91beb8670f
The cc65 tool chain comes with V.24 drivers so it seems reasonable to use the existing Contiki SLIP driver to implement network access via SLIP as alternative to Ethernet. Some notes: - The Ethernet configuration was simplified in order to allow share it with SLIP. - The Contiki SLIP driver presumes an interrupt driven serial receiver to write into the SLIP buffer. However the cc65 V.24 drivers aren't up to that. Therefore the main loops were extended to pull received data from the V.24 buffers and push it into the SLIP buffer. - As far as I understand the serial sender is supposed to block until the data is sent. Therefore a loop calls the non-blocking V.24 driver until the data is sent. On all platforms there's only one V.24 driver available. Therefore V.24 drivers are always loaded statically. On the Apple][ the mouse driver is now loaded statically - independently from SLIP vs. Ethernet. After all there's only one mouse driver available. However there's a major benefit with SLIP: Here all drivers are loaded statically. Therefore the dynamic module loader isn't necessary at all. And without the loader the heap manager isn't necessary at all. This allows for a reduction in code size roughly compensating for the size of the SLIP buffer.
106 lines
2.2 KiB
C
106 lines
2.2 KiB
C
#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <serial.h>
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#include "cfs/cfs.h"
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static struct {
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char *screen;
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uint8_t value;
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} baud[] = {
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{" 300 baud", SER_BAUD_300},
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{" 600 baud", SER_BAUD_600},
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{" 1200 baud", SER_BAUD_1200},
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{" 2400 baud", SER_BAUD_2400},
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{" 4800 baud", SER_BAUD_4800},
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{" 9600 baud", SER_BAUD_9600},
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{"19200 baud", SER_BAUD_19200}
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};
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static struct {
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char *screen;
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uint8_t value;
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} stop[] = {
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{"1 stop bit", SER_STOP_1},
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{"2 stop bits", SER_STOP_2}
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};
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static struct {
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char *screen;
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uint8_t value;
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} parity[] = {
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{" No parity", SER_PAR_NONE},
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{" Odd parity", SER_PAR_ODD},
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{"Even parity", SER_PAR_EVEN}
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};
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uint8_t ipcfg[16];
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struct ser_params params;
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/*-----------------------------------------------------------------------------------*/
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uint8_t
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choose(uint8_t max)
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{
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char val;
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do {
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printf("\n?");
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val = getchar();
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} while(val < '0' || val > max + '0');
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putchar('\n');
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if(val == '0') {
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exit(0);
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}
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putchar('\n');
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return val - '0';
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}
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/*-----------------------------------------------------------------------------------*/
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void
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main(void)
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{
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int f;
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uint8_t c;
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f = cfs_open("contiki.cfg", CFS_READ);
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if(f == -1) {
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printf("Loading Config - Error\n");
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return;
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}
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cfs_read(f, ipcfg, sizeof(ipcfg));
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cfs_close(f);
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for(c = 0; c < sizeof(baud) / sizeof(baud[0]); ++c) {
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printf("%d: %s\n", c + 1, baud[c].screen);
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}
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params.baudrate = baud[choose(c) - 1].value;
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params.databits = SER_BITS_8;
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for(c = 0; c < sizeof(stop) / sizeof(stop[0]); ++c) {
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printf("%d: %s\n", c + 1, stop[c].screen);
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}
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params.stopbits = stop[choose(c) - 1].value;
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for(c = 0; c < sizeof(parity) / sizeof(parity[0]); ++c) {
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printf("%d: %s\n", c + 1, parity[c].screen);
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}
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params.parity = parity[choose(c) - 1].value;
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params.handshake = SER_HS_HW;
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f = cfs_open("contiki.cfg", CFS_WRITE);
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if(f == -1) {
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printf("\nSaving Config - Error\n");
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return;
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}
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cfs_write(f, ipcfg, sizeof(ipcfg));
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cfs_write(f, ¶ms, sizeof(params));
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cfs_close(f);
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printf("Saving Config - Done\n");
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}
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/*-----------------------------------------------------------------------------------*/
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