///////////////////////////////////////////////////////////////////////// // $Id: siminterface.h,v 1.201 2006-09-07 18:50:51 vruppert Exp $ ///////////////////////////////////////////////////////////////////////// // // Intro to siminterface by Bryce Denney: // // Before I can describe what this file is for, I have to make the // distinction between a configuration interface (CI) and the VGA display // window (VGAW). I will try to avoid the term 'GUI' because it is unclear // if that means CI or VGAW, and because not all interfaces are graphical // anyway. // // The traditional Bochs screen is a window with a large VGA display panel and // a series of buttons (floppy, cdrom, snapshot, power). Over the years, we // have collected many implementations of the VGAW for different environments // and platforms; each implementation is in a separate file under gui/*: // x.cc, win32.cc, beos.cc, macintosh.cc, etc. The files gui.h and gui.cc // define the platform independent part of the VGAW, leaving about 15 methods // of the bx_gui_c class undefined. The platform dependent file must // implement the remaining 15 methods. // // The configuration interface is relatively new, started by Bryce Denney in // June 2001. The CI is intended to allow the user to edit a variety of // configuration and runtime options. Some options, such as memory size or // enabling the ethernet card, should only be changed before the simulation // begins; others, such as floppy disk image, instructions per second, and // logging options can be safely changed at runtime. The CI allows the user to // make these changes. Before the CI existed, only a few things could be // changed at runtime, all linked to clicking on the VGAW buttons. // // At the time that the CI was conceived, we were still debating what form the // user interface part would take: stdin/stdout menus, a graphical application // with menus and dialogs running in a separate thread, or even a tiny web // server that you can connect to with a web browser. As a result the // interface to the CI was designed so that the user interface of the CI // could be replaced easily at compile time, or maybe even at runtime via // a plugin architecture. To this end, we kept a clear separation between // the user interface code and the siminterface, the code that interfaces with // the simulator. The same siminterface is used all the time, while // different implementations of the CI can be switched in reasonably easily. // Only the CI code uses library specific graphics and I/O functions; the // siminterface deals in portable abstractions and callback functions. // The first CI implementation was a series of text mode menus implemented in // textconfig.cc. // // The configuration interface MUST use the siminterface methods to access the // simulator. It should not modify settings in some device with code like // bx_floppy.s.media[2].heads = 17. If such access is needed, then a // siminterface method should be written to make the change on the CI's behalf. // This separation is enforced by the fact that the CI does not even include // bochs.h. You'll notice that textconfig.cc includes osdep.h, textconfig.h, // and siminterface.h, so it doesn't know what bx_floppy or bx_cpu_c are. // I'm sure some people will say is overly restrictive and/or annoying. When I // set it up this way, we were still talking about making the CI in a seperate // process, where direct method calls would be impossible. Also, we have been // considering turning devices into plugin modules which are dynamically // linked. Any direct references to something like bx_floppy.s.media[2].heads // would have to be reworked before a plugin interface was possible as well. // // The siminterface is the glue between the CI and the simulator. There is // just one global instance of the siminterface object, which can be referred // to by the global variable bx_simulator_interface_c *SIM. The base class // bx_simulator_interface_c, contains only virtual functions and it defines the // interface that the CI is allowed to use. In siminterface.cc, a class // called bx_real_sim_c is defined with bx_simulator_interface_c as its parent // class. Bx_real_sim_c implements each of the functions. The separation into // parent class and child class leaves the possibility of making a different // child class that talks to the simulator in a different way (networking for // example). If you were writing a user interface in a separate process, you // could define a subclass of bx_simulator_interface_c called // bx_siminterface_proxy_c which opens up a network port and turns all method // calls into network sends and receives. Because the interface is defined // entirely by the base class, the code that calls the methods would not know // the difference. // // An important part of the siminterface implementation is the use of parameter // classes, or bx_param_*. The parameter classes are described below, where // they are declared. Search for "parameter classes" below for details. // // Also this header file declares data structures for certain events that pass // between the siminterface and the CI. Search for "event structures" below. ////////////////////////////////////////////////////// // BX_USE_TEXTCONFIG should be set to 1 when the text mode configuration interface // is compiled in. This gives each type of parameter a text_print and text_ask // method (defined in gui/textconfig.cc) so that you can call text_ask() on any // kind of parameter to ask the user to edit the value. // // I have been considering whether to use the same strategy for the // wxWidgets interface, but I'm not sure if I like it. One problem is // that in order to declare member functions that are useful for // wxWidgets, the wxWidgets header files would have to be included // before the param object definitions. That means that all the // wxWidgets headers would have be included when compiling every // single bochs file. One of the things I like about the separation // between the simulator and CI is that the two parts can be // compiled without any knowledge of the other. Bochs doesn't include // , and the wxWidgets CI (wxmain.cc) doesn't need to include . // Aside from making compiles faster, this enforces the use of the siminterface // so it keeps the interface clean (important when we may have multiple UI // implementations for example). This argues for keeping UI-specific // structures out of the simulator interface. It certainly works ok for the // text interface, but that's because FILE* is standard and portable. ////////////////////////////////////////////////////// // list of possible types for bx_param_c and descendant objects typedef enum { BXT_OBJECT = 201, BXT_PARAM, BXT_PARAM_NUM, BXT_PARAM_BOOL, BXT_PARAM_ENUM, BXT_PARAM_STRING, BXT_PARAM_DATA, BXT_LIST } bx_objtype; // define parameter path names. These names give the location in the // parameter tree where each can be found. The names correspond to // the old BXP_* enum values, which have been eliminated. #define BXPN_CPU_NPROCESSORS "cpu.n_processors" #define BXPN_CPU_NCORES "cpu.n_cores" #define BXPN_CPU_NTHREADS "cpu.n_threads" #define BXPN_IPS "cpu.ips" #define BXPN_SMP_QUANTUM "cpu.quantum" #define BXPN_RESET_ON_TRIPLE_FAULT "cpu.reset_on_triple_fault" #define BXPN_MEM_SIZE "memory.standard.ram.size" #define BXPN_ROM_PATH "memory.standard.rom.path" #define BXPN_ROM_ADDRESS "memory.standard.rom.addr" #define BXPN_VGA_ROM_PATH "memory.standard.vgarom.path" #define BXPN_OPTROM1_PATH "memory.optrom.1.path" #define BXPN_OPTROM1_ADDRESS "memory.optrom.1.addr" #define BXPN_OPTROM2_PATH "memory.optrom.2.path" #define BXPN_OPTROM2_ADDRESS "memory.optrom.2.addr" #define BXPN_OPTROM3_PATH "memory.optrom.3.path" #define BXPN_OPTROM3_ADDRESS "memory.optrom.3.addr" #define BXPN_OPTROM4_PATH "memory.optrom.4.path" #define BXPN_OPTROM4_ADDRESS "memory.optrom.4.addr" #define BXPN_OPTRAM1_PATH "memory.optram.1.path" #define BXPN_OPTRAM1_ADDRESS "memory.optram.1.addr" #define BXPN_OPTRAM2_PATH "memory.optram.2.path" #define BXPN_OPTRAM2_ADDRESS "memory.optram.2.addr" #define BXPN_OPTRAM3_PATH "memory.optram.3.path" #define BXPN_OPTRAM3_ADDRESS "memory.optram.3.addr" #define BXPN_OPTRAM4_PATH "memory.optram.4.path" #define BXPN_OPTRAM4_ADDRESS "memory.optram.4.addr" #define BXPN_CLOCK_SYNC "clock_cmos.clock_sync" #define BXPN_CLOCK_TIME0 "clock_cmos.time0" #define BXPN_CMOSIMAGE_ENABLED "clock_cmos.cmosimage.enabled" #define BXPN_CMOSIMAGE_PATH "clock_cmos.cmosimage.path" #define BXPN_CMOSIMAGE_RTC_INIT "clock_cmos.cmosimage.rtc_init" #define BXPN_I440FX_SUPPORT "pci.i440fx_support" #define BXPN_PCIDEV_VENDOR "pci.pcidev.vendor" #define BXPN_PCIDEV_DEVICE "pci.pcidev.device" #define BXPN_SEL_CONFIG_INTERFACE "display.config_interface" #define BXPN_SEL_DISPLAY_LIBRARY "display.display_library" #define BXPN_DISPLAYLIB_OPTIONS "display.displaylib_options" #define BXPN_PRIVATE_COLORMAP "display.private_colormap" #define BXPN_FULLSCREEN "display.fullscreen" #define BXPN_SCREENMODE "display.screenmode" #define BXPN_VGA_EXTENSION "display.vga_extension" #define BXPN_VGA_UPDATE_INTERVAL "display.vga_update_interval" #define BXPN_KBD_TYPE "keyboard_mouse.keyboard.type" #define BXPN_KBD_SERIAL_DELAY "keyboard_mouse.keyboard.serial_delay" #define BXPN_KBD_PASTE_DELAY "keyboard_mouse.keyboard.paste_delay" #define BXPN_KBD_USEMAPPING "keyboard_mouse.keyboard.use_mapping" #define BXPN_KBD_KEYMAP "keyboard_mouse.keyboard.keymap" #define BXPN_USER_SHORTCUT "keyboard_mouse.keyboard.user_shortcut" #define BXPN_MOUSE_TYPE "keyboard_mouse.mouse.type" #define BXPN_MOUSE_ENABLED "keyboard_mouse.mouse.enabled" #define BXPN_BOOTDRIVE1 "boot_params.boot_drive1" #define BXPN_BOOTDRIVE2 "boot_params.boot_drive2" #define BXPN_BOOTDRIVE3 "boot_params.boot_drive3" #define BXPN_FLOPPYSIGCHECK "boot_params.floppy_sig_check" #define BXPN_LOAD32BITOS_WHICH "boot_params.load32bitos.which" #define BXPN_LOAD32BITOS_PATH "boot_params.load32bitos.path" #define BXPN_LOAD32BITOS_IOLOG "boot_params.load32bitos.iolog" #define BXPN_LOAD32BITOS_INITRD "boot_params.load32bitos.initrd" #define BXPN_FLOPPYA "floppy.0" #define BXPN_FLOPPYA_DEVTYPE "floppy.0.devtype" #define BXPN_FLOPPYA_PATH "floppy.0.path" #define BXPN_FLOPPYA_TYPE "floppy.0.type" #define BXPN_FLOPPYA_STATUS "floppy.0.status" #define BXPN_FLOPPYB "floppy.1" #define BXPN_FLOPPYB_DEVTYPE "floppy.1.devtype" #define BXPN_FLOPPYB_PATH "floppy.1.path" #define BXPN_FLOPPYB_TYPE "floppy.1.type" #define BXPN_FLOPPYB_STATUS "floppy.1.status" #define BXPN_ATA0_RES "ata.0.resources" #define BXPN_ATA1_RES "ata.1.resources" #define BXPN_ATA2_RES "ata.2.resources" #define BXPN_ATA3_RES "ata.3.resources" #define BXPN_ATA0_ENABLED "ata.0.resources.enabled" #define BXPN_ATA1_ENABLED "ata.1.resources.enabled" #define BXPN_ATA0_MASTER "ata.0.master" #define BXPN_ATA1_MASTER "ata.1.master" #define BXPN_ATA2_MASTER "ata.2.master" #define BXPN_ATA3_MASTER "ata.3.master" #define BXPN_ATA0_SLAVE "ata.0.slave" #define BXPN_ATA1_SLAVE "ata.1.slave" #define BXPN_ATA2_SLAVE "ata.2.slave" #define BXPN_ATA3_SLAVE "ata.3.slave" #define BXPN_USB1_ENABLED "ports.usb.1.enabled" #define BXPN_USB1_PORT1 "ports.usb.1.port1" #define BXPN_USB1_OPTION1 "ports.usb.1.option1" #define BXPN_USB1_PORT2 "ports.usb.1.port2" #define BXPN_USB1_OPTION2 "ports.usb.1.option2" #define BXPN_NE2K "network.ne2k" #define BXPN_NE2K_ENABLED "network.ne2k.enabled" #define BXPN_PNIC "network.pnic" #define BXPN_PNIC_ENABLED "network.pnic.enabled" #define BXPN_SB16 "sound.sb16" #define BXPN_SB16_ENABLED "sound.sb16.enabled" #define BXPN_SB16_MIDIFILE "sound.sb16.midifile" #define BXPN_SB16_WAVEFILE "sound.sb16.wavefile" #define BXPN_SB16_DMATIMER "sound.sb16.dmatimer" #define BXPN_SB16_LOGLEVEL "sound.sb16.loglevel" #define BXPN_TEXT_SNAPSHOT_CHECK "misc.text_snapshot_check" #define BXPN_GDBSTUB "misc.gdbstub" #define BXPN_LOG_FILENAME "log.filename" #define BXPN_LOG_PREFIX "log.prefix" #define BXPN_DEBUGGER_LOG_FILENAME "log.debugger_filename" #define BXPN_BOCHS_START "general.start_mode" #define BXPN_DEBUG_RUNNING "general.debug_running" #define BXPN_RESTORE_FLAG "general.restore" #define BXPN_RESTORE_PATH "general.restore_path" #define BXPN_MENU_DISK "menu.disk" #define BXPN_MENU_MEMORY "menu.memory" #define BXPN_MENU_RUNTIME "menu.runtime" #define BXPN_WX_KBD_STATE "wxdebug.keyboard" #define BXPN_WX_CPU_STATE "wxdebug.cpu" #define BXPN_WX_CPU0_STATE "wxdebug.cpu.0" #define BXPN_WX_CPU0_EFLAGS_IOPL "wxdebug.cpu.0.IOPL" // base value for generated new parameter id #define BXP_NEW_PARAM_ID 1001 typedef enum { BX_TOOLBAR_UNDEFINED, BX_TOOLBAR_FLOPPYA, BX_TOOLBAR_FLOPPYB, BX_TOOLBAR_CDROMD, BX_TOOLBAR_RESET, BX_TOOLBAR_POWER, #if BX_SUPPORT_SAVE_RESTORE BX_TOOLBAR_SAVE_RESTORE, #endif BX_TOOLBAR_COPY, BX_TOOLBAR_PASTE, BX_TOOLBAR_SNAPSHOT, BX_TOOLBAR_CONFIG, BX_TOOLBAR_MOUSE_EN, BX_TOOLBAR_USER } bx_toolbar_buttons; // Log level defines typedef enum { LOGLEV_DEBUG = 0, LOGLEV_INFO, LOGLEV_ERROR, LOGLEV_PANIC, LOGLEV_PASS, N_LOGLEV } bx_log_levels; // types of reset #define BX_RESET_SOFTWARE 10 #define BX_RESET_HARDWARE 11 //cdrom #define BX_EJECTED 10 #define BX_INSERTED 11 // boot devices (using the same values as the rombios) #define BX_BOOT_NONE 0 #define BX_BOOT_FLOPPYA 1 #define BX_BOOT_DISKC 2 #define BX_BOOT_CDROM 3 // loader hack #define Load32bitOSNone 0 #define Load32bitOSLinux 1 #define Load32bitOSNullKernel 2 // being developed for plex86 #define Load32bitOSLast 2 /////////////////////////////////////////////////////////////////// // event structures for communication between simulator and CI /////////////////////////////////////////////////////////////////// // Because the CI (configuration interface) might be in a different // thread or even a different process, we pass events encoded in data // structures to it instead of just calling functions. Each type of // event is declared as a different structure, and then all those // structures are squished into a union in BxEvent. (BTW, this is // almost exactly how X windows event structs work.) // // These are simple structs, unblemished by C++ methods and tricks. // No matter what event type it is, we allocate a BxEvent for each // one, as opposed to trying to save a few bytes on small events by // allocating only the bytes necessary for it. This makes it easy and // fast to store events in a queue, like this // BxEvent event_queue[MAX_EVENTS]; // // Events come in two varieties: synchronous and asynchronous. We // have to worry about sync and async events because the CI and the // simulation may be running in different threads. An async event is // the simplest. Whichever thread originates the event just builds // the data structure, sends it, and then continues with its business. // Async events can go in either direction. Synchronous events // require the other thread to "respond" before the originating thread // can continue. It's like a function with a return value; you can't // continue until you get the return value back. // // Examples: // // async event: In the wxWidgets implementation, both the CI and the // VGAW operate in the wxWidgets GUI thread. When the user presses a // key, wxWidgets sends a wxKeyEvent to the VGAW event handler code in // wx.cc. The VGAW handler then builds a BxEvent with // type=BX_ASYNC_EVT_KEY, and fills in the bx_key and raw_scancode // fields. The asynchronous event is placed on the event_queue for // the simulator, then the VGAW handler returns. (With wxWidgets and // many other graphical libaries, the event handler must return // quickly because the window will not be updated until it's done.) // Some time later, the simulator reaches the point where it checks // for new events from the user (actually controlled by // bx_keyb_c::periodic() in iodev/keyboard.cc) and calls // bx_gui.handle_events(). Then all the events in the queue are // processed by the simulator. There is no "response" sent back to // the originating thread. // // sync event: Sometimes the simulator reaches a point where it needs // to ask the user how to proceed. In this case, the simulator sends // a synchronous event because it requires a response before it can // continue. It builds an event structure, perhaps with type // BX_SYNC_EVT_ASK_PARAM, sends it to the user interface // using the event handler function defined by set_notify_callback(), // and pauses the simulation. The user interface asks the user the // question, and puts the answer into the BxEvent.retcode field. The // event handler function returns the modified BxEvent with retcode // filled in, and the simulation continues. The details of this // transaction can be complicated if the simulation and CI are not // in the same thread, but the behavior is as described. // ///// types and definitions used in event structures #define BX_EVT_IS_ASYNC(type) ((type) > __ALL_EVENTS_BELOW_ARE_ASYNC__) typedef enum { __ALL_EVENTS_BELOW_ARE_SYNCHRONOUS__ = 2000, BX_SYNC_EVT_GET_PARAM, // CI -> simulator -> CI BX_SYNC_EVT_ASK_PARAM, // simulator -> CI -> simulator BX_SYNC_EVT_TICK, // simulator -> CI, wait for response. BX_SYNC_EVT_LOG_ASK, // simulator -> CI, wait for response. BX_SYNC_EVT_GET_DBG_COMMAND, // simulator -> CI, wait for response. __ALL_EVENTS_BELOW_ARE_ASYNC__, BX_ASYNC_EVT_KEY, // vga window -> simulator BX_ASYNC_EVT_MOUSE, // vga window -> simulator BX_ASYNC_EVT_SET_PARAM, // CI -> simulator BX_ASYNC_EVT_LOG_MSG, // simulator -> CI BX_ASYNC_EVT_DBG_MSG, // simulator -> CI BX_ASYNC_EVT_VALUE_CHANGED, // simulator -> CI BX_ASYNC_EVT_TOOLBAR, // CI -> simulator BX_ASYNC_EVT_REFRESH // simulator -> CI } BxEventType; typedef union { Bit32s s32; char *charptr; } AnyParamVal; // Define substructures which make up the interior of BxEvent. The // substructures, such as BxKeyEvent or BxMouseEvent, should never be // allocated on their own. They are only intended to be used within // the union in the BxEvent structure. // Event type: BX_SYNC_EVT_TICK // // A tick event is synchronous, sent from the simulator to the GUI. The // event doesn't do anything visible. Primarily it gives the GUI a chance // to tell the simulator to quit, if necessary. There may be other uses // for the tick in the future, such as giving some kind of regular // status report or mentioning watched values that changed, but so far // it's just for that one thing. There is no data associated with a // tick event. // Event type: BX_ASYNC_EVT_KEY // // A key event can be sent from the VGA window to the Bochs simulator. // It is asynchronous. typedef struct { // what was pressed? This is a BX_KEY_* value. For key releases, // BX_KEY_RELEASED is ORed with the base BX_KEY_*. Bit32u bx_key; bx_bool raw_scancode; } BxKeyEvent; // Event type: BX_ASYNC_EVT_MOUSE // // A mouse event can be sent from the VGA window to the Bochs // simulator. It is asynchronous. Currently unused because mouse // events aren't implemented in our wxWidgets code yet. typedef struct { // type is BX_EVT_MOUSE Bit16s dx, dy; // mouse motion delta Bit8u buttons; // which buttons are pressed. // bit 0: 1=left button down, 0=up // bit 1: 1=right button down, 0=up } BxMouseEvent; // Event type: BX_SYNC_EVT_GET_PARAM, BX_ASYNC_EVT_SET_PARAM // // Parameter set/get events are initiated by the CI, since Bochs can // always access the parameters directly. So far, I haven't used // these event types. In the CI I just call // SIM->get_param(parameter_id) to get a pointer to the bx_param_c // object and then call the get/set methods. This is okay for // configuration since bochs is not running. However it could be // dangerous for the GUI thread to poke around in Bochs structures // while the thread is running. For these cases, I may have to be // more careful and actually build get/set events and place them on // Bochs's event queue to be processed during SIM->periodic() or // something. typedef struct { // type is BX_EVT_GET_PARAM, BX_EVT_SET_PARAM class bx_param_c *param; // pointer to param structure AnyParamVal val; } BxParamEvent; // Event type: BX_SYNC_EVT_ASK_PARAM // Synchronous event sent from the simulator to the CI. This tells the // CI to ask the user to choose the value of a parameter. The CI may // need to discover the type of parameter so that it can use the right // kind of graphical display. The BxParamEvent is used for these events // too. // FIXME: at the moment the GUI implements the ASK_PARAM event for just // a few parameter types. I need to implement the event for all parameter // types. // Event type: BX_ASYNC_EVT_VALUE_CHANGED // // Asynchronous event sent from the simulator to the CI, telling it that // some value that it (hopefully) cares about has changed. This isn't // being used yet, but a good example is in a debugger interface, you might // want to maintain a reasonably current display of the PC or some other // simulation state. The CI would set some kind of event mask (which // doesn't exist now of course) and then when certain values change, the // simulator would send this event so that the CI can update. We may need // some kind of "flow control" since the simulator will be able to produce // new events much faster than the gui can accept them. // Event type: BX_ASYNC_EVT_LOG_MSG (unused) // // Asynchronous event from the simulator to the CI. When a BX_PANIC, // BX_ERROR, BX_INFO, or BX_DEBUG is found in the simulator code, this // event type can be used to inform the CI of the condition. There is // no point in sending messages to the CI that will not be displayed; these // would only slow the simulation. So we will need some mechanism for // choosing what kinds of events will be delivered to the CI. Normally, // you wouldn't want to look at the log unless something is going wrong. // At that point, you might want to open up a window to watch the debug // messages from one or two devices only. // // Idea: Except for panics that require user attention to continue, it // might be most efficient to just append log messages to a file. // When the user wants to look at the log messages, the gui can reopen // the file (read only), skip to the end, and look backward for a // reasonable number of lines to display (200?). This allows it to // skip over huge bursts of log entries without allocating memory, // synchronizing threads, etc. for each. typedef struct { Bit8u level; const char *prefix; const char *msg; } BxLogMsgEvent; // Event type: BX_ASYNC_EVT_DBG_MSG (unused) // // Also uses BxLogMsgEvent, but this is a message to be displayed in // the debugger history window. // Event type: BX_SYNC_EVT_LOG_ASK // // This is a synchronous version of BX_ASYNC_EVT_LOG_MSG, which is used // when the "action=ask" setting is used. If the simulator runs into a // panic, it sends a synchronous BX_SYNC_EVT_LOG_ASK to the CI to be // displayed. The CI shows a dialog that asks if the user wants to // continue, quit, etc. and sends the answer back to the simulator. // This event also uses BxLogMsgEvent. enum { BX_LOG_ASK_CHOICE_CONTINUE, BX_LOG_ASK_CHOICE_CONTINUE_ALWAYS, BX_LOG_ASK_CHOICE_DIE, BX_LOG_ASK_CHOICE_DUMP_CORE, BX_LOG_ASK_CHOICE_ENTER_DEBUG, BX_LOG_ASK_N_CHOICES, BX_LOG_NOTIFY_FAILED }; // Event type: BX_SYNC_EVT_GET_DBG_COMMAND // // This is a synchronous event sent from the simulator to the debugger // requesting the next action. In a text mode debugger, this would prompt // the user for the next command. When a new command is ready, the // synchronous event is sent back with its fields filled in. typedef struct { char *command; // null terminated string. allocated by debugger interface // with new operator, freed by simulator with delete. } BxDebugCommand; // Event type: BX_EVT_TOOLBAR // Asynchronous event from the VGAW to the simulator, sent when the user // clicks on a toolbar button. This may one day become something more // general, like a command event, but at the moment it's only needed for // the toolbar events. typedef struct { bx_toolbar_buttons button; bool on; // for toggling buttons, on=true means the toolbar button is // pressed. on=false means it is not pressed. } BxToolbarEvent; // The BxEvent structure should be used for all events. Every event has // a type and a spot for a return code (only used for synchronous events). typedef struct { BxEventType type; // what kind is this? Bit32s retcode; // sucess or failure. only used for synchronous events. union { BxKeyEvent key; BxMouseEvent mouse; BxParamEvent param; BxLogMsgEvent logmsg; BxToolbarEvent toolbar; BxDebugCommand debugcmd; } u; } BxEvent; //////////////////////////////////////////////////////////////////// // parameter classes: bx_param_c and family //////////////////////////////////////////////////////////////////// // // All variables that can be configured through the CI are declared as // "parameters" or objects of type bx_param_*. There is a bx_param_* // class for each type of data that the user would need to see and // edit, e.g. integer, boolean, enum, string, filename, or list of // other parameters. The purpose of the bx_param_* class, in addition // to storing the parameter's value, is to hold the name, description, // and constraints on the value. The bx_param_* class should hold // everything that the CI would need to display the value and allow // the user to modify it. For integer parameters, the minimum and // maximum allowed value can be defined, and the base in which it // should be displayed and interpreted. For enums, the // bx_param_enum_c structure includes the list of values which the // parameter can have. // // Also, some parameter classes support get/set callback functions to // allow arbitrary code to be executed when the parameter is get/set. // An example of where this is useful: if you disable the NE2K card, // the set() handler for that parameter can tell the user interface // that the NE2K's irq, I/O address, and mac address should be // disabled (greyed out, hidden, or made inaccessible). The get/set // methods can also check if the set() value is acceptable using // whatever means and override it. // // The parameter concept is similar to the use of parameters in JavaBeans. class bx_object_c; class bx_param_c; class bx_param_num_c; class bx_param_enum_c; class bx_param_bool_c; class bx_param_string_c; class bx_param_filename_c; class bx_list_c; class BOCHSAPI bx_object_c { private: Bit32u id; bx_objtype type; protected: void set_type(bx_objtype _type) { type = _type; } public: bx_object_c(Bit32u _id): id(_id), type(BXT_OBJECT) {} virtual ~bx_object_c() {} Bit32u get_id() const { return id; } Bit8u get_type() const { return type; } }; #define BASE_DEC 10 #define BASE_HEX 16 class BOCHSAPI bx_param_c : public bx_object_c { BOCHSAPI_CYGONLY static const char *default_text_format; protected: bx_list_c *parent; char *name; char *description; char *label; // label string for text menus and gui dialogs const char *text_format; // printf format string. %d for ints, %s for strings, etc. const char *long_text_format; // printf format string. %d for ints, %s for strings, etc. char *ask_format; // format string for asking for a new value char *group_name; // name of the group the param belongs to int runtime_param; int enabled; public: bx_param_c(Bit32u id, const char *name, const char *description); bx_param_c(Bit32u id, const char *name, const char *label, const char *description); virtual ~bx_param_c(); bx_param_c *get_parent() { return (bx_param_c *) parent; } int get_param_path(char *path_out, int maxlen); void set_format(const char *format) {text_format = format;} const char *get_format() const {return text_format;} void set_long_format(const char *format) {long_text_format = format;} const char *get_long_format() const {return long_text_format;} void set_ask_format(const char *format); const char *get_ask_format() const {return ask_format;} void set_label(const char *text); void set_description(const char *text); const char *get_label() const {return label;} void set_runtime_param(int val) { runtime_param = val; } int get_runtime_param() { return runtime_param; } void set_group(const char *group); const char *get_group() const {return group_name;} const char *get_name() const { return name; } const char *get_description() const { return description; } int get_enabled() const { return enabled; } virtual void set_enabled(int enabled) { this->enabled = enabled; } virtual void reset() {} int getint() const {return -1;} static const char* set_default_format(const char *f); static const char *get_default_format() { return default_text_format; } virtual bx_list_c *get_dependent_list() { return NULL; } #if BX_USE_TEXTCONFIG virtual void text_print(FILE *fp) {} virtual int text_ask(FILE *fpin, FILE *fpout) {return -1;} #endif }; typedef Bit64s (*param_event_handler)(class bx_param_c *, int set, Bit64s val); #if BX_SUPPORT_SAVE_RESTORE typedef Bit64s (*param_sr_handler)(void *devptr, class bx_param_c *, Bit64s val); #endif typedef int (*param_enable_handler)(class bx_param_c *, int en); class BOCHSAPI bx_param_num_c : public bx_param_c { BOCHSAPI_CYGONLY static Bit32u default_base; // The dependent_list is initialized to NULL. If dependent_list is modified // to point to a bx_list_c of other parameters, the set() method of // bx_param_bool_c will enable those parameters when this bool is true, and // disable them when this bool is false. bx_list_c *dependent_list; void update_dependents(); protected: Bit64s min, max, initial_val; union _uval_ { Bit64s number; // used by bx_param_num_c Bit64s *p64bit; // used by bx_shadow_num_c Bit32s *p32bit; // used by bx_shadow_num_c Bit16s *p16bit; // used by bx_shadow_num_c Bit8s *p8bit; // used by bx_shadow_num_c bx_bool *pbool; // used by bx_shadow_bool_c } val; param_event_handler handler; #if BX_SUPPORT_SAVE_RESTORE void *sr_devptr; param_sr_handler save_handler; param_sr_handler restore_handler; #endif param_enable_handler enable_handler; int base; Bit32u options; bx_bool is_shadow; public: enum { // When a bx_param_num_c is displayed in dialog, USE_SPIN_CONTROL controls // whether a spin control should be used instead of a simple text control. USE_SPIN_CONTROL = (1<<0) } bx_numopt_bits; bx_param_num_c(bx_param_c *parent, const char *name, const char *label, const char *description, Bit64s min, Bit64s max, Bit64s initial_val, bx_bool is_shadow = 0); virtual void reset(); void set_handler(param_event_handler handler); #if BX_SUPPORT_SAVE_RESTORE void set_sr_handlers(void *devptr, param_sr_handler save, param_sr_handler restore); #endif void set_enable_handler(param_enable_handler handler); virtual bx_list_c *get_dependent_list() { return dependent_list; } void set_dependent_list(bx_list_c *l); virtual void set_enabled(int enabled); virtual Bit32s get() { return (Bit32s) get64(); } virtual Bit64s get64(); virtual void set(Bit64s val); void set_base(int base) { this->base = base; } void set_initial_val(Bit64s initial_val); int get_base() const { return base; } void set_range(Bit64u min, Bit64u max); Bit64s get_min() { return min; } Bit64s get_max() { return max; } static Bit32u set_default_base(Bit32u val); static Bit32u get_default_base() { return default_base; } void set_options(Bit32u options) { this->options = options; } Bit32u get_options() const { return options; } #if BX_USE_TEXTCONFIG virtual void text_print(FILE *fp); virtual int text_ask(FILE *fpin, FILE *fpout); #endif }; // a bx_shadow_num_c is like a bx_param_num_c except that it doesn't // store the actual value with its data. Instead, it uses val.p32bit // to keep a pointer to the actual data. This is used to register // existing variables as parameters, without having to access it via // set/get methods. class BOCHSAPI bx_shadow_num_c : public bx_param_num_c { Bit8u varsize; // must be 64, 32, 16, or 8 Bit8u lowbit; // range of bits associated with this param Bit64u mask; // mask is ANDed with value before it is returned from get public: bx_shadow_num_c(bx_param_c *parent, const char *name, Bit64s *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 63, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit64u *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 63, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit32s *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 31, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit32u *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 31, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit16s *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 15, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit16u *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 15, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit8s *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 7, Bit8u lowbit = 0); bx_shadow_num_c(bx_param_c *parent, const char *name, Bit8u *ptr_to_real_val, int base = BASE_DEC, Bit8u highbit = 7, Bit8u lowbit = 0); virtual Bit64s get64(); virtual void set(Bit64s val); virtual void reset(); }; class BOCHSAPI bx_param_bool_c : public bx_param_num_c { // many boolean variables are used to enable/disable modules. In the // user interface, the enable variable should enable/disable all the // other parameters associated with that module. public: bx_param_bool_c(bx_param_c *parent, const char *name, const char *label, const char *description, Bit64s initial_val, bx_bool is_shadow = 0); #if BX_USE_TEXTCONFIG virtual void text_print(FILE *fp); virtual int text_ask(FILE *fpin, FILE *fpout); #endif }; // a bx_shadow_bool_c is a shadow param based on bx_param_bool_c. class BOCHSAPI bx_shadow_bool_c : public bx_param_bool_c { // each bit of a bitfield can be a separate value. bitnum tells which // bit is used. get/set will only modify that bit. Bit8u bitnum; public: bx_shadow_bool_c(bx_param_c *parent, const char *name, const char *label, bx_bool *ptr_to_real_val, Bit8u bitnum = 0); bx_shadow_bool_c(bx_param_c *parent, const char *name, bx_bool *ptr_to_real_val, Bit8u bitnum = 0); virtual Bit64s get64(); virtual void set(Bit64s val); }; class BOCHSAPI bx_param_enum_c : public bx_param_num_c { char **choices; public: bx_param_enum_c(bx_param_c *parent, const char *name, const char *label, const char *description, char **choices, Bit64s initial_val, Bit64s value_base = 0); char *get_choice(int n) { return choices[n]; } char *get_selected() { return choices[val.number - min]; } int find_by_name(const char *string); bx_bool set_by_name(const char *string); #if BX_USE_TEXTCONFIG virtual void text_print(FILE *fp); virtual int text_ask(FILE *fpin, FILE *fpout); #endif }; typedef const char* (*param_string_event_handler)(class bx_param_string_c *, int set, const char *val, int maxlen); class BOCHSAPI bx_param_string_c : public bx_param_c { int maxsize; char *val, *initial_val; param_string_event_handler handler; param_enable_handler enable_handler; bx_param_num_c *options; char separator; public: enum { RAW_BYTES = 1, // use binary text editor, like MAC addr IS_FILENAME = 2, // 1=yes it's a filename, 0=not a filename. // Some guis have a file browser. This // bit suggests that they use it. SAVE_FILE_DIALOG = 4, // Use save dialog opposed to open file dialog SELECT_FOLDER_DLG = 8 // Use folder selection dialog } bx_string_opt_bits; bx_param_string_c(bx_param_c *parent, const char *name, const char *label, const char *description, const char *initial_val, int maxsize=-1); virtual ~bx_param_string_c(); virtual void reset(); void set_handler(param_string_event_handler handler); void set_enable_handler(param_enable_handler handler); virtual void set_enabled(int enabled); Bit32s get(char *buf, int len); char *getptr() {return val; } void set(const char *buf); bx_bool equals(const char *buf); bx_param_num_c *get_options() { return options; } void set_separator(char sep) {separator = sep; } char get_separator() const {return separator; } int get_maxsize() const {return maxsize; } void set_initial_val(const char *buf); #if BX_USE_TEXTCONFIG virtual void text_print(FILE *fp); virtual int text_ask(FILE *fpin, FILE *fpout); #endif }; // Declare a filename class. It is identical to a string, except that // it initializes the options differently. This is just a shortcut // for declaring a string param and setting the options with IS_FILENAME. class BOCHSAPI bx_param_filename_c : public bx_param_string_c { public: bx_param_filename_c(bx_param_c *parent, const char *name, const char *label, const char *description, const char *initial_val, int maxsize=-1); }; #if BX_SUPPORT_SAVE_RESTORE class BOCHSAPI bx_shadow_data_c : public bx_param_c { Bit32u data_size; Bit8u *data_ptr; public: bx_shadow_data_c(bx_param_c *parent, const char *name, Bit8u *ptr_to_data, Bit32u data_size); Bit8u *getptr() {return data_ptr;} Bit32u get_size() const {return data_size;} }; #endif #define BX_DEFAULT_LIST_SIZE 6 class BOCHSAPI bx_list_c : public bx_param_c { protected: // just a list of bx_param_c objects. size tells current number of // objects in the list, and maxsize tells how many list items are // allocated in the constructor. bx_param_c **list; int size, maxsize; // options is a bit field whose bits are defined by bx_listopt_bits ORed // together. Options is a bx_param so that if necessary the bx_list could // install a handler to cause get/set of options to have side effects. bx_param_num_c *options; // for a menu, the value of choice before the call to "ask" is default. // After ask, choice holds the value that the user chose. Choice defaults // to 1 in the constructor. bx_param_num_c *choice; // title of the menu or series bx_param_string_c *title; void init(const char *list_title); public: enum { // When a bx_list_c is displayed as a menu, SHOW_PARENT controls whether or // not the menu shows a "Return to parent menu" choice or not. SHOW_PARENT = (1<<0), // Some lists are best displayed shown as menus, others as a series of // related questions. This bit suggests to the CI that the series of // questions format is preferred. SERIES_ASK = (1<<1), // When a bx_list_c is displayed in a dialog, USE_TAB_WINDOW suggests // to the CI that each item in the list should be shown as a separate // tab. This would be most appropriate when each item is another list // of parameters. USE_TAB_WINDOW = (1<<2), // When a bx_list_c is displayed in a dialog, the list name is used as the // label of the group box if USE_BOX_TITLE is set. This is only necessary if // more than one list appears in a dialog box. USE_BOX_TITLE = (1<<3), // When a bx_list_c is displayed as a menu, SHOW_GROUP_NAME controls whether // or not the name of group the item belongs to is added to the name of the // item (used in the runtime menu). SHOW_GROUP_NAME = (1<<4) } bx_listopt_bits; bx_list_c(bx_param_c *parent, int maxsize = BX_DEFAULT_LIST_SIZE); bx_list_c(bx_param_c *parent, const char *name, int maxsize = BX_DEFAULT_LIST_SIZE); bx_list_c(bx_param_c *parent, const char *name, char *title, int maxsize = BX_DEFAULT_LIST_SIZE); bx_list_c(bx_param_c *parent, const char *name, char *title, bx_param_c **init_list); virtual ~bx_list_c(); bx_list_c *clone(); void add(bx_param_c *param); bx_param_c *get(int index); bx_param_c *get_by_name(const char *name); int get_size() const { return size; } bx_param_num_c *get_options() { return options; } bx_param_num_c *get_choice() { return choice; } bx_param_string_c *get_title() { return title; } void set_parent(bx_param_c *newparent); bx_param_c *get_parent() { return parent; } virtual void reset(); virtual void clear(); #if BX_USE_TEXTCONFIG virtual void text_print(FILE *); virtual int text_ask(FILE *fpin, FILE *fpout); #endif }; //////////////////////////////////////////////////////////////// // These are the different start modes. enum { // Just start the simulation without running the configuration interface // at all, unless something goes wrong. BX_QUICK_START = 200, // Run the configuration interface. The default action will be to load a // configuration file. This makes sense if a config file could not be // loaded, either because it wasn't found or because it had errors. BX_LOAD_START, // Run the configuration interface. The default action will be to // edit the configuration. BX_EDIT_START, // Run the configuration interface, but make the default action be to // start the simulation. BX_RUN_START }; enum { BX_MOUSE_TYPE_NONE, BX_MOUSE_TYPE_PS2, BX_MOUSE_TYPE_IMPS2, #if BX_SUPPORT_BUSMOUSE BX_MOUSE_TYPE_BUS, #endif #if BX_SUPPORT_PCIUSB BX_MOUSE_TYPE_USB, #endif BX_MOUSE_TYPE_SERIAL, BX_MOUSE_TYPE_SERIAL_WHEEL }; #define BX_FLOPPY_NONE 10 // floppy not present #define BX_FLOPPY_1_2 11 // 1.2M 5.25" #define BX_FLOPPY_1_44 12 // 1.44M 3.5" #define BX_FLOPPY_2_88 13 // 2.88M 3.5" #define BX_FLOPPY_720K 14 // 720K 3.5" #define BX_FLOPPY_360K 15 // 360K 5.25" #define BX_FLOPPY_160K 16 // 160K 5.25" #define BX_FLOPPY_180K 17 // 180K 5.25" #define BX_FLOPPY_320K 18 // 320K 5.25" #define BX_FLOPPY_LAST 18 // last legal value of floppy type #define BX_FLOPPY_AUTO 19 // autodetect image size #define BX_FLOPPY_UNKNOWN 20 // image size doesn't match one of the types above #define BX_ATA_DEVICE_DISK 0 #define BX_ATA_DEVICE_CDROM 1 #define BX_ATA_DEVICE_LAST 1 #define BX_ATA_BIOSDETECT_NONE 0 #define BX_ATA_BIOSDETECT_AUTO 1 #define BX_ATA_BIOSDETECT_CMOS 2 #define BX_ATA_TRANSLATION_NONE 0 #define BX_ATA_TRANSLATION_LBA 1 #define BX_ATA_TRANSLATION_LARGE 2 #define BX_ATA_TRANSLATION_RECHS 3 #define BX_ATA_TRANSLATION_AUTO 4 #define BX_ATA_TRANSLATION_LAST 4 #define BX_ATA_MODE_FLAT 0 #define BX_ATA_MODE_CONCAT 1 #define BX_ATA_MODE_EXTDISKSIM 2 #define BX_ATA_MODE_DLL_HD 3 #define BX_ATA_MODE_SPARSE 4 #define BX_ATA_MODE_VMWARE3 5 #define BX_ATA_MODE_UNDOABLE 6 #define BX_ATA_MODE_GROWING 7 #define BX_ATA_MODE_VOLATILE 8 #define BX_ATA_MODE_Z_UNDOABLE 9 #define BX_ATA_MODE_Z_VOLATILE 10 #define BX_ATA_MODE_LAST 10 #define BX_CLOCK_SYNC_NONE 0 #define BX_CLOCK_SYNC_REALTIME 1 #define BX_CLOCK_SYNC_SLOWDOWN 2 #define BX_CLOCK_SYNC_BOTH 3 #define BX_CLOCK_SYNC_LAST 3 #define BX_CLOCK_TIME0_LOCAL 1 #define BX_CLOCK_TIME0_UTC 2 BOCHSAPI extern char *bochs_start_names[]; BOCHSAPI extern int n_bochs_start_names; BOCHSAPI extern char *floppy_type_names[]; BOCHSAPI extern int floppy_type_n_sectors[]; BOCHSAPI extern int n_floppy_type_names; BOCHSAPI extern char *floppy_status_names[]; BOCHSAPI extern int n_floppy_status_names; BOCHSAPI extern char *bochs_bootdisk_names[]; BOCHSAPI extern int n_bochs_bootdisk_names; BOCHSAPI extern char *loader_os_names[]; BOCHSAPI extern int n_loader_os_names; BOCHSAPI extern char *keyboard_type_names[]; BOCHSAPI extern int n_keyboard_type_names; BOCHSAPI extern char *atadevice_type_names[]; BOCHSAPI extern int n_atadevice_type_names; BOCHSAPI extern char *atadevice_mode_names[]; BOCHSAPI extern int n_atadevice_mode_names; BOCHSAPI extern char *atadevice_status_names[]; BOCHSAPI extern int n_atadevice_status_names; BOCHSAPI extern char *atadevice_biosdetect_names[]; BOCHSAPI extern int n_atadevice_biosdetect_names; BOCHSAPI extern char *atadevice_translation_names[]; BOCHSAPI extern int n_atadevice_translation_names; BOCHSAPI extern char *clock_sync_names[]; BOCHSAPI extern int clock_sync_n_names; //////////////////////////////////////////////////////////////////// // base class simulator interface, contains just virtual functions. // I'm not longer sure that having a base class is going to be of any // use... -Bryce #include enum ci_command_t { CI_START, CI_RUNTIME_CONFIG, CI_SHUTDOWN }; enum ci_return_t { CI_OK, // normal return value CI_ERR_NO_TEXT_CONSOLE // err: can't work because there's no text console }; typedef int (*config_interface_callback_t)(void *userdata, ci_command_t command); typedef BxEvent* (*bxevent_handler)(void *theclass, BxEvent *event); typedef Bit32s (*user_option_parser_t)(const char *context, int num_params, char *params[]); typedef Bit32s (*user_option_save_t)(FILE *fp); // bx_gui->set_display_mode() changes the mode between the configuration // interface and the simulation. This is primarily intended for display // libraries which have a full-screen mode such as SDL, term, and svgalib. The // display mode is set to DISP_MODE_CONFIG before displaying any configuration // menus, for panics that requires user input, when entering the debugger, etc. // It is set to DISP_MODE_SIM when the Bochs simulation resumes. The constants // are defined here so that configuration interfaces can use them with the // bx_simulator_interface_c::set_display_mode() method. enum disp_mode_t { DISP_MODE_CONFIG=100, DISP_MODE_SIM }; class BOCHSAPI bx_simulator_interface_c { public: bx_simulator_interface_c() {} virtual void set_quit_context(jmp_buf *context) {} virtual int get_init_done() { return -1; } virtual int set_init_done(int n) {return -1;} virtual void reset_all_param() {} // new param methods virtual bx_param_c *get_param(const char *pname, bx_param_c *base=NULL) {return NULL;} virtual bx_param_num_c *get_param_num(const char *pname, bx_param_c *base=NULL) {return NULL;} virtual bx_param_string_c *get_param_string(const char *pname, bx_param_c *base=NULL) {return NULL;} virtual bx_param_bool_c *get_param_bool(const char *pname, bx_param_c *base=NULL) {return NULL;} virtual bx_param_enum_c *get_param_enum(const char *pname, bx_param_c *base=NULL) {return NULL;} virtual unsigned gen_param_id() {return 0;} virtual int get_n_log_modules() {return -1;} virtual char *get_prefix(int mod) {return 0;} virtual int get_log_action(int mod, int level) {return -1;} virtual void set_log_action(int mod, int level, int action) {} virtual int get_default_log_action(int level) {return -1;} virtual void set_default_log_action(int level, int action) {} virtual char *get_action_name(int action) {return 0;} virtual const char *get_log_level_name(int level) {return 0;} virtual int get_max_log_level() {return -1;} // exiting is somewhat complicated! The preferred way to exit bochs is // to call BX_EXIT(exitcode). That is defined to call // SIM->quit_sim(exitcode). The quit_sim function first calls // the cleanup functions in bochs so that it can destroy windows // and free up memory, then sends a notify message to the CI // telling it that bochs has stopped. virtual void quit_sim(int code) {} virtual int get_exit_code() { return 0; } virtual int get_default_rc(char *path, int len) {return -1;} virtual int read_rc(const char *path) {return -1;} virtual int write_rc(const char *rc, int overwrite) {return -1;} virtual int get_log_file(char *path, int len) {return -1;} virtual int set_log_file(char *path) {return -1;} virtual int get_log_prefix(char *prefix, int len) {return -1;} virtual int set_log_prefix(char *prefix) {return -1;} virtual int get_debugger_log_file(char *path, int len) {return -1;} virtual int set_debugger_log_file(char *path) {return -1;} virtual int get_cdrom_options(int drive, bx_list_c **out, int *where = NULL) {return -1;} // The CI calls set_notify_callback to register its event handler function. // This event handler function is called whenever the simulator needs to // send an event to the CI. For example, if the simulator hits a panic and // wants to ask the user how to proceed, it would call the CI event handler // to ask the CI to display a dialog. // // NOTE: At present, the standard VGAW buttons (floppy, snapshot, power, // etc.) are displayed and handled by gui.cc, not by the CI or siminterface. // gui.cc uses its own callback functions to implement the behavior of // the buttons. Some of these implementations call the siminterface. virtual void set_notify_callback(bxevent_handler func, void *arg) {} virtual void get_notify_callback(bxevent_handler *func, void **arg) {} // send an event from the simulator to the CI. virtual BxEvent* sim_to_ci_event(BxEvent *event) {return NULL;} // called from simulator when it hits serious errors, to ask if the user // wants to continue or not virtual int log_msg(const char *prefix, int level, const char *msg) {return -1;} // tell the CI to ask the user for the value of a parameter. virtual int ask_param(bx_param_c *param) {return -1;} virtual int ask_param(const char *pname) {return -1;} // ask the user for a pathname virtual int ask_filename(char *filename, int maxlen, char *prompt, char *the_default, int flags) {return -1;} // yes/no dialog virtual int ask_yes_no(char *title, char *prompt, bx_bool the_default) {return -1;} // 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) {return -3;} // Tell the configuration interface (CI) that some parameter values have // changed. The CI will reread the parameters and change its display if it's // appropriate. Maybe later: mention which params have changed to save time. virtual void refresh_ci() {} // forces a vga update. This was added so that a debugger can force // a vga update when single stepping, without having to wait thousands // of cycles for the normal vga refresh triggered by iodev/keyboard.cc. virtual void refresh_vga() {} // forces a call to bx_gui.handle_events. This was added so that a debugger // can force the gui events to be handled, so that interactive things such // as a toolbar click will be processed. virtual void handle_events() {} // return first hard disk in ATA interface virtual bx_param_c *get_first_cdrom() {return NULL;} // return first cdrom in ATA interface virtual bx_param_c *get_first_hd() {return NULL;} #if BX_DEBUGGER // for debugger: same behavior as pressing control-C virtual void debug_break() {} virtual void debug_interpret_cmd(char *cmd) {} virtual char *debug_get_next_command() {return NULL;} virtual void debug_puts(const char *text) {} #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) {return -1; } virtual int begin_simulation(int argc, char *argv[]) {return -1;} typedef bx_bool (*is_sim_thread_func_t)(); is_sim_thread_func_t is_sim_thread_func; virtual void set_sim_thread_func(is_sim_thread_func_t func) { is_sim_thread_func = func; } virtual bx_bool is_sim_thread() {return 1;} virtual bx_bool is_wx_selected() {return 0;} // provide interface to bx_gui->set_display_mode() method for config // interfaces to use. virtual void set_display_mode(disp_mode_t newmode) {} virtual bx_bool test_for_text_console() {return 1;} // user-defined option support virtual int find_user_option(const char *keyword) {return -1;} virtual bx_bool register_user_option(const char *keyword, user_option_parser_t parser, user_option_save_t save_func) {return 0;} virtual Bit32s parse_user_option(int idx, const char *context, int num_params, char *params []) {return -1;} virtual Bit32s save_user_options(FILE *fp) {return -1;} #if BX_SUPPORT_SAVE_RESTORE // save/restore support virtual void init_save_restore() {} virtual bx_bool save_state(const char *checkpoint_path) {return 0;} virtual bx_bool restore_config() {return 0;} virtual bx_bool restore_logopts() {return 0;} virtual bx_bool restore_hardware() {return 0;} virtual bx_list_c *get_sr_root() {return NULL;} #endif }; BOCHSAPI extern bx_simulator_interface_c *SIM; BOCHSAPI extern void bx_init_siminterface(); BOCHSAPI extern int bx_init_main(int argc, char *argv[]); #if defined(__WXMSW__) || defined(WIN32) // Just to provide HINSTANCE, etc. in files that have not included bochs.h. // I don't like this at all, but I don't see a way around it. #include #endif // define structure to hold data that is passed into our main function. typedef struct BOCHSAPI { // standard argc,argv int argc; char **argv; #ifdef WIN32 char initial_dir[MAX_PATH]; #endif #ifdef __WXMSW__ // these are only used when compiling with wxWidgets. This gives us a // place to store the data that was passed to WinMain. HINSTANCE hInstance; HINSTANCE hPrevInstance; LPSTR m_lpCmdLine; int nCmdShow; #endif } bx_startup_flags_t; BOCHSAPI extern bx_startup_flags_t bx_startup_flags; BOCHSAPI extern bx_bool bx_user_quit; BOCHSAPI extern Bit8u bx_cpu_count;