/* Copyright 1999, Be Incorporated. All Rights Reserved. This file may be used under the terms of the Be Sample Code License. Other authors: Mark Watson; Rudolf Cornelissen 3/2002-1/2016. */ /* standard kernel driver stuff */ #include #include #include #include #include #include #include #include // for strtoXX #include "AGP.h" /* this is for the standardized portion of the driver API */ /* currently only one operation is defined: B_GET_ACCELERANT_SIGNATURE */ #include /* this is for sprintf() */ #include /* this is for string compares */ #include /* The private interface between the accelerant and the kernel driver. */ #include "DriverInterface.h" #include "macros.h" #define get_pci(o, s) (*pci_bus->read_pci_config)(pcii->bus, pcii->device, pcii->function, (o), (s)) #define set_pci(o, s, v) (*pci_bus->write_pci_config)(pcii->bus, pcii->device, pcii->function, (o), (s), (v)) #define MAX_DEVICES 8 #define DEVICE_FORMAT "%04x_%04x_%02x%02x%02x" // apsed /* Tell the kernel what revision of the driver API we support */ int32 api_version = B_CUR_DRIVER_API_VERSION; // apsed, was 2, is 2 in R5 /* these structures are private to the kernel driver */ typedef struct device_info device_info; typedef struct { timer te; /* timer entry for add_timer() */ device_info *di; /* pointer to the owning device */ bigtime_t when_target; /* when we're supposed to wake up */ } timer_info; struct device_info { uint32 is_open; /* a count of how many times the devices has been opened */ area_id shared_area; /* the area shared between the driver and all of the accelerants */ shared_info *si; /* a pointer to the shared area, for convenience */ vuint32 *regs; /* kernel's pointer to memory mapped registers */ pci_info pcii; /* a convenience copy of the pci info for this device */ char name[B_OS_NAME_LENGTH]; /* where we keep the name of the device for publishing and comparing */ }; typedef struct { uint32 count; /* number of devices actually found */ benaphore kernel; /* for serializing opens/closes */ char *device_names[MAX_DEVICES+1]; /* device name pointer storage */ device_info di[MAX_DEVICES]; /* device specific stuff */ } DeviceData; /* prototypes for our private functions */ static status_t open_hook (const char* name, uint32 flags, void** cookie); static status_t close_hook (void* dev); static status_t free_hook (void* dev); static status_t read_hook (void* dev, off_t pos, void* buf, size_t* len); static status_t write_hook (void* dev, off_t pos, const void* buf, size_t* len); static status_t control_hook (void* dev, uint32 msg, void *buf, size_t len); static status_t map_device(device_info *di); static void unmap_device(device_info *di); static void probe_devices(void); static int32 eng_interrupt(void *data); static DeviceData *pd; static isa_module_info *isa_bus = NULL; static pci_module_info *pci_bus = NULL; static agp_gart_module_info *agp_bus = NULL; static device_hooks graphics_device_hooks = { open_hook, close_hook, free_hook, control_hook, read_hook, write_hook, NULL, NULL, NULL, NULL }; #define VENDOR_ID_VIA 0x1106 /* Via */ static uint16 via_device_list[] = { 0x3022, /* CLE266 Unichrome Pro (CLE3022) */ 0x3108, /* K8M800 Unichrome Pro (unknown chiptype) */ 0x3122, /* CLE266 Unichrome Pro (CLE3122) */ 0x3205, /* KM400 Unichrome (VT3205) */ // 0x3344, /* P4M800 Pro (VT3344) */ 0x7205, /* KM400 Unichrome (VT7205) */ 0 }; static struct { uint16 vendor; uint16 *devices; } SupportedDevices[] = { {VENDOR_ID_VIA, via_device_list}, {0x0000, NULL} }; static settings current_settings = { // see comments in skel.settings // for driver DRIVER_PREFIX ".accelerant", false, // dumprom // for accelerant 0x00000000, // logmask 0, // memory true, // usebios true, // hardcursor false, // switchhead false, // force_pci false, // unhide_fw true, // pgm_panel }; static void dumprom (void *rom, uint32 size) { int fd; uint32 cnt; fd = open (kUserDirectory "/" DRIVER_PREFIX ".rom", O_WRONLY | O_CREAT, 0666); if (fd < 0) return; /* apparantly max. 32kb may be written at once; * the ROM size is a multiple of that anyway. */ for (cnt = 0; (cnt < size); cnt += 32768) write (fd, ((void *)(((uint8 *)rom) + cnt)), 32768); close (fd); } /* return 1 if vblank interrupt has occured */ static int caused_vbi(vuint32 * regs) { // return (ENG_REG32(RG32_CRTC_INTS) & 0x00000001); return 0; } /* clear the vblank interrupt */ static void clear_vbi(vuint32 * regs) { // ENG_REG32(RG32_CRTC_INTS) = 0x00000001; } static void enable_vbi(vuint32 * regs) { /* clear the vblank interrupt */ // ENG_REG32(RG32_CRTC_INTS) = 0x00000001; /* enable nVidia interrupt source vblank */ // ENG_REG32(RG32_CRTC_INTE) |= 0x00000001; /* enable nVidia interrupt system hardware (b0-1) */ // ENG_REG32(RG32_MAIN_INTE) = 0x00000001; } static void disable_vbi(vuint32 * regs) { /* disable nVidia interrupt source vblank */ // ENG_REG32(RG32_CRTC_INTE) &= 0xfffffffe; /* clear the vblank interrupt */ // ENG_REG32(RG32_CRTC_INTS) = 0x00000001; /* disable nVidia interrupt system hardware (b0-1) */ // ENG_REG32(RG32_MAIN_INTE) = 0x00000000; } /* init_hardware() - Returns B_OK if one is found, otherwise returns B_ERROR so the driver will be unloaded. */ status_t init_hardware(void) { long pci_index = 0; pci_info pcii; bool found_one = false; /* choke if we can't find the PCI bus */ if (get_module(B_PCI_MODULE_NAME, (module_info **)&pci_bus) != B_OK) return B_ERROR; /* choke if we can't find the ISA bus */ if (get_module(B_ISA_MODULE_NAME, (module_info **)&isa_bus) != B_OK) { put_module(B_PCI_MODULE_NAME); return B_ERROR; } /* while there are more pci devices */ while ((*pci_bus->get_nth_pci_info)(pci_index, &pcii) == B_NO_ERROR) { int vendor = 0; /* if we match a supported vendor */ while (SupportedDevices[vendor].vendor) { if (SupportedDevices[vendor].vendor == pcii.vendor_id) { uint16 *devices = SupportedDevices[vendor].devices; /* while there are more supported devices */ while (*devices) { /* if we match a supported device */ if (*devices == pcii.device_id ) { found_one = true; goto done; } /* next supported device */ devices++; } } vendor++; } /* next pci_info struct, please */ pci_index++; } done: /* put away the module manager */ put_module(B_PCI_MODULE_NAME); return (found_one ? B_OK : B_ERROR); } status_t init_driver(void) { void *settings_handle; // get driver/accelerant settings, apsed settings_handle = load_driver_settings (DRIVER_PREFIX ".settings"); if (settings_handle != NULL) { const char *item; char *end; uint32 value; // for driver item = get_driver_parameter (settings_handle, "accelerant", "", ""); if ((strlen (item) > 0) && (strlen (item) < sizeof (current_settings.accelerant) - 1)) { strcpy (current_settings.accelerant, item); } current_settings.dumprom = get_driver_boolean_parameter (settings_handle, "dumprom", false, false); // for accelerant item = get_driver_parameter (settings_handle, "logmask", "0x00000000", "0x00000000"); value = strtoul (item, &end, 0); if (*end == '\0') current_settings.logmask = value; item = get_driver_parameter (settings_handle, "memory", "0", "0"); value = strtoul (item, &end, 0); if (*end == '\0') current_settings.memory = value; current_settings.hardcursor = get_driver_boolean_parameter (settings_handle, "hardcursor", false, false); current_settings.usebios = get_driver_boolean_parameter (settings_handle, "usebios", false, false); current_settings.switchhead = get_driver_boolean_parameter (settings_handle, "switchhead", false, false); current_settings.force_pci = get_driver_boolean_parameter (settings_handle, "force_pci", false, false); current_settings.unhide_fw = get_driver_boolean_parameter (settings_handle, "unhide_fw", false, false); current_settings.pgm_panel = get_driver_boolean_parameter (settings_handle, "pgm_panel", false, false); unload_driver_settings (settings_handle); } /* get a handle for the pci bus */ if (get_module(B_PCI_MODULE_NAME, (module_info **)&pci_bus) != B_OK) return B_ERROR; /* get a handle for the isa bus */ if (get_module(B_ISA_MODULE_NAME, (module_info **)&isa_bus) != B_OK) { put_module(B_PCI_MODULE_NAME); return B_ERROR; } /* get a handle for the agp bus if it exists */ get_module(B_AGP_GART_MODULE_NAME, (module_info **)&agp_bus); /* driver private data */ pd = (DeviceData *)calloc(1, sizeof(DeviceData)); if (!pd) { if (agp_bus) put_module(B_AGP_GART_MODULE_NAME); put_module(B_ISA_MODULE_NAME); put_module(B_PCI_MODULE_NAME); return B_ERROR; } /* initialize the benaphore */ INIT_BEN(pd->kernel); /* find all of our supported devices */ probe_devices(); return B_OK; } const char ** publish_devices(void) { /* return the list of supported devices */ return (const char **)pd->device_names; } device_hooks * find_device(const char *name) { int index = 0; while (pd->device_names[index]) { if (strcmp(name, pd->device_names[index]) == 0) return &graphics_device_hooks; index++; } return NULL; } void uninit_driver(void) { /* free the driver data */ DELETE_BEN(pd->kernel); free(pd); pd = NULL; /* put the pci module away */ put_module(B_PCI_MODULE_NAME); put_module(B_ISA_MODULE_NAME); /* put the agp module away if it's there */ if (agp_bus) put_module(B_AGP_GART_MODULE_NAME); } static status_t map_device(device_info *di) { char buffer[B_OS_NAME_LENGTH]; /*memory for device name*/ shared_info *si = di->si; uint32 tmpUlong; pci_info *pcii = &(di->pcii); system_info sysinfo; /*storage for the physical to virtual table (used for dma buffer)*/ // physical_entry physical_memory[2]; // #define G400_DMA_BUFFER_SIZE 1024*1024 /* variables for making copy of ROM */ uint8* rom_temp; area_id rom_area; /* Nvidia cards have registers in [0] and framebuffer in [1] */ int registers = 1; int frame_buffer = 0; // int pseudo_dma = 2; /* enable memory mapped IO, disable VGA I/O - this is defined in the PCI standard */ tmpUlong = get_pci(PCI_command, 2); /* enable PCI access */ tmpUlong |= PCI_command_memory; /* enable busmastering */ tmpUlong |= PCI_command_master; /* disable ISA I/O access */ tmpUlong &= ~PCI_command_io; set_pci(PCI_command, 2, tmpUlong); /*work out which version of BeOS is running*/ get_system_info(&sysinfo); if (0)//sysinfo.kernel_build_date[0]=='J')/*FIXME - better ID version*/ { si->use_clone_bugfix = 1; } else { si->use_clone_bugfix = 0; } /* work out a name for the register mapping */ sprintf(buffer, DEVICE_FORMAT " regs", di->pcii.vendor_id, di->pcii.device_id, di->pcii.bus, di->pcii.device, di->pcii.function); /* get a virtual memory address for the registers*/ si->regs_area = map_physical_memory( buffer, /* WARNING: Nvidia needs to map regs as viewed from PCI space! */ di->pcii.u.h0.base_registers_pci[registers], di->pcii.u.h0.base_register_sizes[registers], B_ANY_KERNEL_ADDRESS, B_CLONEABLE_AREA | (si->use_clone_bugfix ? B_READ_AREA|B_WRITE_AREA : 0), (void **)&(di->regs)); si->clone_bugfix_regs = (uint32 *) di->regs; /* if mapping registers to vmem failed then pass on error */ if (si->regs_area < 0) return si->regs_area; /* work out a name for the ROM mapping*/ sprintf(buffer, DEVICE_FORMAT " rom", di->pcii.vendor_id, di->pcii.device_id, di->pcii.bus, di->pcii.device, di->pcii.function); /* disable ROM shadowing, we want the guaranteed exact contents of the chip */ /* warning: * don't touch: (confirmed) NV04, NV05, NV05-M64, NV11 all shutoff otherwise. * NV18, NV28 and NV34 keep working. * confirmed NV28 and NV34 to use upper part of shadowed ROM for scratch purposes, * however the actual ROM content (so the used part) is intact (confirmed). */ //set_pci(ENCFG_ROMSHADOW, 4, 0); /* get ROM memory mapped base adress - this is defined in the PCI standard */ tmpUlong = get_pci(PCI_rom_base, 4); if (tmpUlong) { /* ROM was assigned an adress, so enable ROM decoding - see PCI standard */ tmpUlong |= 0x00000001; set_pci(PCI_rom_base, 4, tmpUlong); rom_area = map_physical_memory( buffer, di->pcii.u.h0.rom_base_pci, di->pcii.u.h0.rom_size, B_ANY_KERNEL_ADDRESS, B_READ_AREA, (void **)&(rom_temp) ); /* check if we got the BIOS signature (might fail on laptops..) */ if (rom_temp[0]!=0x55 || rom_temp[1]!=0xaa) { /* apparantly no ROM is mapped here */ delete_area(rom_area); rom_area = -1; /* force using ISA legacy map as fall-back */ tmpUlong = 0x00000000; } } if (!tmpUlong) { /* ROM was not assigned an adress, fetch it from ISA legacy memory map! */ rom_area = map_physical_memory( buffer, 0x000c0000, 65536, B_ANY_KERNEL_ADDRESS, B_READ_AREA, (void **)&(rom_temp) ); } /* if mapping ROM to vmem failed then clean up and pass on error */ if (rom_area < 0) { delete_area(si->regs_area); si->regs_area = -1; return rom_area; } /* dump ROM to file if selected in skel.settings * (ROM always fits in 64Kb: checked TNT1 - FX5950) */ if (current_settings.dumprom) dumprom (rom_temp, 65536); /* make a copy of ROM for future reference */ memcpy (si->rom_mirror, rom_temp, 65536); /* disable ROM decoding - this is defined in the PCI standard, and delete the area */ tmpUlong = get_pci(PCI_rom_base, 4); tmpUlong &= 0xfffffffe; set_pci(PCI_rom_base, 4, tmpUlong); delete_area(rom_area); /* work out a name for the framebuffer mapping*/ sprintf(buffer, DEVICE_FORMAT " framebuffer", di->pcii.vendor_id, di->pcii.device_id, di->pcii.bus, di->pcii.device, di->pcii.function); /* map the framebuffer into vmem, using Write Combining*/ si->fb_area = map_physical_memory( buffer, /* WARNING: Nvidia needs to map framebuffer as viewed from PCI space! */ di->pcii.u.h0.base_registers_pci[frame_buffer], di->pcii.u.h0.base_register_sizes[frame_buffer], B_ANY_KERNEL_BLOCK_ADDRESS | B_MTR_WC, B_READ_AREA | B_WRITE_AREA | B_CLONEABLE_AREA, &(si->framebuffer)); /*if failed with write combining try again without*/ if (si->fb_area < 0) { si->fb_area = map_physical_memory( buffer, /* WARNING: Nvidia needs to map framebuffer as viewed from PCI space! */ di->pcii.u.h0.base_registers_pci[frame_buffer], di->pcii.u.h0.base_register_sizes[frame_buffer], B_ANY_KERNEL_BLOCK_ADDRESS, B_READ_AREA | B_WRITE_AREA | B_CLONEABLE_AREA, &(si->framebuffer)); } /* if there was an error, delete our other areas and pass on error*/ if (si->fb_area < 0) { delete_area(si->regs_area); si->regs_area = -1; return si->fb_area; } //fixme: retest for card coldstart and PCI/virt_mem mapping!! /* remember the DMA address of the frame buffer for BDirectWindow?? purposes */ si->framebuffer_pci = (void *) di->pcii.u.h0.base_registers_pci[frame_buffer]; // remember settings for use here and in accelerant si->settings = current_settings; /* in any case, return the result */ return si->fb_area; } static void unmap_device(device_info *di) { shared_info *si = di->si; uint32 tmpUlong; pci_info *pcii = &(di->pcii); /* disable memory mapped IO */ tmpUlong = get_pci(PCI_command, 4); tmpUlong &= 0xfffffffc; set_pci(PCI_command, 4, tmpUlong); /* delete the areas */ if (si->regs_area >= 0) delete_area(si->regs_area); if (si->fb_area >= 0) delete_area(si->fb_area); si->regs_area = si->fb_area = -1; si->framebuffer = NULL; di->regs = NULL; } static void probe_devices(void) { uint32 pci_index = 0; uint32 count = 0; device_info *di = pd->di; /* while there are more pci devices */ while ((count < MAX_DEVICES) && ((*pci_bus->get_nth_pci_info)(pci_index, &(di->pcii)) == B_NO_ERROR)) { int vendor = 0; /* if we match a supported vendor */ while (SupportedDevices[vendor].vendor) { if (SupportedDevices[vendor].vendor == di->pcii.vendor_id) { uint16 *devices = SupportedDevices[vendor].devices; /* while there are more supported devices */ while (*devices) { /* if we match a supported device */ if (*devices == di->pcii.device_id ) { /* publish the device name */ sprintf(di->name, "graphics/" DEVICE_FORMAT, di->pcii.vendor_id, di->pcii.device_id, di->pcii.bus, di->pcii.device, di->pcii.function); /* remember the name */ pd->device_names[count] = di->name; /* mark the driver as available for R/W open */ di->is_open = 0; /* mark areas as not yet created */ di->shared_area = -1; /* mark pointer to shared data as invalid */ di->si = NULL; /* inc pointer to device info */ di++; /* inc count */ count++; /* break out of these while loops */ goto next_device; } /* next supported device */ devices++; } } vendor++; } next_device: /* next pci_info struct, please */ pci_index++; } /* propagate count */ pd->count = count; /* terminate list of device names with a null pointer */ pd->device_names[pd->count] = NULL; } static uint32 thread_interrupt_work(int32 *flags, vuint32 *regs, shared_info *si) { uint32 handled = B_HANDLED_INTERRUPT; /* release the vblank semaphore */ if (si->vblank >= 0) { int32 blocked; if ((get_sem_count(si->vblank, &blocked) == B_OK) && (blocked < 0)) { release_sem_etc(si->vblank, -blocked, B_DO_NOT_RESCHEDULE); handled = B_INVOKE_SCHEDULER; } } return handled; } static int32 eng_interrupt(void *data) { int32 handled = B_UNHANDLED_INTERRUPT; device_info *di = (device_info *)data; shared_info *si = di->si; int32 *flags = &(si->flags); vuint32 *regs; /* is someone already handling an interrupt for this device? */ if (atomic_or(flags, SKD_HANDLER_INSTALLED) & SKD_HANDLER_INSTALLED) { goto exit0; } /* get regs */ regs = di->regs; /* was it a VBI? */ if (caused_vbi(regs)) { /*clear the interrupt*/ clear_vbi(regs); /*release the semaphore*/ handled = thread_interrupt_work(flags, regs, si); } /* note that we're not in the handler any more */ atomic_and(flags, ~SKD_HANDLER_INSTALLED); exit0: return handled; } static status_t open_hook (const char* name, uint32 flags, void** cookie) { int32 index = 0; device_info *di; shared_info *si; thread_id thid; thread_info thinfo; status_t result = B_OK; vuint32 *regs; char shared_name[B_OS_NAME_LENGTH]; /* find the device name in the list of devices */ /* we're never passed a name we didn't publish */ while (pd->device_names[index] && (strcmp(name, pd->device_names[index]) != 0)) index++; /* for convienience */ di = &(pd->di[index]); /* make sure no one else has write access to the common data */ AQUIRE_BEN(pd->kernel); /* if it's already open for writing */ if (di->is_open) { /* mark it open another time */ goto mark_as_open; } /* create the shared area */ sprintf(shared_name, DEVICE_FORMAT " shared", di->pcii.vendor_id, di->pcii.device_id, di->pcii.bus, di->pcii.device, di->pcii.function); /* create this area with NO user-space read or write permissions, to prevent accidental dammage */ di->shared_area = create_area(shared_name, (void **)&(di->si), B_ANY_KERNEL_ADDRESS, ((sizeof(shared_info) + (B_PAGE_SIZE - 1)) & ~(B_PAGE_SIZE - 1)), B_FULL_LOCK, B_KERNEL_READ_AREA | B_KERNEL_WRITE_AREA | B_CLONEABLE_AREA); if (di->shared_area < 0) { /* return the error */ result = di->shared_area; goto done; } /* save a few dereferences */ si = di->si; /* save the vendor and device IDs */ si->vendor_id = di->pcii.vendor_id; si->device_id = di->pcii.device_id; si->revision = di->pcii.revision; si->bus = di->pcii.bus; si->device = di->pcii.device; si->function = di->pcii.function; /* device at bus #0, device #0, function #0 holds byte value at byte-index 0xf6 */ si->ps.chip_rev = ((*pci_bus->read_pci_config)(0, 0, 0, 0xf6, 1)); /* map the device */ result = map_device(di); if (result < 0) goto free_shared; result = B_OK; /* create a semaphore for vertical blank management */ si->vblank = create_sem(0, di->name); if (si->vblank < 0) { result = si->vblank; goto unmap; } /* change the owner of the semaphores to the opener's team */ /* this is required because apps can't aquire kernel semaphores */ thid = find_thread(NULL); get_thread_info(thid, &thinfo); set_sem_owner(si->vblank, thinfo.team); /* assign local regs pointer for SAMPLExx() macros */ regs = di->regs; /* disable and clear any pending interrupts */ disable_vbi(regs); /* If there is a valid interrupt line assigned then set up interrupts */ if ((di->pcii.u.h0.interrupt_pin == 0x00) || (di->pcii.u.h0.interrupt_line == 0xff) || /* no IRQ assigned */ (di->pcii.u.h0.interrupt_line <= 0x02)) /* system IRQ assigned */ { /* we are aborting! */ /* Note: the R4 graphics driver kit lacks this statement!! */ result = B_ERROR; /* interrupt does not exist so exit without installing our handler */ goto delete_the_sem; } else { /* otherwise install our interrupt handler */ result = install_io_interrupt_handler(di->pcii.u.h0.interrupt_line, eng_interrupt, (void *)di, 0); /* bail if we couldn't install the handler */ if (result != B_OK) goto delete_the_sem; } mark_as_open: /* mark the device open */ di->is_open++; /* send the cookie to the opener */ *cookie = di; goto done; delete_the_sem: delete_sem(si->vblank); unmap: unmap_device(di); free_shared: /* clean up our shared area */ delete_area(di->shared_area); di->shared_area = -1; di->si = NULL; done: /* end of critical section */ RELEASE_BEN(pd->kernel); /* all done, return the status */ return result; } /* ---------- read_hook - does nothing, gracefully ----- */ static status_t read_hook (void* dev, off_t pos, void* buf, size_t* len) { *len = 0; return B_NOT_ALLOWED; } /* ---------- write_hook - does nothing, gracefully ----- */ static status_t write_hook (void* dev, off_t pos, const void* buf, size_t* len) { *len = 0; return B_NOT_ALLOWED; } /* ---------- close_hook - does nothing, gracefully ----- */ static status_t close_hook (void* dev) { /* we don't do anything on close: there might be dup'd fd */ return B_NO_ERROR; } /* ----------- free_hook - close down the device ----------- */ static status_t free_hook (void* dev) { device_info *di = (device_info *)dev; shared_info *si = di->si; vuint32 *regs = di->regs; /* lock the driver */ AQUIRE_BEN(pd->kernel); /* if opened multiple times, decrement the open count and exit */ if (di->is_open > 1) goto unlock_and_exit; /* disable and clear any pending interrupts */ disable_vbi(regs); /* remove interrupt handler */ remove_io_interrupt_handler(di->pcii.u.h0.interrupt_line, eng_interrupt, di); /* delete the semaphores, ignoring any errors ('cause the owning team may have died on us) */ delete_sem(si->vblank); si->vblank = -1; /* free regs and framebuffer areas */ unmap_device(di); /* clean up our shared area */ delete_area(di->shared_area); di->shared_area = -1; di->si = NULL; unlock_and_exit: /* mark the device available */ di->is_open--; /* unlock the driver */ RELEASE_BEN(pd->kernel); /* all done */ return B_OK; } /* ----------- control_hook - where the real work is done ----------- */ static status_t control_hook (void* dev, uint32 msg, void *buf, size_t len) { device_info *di = (device_info *)dev; status_t result = B_DEV_INVALID_IOCTL; uint32 tmpUlong; switch (msg) { /* the only PUBLIC ioctl */ case B_GET_ACCELERANT_SIGNATURE: { char *sig = (char *)buf; strcpy(sig, current_settings.accelerant); result = B_OK; } break; /* PRIVATE ioctl from here on */ case ENG_GET_PRIVATE_DATA: { eng_get_private_data *gpd = (eng_get_private_data *)buf; if (gpd->magic == VIA_PRIVATE_DATA_MAGIC) { gpd->shared_info_area = di->shared_area; result = B_OK; } } break; case ENG_GET_PCI: { eng_get_set_pci *gsp = (eng_get_set_pci *)buf; if (gsp->magic == VIA_PRIVATE_DATA_MAGIC) { pci_info *pcii = &(di->pcii); gsp->value = get_pci(gsp->offset, gsp->size); result = B_OK; } } break; case ENG_SET_PCI: { eng_get_set_pci *gsp = (eng_get_set_pci *)buf; if (gsp->magic == VIA_PRIVATE_DATA_MAGIC) { pci_info *pcii = &(di->pcii); set_pci(gsp->offset, gsp->size, gsp->value); result = B_OK; } } break; case ENG_DEVICE_NAME: { // apsed eng_device_name *dn = (eng_device_name *)buf; if (dn->magic == VIA_PRIVATE_DATA_MAGIC) { strcpy(dn->name, di->name); result = B_OK; } } break; case ENG_RUN_INTERRUPTS: { eng_set_bool_state *ri = (eng_set_bool_state *)buf; if (ri->magic == VIA_PRIVATE_DATA_MAGIC) { vuint32 *regs = di->regs; if (ri->do_it) { enable_vbi(regs); } else { disable_vbi(regs); } result = B_OK; } } break; case ENG_GET_NTH_AGP_INFO: { eng_nth_agp_info *nai = (eng_nth_agp_info *)buf; if (nai->magic == VIA_PRIVATE_DATA_MAGIC) { nai->exist = false; nai->agp_bus = false; if (agp_bus) { nai->agp_bus = true; if ((*agp_bus->get_nth_agp_info)(nai->index, &(nai->agpi)) == B_NO_ERROR) { nai->exist = true; } } result = B_OK; } } break; case ENG_ENABLE_AGP: { eng_cmd_agp *nca = (eng_cmd_agp *)buf; if (nca->magic == VIA_PRIVATE_DATA_MAGIC) { if (agp_bus) { nca->agp_bus = true; nca->cmd = agp_bus->set_agp_mode(nca->cmd); } else { nca->agp_bus = false; nca->cmd = 0; } result = B_OK; } } break; case ENG_ISA_OUT: { eng_in_out_isa *io_isa = (eng_in_out_isa *)buf; if (io_isa->magic == VIA_PRIVATE_DATA_MAGIC) { pci_info *pcii = &(di->pcii); /* lock the driver: * no other graphics card may have ISA I/O enabled when we enter */ AQUIRE_BEN(pd->kernel); /* enable ISA I/O access */ tmpUlong = get_pci(PCI_command, 2); tmpUlong |= PCI_command_io; set_pci(PCI_command, 2, tmpUlong); if (io_isa->size == 1) isa_bus->write_io_8(io_isa->adress, (uint8)io_isa->data); else isa_bus->write_io_16(io_isa->adress, io_isa->data); result = B_OK; /* disable ISA I/O access */ tmpUlong = get_pci(PCI_command, 2); tmpUlong &= ~PCI_command_io; set_pci(PCI_command, 2, tmpUlong); /* end of critical section */ RELEASE_BEN(pd->kernel); } } break; case ENG_ISA_IN: { eng_in_out_isa *io_isa = (eng_in_out_isa *)buf; if (io_isa->magic == VIA_PRIVATE_DATA_MAGIC) { pci_info *pcii = &(di->pcii); /* lock the driver: * no other graphics card may have ISA I/O enabled when we enter */ AQUIRE_BEN(pd->kernel); /* enable ISA I/O access */ tmpUlong = get_pci(PCI_command, 2); tmpUlong |= PCI_command_io; set_pci(PCI_command, 2, tmpUlong); if (io_isa->size == 1) io_isa->data = isa_bus->read_io_8(io_isa->adress); else io_isa->data = isa_bus->read_io_16(io_isa->adress); result = B_OK; /* disable ISA I/O access */ tmpUlong = get_pci(PCI_command, 2); tmpUlong &= ~PCI_command_io; set_pci(PCI_command, 2, tmpUlong); /* end of critical section */ RELEASE_BEN(pd->kernel); } } break; } return result; }