///////////////////////////////////////////////////////////////////////// // $Id: siminterface.cc,v 1.110 2005-10-15 10:43:55 vruppert Exp $ ///////////////////////////////////////////////////////////////////////// // // See siminterface.h for description of the siminterface concept. // Basically, the siminterface is visible from both the simulator and // the configuration user interface, and allows them to talk to each other. #include "bochs.h" #include "iodev.h" bx_simulator_interface_c *SIM = NULL; logfunctions *siminterface_log = NULL; #define LOG_THIS siminterface_log-> // bx_simulator_interface just defines the interface that the Bochs simulator // and the gui will use to talk to each other. None of the methods of // bx_simulator_interface are implemented; they are all virtual. The // bx_real_sim_c class is a child of bx_simulator_interface_c, and it // implements all the methods. The idea is that a gui needs to know only // definition of bx_simulator_interface to talk to Bochs. The gui should // not need to include bochs.h. // // I made this separation to ensure that all guis use the siminterface to do // access bochs internals, instead of accessing things like // bx_keyboard.s.internal_buffer[4] (or whatever) directly. -Bryce // class bx_real_sim_c : public bx_simulator_interface_c { bxevent_handler bxevent_callback; void *bxevent_callback_data; const char *registered_ci_name; config_interface_callback_t ci_callback; void *ci_callback_data; int init_done; bx_param_c **param_registry; int registry_alloc_size; int enabled; // save context to jump to if we must quit unexpectedly jmp_buf *quit_context; int exit_code; public: bx_real_sim_c (); virtual ~bx_real_sim_c (); virtual void set_quit_context (jmp_buf *context) { quit_context = context; } virtual int get_init_done () { return init_done; } virtual int set_init_done (int n) { init_done = n; return 0;} virtual void get_param_id_range (int *min, int *max) { *min = BXP_NULL; *max = BXP_THIS_IS_THE_LAST-1; } virtual int register_param (bx_id id, bx_param_c *it); virtual void reset_all_param (); virtual bx_param_c *get_param (bx_id id); virtual bx_param_num_c *get_param_num (bx_id id); virtual bx_param_string_c *get_param_string (bx_id id); virtual bx_param_bool_c *get_param_bool (bx_id id); virtual bx_param_enum_c *get_param_enum (bx_id id); virtual int get_n_log_modules (); virtual char *get_prefix (int mod); virtual int get_log_action (int mod, int level); virtual void set_log_action (int mod, int level, int action); virtual char *get_action_name (int action); virtual int get_default_log_action (int level) { return logfunctions::get_default_action (level); } virtual void set_default_log_action (int level, int action) { logfunctions::set_default_action (level, action); } virtual const char *get_log_level_name (int level); virtual int get_max_log_level (); virtual void quit_sim (int code); virtual int get_exit_code () { return exit_code; } virtual int get_default_rc (char *path, int len); virtual int read_rc (char *path); virtual int write_rc (char *path, int overwrite); virtual int get_log_file (char *path, int len); virtual int set_log_file (char *path); virtual int get_log_prefix (char *prefix, int len); virtual int set_log_prefix (char *prefix); virtual int get_debugger_log_file (char *path, int len); virtual int set_debugger_log_file (char *path); virtual int get_floppy_options (int drive, bx_floppy_options *out); virtual int get_cdrom_options (int drive, bx_atadevice_options *out, int *device = NULL); virtual char *get_floppy_type_name (int type); virtual void set_notify_callback (bxevent_handler func, void *arg); virtual void get_notify_callback (bxevent_handler *func, void **arg); virtual BxEvent* sim_to_ci_event (BxEvent *event); virtual int log_msg (const char *prefix, int level, const char *msg); virtual int ask_param (bx_id which); // ask the user for a pathname virtual int ask_filename (char *filename, int maxlen, char *prompt, char *the_default, int flags); // called at a regular interval, currently by the keyboard handler. virtual void periodic (); virtual int create_disk_image (const char *filename, int sectors, bx_bool overwrite); virtual void refresh_ci (); virtual void refresh_vga () { // maybe need to check if something has been initialized yet? DEV_vga_refresh(); } virtual void handle_events () { // maybe need to check if something has been initialized yet? bx_gui->handle_events (); } // find first hard drive or cdrom bx_param_c *get_first_atadevice (Bit32u search_type); bx_param_c *get_first_cdrom () { return get_first_atadevice (BX_ATA_DEVICE_CDROM); } bx_param_c *get_first_hd () { return get_first_atadevice (BX_ATA_DEVICE_DISK); } #if BX_DEBUGGER virtual void debug_break (); virtual void debug_interpret_cmd (char *cmd); virtual char *debug_get_next_command (); virtual void debug_puts (const char *cmd); #endif virtual void register_configuration_interface ( const char* name, config_interface_callback_t callback, void *userdata); virtual int configuration_interface(const char* name, ci_command_t command); virtual int begin_simulation (int argc, char *argv[]); virtual void set_sim_thread_func (is_sim_thread_func_t func) {} virtual bool is_sim_thread (); bool wxsel; virtual bool is_wx_selected () { return wxsel; } // provide interface to bx_gui->set_display_mode() method for config // interfaces to use. virtual void set_display_mode (disp_mode_t newmode) { if (bx_gui != NULL) bx_gui->set_display_mode (newmode); } virtual bool test_for_text_console (); }; bx_param_c * bx_real_sim_c::get_param (bx_id id) { BX_ASSERT (id >= BXP_NULL && id < BXP_THIS_IS_THE_LAST); int index = (int)id - BXP_NULL; bx_param_c *retval = param_registry[index]; if (!retval) BX_INFO (("get_param can't find id %u", id)); return retval; } bx_param_num_c * bx_real_sim_c::get_param_num (bx_id id) { bx_param_c *generic = get_param(id); if (generic==NULL) { BX_PANIC (("get_param_num(%u) could not find a parameter", id)); return NULL; } int type = generic->get_type (); if (type == BXT_PARAM_NUM || type == BXT_PARAM_BOOL || type == BXT_PARAM_ENUM) return (bx_param_num_c *)generic; BX_PANIC (("get_param_num %u could not find an integer parameter with that id", id)); return NULL; } bx_param_string_c * bx_real_sim_c::get_param_string (bx_id id) { bx_param_c *generic = get_param(id); if (generic==NULL) { BX_PANIC (("get_param_string(%u) could not find a parameter", id)); return NULL; } if (generic->get_type () == BXT_PARAM_STRING) return (bx_param_string_c *)generic; BX_PANIC (("get_param_string %u could not find an integer parameter with that id", id)); return NULL; } bx_param_bool_c * bx_real_sim_c::get_param_bool (bx_id id) { bx_param_c *generic = get_param(id); if (generic==NULL) { BX_PANIC (("get_param_bool(%u) could not find a parameter", id)); return NULL; } if (generic->get_type () == BXT_PARAM_BOOL) return (bx_param_bool_c *)generic; BX_PANIC (("get_param_bool %u could not find a bool parameter with that id", id)); return NULL; } bx_param_enum_c * bx_real_sim_c::get_param_enum (bx_id id) { bx_param_c *generic = get_param(id); if (generic==NULL) { BX_PANIC (("get_param_enum(%u) could not find a parameter", id)); return NULL; } if (generic->get_type () == BXT_PARAM_ENUM) return (bx_param_enum_c *)generic; BX_PANIC (("get_param_enum %u could not find a enum parameter with that id", id)); return NULL; } void bx_init_siminterface () { siminterface_log = new logfunctions (); siminterface_log->put ("CTRL"); siminterface_log->settype(CTRLLOG); if (SIM == NULL) SIM = new bx_real_sim_c(); } bx_simulator_interface_c::bx_simulator_interface_c () { } bx_real_sim_c::bx_real_sim_c () { bxevent_callback = NULL; bxevent_callback_data = NULL; ci_callback = NULL; ci_callback_data = NULL; is_sim_thread_func = NULL; wxsel = false; enabled = 1; int i; init_done = 0; registry_alloc_size = BXP_THIS_IS_THE_LAST - BXP_NULL; param_registry = new bx_param_c* [registry_alloc_size]; for (i=0; i= BXP_NULL && id < BXP_THIS_IS_THE_LAST); int index = (int)id - BXP_NULL; if (this->param_registry[index] != NULL) { BX_INFO (("register_param is overwriting parameter id %d", id)); } this->param_registry[index] = it; return 0; } void bx_real_sim_c::reset_all_param () { bx_reset_options (); } int bx_real_sim_c::get_n_log_modules () { return io->get_n_logfns (); } char * bx_real_sim_c::get_prefix (int mod) { logfunc_t *logfn = io->get_logfn (mod); return logfn->getprefix (); } int bx_real_sim_c::get_log_action (int mod, int level) { logfunc_t *logfn = io->get_logfn (mod); return logfn->getonoff (level); } void bx_real_sim_c::set_log_action (int mod, int level, int action) { // normal if (mod >= 0) { logfunc_t *logfn = io->get_logfn (mod); logfn->setonoff (level, action); return; } // if called with mod<0 loop over all int nmod = get_n_log_modules (); for (mod=0; modgetaction (action); } const char * bx_real_sim_c::get_log_level_name (int level) { return io->getlevel (level); } int bx_real_sim_c::get_max_log_level () { return N_LOGLEV; } void bx_real_sim_c::quit_sim (int code) { BX_INFO (("quit_sim called with exit code %d", code)); exit_code = code; // use longjmp to quit cleanly, no matter where in the stack we are. //fprintf (stderr, "using longjmp() to jump directly to the quit context!\n"); if (quit_context != NULL) { longjmp (*quit_context, 1); BX_PANIC (("in bx_real_sim_c::quit_sim, longjmp should never return")); } if (SIM->is_wx_selected ()) { // in wxWidgets, the whole simulator is running in a separate thread. // our only job is to end the thread as soon as possible, NOT to shut // down the whole application with an exit. BX_CPU(0)->async_event = 1; BX_CPU(0)->kill_bochs_request = 1; // the cpu loop will exit very soon after this condition is set. } else { // just a single thread. Use exit() to stop the application. if (!code) BX_PANIC (("Quit simulation command")); ::exit (exit_code); } } int bx_real_sim_c::get_default_rc (char *path, int len) { char *rc = bx_find_bochsrc (); if (rc == NULL) return -1; strncpy (path, rc, len); path[len-1] = 0; return 0; } int bx_real_sim_c::read_rc (char *rc) { return bx_read_configuration (rc); } // return values: // 0: written ok // -1: failed // -2: already exists, and overwrite was off int bx_real_sim_c::write_rc (char *rc, int overwrite) { return bx_write_configuration (rc, overwrite); } int bx_real_sim_c::get_log_file (char *path, int len) { strncpy (path, bx_options.log.Ofilename->getptr (), len); return 0; } int bx_real_sim_c::set_log_file (char *path) { bx_options.log.Ofilename->set (path); return 0; } int bx_real_sim_c::get_log_prefix (char *prefix, int len) { strncpy (prefix, bx_options.log.Oprefix->getptr (), len); return 0; } int bx_real_sim_c::set_log_prefix (char *prefix) { bx_options.log.Oprefix->set (prefix); return 0; } int bx_real_sim_c::get_debugger_log_file (char *path, int len) { strncpy (path, bx_options.log.Odebugger_filename->getptr (), len); return 0; } int bx_real_sim_c::set_debugger_log_file (char *path) { bx_options.log.Odebugger_filename->set (path); return 0; } int bx_real_sim_c::get_floppy_options (int drive, bx_floppy_options *out) { *out = (drive==0)? bx_options.floppya : bx_options.floppyb; return 0; } int bx_real_sim_c::get_cdrom_options (int level, bx_atadevice_options *out, int *where) { for (Bit8u channel=0; channelget() == BX_ATA_DEVICE_CDROM) { if (level==0) { *out = bx_options.atadevice[channel][device]; if (where != NULL) *where=(channel*2)+device; return 1; } else level--; } } } return 0; } char *bochs_start_names[] = { "quick", "load", "edit", "run" }; int n_bochs_start_names = 3; char *floppy_type_names[] = { "none", "1.2M", "1.44M", "2.88M", "720K", "360K", "160K", "180K", "320K", NULL }; int floppy_type_n_sectors[] = { -1, 80*2*15, 80*2*18, 80*2*36, 80*2*9, 40*2*9, 40*1*8, 40*1*9, 40*2*8 }; int n_floppy_type_names = 9; char *floppy_status_names[] = { "ejected", "inserted", NULL }; int n_floppy_status_names = 2; char *bochs_bootdisk_names[] = { "none", "floppy", "disk","cdrom", NULL }; int n_bochs_bootdisk_names = 4; char *loader_os_names[] = { "none", "linux", "nullkernel", NULL }; int n_loader_os_names = 3; char *keyboard_type_names[] = { "xt", "at", "mf", NULL }; int n_keyboard_type_names = 3; char *atadevice_type_names[] = { "disk", "cdrom", NULL }; int n_atadevice_type_names = 2; //char *atadevice_mode_names[] = { "flat", "concat", "external", "dll", "sparse", "vmware3", "split", "undoable", "growing", "volatile", "z-undoable", "z-volatile", NULL }; char *atadevice_mode_names[] = { "flat", "concat", "external", "dll", "sparse", "vmware3", "undoable", "growing", "volatile", NULL }; int n_atadevice_mode_names = 9; char *atadevice_status_names[] = { "ejected", "inserted", NULL }; int n_atadevice_status_names = 2; char *atadevice_biosdetect_names[] = { "none", "auto", "cmos", NULL }; int n_atadevice_biosdetect_names = 3; char *atadevice_translation_names[] = { "none", "lba", "large", "rechs", "auto", NULL }; int n_atadevice_translation_names = 5; char *clock_sync_names[] = { "none", "realtime", "slowdown", "both", NULL }; int clock_sync_n_names=4; char * bx_real_sim_c::get_floppy_type_name (int type) { BX_ASSERT (type >= BX_FLOPPY_NONE && type <= BX_FLOPPY_LAST); type -= BX_FLOPPY_NONE; return floppy_type_names[type]; } void bx_real_sim_c::set_notify_callback (bxevent_handler func, void *arg) { bxevent_callback = func; bxevent_callback_data = arg; } void bx_real_sim_c::get_notify_callback ( bxevent_handler *func, void **arg) { *func = bxevent_callback; *arg = bxevent_callback_data; } BxEvent * bx_real_sim_c::sim_to_ci_event (BxEvent *event) { if (bxevent_callback == NULL) { BX_ERROR (("notify called, but no bxevent_callback function is registered")); return NULL; } else { return (*bxevent_callback)(bxevent_callback_data, event); } } // returns 0 for continue, 1 for alwayscontinue, 2 for die. int bx_real_sim_c::log_msg (const char *prefix, int level, const char *msg) { BxEvent be; be.type = BX_SYNC_EVT_LOG_ASK; be.u.logmsg.prefix = prefix; be.u.logmsg.level = level; be.u.logmsg.msg = msg; // default return value in case something goes wrong. be.retcode = BX_LOG_ASK_CHOICE_DIE; //fprintf (stderr, "calling notify.\n"); sim_to_ci_event (&be); return be.retcode; } // Called by simulator whenever it needs the user to choose a new value // for a registered parameter. Create a synchronous ASK_PARAM event, // send it to the CI, and wait for the response. The CI will call the // set() method on the parameter if the user changes the value. int bx_real_sim_c::ask_param (bx_id param) { bx_param_c *paramptr = SIM->get_param(param); BX_ASSERT (paramptr != NULL); // create appropriate event BxEvent event; event.type = BX_SYNC_EVT_ASK_PARAM; event.u.param.param = paramptr; sim_to_ci_event (&event); return event.retcode; } int bx_real_sim_c::ask_filename (char *filename, int maxlen, char *prompt, char *the_default, int flags) { // implement using ASK_PARAM on a newly created param. I can't use // ask_param because I don't intend to register this param. BxEvent event; bx_param_string_c param (BXP_NULL, prompt, "filename", the_default, maxlen); flags |= param.IS_FILENAME; param.get_options()->set (flags); event.type = BX_SYNC_EVT_ASK_PARAM; event.u.param.param = ¶m; sim_to_ci_event (&event); if (event.retcode >= 0) memcpy (filename, param.getptr(), maxlen); return event.retcode; } void bx_real_sim_c::periodic () { // give the GUI a chance to do periodic things on the bochs thread. in // particular, notice if the thread has been asked to die. BxEvent tick; tick.type = BX_SYNC_EVT_TICK; sim_to_ci_event (&tick); if (tick.retcode < 0) { BX_INFO (("Bochs thread has been asked to quit.")); bx_atexit (); quit_sim (0); } static int refresh_counter = 0; if (++refresh_counter == 50) { // only ask the CI to refresh every 50 times periodic() is called. // This should obviously be configurable because system speeds and // user preferences vary. refresh_ci (); refresh_counter = 0; } #if 0 // watch for memory leaks. Allocate a small block of memory, print the // pointer that is returned, then free. BxEvent *memcheck = new BxEvent (); BX_INFO(("memory allocation at %p", memcheck)); delete memcheck; #endif } // create a disk image file called filename, size=512 bytes * sectors. // If overwrite is true and the file exists, returns -1 without changing it. // Otherwise, opens up the image and starts writing. Returns -2 if // the image could not be opened, or -3 if there are failures during // write, e.g. disk full. // // wxWidgets: This may be called from the gui thread. int bx_real_sim_c::create_disk_image ( const char *filename, int sectors, bx_bool overwrite) { FILE *fp; if (!overwrite) { // check for existence first fp = fopen (filename, "r"); if (fp) { // yes it exists fclose (fp); return -1; } } fp = fopen (filename, "w"); if (fp == NULL) { #ifdef HAVE_PERROR char buffer[1024]; sprintf (buffer, "while opening '%s' for writing", filename); perror (buffer); // not sure how to get this back into the CI #endif return -2; } int sec = sectors; /* * seek to sec*512-1 and write a single character. * can't just do: fseek(fp, 512*sec-1, SEEK_SET) * because 512*sec may be too large for signed int. */ while (sec > 0) { /* temp <-- min(sec, 4194303) * 4194303 is (int)(0x7FFFFFFF/512) */ int temp = ((sec < 4194303) ? sec : 4194303); fseek(fp, 512*temp, SEEK_CUR); sec -= temp; } fseek(fp, -1, SEEK_CUR); if (fputc('\0', fp) == EOF) { fclose (fp); return -3; } fclose (fp); return 0; } void bx_real_sim_c::refresh_ci () { if (SIM->is_wx_selected ()) { // presently, only wxWidgets interface uses these events // It's an async event, so allocate a pointer and send it. // The event will be freed by the recipient. BxEvent *event = new BxEvent (); event->type = BX_ASYNC_EVT_REFRESH; sim_to_ci_event (event); } } bx_param_c * bx_real_sim_c::get_first_atadevice (Bit32u search_type) { for (int channel=0; channelget ()) continue; for (int slave=0; slave<2; slave++) { Bit32u present = bx_options.atadevice[channel][slave].Opresent->get (); Bit32u type = bx_options.atadevice[channel][slave].Otype->get (); if (present && (type == search_type)) { return bx_options.atadevice[channel][slave].Omenu; } } } return NULL; } #if BX_DEBUGGER // this can be safely called from either thread. void bx_real_sim_c::debug_break () { bx_debug_break (); } // this should only be called from the sim_thread. void bx_real_sim_c::debug_interpret_cmd (char *cmd) { if (!is_sim_thread ()) { fprintf (stderr, "ERROR: debug_interpret_cmd called but not from sim_thread\n"); return; } bx_dbg_interpret_line (cmd); } char *bx_real_sim_c::debug_get_next_command () { fprintf (stderr, "begin debug_get_next_command\n"); BxEvent event; event.type = BX_SYNC_EVT_GET_DBG_COMMAND; BX_INFO (("asking for next debug command")); sim_to_ci_event (&event); BX_INFO (("received next debug command: '%s'", event.u.debugcmd.command)); if (event.retcode >= 0) return event.u.debugcmd.command; return NULL; } void bx_real_sim_c::debug_puts (const char *text) { if (SIM->is_wx_selected ()) { // send message to the wxWidgets debugger BxEvent *event = new BxEvent (); event->type = BX_ASYNC_EVT_DBG_MSG; event->u.logmsg.msg = text; sim_to_ci_event (event); // the event will be freed by the recipient } else { // text mode debugger: just write to console fputs (text, stderr); delete [] (char *)text; } } #endif void bx_real_sim_c::register_configuration_interface ( const char* name, config_interface_callback_t callback, void *userdata) { ci_callback = callback; ci_callback_data = userdata; registered_ci_name = name; } int bx_real_sim_c::configuration_interface(const char *ignore, ci_command_t command) { bx_param_enum_c *ci_param = SIM->get_param_enum (BXP_SEL_CONFIG_INTERFACE); char *name = ci_param->get_choice (ci_param->get ()); if (!ci_callback) { BX_PANIC (("no configuration interface was loaded")); return -1; } if (strcmp (name, registered_ci_name) != 0) { BX_PANIC (("siminterface does not support loading one configuration interface and then calling another")); return -1; } if (!strcmp (name, "wx")) wxsel = true; else wxsel = false; // enter configuration mode, just while running the configuration interface set_display_mode (DISP_MODE_CONFIG); int retval = (*ci_callback)(ci_callback_data, command); set_display_mode (DISP_MODE_SIM); return retval; } int bx_real_sim_c::begin_simulation (int argc, char *argv[]) { return bx_begin_simulation (argc, argv); } bool bx_real_sim_c::is_sim_thread () { if (is_sim_thread_func == NULL) return true; return (*is_sim_thread_func)(); } // check if the text console exists. On some platforms, if Bochs is // started from the "Start Menu" or by double clicking on it on a Mac, // there may be nothing attached to stdin/stdout/stderr. This function // tests if stdin/stdout/stderr are usable and returns false if not. bool bx_real_sim_c::test_for_text_console () { #if BX_WITH_CARBON // In a Carbon application, you have a text console if you run the app from // the command line, but if you start it from the finder you don't. if(!isatty(STDIN_FILENO)) return false; #endif // default: yes return true; } ///////////////////////////////////////////////////////////////////////// // define methods of bx_param_* and family ///////////////////////////////////////////////////////////////////////// bx_object_c::bx_object_c (bx_id id) { this->id = id; this->type = BXT_OBJECT; } void bx_object_c::set_type (bx_objtype type) { this->type = type; } const char* bx_param_c::default_text_format = NULL; bx_param_c::bx_param_c (bx_id id, char *name, char *description) : bx_object_c (id) { set_type (BXT_PARAM); this->name = name; this->description = description; this->text_format = default_text_format; this->ask_format = NULL; this->label = NULL; this->group_name = NULL; this->runtime_param = 0; this->enabled = 1; SIM->register_param (id, this); } const char* bx_param_c::set_default_format (const char *f) { const char *old = default_text_format; default_text_format = f; return old; } bx_param_num_c::bx_param_num_c (bx_id id, char *name, char *description, Bit64s min, Bit64s max, Bit64s initial_val) : bx_param_c (id, name, description) { set_type (BXT_PARAM_NUM); this->min = min; this->max = max; this->initial_val = initial_val; this->val.number = initial_val; this->handler = NULL; this->enable_handler = NULL; this->base = default_base; // dependent_list must be initialized before the set(), // because set calls update_dependents(). dependent_list = NULL; set (initial_val); } Bit32u bx_param_num_c::default_base = 10; Bit32u bx_param_num_c::set_default_base (Bit32u val) { Bit32u old = default_base; default_base = val; return old; } void bx_param_num_c::reset () { this->val.number = initial_val; } void bx_param_num_c::set_handler (param_event_handler handler) { this->handler = handler; // now that there's a handler, call set once to run the handler immediately //set (get ()); } void bx_param_num_c::set_enable_handler (param_enable_handler handler) { this->enable_handler = handler; } void bx_param_num_c::set_dependent_list (bx_list_c *l) { dependent_list = l; update_dependents (); } Bit64s bx_param_num_c::get64 () { if (handler) { // the handler can decide what value to return and/or do some side effect return (*handler)(this, 0, val.number); } else { // just return the value return val.number; } } void bx_param_num_c::set (Bit64s newval) { if (handler) { // the handler can override the new value and/or perform some side effect val.number = newval; (*handler)(this, 1, newval); } else { // just set the value. This code does not check max/min. val.number = newval; } if ((val.number < min || val.number > max) && (Bit64u)max != BX_MAX_BIT64U) BX_PANIC (("numerical parameter %s was set to " FMT_LL "d, which is out of range " FMT_LL "d to " FMT_LL "d", get_name (), val.number, min, max)); if (dependent_list != NULL) update_dependents (); } void bx_param_num_c::set_range (Bit64u min, Bit64u max) { this->min = min; this->max = max; } void bx_param_num_c::set_initial_val (Bit64s initial_val) { this->val.number = this->initial_val = initial_val; } void bx_param_num_c::update_dependents () { if (dependent_list) { int en = val.number && enabled; for (int i=0; iget_size (); i++) { bx_param_c *param = dependent_list->get (i); if (param != this) param->set_enabled (en); } } } void bx_param_num_c::set_enabled (int en) { // The enable handler may wish to allow/disallow the action if (enable_handler) { en = (*enable_handler) (this, en); } bx_param_c::set_enabled (en); update_dependents (); } // Signed 64 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit64s *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT64S, BX_MAX_BIT64S, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p64bit = ptr_to_real_val; } // Unsigned 64 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit64u *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT64U, BX_MAX_BIT64U, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p64bit = (Bit64s*) ptr_to_real_val; } // Signed 32 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit32s *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT32S, BX_MAX_BIT32S, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p32bit = ptr_to_real_val; } // Unsigned 32 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit32u *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT32U, BX_MAX_BIT32U, *ptr_to_real_val) { this->varsize = 32; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p32bit = (Bit32s*) ptr_to_real_val; } // Signed 16 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit16s *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT16S, BX_MAX_BIT16S, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p16bit = ptr_to_real_val; } // Unsigned 16 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit16u *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT16U, BX_MAX_BIT16U, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p16bit = (Bit16s*) ptr_to_real_val; } // Signed 8 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit8s *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT8S, BX_MAX_BIT8S, *ptr_to_real_val) { this->varsize = 16; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p8bit = ptr_to_real_val; } // Unsigned 8 bit bx_shadow_num_c::bx_shadow_num_c (bx_id id, char *name, char *description, Bit8u *ptr_to_real_val, Bit8u highbit, Bit8u lowbit) : bx_param_num_c (id, name, description, BX_MIN_BIT8U, BX_MAX_BIT8U, *ptr_to_real_val) { this->varsize = 8; this->lowbit = lowbit; this->mask = (1 << (highbit - lowbit)) - 1; val.p8bit = (Bit8s*) ptr_to_real_val; } Bit64s bx_shadow_num_c::get64 () { Bit64u current = 0; switch (varsize) { case 8: current = *(val.p8bit); break; case 16: current = *(val.p16bit); break; case 32: current = *(val.p32bit); break; case 64: current = *(val.p64bit); break; default: BX_PANIC(("unsupported varsize %d", varsize)); } current = (current >> lowbit) & mask; if (handler) { // the handler can decide what value to return and/or do some side effect return (*handler)(this, 0, current) & mask; } else { // just return the value return current; } } void bx_shadow_num_c::set (Bit64s newval) { Bit64u tmp = 0; if ((newval < min || newval > max) && (Bit64u)max != BX_MAX_BIT64U) BX_PANIC (("numerical parameter %s was set to " FMT_LL "d, which is out of range " FMT_LL "d to " FMT_LL "d", get_name (), newval, min, max)); switch (varsize) { case 8: tmp = (*(val.p8bit) >> lowbit) & mask; tmp |= (newval & mask) << lowbit; *(val.p8bit) = (Bit8s)tmp; break; case 16: tmp = (*(val.p16bit) >> lowbit) & mask; tmp |= (newval & mask) << lowbit; *(val.p16bit) = (Bit16s)tmp; break; case 32: tmp = (*(val.p32bit) >> lowbit) & mask; tmp |= (newval & mask) << lowbit; *(val.p32bit) = (Bit32s)tmp; break; case 64: tmp = (*(val.p64bit) >> lowbit) & mask; tmp |= (newval & mask) << lowbit; *(val.p64bit) = tmp; break; default: BX_PANIC(("unsupported varsize %d", varsize)); } if (handler) { // the handler can override the new value and/or perform some side effect (*handler)(this, 1, tmp); } } bx_param_bool_c::bx_param_bool_c (bx_id id, char *name, char *description, Bit64s initial_val) : bx_param_num_c (id, name, description, 0, 1, initial_val) { set_type (BXT_PARAM_BOOL); set (initial_val); } bx_shadow_bool_c::bx_shadow_bool_c (bx_id id, char *name, char *description, bx_bool *ptr_to_real_val, Bit8u bitnum) : bx_param_bool_c (id, name, description, (Bit64s) *ptr_to_real_val) { val.pbool = ptr_to_real_val; this->bitnum = bitnum; } Bit64s bx_shadow_bool_c::get64 () { if (handler) { // the handler can decide what value to return and/or do some side effect Bit64s ret = (*handler)(this, 0, (Bit64s) *(val.pbool)); return (ret>>bitnum) & 1; } else { // just return the value return (*(val.pbool)) & 1; } } void bx_shadow_bool_c::set (Bit64s newval) { // only change the bitnum bit Bit64s tmp = (newval&1) << bitnum; *(val.pbool) &= ~tmp; *(val.pbool) |= tmp; if (handler) { // the handler can override the new value and/or perform some side effect (*handler)(this, 1, newval&1); } } bx_param_enum_c::bx_param_enum_c (bx_id id, char *name, char *description, char **choices, Bit64s initial_val, Bit64s value_base) : bx_param_num_c (id, name, description, value_base, BX_MAX_BIT64S, initial_val) { set_type (BXT_PARAM_ENUM); this->choices = choices; // count number of choices, set max char **p = choices; while (*p != NULL) p++; this->min = value_base; // now that the max is known, replace the BX_MAX_BIT64S sent to the parent // class constructor with the real max. this->max = value_base + (p - choices - 1); set (initial_val); } int bx_param_enum_c::find_by_name (const char *string) { char **p; for (p=&choices[0]; *p; p++) { if (!strcmp (string, *p)) return p-choices; } return -1; } bool bx_param_enum_c::set_by_name (const char *string) { int n = find_by_name (string); if (n<0) return false; set (n); return true; } bx_param_string_c::bx_param_string_c (bx_id id, char *name, char *description, char *initial_val, int maxsize) : bx_param_c (id, name, description) { set_type (BXT_PARAM_STRING); if (maxsize < 0) maxsize = strlen(initial_val) + 1; this->val = new char[maxsize]; this->initial_val = new char[maxsize]; this->handler = NULL; this->enable_handler = NULL; this->maxsize = maxsize; strncpy (this->val, initial_val, maxsize); strncpy (this->initial_val, initial_val, maxsize); this->options = new bx_param_num_c (BXP_NULL, "stringoptions", NULL, 0, BX_MAX_BIT64S, 0); set (initial_val); } bx_param_filename_c::bx_param_filename_c (bx_id id, char *name, char *description, char *initial_val, int maxsize) : bx_param_string_c (id, name, description, initial_val, maxsize) { get_options()->set (IS_FILENAME); } bx_param_string_c::~bx_param_string_c () { if ( this->val != NULL ) { delete [] this->val; this->val = NULL; } if ( this->initial_val != NULL ) { delete [] this->initial_val; this->initial_val = NULL; } if ( this->options != NULL ) { delete [] this->options; this->options = NULL; } } void bx_param_string_c::reset () { strncpy (this->val, this->initial_val, maxsize); } void bx_param_string_c::set_handler (param_string_event_handler handler) { this->handler = handler; // now that there's a handler, call set once to run the handler immediately //set (getptr ()); } void bx_param_string_c::set_enable_handler (param_enable_handler handler) { this->enable_handler = handler; } void bx_param_string_c::set_enabled (int en) { // The enable handler may wish to allow/disallow the action if (enable_handler) { en = (*enable_handler) (this, en); } bx_param_c::set_enabled (en); } Bit32s bx_param_string_c::get (char *buf, int len) { if (options->get () & RAW_BYTES) memcpy (buf, val, len); else strncpy (buf, val, len); if (handler) { // the handler can choose to replace the value in val/len. Also its // return value is passed back as the return value of get. (*handler)(this, 0, buf, len); } return 0; } void bx_param_string_c::set (char *buf) { if (options->get () & RAW_BYTES) memcpy (val, buf, maxsize); else strncpy (val, buf, maxsize); if (handler) { // the handler can return a different char* to be copied into the value buf = (*handler)(this, 1, buf, -1); } } bx_bool bx_param_string_c::equals (const char *buf) { if (options->get () & RAW_BYTES) return (memcmp (val, buf, maxsize) == 0); else return (strncmp (val, buf, maxsize) == 0); } void bx_param_string_c::set_initial_val (char *buf) { if (options->get () & RAW_BYTES) memcpy (initial_val, buf, maxsize); else strncpy (initial_val, buf, maxsize); set (initial_val); } bx_list_c::bx_list_c (bx_id id, int maxsize) : bx_param_c (id, "list", "") { set_type (BXT_LIST); this->size = 0; this->maxsize = maxsize; this->list = new bx_param_c* [maxsize]; init (); } bx_list_c::bx_list_c (bx_id id, char *name, char *description, int maxsize) : bx_param_c (id, name, description) { set_type (BXT_LIST); this->size = 0; this->maxsize = maxsize; this->list = new bx_param_c* [maxsize]; init (); } bx_list_c::bx_list_c (bx_id id, char *name, char *description, bx_param_c **init_list) : bx_param_c (id, name, description) { set_type (BXT_LIST); this->size = 0; while (init_list[this->size] != NULL) this->size++; this->maxsize = this->size; this->list = new bx_param_c* [maxsize]; for (int i=0; isize; i++) this->list[i] = init_list[i]; init (); } bx_list_c::~bx_list_c() { if (this->list) { delete [] this->list; this->list = NULL; } if ( this->title != NULL) { delete this->title; this->title = NULL; } if (this->options != NULL) { delete this->options; this->options = NULL; } if ( this->choice != NULL ) { delete this->choice; this->choice = NULL; } } void bx_list_c::init () { // the title defaults to the name this->title = new bx_param_string_c (BXP_NULL, "title of list", "", get_name (), 80); this->options = new bx_param_num_c (BXP_NULL, "list_option", "", 0, BX_MAX_BIT64S, 0); this->choice = new bx_param_num_c (BXP_NULL, "list_choice", "", 0, BX_MAX_BIT64S, 1); this->parent = NULL; } bx_list_c * bx_list_c::clone () { bx_list_c *newlist = new bx_list_c (BXP_NULL, name, description, maxsize); for (int i=0; iadd (get(i)); newlist->set_options (get_options ()); newlist->set_parent (get_parent ()); return newlist; } void bx_list_c::add (bx_param_c *param) { if (this->size >= this->maxsize) BX_PANIC (("add param %u to bx_list_c id=%u: list capacity exceeded", param->get_id (), get_id ())); list[size] = param; size++; } bx_param_c * bx_list_c::get (int index) { BX_ASSERT (index >= 0 && index < size); return list[index]; }