/* $XFree86: xc/programs/Xserver/hw/xfree86/int10/generic.c,v 1.23 2001/05/28 14:21:56 eich Exp $ */ /* * XFree86 int10 module * execute BIOS int 10h calls in x86 real mode environment * Copyright 1999 Egbert Eich */ #include "xf86.h" #include "xf86_OSproc.h" #include "xf86_ansic.h" #include "xf86Pci.h" #include "compiler.h" #define _INT10_PRIVATE #include "xf86int10.h" #include "int10Defines.h" #define ALLOC_ENTRIES(x) ((V_RAM / x) - 1) static CARD8 read_b(xf86Int10InfoPtr pInt,int addr); static CARD16 read_w(xf86Int10InfoPtr pInt,int addr); static CARD32 read_l(xf86Int10InfoPtr pInt,int addr); static void write_b(xf86Int10InfoPtr pInt,int addr, CARD8 val); static void write_w(xf86Int10InfoPtr pInt,int addr, CARD16 val); static void write_l(xf86Int10InfoPtr pInt,int addr, CARD32 val); /* * the emulator cannot pass a pointer to the current xf86Int10InfoRec * to the memory access functions therefore store it here. */ typedef struct { int shift; int entries; void* base; void* vRam; void* sysMem; char* alloc; } genericInt10Priv; #define INTPriv(x) ((genericInt10Priv*)x->private) int10MemRec genericMem = { read_b, read_w, read_l, write_b, write_w, write_l }; static void MapVRam(xf86Int10InfoPtr pInt); static void UnmapVRam(xf86Int10InfoPtr pInt); static void *sysMem = NULL; xf86Int10InfoPtr xf86InitInt10(int entityIndex) { xf86Int10InfoPtr pInt; int screen; void* base = 0; void* vbiosMem = 0; void* options = NULL; legacyVGARec vga; xf86int10BiosLocation bios; #ifdef _PC CARD32 cs; #endif screen = (xf86FindScreenForEntity(entityIndex))->scrnIndex; options = xf86HandleInt10Options(xf86Screens[screen],entityIndex); if (int10skip(options)) { xfree(options); return NULL; } pInt = (xf86Int10InfoPtr)xnfcalloc(1, sizeof(xf86Int10InfoRec)); pInt->entityIndex = entityIndex; if (!xf86Int10ExecSetup(pInt)) goto error0; pInt->mem = &genericMem; pInt->private = (pointer)xnfcalloc(1, sizeof(genericInt10Priv)); INTPriv(pInt)->alloc = (pointer)xnfcalloc(1, ALLOC_ENTRIES(getpagesize())); pInt->scrnIndex = screen; base = INTPriv(pInt)->base = xnfalloc(SYS_BIOS); /* * we need to map video RAM MMIO as some chipsets map mmio * registers into this range. */ MapVRam(pInt); #ifdef _PC if (!sysMem) sysMem = xf86MapVidMem(screen, VIDMEM_FRAMEBUFFER, SYS_BIOS, BIOS_SIZE); INTPriv(pInt)->sysMem = sysMem; if (xf86ReadBIOS(0, 0, base, LOW_PAGE_SIZE) < 0) { xf86DrvMsg(screen, X_ERROR, "Cannot read int vect\n"); goto error1; } /* * Retrieve everything between V_BIOS and SYS_BIOS as some system BIOSes * have executable code there. Note that xf86ReadBIOS() can only read in * 64kB at a time. */ (void)memset((char *)base + V_BIOS, 0, SYS_BIOS - V_BIOS); for (cs = V_BIOS; cs < SYS_BIOS; cs += V_BIOS_SIZE) if (xf86ReadBIOS(cs, 0, (unsigned char *)base + cs, V_BIOS_SIZE) < V_BIOS_SIZE) xf86DrvMsg(screen, X_WARNING, "Unable to retrieve all of segment 0x%06X.\n", cs); xf86int10ParseBiosLocation(options,&bios); if (xf86IsEntityPrimary(entityIndex) && !(initPrimary(options))) { if (bios.bus == BUS_ISA && bios.location.legacy) { xf86DrvMsg(screen, X_CONFIG, "Overriding BIOS location: 0x%lx\n", bios.location.legacy); cs = bios.location.legacy >> 4; vbiosMem = (unsigned char *)base + (cs << 4); if (!int10_check_bios(screen, cs, vbiosMem)) { xf86DrvMsg(screen, X_ERROR, "No V_BIOS at specified address 0x%x\n",cs << 4); goto error1; } } else { if (bios.bus == BUS_PCI) { xf86DrvMsg(screen, X_WARNING, "Option BiosLocation for primary device ignored: " "It points to PCI.\n"); xf86DrvMsg(screen, X_WARNING, "You must set Option InitPrimary also\n"); } cs = MEM_RW(pInt,((0x10<<2)+2)); vbiosMem = (unsigned char *)base + (cs << 4); if (!int10_check_bios(screen, cs, vbiosMem)) { cs = MEM_RW(pInt, (0x42 << 2) + 2); vbiosMem = (unsigned char *)base + (cs << 4); if (!int10_check_bios(screen, cs, vbiosMem)) { cs = V_BIOS >> 4; vbiosMem = (unsigned char *)base + (cs << 4); if (!int10_check_bios(screen, cs, vbiosMem)) { xf86DrvMsg(screen, X_ERROR, "No V_BIOS found\n"); goto error1; } } } } xf86DrvMsg(screen, X_INFO, "Primary V_BIOS segment is: 0x%x\n", cs); set_return_trap(pInt); pInt->BIOSseg = cs; } else { BusType location_type; int bios_location = V_BIOS; int pci_entity; EntityInfoPtr pEnt = xf86GetEntityInfo(pInt->entityIndex); reset_int_vect(pInt); set_return_trap(pInt); if (bios.bus != BUS_NONE) { switch (location_type = bios.bus) { case BUS_PCI: xf86DrvMsg(screen,X_CONFIG,"Overriding bios location: " "PCI:%i:%i%i\n",bios.location.pci.bus, bios.location.pci.dev,bios.location.pci.func); break; case BUS_ISA: bios_location = bios.location.legacy; if (bios.location.legacy) xf86DrvMsg(screen,X_CONFIG,"Overriding bios location: " "Legacy:0x%x\n",bios.location.legacy); else xf86DrvMsg(screen,X_CONFIG,"Overriding bios location: " "Legacy\n"); break; default: break; } } else location_type = pEnt->location.type; vbiosMem = (unsigned char *)base + bios_location; switch (location_type) { case BUS_PCI: if (bios.bus == BUS_PCI) pci_entity = xf86GetPciEntity(bios.location.pci.bus, bios.location.pci.dev, bios.location.pci.func); else pci_entity = pInt->entityIndex; if (!mapPciRom(pci_entity,(unsigned char *)(vbiosMem))) { xf86DrvMsg(screen,X_ERROR,"Cannot read V_BIOS (3)\n"); goto error1; } break; case BUS_ISA: #if 0 (void)memset(vbiosMem, 0, V_BIOS_SIZE); if (xf86ReadBIOS(bios_location, 0, vbiosMem, V_BIOS_SIZE) < V_BIOS_SIZE) xf86DrvMsg(screen, X_WARNING, "Unable to retrieve all of segment 0x%x.\n",bios_location); #endif if (!int10_check_bios(screen, bios_location >> 4, vbiosMem)) { xf86DrvMsg(screen,X_ERROR,"Cannot read V_BIOS (4)\n"); goto error1; } default: goto error1; } xfree(pEnt); pInt->BIOSseg = V_BIOS >> 4; pInt->num = 0xe6; LockLegacyVGA(screen, &vga); xf86ExecX86int10(pInt); UnlockLegacyVGA(screen, &vga); } #else if (!sysMem) { sysMem = xnfalloc(BIOS_SIZE); setup_system_bios(sysMem); } INTPriv(pInt)->sysMem = sysMem; setup_int_vect(pInt); set_return_trap(pInt); /* * Retrieve two segments: one at V_BIOS, the other 64kB beyond the first. * This'll catch any BIOS that might have been initialised before server * entry. */ vbiosMem = (char *)base + V_BIOS; (void)memset(vbiosMem, 0, 2 * V_BIOS_SIZE); if (xf86ReadBIOS(V_BIOS, 0, vbiosMem, V_BIOS_SIZE) < V_BIOS_SIZE) xf86DrvMsg(screen, X_WARNING, "Unable to retrieve all of segment 0x0C0000.\n"); else if (((unsigned char *)vbiosMem)[2] > 0x80) if (xf86ReadBIOS(V_BIOS + V_BIOS_SIZE, 0, (unsigned char *)vbiosMem + V_BIOS_SIZE, V_BIOS_SIZE) < V_BIOS_SIZE) xf86DrvMsg(screen, X_WARNING, "Unable to retrieve all of segment 0x0D0000.\n"); /* * If this adapter is the primary, use its post-init BIOS (if we can find * it). */ xf86int10ParseBiosLocation(options,&bios); { int bios_location = V_BIOS; Bool done = FALSE; vbiosMem = (unsigned char *)base + bios_location; if ((bios.bus == BUS_ISA) || (bios.bus != BUS_PCI && xf86IsEntityPrimary(entityIndex))) { if (bios.bus == BUS_ISA && bios.location.legacy) { xf86DrvMsg(screen, X_CONFIG,"Looking for legacy V_BIOS " "at 0x%x for %sprimary device\n", bios.location.legacy, xf86IsEntityPrimary(entityIndex) ? "" : "non-"); bios_location = bios.location.legacy; vbiosMem = (unsigned char *)base + bios_location; } if (int10_check_bios(screen, bios_location >> 4, vbiosMem)) done = TRUE; else xf86DrvMsg(screen,X_INFO, "No legacy BIOS found -- trying PCI\n"); } if (!done) { int pci_entity; if (bios.bus == BUS_PCI) { xf86DrvMsg(screen,X_CONFIG,"Looking for BIOS at PCI:%i%i%i\n", bios.location.pci.bus,bios.location.pci.dev, bios.location.pci.func); pci_entity = xf86GetPciEntity(bios.location.pci.bus, bios.location.pci.dev, bios.location.pci.func); } else pci_entity = pInt->entityIndex; if (!mapPciRom(pci_entity, vbiosMem)) { xf86DrvMsg(screen, X_ERROR, "Cannot read V_BIOS (5)\n"); goto error1; } } } pInt->BIOSseg = V_BIOS >> 4; pInt->num = 0xe6; LockLegacyVGA(screen, &vga); xf86ExecX86int10(pInt); UnlockLegacyVGA(screen, &vga); #endif xfree(options); return pInt; error1: xfree(base); UnmapVRam(pInt); xfree(INTPriv(pInt)->alloc); xfree(pInt->private); error0: xfree(pInt); xfree(options); return NULL; } static void MapVRam(xf86Int10InfoPtr pInt) { int screen = pInt->scrnIndex; int pagesize = getpagesize(); int size = ((VRAM_SIZE + pagesize - 1)/pagesize) * pagesize; INTPriv(pInt)->vRam = xf86MapVidMem(screen, VIDMEM_MMIO, V_RAM, size); } static void UnmapVRam(xf86Int10InfoPtr pInt) { int screen = pInt->scrnIndex; int pagesize = getpagesize(); int size = ((VRAM_SIZE + pagesize - 1)/pagesize) * pagesize; xf86UnMapVidMem(screen, INTPriv(pInt)->vRam, size); } Bool MapCurrentInt10(xf86Int10InfoPtr pInt) { /* nothing to do here */ return TRUE; } void xf86FreeInt10(xf86Int10InfoPtr pInt) { if (!pInt) return; if (Int10Current == pInt) Int10Current = NULL; xfree(INTPriv(pInt)->base); UnmapVRam(pInt); xfree(INTPriv(pInt)->alloc); xfree(pInt->private); xfree(pInt); } void * xf86Int10AllocPages(xf86Int10InfoPtr pInt, int num, int *off) { int pagesize = getpagesize(); int num_pages = ALLOC_ENTRIES(pagesize); int i,j; for (i = 0; i < (num_pages - num); i++) { if (INTPriv(pInt)->alloc[i] == 0) { for (j = i; j < (num + i); j++) if (INTPriv(pInt)->alloc[j] != 0) break; if (j == (num + i)) break; i += num; } } if (i == (num_pages - num)) return NULL; for (j = i; j < (i + num); j++) INTPriv(pInt)->alloc[j] = 1; *off = (i + 1) * pagesize; return (char *)INTPriv(pInt)->base + *off; } void xf86Int10FreePages(xf86Int10InfoPtr pInt, void *pbase, int num) { int pagesize = getpagesize(); int first = (((char *)pbase - (char *)INTPriv(pInt)->base) / pagesize) - 1; int i; for (i = first; i < (first + num); i++) INTPriv(pInt)->alloc[i] = 0; } #define OFF(addr) ((addr) & 0xffff) #define SYS(addr) ((addr) >= SYS_BIOS) #define V_ADDR(addr) \ (SYS(addr) ? ((char*)INTPriv(pInt)->sysMem) + (addr - SYS_BIOS) \ : ((char*)(INTPriv(pInt)->base) + addr)) #define VRAM_ADDR(addr) (addr - V_RAM) #define VRAM_BASE (INTPriv(pInt)->vRam) #define VRAM(addr) ((addr >= V_RAM) && (addr < (V_RAM + VRAM_SIZE))) #define V_ADDR_RB(addr) \ (VRAM(addr)) ? MMIO_IN8((CARD8*)VRAM_BASE,VRAM_ADDR(addr)) \ : *(CARD8*) V_ADDR(addr) #define V_ADDR_RW(addr) \ (VRAM(addr)) ? MMIO_IN16((CARD16*)VRAM_BASE,VRAM_ADDR(addr)) \ : ldw_u((pointer)V_ADDR(addr)) #define V_ADDR_RL(addr) \ (VRAM(addr)) ? MMIO_IN32((CARD32*)VRAM_BASE,VRAM_ADDR(addr)) \ : ldl_u((pointer)V_ADDR(addr)) #define V_ADDR_WB(addr,val) \ if(VRAM(addr)) \ MMIO_OUT8((CARD8*)VRAM_BASE,VRAM_ADDR(addr),val); \ else \ *(CARD8*) V_ADDR(addr) = val; #define V_ADDR_WW(addr,val) \ if(VRAM(addr)) \ MMIO_OUT16((CARD16*)VRAM_BASE,VRAM_ADDR(addr),val); \ else \ stw_u((val),(pointer)(V_ADDR(addr))); #define V_ADDR_WL(addr,val) \ if (VRAM(addr)) \ MMIO_OUT32((CARD32*)VRAM_BASE,VRAM_ADDR(addr),val); \ else \ stl_u(val,(pointer)(V_ADDR(addr))); static CARD8 read_b(xf86Int10InfoPtr pInt, int addr) { return V_ADDR_RB(addr); } static CARD16 read_w(xf86Int10InfoPtr pInt, int addr) { #if X_BYTE_ORDER == X_LITTLE_ENDIAN if (OFF(addr + 1) > 0) return V_ADDR_RW(addr); #endif return V_ADDR_RB(addr) | (V_ADDR_RB(addr + 1) << 8); } static CARD32 read_l(xf86Int10InfoPtr pInt, int addr) { #if X_BYTE_ORDER == X_LITTLE_ENDIAN if (OFF(addr + 3) > 2) return V_ADDR_RL(addr); #endif return V_ADDR_RB(addr) | (V_ADDR_RB(addr + 1) << 8) | (V_ADDR_RB(addr + 2) << 16) | (V_ADDR_RB(addr + 3) << 24); } static void write_b(xf86Int10InfoPtr pInt, int addr, CARD8 val) { V_ADDR_WB(addr,val); } static void write_w(xf86Int10InfoPtr pInt, int addr, CARD16 val) { #if X_BYTE_ORDER == X_LITTLE_ENDIAN if (OFF(addr + 1) > 0) { V_ADDR_WW(addr, val); } #endif V_ADDR_WB(addr, val); V_ADDR_WB(addr + 1, val >> 8); } static void write_l(xf86Int10InfoPtr pInt, int addr, CARD32 val) { #if X_BYTE_ORDER == X_LITTLE_ENDIAN if (OFF(addr + 3) > 2) { V_ADDR_WL(addr, val); } #endif V_ADDR_WB(addr, val); V_ADDR_WB(addr + 1, val >> 8); V_ADDR_WB(addr + 2, val >> 16); V_ADDR_WB(addr + 3, val >> 24); } pointer xf86int10Addr(xf86Int10InfoPtr pInt, CARD32 addr) { return V_ADDR(addr); }