828/applications/DATA/DATA_uart.c


								/*

								 * Copyright (c) 2006-2021, RT-Thread Development Team

								 *

								 * SPDX-License-Identifier: Apache-2.0

								 *

								 * Change Logs:

								 * Date           Author       Notes

								 * 2025-10-20     Administrator       the first version

								 */

								/* DATA_uart.c */

								#include <rtthread.h>

								#include <rtdevice.h>

								#include "data_comm.h"


								#define SAMPLE_UART_NAME   "uart2"

								#define DMA_RX_BUF_SIZE    512

								#define RINGBUF_SIZE       4096


								static rt_device_t serial;


								// DMA 接收缓冲区

								//static rt_uint8_t dma_rx_buffer[DMA_RX_BUF_SIZE];


								// 环形缓冲区（暂存未完整报文）

								static struct rt_ringbuffer rx_rb;

								static rt_uint8_t rb_pool[RINGBUF_SIZE];


								// 接收回调信号量

								static struct rt_semaphore rx_sem;


								// 函数声明

								static rt_err_t uart_rx_ind(rt_device_t dev, rt_size_t size);

								static int get_line(char *buf, int maxlen);


								void uart_thread_entry(void *parameter)

								{

								    char input[MAX_INPUT_LEN];

								    int len;


								    // 初始化环形缓冲区和信号量

								    rt_ringbuffer_init(&rx_rb, rb_pool, sizeof(rb_pool));

								    rt_sem_init(&rx_sem, "rx_sem", 0, RT_IPC_FLAG_FIFO);


								    // 查找串口设备

								    serial = rt_device_find(SAMPLE_UART_NAME);

								    if (!serial) {

								        rt_kprintf("Cannot find %s\n", SAMPLE_UART_NAME);

								        return;

								    }


								    // 配置串口参数（只设置 bufsz，去掉 dma_rx）

								    struct serial_configure config = RT_SERIAL_CONFIG_DEFAULT;

								    config.bufsz = DMA_RX_BUF_SIZE;  // 设置接收缓冲区大小


								    rt_device_control(serial, RT_DEVICE_CTRL_CONFIG, &config);


								    // 打开设备：关键！使用 RT_DEVICE_FLAG_DMA_RX 启用 DMA 接收

								    rt_err_t result = rt_device_open(serial, RT_DEVICE_FLAG_DMA_RX | RT_DEVICE_FLAG_DMA_TX);

								    if (result != RT_EOK)

								    {

								        rt_kprintf("Failed to open %s with DMA, error=%d\n", SAMPLE_UART_NAME, result);

								        return;

								    }


								    // 设置接收指示回调（DMA 完成或中断后调用）

								    rt_device_set_rx_indicate(serial, uart_rx_ind);


								    rt_kprintf("UART DMA thread running...\n");


								    while (1)

								    {

								        // 等待数据就绪

								        if (rt_sem_take(&rx_sem, RT_WAITING_FOREVER) == RT_EOK)

								        {

								            // 处理接收到的数据（提取完整行）

								            while ((len = get_line(input, sizeof(input))) > 0)

								            { // 调试：打印每个字节

								              /*  rt_kprintf("Len=%d, Data: ", len);

								                for (int i = 0; i < len; i++) {

								                    rt_kprintf("[%02X '%c'] ", input[i],

								                               (input[i] >= 32 && input[i] < 127) ? input[i] : '.');

								                }

								                rt_kprintf("\n");


								                rt_kprintf("Received: [%.*s]\n", len, input);*/

								                // 动态分配请求结构体（见之前完整代码）

								                struct proc_request *req = rt_malloc(sizeof(struct proc_request));

								                if (!req) continue;


								                rt_strncpy(req->input, input, sizeof(req->input));

								                req->input_len = len;


								                req->sem = rt_malloc(sizeof(struct rt_semaphore));

								                if (!req->sem) {

								                    rt_free(req);

								                    continue;

								                }

								                rt_sem_init(req->sem, "uart_resp", 0, RT_IPC_FLAG_FIFO);


								                // 发送到处理线程

								                if (rt_mq_send(proc_mq, &req, sizeof(req)) == RT_EOK)

								                {

								                    // 等待处理完成

								                    if (rt_sem_take(req->sem, RT_WAITING_FOREVER) == RT_EOK)

								                    {

								                        rt_device_write(serial, 0, req->output, req->output_len);

								                    }

								                }


								                // 清理

								                rt_sem_detach(req->sem);  // 或 rt_sem_delete

								                rt_free(req->sem);

								                rt_free(req);

								            }

								        }

								    }

								}

								// DMA 接收回调

								static rt_err_t uart_rx_ind(rt_device_t dev, rt_size_t size)

								{

								    rt_uint8_t temp[64];

								       rt_size_t read_size;


								       // 从设备读取数据（驱动内部有 DMA buffer）

								       while (size > 0)

								       {

								           read_size = rt_device_read(dev, 0, temp, (size > 64) ? 64 : size);

								           if (read_size > 0) {

								               rt_ringbuffer_put(&rx_rb, temp, read_size);

								               // 调试：打印实际读到的数据

								            /*   for (int i = 0; i < read_size; i++) {

								                   rt_kprintf("RX: 0x%02X '%c'\n", temp[i],

								                              (temp[i] >= 32 && temp[i] < 127) ? temp[i] : '.');

								               }*/

								           }

								           size -= read_size;

								       }


								       rt_sem_release(&rx_sem);

								       return RT_EOK;

								}


								// 从环形缓冲区提取一行

								static int get_line(char *buf, int maxlen)

								{

								    int len = rt_ringbuffer_get(&rx_rb, (rt_uint8_t*)buf, maxlen - 1);

								        if (len > 0) {

								            buf[len] = '\0';

								            return len;

								        }

								        return 0;

								}


								// 启动 UART 线程

								int start_uart_thread(void)

								{

								    rt_thread_t tid = rt_thread_create("data_uart", uart_thread_entry, RT_NULL,

								                                       4096,      // 栈大小：4KB

								                                       25,        // 优先级

								                                       10);       // 时间片

								    if (tid != RT_NULL)

								    {

								        rt_thread_startup(tid);

								    }

								    return 0;

								}

								//INIT_COMPONENT_EXPORT(start_uart_thread);