Code:
+// --------------------------------------------------------------------- // S628.c Study/experiment with interrupt driven serial // communications with a PIC-equiped device as DCE. // // Author: Rob Hamerling. // Date: February 2004. // E-mail: info@robh.nl // homepage: http://www.robh.nl // --------------------------------------------------------------------- // // Function: echo incoming datastream from DTE back to DTE // Features: // - Interrupt driven, high speed, full duplex data flow (57600 bps) // - Use of builtin USART in RS232 mode (8 bits, no parity). // - With relatively large receive buffer. // - Using CTS flow control (PC -> PIC). // PC-side should have set CTS output flow control enabled, // PC FiFo transmit load count may be set to 16 (max). // - While DTE inactive (RTS false) the PIC slumbers. It gives a 'being // alive' signal by slowly flashing the RTS light. It is waked-up by // RB0 (to which RTS is connected) // - Note: no RTS flow control (PIC -> PC)! // // Language support: CC5X compiler version 3.1 // // Hardware: PIC 16F628 or similar with UART, and MAX232. // // // --------------------------------------------------------------------- // // Simplified schematics: // COMx plug // PIC16F628 MAX232 RS232 DB9 DB25 // +-------------+ +-----------+ // | | | | // | RA2 (1)|-----|(11)---(14)|--->-- CTS --- 8 5 // | RB0 (6)|-----|(12)---(13)|---<-- RTS --- 7 4 // | | | | // | RB1 (7)|-----|(9)-----(8)|---<-- TxD --- 3 2 // | RB2 (8)|-----|(10)----(7)|--->-- RxD --- 2 3 // | | | | // | (5) | | (15) | // +------|------+ +----|------+ // +-----------------+----------- GND --- 5 7 // // +-< DTR --- 4 20 // Optional cable wraps: | // (maybe required by PC softw.) +-> DSR --- 6 6 // +-> DCD --- 1 8 // // --------------------------------------------------------------------- // Some basic PIC and RS232 knowledge will be needed to fully understand // the data flow and control signalling used in this program. // // The PIC ports use positive logic: // '1' is positive voltage, '0' is ground. // // This program uses positive logic for boolean variables: // the symbol TRUE for '1', the symbol FALSE for '0'. // // In the RS232 standard: // - Negative voltage ('mark') means OFF for control signals, and // indicates 1 (one) for a data signals (start-, data-, stop-bits). // - Positive voltage ('space') means ON for control signals and // 0 (zero) for start-, data- and stop-bits. // // Since the MAX232 is not only a level convertor (between TTL and RS232) // but also a signal inverter, you should be aware of the following: // - The inversion of PIC data-in and data-out by the MAX232 is required // to convert data-, start- and stop-bits to/from the corresponding // RS232 polarity. So nothing special has to be done in the program. // - For RTS and CTS the inversion by the MAX232 inversion is NOT desired, // and therefore the program uses inverted signaling for RTS and CTS: // 'FALSE' is used for ON and 'TRUE' for OFF with RTS/CTS signals! // As a reminder for this 'inversed' logic the signals are called // here CTSinv and RTSinv. // // ------------------------------------------------------------------------- // For other examples and useful learning material see also: // - MicroChip datasheets (for the PIC16F62X: DS30400C). // - Tony Kubek's example for the PIC16F876, // ASM, interrupt driven, no CTS flow control, single byte buffer. // - Fr. Thomas MacGhee's example for the PIC16C74, // ASM, not interrupt driven, but contains many educational notes. // ------------------------------------------------------------------------- #pragma chip PIC16F628 // target PIC #include <int16cxx.h> // interrupt support #pragma config &= ~0b11.1111.1111.1111 // all OFF #pragma config |= 0b11.1111.0110.0110 // x xx FOSC = HS // x WDT enabled // x x BOD enabled (forces /PWRTE) // x LVP disabled (makes RB4 free) // xxxxxxx no memory protection #pragma config ID = 0x6281 // firmware ID (optional) #pragma bit CTSinv @ PORTA.2 // CTS signal to DTE (PC) #pragma bit RTSinv @ PORTB.0 // RTS signal from DTE (PC) #pragma bit RTSled @ PORTB.3 // visual RTS signal typedef bit BOOL, BOOLEAN; // boolean variable type(s) #define FALSE 0 // PIC: off, low #define TRUE 1 // PIC: on, high #define OSCFREQ 20000000 // oscillator frequency #define TMR1COUNT (OSCFREQ/4/1000) // 16-bits count for 1 ms // (prescaler 1:1) #define BPSRATE 57600 // desired speed #define BPSCLASS TRUE // BRGH setting (high) #define BPSCOUNT ((10*OSCFREQ/16/BPSRATE-5)/10) // SPBRG (BRGH=1) // closest integer value #define XMTBUFSIZE 32 // output buffer size #define RCVBUFSIZE 64 // input buffer size #define DELTA 17 // minimum free rcv buffer .. // .. space (PC UARTFiFo + 1) int8 xmtoffset; // offset next byte to xmit int8 putoffset; // offset last appl. out byte int8 rcvoffset; // offset next byte to receive int8 getoffset; // offset last appl. in byte char xmtbuf[XMTBUFSIZE]; // circular output buffer bank1 char rcvbuf[RCVBUFSIZE]; // circular input buffer // located in RAM bank1! // ---------------------------- // Interrupt service routine // ---------------------------- #pragma origin 4 // hardware requirement extern interrupt isr(void) { char save_FSR; // FSR save byte char x; // intermediate byte value int_save_registers // save registers save_FSR = FSR; // save FSR if (TXIF == TRUE && TXIE == TRUE) { // RS232 transmit interrupt if (xmtoffset != putoffset) { // still data in xmit buffer x = xmtbuf[xmtoffset]; // next char to xmit if (++xmtoffset >= XMTBUFSIZE) // update offset xmtoffset = 0; // wrap if (xmtoffset == putoffset) // was this last byte? TXIE = FALSE; // disable xmit interrupts TXREG = x; // now actually xmit char } } if (RCIF == TRUE && RCIE == TRUE) { // RS232 receive interrupt if (OERR == TRUE) { // overrun, reset UART CREN = FALSE; // disable UART CREN = TRUE; // re-enable UART } // discard pending bytes else if (FERR == TRUE) { // framing error (break?) getoffset = 0; // flush buffers xmtoffset = 0; putoffset = 0; rcvoffset = 1; rcvbuf[0] = RCREG; // move byte to rcv buffer CTSinv = TRUE; // ensure CTS is true } else { // data without errors rcvbuf[rcvoffset] = RCREG; // move byte to rcv buffer x = rcvoffset + 1; // offset next byte if (x >= RCVBUFSIZE) // beyond buffer boundary x = 0; // wrap to begin if (x != getoffset) // buffer not yet full rcvoffset = x; // update offset, // (else discard byte, // CTS flow control failed) if (CTSinv == FALSE) { // CTS is TRUE x = getoffset - rcvoffset; // offset difference if (x <= 0) // wrapping effect x += RCVBUFSIZE; // wrapping correction if (x < DELTA) // buffer reaches 'full' CTSinv = TRUE; // make CTS FALSE } } } if (INTE == TRUE && INTF == TRUE) { // RB0 change interrupt // nothing to do, just .. INTF = FALSE; // .. wake-up from sleep } /* Note: Other interrupts disabled, so no further checks needed */ FSR = save_FSR; // restore FSR int_restore_registers // restore other } // ----------------------------------------------- // copy output bytes of caller // from: application buffer // to: interrupt controlled transmit buffer // // returns nothing // // notes: - initiates transmission (interrupt handler) // when not currently transmitting // - spin when transmission buffer full // (wait for free buffer space) // ----------------------------------------------- static void putdata(char *buffer, char bytesout) { char i; // counter(s) char x; // intermediate byte value for (i=0; i<bytesout; i++) { // all user data x = buffer[i]; // copy char xmtbuf[putoffset] = x; // .. to buffer x = putoffset + 1; // next char if (x >= XMTBUFSIZE) // beyond buffer boundary x = 0; while (x == xmtoffset) // buffer full! ; // spin until something xmit'd putoffset = x; // update offset TXIE = TRUE; // (re-)enable xmit interrupts } } // ---------------------------------------------------------------- // copy input bytes to callers buffer // from: interrupt controlled receive buffer // to: application buffer // returns: number of bytes actually stored in application buffer // // notes: - rise CTS when receive buffer has more than <DELTA>> // bytes free space after delivering data to caller. // ---------------------------------------------------------------- static char getdata(char *buffer, // application buffer char bufsize) { // size of appl. buffer char i, x; for (i=0; i<bufsize; i++) { // fill user buffer (max) if (getoffset == rcvoffset) // no more data break; x = rcvbuf[getoffset]; // copy char buffer[i] = x; // .. to user buffer if (++getoffset >= RCVBUFSIZE) // update offset getoffset = 0; } if (CTSinv == TRUE) { // (CTS is FALSE) x = getoffset - rcvoffset; // offset difference if (x <= 0) // wrapping effect x += RCVBUFSIZE; // wrapping correction if (x >= DELTA) // enough free space now CTSinv = FALSE; // (make CTS TRUE) } return i; // number of bytes returned } // ------------------------------------------------------- // Perform all required initial PIC setup // ------------------------------------------------------- static void setup() { CMCON = 0b0000.0111; // Comparator off CCP1CON = 0b0000.0000; // Capt/Comp/PWM off OPTION = 0b0000.1111; // WDT prescaler 1:128 T1CON = 0b0000.0001; // Timer1 enabled, presc 1:1 INTCON = 0; // all interrupt bits off PIR1 = 0; // .. INTEDG = 0; // int at falling edge RB0 // (= rising of RTS!) PORTA = 0; // all ports zero PORTB = 0; // .. TRISA = 0b0010.0000; // IN: RA5/MCLR TRISB = 0b0001.0011; // IN: RB0,1,4 PIE1 = 0; // disable all ext. interrupts BRGH = BPSCLASS; // baudrate class SPBRG = BPSCOUNT; // baudrate clock divisor TXEN = TRUE; // enable UART transmit SYNC = FALSE; // async mode RCIE = TRUE; // enable receive interrupts SPEN = TRUE; // enable UART CREN = TRUE; // enable UART receive PEIE = TRUE; // enable external interrupts INTE = TRUE; // RB0 (RTSinv) change GIE = TRUE; // globally enable interrupts } // ------------------------------------------------------------------- // Milliseconds delay by using TMR1 as 16-bits counter // // See top of source for the value of TMR1COUNT // ------------------------------------------------------------------- static void msdelay(char millisec) { uns16 usTimeCount; // value of Timer1 do { TMR1H = 0; // restart Timer1 .. TMR1L = 0; // .. counting do { usTimeCount = (uns16)TMR1H << 8; // take high byte value usTimeCount += TMR1L; // aad low byte value } while (usTimeCount < TMR1COUNT); // pause 1 millisecond } while (--millisec > 0); // number of milliseconds } // ------------------------------------------------------------------- // Keep PIC in slumbering state: sleep most of the time // // Flash a LED as visual 'being alive' signal // // ------------------------------------------------------------------- static void waitforRTS(void) { char ucOptionSave; // option reg at entry ucOptionSave = OPTION; // save OPTION register while (RTSinv == TRUE) { // waiting for RTS OPTION = 0b0000.1111; // WDT postscaler 1:128 sleep(); // wait for RB0 or Watchdog RTSled = TRUE; // RTS LED on OPTION = 0b0000.1001; // WDT postscaler 1:2 sleep(); // duration of RTS LED flash RTSled = FALSE; // RTS LED off } OPTION = ucOptionSave; // restore OPTION to original } // =============================================================== // // M A I N L I N E // // Initially CTS is set false and the program waits for // RTS to become true before activating the echo loop. // When RTS become true, CTS follows, which allows the // DTE to send data. The echo loop remains active as // long as RTS remains true. When RTS becomes false the // echo-loop is terminated and the PIC reset to its initial // state, waiting for RTS. // // =============================================================== extern void main(void) { char i, k, l; // counter(s) char buffer[20]; // local I/O buffer const char *welcome = "Echo from S628\n\r"; // welcome! setup(); // init PIC for (;;) { // forever RTSled = FALSE; // assume RTS false CTSinv = TRUE; // CTS FALSE waitforRTS(); // in slumbering state RTSled = TRUE; // show RTS status CTSinv = FALSE; // CTS TRUE xmtoffset = 0; // (re-)init .. putoffset = 0; // .. input and .. rcvoffset = 0; // .. output .. getoffset = 0; // .. buffer offsets for (i=0; welcome[i] != '\0'; i++) { // copy msg to I/O buffer k = welcome[i]; buffer[i] = k; } putdata(buffer, i); // send msg to DTE while (RTSinv == FALSE) { // RTS true l = getdata(buffer, sizeof(buffer)); // get input if (l > 0) // something received putdata(buffer, l); // echo the input else // nothing received msdelay(25); // do 'low priority' work clrwdt(); // reset watchdog } } }
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BUg on lineJames Newton replies: Ah! Very common and annoying error. X is being ASSIGNED the value of RCVBUFSIZE rather then being compaired to it. It should be "if (x==RCVBUFSIZE)" and the best coding style to avoid makeing this mistake is to always put the constant first. E.g. "if (RCVBUFSIZE==X)" becuase if you only put in one "=" the compiler will show you the error.+
if (x = RCVBUFSIZE) // beyond buffer boundary
x = 0; // wrap to begin
note the missing = in the if statement drove me mad for we while!
file: /Techref/microchip/language/c/S628.htm, 20KB, , updated: 2007/10/7 13:15, local time: 2024/11/11 12:37,
owner: RH-planet-b,
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©2024 These pages are served without commercial sponsorship. (No popup ads, etc...).Bandwidth abuse increases hosting cost forcing sponsorship or shutdown. This server aggressively defends against automated copying for any reason including offline viewing, duplication, etc... Please respect this requirement and DO NOT RIP THIS SITE. Questions? <A HREF="http://massmind.org/techref/microchip/language/c/S628.htm"> Interrupt driven routines, using PIC hardware USART,with CTS flow control. Source code for CC5X C compiler with amplecomments, easily adaptable to other PICs than the sample 16F628.</A> |
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