// =============================================================================
// 功能: 启动串口发送,其目的是触发中断,用中断方式发送数据。
// 参数: PrivateTag,被操作的串口设备指针数值.
// 返回: 发送的个数
// =============================================================================
static u32 __UART_SendStart (tagUartReg *Reg,u32 timeout)
{
u8 fifodep=1,num,ch[8],port;
switch((u32)Reg)
{
//UART0和UART1的FIFO深度为8,而其他的为1
case CN_UART0_BASE: port = CN_UART0; fifodep = 8; break;
case CN_UART1_BASE: port = CN_UART1; fifodep = 8; break;
case CN_UART2_BASE: port = CN_UART2; break;
case CN_UART3_BASE: port = CN_UART3; break;
case CN_UART4_BASE: port = CN_UART4; break;
case CN_UART5_BASE: port = CN_UART5; break;
default:return 0;
}
__UART_TxIntDisable(Reg);
if(__UART_TxTranEmpty(Reg))
{
fifodep = UART_PortRead(pUartCB[port],ch,fifodep,0);// UART的FIFO大小为8字节
for(num = 0; num < fifodep; num++)
{
Reg->D = ch[num];
}
}
__UART_TxIntEnable(Reg);
return num;
}
// =============================================================================
// 功能: 使用中断方式效率能够大大提升软件执行效率;包括接收、发送和异常等,接收到数据
// 后,调用通用接口模块,写入软件缓冲区;发送数据时,调用通用接口模块,从软件缓
// 冲区读出数据,写入硬件发送寄存器;此外,根据芯片,可通过DMA方式发送
// 参数: 中断号.
// 返回: 0.
// =============================================================================
uint32_t UART_ISR(ufast_t IntLine)
{
static struct tagUartCB *UCB;
tagUartReg *Reg;
uint32_t timeout = 1000,num;
uint8_t ch,*puart_dma_send_buf,*puart_dma_recv_buf;
uint32_t IIR=0,Port,DmaBufLen,DmaRcvLen;
switch(IntLine)
{
case CN_INT_LINE_UART0:
Port = CN_UART0;
UCB = pUartCB[Port];
Reg = (tagUartReg *)CN_UART0_BASE;
DmaBufLen = UART0_DMA_BUF_LEN;
DmaRcvLen = s_UART0_DmaRcvLen;
puart_dma_send_buf = (uint8_t*)UART0_DmaSendBuf;
puart_dma_recv_buf = (uint8_t*)UART0_DmaRecvBuf;
break;
case CN_INT_LINE_UART1:
Port = CN_UART1;
UCB = pUartCB[Port];
Reg = (tagUartReg *)CN_UART1_BASE;
DmaBufLen = UART1_DMA_BUF_LEN;
DmaRcvLen = &s_UART1_DmaRcvLen;
puart_dma_send_buf = (uint8_t*)UART1_DmaSendBuf;
puart_dma_recv_buf = (uint8_t*)UART1_DmaRecvBuf;
break;
case CN_INT_LINE_USART0:
Port = CN_USART0;
UCB = pUartCB[Port];
Reg = (tagUartReg *)CN_UART1_BASE;
DmaBufLen = USART0_DMA_BUF_LEN;
DmaRcvLen = &s_USART0_DmaRcvLen;
puart_dma_send_buf = (uint8_t*)USART0_DmaSendBuf;
puart_dma_recv_buf = (uint8_t*)USART0_DmaRecvBuf;
break;
case CN_INT_LINE_USART1:
Port = CN_USART1;
UCB = pUartCB[Port];
Reg = (tagUartReg *)CN_UART1_BASE;
DmaBufLen = USART1_DMA_BUF_LEN;
DmaRcvLen = &s_USART1_DmaRcvLen;
puart_dma_send_buf = (uint8_t*)USART1_DmaSendBuf;
puart_dma_recv_buf = (uint8_t*)USART1_DmaRecvBuf;
break;
default:
return 0;
}
IIR = Reg->UART_SR;
if(s_UART_DmaUsed[Port] == cn_dma_unused)//非DMA方式发送和接收
{
if((IIR & (1<<0)) && (Reg->UART_IMR &(1<<0)))//rxrdy int
{
ch = Reg->UART_RHR;
num = UART_PortWrite(UCB,&ch,1,0);
if(num != 1)
{
UART_ErrHandle(UCB,CN_UART_BUF_OVER_ERR);
}
}
//tx empty int
if((IIR &(1<<9)) && (Reg->UART_IMR &(1<<9)))
{
num = UART_PortRead(UCB,&ch,1,0);
while((!__UART_TxTranEmpty(Reg)) && (timeout-- > 0));
if(num != 0)
Reg->UART_THR = ch;
else
{
__UART_SendIntDisable(Reg,s_UART_DmaUsed[Port]);
}
}
}
else //DMA方式发送和接收
{
if((IIR & (1<<3)) && (Reg->UART_IMR &(1<<3)))//endrx int
{
if(DmaRcvLen > DmaBufLen) //计算从DMA BUF中读多少数据
num = DmaBufLen;
else
num = DmaRcvLen;
UART_PortWrite(UCB,puart_dma_recv_buf,num,0);
DmaRcvLen = DmaRcvLen - num;
if(DmaRcvLen > DmaBufLen) //计算下次DMA接收数据量
Reg->UART_RCR = DmaBufLen;
else if(DmaRcvLen > 1)
Reg->UART_RCR = DmaRcvLen;
else //接收DMA最少为1
{
Reg->UART_RCR = 1;
DmaRcvLen = 1;
}
Reg->UART_RPR = (vu32)puart_dma_recv_buf;
}
if((IIR & (1<<11)) && (Reg->UART_IMR &(1<<11)))//txbufe int
{
while(!(Reg->UART_SR & (1<<9)));//wait for empty
num = UART_PortRead(UCB,puart_dma_send_buf, DmaBufLen,0);
if(num > 0)
{
Reg->UART_PTCR = (1<<9);//diable dma tx
if((Reg->UART_TCR==0)&&(Reg->UART_TNCR==0))
{
// num = UART_PortRead(UCB,puart_dma_send_buf,
// DmaBufLen,0);
Reg->UART_TPR = (uint32_t)puart_dma_send_buf;
Reg->UART_TCR = num;
}
Reg->UART_PTCR = (1<<8);//enable dma tx
}
else
{
//是否需禁止 dma tx int
while(!__UART_TxTranEmpty(Reg));
__UART_SendIntDisable(Reg,s_UART_DmaUsed[Port]);
}
}
}
if(IIR &(0xE0)) //其他中断
{
UART_ErrHandle(UCB,CN_UART_HARD_COMM_ERR);
}
return 0;
}
// =============================================================================
// 功能: UART的中断服务函数,包括发送空、接收、错误三种中断。
// 1.接收中断,从接收FIFO中读数据,并调用UART_PortWrite写入接收缓冲区中;
// 2.发送中断,调用UART_PortRead读发送缓冲区中数据,并写入发送FIFO;
// 3.错误中断,弹出错误事件
// 参数: 中断线号.
// 返回: 0.
// =============================================================================
static u32 UART_ISR(ptu32_t IntLine)
{
struct UartCB *UCB;
volatile tagUartReg *Reg;
u32 i,fifodep=1,num=0;
u8 ch[16];
switch(IntLine)
{
case CN_INT_LINE_UART0_RX_TX:
case CN_INT_LINE_UART0_ERR:
UCB = pUartCB[CN_UART0];
Reg = tg_UART_Reg[CN_UART0];
fifodep = 8;
break;
case CN_INT_LINE_UART1_RX_TX:
case CN_INT_LINE_UART1_ERR:
UCB = pUartCB[CN_UART1];
Reg = tg_UART_Reg[CN_UART1];
fifodep = 8;
break;
case CN_INT_LINE_UART2_RX_TX:
case CN_INT_LINE_UART2_ERR:
UCB = pUartCB[CN_UART2];
Reg = tg_UART_Reg[CN_UART2];
break;
case CN_INT_LINE_UART3_RX_TX:
case CN_INT_LINE_UART3_ERR:
UCB = pUartCB[CN_UART3];
Reg = tg_UART_Reg[CN_UART3];
break;
case CN_INT_LINE_UART4_RX_TX:
case CN_INT_LINE_UART4_ERR:
UCB = pUartCB[CN_UART4];
Reg = tg_UART_Reg[CN_UART4];
break;
case CN_INT_LINE_UART5_RX_TX:
case CN_INT_LINE_UART5_ERR:
UCB = pUartCB[CN_UART5];
Reg = tg_UART_Reg[CN_UART5];
break;
default:return 0;
}
if(Reg->S1 & UART_S1_RDRF_MASK) //接收中断标志
{
for(num = 0; num < fifodep; num++)
{
if(!(Reg->SFIFO & UART_SFIFO_RXEMPT_MASK))
ch[num] = Reg->D;
else
break;
}
UART_PortWrite(UCB,ch,num,0);
}
if(Reg->S1 & UART_S1_TDRE_MASK) //发送中断标志
{
num = UART_PortRead(UCB,ch,fifodep,0);
if(num>0)
{
for(i = 0; i < num; i++)
Reg->D = ch[i++];
}
else
{
__UART_TxIntDisable(Reg);
}
}
if(Reg->S1 & (UART_S1_FE_MASK | UART_S1_PF_MASK)) //硬件错误
{
UART_ErrHandle(UCB,CN_UART_HARD_COMM_ERR);
}
return 0;
}
