PIC32MX: I2C Communication between PIC32s
From Mech
Original Assignment
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Your assignment is to create code that allows two PIC32s to communicate via I2C.
Overview
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Circuit
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Code
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Master Code
/******************************************************* * I2C_Master.c: Master code for I2C communication. * * Both PICS use I2C1 module to send/ recieve data.* * The master sends different values to a slave, * * which uses an interrupt to respond accordingly. * * * * Hardware: 2 PIC32MX460F512L PICs on NU32 boards * ******************************************************* * Thomas Peterson, James Rein, Eric West * * ME333 Winter 2010 * * File Created: 05-FEB-2010 * * Last Modified: 14-FEB-2010 * *******************************************************/ #include "HardwareProfile.h" #include <plib.h> #define SYSCLK (80000000) #define PBCLK (SYSCLK) #pragma config FPBDIV = DIV_1 //Sets PBCLK to SYSCLK #define Fsck 50000 //Frequency of (I2C) serial clock #define Nop() asm( "nop" ) //No-operation; asm stands for assembly, using an assembly command in C. Cool! #define INPUT_A9 PORTAbits.RA9 #define INPUT_A10 PORTAbits.RA10 //function declaration for sending data and selecting slave address void SendData(int,unsigned int); void Delayms( unsigned t); /* This function is a delay function, causing the program to wait for approximately 4 * cnt cycles 1 cycle is 1/SYSCLK seconds. */ void i2c_wait(unsigned int cnt) { while(--cnt) { Nop(); Nop(); } } /* Main function */ int main(void) { // Configure the proper PB frequency and the number of wait states. SYSTEMConfigPerformance(SYS_FREQ); // Set all analog pins to be digital I/O AD1PCFG = 0xFFFF; //Setup TRIS bits for switches and I2C pins TRISAbits.TRISA14=0; TRISAbits.TRISA15=0; //Initialize all of the LED pins mInitAllLEDs(); mInitAllSwitches() unsigned char SlaveAddress; //Slave address variable to tell the master where to send the data. //Will be re-assigned for multiple slaves. //Enable I2C channel and set the baud rate to BRG_VAL) OpenI2C1( I2C_EN, BRG_VAL ); int rcv; //For received data //While loop to test LED functionality while(1) { if (swProgram) { //First button pressed while(swProgram) { Nop(); } //Wait for release mLED_2_Toggle(); //Toggle LED2 SendData(0xAA,0x40); //Sends hex data 0xAA to slave address 0x40 rcv = RcvData(0x40); //Receives data from address 0x40 Delayms(100); } if (swUser) { //Second button pressed while(swUser) { Nop(); } mLED_1_Toggle(); //Toggle LED1 SendData(0x23,0x40); //Sends hex data 0xAA to slave address 0x40 rcv = RcvData(0x40); //Receives data from address 0x40 Delayms(100); } }//while loop ending return 0; } //ending main /***************************************************** * RcvData(unsigned int address) * * * * Gets a byte of data from I2C slave device at * * ADDRESS. * * * * Returns: Received data * ****************************************************/ int RcvData(unsigned int address) { StartI2C1(); //Send line start condition IdleI2C1(); //Wait to complete MasterWriteI2C1((address << 1) | 1); //Write out slave address OR 1 (read command) IdleI2C1(); //Wait to complete int rcv = MasterReadI2C1(); //Read in a value StopI2C1(); //Send line stop condition IdleI2C1(); //Wait co complete return rcv; //Return read value } /*************************************************** * SendData(int data, unsigned int address) * * * * Sends a byte of data (DATA) over the I2C line * * to I2C address ADDRESS * * * * Returns: nothing * ***************************************************/ void SendData (int data, unsigned int address){ StartI2C1(); //Send the Start Bit IdleI2C1(); //Wait to complete MasterWriteI2C1((address << 1) | 0); //Sends the slave address over the I2C line. This must happen first so the //proper slave is selected to receive data. IdleI2C1(); //Wait to complete MasterWriteI2C1(data); //Sends data byte over I2C line IdleI2C1(); //Wait to complete StopI2C1(); //Send the Stop condition IdleI2C1(); //Wait to complete } //end function void Delayms( unsigned t) // This uses Timer 1, can be changed to another timer. Assumes FPB = SYS_FREQ { OpenTimer1(T1_ON | T1_PS_1_256, 0xFFFF); while (t--) { // t x 1ms loop WriteTimer1(0); while (ReadTimer1() < SYS_FREQ/256/1000); } CloseTimer1(); } // Delayms
Slave Code
/*********************************************************************** * PIC32 I2C Slave Code ***********************************************************************/ #include "GenericTypeDefs.h" #include "Compiler.h" #include "HardwareProfile.h" #include <plib.h> #define SYSCLK (80000000) #define PBCLK (SYSCLK) #define Fsck 50000 #define BRG_VAL ((PBCLK/2/Fsck)-2) // this is the modules Slave Address #define SLAVE_ADDRESS 0x40 // volatile variables to hold the switch and led states volatile unsigned char dataRead = 0; /////////////////////////////////////////////////////////////////// // // InitI2C // // Perform initialisation of the I2C module to operate as a slave // /////////////////////////////////////////////////////////////////// void InitI2C(void) { unsigned char temp; // Enable the I2C module with clock stretching enabled OpenI2C1(I2C_ON | I2C_7BIT_ADD | I2C_STR_EN, BRG_VAL); // set the address of the slave module, address matching is with bits // 7:1 of the message compared with bits 6:0 of the ADD SFR so we // need to shift the desired address 1 bit. I2C1ADD = SLAVE_ADDRESS; // >> 1; I2C1MSK = 0; // configure the interrupt priority for the I2C peripheral mI2C1SetIntPriority(I2C_INT_PRI_3 | I2C_INT_SLAVE); // clear pending interrupts and enable I2C interrupts mI2C1SClearIntFlag(); EnableIntSI2C1; } /////////////////////////////////////////////////////////////////// // // main routine // // This code example demonstrates using the PIC32 as an I2C slave // // /////////////////////////////////////////////////////////////////// int main (void) { // set for 80MHz operation SYSTEMConfigPerformance(SYSCLK); // set the Pbus to be 40000000 mOSCSetPBDIV(OSC_PB_DIV_2); // disable the JTAG port mJTAGPortEnable(0); // enable interrupts INTEnableSystemMultiVectoredInt(); InitI2C(); mInitAllLEDs(); // main loop while (1) { /* If global variable "dataRead" is set high during interrupt, turn on all LEDs */ if (dataRead == 0xAA) { mLED_0_On(); mLED_1_On(); mLED_2_On(); mLED_3_On(); } } } /////////////////////////////////////////////////////////////////// // // Slave I2C interrupt handler // This handler is called when a qualifying I2C events occurs // this means that as well as Slave events // Master and Bus Collision events will also trigger this handler. // /////////////////////////////////////////////////////////////////// void __ISR(_I2C_1_VECTOR, ipl3) _SlaveI2CHandler(void) { mLED_1_On(); unsigned char temp; static unsigned int dIndex; // check for MASTER and Bus events and respond accordingly if (IFS0bits.I2C1MIF == 1) { mI2C1MClearIntFlag(); return; } if (IFS0bits.I2C1BIF == 1) { mI2C1BClearIntFlag(); return; } mLED_1_Off(); mLED_2_On(); // handle the incoming message if ((I2C1STATbits.R_W == 0) && (I2C1STATbits.D_A == 0)) { // R/W bit = 0 --> indicates data transfer is input to slave // D/A bit = 0 --> indicates last byte was address // reset any state variables needed by a message sequence // perform a dummy read of the address temp = SlaveReadI2C1(); mLED_3_On(); mLED_2_Off(); // release the clock to restart I2C I2C1CONbits.SCLREL = 1; // release the clock } else if ((I2C1STATbits.R_W == 0) && (I2C1STATbits.D_A == 1)) { // R/W bit = 0 --> indicates data transfer is input to slave // D/A bit = 1 --> indicates last byte was data mLED_3_On(); mLED_2_On(); // writing data to our module, just store it in adcSample dataRead = SlaveReadI2C1(); // release the clock to restart I2C I2C1CONbits.SCLREL = 1; // release clock stretch bit } else if ((I2C1STATbits.R_W == 1) && (I2C1STATbits.D_A == 0)) { // R/W bit = 1 --> indicates data transfer is output from slave // D/A bit = 1 --> indicates last byte was address mLED_0_On(); mLED_2_Off(); // read of the slave device, read the address temp = SlaveReadI2C1(); dIndex = 0; SlaveWriteI2C1(dataRead); } else if ((I2C1STATbits.R_W == 1) && (I2C1STATbits.D_A == 1)) { // R/W bit = 1 --> indicates data transfer is input to slave // D/A bit = 1 --> indicates last byte was data mLED_0_On(); mLED_2_On(); // output the data until the MASTER terminates the // transfer with a NACK, continuing reads return 0 if (dIndex == 0) { SlaveWriteI2C1(dataRead); dIndex++; } else SlaveWriteI2C1(0); } // finally clear the slave interrupt flag mI2C1SClearIntFlag(); }