老师您好,我现在通过IPC让CPU2核给CPU1核发送一段数据,CPU1核接收到CPU2核的数据后,通过sci发送到串口助手。现在IPC通信正常,CPU1能够收到CPU2发送的数据,但是CPU1不能往外发送数据,不知道是什么原因,具体代码如下:
//
// Included Files
//
#include "driverlib.h"
#include "device.h"
#include "ipc.h"
//
// Defines
//
#define IPC_CMD_READ_MEM 0x1001
#define IPC_CMD_RESP 0x2001
#define TEST_PASS 0x5555
#define TEST_FAIL 0xAAAA
#pragma DATA_SECTION(readData, "MSGRAM_CPU2_TO_CPU1") //
//char sdData[170]={'#',',',1,',',2,',',3,',',4,',',5,',',6,'*'};
//char sdData[170]={'#',11,0,3,5,77,36,152,0};
char sdData[17]={1,2,3,4,5,6,7,8,'\n'};
uint32_t readData[17]={0};
char send_flag=0;
uint32_t pass; //
//
// Main
//
void main(void)
{
int i;
//
// Initialize device clock and peripherals
//
Device_init();
//
// Initialize PIE and clear PIE registers. Disables CPU interrupts.
//
Interrupt_initModule();
//
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
//
Interrupt_initVectorTable();
//
// Clear any IPC flags if set already
//
//IPC_clearFlagLtoR(IPC_CPU2_L_CPU1_R, IPC_FLAG_ALL);
IPC_clearFlagLtoR(IPC_CPU2_L_CPU1_R, IPC_FLAG_ALL); ////
//
// Enable IPC interrupts
//
// IPC_registerInterrupt(IPC_CPU2_L_CPU1_R, IPC_INT0, IPC_ISR0);
// Synchronize both the cores.
//
IPC_sync(IPC_CPU2_L_CPU1_R, IPC_FLAG31);
for(i=0; i<17; i++)
{
readData[i] = sdData[i];
}
send_flag=1;
while(1)
{
if(send_flag)
{
//
// Send a message without message queue
// Length of the data to be read is passed as data.
//
IPC_sendCommand(IPC_CPU2_L_CPU1_R, IPC_FLAG0, IPC_ADDR_CORRECTION_ENABLE,
IPC_CMD_READ_MEM, (uint32_t)readData, 17); ///数据长度
//
// Wait for acknowledgment
//
IPC_waitForAck(IPC_CPU2_L_CPU1_R, IPC_FLAG0);
//
// Read response
//
if(IPC_getResponse(IPC_CPU2_L_CPU1_R) == TEST_PASS)
{
pass = 1;
}
else
{
pass = 0;
}
}
}
}
//
// Included Files
//
#include "driverlib.h"
#include "device.h"
//
// Defines
//
#define IPC_CMD_READ_MEM 0x1001
#define IPC_CMD_RESP 0x2001
#define TEST_PASS 0x5555
#define TEST_FAIL 0xAAAA
//Define variables ////
//
char CPU2_flag=0;
char start_flag = 0;
char start_cnt = 0;
uint32_t recbuf[17]={0};
char recbuf1[17]={0};
//
// Function prototypes
//
__interrupt void IPC_ISR0(); ////
//
// Main
//
void main(void)
{
int t = 0;
//
// Initialize device clock and peripherals
//
Device_init();
//
// Boot CPU2 core
//
#ifdef _FLASH
Device_bootCPU2(BOOTMODE_BOOT_TO_FLASH_SECTOR0);
#else
Device_bootCPU2(BOOTMODE_BOOT_TO_M0RAM);
#endif
//
// Initialize PIE and clear PIE registers. Disables CPU interrupts.
//
Interrupt_initModule();
//
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
//
Interrupt_initVectorTable();
//
// Clear any IPC flags if set already
//
IPC_clearFlagLtoR(IPC_CPU1_L_CPU2_R, IPC_FLAG_ALL);
IPC_registerInterrupt(IPC_CPU1_L_CPU2_R, IPC_INT0, IPC_ISR0);
//
// Synchronize both the cores.
//
IPC_sync(IPC_CPU1_L_CPU2_R, IPC_FLAG31);
//Configure SCIB&SCIC
//
SCI_setConfig(SCIB_BASE, DEVICE_LSPCLK_FREQ, 256000, (SCI_CONFIG_WLEN_8 | SCI_CONFIG_STOP_ONE | SCI_CONFIG_PAR_NONE));
SCI_resetChannels(SCIB_BASE);
SCI_enableModule(SCIB_BASE);
SCI_performSoftwareReset(SCIB_BASE);
SCI_setConfig(SCIC_BASE, DEVICE_LSPCLK_FREQ, 230400, (SCI_CONFIG_WLEN_8 | SCI_CONFIG_STOP_ONE | SCI_CONFIG_PAR_NONE));
SCI_resetChannels(SCIC_BASE);
SCI_enableModule(SCIC_BASE);
SCI_performSoftwareReset(SCIC_BASE);
//
// Enable Global Interrupt (INTM) and realtime interrupt (DBGM)
//
EINT;
ERTM;
//
// Loop forever. Wait for IPC interrupt
//
while(1)
{
if(CPU2_flag)
{
CPU2_flag = 0;
for(t=0;t<17;t++)
{
recbuf1[t]=recbuf[t];
recbuf[t]=0; //测试使用
}
for(t=0;t<17;t++)
{
SCI_writeCharBlockingNonFIFO(SCIB_BASE, recbuf1[t]); //会给CPU2_flag赋1
if(recbuf1[t] == '\n')
{
recbuf1[t] = 0;
break;
}
recbuf1[t] = 0;
}
}
}
}
__interrupt void IPC_ISR0()
{
int i=0;
int count=0;
uint32_t command, addr, data;
bool status = false;
//
// Read the command
//
IPC_readCommand(IPC_CPU1_L_CPU2_R, IPC_FLAG0, IPC_ADDR_CORRECTION_ENABLE,
&command, &addr, &data);
if(command == IPC_CMD_READ_MEM)
{
status = true;
//
// Read and compare data
//
for(i=0; i<data; i++)
{
recbuf[i]=*((uint32_t *)addr + i);
count++;
if(count == 9)
{
CPU2_flag=1;
count=0;
break;
}
}
}
//if(*((uint32_t *)addr + i) != i)
//status = false;
//
// Send response to C28x core
//
if(status)
{
IPC_sendResponse(IPC_CPU1_L_CPU2_R, TEST_PASS);
}
else
{
IPC_sendResponse(IPC_CPU1_L_CPU2_R, TEST_FAIL);
}
//
// Acknowledge the flag
//
IPC_ackFlagRtoL(IPC_CPU1_L_CPU2_R, IPC_FLAG0);
//
// Acknowledge the PIE interrupt.
//
Interrupt_clearACKGroup(INTERRUPT_ACK_GROUP1);
}
