// Option rom scanning code. // // Copyright (C) 2008 Kevin O'Connor // Copyright (C) 2002 MandrakeSoft S.A. // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "bregs.h" // struct bregs #include "config.h" // CONFIG_* #include "farptr.h" // FLATPTR_TO_SEG #include "hw/pci.h" // foreachpci #include "hw/pci_ids.h" // PCI_CLASS_DISPLAY_VGA #include "hw/pci_regs.h" // PCI_ROM_ADDRESS #include "malloc.h" // rom_confirm #include "output.h" // dprintf #include "romfile.h" // romfile_loadint #include "stacks.h" // farcall16big #include "std/optionrom.h" // struct rom_header #include "std/pnpbios.h" // PNP_SIGNATURE #include "string.h" // memset #include "util.h" // get_pnp_offset /**************************************************************** * Helper functions ****************************************************************/ // Execute a given option rom. static void __callrom(struct rom_header *rom, u16 offset, u16 bdf) { u16 seg = FLATPTR_TO_SEG(rom); dprintf(1, "Running option rom at %04x:%04x\n", seg, offset); struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; br.ax = bdf; br.bx = 0xffff; br.dx = 0xffff; br.es = SEG_BIOS; br.di = get_pnp_offset(); br.code = SEGOFF(seg, offset); start_preempt(); farcall16big(&br); finish_preempt(); } // Execute a given option rom at the standard entry vector. void callrom(struct rom_header *rom, u16 bdf) { __callrom(rom, OPTION_ROM_INITVECTOR, bdf); } // Execute a BCV option rom registered via add_bcv(). void call_bcv(u16 seg, u16 ip) { __callrom(MAKE_FLATPTR(seg, 0), ip, 0); } static int EnforceChecksum; // Verify that an option rom looks valid static int is_valid_rom(struct rom_header *rom) { dprintf(6, "Checking rom %p (sig %x size %d)\n" , rom, rom->signature, rom->size); if (rom->signature != OPTION_ROM_SIGNATURE) return 0; if (! rom->size) return 0; u32 len = rom->size * 512; u8 sum = checksum(rom, len); if (sum != 0) { dprintf(1, "Found option rom with bad checksum: loc=%p len=%d sum=%x\n" , rom, len, sum); if (EnforceChecksum) return 0; } return 1; } // Check if a valid option rom has a pnp struct; return it if so. static struct pnp_data * get_pnp_rom(struct rom_header *rom) { struct pnp_data *pnp = (void*)((u8*)rom + rom->pnpoffset); if (pnp->signature != PNP_SIGNATURE) return NULL; return pnp; } // Check for multiple pnp option rom headers. static struct pnp_data * get_pnp_next(struct rom_header *rom, struct pnp_data *pnp) { if (! pnp->nextoffset) return NULL; pnp = (void*)((u8*)rom + pnp->nextoffset); if (pnp->signature != PNP_SIGNATURE) return NULL; return pnp; } // Check if a valid option rom has a pci struct; return it if so. static struct pci_data * get_pci_rom(struct rom_header *rom) { struct pci_data *pd = (void*)((u32)rom + rom->pcioffset); if (pd->signature != PCI_ROM_SIGNATURE) return NULL; if (rom->pcioffset & 3) dprintf(1, "WARNING! Found unaligned PCI rom (vd=%04x:%04x)\n" , pd->vendor, pd->device); return pd; } // Run rom init code and note rom size. static int init_optionrom(struct rom_header *rom, u16 bdf, int isvga) { if (! is_valid_rom(rom)) return -1; struct rom_header *newrom = rom_reserve(rom->size * 512); if (!newrom) { warn_noalloc(); return -1; } if (newrom != rom) memmove(newrom, rom, rom->size * 512); if (isvga || get_pnp_rom(newrom)) // Only init vga and PnP roms here. callrom(newrom, bdf); return rom_confirm(newrom->size * 512); } #define RS_PCIROM (1LL<<33) static void setRomSource(u64 *sources, struct rom_header *rom, u64 source) { if (sources) sources[((u32)rom - BUILD_ROM_START) / OPTION_ROM_ALIGN] = source; } static int getRomPriority(u64 *sources, struct rom_header *rom, int instance) { u64 source = sources[((u32)rom - BUILD_ROM_START) / OPTION_ROM_ALIGN]; if (!source) return -1; if (source & RS_PCIROM) return bootprio_find_pci_rom((void*)(u32)source, instance); struct romfile_s *file = (void*)(u32)source; return bootprio_find_named_rom(file->name, instance); } /**************************************************************** * Roms in CBFS ****************************************************************/ static struct rom_header * deploy_romfile(struct romfile_s *file) { u32 size = file->size; struct rom_header *rom = rom_reserve(size); if (!rom) { warn_noalloc(); return NULL; } int ret = file->copy(file, rom, size); if (ret <= 0) return NULL; return rom; } // Check if an option rom is at a hardcoded location or in CBFS. static struct rom_header * lookup_hardcode(struct pci_device *pci) { char fname[17]; snprintf(fname, sizeof(fname), "pci%04x,%04x.rom" , pci->vendor, pci->device); struct romfile_s *file = romfile_find(fname); if (file) return deploy_romfile(file); return NULL; } // Run all roms in a given CBFS directory. static void run_file_roms(const char *prefix, int isvga, u64 *sources) { struct romfile_s *file = NULL; for (;;) { file = romfile_findprefix(prefix, file); if (!file) break; struct rom_header *rom = deploy_romfile(file); if (rom) { setRomSource(sources, rom, (u32)file); init_optionrom(rom, 0, isvga); } } } /**************************************************************** * PCI roms ****************************************************************/ // Verify device is a vga device with legacy address decoding enabled. int is_pci_vga(struct pci_device *pci) { if (pci->class != PCI_CLASS_DISPLAY_VGA) return 0; u16 cmd = pci_config_readw(pci->bdf, PCI_COMMAND); if (!(cmd & PCI_COMMAND_IO && cmd & PCI_COMMAND_MEMORY)) return 0; while (pci->parent) { pci = pci->parent; u32 ctrl = pci_config_readb(pci->bdf, PCI_BRIDGE_CONTROL); if (!(ctrl & PCI_BRIDGE_CTL_VGA)) return 0; } return 1; } // Copy a rom to its permanent location below 1MiB static struct rom_header * copy_rom(struct rom_header *rom) { u32 romsize = rom->size * 512; struct rom_header *newrom = rom_reserve(romsize); if (!newrom) { warn_noalloc(); return NULL; } dprintf(4, "Copying option rom (size %d) from %p to %p\n" , romsize, rom, newrom); iomemcpy(newrom, rom, romsize); return newrom; } // Map the option rom of a given PCI device. static struct rom_header * map_pcirom(struct pci_device *pci) { u16 bdf = pci->bdf; dprintf(6, "Attempting to map option rom on dev %02x:%02x.%x\n" , pci_bdf_to_bus(bdf), pci_bdf_to_dev(bdf), pci_bdf_to_fn(bdf)); if ((pci->header_type & 0x7f) != PCI_HEADER_TYPE_NORMAL) { dprintf(6, "Skipping non-normal pci device (type=%x)\n" , pci->header_type); return NULL; } u32 orig = pci_config_readl(bdf, PCI_ROM_ADDRESS); pci_config_writel(bdf, PCI_ROM_ADDRESS, ~PCI_ROM_ADDRESS_ENABLE); u32 sz = pci_config_readl(bdf, PCI_ROM_ADDRESS); dprintf(6, "Option rom sizing returned %x %x\n", orig, sz); orig &= ~PCI_ROM_ADDRESS_ENABLE; if (!sz || sz == 0xffffffff) goto fail; if (orig == sz || (u32)(orig + 4*1024*1024) < 20*1024*1024) { // Don't try to map to a pci addresses at its max, in the last // 4MiB of ram, or the first 16MiB of ram. dprintf(6, "Preset rom address doesn't look valid\n"); goto fail; } // Looks like a rom - enable it. pci_config_writel(bdf, PCI_ROM_ADDRESS, orig | PCI_ROM_ADDRESS_ENABLE); struct rom_header *rom = (void*)orig; for (;;) { dprintf(5, "Inspecting possible rom at %p (vd=%04x:%04x" " bdf=%02x:%02x.%x)\n" , rom, pci->vendor, pci->device , pci_bdf_to_bus(bdf), pci_bdf_to_dev(bdf), pci_bdf_to_fn(bdf)); if (rom->signature != OPTION_ROM_SIGNATURE) { dprintf(6, "No option rom signature (got %x)\n", rom->signature); goto fail; } struct pci_data *pd = get_pci_rom(rom); if (! pd) { dprintf(6, "No valid pci signature found\n"); goto fail; } if (pd->vendor == pci->vendor && pd->device == pci->device && pd->type == PCIROM_CODETYPE_X86) // A match break; dprintf(6, "Didn't match dev/ven (got %04x:%04x) or type (got %d)\n" , pd->vendor, pd->device, pd->type); if (pd->indicator & 0x80) { dprintf(6, "No more images left\n"); goto fail; } rom = (void*)((u32)rom + pd->ilen * 512); } rom = copy_rom(rom); pci_config_writel(bdf, PCI_ROM_ADDRESS, orig); return rom; fail: // Not valid - restore original and exit. pci_config_writel(bdf, PCI_ROM_ADDRESS, orig); return NULL; } // Attempt to map and initialize the option rom on a given PCI device. static int init_pcirom(struct pci_device *pci, int isvga, u64 *sources) { u16 bdf = pci->bdf; dprintf(4, "Attempting to init PCI bdf %02x:%02x.%x (vd %04x:%04x)\n" , pci_bdf_to_bus(bdf), pci_bdf_to_dev(bdf), pci_bdf_to_fn(bdf) , pci->vendor, pci->device); struct rom_header *rom = lookup_hardcode(pci); if (! rom) rom = map_pcirom(pci); if (! rom) // No ROM present. return -1; setRomSource(sources, rom, RS_PCIROM | (u32)pci); return init_optionrom(rom, bdf, isvga); } /**************************************************************** * Non-VGA option rom init ****************************************************************/ void optionrom_setup(void) { if (! CONFIG_OPTIONROMS) return; dprintf(1, "Scan for option roms\n"); u64 sources[(BUILD_BIOS_ADDR - BUILD_ROM_START) / OPTION_ROM_ALIGN]; memset(sources, 0, sizeof(sources)); u32 post_vga = rom_get_last(); if (CONFIG_OPTIONROMS_DEPLOYED) { // Option roms are already deployed on the system. u32 pos = post_vga; while (pos < rom_get_max()) { int ret = init_optionrom((void*)pos, 0, 0); if (ret) pos += OPTION_ROM_ALIGN; else pos = rom_get_last(); } } else { // Find and deploy PCI roms. struct pci_device *pci; foreachpci(pci) { if (pci->class == PCI_CLASS_DISPLAY_VGA || pci->have_driver) continue; init_pcirom(pci, 0, sources); } // Find and deploy CBFS roms not associated with a device. run_file_roms("genroms/", 0, sources); } rom_reserve(0); // All option roms found and deployed - now build BEV/BCV vectors. u32 pos = post_vga; while (pos < rom_get_last()) { struct rom_header *rom = (void*)pos; if (! is_valid_rom(rom)) { pos += OPTION_ROM_ALIGN; continue; } pos += ALIGN(rom->size * 512, OPTION_ROM_ALIGN); struct pnp_data *pnp = get_pnp_rom(rom); if (! pnp) { // Legacy rom. boot_add_bcv(FLATPTR_TO_SEG(rom), OPTION_ROM_INITVECTOR, 0 , getRomPriority(sources, rom, 0)); continue; } // PnP rom - check for BEV and BCV boot capabilities. int instance = 0; while (pnp) { if (pnp->bev) boot_add_bev(FLATPTR_TO_SEG(rom), pnp->bev, pnp->productname , getRomPriority(sources, rom, instance++)); else if (pnp->bcv) boot_add_bcv(FLATPTR_TO_SEG(rom), pnp->bcv, pnp->productname , getRomPriority(sources, rom, instance++)); else break; pnp = get_pnp_next(rom, pnp); } } } /**************************************************************** * VGA init ****************************************************************/ static int S3ResumeVga; int ScreenAndDebug; struct rom_header *VgaROM; // Call into vga code to turn on console. void vgarom_setup(void) { if (! CONFIG_OPTIONROMS) return; dprintf(1, "Scan for VGA option rom\n"); // Load some config settings that impact VGA. EnforceChecksum = romfile_loadint("etc/optionroms-checksum", 1); S3ResumeVga = romfile_loadint("etc/s3-resume-vga-init", CONFIG_QEMU); ScreenAndDebug = romfile_loadint("etc/screen-and-debug", 1); if (CONFIG_OPTIONROMS_DEPLOYED) { // Option roms are already deployed on the system. init_optionrom((void*)BUILD_ROM_START, 0, 1); } else { // Clear option rom memory memset((void*)BUILD_ROM_START, 0, rom_get_max() - BUILD_ROM_START); // Find and deploy PCI VGA rom. struct pci_device *pci; foreachpci(pci) { if (!is_pci_vga(pci)) continue; vgahook_setup(pci); init_pcirom(pci, 1, NULL); break; } // Find and deploy CBFS vga-style roms not associated with a device. run_file_roms("vgaroms/", 1, NULL); } rom_reserve(0); if (rom_get_last() == BUILD_ROM_START) // No VGA rom found return; VgaROM = (void*)BUILD_ROM_START; enable_vga_console(); } void s3_resume_vga(void) { if (!S3ResumeVga) return; if (!VgaROM || ! is_valid_rom(VgaROM)) return; callrom(VgaROM, 0); }