//****************************************************************************** // MSP430xG46x Demo - USCI_A0, SPI 3-Wire Master Incremented Data // // Description: SPI master talks to SPI slave using 3-wire mode. Incrementing // data is sent by the master starting at 0x01. Received data is expected to // be same as the previous transmission. USCI RX ISR is used to handle // communication with the CPU, normally in LPM0. If high, P5.1 indicates // valid data reception. Because all execution after LPM0 is in ISRs, // initialization waits for DCO to stabilize against ACLK. // ACLK = 32.768kHz, MCLK = SMCLK = DCO ~ 1048kHz. BRCLK = SMCLK/2 // // Use with SPI Slave Data Echo code example. If slave is in debug mode, P5.2 // slave reset signal conflicts with slave's JTAG; to work around, use IAR's // "Release JTAG on Go" on slave device. If breakpoints are set in // slave RX ISR, master must stopped also to avoid overrunning slave // RXBUF. // // MSP430FG4619 // ----------------- // /|\| XIN|- // | | | 32kHz xtal // --|RST XOUT|- // | | // | P7.1|-> Data Out (UCA0SIMO) // | | // LED <-|P5.1 P7.2|<- Data In (UCA0SOMI) // | | // Slave reset <-|P5.2 P7.3|-> Serial Clock Out (UCA0CLK) // // // K. Quiring/ M. Mitchell // Texas Instruments Inc. // October 2006 // Built with IAR Embedded Workbench Version: 3.41A //****************************************************************************** #include unsigned char MST_Data,SLV_Data; void main(void) { volatile unsigned int i; WDTCTL = WDTPW+WDTHOLD; // Stop watchdog timer FLL_CTL0 |= XCAP14PF; // Configure load caps // Wait for xtal to stabilize do { IFG1 &= ~OFIFG; // Clear OSCFault flag for (i = 0x47FF; i > 0; i--); // Time for flag to set } while ((IFG1 & OFIFG)); // OSCFault flag still set? for(i=2100;i>0;i--); // Now with stable ACLK, wait for // DCO to stabilize. P5OUT = 0x04; // P5 setup for LED and slave reset P5DIR |= 0x06; // P7SEL |= 0x0E; // P7.3,2,1 option select UCA0CTL0 |= UCMST+UCSYNC+UCCKPL+UCMSB; //3-pin, 8-bit SPI master UCA0CTL1 |= UCSSEL_2; // SMCLK UCA0BR0 = 0x02; // /2 UCA0BR1 = 0; // UCA0MCTL = 0; // No modulation UCA0CTL1 &= ~UCSWRST; // **Initialize USCI state machine** IE2 |= UCA0RXIE; // Enable USCI_A0 RX interrupt P5OUT &= ~0x04; // Now with SPI signals initialized, P5OUT |= 0x04; // reset slave for(i=50;i>0;i--); // Wait for slave to initialize MST_Data = 0x001; // Initialize data values SLV_Data = 0x000; // UCA0TXBUF = MST_Data; // Transmit first character _BIS_SR(LPM0_bits + GIE); // CPU off, enable interrupts } #pragma vector=USCIAB0RX_VECTOR __interrupt void USCIA0RX_ISR (void) { volatile unsigned int i; while (!(IFG2 & UCA0TXIFG)); // USART1 TX buffer ready? if (UCA0RXBUF==SLV_Data) // Test for correct character RX'd P5OUT |= 0x02; // If correct, light LED else P5OUT &= ~0x02; // If incorrect, clear LED MST_Data++; // Increment data SLV_Data++; UCA0TXBUF = MST_Data; // Send next value for(i=30;i>0;i--); // Add time between transmissions to } // make sure slave can keep up