// Code to load disk image and start system boot. // // Copyright (C) 2008-2013 Kevin O'Connor // Copyright (C) 2002 MandrakeSoft S.A. // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "block.h" // struct drive_s #include "bregs.h" // struct bregs #include "config.h" // CONFIG_* #include "fw/paravirt.h" // qemu_cfg_show_boot_menu #include "hw/pci.h" // pci_bdf_to_* #include "hw/pcidevice.h" // struct pci_device #include "hw/rtc.h" // rtc_read #include "hw/usb.h" // struct usbdevice_s #include "list.h" // hlist_node #include "malloc.h" // free #include "output.h" // dprintf #include "romfile.h" // romfile_loadint #include "std/disk.h" // struct mbr_s #include "string.h" // memset #include "util.h" // irqtimer_calc #include "tcgbios.h" // tpm_* /**************************************************************** * Helper search functions ****************************************************************/ // See if 'str' starts with 'glob' - if glob contains an '*' character // it will match any number of characters in str that aren't a '/' or // the next glob character. static char * glob_prefix(const char *glob, const char *str) { for (;;) { if (!*glob && (!*str || *str == '/')) return (char*)str; if (*glob == '*') { if (!*str || *str == '/' || *str == glob[1]) glob++; else str++; continue; } if (*glob != *str) return NULL; glob++; str++; } } #define FW_PCI_DOMAIN "/pci@i0cf8" static char * build_pci_path(char *buf, int max, const char *devname, struct pci_device *pci) { // Build the string path of a bdf - for example: /pci@i0cf8/isa@1,2 char *p = buf; if (pci->parent) { p = build_pci_path(p, max, "pci-bridge", pci->parent); } else { p += snprintf(p, buf+max-p, "%s", FW_PCI_DOMAIN); if (pci->rootbus) p += snprintf(p, buf+max-p, ",%x", pci->rootbus); } int dev = pci_bdf_to_dev(pci->bdf), fn = pci_bdf_to_fn(pci->bdf); p += snprintf(p, buf+max-p, "/%s@%x", devname, dev); if (fn) p += snprintf(p, buf+max-p, ",%x", fn); return p; } static char * build_scsi_path(char *buf, int max, struct pci_device *pci, int target, int lun) { // Build the string path of a scsi drive - for example: // /pci@i0cf8/scsi@5/channel@0/disk@1,0 char *p; p = build_pci_path(buf, max, "*", pci); p += snprintf(p, buf+max-p, "/*@0/*@%x,%x", target, lun); return p; } static char * build_ata_path(char *buf, int max, struct pci_device *pci, int chanid, int slave) { // Build the string path of an ata drive - for example: // /pci@i0cf8/ide@1,1/drive@1/disk@0 char *p; p = build_pci_path(buf, max, "*", pci); p += snprintf(p, buf+max-p, "/drive@%x/disk@%x", chanid, slave); return p; } /**************************************************************** * Boot device logical geometry ****************************************************************/ typedef struct BootDeviceLCHS { char *name; u32 lcyls; u32 lheads; u32 lsecs; } BootDeviceLCHS; static BootDeviceLCHS *BiosGeometry VARVERIFY32INIT; static int BiosGeometryCount; static char * parse_u32(char *cur, u32 *n) { u32 m = 0; if (cur) { while ('0' <= *cur && *cur <= '9') { m = 10 * m + (*cur - '0'); cur++; } if (*cur != '\0') cur++; } *n = m; return cur; } static void loadBiosGeometry(void) { if (!CONFIG_HOST_BIOS_GEOMETRY) return; char *f = romfile_loadfile("bios-geometry", NULL); if (!f) return; int i = 0; BiosGeometryCount = 1; while (f[i]) { if (f[i] == '\n') BiosGeometryCount++; i++; } BiosGeometry = malloc_tmphigh(BiosGeometryCount * sizeof(BootDeviceLCHS)); if (!BiosGeometry) { warn_noalloc(); free(f); BiosGeometryCount = 0; return; } dprintf(1, "bios geometry:\n"); i = 0; do { BootDeviceLCHS *d = &BiosGeometry[i]; d->name = f; f = strchr(f, '\n'); if (f) *(f++) = '\0'; char *chs_values = strchr(d->name, ' '); if (chs_values) *(chs_values++) = '\0'; chs_values = parse_u32(chs_values, &d->lcyls); chs_values = parse_u32(chs_values, &d->lheads); chs_values = parse_u32(chs_values, &d->lsecs); dprintf(1, "%s: (%u, %u, %u)\n", d->name, d->lcyls, d->lheads, d->lsecs); i++; } while (f); } // Search the bios-geometry list for the given glob pattern. static BootDeviceLCHS * boot_lchs_find(const char *glob) { dprintf(1, "Searching bios-geometry for: %s\n", glob); int i; for (i = 0; i < BiosGeometryCount; i++) if (glob_prefix(glob, BiosGeometry[i].name)) return &BiosGeometry[i]; return NULL; } int boot_lchs_find_pci_device(struct pci_device *pci, struct chs_s *chs) { if (!CONFIG_HOST_BIOS_GEOMETRY) return -1; char desc[256]; build_pci_path(desc, sizeof(desc), "*", pci); BootDeviceLCHS *b = boot_lchs_find(desc); if (!b) return -1; chs->cylinder = (u16)b->lcyls; chs->head = (u16)b->lheads; chs->sector = (u16)b->lsecs; return 0; } int boot_lchs_find_scsi_device(struct pci_device *pci, int target, int lun, struct chs_s *chs) { if (!CONFIG_HOST_BIOS_GEOMETRY) return -1; if (!pci) // support only pci machine for now return -1; // Find scsi drive - for example: /pci@i0cf8/scsi@5/channel@0/disk@1,0 char desc[256]; build_scsi_path(desc, sizeof(desc), pci, target, lun); BootDeviceLCHS *b = boot_lchs_find(desc); if (!b) return -1; chs->cylinder = (u16)b->lcyls; chs->head = (u16)b->lheads; chs->sector = (u16)b->lsecs; return 0; } int boot_lchs_find_ata_device(struct pci_device *pci, int chanid, int slave, struct chs_s *chs) { if (!CONFIG_HOST_BIOS_GEOMETRY) return -1; if (!pci) // support only pci machine for now return -1; // Find ata drive - for example: /pci@i0cf8/ide@1,1/drive@1/disk@0 char desc[256]; build_ata_path(desc, sizeof(desc), pci, chanid, slave); BootDeviceLCHS *b = boot_lchs_find(desc); if (!b) return -1; chs->cylinder = (u16)b->lcyls; chs->head = (u16)b->lheads; chs->sector = (u16)b->lsecs; return 0; } /**************************************************************** * Boot priority ordering ****************************************************************/ static char **Bootorder VARVERIFY32INIT; static int BootorderCount; static void loadBootOrder(void) { if (!CONFIG_BOOTORDER) return; char *f = romfile_loadfile("bootorder", NULL); if (!f) return; int i = 0; BootorderCount = 1; while (f[i]) { if (f[i] == '\n') BootorderCount++; i++; } Bootorder = malloc_tmphigh(BootorderCount*sizeof(char*)); if (!Bootorder) { warn_noalloc(); free(f); BootorderCount = 0; return; } dprintf(1, "boot order:\n"); i = 0; do { Bootorder[i] = f; f = strchr(f, '\n'); if (f) *(f++) = '\0'; Bootorder[i] = nullTrailingSpace(Bootorder[i]); dprintf(1, "%d: %s\n", i+1, Bootorder[i]); i++; } while (f); } // Search the bootorder list for the given glob pattern. static int find_prio(const char *glob) { dprintf(1, "Searching bootorder for: %s\n", glob); int i; for (i = 0; i < BootorderCount; i++) if (glob_prefix(glob, Bootorder[i])) return i+1; return -1; } u8 is_bootprio_strict(void) { static int prio_halt = -2; if (prio_halt == -2) prio_halt = find_prio("HALT"); return prio_halt >= 0; } int bootprio_find_pci_device(struct pci_device *pci) { if (CONFIG_CSM) return csm_bootprio_pci(pci); if (!CONFIG_BOOTORDER) return -1; // Find pci device - for example: /pci@i0cf8/ethernet@5 char desc[256]; build_pci_path(desc, sizeof(desc), "*", pci); return find_prio(desc); } int bootprio_find_mmio_device(void *mmio) { if (!CONFIG_BOOTORDER) return -1; char desc[256]; snprintf(desc, sizeof(desc), "/virtio-mmio@%016x/*", (u32)mmio); return find_prio(desc); } int bootprio_find_scsi_device(struct pci_device *pci, int target, int lun) { if (!CONFIG_BOOTORDER) return -1; if (!pci) // support only pci machine for now return -1; char desc[256]; build_scsi_path(desc, sizeof(desc), pci, target, lun); return find_prio(desc); } int bootprio_find_scsi_mmio_device(void *mmio, int target, int lun) { if (!CONFIG_BOOTORDER) return -1; char desc[256]; snprintf(desc, sizeof(desc), "/virtio-mmio@%016x/*@0/*@%x,%x", (u32)mmio, target, lun); return find_prio(desc); } int bootprio_find_ata_device(struct pci_device *pci, int chanid, int slave) { if (CONFIG_CSM) return csm_bootprio_ata(pci, chanid, slave); if (!CONFIG_BOOTORDER) return -1; if (!pci) // support only pci machine for now return -1; char desc[256]; build_ata_path(desc, sizeof(desc), pci, chanid, slave); return find_prio(desc); } int bootprio_find_fdc_device(struct pci_device *pci, int port, int fdid) { if (CONFIG_CSM) return csm_bootprio_fdc(pci, port, fdid); if (!CONFIG_BOOTORDER) return -1; if (!pci) // support only pci machine for now return -1; // Find floppy - for example: /pci@i0cf8/isa@1/fdc@03f1/floppy@0 char desc[256], *p; p = build_pci_path(desc, sizeof(desc), "isa", pci); snprintf(p, desc+sizeof(desc)-p, "/fdc@%04x/floppy@%x", port, fdid); return find_prio(desc); } int bootprio_find_pci_rom(struct pci_device *pci, int instance) { if (!CONFIG_BOOTORDER) return -1; // Find pci rom - for example: /pci@i0cf8/scsi@3:rom2 char desc[256], *p; p = build_pci_path(desc, sizeof(desc), "*", pci); if (instance) snprintf(p, desc+sizeof(desc)-p, ":rom%x", instance); return find_prio(desc); } int bootprio_find_named_rom(const char *name, int instance) { if (!CONFIG_BOOTORDER) return -1; // Find named rom - for example: /rom@genroms/linuxboot.bin char desc[256], *p; p = desc + snprintf(desc, sizeof(desc), "/rom@%s", name); if (instance) snprintf(p, desc+sizeof(desc)-p, ":rom%x", instance); return find_prio(desc); } static int usb_portmap(struct usbdevice_s *usbdev) { if (usbdev->hub->op->portmap) return usbdev->hub->op->portmap(usbdev->hub, usbdev->port); return usbdev->port + 1; } static char * build_usb_path(char *buf, int max, struct usbhub_s *hub) { if (!hub->usbdev) // Root hub - nothing to add. return buf; char *p = build_usb_path(buf, max, hub->usbdev->hub); p += snprintf(p, buf+max-p, "/hub@%x", usb_portmap(hub->usbdev)); return p; } int bootprio_find_usb(struct usbdevice_s *usbdev, int lun) { if (!CONFIG_BOOTORDER) return -1; // Find usb - examples: // pci: /pci@i0cf8/usb@1,2/storage@1/channel@0/disk@0,0 // mmio: /sysbus-xhci@00000000fe900000/storage@1/channel@0/disk@0,0 char desc[256], *p; if (usbdev->hub->cntl->pci) p = build_pci_path(desc, sizeof(desc), "usb", usbdev->hub->cntl->pci); else if (usbdev->hub->cntl->mmio) p = desc + snprintf(desc, sizeof(desc), "/*@%016x" , (u32)usbdev->hub->cntl->mmio); else return -1; p = build_usb_path(p, desc+sizeof(desc)-p, usbdev->hub); snprintf(p, desc+sizeof(desc)-p, "/storage@%x/*@0/*@0,%x" , usb_portmap(usbdev), lun); int ret = find_prio(desc); if (ret >= 0) return ret; // Try usb-host/redir - for example: /pci@i0cf8/usb@1,2/usb-host@1 snprintf(p, desc+sizeof(desc)-p, "/usb-*@%x", usb_portmap(usbdev)); return find_prio(desc); } /**************************************************************** * Boot setup ****************************************************************/ static int BootRetryTime; static int CheckFloppySig = 1; #define DEFAULT_PRIO 9999 static int DefaultFloppyPrio = 101; static int DefaultCDPrio = 102; static int DefaultHDPrio = 103; static int DefaultBEVPrio = 104; void boot_init(void) { if (! CONFIG_BOOT) return; if (CONFIG_QEMU) { // On emulators, get boot order from nvram. if (rtc_read(CMOS_BIOS_BOOTFLAG1) & 1) CheckFloppySig = 0; u32 bootorder = (rtc_read(CMOS_BIOS_BOOTFLAG2) | ((rtc_read(CMOS_BIOS_BOOTFLAG1) & 0xf0) << 4)); DefaultFloppyPrio = DefaultCDPrio = DefaultHDPrio = DefaultBEVPrio = DEFAULT_PRIO; int i; for (i=101; i<104; i++) { u32 val = bootorder & 0x0f; bootorder >>= 4; switch (val) { case 1: DefaultFloppyPrio = i; break; case 2: DefaultHDPrio = i; break; case 3: DefaultCDPrio = i; break; case 4: DefaultBEVPrio = i; break; } } } BootRetryTime = romfile_loadint("etc/boot-fail-wait", 60*1000); loadBootOrder(); loadBiosGeometry(); } /**************************************************************** * BootList handling ****************************************************************/ struct bootentry_s { int type; union { u32 data; struct segoff_s vector; struct drive_s *drive; }; int priority; const char *description; struct hlist_node node; }; static struct hlist_head BootList VARVERIFY32INIT; #define IPL_TYPE_FLOPPY 0x01 #define IPL_TYPE_HARDDISK 0x02 #define IPL_TYPE_CDROM 0x03 #define IPL_TYPE_CBFS 0x20 #define IPL_TYPE_BEV 0x80 #define IPL_TYPE_BCV 0x81 #define IPL_TYPE_HALT 0xf0 static void bootentry_add(int type, int prio, u32 data, const char *desc) { if (! CONFIG_BOOT) return; struct bootentry_s *be = malloc_tmp(sizeof(*be)); if (!be) { warn_noalloc(); return; } be->type = type; be->priority = prio; be->data = data; be->description = desc ?: "?"; dprintf(3, "Registering bootable: %s (type:%d prio:%d data:%x)\n" , be->description, type, prio, data); // Add entry in sorted order. struct hlist_node **pprev; struct bootentry_s *pos; hlist_for_each_entry_pprev(pos, pprev, &BootList, node) { if (be->priority < pos->priority) break; if (be->priority > pos->priority) continue; if (be->type < pos->type) break; if (be->type > pos->type) continue; if (be->type <= IPL_TYPE_CDROM && (be->drive->type < pos->drive->type || (be->drive->type == pos->drive->type && be->drive->cntl_id < pos->drive->cntl_id))) break; } hlist_add(&be->node, pprev); } // Return the given priority if it's set - defaultprio otherwise. static inline int defPrio(int priority, int defaultprio) { return (priority < 0) ? defaultprio : priority; } // Add a BEV vector for a given pnp compatible option rom. void boot_add_bev(u16 seg, u16 bev, u16 desc, int prio) { bootentry_add(IPL_TYPE_BEV, defPrio(prio, DefaultBEVPrio) , SEGOFF(seg, bev).segoff , desc ? MAKE_FLATPTR(seg, desc) : "Unknown"); DefaultBEVPrio = DEFAULT_PRIO; } // Add a bcv entry for an expansion card harddrive or legacy option rom void boot_add_bcv(u16 seg, u16 ip, u16 desc, int prio) { bootentry_add(IPL_TYPE_BCV, defPrio(prio, DefaultHDPrio) , SEGOFF(seg, ip).segoff , desc ? MAKE_FLATPTR(seg, desc) : "Legacy option rom"); } void boot_add_floppy(struct drive_s *drive, const char *desc, int prio) { bootentry_add(IPL_TYPE_FLOPPY, defPrio(prio, DefaultFloppyPrio) , (u32)drive, desc); } void boot_add_hd(struct drive_s *drive, const char *desc, int prio) { bootentry_add(IPL_TYPE_HARDDISK, defPrio(prio, DefaultHDPrio) , (u32)drive, desc); } void boot_add_cd(struct drive_s *drive, const char *desc, int prio) { if (GET_GLOBAL(PlatformRunningOn) & PF_QEMU) { // We want short boot times. But on physical hardware even // the test unit ready can take several seconds. So do media // access on qemu only, where we know it will be fast. char *extra = cdrom_media_info(drive); if (extra) { desc = znprintf(MAXDESCSIZE, "%s (%s)", desc, extra); free(extra); } } bootentry_add(IPL_TYPE_CDROM, defPrio(prio, DefaultCDPrio) , (u32)drive, desc); } // Add a CBFS payload entry void boot_add_cbfs(void *data, const char *desc, int prio) { bootentry_add(IPL_TYPE_CBFS, defPrio(prio, DEFAULT_PRIO), (u32)data, desc); } /**************************************************************** * Keyboard calls ****************************************************************/ // See if a keystroke is pending in the keyboard buffer. static int check_for_keystroke(void) { struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF|F_ZF; br.ah = 1; call16_int(0x16, &br); return !(br.flags & F_ZF); } // Return a keystroke - waiting forever if necessary. static int get_raw_keystroke(void) { struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; call16_int(0x16, &br); return br.ax; } // Read a keystroke - waiting up to 'msec' milliseconds. // returns both scancode and ascii code. int get_keystroke_full(int msec) { u32 end = irqtimer_calc(msec); for (;;) { if (check_for_keystroke()) return get_raw_keystroke(); if (irqtimer_check(end)) return -1; yield_toirq(); } } // Read a keystroke - waiting up to 'msec' milliseconds. // returns scancode only. int get_keystroke(int msec) { int keystroke = get_keystroke_full(msec); if (keystroke < 0) return keystroke; return keystroke >> 8; } /**************************************************************** * Boot menu and BCV execution ****************************************************************/ #define DEFAULT_BOOTMENU_WAIT 2500 static const char menuchars[] = { '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f', 'g', 'h', 'i', 'j', 'k', 'l', 'm', 'n', 'o', 'p', 'q', 'r', 's', /* skip t (tpm menu) */ 'u', 'v', 'w', 'x', 'y', 'z' }; // Show IPL option menu. void interactive_bootmenu(void) { if (! CONFIG_BOOTMENU) return; int show_boot_menu = romfile_loadint("etc/show-boot-menu", 1); if (!show_boot_menu) return; // skip menu if only one boot device and no TPM if (show_boot_menu == 2 && !tpm_can_show_menu() && !hlist_empty(&BootList) && !BootList.first->next) { dprintf(1, "Only one boot device present. Skip boot menu.\n"); printf("\n"); return; } while (get_keystroke(0) >= 0) ; char *bootmsg = romfile_loadfile("etc/boot-menu-message", NULL); int menukey = romfile_loadint("etc/boot-menu-key", 1); printf("%s", bootmsg ?: "\nPress ESC for boot menu.\n\n"); free(bootmsg); u32 menutime = romfile_loadint("etc/boot-menu-wait", DEFAULT_BOOTMENU_WAIT); enable_bootsplash(); int scan_code = get_keystroke(menutime); disable_bootsplash(); if (scan_code != menukey) return; while (get_keystroke(0) >= 0) ; printf("Select boot device:\n\n"); wait_threads(); // Show menu items int maxmenu = 0; struct bootentry_s *pos, *boot = NULL; hlist_for_each_entry(pos, &BootList, node) { char desc[77]; if (maxmenu >= ARRAY_SIZE(menuchars)) { break; } printf("%c. %s\n", menuchars[maxmenu] , strtcpy(desc, pos->description, ARRAY_SIZE(desc))); maxmenu++; } if (tpm_can_show_menu()) { printf("\nt. TPM Configuration\n"); } // Get key press. If the menu key is ESC, do not restart boot unless // 1.5 seconds have passed. Otherwise users (trained by years of // repeatedly hitting keys to enter the BIOS) will end up hitting ESC // multiple times and immediately booting the primary boot device. int esc_accepted_time = irqtimer_calc(menukey == 1 ? 1500 : 0); for (;;) { int keystroke = get_keystroke_full(1000); if (keystroke == 0x011b && !irqtimer_check(esc_accepted_time)) continue; if (keystroke < 0) // timeout continue; scan_code = keystroke >> 8; int key_ascii = keystroke & 0xff; if (tpm_can_show_menu() && key_ascii == 't') { printf("\n"); tpm_menu(); } if (scan_code == 1) { // ESC printf("\n"); return; } maxmenu = 0; hlist_for_each_entry(pos, &BootList, node) { if (maxmenu >= ARRAY_SIZE(menuchars)) break; if (key_ascii == menuchars[maxmenu]) { boot = pos; break; } maxmenu++; } if (boot) break; } printf("\n"); // Find entry and make top priority. hlist_del(&boot->node); boot->priority = 0; hlist_add_head(&boot->node, &BootList); } // BEV (Boot Execution Vector) list struct bev_s { int type; u32 vector; }; static struct bev_s BEV[20]; static int BEVCount; static int HaveHDBoot, HaveFDBoot; static void add_bev(int type, u32 vector) { if (type == IPL_TYPE_HARDDISK && HaveHDBoot++) return; if (type == IPL_TYPE_FLOPPY && HaveFDBoot++) return; if (BEVCount >= ARRAY_SIZE(BEV)) return; struct bev_s *bev = &BEV[BEVCount++]; bev->type = type; bev->vector = vector; } // Prepare for boot - show menu and run bcvs. void bcv_prepboot(void) { if (! CONFIG_BOOT) return; int haltprio = find_prio("HALT"); if (haltprio >= 0) bootentry_add(IPL_TYPE_HALT, haltprio, 0, "HALT"); // Map drives and populate BEV list struct bootentry_s *pos; hlist_for_each_entry(pos, &BootList, node) { switch (pos->type) { case IPL_TYPE_BCV: call_bcv(pos->vector.seg, pos->vector.offset); add_bev(IPL_TYPE_HARDDISK, 0); break; case IPL_TYPE_FLOPPY: map_floppy_drive(pos->drive); add_bev(IPL_TYPE_FLOPPY, 0); break; case IPL_TYPE_HARDDISK: map_hd_drive(pos->drive); add_bev(IPL_TYPE_HARDDISK, 0); break; case IPL_TYPE_CDROM: map_cd_drive(pos->drive); // NO BREAK default: add_bev(pos->type, pos->data); break; } } // If nothing added a floppy/hd boot - add it manually. add_bev(IPL_TYPE_FLOPPY, 0); add_bev(IPL_TYPE_HARDDISK, 0); } /**************************************************************** * Boot code (int 18/19) ****************************************************************/ // Jump to a bootup entry point. static void call_boot_entry(struct segoff_s bootsegip, u8 bootdrv) { dprintf(1, "Booting from %04x:%04x\n", bootsegip.seg, bootsegip.offset); struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; br.code = bootsegip; // Set the magic number in ax and the boot drive in dl. br.dl = bootdrv; br.ax = 0xaa55; farcall16(&br); } // Boot from a disk (either floppy or harddrive) static void boot_disk(u8 bootdrv, int checksig) { u16 bootseg = 0x07c0; // Read sector struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; br.dl = bootdrv; br.es = bootseg; br.ah = 2; br.al = 1; br.cl = 1; call16_int(0x13, &br); if (br.flags & F_CF) { printf("Boot failed: could not read the boot disk\n\n"); return; } if (checksig) { struct mbr_s *mbr = (void*)0; if (GET_FARVAR(bootseg, mbr->signature) != MBR_SIGNATURE) { printf("Boot failed: not a bootable disk\n\n"); return; } } tpm_add_bcv(bootdrv, MAKE_FLATPTR(bootseg, 0), 512); /* Canonicalize bootseg:bootip */ u16 bootip = (bootseg & 0x0fff) << 4; bootseg &= 0xf000; call_boot_entry(SEGOFF(bootseg, bootip), bootdrv); } // Boot from a CD-ROM static void boot_cdrom(struct drive_s *drive) { if (! CONFIG_CDROM_BOOT) return; printf("Booting from DVD/CD...\n"); int status = cdrom_boot(drive); if (status) { printf("Boot failed: Could not read from CDROM (code %04x)\n", status); return; } u8 bootdrv = CDEmu.emulated_drive; u16 bootseg = CDEmu.load_segment; tpm_add_cdrom(bootdrv, MAKE_FLATPTR(bootseg, 0), 512); /* Canonicalize bootseg:bootip */ u16 bootip = (bootseg & 0x0fff) << 4; bootseg &= 0xf000; call_boot_entry(SEGOFF(bootseg, bootip), bootdrv); } // Boot from a CBFS payload static void boot_cbfs(struct cbfs_file *file) { if (!CONFIG_COREBOOT_FLASH) return; printf("Booting from CBFS...\n"); cbfs_run_payload(file); } // Boot from a BEV entry on an optionrom. static void boot_rom(u32 vector) { printf("Booting from ROM...\n"); struct segoff_s so; so.segoff = vector; call_boot_entry(so, 0); } // Unable to find bootable device - warn user and eventually retry. static void boot_fail(void) { if (BootRetryTime == (u32)-1) printf("No bootable device.\n"); else printf("No bootable device. Retrying in %d seconds.\n" , BootRetryTime/1000); // Wait for 'BootRetryTime' milliseconds and then reboot. u32 end = irqtimer_calc(BootRetryTime); for (;;) { if (BootRetryTime != (u32)-1 && irqtimer_check(end)) break; yield_toirq(); } printf("Rebooting.\n"); reset(); } // Determine next boot method and attempt a boot using it. static void do_boot(int seq_nr) { if (! CONFIG_BOOT) panic("Boot support not compiled in.\n"); if (seq_nr >= BEVCount) boot_fail(); // Boot the given BEV type. struct bev_s *ie = &BEV[seq_nr]; switch (ie->type) { case IPL_TYPE_FLOPPY: printf("Booting from Floppy...\n"); boot_disk(0x00, CheckFloppySig); break; case IPL_TYPE_HARDDISK: printf("Booting from Hard Disk...\n"); boot_disk(0x80, 1); break; case IPL_TYPE_CDROM: boot_cdrom((void*)ie->vector); break; case IPL_TYPE_CBFS: boot_cbfs((void*)ie->vector); break; case IPL_TYPE_BEV: boot_rom(ie->vector); break; case IPL_TYPE_HALT: boot_fail(); break; } // Boot failed: invoke the boot recovery function struct bregs br; memset(&br, 0, sizeof(br)); br.flags = F_IF; call16_int(0x18, &br); } int BootSequence VARLOW = -1; // Boot Failure recovery: try the next device. void VISIBLE32FLAT handle_18(void) { debug_enter(NULL, DEBUG_HDL_18); int seq = BootSequence + 1; BootSequence = seq; do_boot(seq); } // INT 19h Boot Load Service Entry Point void VISIBLE32FLAT handle_19(void) { debug_enter(NULL, DEBUG_HDL_19); BootSequence = 0; do_boot(0); }