// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: t -*- // // Simple commandline menu system. // #include #include #include #include #include #include #include "AP_Menu.h" extern const AP_HAL::HAL& hal; // statics char Menu::_inbuf[MENU_COMMANDLINE_MAX]; Menu::arg Menu::_argv[MENU_ARGS_MAX + 1]; AP_HAL::BetterStream *Menu::_port; // constructor Menu::Menu(const prog_char *prompt, const Menu::command *commands, uint8_t entries, preprompt ppfunc) : _prompt(prompt), _commands(commands), _entries(entries), _ppfunc(ppfunc) { } // run the menu void Menu::run(void) { int8_t ret; uint8_t len, i; uint8_t argc; int c; char *s; if (_port == NULL) { // default to main serial port _port = hal.console; } // loop performing commands for (;;) { // run the pre-prompt function, if one is defined if ((NULL != _ppfunc) && !_ppfunc()) return; // loop reading characters from the input len = 0; _port->printf_P(PSTR("%S] "), FPSTR(_prompt)); for (;; ) { c = _port->read(); if (-1 == c) continue; // carriage return -> process command if ('\r' == c) { _inbuf[len] = '\0'; _port->write('\r'); _port->write('\n'); break; } // backspace if ('\b' == c) { if (len > 0) { len--; _port->write('\b'); _port->write(' '); _port->write('\b'); continue; } } // printable character if (isprint(c) && (len < (MENU_COMMANDLINE_MAX - 1))) { _inbuf[len++] = c; _port->write((char)c); continue; } } // split the input line into tokens argc = 0; _argv[argc++].str = strtok_r(_inbuf, " ", &s); // XXX should an empty line by itself back out of the current menu? while (argc <= MENU_ARGS_MAX) { _argv[argc].str = strtok_r(NULL, " ", &s); if ('\0' == _argv[argc].str) break; _argv[argc].i = atol(_argv[argc].str); _argv[argc].f = atof(_argv[argc].str); // calls strtod, > 700B ! argc++; } if (_argv[0].str == NULL) { continue; } // populate arguments that have not been specified with "" and 0 // this is safer than NULL in the case where commands may look // without testing argc i = argc; while (i <= MENU_ARGS_MAX) { _argv[i].str = ""; _argv[i].i = 0; _argv[i].f = 0; i++; } bool cmd_found = false; // look for a command matching the first word (note that it may be empty) for (i = 0; i < _entries; i++) { if (!strcasecmp_P(_argv[0].str, _commands[i].command)) { ret = _call(i, argc); cmd_found=true; if (-2 == ret) return; break; } } // implicit commands if (i == _entries) { if (!strcmp(_argv[0].str, "?") || (!strcasecmp_P(_argv[0].str, PSTR("help")))) { _help(); cmd_found=true; } else if (!strcasecmp_P(_argv[0].str, PSTR("exit"))) { return; } } if (cmd_found==false) { _port->println_P(PSTR("Invalid command, type 'help'")); } } } // display the list of commands in response to the 'help' command void Menu::_help(void) { int i; _port->println_P(PSTR("Commands:")); for (i = 0; i < _entries; i++) { hal.scheduler->delay(10); _port->printf_P(PSTR(" %S\n"), FPSTR(_commands[i].command)); } } // run the n'th command in the menu int8_t Menu::_call(uint8_t n, uint8_t argc) { func fn; fn = (func)pgm_read_pointer(&_commands[n].func); return(fn(argc, &_argv[0])); }