280 lines
7.3 KiB
C++
280 lines
7.3 KiB
C++
#include "Sys.h"
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#include "Task.h"
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#include "SerialPort.h"
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#include "Platform\stm32.h"
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#define COM_DEBUG 0
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const byte uart_irqs[] = UART_IRQs;
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void SerialPort::OnInit()
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{
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_parity = USART_Parity_No;
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_dataBits = USART_WordLength_8b;
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_stopBits = USART_StopBits_1;
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}
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bool SerialPort::OnSet()
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{
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USART_TypeDef* const g_Uart_Ports[] = UARTS;
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assert_param(_index < ArrayLength(g_Uart_Ports));
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auto sp = g_Uart_Ports[_index];
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_port = sp;
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// 根据端口实际情况决定打开状态
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return sp->CR1 & USART_CR1_UE;
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}
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// 打开串口
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void SerialPort::OnOpen2()
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{
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Pin rx, tx;
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GetPins(&tx, &rx);
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//串口引脚初始化
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_tx.Set(tx).Open();
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_rx.Init(rx, false).Open();
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auto st = (USART_TypeDef*)_port;
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// 不要关调试口,否则杯具
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if(_index != Sys.MessagePort) USART_DeInit(st);
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// USART_DeInit其实就是关闭时钟,这里有点多此一举。但为了安全起见,还是使用
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// 检查重映射
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#ifdef STM32F1
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if(Remap)
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{
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RCC_APB2PeriphClockCmd(RCC_APB2Periph_AFIO, ENABLE);
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switch (_index) {
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case 0: AFIO->MAPR |= AFIO_MAPR_USART1_REMAP; break;
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case 1: AFIO->MAPR |= AFIO_MAPR_USART2_REMAP; break;
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case 2: AFIO->MAPR |= AFIO_MAPR_USART3_REMAP_FULLREMAP; break;
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}
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}
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#endif
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// 打开 UART 时钟。必须先打开串口时钟,才配置引脚
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#if defined(STM32F0) || defined(GD32F150)
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switch(_index)
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{
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case COM1: RCC_APB2PeriphClockCmd(RCC_APB2Periph_USART1, ENABLE); break;
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case COM2: RCC_APB1PeriphClockCmd(RCC_APB1Periph_USART2, ENABLE); break;
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default: break;
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}
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#else
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if (_index) { // COM2-5 on APB1
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RCC->APB1ENR |= RCC_APB1ENR_USART2EN >> 1 << _index;
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} else { // COM1 on APB2
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RCC->APB2ENR |= RCC_APB2ENR_USART1EN;
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}
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#endif
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#if defined(STM32F0) || defined(GD32F150)
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_tx.AFConfig(Port::AF_1);
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_rx.AFConfig(Port::AF_1);
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#elif defined(STM32F4)
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const byte afs[] = { GPIO_AF_USART1, GPIO_AF_USART2, GPIO_AF_USART3, GPIO_AF_UART4, GPIO_AF_UART5, GPIO_AF_USART6, GPIO_AF_UART7, GPIO_AF_UART8 };
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_tx.AFConfig((Port::GPIO_AF)afs[_index]);
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_rx.AFConfig((Port::GPIO_AF)afs[_index]);
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#endif
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USART_InitTypeDef p;
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USART_StructInit(&p);
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p.USART_BaudRate = _baudRate;
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p.USART_WordLength = _dataBits;
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p.USART_StopBits = _stopBits;
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p.USART_Parity = _parity;
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USART_Init(st, &p);
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// 串口接收中断配置,同时会打开过载错误中断
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USART_ITConfig(st, USART_IT_RXNE, ENABLE);
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//USART_ITConfig(st, USART_IT_PE, ENABLE);
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//USART_ITConfig(st, USART_IT_ERR, ENABLE);
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//USART_ITConfig(st, USART_IT_TXE, DISABLE);
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//#if defined(STM32F0) || defined(GD32F150)
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// GD官方提供,因GD设计比ST严格,导致一些干扰被错误认为是溢出
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//USART_OverrunDetectionConfig(st, USART_OVRDetection_Disable);
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//#else
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// 打开中断,收发都要使用
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//const byte irqs[] = UART_IRQs;
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byte irq = uart_irqs[_index];
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Interrupt.SetPriority(irq, 0);
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Interrupt.Activate(irq, OnHandler, this);
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//#endif
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USART_Cmd(st, ENABLE);//使能串口
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}
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// 关闭端口
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void SerialPort::OnClose2()
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{
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auto st = (USART_TypeDef*)_port;
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USART_Cmd(st, DISABLE);
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USART_DeInit(st);
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_tx.Close();
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_rx.Close();
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//const byte irqs[] = UART_IRQs;
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byte irq = uart_irqs[_index];
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Interrupt.Deactivate(irq);
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// 检查重映射
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#ifdef STM32F1
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if(Remap)
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{
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switch (_index) {
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case 0: AFIO->MAPR &= ~AFIO_MAPR_USART1_REMAP; break;
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case 1: AFIO->MAPR &= ~AFIO_MAPR_USART2_REMAP; break;
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case 2: AFIO->MAPR &= ~AFIO_MAPR_USART3_REMAP_FULLREMAP; break;
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}
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}
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#endif
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}
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// 发送单一字节数据
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uint SerialPort::SendData(byte data, uint times)
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{
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/*
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在USART_DR寄存器中写入了最后一个数据字后,在关闭USART模块之前或设置微控制器进入低功耗模式之前,
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必须先等待TC=1。使用下列软件过程清除TC位:
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1.读一次USART_SR寄存器;
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2.写一次USART_DR寄存器。
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*/
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auto st = (USART_TypeDef*)_port;
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USART_SendData(st, (ushort)data);
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// 等待发送完毕
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while(USART_GetFlagStatus(st, USART_FLAG_TXE) == RESET && --times > 0);
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if(!times) Error++;
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return times;
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}
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// 向某个端口写入数据。如果size为0,则把data当作字符串,一直发送直到遇到\0为止
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void SerialPort::OnWrite2()
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{
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// 打开串口发送
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USART_ITConfig((USART_TypeDef*)_port, USART_IT_TXE, ENABLE);
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}
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#if !defined(TINY) && defined(STM32F0)
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#pragma arm section code = "SectionForSys"
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#endif
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void SerialPort::OnTxHandler()
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{
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//#if !(defined(STM32F0) || defined(GD32F150))
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if(!Tx.Empty())
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USART_SendData((USART_TypeDef*)_port, (ushort)Tx.Pop());
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else
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{
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USART_ITConfig((USART_TypeDef*)_port, USART_IT_TXE, DISABLE);
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if(RS485) *RS485 = false;
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}
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//#endif
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}
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void SerialPort::OnRxHandler()
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{
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// 串口接收中断必须以极快的速度完成,否则会出现丢数据的情况
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// 判断缓冲区足够最小值以后才唤醒任务,减少时间消耗
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// 缓冲区里面别用%,那会产生非常耗时的除法运算
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byte dat = (byte)USART_ReceiveData((USART_TypeDef*)_port);
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Rx.Push(dat);
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// 收到数据,开启任务调度。延迟_byteTime,可能还有字节到来
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//!!! 暂时注释任务唤醒,避免丢数据问题
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if(_taskidRx && Rx.Length() >= MinSize)
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{
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//Sys.SetTask(_taskidRx, true, (ByteTime >> 10) + 1);
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((Task*)_task)->Set(true, 10);
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}
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}
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// 真正的串口中断函数
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void SerialPort::OnHandler(ushort num, void* param)
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{
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auto sp = (SerialPort*)param;
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auto st = (USART_TypeDef*)sp->_port;
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//#if !(defined(STM32F0) || defined(GD32F150))
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if(USART_GetITStatus(st, USART_IT_TXE) != RESET) sp->OnTxHandler();
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//#endif
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// 接收中断
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if(USART_GetITStatus(st, USART_IT_RXNE) != RESET) sp->OnRxHandler();
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// 溢出
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if(USART_GetFlagStatus(st, USART_FLAG_ORE) != RESET)
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{
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USART_ClearFlag(st, USART_FLAG_ORE);
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// 读取并扔到错误数据
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USART_ReceiveData(st);
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sp->Error++;
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//debug_printf("Serial%d 溢出 \r\n", sp->_index + 1);
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}
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/*if(USART_GetFlagStatus(st, USART_FLAG_NE) != RESET) USART_ClearFlag(st, USART_FLAG_NE);
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if(USART_GetFlagStatus(st, USART_FLAG_FE) != RESET) USART_ClearFlag(st, USART_FLAG_FE);
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if(USART_GetFlagStatus(st, USART_FLAG_PE) != RESET) USART_ClearFlag(st, USART_FLAG_PE);*/
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}
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#pragma arm section code
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// 获取引脚
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void SerialPort::GetPins(Pin* txPin, Pin* rxPin)
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{
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*rxPin = *txPin = P0;
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const Pin g_Uart_Pins[] = UART_PINS;
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const Pin* p = g_Uart_Pins;
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#ifdef STM32F1
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const Pin g_Uart_Pins_Map[] = UART_PINS_FULLREMAP;
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if(Remap) p = g_Uart_Pins_Map;
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#endif
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int n = _index << 2;
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*txPin = p[n];
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*rxPin = p[n + 1];
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}
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extern "C"
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{
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extern SerialPort* _printf_sp;
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bool isInFPutc;
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/* 重载fputc可以让用户程序使用printf函数 */
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int fputc(int ch, FILE *f)
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{
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#if DEBUG
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if(Sys.Clock == 0) return ch;
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int idx = Sys.MessagePort;
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if(idx == COM_NONE) return ch;
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USART_TypeDef* g_Uart_Ports[] = UARTS;
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auto port = g_Uart_Ports[idx];
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if(isInFPutc) return ch;
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isInFPutc = true;
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// 检查并打开串口
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if((port->CR1 & USART_CR1_UE) != USART_CR1_UE)
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{
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_printf_sp = SerialPort::GetMessagePort();
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}
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if(_printf_sp)
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{
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byte b = ch;
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_printf_sp->Write(Buffer(&b, 1));
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}
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isInFPutc = false;
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#endif
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return ch;
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}
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}
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