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[/] [ao486/] [trunk/] [bochsDevs/] [main.cpp] - Rev 2
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#include <cstdio> #include <cstdlib> #include <dlfcn.h> #include <sys/mman.h> #include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> #include <unistd.h> #include "shared_mem.h" #include "bochs.h" #include "plugin.h" #include "extplugin.h" #include "iodev/iodev.h" #include "iodev/virt_timer.h" //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ volatile shared_mem_t *shared_ptr = NULL; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ ioWriteHandler_t io_write_handlers[65537]; void * io_write_this [65537]; uint8 io_write_mask [65537]; ioReadHandler_t io_read_handlers [65537]; void * io_read_this [65537]; uint8 io_read_mask [65537]; void (*pluginRegisterIRQ)(unsigned irq, const char* name) = 0; int (*pluginRegisterIOReadHandler)(void *thisPtr, ioReadHandler_t callback, unsigned base, const char *name, Bit8u mask) = 0; int (*pluginRegisterIOWriteHandler)(void *thisPtr, ioWriteHandler_t callback, unsigned base, const char *name, Bit8u mask) = 0; int (*pluginRegisterDefaultIOReadHandler)(void *thisPtr, ioReadHandler_t callback, const char *name, Bit8u mask) = 0; int (*pluginRegisterDefaultIOWriteHandler)(void *thisPtr, ioWriteHandler_t callback, const char *name, Bit8u mask) = 0; static void builtinRegisterIRQ(unsigned irq, const char* name) { //bx_devices.register_irq(irq, name); printf("builtinRegisterIRQ(%d, %s)\n", irq, name); } static int builtinRegisterIOReadHandler(void *thisPtr, ioReadHandler_t callback, unsigned base, const char *name, Bit8u mask) { // int ret; // BX_ASSERT(mask<8); // ret = bx_devices.register_io_read_handler (thisPtr, callback, base, name, mask); // pluginlog->ldebug("plugin %s registered I/O read address at %04x", name, base); // return ret; printf("builtinRegisterIOReadHandler: %s %04x %d\n", name, base, mask); io_read_handlers[base] = callback; io_read_mask[base] = mask; io_read_this[base] = thisPtr; return 1; } static int builtinRegisterIOWriteHandler(void *thisPtr, ioWriteHandler_t callback, unsigned base, const char *name, Bit8u mask) { // int ret; // BX_ASSERT(mask<8); // ret = bx_devices.register_io_write_handler (thisPtr, callback, base, name, mask); // pluginlog->ldebug("plugin %s registered I/O write address at %04x", name, base); // return ret; printf("builtinRegisterIOWriteHandler: %s %04x %d\n", name, base, mask); io_write_handlers[base] = callback; io_write_mask[base] = mask; io_write_this[base] = thisPtr; return 1; } static int builtinRegisterDefaultIOReadHandler(void *thisPtr, ioReadHandler_t callback, const char *name, Bit8u mask) { // BX_ASSERT(mask<8); // bx_devices.register_default_io_read_handler (thisPtr, callback, name, mask); // pluginlog->ldebug("plugin %s registered default I/O read ", name); printf("builtinRegisterDefaultIOReadHandler: %s %x\n", name, mask); io_read_handlers[65536] = callback; io_read_mask[65536] = mask; io_read_this[65536] = thisPtr; return 1; } static int builtinRegisterDefaultIOWriteHandler(void *thisPtr, ioWriteHandler_t callback, const char *name, Bit8u mask) { // BX_ASSERT(mask<8); // bx_devices.register_default_io_write_handler (thisPtr, callback, name, mask); // pluginlog->ldebug("plugin %s registered default I/O write ", name); printf("builtinRegisterDefaultIOWriteHandler: %s %x\n", name, mask); io_write_handlers[65536] = callback; io_write_mask[65536] = mask; io_write_this[65536] = thisPtr; return 1; } void pluginRegisterDeviceDevmodel(plugin_t *plugin, plugintype_t type, bx_devmodel_c *devmodel, const char *name) { printf("pluginRegisterDeviceDevmodel() for %s\n", name); devmodel->init(); } //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ SIM const char *enum_choices[] = { "0_choice", "1_choice", NULL }; #define BOCHS_DEVS_IPS 480000 BxEvent *callback(void *theclass, BxEvent *event) { printf("bochsDevs::callback()\n"); return event; } bxevent_handler bxevent_callback = callback; void * bxevent_callback_data = NULL; class bochsDevs_sim : public bx_simulator_interface_c { bx_param_bool_c *get_param_bool(const char *pname, bx_param_c *base) { printf("bochsDevs_sim::get_param_bool(%s, base=%s)\n", pname, (base==NULL)? "(nil)" : (base->get_name() == NULL)? "(nill name)" : base->get_name()); if(base != NULL) { bx_param_c *param = ((bx_list_c *)base)->get_by_name(pname); return (bx_param_bool_c *)param; } if(strcmp(pname, BXPN_PORT_E9_HACK) == 0) return new bx_param_bool_c(NULL, "port_e9_hack", "", "", 0); if(strcmp(pname, BXPN_CMOSIMAGE_ENABLED) == 0) return new bx_param_bool_c(NULL, "enabled", "", "", 0); if(strcmp(pname, BXPN_FLOPPYSIGCHECK) == 0) return new bx_param_bool_c(NULL, "floppy_sig_check", "", "", 0); if(strcmp(pname, BXPN_PCI_ENABLED) == 0) return new bx_param_bool_c(NULL, "enabled", "", "", 0); if(strcmp(pname, BXPN_PRIVATE_COLORMAP) == 0) return new bx_param_bool_c(NULL, "private_colormap", "", "", 0); if(strcmp(pname, BXPN_KBD_USEMAPPING) == 0) return new bx_param_bool_c(NULL, "use_mapping", "", "", 0); if(strcmp(pname, BXPN_MOUSE_ENABLED) == 0) return new bx_param_bool_c(NULL, "enabled", "", "", 0); return NULL; } bx_param_string_c *get_param_string(const char *pname, bx_param_c *base) { printf("bochsDevs_sim::get_param_string(%s, base=%s)\n", pname, (base==NULL)? "(nil)" : (base->get_name() == NULL)? "(nill name)" : base->get_name()); if(base != NULL) { bx_param_c *param = ((bx_list_c *)base)->get_by_name(pname); return (bx_param_string_c *)param; } if(strcmp(pname, BXPN_VGA_EXTENSION) == 0) return new bx_param_string_c(NULL, "vga_extension", "", "", "none"); if(strcmp(pname, BXPN_DISPLAYLIB_OPTIONS) == 0) return new bx_param_string_c(NULL, "displaylib_options", "", "", ""); if(strcmp(pname, BXPN_VGA_ROM_PATH) == 0) return new bx_param_string_c(NULL, "path", "", "", ""); return NULL; } bx_param_enum_c *get_param_enum(const char *pname, bx_param_c *base) { printf("bochsDevs_sim::get_param_enum(%s, base=%s)\n", pname, (base==NULL)? "(nil)" : (base->get_name() == NULL)? "(nill name)" : base->get_name()); if(base != NULL) { bx_param_c *param = ((bx_list_c *)base)->get_by_name(pname); return (bx_param_enum_c *)param; } if(strcmp(pname, BXPN_CLOCK_SYNC) == 0) return new bx_param_enum_c(NULL, "clock_sync", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYA_DEVTYPE) == 0) return new bx_param_enum_c(NULL, "devtype", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYA_TYPE) == 0) return new bx_param_enum_c(NULL, "type", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYA_STATUS) == 0) return new bx_param_enum_c(NULL, "status", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYB_DEVTYPE) == 0) return new bx_param_enum_c(NULL, "devtype", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYB_TYPE) == 0) return new bx_param_enum_c(NULL, "type", "", "", enum_choices, 0); if(strcmp(pname, BXPN_FLOPPYB_STATUS) == 0) return new bx_param_enum_c(NULL, "status", "", "", enum_choices, 0); if(strcmp(pname, BXPN_BOOTDRIVE1) == 0) return new bx_param_enum_c(NULL, "boot_drive1", "", "", enum_choices, BX_BOOT_FLOPPYA); if(strcmp(pname, BXPN_BOOTDRIVE2) == 0) return new bx_param_enum_c(NULL, "boot_drive2", "", "", enum_choices, BX_BOOT_FLOPPYA); if(strcmp(pname, BXPN_BOOTDRIVE3) == 0) return new bx_param_enum_c(NULL, "boot_drive3", "", "", enum_choices, BX_BOOT_FLOPPYA); if(strcmp(pname, BXPN_MOUSE_TYPE) == 0) return new bx_param_enum_c(NULL, "type", "", "", enum_choices, BX_MOUSE_TYPE_PS2); if(strcmp(pname, BXPN_MOUSE_TOGGLE) == 0) return new bx_param_enum_c(NULL, "toggle", "", "", enum_choices, BX_MOUSE_TOGGLE_CTRL_F10); if(strcmp(pname, BXPN_KBD_TYPE) == 0) return new bx_param_enum_c(NULL, "type", "", "", enum_choices, BX_KBD_AT_TYPE); return NULL; } bx_param_num_c *get_param_num(const char *pname, bx_param_c *base) { printf("bochsDevs_sim::get_param_num(%s, base=%s)\n", pname, (base==NULL)? "(nil)" : (base->get_name() == NULL)? "(nill name)" : base->get_name()); if(base != NULL) { bx_param_c *param = ((bx_list_c *)base)->get_by_name(pname); return (bx_param_num_c *)param; } if(strcmp(pname, BXPN_CLOCK_TIME0) == 0) return new bx_param_num_c(NULL, "time0", "", "", 100,100,100); if(strcmp(pname, BXPN_KBD_SERIAL_DELAY) == 0) return new bx_param_num_c(NULL, "serial_delay", "", "", 100,100,100); if(strcmp(pname, BXPN_KBD_PASTE_DELAY) == 0) return new bx_param_num_c(NULL, "paste_delay", "", "", 100,100,100); if(strcmp(pname, BXPN_MOUSE_ENABLED) == 0) return new bx_param_num_c(NULL, "enabled", "", "", 1,1,1); if(strcmp(pname, BXPN_VGA_UPDATE_FREQUENCY) == 0) return new bx_param_num_c(NULL, "vga_update_frequency", "", "", 500000,500000,500000); if(strcmp(pname, BXPN_IPS) == 0) return new bx_param_num_c(NULL, "ips", "", "", BOCHS_DEVS_IPS, BOCHS_DEVS_IPS, BOCHS_DEVS_IPS); return NULL; } bx_param_c *get_param(const char *pname, bx_param_c *base=NULL) { if(strcmp(pname, BXPN_ATA0_RES) == 0) { bx_list_c *list = new bx_list_c(NULL); list->add(new bx_param_bool_c(NULL, "enabled", "", "", 1)); list->add(new bx_param_num_c(NULL, "ioaddr1", "", "", 0x1f0,0x1f0,0x1f0)); list->add(new bx_param_num_c(NULL, "ioaddr2", "", "", 0x3f0,0x3f0,0x3f0)); list->add(new bx_param_num_c(NULL, "irq", "", "", 14,14,14)); return list; } if(strcmp(pname, BXPN_ATA1_RES) == 0 || strcmp(pname, BXPN_ATA2_RES) == 0 || strcmp(pname, BXPN_ATA3_RES) == 0) { bx_list_c *list = new bx_list_c(NULL); list->add(new bx_param_bool_c(NULL, "enabled", "", "", 0)); return list; } if(strcmp(pname, BXPN_FLOPPYA) == 0 || strcmp(pname, BXPN_FLOPPYB) == 0) { bx_list_c *list = new bx_list_c(NULL); list->add(new bx_param_enum_c(NULL, "status", "", "", enum_choices, 0)); list->add(new bx_param_bool_c(NULL, "readonly", "", "", 1)); list->add(new bx_param_string_c(NULL, "path", "", "", "none")); return list; } if(strcmp(pname, BXPN_ATA0_MASTER) == 0) { bx_list_c *list = new bx_list_c(NULL); list->add(new bx_param_enum_c(NULL, "type", "", "", enum_choices, BX_ATA_DEVICE_DISK)); list->add(new bx_param_string_c(NULL, "model", "", "", "HDmodel")); list->add(new bx_param_num_c(NULL, "cylinders", "", "", 1024,1024,1024)); list->add(new bx_param_num_c(NULL, "heads", "", "", 16,16,16)); list->add(new bx_param_num_c(NULL, "spt", "", "", 63,63,63)); list->add(new bx_param_enum_c(NULL, "mode", "", "", enum_choices, BX_HDIMAGE_MODE_FLAT)); list->add(new bx_param_string_c(NULL, "path", "", "", "/home/alek/temp/bochs-run/hd.img")); list->add(new bx_param_string_c(NULL, "journal", "", "", "")); list->add(new bx_param_enum_c(NULL, "translation", "", "", enum_choices, BX_ATA_TRANSLATION_NONE)); return list; } if(strcmp(pname, BXPN_ATA1_MASTER) == 0 || strcmp(pname, BXPN_ATA2_MASTER) == 0 || strcmp(pname, BXPN_ATA3_MASTER) == 0 || strcmp(pname, BXPN_ATA0_SLAVE) == 0 || strcmp(pname, BXPN_ATA1_SLAVE) == 0 || strcmp(pname, BXPN_ATA2_SLAVE) == 0 || strcmp(pname, BXPN_ATA3_SLAVE) == 0) { bx_list_c *list = new bx_list_c(NULL); list->add(new bx_param_enum_c(NULL, "type", "", "", enum_choices, BX_ATA_DEVICE_NONE)); return list; } return NULL; } void set_notify_callback(bxevent_handler func, void *arg) { bxevent_callback = func; bxevent_callback_data = arg; } void get_notify_callback(bxevent_handler *func, void **arg) { *func = bxevent_callback; *arg = bxevent_callback_data; } }; bx_simulator_interface_c *SIM; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ logfunctions void logfunctions::panic(const char *fmt, ...) { printf("#bochsDevs::logfunctions::panic(): "); va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); fflush(stdout); if(strstr(fmt, "exception with no resolution") != NULL) { printf("start_shutdown: 0\n"); printf("\n"); fflush(stdout); exit(0); } else { exit(-1); } } void logfunctions::error(const char *fmt, ...) { printf("#bochsDevs::logfunctions::error(): "); va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); fflush(stdout); } void logfunctions::ldebug(const char *fmt, ...) { printf("#bochsDevs::logfunctions::debug(): "); va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); fflush(stdout); } void logfunctions::info(const char *fmt, ...) { printf("#bochsDevs::logfunctions::info(): "); va_list ap; va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); printf("\n"); fflush(stdout); } void logfunctions::put(const char *n, const char *p) { } void logfunctions::put(const char *p) { } logfunctions::logfunctions() { } logfunctions::~logfunctions() { } static logfunctions theLog; logfunctions *pluginlog = &theLog; logfunctions *siminterface_log = &theLog; logfunctions *genlog = &theLog; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ menu void bx_param_string_c::text_print(FILE *fp) { printf("#bochsDevs::bx_param_string_c::text_print()\n"); } void bx_param_enum_c::text_print(FILE *fp) { printf("bochsDevs::bx_param_enum_c::text_print()\n"); } void bx_param_bool_c::text_print(FILE *fp) { printf("bochsDevs::bx_param_bool_c::text_print()\n"); } void bx_param_num_c::text_print(FILE *fp) { printf("bochsDevs::bx_param_num_c::text_print()\n"); } void bx_list_c::text_print(FILE *fp) { printf("bochsDevs::bx_list_c::text_print()\n"); } int bx_param_enum_c::text_ask(FILE *fpin, FILE *fpout) { printf("bochsDevs::bx_param_enum_c::text_ask()\n"); return 0; } int bx_param_bool_c::text_ask(FILE *fpin, FILE *fpout) { printf("bochsDevs::bx_param_bool_c::text_ask()\n"); return 0; } int bx_param_num_c::text_ask(FILE *fpin, FILE *fpout) { printf("bochsDevs::bx_param_num_c::text_ask()\n"); return 0; } int bx_param_string_c::text_ask(FILE *fpin, FILE *fpout) { printf("bochsDevs::bx_param_string_c::text_ask()\n"); return 0; } int bx_list_c::text_ask(FILE *fpin, FILE *fpout) { printf("bochsDevs::bx_list_c::text_ask()\n"); return 0; } bx_list_c *root_param = NULL; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ memory memory_handler_t vga_read_memory = NULL; memory_handler_t vga_write_memory = NULL; void * vga_param = NULL; BX_MEM_C::BX_MEM_C() { } BX_MEM_C::~BX_MEM_C() { } void BX_MEM_C::dmaReadPhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data) { printf("bochsDevs::BX_MEM_C::dmaReadPhysicalPage()\n"); memcpy(data, (void *)(shared_ptr->mem.bytes + addr), len); } void BX_MEM_C::dmaWritePhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data) { printf("bochsDevs::BX_MEM_C::dmaWritePhysicalPage()\n"); memcpy((void *)(shared_ptr->mem.bytes + addr), data, len); } bx_bool BX_MEM_C::registerMemoryHandlers(void *param, memory_handler_t read_handler, memory_handler_t write_handler, memory_direct_access_handler_t da_handler, bx_phy_address begin_addr, bx_phy_address end_addr) { printf("bochsDevs::BX_MEM_C::registerMemoryHandlers(): %llx %llx\n", begin_addr, end_addr); if(da_handler != NULL) { printf("bochsDevs::da_handler != NULL\n"); exit(-1); } if(begin_addr != 0xA0000 || end_addr != 0xBFFFF) { printf("bochsDevs::invalid address\n"); exit(-1); } vga_read_memory = read_handler; vga_write_memory= write_handler; vga_param = param; return 1; } void BX_MEM_C::load_ROM(const char *path, bx_phy_address romaddress, Bit8u type) { printf("bochsDevs::BX_MEM_C::load_ROM()\n"); } BX_MEM_C bx_mem; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ bx_bool bx_dbg_register_debug_info(const char *devname, void *dev) { printf("bochsDevs::bx_dbg_register_debug_info() %s\n", devname); return true; } void dbg_printf(const char *fmt, ...) { printf("bochsDevs::dbg_printf(%s)\n", fmt); } void bx_dbg_dma_report(bx_phy_address addr, unsigned len, unsigned what, Bit32u val) { printf("bochsDevs::bx_dbg_dma_report()\n"); } void bx_dbg_iac_report(unsigned vector, unsigned irq) { printf("bochsDevs::bx_dbg_iac_report()\n"); } void bx_debug_break() { printf("bochsDevs::bx_debug_break()\n"); } bx_guard_t bx_guard; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ #define MinAllowableTimerPeriod 1 const Bit64u bx_pc_system_c::NullTimerInterval = 0xffffffff; bx_pc_system_c::bx_pc_system_c() { this->put("pc_system", "SYS"); BX_ASSERT(numTimers == 0); // Timer[0] is the null timer. It is initialized as a special // case here. It should never be turned off or modified, and its // duration should always remain the same. ticksTotal = 0; // Reset ticks since emulator started. timer[0].inUse = 1; timer[0].period = NullTimerInterval; timer[0].active = 1; timer[0].continuous = 1; timer[0].funct = nullTimer; timer[0].this_ptr = this; numTimers = 1; // So far, only the nullTimer. //initialize() ticksTotal = 0; timer[0].timeToFire = NullTimerInterval; currCountdown = NullTimerInterval; currCountdownPeriod = NullTimerInterval; lastTimeUsec = 0; usecSinceLast = 0; triggeredTimer = 0; HRQ = 0; kill_bochs_request = 0; // parameter 'ips' is the processor speed in Instructions-Per-Second m_ips = BOCHS_DEVS_IPS / 1000000.0L; } void bx_pc_system_c::nullTimer(void* this_ptr) { } int bx_pc_system_c::register_timer_ticks(void* this_ptr, bx_timer_handler_t funct, Bit64u ticks, bx_bool continuous, bx_bool active, const char *id) { unsigned i; // If the timer frequency is rediculously low, make it more sane. // This happens when 'ips' is too low. if (ticks < MinAllowableTimerPeriod) { //BX_INFO(("register_timer_ticks: adjusting ticks of %llu to min of %u", // ticks, MinAllowableTimerPeriod)); ticks = MinAllowableTimerPeriod; } // search for new timer for i=1, i=0 is reserved for NullTimer for (i=1; i < numTimers; i++) { if (timer[i].inUse == 0) break; } timer[i].inUse = 1; timer[i].period = ticks; timer[i].timeToFire = (ticksTotal + Bit64u(currCountdownPeriod-currCountdown)) + ticks; timer[i].active = active; timer[i].continuous = continuous; timer[i].funct = funct; timer[i].this_ptr = this_ptr; strncpy(timer[i].id, id, BxMaxTimerIDLen); timer[i].id[BxMaxTimerIDLen-1] = 0; // Null terminate if not already. if (active) { if (ticks < Bit64u(currCountdown)) { // This new timer needs to fire before the current countdown. // Skew the current countdown and countdown period to be smaller // by the delta. currCountdownPeriod -= (currCountdown - Bit32u(ticks)); currCountdown = Bit32u(ticks); } } printf("bochsDevs::timer id %d registered for '%s'", i, id); // If we didn't find a free slot, increment the bound, numTimers. if (i==numTimers) numTimers++; // One new timer installed. // Return timer id. return(i); } int bx_pc_system_c::register_timer(void *this_ptr, void (*funct)(void *), Bit32u useconds, bx_bool continuous, bx_bool active, const char *id) { printf("bochsDevs::bx_pc_system_c::register_timer()\n"); // Convert useconds to number of ticks. Bit64u ticks = (Bit64u) (double(useconds) * m_ips); return register_timer_ticks(this_ptr, funct, ticks, continuous, active, id); } void bx_pc_system_c::activate_timer_ticks(unsigned i, Bit64u ticks, bx_bool continuous) { // If the timer frequency is rediculously low, make it more sane. // This happens when 'ips' is too low. if (ticks < MinAllowableTimerPeriod) { //BX_INFO(("activate_timer_ticks: adjusting ticks of %llu to min of %u", // ticks, MinAllowableTimerPeriod)); ticks = MinAllowableTimerPeriod; } timer[i].period = ticks; timer[i].timeToFire = (ticksTotal + Bit64u(currCountdownPeriod-currCountdown)) + ticks; timer[i].active = 1; timer[i].continuous = continuous; if (ticks < Bit64u(currCountdown)) { // This new timer needs to fire before the current countdown. // Skew the current countdown and countdown period to be smaller // by the delta. currCountdownPeriod -= (currCountdown - Bit32u(ticks)); currCountdown = Bit32u(ticks); } } void bx_pc_system_c::activate_timer(unsigned i, Bit32u useconds, bx_bool continuous) { //printf("bochsDevs::bx_pc_system_c::activate_timer(%d, %d, %d)\n", i, useconds, continuous); Bit64u ticks; // if useconds = 0, use default stored in period field // else set new period from useconds if (useconds==0) { ticks = timer[i].period; } else { // convert useconds to number of ticks ticks = (Bit64u) (double(useconds) * m_ips); // If the timer frequency is rediculously low, make it more sane. // This happens when 'ips' is too low. if (ticks < MinAllowableTimerPeriod) { //BX_INFO(("activate_timer: adjusting ticks of %llu to min of %u", // ticks, MinAllowableTimerPeriod)); ticks = MinAllowableTimerPeriod; } timer[i].period = ticks; } activate_timer_ticks(i, ticks, continuous); } void bx_pc_system_c::deactivate_timer(unsigned i) { //printf("bochsDevs::bx_pc_system_c::deactivate_timer(%d)\n", i); timer[i].active = 0; } Bit64u bx_pc_system_c::time_usec() { return (Bit64u) (((double)(Bit64s)time_ticks()) / m_ips); } void bx_pc_system_c::countdownEvent(void) { unsigned i; Bit64u minTimeToFire; bx_bool triggered[BX_MAX_TIMERS]; // Increment global ticks counter by number of ticks which have // elapsed since the last update. ticksTotal += Bit64u(currCountdownPeriod); minTimeToFire = (Bit64u) -1; for (i=0; i < numTimers; i++) { triggered[i] = 0; // Reset triggered flag. if (timer[i].active) { if (ticksTotal == timer[i].timeToFire) { // This timer is ready to fire. triggered[i] = 1; if (timer[i].continuous==0) { // If triggered timer is one-shot, deactive. timer[i].active = 0; } else { // Continuous timer, increment time-to-fire by period. timer[i].timeToFire += timer[i].period; if (timer[i].timeToFire < minTimeToFire) minTimeToFire = timer[i].timeToFire; } } else { // This timer is not ready to fire yet. if (timer[i].timeToFire < minTimeToFire) minTimeToFire = timer[i].timeToFire; } } } // Calculate next countdown period. We need to do this before calling // any of the callbacks, as they may call timer features, which need // to be advanced to the next countdown cycle. currCountdown = currCountdownPeriod = Bit32u(minTimeToFire - ticksTotal); for (i=0; i < numTimers; i++) { // Call requested timer function. It may request a different // timer period or deactivate etc. if (triggered[i]) { triggeredTimer = i; timer[i].funct(timer[i].this_ptr); triggeredTimer = 0; } } } //------------------------------------------------------------------------------ bool a20_state = true; void bx_pc_system_c::set_HRQ(bx_bool val) { printf("bochsDevs::bx_pc_system_c::set_HRQ() %d\n", val); if(val) { bx_devices.pluginDmaDevice->raise_HLDA(); } } int bx_pc_system_c::Reset(unsigned type) { printf("bochsDevs::bx_pc_system_c::Reset() %d\n", type); std::exit(-1); return 0; } bx_bool bx_pc_system_c::get_enable_a20(void) { printf("bochsDevs::bx_pc_system_c::get_enable_a20() %d\n", a20_state); return a20_state; } void bx_pc_system_c::set_enable_a20(bx_bool value) { printf("bochsDevs::bx_pc_system_c::set_enable_a20(%d) %d\n", value, a20_state); a20_state = value; } void bx_pc_system_c::clear_INTR(void) { printf("bochsDevs::bx_pc_system_c::clear_INTR()\n"); shared_ptr->interrupt_at_counter = 0; } void bx_pc_system_c::raise_INTR(void) { printf("bochsDevs::bx_pc_system_c::raise_INTR()\n"); uint32 last = shared_ptr->interrupt_at_counter; shared_ptr->interrupt_vector = bx_devices.pluginPicDevice->IAC(); uint32 v1 = shared_ptr->bochs486_pc.instr_counter + 5; uint32 v2 = shared_ptr->ao486.instr_counter + 5; shared_ptr->interrupt_at_counter = (v1 > v2)? v1 : v2; printf("interrupt: %02x\n", shared_ptr->interrupt_vector); FILE *interrupt_fp = fopen("interrupt.txt", "a"); fprintf(interrupt_fp, "irq %02x at %d (%d %d) %d\n", shared_ptr->interrupt_vector, shared_ptr->interrupt_at_counter, v1, v2, shared_ptr->interrupt_at_counter - last); fclose(interrupt_fp); } class capture_pic_stub_c : public bx_pic_stub_c { public: capture_pic_stub_c(bx_pic_stub_c *orig) { this->orig = orig; } virtual void raise_irq(unsigned irq_no) { FILE *fp = fopen("track.txt", "a"); fprintf(fp, "raise_irq %d\n", irq_no); fclose(fp); orig->raise_irq(irq_no); } virtual void lower_irq(unsigned irq_no) { FILE *fp = fopen("track.txt", "a"); fprintf(fp, "lower_irq %d\n", irq_no); fclose(fp); orig->lower_irq(irq_no); } virtual void set_mode(bx_bool ma_sl, Bit8u mode) { FILE *fp = fopen("track.txt", "a"); fprintf(fp, "set_mode %d %d\n", ma_sl, mode); fclose(fp); orig->set_mode(ma_sl, mode); } virtual Bit8u IAC(void) { Bit8u ret = orig->IAC(); FILE *fp = fopen("track.txt", "a"); fprintf(fp, "IAC %d\n", ret); fclose(fp); return ret; } private: bx_pic_stub_c *orig; }; bx_pc_system_c bx_pc_system; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ Bit64u bx_get_realtime64_usec(void) { timeval thetime; gettimeofday(&thetime,0); Bit64u mytime; mytime=(Bit64u)thetime.tv_sec*(Bit64u)1000000+(Bit64u)thetime.tv_usec; return mytime; } //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ bx_devices_c::bx_devices_c() { } bx_devices_c::~bx_devices_c() { } void bx_devices_c::mouse_motion(int delta_x, int delta_y, int delta_z, unsigned button_state, bx_bool absxy) { printf("bochsDevs::bx_devices_c::mouse_motion()\n"); // If mouse events are disabled on the GUI headerbar, don't // generate any mouse data if (!mouse_captured) return; // if a removable mouse is connected, redirect mouse data to the device if (bx_mouse[1].dev != NULL) { bx_mouse[1].enq_event(bx_mouse[1].dev, delta_x, delta_y, delta_z, button_state, absxy); return; } // if a mouse is connected, direct mouse data to the device if (bx_mouse[0].dev != NULL) { bx_mouse[0].enq_event(bx_mouse[0].dev, delta_x, delta_y, delta_z, button_state, absxy); } } bx_bool bx_devices_c::optional_key_enq(Bit8u *scan_code) { printf("bochsDevs::bx_devices_c::optional_key_enq()\n"); if (bx_keyboard.dev != NULL) { return bx_keyboard.enq_event(bx_keyboard.dev, scan_code); } return 0; } void bx_devices_c::mouse_enabled_changed(bx_bool enabled) { printf("bochsDevs::bx_devices_c::mouse_enabled_changed()\n"); mouse_captured = enabled; if ((bx_mouse[1].dev != NULL) && (bx_mouse[1].enabled_changed != NULL)) { bx_mouse[1].enabled_changed(bx_mouse[1].dev, enabled); return; } if ((bx_mouse[0].dev != NULL) && (bx_mouse[0].enabled_changed != NULL)) { bx_mouse[0].enabled_changed(bx_mouse[0].dev, enabled); } } void bx_devices_c::register_default_mouse(void *dev, bx_mouse_enq_t mouse_enq, bx_mouse_enabled_changed_t mouse_enabled_changed) { printf("bochsDevs::bx_devices_c::register_default_mouse()\n"); if (bx_mouse[0].dev == NULL) { bx_mouse[0].dev = dev; bx_mouse[0].enq_event = mouse_enq; bx_mouse[0].enabled_changed = mouse_enabled_changed; } } bx_devices_c bx_devices; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ const char *hdimage_mode_names[] = { "flat", "concat", "external", "dll", "sparse", "vmware3", "vmware4", "undoable", "growing", "volatile", "vvfat", "vpc", NULL }; void bx_stop_simulation() { printf("bochsDevs::bx_stop_simulation()\n"); } class BX_CPU_C : public logfunctions { }; BX_CPU_C bx_cpu; bx_bool bx_user_quit; //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ //------------------------------------------------------------------------------ void register_plugin(const char *libname, const char *initname) { void *handle; handle = dlopen(libname, RTLD_NOW | RTLD_GLOBAL); if(handle == NULL) { char *error = dlerror(); printf("dlopen() error: %s\n", error); exit(-1); } plugin_init_t plugin_init = (plugin_init_t)dlsym(handle, initname); if(plugin_init == NULL) { char *error = dlerror(); printf("dlsym() error: %s\n", error); dlclose(handle); exit(-2); } plugin_init(NULL, PLUGTYPE_CORE, 0,NULL); //dlclose(handle); } int main(int argc, char **argv) { //map shared memory int fd = open("./../sim/sim_pc/shared_mem.dat", O_RDWR, S_IRUSR | S_IWUSR); if(fd == -1) { perror("open() failed for shared_mem.dat"); return -1; } shared_ptr = (shared_mem_t *)mmap(NULL, sizeof(shared_mem_t), PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0); if(shared_ptr == MAP_FAILED) { perror("mmap() failed"); close(fd); return -2; } //wait for ack shared_ptr->bochsDevs_starting = STEP_REQ; printf("Waiting for startup ack..."); fflush(stdout); while(shared_ptr->bochsDevs_starting != STEP_ACK) { usleep(100000); } printf("done.\n"); //-------------------------------------------------------------------------- printf("bochsDevs\n"); FILE *debug_fp = fopen("output.txt", "w"); pluginRegisterIRQ = builtinRegisterIRQ; pluginRegisterIOReadHandler = builtinRegisterIOReadHandler; pluginRegisterIOWriteHandler = builtinRegisterIOWriteHandler; pluginRegisterDefaultIOReadHandler = builtinRegisterDefaultIOReadHandler; pluginRegisterDefaultIOWriteHandler = builtinRegisterDefaultIOWriteHandler; SIM = new bochsDevs_sim(); bx_virt_timer.init(); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_unmapped.so.0.0.0", "libunmapped_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_biosdev.so.0.0.0", "libbiosdev_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_cmos.so.0.0.0", "libcmos_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_dma.so.0.0.0", "libdma_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_x.so.0.0.0", "libx_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_floppy.so.0.0.0", "libfloppy_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_hdimage.so.0.0.0", "libhdimage_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_harddrv.so.0.0.0", "libharddrv_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_iodebug.so.0.0.0", "libiodebug_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_keyboard.so.0.0.0", "libkeyboard_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_pic.so.0.0.0", "libpic_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_pit.so.0.0.0", "libpit_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_speaker.so.0.0.0", "libspeaker_LTX_plugin_init"); register_plugin("/opt/bochs-2.6.2/lib/bochs/plugins/libbx_vga.so.0.0.0", "libvga_LTX_plugin_init"); // misc. CMOS Bit64u memory_in_bytes = sizeof(shared_ptr->mem.bytes); Bit64u BASE_MEMORY_IN_K = 640; Bit64u memory_in_k = memory_in_bytes / 1024; Bit64u extended_memory_in_k = memory_in_k > 1024 ? (memory_in_k - 1024) : 0; if (extended_memory_in_k > 0xfc00) extended_memory_in_k = 0xfc00; DEV_cmos_set_reg(0x15, (Bit8u) BASE_MEMORY_IN_K); DEV_cmos_set_reg(0x16, (Bit8u) (BASE_MEMORY_IN_K >> 8)); DEV_cmos_set_reg(0x17, (Bit8u) (extended_memory_in_k & 0xff)); DEV_cmos_set_reg(0x18, (Bit8u) ((extended_memory_in_k >> 8) & 0xff)); DEV_cmos_set_reg(0x30, (Bit8u) (extended_memory_in_k & 0xff)); DEV_cmos_set_reg(0x31, (Bit8u) ((extended_memory_in_k >> 8) & 0xff)); Bit64u extended_memory_in_64k = memory_in_k > 16384 ? (memory_in_k - 16384) / 64 : 0; // Limit to 3 GB - 16 MB. PCI Memory Address Space starts at 3 GB. if (extended_memory_in_64k > 0xbf00) extended_memory_in_64k = 0xbf00; DEV_cmos_set_reg(0x34, (Bit8u) (extended_memory_in_64k & 0xff)); DEV_cmos_set_reg(0x35, (Bit8u) ((extended_memory_in_64k >> 8) & 0xff)); Bit64u memory_above_4gb = (memory_in_bytes > BX_CONST64(0x100000000)) ? (memory_in_bytes - BX_CONST64(0x100000000)) : 0; if (memory_above_4gb) { DEV_cmos_set_reg(0x5b, (Bit8u)(memory_above_4gb >> 16)); DEV_cmos_set_reg(0x5c, (Bit8u)(memory_above_4gb >> 24)); DEV_cmos_set_reg(0x5d, memory_above_4gb >> 32); } /* now perform checksum of CMOS memory */ DEV_cmos_checksum(); //replace pic with capture capture_pic_stub_c *capture = new capture_pic_stub_c(bx_devices.pluginPicDevice); bx_devices.pluginPicDevice = capture; uint32 last_instr_counter = 0; while(true) { //---------------------------------------------------------------------- stop if(shared_ptr->bochsDevs_stop == STEP_REQ) { shared_ptr->bochsDevs_stop = STEP_ACK; while(shared_ptr->bochsDevs_stop != STEP_IDLE) { usleep(500); } } //---------------------------------------------------------------------- irq static step_t last_pit_irq_step = STEP_IDLE; if(last_pit_irq_step == STEP_IDLE && shared_ptr->pit_irq_step == STEP_REQ) { bx_devices.pluginPicDevice->raise_irq(0); last_pit_irq_step = STEP_REQ; } else if(last_pit_irq_step == STEP_REQ && shared_ptr->pit_irq_step == STEP_IDLE) { bx_devices.pluginPicDevice->lower_irq(0); last_pit_irq_step = STEP_IDLE; } static step_t last_rtc_irq_step = STEP_IDLE; if(last_rtc_irq_step == STEP_IDLE && shared_ptr->rtc_irq_step == STEP_REQ) { bx_devices.pluginPicDevice->raise_irq(8); last_rtc_irq_step = STEP_REQ; } else if(last_rtc_irq_step == STEP_REQ && shared_ptr->rtc_irq_step == STEP_IDLE) { bx_devices.pluginPicDevice->lower_irq(8); last_rtc_irq_step = STEP_IDLE; } static step_t last_floppy_irq_step = STEP_IDLE; if(last_floppy_irq_step == STEP_IDLE && shared_ptr->floppy_irq_step == STEP_REQ) { bx_devices.pluginPicDevice->raise_irq(6); last_floppy_irq_step = STEP_REQ; } else if(last_floppy_irq_step == STEP_REQ && shared_ptr->floppy_irq_step == STEP_IDLE) { bx_devices.pluginPicDevice->lower_irq(6); last_floppy_irq_step = STEP_IDLE; } static step_t last_keyboard_irq_step = STEP_IDLE; if(last_keyboard_irq_step == STEP_IDLE && shared_ptr->keyboard_irq_step == STEP_REQ) { bx_devices.pluginPicDevice->raise_irq(1); last_keyboard_irq_step = STEP_REQ; } else if(last_keyboard_irq_step == STEP_REQ && shared_ptr->keyboard_irq_step == STEP_IDLE) { bx_devices.pluginPicDevice->lower_irq(1); last_keyboard_irq_step = STEP_IDLE; } static step_t last_mouse_irq_step = STEP_IDLE; if(last_mouse_irq_step == STEP_IDLE && shared_ptr->mouse_irq_step == STEP_REQ) { bx_devices.pluginPicDevice->raise_irq(12); last_mouse_irq_step = STEP_REQ; } else if(last_mouse_irq_step == STEP_REQ && shared_ptr->mouse_irq_step == STEP_IDLE) { bx_devices.pluginPicDevice->lower_irq(12); last_mouse_irq_step = STEP_IDLE; } //---------------------------------------------------------------------- service io if(shared_ptr->combined.io_step == STEP_REQ) { uint32 address = shared_ptr->combined.io_address & 0xFFFF; uint32 byteena = shared_ptr->combined.io_byteenable; uint32 value = shared_ptr->combined.io_data; uint32 shifted = 0; if(address == 0x01F0 || address == 0x01F4 || (address == 0x03F4 && byteena == 0x4) || address == 0x0040 || (address == 0x0060 && byteena == 0x2) || (address == 0x0070 && (byteena == 0x1 || byteena == 0x02)) || (address == 0x03F4 && ((byteena >> 2) & 1) == 0) || address == 0x03F0 || address == 0x0000 || address == 0x0004 || address == 0x0008 || address == 0x000C || address == 0x0080 || address == 0x0084 || address == 0x0088 || address == 0x008C || address == 0x00C0 || address == 0x00C4 || address == 0x00C8 || address == 0x00CC || address == 0x00D0 || address == 0x00D4 || address == 0x00D8 || address == 0x00DC || address == 0x03B0 || address == 0x03B4 || address == 0x03B8 || address == 0x03BC || address == 0x03C0 || address == 0x03C4 || address == 0x03C8 || address == 0x03CC || address == 0x03D0 || address == 0x03D4 || address == 0x03D8 || address == 0x03DC || (address == 0x0060 && ((byteena >> 1) & 1) == 0) || address == 0x0064 || address == 0x0090 || address == 0x0094 || address == 0x0098 || address == 0x009C || (address == 0x0020 && ((byteena >> 2) & 3) == 0) || (address == 0x00A0 && ((byteena >> 2) & 3) == 0) || address == 0x8888 || address == 0x888C) { // } else { if(shared_ptr->combined.io_is_write) { FILE *fp = fopen("track.txt", "a"); fprintf(fp, "io wr %04x %x %08x\n", address, byteena, value); fclose(fp); } for(uint32 i=0; i<4; i++) { if(byteena & 1) break; shifted++; address++; byteena >>= 1; value >>= 8; } uint32 length = 0; for(uint32 i=0; i<4; i++) { if(byteena & 1) length++; byteena >>= 1; } if(shared_ptr->combined.io_is_write) { ioWriteHandler_t handler = io_write_handlers[address]; uint8 mask = io_write_mask[address]; void *this_ptr = io_write_this[address]; if(handler == NULL) { handler = io_write_handlers[65536]; mask = io_write_mask[65536]; } if(mask & length) { ((bx_write_handler_t)handler)(this_ptr, address, value, length); } else { printf("bochsDevs::io write mismatch: mask=%d, length=%d, address=%04x\n", mask, length, address); } if(address == 0x92) { a20_state = (value & 2)? 1 : 0; } /* if(address == 0x8888) { fprintf(debug_fp, "%c", value & 0xFF); fflush(debug_fp); } */ } else { ioReadHandler_t handler = io_read_handlers[address]; uint8 mask = io_read_mask[address]; void *this_ptr = io_read_this[address]; if(handler == NULL) { handler = io_read_handlers[65536]; mask = io_read_mask[65536]; } uint32 ret = 0xFFFFFF; if(mask & length) { ret = ((bx_read_handler_t)handler)(this_ptr, address, length); } else { printf("bochsDevs::io read mismatch: mask=%d, length=%d, address=%04x\n", mask, length, address); ret = (length == 1)? 0xFF : (length == 2)? 0xFFFF : 0xFFFFFFFF; } if(address == 0x92) { ret = (a20_state)? 0x02 : 0x00; } ret &= (length == 1)? 0xFF : (length == 2)? 0xFFFF : (length == 3)? 0xFFFFFF : 0xFFFFFFFF; shared_ptr->combined.io_data = ret << (8*shifted); FILE *fp = fopen("track.txt", "a"); fprintf(fp, "io rd %04x %x %08x\n", shared_ptr->combined.io_address & 0xFFFF, shared_ptr->combined.io_byteenable, shared_ptr->combined.io_data); fclose(fp); } shared_ptr->combined.io_step = STEP_ACK; } } //---------------------------------------------------------------------- service vga memory /* if(shared_ptr->combined.mem_step == STEP_REQ) { uint32 address = shared_ptr->combined.mem_address; uint32 byteena = shared_ptr->combined.mem_byteenable; uint32 value = shared_ptr->combined.mem_data; uint32 shifted = 0; for(uint32 i=0; i<4; i++) { if(byteena & 1) break; shifted++; address++; byteena >>= 1; value >>= 8; } uint32 length = 0; for(uint32 i=0; i<4; i++) { if(byteena & 1) length++; byteena >>= 1; } if(address >= 0xA0000 && address < 0xC0000) { if(shared_ptr->combined.mem_is_write) { (vga_write_memory)(address, length, &value, vga_param); FILE *fp = fopen("track.txt", "a"); fprintf(fp, "vga wr %08x %x %08x\n", address, byteena, value); fclose(fp); } else { uint32 ret = 0xFFFFFF; (vga_read_memory)(address, length, &ret, vga_param); ret &= (length == 1)? 0xFF : (length == 2)? 0xFFFF : (length == 3)? 0xFFFFFF : 0xFFFFFFFF; shared_ptr->combined.mem_data = ret << (8*shifted); FILE *fp = fopen("track.txt", "a"); fprintf(fp, "vga rd %08x %x %08x\n", shared_ptr->combined.mem_address, shared_ptr->combined.mem_byteenable, shared_ptr->combined.mem_data); fclose(fp); } shared_ptr->combined.mem_step = STEP_ACK; } } */ //---------------------------------------------------------------------- bx_gui->handle_events(); //bx_pc_system.tickn(1); //usleep(100); uint32 snapshot = shared_ptr->bochs486_pc.instr_counter; if(snapshot > last_instr_counter) { bx_pc_system.tickn(snapshot - last_instr_counter); //500 -- hang (too fast interrupt), 100 -- ok last_instr_counter = snapshot; } usleep(10); } return 0; }