/* * File : canapp.c * This file is part of RT-Thread RTOS * COPYRIGHT (C) 2006, RT-Thread Development Team * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.rt-thread.org/license/LICENSE * * Change Logs: * Date Author Notes * 2015-05-14 aubrcool@qq.com first version */ #include #include #include #ifdef RT_USING_CAN #define CANRT1 8 #define CANERR1 9 #define CANRT2 37 #define CANERR2 38 static struct canledtype { struct stm32_hw_pin_userdata rtd; struct stm32_hw_pin_userdata err; } canled[] = { #ifdef USING_BXCAN1 { {CANRT1, PIN_MODE_OUTPUT_OD,}, {CANERR1, PIN_MODE_OUTPUT_OD,}, }, #endif /*USING_BXCAN1*/ #ifdef USING_BXCAN2 { {CANRT2, PIN_MODE_OUTPUT_OD,}, {CANERR2, PIN_MODE_OUTPUT_OD,}, }, #endif /*USING_BXCAN2*/ }; void can_bus_hook(struct rt_can_device *can, struct canledtype *led) { if (can->timerinitflag == 1) { rt_pin_write(led->rtd.pin, 0); } else { if (can->status.rcvchange == 1 || can->status.sndchange == 1) { can->status.rcvchange = 0; can->status.sndchange = 0; rt_pin_write(led->rtd.pin, rt_pin_read(led->rtd.pin) ? 0 : 1); } else { rt_pin_write(led->rtd.pin, 1); } } if (can->timerinitflag == 1) { rt_pin_write(led->err.pin, 0); } else { if (can->status.errcode) { rt_pin_write(led->err.pin, 0); } else { rt_pin_write(led->err.pin, 1); } } } #ifdef USING_BXCAN1 void can1_bus_hook(struct rt_can_device *can) { static rt_int32_t inited = 0; if (!inited) { inited = 1; rt_pin_mode(canled[0].rtd.pin, canled[0].rtd.mode); rt_pin_mode(canled[0].err.pin, canled[0].err.mode); } can_bus_hook(can, &canled[0]); } #endif /*USING_BXCAN1*/ #ifdef USING_BXCAN2 void can2_bus_hook(struct rt_can_device *can) { static rt_int32_t inited = 0; if (!inited) { inited = 1; rt_pin_mode(canled[1].rtd.pin, canled[1].rtd.mode); rt_pin_mode(canled[1].err.pin, canled[1].err.mode); } can_bus_hook(can, &canled[1]); } #endif /*USING_BXCAN2*/ int can_bus_hook_init(void) { rt_device_t candev; #ifdef USING_BXCAN1 candev = rt_device_find("bxcan1"); RT_ASSERT(candev); rt_device_control(candev, RT_CAN_CMD_SET_BUS_HOOK, (void *)can1_bus_hook); #endif /*USING_BXCAN1*/ #ifdef USING_BXCAN2 candev = rt_device_find("bxcan2"); RT_ASSERT(candev); rt_device_control(candev, RT_CAN_CMD_SET_BUS_HOOK, (void *)can2_bus_hook); #endif /*USING_BXCAN2*/ return RT_EOK; } INIT_DEVICE_EXPORT(can_bus_hook_init); struct can_app_struct { const char *name; struct rt_event event; struct rt_can_filter_config *filter; rt_uint8_t eventopt; }; static struct can_app_struct can_data[2]; static rt_err_t can1ind(rt_device_t dev, void *args, rt_int32_t hdr, rt_size_t size) { rt_event_t pevent = (rt_event_t)args; rt_event_send(pevent, 1 << (hdr)); return RT_EOK; } static rt_err_t can2ind(rt_device_t dev, void *args, rt_int32_t hdr, rt_size_t size) { rt_event_t pevent = (rt_event_t)args; rt_event_send(pevent, 1 << (hdr)); return RT_EOK; } struct rt_can_filter_item filter1item[4] = { RT_CAN_FILTER_STD_INIT(1, can1ind, &can_data[0].event), RT_CAN_FILTER_STD_INIT(2, can1ind, &can_data[0].event), RT_CAN_STD_RMT_FILTER_INIT(3, can1ind, &can_data[0].event), RT_CAN_STD_RMT_DATA_FILTER_INIT(4, can1ind, &can_data[0].event), }; struct rt_can_filter_item filter2item[4] = { RT_CAN_FILTER_STD_INIT(1, can2ind, &can_data[1].event), RT_CAN_FILTER_STD_INIT(2, can2ind, &can_data[1].event), RT_CAN_STD_RMT_FILTER_INIT(3, can2ind, &can_data[1].event), RT_CAN_STD_RMT_DATA_FILTER_INIT(4, can2ind, &can_data[1].event), }; struct rt_can_filter_config filter1 = { .count = 4, .actived = 1, .items = filter1item, }; struct rt_can_filter_config filter2 = { .count = 4, .actived = 1, .items = filter2item, }; static struct can_app_struct can_data[2] = { { .name = "bxcan1", .filter = &filter1, .eventopt = RT_EVENT_FLAG_OR | RT_EVENT_FLAG_CLEAR, }, { .name = "bxcan2", .filter = &filter2, .eventopt = RT_EVENT_FLAG_AND | RT_EVENT_FLAG_CLEAR, }, }; void rt_can_thread_entry(void *parameter) { struct rt_can_msg msg; struct can_app_struct *canpara = (struct can_app_struct *) parameter; rt_device_t candev; rt_uint32_t e; candev = rt_device_find(canpara->name); RT_ASSERT(candev); rt_event_init(&canpara->event, canpara->name, RT_IPC_FLAG_FIFO); rt_device_open(candev, (RT_DEVICE_OFLAG_RDWR | RT_DEVICE_FLAG_INT_RX | RT_DEVICE_FLAG_INT_TX)); rt_device_control(candev, RT_CAN_CMD_SET_FILTER, canpara->filter); while (1) { if ( rt_event_recv(&canpara->event, ((1 << canpara->filter->items[0].hdr) | (1 << canpara->filter->items[1].hdr) | (1 << canpara->filter->items[2].hdr) | (1 << canpara->filter->items[3].hdr)), canpara->eventopt, RT_WAITING_FOREVER, &e) != RT_EOK ) { continue; } if (e & (1 << canpara->filter->items[0].hdr)) { msg.hdr = canpara->filter->items[0].hdr; while (rt_device_read(candev, 0, &msg, sizeof(msg)) == sizeof(msg)) { rt_device_write(candev, 0, &msg, sizeof(msg)); } } if (e & (1 << canpara->filter->items[1].hdr)) { msg.hdr = canpara->filter->items[1].hdr; while (rt_device_read(candev, 0, &msg, sizeof(msg)) == sizeof(msg)) { rt_device_write(candev, 0, &msg, sizeof(msg)); } } if (e & (1 << canpara->filter->items[2].hdr)) { msg.hdr = canpara->filter->items[2].hdr; while (rt_device_read(candev, 0, &msg, sizeof(msg)) == sizeof(msg)) { rt_device_write(candev, 0, &msg, sizeof(msg)); } } if (e & (1 << canpara->filter->items[3].hdr)) { msg.hdr = canpara->filter->items[3].hdr; while (rt_device_read(candev, 0, &msg, sizeof(msg)) == sizeof(msg)) { rt_device_write(candev, 0, &msg, sizeof(msg)); } } } } int rt_can_app_init(void) { rt_thread_t tid; tid = rt_thread_create("canapp1", rt_can_thread_entry, &can_data[0], 512, RT_THREAD_PRIORITY_MAX / 3 - 1, 20); if (tid != RT_NULL) rt_thread_startup(tid); tid = rt_thread_create("canapp2", rt_can_thread_entry, &can_data[1], 512, RT_THREAD_PRIORITY_MAX / 3 - 1, 20); if (tid != RT_NULL) rt_thread_startup(tid); return 0; } INIT_APP_EXPORT(rt_can_app_init); #endif /*RT_USING_CAN*/