas_module_cfg.flash_start_adr);
  cas_module_cfg.flash_size = CA_DATA_SIZE;
  cas_module_cfg.task_prio = DRV_CAS_MODUL_TASK_PRIORITY_START;
  cas_module_cfg.end_task_prio = DRV_CAS_MODUL_TASK_PRIORITY_END;
  cas_module_cfg.queue_task_prio = CUSTOMER_TASK_PRIORITY;

OS_PRINTF("####debug cas_tr_attach 0\n");
  cas_tr_attach(&cas_module_cfg, &cas_id);
OS_PRINTF("####debug cas_tr_attach\n");
  cas_module_init(AP_CAS_ID);
  OS_PRINTF("####debug cas_module_init\n");
#endif
#endif

  register_monitor_table();

}
Esempio n. 10
0
static RET_CODE nvram_read(u32 offset, u8 *p_buf, u32 *size)
{
  charsto_device_t *p_charsto_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_CHARSTO);
  RET_CODE ret = SUCCESS;
  handle_t dm_handle = class_get_handle_by_id(DM_CLASS_ID);
  u32 base_addr =  dm_get_block_addr(dm_handle, CADATA_BLOCK_ID) - get_flash_addr();

  mtos_task_lock();

  MT_ASSERT(dm_handle != NULL);

  ret = charsto_read(p_charsto_dev, base_addr + offset, p_buf, *size);
  if (ret != SUCCESS)
  {
    mtos_task_unlock();
    OS_PRINTF("read error\n");
    return ERR_FAILURE;
  }
  OS_PRINTF("nvram_read success!\n");

  mtos_task_unlock();
  return SUCCESS;
}
Esempio n. 11
0
BOOL get_dm_block_real_file_info(u8 block_id,dmh_block_info_t *block_info)
{
  void *p_dev = NULL;
  u32 block_addr = 0;
  u32 block_size = 0;
  u32 wr_addr = 0;
  dmh_block_info_t real_dm_info = {0};
  RET_CODE ret = ERR_NOFEATURE;
  dmh_block_info_t block_dm_info = {0};
  if(dm_get_block_header(class_get_handle_by_id(DM_CLASS_ID),block_id,&block_dm_info) == DM_FAIL)
  {
    return -1;
  }
  if(block_dm_info.type != BLOCK_TYPE_RO)
  {
    memcpy(block_info,&block_dm_info,sizeof(dmh_block_info_t));
    return 0;
  }
  p_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_CHARSTO);
  MT_ASSERT(NULL != p_dev);
  block_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), block_id);
  if(block_addr == 0)
    {
       return -1;
    }
  block_addr = block_addr - get_flash_addr();
  block_size = dm_get_block_size(class_get_handle_by_id(DM_CLASS_ID),block_id);
  wr_addr = block_addr + block_size - sizeof(dmh_block_info_t);
  ret = charsto_read(p_dev,wr_addr,(u8 *)&real_dm_info,sizeof(dmh_block_info_t));
  if((ret == SUCCESS) && (block_id == real_dm_info.id))
    {
        memcpy(block_info,&real_dm_info,sizeof(dmh_block_info_t));
        return 0;
    }
  return -1;
}
void on_cas_init(void)
{
    u32 cas_id = 0;
    cas_adapter_cfg_t cas_cfg = {0};
    cas_module_cfg_t cas_module_cfg = {0};
    p_ca_buffer = mtos_malloc(CA_DATA_SIZE);
    MT_ASSERT(NULL != p_ca_buffer);
    memset(p_ca_buffer, 0, CA_DATA_SIZE);
    //config cas adapter
    cas_cfg.p_smc_drv[0] = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_SMC);

    cas_cfg.slot_num = 1;

    cas_cfg.p_task_stack = mtos_malloc(4096);
    cas_cfg.stack_size = 4096;
    cas_cfg.task_prio = DRV_CAS_ADAPTER_TASK_PRIORITY;
#ifndef WIN32
    cas_init(&cas_cfg);
#endif
    cas_module_cfg.p_dmx_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_PTI);
    cas_module_cfg.nvram_read = NULL;
    cas_module_cfg.nvram_write = NULL;
    cas_module_cfg.flash_start_adr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), CADATA_BLOCK_ID)
                                     - get_flash_addr();
    OS_PRINTF("set ca addr is 0x%x\n", cas_module_cfg.flash_start_adr);
    cas_module_cfg.flash_size = CA_DATA_SIZE;
    cas_module_cfg.task_prio = MDL_CAS_TASK_PRIO_BEGIN;                            //need fixed
    cas_module_cfg.end_task_prio = MDL_CAS_TASK_PRIO_END;                    //need fixed
    cas_module_cfg.machine_serial_get = NULL;
    cas_module_cfg.query_check = force_channel_pg_check;
#ifndef WIN32
    cas_ds_attach_v5(&cas_module_cfg, &cas_id);
    cas_module_init(CAS_ID_DS);
#endif
    register_monitor_table();
}
RET_CODE check_is_msg_serial_num(u8 *p_uni_str)
{
 charsto_device_t *p_charsto_dev = dev_find_identifier(NULL, DEV_IDT_TYPE, SYS_DEV_TYPE_CHARSTO);

  //dm_v2_init_para_t dm_para = { 0 };
  u32 indentity_block_addr;
  u32 rw_addr;
  u8 *p_buffer = mtos_malloc(CHARSTO_SECTOR_SIZE);
  charsto_prot_status_t st_set = {0};
  charsto_prot_status_t st_old = {0};

  memset(p_buffer, 0, CHARSTO_SECTOR_SIZE);
  //unprotect
  dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_GET_STATUS, (u32)&st_old);
  st_set.prt_t = PRT_UNPROT_ALL;
  dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_SET_STATUS, (u32)&st_set);

  //if(charsto_unprotect_all(p_charsto_dev) == SUCCESS)
  {
    indentity_block_addr = dm_get_block_addr(class_get_handle_by_id(DM_CLASS_ID), IDENTITY_BLOCK_ID) - get_flash_addr();
    rw_addr = indentity_block_addr / CHARSTO_SECTOR_SIZE * CHARSTO_SECTOR_SIZE;
    if(charsto_read(p_charsto_dev, rw_addr, p_buffer, CHARSTO_SECTOR_SIZE) == SUCCESS)
    {
      memcpy(p_buffer+ (indentity_block_addr - rw_addr), p_uni_str, 64);
      if(charsto_erase(p_charsto_dev, rw_addr, 1) == SUCCESS)
      {
        charsto_writeonly(p_charsto_dev, rw_addr, p_buffer, CHARSTO_SECTOR_SIZE);
      }
      else
      {
	  OS_PRINTF("charsto erase fail\n");
	  return ERR_FAILURE;
	}
    }
    else
    {
	OS_PRINTF("charsto_read fail\n");
	return ERR_FAILURE;
    }
  }
  //restore
  dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_SET_STATUS, (u32)&st_old);

  mtos_free(p_buffer);
  return SUCCESS;

}
Esempio n. 14
0
static RET_CODE nvram_write(u32 offset, u8 *p_buf, u32 size)
{
  charsto_device_t *p_charsto_dev = dev_find_identifier(NULL, DEV_IDT_TYPE,
    SYS_DEV_TYPE_CHARSTO);
  RET_CODE ret = SUCCESS;
  handle_t dm_handle = class_get_handle_by_id(DM_CLASS_ID);
  u32 base_addr = dm_get_block_addr(dm_handle, CADATA_BLOCK_ID) - get_flash_addr();
  u32 start_addr = 0;
  u32 padding = 0;
  u32 wrlen = 0;

  mtos_task_lock();

  MT_ASSERT(dm_handle != NULL);
  OS_PRINTF("ca write addr[0x%x], size[0x%x]\n", offset, size);

  start_addr = ((base_addr + offset) / CHARSTO_SECTOR_SIZE) * CHARSTO_SECTOR_SIZE;
  padding = (base_addr + offset) % CHARSTO_SECTOR_SIZE;

  while(size)
  {
    if (size > (CHARSTO_SECTOR_SIZE - padding))
    {
      wrlen = CHARSTO_SECTOR_SIZE - padding;
    }
    else
    {
      wrlen = size;
    }
    //read sector data
    ret = charsto_read(p_charsto_dev, start_addr, p_ca_buffer, CHARSTO_SECTOR_SIZE);
    if (ret != SUCCESS)
    {
      mtos_task_unlock();
      OS_PRINTF("write/read error1\n");
      return ERR_FAILURE;
    }
    memcpy(p_ca_buffer + padding, p_buf, wrlen);
    //charsto_unprotect_all(p_charsto_dev);
    ret = charsto_erase(p_charsto_dev, start_addr, 1);
    //charsto_protect_all(p_charsto_dev);
    if (ret != SUCCESS)
    {
      mtos_task_unlock();
      OS_PRINTF("write/erase error2\n");
      return ERR_FAILURE;
    }
    //charsto_unprotect_all(p_charsto_dev);
    charsto_writeonly(p_charsto_dev, start_addr, p_ca_buffer, CHARSTO_SECTOR_SIZE);
    //charsto_protect_all(p_charsto_dev);
    if (ret != SUCCESS)
    {
      mtos_task_unlock();
      OS_PRINTF("write error3\n");
      return ERR_FAILURE;
    }
    start_addr += CHARSTO_SECTOR_SIZE;
    padding = 0;
    p_buf += wrlen;
    size -= wrlen;
  }
  OS_PRINTF("nvram_write success!\n");

  mtos_task_unlock();
  return SUCCESS;

}
static RET_CODE nvram_ad_logo_write(ST_DSAD_AV_SHOW_INFO * av_show_info)
{
  RET_CODE ret = SUCCESS;
  handle_t dm_handle = class_get_handle_by_id(DM_CLASS_ID);
  charsto_device_t *p_charsto_dev = dev_find_identifier(NULL, DEV_IDT_TYPE,SYS_DEV_TYPE_CHARSTO);
  u32 base_addr = dm_get_block_addr(dm_handle, START_LOGO_BLOCK_ID) - get_flash_addr();
  u32 block_size = 0;
  u32 wr_addr = 0;
  u8 *p_data = NULL;
  u32 size = 0;

  //lint -save -e64
  charsto_prot_status_t st_old={0};
  charsto_prot_status_t st_set={0};
  dmh_block_info_t real_dm_info={0};
  //lint -restore
  u8 logo_head[4] = {0}; // logo data size; without head size.
  
  u32 head_size = sizeof(logo_head);
  block_size = dm_get_block_size(dm_handle, START_LOGO_BLOCK_ID);

  size = av_show_info->uiDataLen;
  p_data = av_show_info->pucAvData;
  if(base_addr == 0 || block_size == 0 || (size + head_size) > block_size)
  {
    OS_PRINTF("Error!,blocksize:%d,size:%d\n",block_size, size);
    return ERR_FAILURE;
  }
    
  wr_addr = base_addr + block_size - sizeof(dmh_block_info_t);

  ret = charsto_read(p_charsto_dev,wr_addr,(u8 *)&real_dm_info,sizeof(dmh_block_info_t));

  if(ret == SUCCESS)
  {
    real_dm_info.size = size;
  }
  else
  {
    OS_PRINTF("Error!\n");
    return ERR_FAILURE;
  }

  dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_GET_STATUS, (u32)&st_old);
  //unprotect
  st_set.prt_t = PRT_UNPROT_ALL;
  dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_SET_STATUS, (u32)&st_set);

  ret = charsto_erase(p_charsto_dev, base_addr, block_size/CHARSTO_SECTOR_SIZE);
  MT_ASSERT(ret == SUCCESS);

  logo_head[0] = SYS_GET_BYTE3(size);
  logo_head[1] = SYS_GET_BYTE2(size); 
  logo_head[2] = SYS_GET_BYTE1(size); 
  logo_head[3] = SYS_GET_BYTE0(size); 
  
  ret = charsto_writeonly(p_charsto_dev, base_addr, logo_head, head_size);
  ret = charsto_writeonly(p_charsto_dev, base_addr+head_size, p_data, size);
  MT_ASSERT(ret == SUCCESS);
  //write dmh_block_info_t infomation for OTA upgrade, the end of block.
  ret = charsto_writeonly(p_charsto_dev, wr_addr, (u8 *)&real_dm_info, sizeof(dmh_block_info_t));
  OS_PRINTF("!!!!!!!!!!wr_addr=0x%x,sizeof(dmh_block_info_t)=0x%x\n",wr_addr,sizeof(dmh_block_info_t));
  MT_ASSERT(ret == SUCCESS);
  //restore
  ret = dev_io_ctrl(p_charsto_dev, CHARSTO_IOCTRL_SET_STATUS, (u32)&st_old);
  MT_ASSERT(ret == SUCCESS);
  OS_PRINTF("AD nvram_write success !! \n");
  
  return SUCCESS;
//lint -save -e550
}
Esempio n. 16
0
/***********************************************************************
	This is the main controller loop.
	sequences of operations:
		- reads from CAN bus or serial port 1.
		- reads encoders (or ADC).
		- computes the control value (a PID in this version).
		- checks limits and other errors.
		- sets PWM
		- does extra functions (e.g. communicate with neighboring cards).
 ***********************************************************************/
void main(void)
{

	Int32 PWMoutput [JN];
	Int32 PWMoutput_old [JN];
	byte i=0;
	byte wi=0;
	byte k=0;
	UInt16 *value=0;
	Int32 t1val=0;
	Int32 PID_R= 2;
	Int32 kpp=1;
	Int16 current_turn=0;
	Int16 print_number=0;
	Int16 real_pos=0;
	byte first_step=0;

#if (VERSION == 0x0351)
	#define winSizeMax 32
	#define initialWindowSize 4
#else
	#define winSizeMax 32
	#define initialWindowSize 30
#endif

	byte divJntPos[JN]=INIT_ARRAY(initialWindowSize-1);
	byte divJntVel[JN]=INIT_ARRAY(initialWindowSize-1);
	byte divMotPos[JN]=INIT_ARRAY(initialWindowSize-1);
	byte divMotVel[JN]=INIT_ARRAY(initialWindowSize-1);
	byte headJntPos[JN]=INIT_ARRAY(0);  //current joint pos
	byte tailJntPos[JN]=INIT_ARRAY(0); 
	byte headJntVel[JN]=INIT_ARRAY(0);  //current joint vel
	byte tailJntVel[JN]=INIT_ARRAY(0); 
	byte headMotPos[JN]=INIT_ARRAY(0);  //current motor pos
	byte tailMotPos[JN]=INIT_ARRAY(0); 
	byte headMotVel[JN]=INIT_ARRAY(0);  //current motor vel
	byte tailMotVel[JN]=INIT_ARRAY(0); 
	Int32 jntPosWindow[winSizeMax][JN]; //max window size = winSizeMax
	Int32 jntVelWindow[winSizeMax][JN]; //max window size = winSizeMax
	Int32 motPosWindow[winSizeMax][JN]; //max window size = winSizeMax
	Int32 motVelWindow[winSizeMax][JN]; //max window size = winSizeMax
	Int16 _safeband[JN];	//it is a value for reducing the JOINT limit of 2*_safeband [tick encoder]
#ifdef TEMPERATURE_SENSOR
	byte   TempSensCount1 = 0;
	UInt32 TempSensCount2 = 0;
	byte   temp_sens_status=0;
	overtemp[0]=0;
	overtemp[1]=0;
	errortemp[0]=0;
	errortemp[1]=0;

#endif
	
	/* gets the address of flash memory from the linker */
	_flash_addr = get_flash_addr();
		
	/* enable interrupts */
	setReg(SYS_CNTL, 0);
	
	// IPL channels from 0 to 6 enabled
	// external interrupts IRQA and IRQB disabled
	setRegBits(IPR, 0xFE00); 

	// enable FAULT
	__ENIGROUP (61, 3); 
	#if (VERSION == 0x0254)
	#else
	__ENIGROUP (60, 3);
	#endif	
	// enable SCI
	__ENIGROUP (52, 4);
	__ENIGROUP (53, 4);
	__ENIGROUP (50, 4);
	__ENIGROUP (51, 4);
	
    // enable data flash
	__ENIGROUP (13, 4);
	
	// enable CAN	
	__ENIGROUP (14, 6);
	__ENIGROUP (15, 6);
	__ENIGROUP (16, 6);
	__ENIGROUP (17, 6);
	
	// enable ADCA/ADCB
	__ENIGROUP (55, 6);
	__ENIGROUP (54, 6);
	
	//enable PWM reload 
	__ENIGROUP (59, 7); // PMWA
	
	#if (VERSION == 0x0254)
	#else	
	__ENIGROUP (58, 7); // PWMB
	#endif
	// enable timers
	// TIMER_A
	__ENIGROUP (45, 7); //Timer for the encoder commutation if used
    __ENIGROUP (44, 7); //
	__ENIGROUP (43, 7); //
	__ENIGROUP (42, 4); //TI1 1ms delay main loop
	// TIMER_B

	__ENIGROUP (41, 7); //
	__ENIGROUP (40, 7); //
	__ENIGROUP (39, 7); //
	__ENIGROUP (38, 7);

	// TIMER_C
	__ENIGROUP (37, 1); 
	__ENIGROUP (36, 1);
	__ENIGROUP (35, 1);
	__ENIGROUP (34, 1);
	// TIMER_D
	__ENIGROUP (33, 7); //1ms delay duty cycle
	__ENIGROUP (32, 1);
	__ENIGROUP (31, 1);
	__ENIGROUP (30, 1);

	__EI();
	
	flash_interface_init  (JN);			
	readFromFlash (_flash_addr);  
	if (_version==_flash_version)
	{
		
	}
	else
	{
		writeToFlash(_flash_addr);
	}
	__DI();
	
	#warning "debug"//   ;
	
	__EI();

	init_leds  			  ();
	
	#if (VERSION == 0x0254)
	
	Init_Brushless_Comm	  (1,HALL); 
  	
  	#else 

	Init_Brushless_Comm	  (JN,HALL); 
  	
  	#endif
	can_interface_init    (JN);	 
    init_strain ();


    init_position_abs_ssi ();
#if VERSION ==0x0257 
    init_relative_position_abs_ssi();
#endif 
 
    init_faults           (true,true,true);	 
    
    init_position_encoder ();


	TI1_init 			  ();

//variable init	
	mainLoopOVF=0;
	_count=0;
	
	for(i=0;i<JN;i++)
	{
	_received_pid[i].rec_pid=0;
	}
	
	BUS_OFF=false;
 	#warning "debug"//   ;
	
	//__EI();

	  
//	print_version ();
	
	/* initialization */
	for (i=0; i<JN; i++) _calibrated[i] = false;
	
	/* reset trajectory generation */
	for (i=0; i<JN; i++) abort_trajectory (i, 0);
	
	
	///////////////////////////////////////
	// reset of the ABS_SSI
	// this is needed because the AS5045 gives the first value wrong !!!
    for (i=0; i<JN; i++)	_position[i]=(Int32) Filter_Bit(get_position_abs_ssi(i));
    for (i=0; i<JN; i++)    _max_real_position[i]=Filter_Bit(4095);
 	
	//////////////////////////////////////
	
	/* initialize speed and acceleration to zero (useful later on) */
	for (i=0; i<JN; i++) _position_old[i] = 0;
	for (i=0; i<JN; i++) _speed[i] = 0;
	for (i=0; i<JN; i++) _accel[i] = 0;
	for (i=0; i<JN; i++) _safeband[i] =5; //5 ticks => 1 grado di AEA.
	for (i=0; i<JN; i++) PWMoutput [i] = PWMoutput_old[i] = 0;
	
	/* reset the recursive windows for storage of position and velocity data */
	/* (for velocity and position estimates) */
	for(i=0;i<JN;i++)
	{
		for(wi=0;wi<winSizeMax;wi++)
		{
			jntPosWindow[wi][i]=_position[i];	
			jntVelWindow[wi][i]=0;
			motPosWindow[wi][i]=0;	
			motVelWindow[wi][i]=0;
		}
	}
	
	//set_relative_position_abs_ssi(1,get_absolute_real_position_abs_ssi(1));
	/* main control loop */
	for(_counter = 0;; _counter ++) 
	{
		if (_counter >= CAN_SYNCHRO_STEPS) _counter = 0;
		led3_on
		while (_wait);
		_count=0;
		led3_off
		
// BUS_OFF check
		if (getCanBusOffstatus() )
		{
			#ifdef DEBUG_CAN_MSG
				can_printf("DISABLE BUS OFF");
			#endif	
			for (i=0; i<JN; i++) put_motor_in_fault(i);
			led1_off
		}
		else
			led1_on

// READING CAN MESSAGES
		can_interface();

		for (i=0; i<JN; i++)
		if (_pad_enabled[i]==false && _control_mode[i]!=MODE_HW_FAULT) _control_mode[i]=MODE_IDLE;		
	
	
	    //Position calculation
	    // This is used to have a shift of the zero-cross out of the 
	    // joint workspace
	    //
	    // max_real_position is the limit of the joint starting from 
	    // 4095 and going to decrease this number without zero-cross
	    // untill the joint limit is reached
#if    VERSION == 0x0257 
		_position_old[0]=_position[0]; 
		if(get_error_abs_ssi(0)==ERR_OK)
			_position[0]=Filter_Bit (get_position_abs_ssi(0));
    	_position_old[1]=_position[1];
		if(get_error_abs_ssi(1)==ERR_OK) 
			_position[1]=Filter_Bit (get_position_abs_ssi(1));		 
#else
	 	for (i=0; i<JN; i++) 
		{
		_position_old[i]=_position[i];
		if(get_error_abs_ssi(i)==ERR_OK)
		_position[i]=Filter_Bit (get_position_abs_ssi(i));
		
		}
#endif 

		// get_commutations() is used to read the incremental encoder of the motors.
		// the variable _motor_position is then used to estimate the rotor speed and
		// compensate the back-EMF of the motor.
		for (i=0; i<JN; i++) _motor_position[i]=get_position_encoder(i);//get_commutations(i);


///////////////////////////////////////////DEBUG////////////
#if (VERSION !=0x0254)
	    for (i=0; i<JN; i++) 
		{		
		   if (get_error_abs_ssi(i)==ERR_ABS_SSI)
		   {
				put_motor_in_fault(i);	
				#ifdef DEBUG_CAN_MSG
		    	can_printf("ABS error %d",i);	
				#endif
		   }				
		}  
#endif
	
#if (VERSION ==0x0254)
		   if (get_error_abs_ssi(0)==ERR_ABS_SSI)
		   {
				put_motor_in_fault(0);
				#ifdef DEBUG_CAN_MSG
		    	can_printf("ABS error %d",0);	
				#endif
		   }	
					 
#endif	


 //DO NOTHING


		// decoupling the position	 	
		decouple_positions();
		

				/* velocity and acceleration estimators */
		{	
			for (i=0; i<JN; i++)
			{	
				//joint velocity estimator
				tailJntPos[i]=headJntPos[i]+(winSizeMax-divJntPos[i]); if(tailJntPos[i]>=winSizeMax) tailJntPos[i]=tailJntPos[i]%winSizeMax;			
				_speed_old[i] = _speed[i];
				jntPosWindow[headJntPos[i]][i]=_position[i];
				_speed[i] = (Int32) (((jntPosWindow[headJntPos[i]][i] - jntPosWindow[tailJntPos[i]][i] ))<<_jntVel_est_shift[i]);
			//	_speed[i] <<= _jntVel_est_shift[i];
				_speed[i] = (Int32)(_speed[i]) / divJntPos[i];
				headJntPos[i]=headJntPos[i]+1; if(headJntPos[i]>=winSizeMax) headJntPos[i]=0;
/*
				//joint acceleration estimator
				tailJntVel[i]=headJntVel[i]+(winSizeMax-divJntVel[i]); if(tailJntVel[i]>=winSizeMax) tailJntVel[i]=tailJntVel[i]%winSizeMax;			
				_accel_old[i] = _accel[i];
				jntVelWindow[headJntVel[i]][i]=_speed[i];
				_accel[i] = ((jntVelWindow[headJntVel[i]][i] - jntVelWindow[tailJntVel[i]][i] ));
				_accel[i] << _jntAcc_est_shift[i];
				_accel[i] = (Int32)(_accel[i]) / divJntVel[i];
				headJntVel[i]=headJntVel[i]+1; if(headJntVel[i]>=winSizeMax) headJntVel[i]=0;
*/				
				//motor velocity estimator
				tailMotPos[i]=headMotPos[i]+(winSizeMax-divMotPos[i]); if(tailMotPos[i]>=winSizeMax) tailMotPos[i]=tailMotPos[i]%winSizeMax;			
				_motor_speed_old[i] = _motor_speed[i];
				motPosWindow[headMotPos[i]][i]=_motor_position[i];
				_motor_speed[i] = ((motPosWindow[headMotPos[i]][i] - motPosWindow[tailMotPos[i]][i] ));
				_motor_speed[i] <<= _motVel_est_shift[i];
				_motor_speed[i] = (_motor_speed[i]) / divMotPos[i];
				headMotPos[i]=headMotPos[i]+1; if(headMotPos[i]>=winSizeMax) headMotPos[i]=0;				
			}
		}
		


					
		/* in position? */
#if (VERSION != 0x0254)
		for (i=0; i<JN; i++) _in_position[i] = check_in_position(i); 
#else
		_in_position[0] = check_in_position(0);
#endif
				
		/* in reference configuration for calibration? */
		//for (i=0; i<JN; i++) check_in_position_calib(i); 

	
//******************************************* POSITION LIMIT CHECK ***************************/
		for (i=0; i<JN; i++)  check_range(i, _safeband[i], PWMoutput);

//******************************************* COMPUTES CONTROLS *****************************/

		//FT sensor watchdog update 
		for (i=0; i<STRAIN_MAX; i++) 
			if (_strain_wtd[i]>0) _strain_wtd[i]--;
			
		for (i=0; i<JN; i++) 
		{
			//computing the PWM value (PID)
			PWMoutput[i] = compute_pwm(i);

			// PWM filtering in torque control if there is no bemf compensation
			#if (VERSION != 0x0351)
			if (_control_mode[i] == MODE_TORQUE ||
			 	_control_mode[i] == MODE_IMPEDANCE_POS ||
			 	_control_mode[i] == MODE_IMPEDANCE_VEL)
				{
					if (_useFilter[i] == 3) PWMoutput[i] = lpf_ord1_3hz (PWMoutput[i], i);
				}	
			// saving the PWM value before the decoupling					
			_bfc_PWMoutput[i] = PWMoutput_old[i] = PWMoutput[i];

			// applying the saturation to the PWM
			if      (_bfc_PWMoutput[i] < -MAX_DUTY) _bfc_PWMoutput[i]=-MAX_DUTY;
			else if (_bfc_PWMoutput[i] > MAX_DUTY)  _bfc_PWMoutput[i]= MAX_DUTY;
			#endif //(VERSION != 0x0351)			
		}

        //decouple PWM	
		decouple_dutycycle(PWMoutput);
		
//******************************************* SATURATES CONTROLS ***************************/                
		/* back emf compensation + controls saturation (if necessary) */
		for (i=0; i<JN; i++)
		{
			if (_control_mode[i] == MODE_TORQUE ||
				_control_mode[i] == MODE_IMPEDANCE_POS ||
				_control_mode[i] == MODE_IMPEDANCE_VEL)
			{
				#if (VERSION != 0x0351)
				// Back emf compensation			
			
				//PWMoutput[i]+=compensate_bemf(i, _comm_speed[i]); //use the motor speed
				PWMoutput[i]+=compensate_bemf(i, _speed[i]); //use the joint speed
				
				//add the coulomb friction compensation term
				if (_kstp_torque[i] != 0 ||
				    _kstn_torque[i] != 0)
				//PWMoutput[i]+=compensate_friction(i, _comm_speed[i]); //use the motor speed
				PWMoutput[i]+=compensate_friction(i, _speed[i]); //use the joint speed
				
				// Protection for joints out of the admissible range during force control
				check_range_torque(i, _safeband[i], PWMoutput);
				// PWM saturation
				ENFORCE_LIMITS	(i,PWMoutput[i], _pid_limit_torque[i] );
				#else  //(VERSION != 0x0351)
				ENFORCE_LIMITS	(i,PWMoutput[i], _pid_limit[i] );
				#endif //(VERSION != 0x0351)
			}
			else
			{
				ENFORCE_LIMITS	(i,PWMoutput[i], _pid_limit[i] );
			}			
			if      (_pid[i] < -MAX_DUTY) _pid[i]=-MAX_DUTY;
			else if (_pid[i] > MAX_DUTY)  _pid[i]= MAX_DUTY;
		}
				
		/* generate PWM */		
		for (i=0; i<JN; i++)
		{
			if (!mode_is_idle(i)) {PWM_generate(i,_pid[i]);}			
		}
	
		/* Check Current done in T1 */

		/* do extra functions, communicate, etc. */
		//send broadcast data	
		can_send_broadcast();

		//send additional debug information
		//can_send_broadcast_debug(1,1);
	 
/***********************************************************************
// Check Current is made here
/***********************************************************************/

#if (VERSION != 0x0254)
		for (i=0; i<JN; i++)
#else
		for (i=0; i<1; i++)
#endif  
		{
			if ((get_current(i)>=25000) || (get_current(i)<=-25000))
			{
				put_motor_in_fault(i);	
				highcurrent[i]=true;
				#ifdef DEBUG_CAN_MSG
				can_printf("j%d curr %f",i,get_current(i));
				#endif
			}
			check_current(i, (_pid[i] > 0));		
			compute_i2t(i);
			if (_filt_current[i] > MAX_I2T_CURRENT)
			{
				put_motor_in_fault(i);	
				highcurrent[i]=true;
				#ifdef DEBUG_CAN_MSG
				can_printf("j%d filtcurr %f",i,_filt_current[i]);
				#endif	
			}			
		}

//	Check for the MAIN LOOP duration
 
			
//		t1val= (UInt16) TI1_getCounter(); 	
		if (	_count>0)
		{	
			mainLoopOVF=1;
			_count=0;
		}


		
		/* tells that the control cycle is completed */
		
		_wait = true;		
		
	} /* end for(;;) */