// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- // // 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::arg *Menu::_argv; AP_HAL::BetterStream *Menu::_port; // constructor Menu::Menu(const char *prompt, const Menu::command *commands, uint8_t entries, preprompt ppfunc) : _prompt(prompt), _commands(commands), _entries(entries), _ppfunc(ppfunc), _commandline_max(MENU_COMMANDLINE_MAX), _args_max(MENU_ARGS_MAX) { // the buffers are initially NULL, then they are allocated on // first use _inbuf = NULL; _argv = NULL; } /** check for another input byte on the port and accumulate return true if we have a full line ready to process */ bool Menu::_check_for_input(void) { if (_port->available() <= 0) { return false; } // loop reading characters from the input int c = _port->read(); // carriage return -> process command if ('\r' == c || '\n' == c) { _inbuf[_input_len] = '\0'; _port->write('\r'); _port->write('\n'); // we have a full line to process return true; } // backspace if ('\b' == c) { if (_input_len > 0) { _input_len--; _port->write('\b'); _port->write(' '); _port->write('\b'); return false; } } // printable character if (isprint(c) && (_input_len < (_commandline_max - 1))) { _inbuf[_input_len++] = c; _port->write((char)c); } return false; } // display the prompt void Menu::_display_prompt(void) { _port->printf("%s] ", _prompt); } // run the menu bool Menu::_run_command(bool prompt_on_enter) { int8_t ret; uint8_t i; uint8_t argc; char *s = NULL; _input_len = 0; // split the input line into tokens argc = 0; s = NULL; _argv[argc++].str = strtok_r(_inbuf, " ", &s); // XXX should an empty line by itself back out of the current menu? while (argc <= _args_max) { _argv[argc].str = strtok_r(NULL, " ", &s); if (_argv[argc].str == NULL || '\0' == _argv[argc].str[0]) break; _argv[argc].i = atol(_argv[argc].str); _argv[argc].f = atof(_argv[argc].str); // calls strtod, > 700B ! argc++; } if (_argv[0].str == NULL) { // we got a blank line, re-display the prompt if (prompt_on_enter) { _display_prompt(); } return false; } // 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 <= _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(_argv[0].str, _commands[i].command)) { ret = _call(i, argc); cmd_found=true; if (-2 == ret) return true; break; } } // implicit commands if (i == _entries) { if (!strcmp(_argv[0].str, "?") || (!strcasecmp(_argv[0].str, "help"))) { _help(); cmd_found=true; } else if (!strcasecmp(_argv[0].str, "exit")) { // exit the menu return true; } } if (cmd_found==false) { _port->println("Invalid command, type 'help'"); } return false; } // run the menu void Menu::run(void) { if (_port == NULL) { // default to main serial port _port = hal.console; } _allocate_buffers(); _display_prompt(); // loop performing commands for (;;) { // run the pre-prompt function, if one is defined if (_ppfunc) { if (!_ppfunc()) return; _display_prompt(); } // loop reading characters from the input _input_len = 0; for (;; ) { if (_check_for_input()) { break; } hal.scheduler->delay(20); } // we have a full command to run if (_run_command(false)) break; _display_prompt(); } } // check for new user input bool Menu::check_input(void) { if (_port == NULL) { // default to main serial port _port = hal.console; } _allocate_buffers(); if (_check_for_input()) { return _run_command(true); } return false; } // display the list of commands in response to the 'help' command void Menu::_help(void) { int i; _port->println("Commands:"); for (i = 0; i < _entries; i++) { hal.scheduler->delay(10); _port->printf(" %s\n", _commands[i].command); } } // run the n'th command in the menu int8_t Menu::_call(uint8_t n, uint8_t argc) { func fn; pgm_read_block(&_commands[n].func, &fn, sizeof(fn)); return(fn(argc, &_argv[0])); } /** set limits on max args and command line length */ void Menu::set_limits(uint8_t commandline_max, uint8_t args_max) { if (_inbuf != NULL) { delete[] _inbuf; _inbuf = NULL; } if (_argv != NULL) { delete[] _argv; _argv = NULL; } // remember limits, the buffers will be allocated by allocate_buffers() _commandline_max = commandline_max; _args_max = args_max; } void Menu::_allocate_buffers(void) { /* only allocate if the buffers are NULL */ if (_inbuf == NULL) { _inbuf = new char[_commandline_max]; memset(_inbuf, 0, _commandline_max); } if (_argv == NULL) { _argv = new arg[_args_max+1]; memset(_argv, 0, (_args_max+1) * sizeof(_argv[0])); } }