例程是TI的例程：
#include "DSP280x_Device.h" // DSP280x Headerfile Include File
#include "DSP280x_Examples.h" // DSP280x Examples Include File

// Prototype statements for functions found within this file.
void mailbox_check(int32 T1, int32 T2, int32 T3);
void mailbox_read(int16 i);

// Global variable for this example
Uint32 ErrorCount;
Uint32 PassCount;
Uint32 MessageReceivedCount;

Uint32 TestMbox1 = 0;
Uint32 TestMbox2 = 0;
Uint32 TestMbox3 = 0;

void main(void)
{

Uint16 j;

// eCAN control registers require read/write access using 32-bits. Thus we
// will create a set of shadow registers for this example. These shadow
// registers will be used to make sure the access is 32-bits and not 16.
struct ECAN_REGS ECanaShadow;

// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the DSP280x_SysCtrl.c file.
InitSysCtrl();

// Step 2. Initalize GPIO:
// This example function is found in the DSP280x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example

// For this example, configure CAN pins using GPIO regs here
// This function is found in DSP280x_ECan.c
InitECanGpio();

// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
DINT;

// Initialize PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the DSP280x_PieCtrl.c file.
InitPieCtrl();

// Disable CPU interrupts and clear all CPU interrupt flags:
IER = 0x0000;
IFR = 0x0000;

// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in DSP280x_DefaultIsr.c.
// This function is found in DSP280x_PieVect.c.
InitPieVectTable();

// Step 4. Initialize all the Device Peripherals:
// This function is found in DSP280x_InitPeripherals.c
// InitPeripherals(); // Not required for this example

// Step 5. User specific code, enable interrupts:

MessageReceivedCount = 0;
ErrorCount = 0;
PassCount = 0;

// eCAN control registers require 32-bit access.
// If you want to write to a single bit, the compiler may break this
// access into a 16-bit access. One solution, that is presented here,
// is to use a shadow register to force the 32-bit access.

// Read the entire register into a shadow register. This access
// will be 32-bits. Change the desired bit and copy the value back
// to the eCAN register with a 32-bit write.

// Configure the eCAN RX and TX pins for eCAN transmissions
EALLOW;
ECanaShadow.CANTIOC.all = ECanaRegs.CANTIOC.all;
ECanaShadow.CANTIOC.bit.TXFUNC = 1;
ECanaRegs.CANTIOC.all = ECanaShadow.CANTIOC.all;

ECanaShadow.CANRIOC.all = ECanaRegs.CANRIOC.all;
ECanaShadow.CANRIOC.bit.RXFUNC = 1;
ECanaRegs.CANRIOC.all = ECanaShadow.CANRIOC.all;
EDIS;

// Disable all Mailboxes
// Since this write is to the entire register (instead of a bit
// field) a shadow register is not required.
ECanaRegs.CANME.all = 0;

// Mailboxs can be written to 16-bits or 32-bits at a time
// Write to the MSGID field of TRANSMIT mailboxes MBOX0 - 15
ECanaMboxes.MBOX0.MSGID.all = 0x9555AAA0;
ECanaMboxes.MBOX1.MSGID.all = 0x9555AAA1;
ECanaMboxes.MBOX2.MSGID.all = 0x9555AAA2;
ECanaMboxes.MBOX3.MSGID.all = 0x9555AAA3;
ECanaMboxes.MBOX4.MSGID.all = 0x9555AAA4;
ECanaMboxes.MBOX5.MSGID.all = 0x9555AAA5;
ECanaMboxes.MBOX6.MSGID.all = 0x9555AAA6;
ECanaMboxes.MBOX7.MSGID.all = 0x9555AAA7;
ECanaMboxes.MBOX8.MSGID.all = 0x9555AAA8;
ECanaMboxes.MBOX9.MSGID.all = 0x9555AAA9;
ECanaMboxes.MBOX10.MSGID.all = 0x9555AAAA;
ECanaMboxes.MBOX11.MSGID.all = 0x9555AAAB;
ECanaMboxes.MBOX12.MSGID.all = 0x9555AAAC;
ECanaMboxes.MBOX13.MSGID.all = 0x9555AAAD;
ECanaMboxes.MBOX14.MSGID.all = 0x9555AAAE;
ECanaMboxes.MBOX15.MSGID.all = 0x9555AAAF;

// Write to the MSGID field of RECEIVE mailboxes MBOX16 - 31
ECanaMboxes.MBOX16.MSGID.all = 0x9555AAA0;
ECanaMboxes.MBOX17.MSGID.all = 0x9555AAA1;
ECanaMboxes.MBOX18.MSGID.all = 0x9555AAA2;
ECanaMboxes.MBOX19.MSGID.all = 0x9555AAA3;
ECanaMboxes.MBOX20.MSGID.all = 0x9555AAA4;
ECanaMboxes.MBOX21.MSGID.all = 0x9555AAA5;
ECanaMboxes.MBOX22.MSGID.all = 0x9555AAA6;
ECanaMboxes.MBOX23.MSGID.all = 0x9555AAA7;
ECanaMboxes.MBOX24.MSGID.all = 0x9555AAA8;
ECanaMboxes.MBOX25.MSGID.all = 0x9555AAA9;
ECanaMboxes.MBOX26.MSGID.all = 0x9555AAAA;
ECanaMboxes.MBOX27.MSGID.all = 0x9555AAAB;
ECanaMboxes.MBOX28.MSGID.all = 0x9555AAAC;
ECanaMboxes.MBOX29.MSGID.all = 0x9555AAAD;
ECanaMboxes.MBOX30.MSGID.all = 0x9555AAAE;
ECanaMboxes.MBOX31.MSGID.all = 0x9555AAAF;

// Configure Mailboxes 0-15 as Tx, 16-31 as Rx
// Since this write is to the entire register (instead of a bit
// field) a shadow register is not required.
ECanaRegs.CANMD.all = 0xFFFF0000;

// Enable all Mailboxes */
// Since this write is to the entire register (instead of a bit
// field) a shadow register is not required.
ECanaRegs.CANME.all = 0xFFFFFFFF;

// Specify that 8 bits will be sent/received
ECanaMboxes.MBOX0.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX1.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX2.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX3.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX4.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX5.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX6.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX7.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX8.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX9.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX10.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX11.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX12.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX13.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX14.MSGCTRL.bit.DLC = 8;
ECanaMboxes.MBOX15.MSGCTRL.bit.DLC = 8;

// No remote frame is requested
// Since RTR bit is undefined upon reset,
// it must be initialized to the proper value
ECanaMboxes.MBOX0.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX1.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX2.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX3.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX4.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX5.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX6.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX7.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX8.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX9.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX10.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX11.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX12.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX13.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX14.MSGCTRL.bit.RTR = 0;
ECanaMboxes.MBOX15.MSGCTRL.bit.RTR = 0;

// Write to the mailbox RAM field of MBOX0 - 15
ECanaMboxes.MBOX0.MDL.all = 0x9555AAA0;
ECanaMboxes.MBOX0.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX1.MDL.all = 0x9555AAA1;
ECanaMboxes.MBOX1.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX2.MDL.all = 0x9555AAA2;
ECanaMboxes.MBOX2.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX3.MDL.all = 0x9555AAA3;
ECanaMboxes.MBOX3.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX4.MDL.all = 0x9555AAA4;
ECanaMboxes.MBOX4.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX5.MDL.all = 0x9555AAA5;
ECanaMboxes.MBOX5.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX6.MDL.all = 0x9555AAA6;
ECanaMboxes.MBOX6.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX7.MDL.all = 0x9555AAA7;
ECanaMboxes.MBOX7.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX8.MDL.all = 0x9555AAA8;
ECanaMboxes.MBOX8.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX9.MDL.all = 0x9555AAA9;
ECanaMboxes.MBOX9.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX10.MDL.all = 0x9555AAAA;
ECanaMboxes.MBOX10.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX11.MDL.all = 0x9555AAAB;
ECanaMboxes.MBOX11.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX12.MDL.all = 0x9555AAAC;
ECanaMboxes.MBOX12.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX13.MDL.all = 0x9555AAAD;
ECanaMboxes.MBOX13.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX14.MDL.all = 0x9555AAAE;
ECanaMboxes.MBOX14.MDH.all = 0x89ABCDEF;

ECanaMboxes.MBOX15.MDL.all = 0x9555AAAF;
ECanaMboxes.MBOX15.MDH.all = 0x89ABCDEF;

// Since this write is to the entire register (instead of a bit
// field) a shadow register is not required.
EALLOW;
ECanaRegs.CANMIM.all = 0xFFFFFFFF;

// Request permission to change the configuration registers
ECanaShadow.CANMC.all = ECanaRegs.CANMC.all;
ECanaShadow.CANMC.bit.CCR = 1;
ECanaRegs.CANMC.all = ECanaShadow.CANMC.all;
EDIS;

// Wait until the CPU has been granted permission to change the
// configuration registers
// Wait for CCE bit to be set..
do
{
ECanaShadow.CANES.all = ECanaRegs.CANES.all;
} while(ECanaShadow.CANES.bit.CCE != 1 );

// Configure the eCAN timing
EALLOW;
ECanaShadow.CANBTC.all = ECanaRegs.CANBTC.all;

ECanaShadow.CANBTC.bit.BRPREG = 9; // (BRPREG + 1) = 10 feeds a 15 MHz CAN clock
ECanaShadow.CANBTC.bit.TSEG2REG = 5 ; // to the CAN module. (150 / 10 = 15)
ECanaShadow.CANBTC.bit.TSEG1REG = 7; // Bit time = 15
ECanaRegs.CANBTC.all = ECanaShadow.CANBTC.all;

ECanaShadow.CANMC.all = ECanaRegs.CANMC.all;
ECanaShadow.CANMC.bit.CCR = 0;
ECanaRegs.CANMC.all = ECanaShadow.CANMC.all;
EDIS;

// Wait until the CPU no longer has permission to change the
// configuration registers
do
{
ECanaShadow.CANES.all = ECanaRegs.CANES.all;
} while(ECanaShadow.CANES.bit.CCE != 0 );

// Configure the eCAN for self test mode
// Enable the enhanced features of the eCAN.
EALLOW;
ECanaShadow.CANMC.all = ECanaRegs.CANMC.all;
ECanaShadow.CANMC.bit.STM = 1; // Configure CAN for self-test mode
ECanaShadow.CANMC.bit.SCB = 1; // eCAN mode (reqd to access 32 mailboxes)
ECanaRegs.CANMC.all = ECanaShadow.CANMC.all;
EDIS;

// Begin transmitting
for(;;)
{

ECanaRegs.CANTRS.all = 0x0000FFFF; // Set TRS for all transmit mailboxes
while(ECanaRegs.CANTA.all != 0x0000FFFF ) {} // Wait for all TAn bits to be set..
ECanaRegs.CANTA.all = 0x0000FFFF; // Clear all TAn
MessageReceivedCount++;

//Read from Receive mailboxes and begin checking for data */
for(j=0; j<16; j++) // Read & check 16 mailboxes
{
mailbox_read(j); // This func reads the indicated mailbox data
mailbox_check(TestMbox1,TestMbox2,TestMbox3); // Checks the received data
}
}
}

// This function reads out the contents of the indicated
// by the Mailbox number (MBXnbr).
void mailbox_read(int16 MBXnbr)
{
volatile struct MBOX *Mailbox;
Mailbox = &ECanaMboxes.MBOX0 + MBXnbr;
TestMbox1 = Mailbox->MDL.all; // = 0x9555AAAn (n is the MBX number)
TestMbox2 = Mailbox->MDH.all; // = 0x89ABCDEF (a constant)
TestMbox3 = Mailbox->MSGID.all;// = 0x9555AAAn (n is the MBX number)

} // MSGID of a rcv MBX is transmitted as the MDL data.


void mailbox_check(int32 T1, int32 T2, int32 T3)
{
if((T1 != T3) || ( T2 != 0x89ABCDEF))
{
ErrorCount++;
}
else
{
PassCount++;
}
}

怎么不正确的 把结果发出来啊

你可以自己自循环测试一下。

建议把单片机串口工作方式改成方式三，波特率和其他的不用变。再然串口调试软件接收数据看看。