#include #include #include "plan.h" #include "buffer.h" #include "button.h" #include "display.h" #include uint8_t isCC = 0 ; const uint8_t isTag = 0 ; //是否含识读标签 unsigned char isn = 1; //是否新大屏 unsigned char remote_sumweight = 0; //远程是否包含重量 unsigned char iscowweight = 0; //是否奶牛秤 unsigned char eid[10]; //电子耳标,0为长度 uint8_t XbeeConst_DeviceAddress = 0x01; uint8_t XbeeConst_NetAddress = 0x00; uint8_t XbeeConst_UseAPI = 0x01; uint8_t WeightConst_TQ = 0x07;//0x05; uint8_t WeightConst_BLE = 0; uint8_t WeightConst_ChanCheShu = 0x02; uint8_t WeightConst_SBType = 0x04; int16_t WeightConst_WeightBegin = 0; //按键开始重量 uint8_t ad_Percent= 0x00; // 7, 校正重量,1字节 unsigned int ad_Maxval= 0x00007530; // 8, 最大称量,4字节 uint8_t ad_FS= 0x04; // 12, 滤波深度,1字节 uint8_t ad_Point= 0x00; // 13, 小数点, 1字节 uint8_t ad_Inteval= 0x02; // 14, 分度值, 1字节 float ad_Spanz = 0.9; // 15, 分度内码数, 4字节 unsigned int ad_Zero = 0x00000000; // 19, 真零内码, 4字节 unsigned int ad_Tare = 0x00002320; // 23, 皮零内码, 4字节 static uint32_t read_key = 1; static uint32_t read_plan = 1; static uint32_t read_weight = 1; static struct fdb_default_kv_node default_kv_table[] = { {"CH", &XbeeConst_DeviceAddress, sizeof(XbeeConst_DeviceAddress)}, // 1, 车号, 1字节 {"TQ", &WeightConst_TQ, sizeof(WeightConst_TQ)}, // 2, 提取方式,1字节 {"PM", &WeightConst_SBType, sizeof(WeightConst_SBType)}, // 3, 屏幕类型,1字节 6、海安 7长屏铲车 8 新彩屏 {"WL", &XbeeConst_NetAddress, sizeof(XbeeConst_NetAddress)}, // 4, 网络地址,1字节 {"API", &XbeeConst_UseAPI, sizeof(XbeeConst_UseAPI)}, // 5, 使用API,1字节 {"CC", &WeightConst_ChanCheShu, sizeof(WeightConst_ChanCheShu)}, // 6, TMR数量,1字节 {"BLE", &WeightConst_BLE, sizeof(WeightConst_BLE)}, // 27, 皮零内码, 4字节 /////////////////////////////////////////////////////////////////////////////////////// {"ad_Percent", &ad_Percent, sizeof(ad_Percent)}, // 7, 校正重量,1字节 {"ad_Maxval", &ad_Maxval, sizeof(ad_Maxval)}, // 8, 最大称量,4字节 {"ad_FS", &ad_FS, sizeof(ad_FS)}, // 12, 滤波深度,1字节 {"ad_Point", &ad_Point, sizeof(ad_Point)}, // 13, 小数点, 1字节 {"ad_Inteval", &ad_Inteval, sizeof(ad_Inteval)}, // 14, 分度值, 1字节 {"ad_Spanz", &ad_Spanz, sizeof(ad_Spanz)}, // 15, 分度内码数, 4字节 {"ad_Zero", &ad_Zero, sizeof(ad_Zero)}, // 19, 真零内码, 4字节 {"ad_Tare", &ad_Tare, sizeof(ad_Tare)}, // 23, 皮零内码, 4字节 {"read_key", &read_key, sizeof(read_key)}, {"read_plan", &read_plan, sizeof(read_plan)}, {"read_weight", &read_weight, sizeof(read_weight)}, {"beginweight", &WeightConst_WeightBegin, sizeof(WeightConst_WeightBegin)}, {"begintime", &TimeConst, sizeof(TimeConst)}, {"completeorder", &CompleteTarget_order, sizeof(CompleteTarget_order)}, {"TimeConst", &TimeConst, sizeof(TimeConst)}, }; #define FDB_LOG_TAG "[main]" struct fdb_tsdb ts_keydb = { 0 }; struct fdb_tsdb ts_plandb = { 0 }; struct fdb_tsdb ts_weightdb = { 0 }; struct fdb_kvdb kvdb = { 0 }; static uint32_t ts_keyTime = 0; static uint32_t ts_planTime = 0; static uint32_t ts_weightTime = 0; rt_sem_t kv_db_lock; static void lock(fdb_db_t db) { rt_sem_take(kv_db_lock, RT_WAITING_FOREVER); __disable_irq(); } static void unlock(fdb_db_t db) { rt_sem_release(kv_db_lock); __enable_irq(); } static fdb_time_t get_keydbtime(void) { return ++ts_keyTime; } void write_Flash(const char *key, const void *value_buf, size_t buf_len) { struct fdb_blob blob; fdb_kv_set_blob(&kvdb, key, fdb_blob_make(&blob, (void *)value_buf, buf_len)); } void reset_read_ts(const char key) { if (key == 'k'){ read_key = ts_keyTime+1; write_Flash("read_key", &read_key, sizeof(read_key)); }else if (key == 'p'){ read_plan = ts_planTime+1; write_Flash("read_plan", &read_plan, sizeof(read_plan)); // rt_kprintf("read_plan:%02X \n",read_plan); }else { read_weight = ts_weightTime+1; write_Flash("read_weight", &read_weight, sizeof(read_weight)); }; } void init_allflash(void) { // fdb_kv_set_default(&kvdb); fdb_tsl_clean(&ts_weightdb); fdb_tsl_clean(&ts_plandb); fdb_tsl_clean(&ts_keydb); ts_keyTime=0; ts_planTime=0; ts_weightTime=0; reset_read_ts('k'); reset_read_ts('p'); reset_read_ts('w'); } static fdb_time_t get_plandbtime(void) { return ++ts_planTime; } static fdb_time_t get_weightdbtime(void) { return ++ts_weightTime; } uint32_t tsdb_recordcount(const char key) { if (key== 'k'){ if (read_key > ts_keyTime || ts_keyTime == 0 ) return 0; else return ts_keyTime-read_key+1; } else if (key== 'p'){ if (read_plan > ts_planTime || ts_planTime == 0 ) return 0; else return ts_planTime-read_plan+1; } else if (read_weight > ts_weightTime || ts_weightTime == 0 ) return 0; else return ts_weightTime-read_weight+1; } static uint8_t foundF8 = 0; static bool query_f8_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; unsigned char buf[tsl->log_len]; fdb_tsdb_t db = arg; rt_memset(buf, 0, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &buf, tsl->log_len))); if ((buf[3]==0xf8 || buf[3]==0xE8) && tsl->status==FDB_TSL_WRITE) { foundF8 = 1; return true; } return false; //write_Flash("read_key", &ts_keyTime, sizeof(ts_keyTime)); } void findF8(void) { fdb_tsl_iter_by_time(&ts_keydb, read_key, 0xFFFFFFFF, query_f8_cb, &ts_keydb); } static uint8_t foundF4 = 0; static bool query_f4_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; unsigned char buf[tsl->log_len]; fdb_tsdb_t db = arg; rt_memset(buf, 0, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &buf, tsl->log_len))); if ((buf[3]==0xf4 || buf[3]==0xE4) && tsl->status==FDB_TSL_WRITE) { foundF4 = 1; return true; } return false; //write_Flash("read_key", &ts_keyTime, sizeof(ts_keyTime)); } void findF4(void) { fdb_tsl_iter_by_time(&ts_keydb, read_key, 0xFFFFFFFF, query_f4_cb, &ts_keydb); } static bool query_f12_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; unsigned char buf[tsl->log_len]; unsigned char len = 0; fdb_tsdb_t db = arg; if (tsl->log_len>40) len=40; else len=tsl->log_len; rt_memset(WeightConst_PlantempList, 0x20, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &buf, tsl->log_len))); rt_memcpy(WeightConst_PlantempList,buf, len); if (buf[3]==0x12 && tsl->status==FDB_TSL_WRITE) { WeightConst_Run = 1; rt_memset(WeightConst_product,0x20,40); rt_memset(WeightConst_feed,0x20,40); for (int i = 0; i <= buf[1]-10; i++) { WeightConst_product[i] = buf[i+4]; //产品名称 if (WeightConst_SBType==1||WeightConst_SBType==6) WeightConst_feed[i] = WeightConst_product[i]; //显示一秒牛舍 } plan_comp.Buffer[0] = buf[buf[1]-5+1]; //产品名称 plan_comp.Buffer[1] = buf[buf[1]-5]; //产品名称 for (int i = 2; i < 6; i++) plan_comp.Buffer[i] = buf[buf[1]-5+i]; //产品名称 } return false; } void findF12(void) { uint8_t i = 0; if (read_plan>50) i = read_plan-50; fdb_tsl_iter_by_time(&ts_plandb, i, read_plan, query_f12_cb, &ts_plandb); } static uint32_t foundkey = 0; static bool query_key_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; //unsigned char buf[tsl->log_len]; fdb_tsdb_t db = arg; rt_memset(XbeeConst_FTxBuf0, 0, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &XbeeConst_FTxBuf0, tsl->log_len))); for (int i=tsl->log_len; i>0; i--) { XbeeConst_FTxBuf0[i] = XbeeConst_FTxBuf0[i-1]; } XbeeConst_FTxBuf0[0] = tsl->log_len; if (tsl->status==FDB_TSL_WRITE) { foundkey = tsl->time; read_key = foundkey; return true; } return false; } uint32_t findkey(void) { foundkey = 0xFFFFFFFF; fdb_tsl_iter_by_time(&ts_keydb, read_key, 0xFFFFFFFF, query_key_cb, &ts_keydb); return foundkey; //return 0xFFFFFFFF; } void save_read_ts(const char key) { if (tsdb_recordcount(key)>0) { if (key == 'k'){ if (findkey()<0xFFFFFFFF){ if(XbeeConst_FrameNumLast == XbeeConst_FTxBuf0[XbeeConst_FTxBuf0[0]-1]){ read_key++; write_Flash("read_key", &read_key, sizeof(read_key)); } } }else if (key == 'p'){ read_plan++; write_Flash("read_plan", &read_plan, sizeof(read_plan)); // rt_kprintf("read_plan save_read_t:%02X \n",read_plan); }else { read_weight++; write_Flash("read_weight", &read_weight, sizeof(read_weight)); }; } } static uint32_t foundplan = 0; static bool query_plan_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; //unsigned char buf[tsl->log_len]; fdb_tsdb_t db = arg; rt_memset(WeightConst_PlantempList, 0, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &WeightConst_PlantempList, tsl->log_len))); if (tsl->status==FDB_TSL_WRITE) { foundplan = tsl->time; read_plan = tsl->time; return true; } return false; } uint32_t findplan(void) { foundplan = 0; // rt_kprintf("read_plan findplan:%02X \n",read_plan); fdb_tsl_iter_by_time(&ts_plandb, read_plan, 0xFFFFFFFF, query_plan_cb, &ts_plandb); return foundplan; } static uint8_t foundlastplan = 0; static bool query_lastplan_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; //unsigned char buf[tsl->log_len]; fdb_tsdb_t db = arg; rt_memset(WeightConst_PlantempList, 0, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &WeightConst_PlantempList, tsl->log_len))); if (tsl->status==FDB_TSL_WRITE) { if (WeightConst_PlantempList[3]==0x15) foundlastplan = WeightConst_PlantempList[WeightConst_PlantempList[1]-1]; return true; } return false; } uint32_t findlastplan(void) { foundlastplan = 0xF0; // rt_kprintf("read_plan findplan:%02X \n",read_plan); fdb_tsl_iter_by_time(&ts_plandb, ts_planTime, 0xFFFFFFFF, query_lastplan_cb, &ts_plandb); return foundlastplan; } static uint32_t foundNextplan = 0; static bool query_Nextplan_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; fdb_tsdb_t db = arg; uint8_t Nextfeedlength = 0; rt_memset(WeightConst_Nextfeed, 0x20, tsl->log_len); fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &WeightConst_Nextfeed, tsl->log_len))); if (tsl->status==FDB_TSL_WRITE) { foundNextplan = tsl->time; if (WeightConst_Nextfeed[3]==0x15) { Nextfeedlength = WeightConst_Nextfeed[1]; WeightConst_NextWeightTarget = WeightConst_Nextfeed[Nextfeedlength-6]<<8 ; //目标总量 WeightConst_NextWeightTarget = WeightConst_NextWeightTarget | WeightConst_Nextfeed[Nextfeedlength-5]; for (int i = 0; i <= Nextfeedlength-11; i++) WeightConst_Nextfeed[i] = WeightConst_Nextfeed[i+4]; for (int i = Nextfeedlength-11; i <= tsl->log_len; i++) WeightConst_Nextfeed[i] = 0x20; } return true; } return false; } uint32_t findNextplan(void) { foundNextplan = 0; fdb_tsl_iter_by_time(&ts_plandb, read_plan+1, 0xFFFFFFFF, query_Nextplan_cb, &ts_plandb); return foundNextplan; } static uint32_t foundweight = 0; static uint32_t read_weight_temp = 0; static bool query_weight_cb(fdb_tsl_t tsl, void *arg) { struct fdb_blob blob; unsigned char buf[7]; fdb_tsdb_t db = arg; fdb_blob_read((fdb_db_t) db, fdb_tsl_to_blob(tsl, fdb_blob_make(&blob, &buf, 7))); for (int i=7; i>0; i--) XbeeConst_FTxBuf0[4+foundweight*7+i] = buf[7-i]; read_weight_temp = tsl->time; foundweight++; return foundweight>3; } uint32_t findweight(void) { unsigned char CRCNum=0; foundweight = 0; read_weight_temp = read_weight; rt_memset(XbeeConst_FTxBuf0, 0, 0x22); fdb_tsl_iter_by_time(&ts_weightdb, read_weight, 0xFFFFFFFF, query_weight_cb, &ts_weightdb); if (foundweight>3){ XbeeConst_FTxBuf0[0] = 0x22; XbeeConst_FTxBuf0[1] = 0x7E; XbeeConst_FTxBuf0[2] = 0x20; XbeeConst_FTxBuf0[3] = XbeeConst_DeviceAddress; XbeeConst_FTxBuf0[4] = 0xF0; XbeeConst_FTxBuf0[33] = XbeeConst_FrameNum ++; for (int i=1; i< 34; i++) CRCNum+=XbeeConst_FTxBuf0[i]; XbeeConst_FTxBuf0[34] = 0xFF - CRCNum; read_weight = read_weight_temp; } return foundweight; } uint8_t ts_pushArrary(fdb_tsdb_t db, uint8_t *buf, uint8_t length) { struct fdb_blob blob; fdb_err_t result = FDB_NO_ERR; foundF8 = 0; foundF4 = 0; if (strcmp(((fdb_db_t)db)->name, "key") == 0 && (buf[3] == 0xF8 || buf[3] == 0xE8)) findF8(); if (strcmp(((fdb_db_t)db)->name, "key") == 0 && (buf[3] == 0xF4 || buf[3] == 0xE4)) findF4(); if (foundF8==0 && foundF4==0){ result = fdb_tsl_append(db, fdb_blob_make(&blob, buf, length)); if (result != FDB_NO_ERR) { // rt_kprintf("ts_pushArrary:%02X \n", ts_planTime); return 0; } } return 1; } void read_Flash(void) { struct fdb_blob blob; fdb_kv_get_blob(&kvdb, "CH", fdb_blob_make(&blob, &XbeeConst_DeviceAddress, sizeof(XbeeConst_DeviceAddress))); fdb_kv_get_blob(&kvdb, "TQ", fdb_blob_make(&blob, &WeightConst_TQ, sizeof(WeightConst_TQ))); fdb_kv_get_blob(&kvdb, "PM", fdb_blob_make(&blob, &WeightConst_SBType, sizeof(WeightConst_SBType))); fdb_kv_get_blob(&kvdb, "WL", fdb_blob_make(&blob, &XbeeConst_NetAddress, sizeof(XbeeConst_NetAddress))); fdb_kv_get_blob(&kvdb, "API", fdb_blob_make(&blob, &XbeeConst_UseAPI, sizeof(XbeeConst_UseAPI))); fdb_kv_get_blob(&kvdb, "CC", fdb_blob_make(&blob, &WeightConst_ChanCheShu, sizeof(WeightConst_ChanCheShu))); fdb_kv_get_blob(&kvdb, "BLE", fdb_blob_make(&blob, &WeightConst_BLE, sizeof(WeightConst_BLE))); if (WeightConst_BLE>1) isCC=1; fdb_kv_get_blob(&kvdb, "ad_Percent", fdb_blob_make(&blob, &ad_Percent, sizeof(ad_Percent))); fdb_kv_get_blob(&kvdb, "ad_Maxval", fdb_blob_make(&blob, &ad_Maxval, sizeof(ad_Maxval))); fdb_kv_get_blob(&kvdb, "ad_FS", fdb_blob_make(&blob, &ad_FS, sizeof(ad_FS))); fdb_kv_get_blob(&kvdb, "ad_Point", fdb_blob_make(&blob, &ad_Point, sizeof(ad_Point))); fdb_kv_get_blob(&kvdb, "ad_Inteval", fdb_blob_make(&blob, &ad_Inteval, sizeof(ad_Inteval))); fdb_kv_get_blob(&kvdb, "ad_Spanz", fdb_blob_make(&blob, &ad_Spanz, sizeof(ad_Spanz))); fdb_kv_get_blob(&kvdb, "ad_Zero", fdb_blob_make(&blob, &ad_Zero, sizeof(ad_Zero))); fdb_kv_get_blob(&kvdb, "ad_Tare", fdb_blob_make(&blob, &ad_Tare, sizeof(ad_Tare))); fdb_kv_get_blob(&kvdb, "read_key", fdb_blob_make(&blob, &read_key, sizeof(read_key))); fdb_kv_get_blob(&kvdb, "read_plan", fdb_blob_make(&blob, &read_plan, sizeof(read_plan))); fdb_kv_get_blob(&kvdb, "read_weight", fdb_blob_make(&blob, &read_weight, sizeof(read_weight))); fdb_kv_get_blob(&kvdb, "beginweight", fdb_blob_make(&blob, &WeightConst_WeightBegin, sizeof(WeightConst_WeightBegin))); fdb_kv_get_blob(&kvdb, "begintime", fdb_blob_make(&blob, &TimeConst, sizeof(TimeConst))); fdb_kv_get_blob(&kvdb, "completeorder", fdb_blob_make(&blob, &CompleteTarget_order, sizeof(CompleteTarget_order))); fdb_kv_get_blob(&kvdb, "TimeConst", fdb_blob_make(&blob, &TimeConst, sizeof(TimeConst))); } void onbordflash_init(void) { fdb_err_t result; struct fdb_default_kv default_kv; kv_db_lock = rt_sem_create("kv_db_lock", 1, RT_IPC_FLAG_FIFO); default_kv.kvs = default_kv_table; default_kv.num = sizeof(default_kv_table) / sizeof(default_kv_table[0]); fdb_kvdb_control(&kvdb, FDB_KVDB_CTRL_SET_LOCK, lock); fdb_kvdb_control(&kvdb, FDB_KVDB_CTRL_SET_UNLOCK, unlock); result = fdb_kvdb_init(&kvdb, "env", "kv", &default_kv, NULL); if (result != FDB_NO_ERR) { return ; } ///////////// fdb_tsdb_control(&ts_keydb, FDB_TSDB_CTRL_SET_LOCK, lock); fdb_tsdb_control(&ts_keydb, FDB_TSDB_CTRL_SET_UNLOCK, unlock); result = fdb_tsdb_init(&ts_keydb, "key", "ts_key", get_keydbtime, 48, NULL); if (result != FDB_NO_ERR) { return ; } /* read last saved time for simulated timestamp */ fdb_tsdb_control(&ts_keydb, FDB_TSDB_CTRL_GET_LAST_TIME, &ts_keyTime); ///////////////// ///////////// fdb_tsdb_control(&ts_plandb, FDB_TSDB_CTRL_SET_LOCK, lock); fdb_tsdb_control(&ts_plandb, FDB_TSDB_CTRL_SET_UNLOCK, unlock); result = fdb_tsdb_init(&ts_plandb, "plan", "ts_plan", get_plandbtime, 48, NULL); if (result != FDB_NO_ERR) { return ; } /* read last saved time for simulated timestamp */ fdb_tsdb_control(&ts_plandb, FDB_TSDB_CTRL_GET_LAST_TIME, &ts_planTime); ///////////////// ///////////// fdb_tsdb_control(&ts_weightdb, FDB_TSDB_CTRL_SET_LOCK, lock); fdb_tsdb_control(&ts_weightdb, FDB_TSDB_CTRL_SET_UNLOCK, unlock); result = fdb_tsdb_init(&ts_weightdb, "weight", "ts_weight", get_weightdbtime, 7, NULL); if (result != FDB_NO_ERR) { return ; } /* read last saved time for simulated timestamp */ fdb_tsdb_control(&ts_weightdb, FDB_TSDB_CTRL_GET_LAST_TIME, &ts_weightTime); ///////////////// read_Flash(); } void saveApi(rt_sem_t lock_sem,UART_HandleTypeDef *huart, uint8_t *pData) { //保存命令 pData[0] = 0x41; pData[1] = 0x54; pData[2] = 0x57; pData[3] = 0x52; pData[4] = 0x0D; HAL_UART_Transmit_DMA(huart, pData, 5); if (rt_sem_take(lock_sem, 2000) == RT_EOK) { //退出命令 pData[0] = 0x41; pData[1] = 0x54; pData[2] = 0x43; pData[3] = 0x4E; pData[4] = 0x0D; HAL_UART_Transmit_DMA(huart, pData, 5); if (rt_sem_take(lock_sem, 2000) != RT_EOK) rt_sem_release(lock_sem); else rt_sem_release(lock_sem); } else rt_sem_release(lock_sem); } void enterApi(rt_sem_t lock_sem, UART_HandleTypeDef *huart, uint8_t *pData) { unsigned char i; for (i = 0; i < 3; i++) pData[i] = 0x2B; rt_sem_take(lock_sem, RT_WAITING_FOREVER); HAL_UART_Transmit_DMA(huart, pData, 3); } void setAPI(void) { if (!XbeeConst_UseAPI && iscowweight<1) { enterApi(uart3_lock, &huart3, usart3_send_data); if (rt_sem_take(uart3_lock, 2000) == RT_EOK) { usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x41; usart3_send_data[3] = 0x50; usart3_send_data[4] = 0x30; usart3_send_data[5] = 0x0D; HAL_UART_Transmit_DMA(&huart3, usart3_send_data, 6); if (rt_sem_take(uart3_lock, 2000) == RT_EOK) { saveApi(uart3_lock, &huart3, usart3_send_data); } else rt_sem_release(uart3_lock); } else rt_sem_release(uart3_lock); } enterApi(uart2_lock, &huart2, usart2_send_data); if (rt_sem_take(uart2_lock, 2000) == RT_EOK) { //设置API Enable =2 usart2_send_data[0] = 0x41; usart2_send_data[1] = 0x54; usart2_send_data[2] = 0x41; usart2_send_data[3] = 0x50; if (XbeeConst_UseAPI>0) usart2_send_data[4] = 0x32; else usart2_send_data[4] = 0x30; usart2_send_data[5] = 0x0D; HAL_UART_Transmit_DMA(&huart2, usart2_send_data, 6); if (rt_sem_take(uart2_lock, 2000) == RT_EOK) { saveApi(uart2_lock, &huart2, usart2_send_data); beep(); rt_thread_mdelay(500); beep(); return; } else rt_sem_release(uart2_lock); } else rt_sem_release(uart2_lock); beep(); } void setNetAddress(void) { if (!XbeeConst_UseAPI && iscowweight<1) { enterApi(uart3_lock, &huart3, usart3_send_data); if (rt_sem_take(uart3_lock, 2000) == RT_EOK) { usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x49; usart3_send_data[3] = 0x44; usart3_send_data[4] = 0x37; usart3_send_data[5] = 0x46; usart3_send_data[6] = 0x46; usart3_send_data[7] = 0x45; usart3_send_data[8] = 0x0D; HAL_UART_Transmit_DMA(&huart3, usart3_send_data, 9); if (rt_sem_take(uart3_lock, 2000) == RT_EOK) { saveApi(uart3_lock, &huart3, usart3_send_data); } else rt_sem_release(uart3_lock); } else rt_sem_release(uart3_lock); } enterApi(uart2_lock, &huart2, usart2_send_data); if (rt_sem_take(uart2_lock, 2000) == RT_EOK) { //设置API Enable =2 usart2_send_data[0] = 0x41; usart2_send_data[1] = 0x54; usart2_send_data[2] = 0x49; usart2_send_data[3] = 0x44; usart2_send_data[4] = 0x37; usart2_send_data[5] = 0x46; usart2_send_data[6] = 0x46; if(XbeeConst_NetAddress>0) { if (XbeeConst_NetAddress>9) usart2_send_data[7] = (XbeeConst_NetAddress-10)+0x41; else usart2_send_data[7] = XbeeConst_NetAddress+0x30; } else usart2_send_data[7] = 0x46; usart2_send_data[8] = 0x0D; HAL_UART_Transmit_DMA(&huart2, usart2_send_data, 9); if (rt_sem_take(uart2_lock, 2000) == RT_EOK) { saveApi(uart2_lock, &huart2, usart2_send_data); beep(); rt_thread_mdelay(500); beep(); return; } else rt_sem_release(uart2_lock); } else rt_sem_release(uart2_lock); beep(); } /* void setBT(void) { //进入命令 // WeightConst_Weight_display[7] = 0x20;WeightConst_Weight_display[6] = 0x20; // WeightConst_Weight_display[5] = 0x20;WeightConst_Weight_display[4] = 0x20; unsigned char sendCount=0,i; for (int SendDisplay_i = 0; SendDisplay_i < 8; SendDisplay_i++) //显示重量 WeightConst_Weight_display[SendDisplay_i]=0x20; USART3_Configuration(0); sendCount = 0; while(sendCount<2) { setBT_timer = 1; //AT+CLRBAND AT+HOSTEN1 usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x2B; usart3_send_data[3] = 0x43; usart3_send_data[4] = 0x4C; usart3_send_data[5] = 0x52; usart3_send_data[6] = 0x42; usart3_send_data[7] = 0x41; usart3_send_data[8] = 0x4E; usart3_send_data[9] = 0x44; USART_Send_DMA(remoteSerial, 0x0A); while(setBT_timer>0 && setBT_timer<500); if (setBT_timer>=500) sendCount++; else if(setBT_timer==0) sendCount=4; } sendCount = 0; while(sendCount<2) { setBT_timer = 1; //41 54 2B 48 4F 53 54 45 4E 31 AT+HOSTEN1 usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x2B; usart3_send_data[3] = 0x48; usart3_send_data[4] = 0x4F; usart3_send_data[5] = 0x53; usart3_send_data[6] = 0x54; usart3_send_data[7] = 0x45; usart3_send_data[8] = 0x4E; usart3_send_data[9] = 0x31; USART_Send_DMA(remoteSerial, 0x0A); while(setBT_timer>0 && setBT_timer<500); if (setBT_timer>=500) sendCount++; else if(setBT_timer==0) sendCount=4; } sendCount = 0; while(sendCount<2) { setBT_timer = 1; //AT+RST usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x2B; usart3_send_data[3] = 0x52; usart3_send_data[4] = 0x53; usart3_send_data[5] = 0x54; USART_Send_DMA(remoteSerial, 0x06); while(setBT_timer>0 && setBT_timer<500); if (setBT_timer>=500) sendCount++; else if(setBT_timer==0) { setBT_timer=1; while(setBT_timer>0 && setBT_timer<1000); sendCount=4; } } sendCount = 0; // while(sendCount<2) { setBT_timer = 1; //AT+SCAN1 usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x2B; usart3_send_data[3] = 0x53; usart3_send_data[4] = 0x43; usart3_send_data[5] = 0x41; usart3_send_data[6] = 0x4E; usart3_send_data[7] = 0x31; USART_Send_DMA(remoteSerial, 0x08); while(setBT_timer>0 && setBT_timer<500); if (setBT_timer>=500) sendCount++; else if(setBT_timer==0) { setBT_timer=1; while(setBT_timer>0 && setBT_timer<5000); if (setBT_timer>=5000) { WeightConst_Weight_display[7] = 0xCA; WeightConst_Weight_display[6] = 0xA7; WeightConst_Weight_display[5] = 0xB0; WeightConst_Weight_display[4] = 0xDC; sendCount=4; WeightConst_BLE = 0; TMRWatchConst[Const_BLE].Data = WeightConst_BLE; EE_WriteVariable(TMRWatchConst_EEPROM_START_ADDRESS, TMRWatchConst[Const_BLE].VirtAddress, TMRWatchConst, &TMRWatchConst_CurWrAddress); } //失败CAA7 B0DC //失败 else { setBT_timer = 1; //AT+BAND0 usart3_send_data[0] = 0x41; usart3_send_data[1] = 0x54; usart3_send_data[2] = 0x2B; usart3_send_data[3] = 0x42; usart3_send_data[4] = 0x41; usart3_send_data[5] = 0x4E; usart3_send_data[6] = 0x44; usart3_send_data[7] = 0x30; USART_Send_DMA(remoteSerial, 0x08); while(setBT_timer>0 && setBT_timer<500); if (setBT_timer>=500) { WeightConst_Weight_display[7] = 0xCA; WeightConst_Weight_display[6] = 0xA7; WeightConst_Weight_display[5] = 0xB0; WeightConst_Weight_display[4] = 0xDC; WeightConst_BLE = 0; TMRWatchConst[Const_BLE].Data = WeightConst_BLE; EE_WriteVariable(TMRWatchConst_EEPROM_START_ADDRESS, TMRWatchConst[Const_BLE].VirtAddress, TMRWatchConst, &TMRWatchConst_CurWrAddress); } //失败CAA7 B0DC else if(setBT_timer==0) { WeightConst_Weight_display[7] = 0xB3; WeightConst_Weight_display[6] = 0xC9; WeightConst_Weight_display[5] = 0xB9; WeightConst_Weight_display[4] = 0xA6; WeightConst_BLE = 1; TMRWatchConst[Const_BLE].Data = WeightConst_BLE; EE_WriteVariable(TMRWatchConst_EEPROM_START_ADDRESS, TMRWatchConst[Const_BLE].VirtAddress, TMRWatchConst, &TMRWatchConst_CurWrAddress); } //成功B3C9 B9A6 } } } USART3_Configuration(1); } void setNetAddress_byapi(u8 netid) { //7E 00 06 08 01 49 44 7F FE EC unsigned char sendCount=0,i; usart2_send_data[0] = 0x7E; usart2_send_data[1] = 0x00; usart2_send_data[2] = 0x06; usart2_send_data[3] = 0x08; usart2_send_data[4] = 0x01; usart2_send_data[5] = 0x49; usart2_send_data[6] = 0x44; usart2_send_data[7] = 0x7F; if(netid) usart2_send_data[8] = 0xF0 + netid; else usart2_send_data[8] = 0xFF; for (i = 3; i < 9; i++) sendCount = sendCount + usart2_send_data[i]; usart2_send_data[9] = 0xFF-sendCount; USART_Send_DMA(xbeeSerial, 0x0A); } */