// TI File $Revision: /main/10 $ // Checkin $Date: April 21, 2008 15:43:02 $ //########################################################################### // // FILE: Example_2833xI2c_eeprom.c // // TITLE: DSP2833x I2C EEPROM Example // // ASSUMPTIONS: // // This program requires the DSP2833x header files. // // This program requires an external I2C EEPROM connected to // the I2C bus at address 0x50. // // As supplied, this project is configured for "boot to SARAM" // operation. The 2833x Boot Mode table is shown below. // For information on configuring the boot mode of an eZdsp, // please refer to the documentation included with the eZdsp, // // $Boot_Table: // // GPIO87 GPIO86 GPIO85 GPIO84 // XA15 XA14 XA13 XA12 // PU PU PU PU // ========================================== // 1 1 1 1 Jump to Flash // 1 1 1 0 SCI-A boot // 1 1 0 1 SPI-A boot // 1 1 0 0 I2C-A boot // 1 0 1 1 eCAN-A boot // 1 0 1 0 McBSP-A boot // 1 0 0 1 Jump to XINTF x16 // 1 0 0 0 Jump to XINTF x32 // 0 1 1 1 Jump to OTP // 0 1 1 0 Parallel GPIO I/O boot // 0 1 0 1 Parallel XINTF boot // 0 1 0 0 Jump to SARAM <- "boot to SARAM" // 0 0 1 1 Branch to check boot mode // 0 0 1 0 Boot to flash, bypass ADC cal // 0 0 0 1 Boot to SARAM, bypass ADC cal // 0 0 0 0 Boot to SCI-A, bypass ADC cal // Boot_Table_End$ // // DESCRIPTION: // // This program will write 1-14 words to EEPROM and read them back. // The data written and the EEPROM address written to are contained // in the message structure, I2cMsgOut1. The data read back will be // contained in the message structure I2cMsgIn1. // // This program will work with the on-board I2C EEPROM supplied on // the F2833x eZdsp. // // //########################################################################### // Original Author: D.F. // // $TI Release: DSP2833x/DSP2823x Header Files V1.20 $ // $Release Date: August 1, 2008 $ //########################################################################### #include "DSP28x_Project.h" // Device Headerfile and Examples Include File // Note: I2C Macros used in this example can be found in the // DSP2833x_I2C_defines.h file // Prototype statements for functions found within this file. void I2CA_Init(void); Uint16 I2CA_WriteData(struct I2CMSG *msg); Uint16 I2CA_ReadData(struct I2CMSG *msg); interrupt void i2c_int1a_isr(void); void pass(void); void fail(void); #define I2C_SLAVE_ADDR 0x50 #define I2C_NUMBYTES 4 #define I2C_EEPROM_HIGH_ADDR 0x00 #define I2C_EEPROM_LOW_ADDR 0x30 // Global variables // Two bytes will be used for the outgoing address, // thus only setup 14 bytes maximum struct I2CMSG I2cMsgOut1={I2C_MSGSTAT_SEND_WITHSTOP, I2C_SLAVE_ADDR, I2C_NUMBYTES, I2C_EEPROM_HIGH_ADDR, I2C_EEPROM_LOW_ADDR, 0x12, // Msg Byte 1 0x34, // Msg Byte 2 0x56, // Msg Byte 3 0x78, // Msg Byte 4 0x9A, // Msg Byte 5 0xBC, // Msg Byte 6 0xDE, // Msg Byte 7 0xF0, // Msg Byte 8 0x11, // Msg Byte 9 0x10, // Msg Byte 10 0x11, // Msg Byte 11 0x12, // Msg Byte 12 0x13, // Msg Byte 13 0x12}; // Msg Byte 14 struct I2CMSG I2cMsgIn1={ I2C_MSGSTAT_SEND_NOSTOP, I2C_SLAVE_ADDR, I2C_NUMBYTES, I2C_EEPROM_HIGH_ADDR, I2C_EEPROM_LOW_ADDR}; struct I2CMSG *CurrentMsgPtr; // Used in interrupts Uint16 PassCount; Uint16 FailCount; void main(void) { Uint16 Error; Uint16 i; CurrentMsgPtr = &I2cMsgOut1; // Step 1. Initialize System Control: // PLL, WatchDog, enable Peripheral Clocks // This example function is found in the DSP2833x_SysCtrl.c file. InitSysCtrl(); // Step 2. Initalize GPIO: // This example function is found in the DSP2833x_Gpio.c file and // illustrates how to set the GPIO to it's default state. // InitGpio(); // Setup only the GP I/O only for I2C functionality InitI2CGpio(); // 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 DSP2833x_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 DSP2833x_DefaultIsr.c. // This function is found in DSP2833x_PieVect.c. InitPieVectTable(); // Interrupts that are used in this example are re-mapped to // ISR functions found within this file. EALLOW; // This is needed to write to EALLOW protected registers PieVectTable.I2CINT1A = &i2c_int1a_isr; EDIS; // This is needed to disable write to EALLOW protected registers // Step 4. Initialize all the Device Peripherals: // This function is found in DSP2833x_InitPeripherals.c // InitPeripherals(); // Not required for this example I2CA_Init(); // Step 5. User specific code // Clear Counters PassCount = 0; FailCount = 0; // Clear incoming message buffer for (i = 0; i < I2C_MAX_BUFFER_SIZE; i++) { I2cMsgIn1.MsgBuffer[i] = 0x0000; } // Enable interrupts required for this example // Enable I2C interrupt 1 in the PIE: Group 8 interrupt 1 PieCtrlRegs.PIEIER8.bit.INTx1 = 1; // Enable CPU INT8 which is connected to PIE group 8 IER |= M_INT8; EINT; // Application loop for(;;) { ////////////////////////////////// // Write data to EEPROM section // ////////////////////////////////// // Check the outgoing message to see if it should be sent. // In this example it is initialized to send with a stop bit. if(I2cMsgOut1.MsgStatus == I2C_MSGSTAT_SEND_WITHSTOP) { Error = I2CA_WriteData(&I2cMsgOut1); // If communication is correctly initiated, set msg status to busy // and update CurrentMsgPtr for the interrupt service routine. // Otherwise, do nothing and try again next loop. Once message is // initiated, the I2C interrupts will handle the rest. Search for // ICINTR1A_ISR in the i2c_eeprom_isr.c file. if (Error == I2C_SUCCESS) { CurrentMsgPtr = &I2cMsgOut1; I2cMsgOut1.MsgStatus = I2C_MSGSTAT_WRITE_BUSY; } } // end of write section /////////////////////////////////// // Read data from EEPROM section // /////////////////////////////////// // Check outgoing message status. Bypass read section if status is // not inactive. if (I2cMsgOut1.MsgStatus == I2C_MSGSTAT_INACTIVE) { // Check incoming message status. if(I2cMsgIn1.MsgStatus == I2C_MSGSTAT_SEND_NOSTOP) { // EEPROM address setup portion while(I2CA_ReadData(&I2cMsgIn1) != I2C_SUCCESS) { // Maybe setup an attempt counter to break an infinite while // loop. The EEPROM will send back a NACK while it is performing // a write operation. Even though the write communique is // complete at this point, the EEPROM could still be busy // programming the data. Therefore, multiple attempts are // necessary. } // Update current message pointer and message status CurrentMsgPtr = &I2cMsgIn1; I2cMsgIn1.MsgStatus = I2C_MSGSTAT_SEND_NOSTOP_BUSY; } // Once message has progressed past setting up the internal address // of the EEPROM, send a restart to read the data bytes from the // EEPROM. Complete the communique with a stop bit. MsgStatus is // updated in the interrupt service routine. else if(I2cMsgIn1.MsgStatus == I2C_MSGSTAT_RESTART) { // Read data portion while(I2CA_ReadData(&I2cMsgIn1) != I2C_SUCCESS) { // Maybe setup an attempt counter to break an infinite while // loop. } // Update current message pointer and message status CurrentMsgPtr = &I2cMsgIn1; I2cMsgIn1.MsgStatus = I2C_MSGSTAT_READ_BUSY; } } // end of read section } // end of for(;;) } // end of main void I2CA_Init(void) { // Initialize I2C I2caRegs.I2CSAR = 0x0050; // Slave address - EEPROM control code #if (CPU_FRQ_150MHZ) // Default - For 150MHz SYSCLKOUT I2caRegs.I2CPSC.all = 14; // Prescaler - need 7-12 Mhz on module clk (150/15 = 10MHz) #endif #if (CPU_FRQ_100MHZ) // For 100 MHz SYSCLKOUT I2caRegs.I2CPSC.all = 9; // Prescaler - need 7-12 Mhz on module clk (100/10 = 10MHz) #endif I2caRegs.I2CCLKL = 10; // NOTE: must be non zero I2caRegs.I2CCLKH = 5; // NOTE: must be non zero I2caRegs.I2CIER.all = 0x24; // Enable SCD & ARDY interrupts I2caRegs.I2CMDR.all = 0x0020; // Take I2C out of reset // Stop I2C when suspended I2caRegs.I2CFFTX.all = 0x6000; // Enable FIFO mode and TXFIFO I2caRegs.I2CFFRX.all = 0x2040; // Enable RXFIFO, clear RXFFINT, return; } Uint16 I2CA_WriteData(struct I2CMSG *msg) { Uint16 i; // Wait until the STP bit is cleared from any previous master communication. // Clearing of this bit by the module is delayed until after the SCD bit is // set. If this bit is not checked prior to initiating a new message, the // I2C could get confused. if (I2caRegs.I2CMDR.bit.STP == 1) { return I2C_STP_NOT_READY_ERROR; } // Setup slave address I2caRegs.I2CSAR = msg->SlaveAddress; // Check if bus busy if (I2caRegs.I2CSTR.bit.BB == 1) { return I2C_BUS_BUSY_ERROR; } // Setup number of bytes to send // MsgBuffer + Address I2caRegs.I2CCNT = msg->NumOfBytes+2; // Setup data to send I2caRegs.I2CDXR = msg->MemoryHighAddr; I2caRegs.I2CDXR = msg->MemoryLowAddr; // for (i=0; iNumOfBytes-2; i++) for (i=0; iNumOfBytes; i++) { I2caRegs.I2CDXR = *(msg->MsgBuffer+i); } // Send start as master transmitter I2caRegs.I2CMDR.all = 0x6E20; return I2C_SUCCESS; } Uint16 I2CA_ReadData(struct I2CMSG *msg) { // Wait until the STP bit is cleared from any previous master communication. // Clearing of this bit by the module is delayed until after the SCD bit is // set. If this bit is not checked prior to initiating a new message, the // I2C could get confused. if (I2caRegs.I2CMDR.bit.STP == 1) { return I2C_STP_NOT_READY_ERROR; } I2caRegs.I2CSAR = msg->SlaveAddress; if(msg->MsgStatus == I2C_MSGSTAT_SEND_NOSTOP) { // Check if bus busy if (I2caRegs.I2CSTR.bit.BB == 1) { return I2C_BUS_BUSY_ERROR; } I2caRegs.I2CCNT = 2; I2caRegs.I2CDXR = msg->MemoryHighAddr; I2caRegs.I2CDXR = msg->MemoryLowAddr; I2caRegs.I2CMDR.all = 0x2620; // Send data to setup EEPROM address } else if(msg->MsgStatus == I2C_MSGSTAT_RESTART) { I2caRegs.I2CCNT = msg->NumOfBytes; // Setup how many bytes to expect I2caRegs.I2CMDR.all = 0x2C20; // Send restart as master receiver } return I2C_SUCCESS; } interrupt void i2c_int1a_isr(void) // I2C-A { Uint16 IntSource, i; // Read interrupt source IntSource = I2caRegs.I2CISRC.all; // Interrupt source = stop condition detected if(IntSource == I2C_SCD_ISRC) { // If completed message was writing data, reset msg to inactive state if (CurrentMsgPtr->MsgStatus == I2C_MSGSTAT_WRITE_BUSY) { CurrentMsgPtr->MsgStatus = I2C_MSGSTAT_INACTIVE; } else { // If a message receives a NACK during the address setup portion of the // EEPROM read, the code further below included in the register access ready // interrupt source code will generate a stop condition. After the stop // condition is received (here), set the message status to try again. // User may want to limit the number of retries before generating an error. if(CurrentMsgPtr->MsgStatus == I2C_MSGSTAT_SEND_NOSTOP_BUSY) { CurrentMsgPtr->MsgStatus = I2C_MSGSTAT_SEND_NOSTOP; } // If completed message was reading EEPROM data, reset msg to inactive state // and read data from FIFO. else if (CurrentMsgPtr->MsgStatus == I2C_MSGSTAT_READ_BUSY) { CurrentMsgPtr->MsgStatus = I2C_MSGSTAT_INACTIVE; for(i=0; i < I2C_NUMBYTES; i++) { CurrentMsgPtr->MsgBuffer[i] = I2caRegs.I2CDRR; } { // Check recieved data for(i=0; i < I2C_NUMBYTES; i++) { if(I2cMsgIn1.MsgBuffer[i] == I2cMsgOut1.MsgBuffer[i]) { PassCount++; } else { FailCount++; } } if(PassCount == I2C_NUMBYTES) { pass(); } else { fail(); } } } } } // end of stop condition detected // Interrupt source = Register Access Ready // This interrupt is used to determine when the EEPROM address setup portion of the // read data communication is complete. Since no stop bit is commanded, this flag // tells us when the message has been sent instead of the SCD flag. If a NACK is // received, clear the NACK bit and command a stop. Otherwise, move on to the read // data portion of the communication. else if(IntSource == I2C_ARDY_ISRC) { if(I2caRegs.I2CSTR.bit.NACK == 1) { I2caRegs.I2CMDR.bit.STP = 1; I2caRegs.I2CSTR.all = I2C_CLR_NACK_BIT; } else if(CurrentMsgPtr->MsgStatus == I2C_MSGSTAT_SEND_NOSTOP_BUSY) { CurrentMsgPtr->MsgStatus = I2C_MSGSTAT_RESTART; } } // end of register access ready else { // Generate some error due to invalid interrupt source asm(" ESTOP0"); } // Enable future I2C (PIE Group 8) interrupts PieCtrlRegs.PIEACK.all = PIEACK_GROUP8; } void pass() { asm(" ESTOP0"); for(;;); } void fail() { asm(" ESTOP0"); for(;;); } //=========================================================================== // No more. //===========================================================================