src/boot.c - chromiumos/third_party/seabios - Git at Google

 // Code to load disk image and start system boot.
 //
 // Copyright (C) 2008-2010  Kevin O'Connor <kevin@koconnor.net>
 // Copyright (C) 2002  MandrakeSoft S.A.
 //
 // This file may be distributed under the terms of the GNU LGPLv3 license.

 #include "util.h" // dprintf
 #include "biosvar.h" // GET_EBDA
 #include "config.h" // CONFIG_*
 #include "disk.h" // cdrom_boot
 #include "bregs.h" // struct bregs
 #include "boot.h" // func defs
 #include "cmos.h" // inb_cmos
 #include "paravirt.h" // romfile_loadfile
 #include "pci.h" //pci_bdf_to_*


 /****************************************************************
  * Boot priority ordering
  ****************************************************************/

 static char **Bootorder;
 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(3, "boot order:\n");
     i = 0;
     do {
         Bootorder[i] = f;
         f = strchr(f, '\n');
         if (f)
             *(f++) = '\0';
         nullTrailingSpace(Bootorder[i]);
         dprintf(3, "%d: %s\n", i+1, Bootorder[i]);
         i++;
     } while (f);
 }

 // 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++;
     }
 }

 // 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;
 }

 #define FW_PCI_DOMAIN "/pci@i0cf8"

 static char *
 build_pci_path(char *buf, int max, const char *devname, int bdf)
 {
     // Build the string path of a bdf - for example: /pci@i0cf8/isa@1,2
     char *p = buf;
     int parent = pci_bdf_to_bus(bdf);
     if (PCIpaths)
         parent = PCIpaths[parent];
     int parentdev = parent & 0xffff;
     if (parent & PP_PCIBRIDGE) {
         p = build_pci_path(p, max, "pci-bridge", parentdev);
     } else {
         if (parentdev)
             p += snprintf(p, max, "/pci-root@%x", parentdev);
         p += snprintf(p, buf+max-p, "%s", FW_PCI_DOMAIN);
     }

     int dev = pci_bdf_to_dev(bdf), fn = pci_bdf_to_fn(bdf);
     p += snprintf(p, buf+max-p, "/%s@%x", devname, dev);
     if (fn)
         p += snprintf(p, buf+max-p, ",%x", fn);
     return p;
 }

 int bootprio_find_pci_device(int bdf)
 {
     if (!CONFIG_BOOTORDER)
         return -1;
     // Find pci device - for example: /pci@i0cf8/ethernet@5
     char desc[256];
     build_pci_path(desc, sizeof(desc), "*", bdf);
     return find_prio(desc);
 }

 int bootprio_find_ata_device(int bdf, int chanid, int slave)
 {
     if (!CONFIG_BOOTORDER)
         return -1;
     if (bdf == -1)
         // 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], *p;
     p = build_pci_path(desc, sizeof(desc), "*", bdf);
     snprintf(p, desc+sizeof(desc)-p, "/drive@%x/disk@%x", chanid, slave);
     return find_prio(desc);
 }

 int bootprio_find_fdc_device(int bdf, int port, int fdid)
 {
     if (!CONFIG_BOOTORDER)
         return -1;
     if (bdf == -1)
         // 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", bdf);
     snprintf(p, desc+sizeof(desc)-p, "/fdc@%04x/floppy@%x", port, fdid);
     return find_prio(desc);
 }

 int bootprio_find_pci_rom(int bdf, 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), "*", bdf);
     if (instance)
         snprintf(p, desc+sizeof(desc)-p, ":rom%d", 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%d", instance);
     return find_prio(desc);
 }

 int bootprio_find_usb(int bdf, u64 path)
 {
     if (!CONFIG_BOOTORDER)
         return -1;
     // Find usb - for example: /pci@i0cf8/usb@1,2/hub@1/network@0/ethernet@0
     int i;
     char desc[256], *p;
     p = build_pci_path(desc, sizeof(desc), "usb", bdf);
     for (i=56; i>0; i-=8) {
         int port = (path >> i) & 0xff;
         if (port != 0xff)
             p += snprintf(p, desc+sizeof(desc)-p, "/hub@%x", port);
     }
     snprintf(p, desc+sizeof(desc)-p, "/*@%x", (u32)(path & 0xff));
     return find_prio(desc);
 }


 /****************************************************************
  * Boot setup
  ****************************************************************/

 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_setup(void)
 {
     if (! CONFIG_BOOT)
         return;

     SET_EBDA(boot_sequence, 0xffff);

     if (!CONFIG_COREBOOT) {
         // On emulators, get boot order from nvram.
         if (inb_cmos(CMOS_BIOS_BOOTFLAG1) & 1)
             CheckFloppySig = 0;
         u32 bootorder = (inb_cmos(CMOS_BIOS_BOOTFLAG2)
                          | ((inb_cmos(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;
             }
         }
     }

     loadBootOrder();
 }


 /****************************************************************
  * BootList handling
  ****************************************************************/

 struct bootentry_s {
     int type;
     union {
         u32 data;
         struct segoff_s vector;
         struct drive_s *drive;
     };
     int priority;
     const char *description;
     struct bootentry_s *next;
 };
 static struct bootentry_s *BootList;

 #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

 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 bootentry_s **pprev;
     for (pprev = &BootList; *pprev; pprev = &(*pprev)->next) {
         struct bootentry_s *pos = *pprev;
         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;
     }
     be->next = *pprev;
     *pprev = be;
 }

 // 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, DEFAULT_PRIO)
                   , SEGOFF(seg, ip).segoff
                   , desc ? MAKE_FLATPTR(seg, desc) : "Legacy option rom");
 }

 void
 boot_add_floppy(struct drive_s *drive_g, const char *desc, int prio)
 {
     bootentry_add(IPL_TYPE_FLOPPY, defPrio(prio, DefaultFloppyPrio)
                   , (u32)drive_g, desc);
 }

 void
 boot_add_hd(struct drive_s *drive_g, const char *desc, int prio)
 {
     bootentry_add(IPL_TYPE_HARDDISK, defPrio(prio, DefaultHDPrio)
                   , (u32)drive_g, desc);
 }

 void
 boot_add_cd(struct drive_s *drive_g, const char *desc, int prio)
 {
     bootentry_add(IPL_TYPE_CDROM, defPrio(prio, DefaultCDPrio)
                   , (u32)drive_g, 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);
 }


 /****************************************************************
  * Boot menu and BCV execution
  ****************************************************************/

 // Show IPL option menu.
 static void
 interactive_bootmenu(void)
 {
     if (! CONFIG_BOOTMENU || ! qemu_cfg_show_boot_menu())
         return;

     while (get_keystroke(0) >= 0)
         ;

     printf("Press F12 for boot menu.\n\n");

     enable_bootsplash();
     int scan_code = get_keystroke(CONFIG_BOOTMENU_WAIT);
     disable_bootsplash();
     if (scan_code != 0x86)
         /* not F12 */
         return;

     while (get_keystroke(0) >= 0)
         ;

     printf("Select boot device:\n\n");
     wait_threads();

     // Show menu items
     struct bootentry_s *pos = BootList;
     int maxmenu = 0;
     while (pos) {
         char desc[60];
         maxmenu++;
         printf("%d. %s\n", maxmenu
                , strtcpy(desc, pos->description, ARRAY_SIZE(desc)));
         pos = pos->next;
     }

     // Get key press
     for (;;) {
         scan_code = get_keystroke(1000);
         if (scan_code >= 1 && scan_code <= maxmenu+1)
             break;
     }
     printf("\n");
     if (scan_code == 0x01)
         // ESC
         return;

     // Find entry and make top priority.
     int choice = scan_code - 1;
     struct bootentry_s **pprev = &BootList;
     while (--choice)
         pprev = &(*pprev)->next;
     pos = *pprev;
     *pprev = pos->next;
     pos->next = BootList;
     BootList = pos;
     pos->priority = 0;
 }

 // 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
 boot_prep(void)
 {
     if (! CONFIG_BOOT) {
         wait_threads();
         return;
     }

     // XXX - show available drives?

     // Allow user to modify BCV/IPL order.
     interactive_bootmenu();
     wait_threads();

     // Map drives and populate BEV list
     struct bootentry_s *pos = BootList;
     while (pos) {
         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;
         }
         pos = pos->next;
     }

     // 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;
     call16(&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;
         }
     }

     /* 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_g)
 {
     if (! CONFIG_CDROM_BOOT)
         return;
     printf("Booting from DVD/CD...\n");

     int status = cdrom_boot(drive_g);
     if (status) {
         printf("Boot failed: Could not read from CDROM (code %04x)\n", status);
         return;
     }

     u16 ebda_seg = get_ebda_seg();
     u8 bootdrv = GET_EBDA2(ebda_seg, cdemu.emulated_extdrive);
     u16 bootseg = GET_EBDA2(ebda_seg, cdemu.load_segment);
     /* 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 || !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);
 }

 // Determine next boot method and attempt a boot using it.
 static void
 do_boot(u16 seq_nr)
 {
     if (! CONFIG_BOOT)
         panic("Boot support not compiled in.\n");

     if (seq_nr >= BEVCount) {
         printf("No bootable device.\n");
         // Loop with irqs enabled - this allows ctrl+alt+delete to work.
         for (;;)
             wait_irq();
     }

     // 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;
     }

     // Boot failed: invoke the boot recovery function
     struct bregs br;
     memset(&br, 0, sizeof(br));
     br.flags = F_IF;
     call16_int(0x18, &br);
 }

 // Boot Failure recovery: try the next device.
 void VISIBLE32FLAT
 handle_18(void)
 {
     debug_serial_setup();
     debug_enter(NULL, DEBUG_HDL_18);
     u16 ebda_seg = get_ebda_seg();
     u16 seq = GET_EBDA2(ebda_seg, boot_sequence) + 1;
     SET_EBDA2(ebda_seg, boot_sequence, seq);
     do_boot(seq);
 }

 // INT 19h Boot Load Service Entry Point
 void VISIBLE32FLAT
 handle_19(void)
 {
     debug_serial_setup();
     debug_enter(NULL, DEBUG_HDL_19);
     SET_EBDA(boot_sequence, 0);
     do_boot(0);
 }
	// Code to load disk image and start system boot.
	//
	// Copyright (C) 2008-2010 Kevin O'Connor <kevin@koconnor.net>
	// Copyright (C) 2002 MandrakeSoft S.A.
	//
	// This file may be distributed under the terms of the GNU LGPLv3 license.

	#include "util.h" // dprintf
	#include "biosvar.h" // GET_EBDA
	#include "config.h" // CONFIG_*
	#include "disk.h" // cdrom_boot
	#include "bregs.h" // struct bregs
	#include "boot.h" // func defs
	#include "cmos.h" // inb_cmos
	#include "paravirt.h" // romfile_loadfile
	#include "pci.h" //pci_bdf_to_*


	/****************************************************************
	* Boot priority ordering
	****************************************************************/

	static char **Bootorder;
	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(BootorderCountsizeof(char));
	if (!Bootorder) {
	warn_noalloc();
	free(f);
	BootorderCount = 0;
	return;
	}

	dprintf(3, "boot order:\n");
	i = 0;
	do {
	Bootorder[i] = f;
	f = strchr(f, '\n');
	if (f)
	*(f++) = '\0';
	nullTrailingSpace(Bootorder[i]);
	dprintf(3, "%d: %s\n", i+1, Bootorder[i]);
	i++;
	} while (f);
	}

	// 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++;
	}
	}

	// 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;
	}

	#define FW_PCI_DOMAIN "/pci@i0cf8"

	static char *
	build_pci_path(char buf, int max, const char devname, int bdf)
	{
	// Build the string path of a bdf - for example: /pci@i0cf8/isa@1,2
	char *p = buf;
	int parent = pci_bdf_to_bus(bdf);
	if (PCIpaths)
	parent = PCIpaths[parent];
	int parentdev = parent & 0xffff;
	if (parent & PP_PCIBRIDGE) {
	p = build_pci_path(p, max, "pci-bridge", parentdev);
	} else {
	if (parentdev)
	p += snprintf(p, max, "/pci-root@%x", parentdev);
	p += snprintf(p, buf+max-p, "%s", FW_PCI_DOMAIN);
	}

	int dev = pci_bdf_to_dev(bdf), fn = pci_bdf_to_fn(bdf);
	p += snprintf(p, buf+max-p, "/%s@%x", devname, dev);
	if (fn)
	p += snprintf(p, buf+max-p, ",%x", fn);
	return p;
	}

	int bootprio_find_pci_device(int bdf)
	{
	if (!CONFIG_BOOTORDER)
	return -1;
	// Find pci device - for example: /pci@i0cf8/ethernet@5
	char desc[256];
	build_pci_path(desc, sizeof(desc), "*", bdf);
	return find_prio(desc);
	}

	int bootprio_find_ata_device(int bdf, int chanid, int slave)
	{
	if (!CONFIG_BOOTORDER)
	return -1;
	if (bdf == -1)
	// 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], *p;
	p = build_pci_path(desc, sizeof(desc), "*", bdf);
	snprintf(p, desc+sizeof(desc)-p, "/drive@%x/disk@%x", chanid, slave);
	return find_prio(desc);
	}

	int bootprio_find_fdc_device(int bdf, int port, int fdid)
	{
	if (!CONFIG_BOOTORDER)
	return -1;
	if (bdf == -1)
	// 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", bdf);
	snprintf(p, desc+sizeof(desc)-p, "/fdc@%04x/floppy@%x", port, fdid);
	return find_prio(desc);
	}

	int bootprio_find_pci_rom(int bdf, 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), "*", bdf);
	if (instance)
	snprintf(p, desc+sizeof(desc)-p, ":rom%d", 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%d", instance);
	return find_prio(desc);
	}

	int bootprio_find_usb(int bdf, u64 path)
	{
	if (!CONFIG_BOOTORDER)
	return -1;
	// Find usb - for example: /pci@i0cf8/usb@1,2/hub@1/network@0/ethernet@0
	int i;
	char desc[256], *p;
	p = build_pci_path(desc, sizeof(desc), "usb", bdf);
	for (i=56; i>0; i-=8) {
	int port = (path >> i) & 0xff;
	if (port != 0xff)
	p += snprintf(p, desc+sizeof(desc)-p, "/hub@%x", port);
	}
	snprintf(p, desc+sizeof(desc)-p, "/*@%x", (u32)(path & 0xff));
	return find_prio(desc);
	}


	/****************************************************************
	* Boot setup
	****************************************************************/

	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_setup(void)
	{
	if (! CONFIG_BOOT)
	return;

	SET_EBDA(boot_sequence, 0xffff);

	if (!CONFIG_COREBOOT) {
	// On emulators, get boot order from nvram.
	if (inb_cmos(CMOS_BIOS_BOOTFLAG1) & 1)
	CheckFloppySig = 0;
	u32 bootorder = (inb_cmos(CMOS_BIOS_BOOTFLAG2)
	\| ((inb_cmos(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;
	}
	}
	}

	loadBootOrder();
	}


	/****************************************************************
	* BootList handling
	****************************************************************/

	struct bootentry_s {
	int type;
	union {
	u32 data;
	struct segoff_s vector;
	struct drive_s *drive;
	};
	int priority;
	const char *description;
	struct bootentry_s *next;
	};
	static struct bootentry_s *BootList;

	#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

	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 bootentry_s **pprev;
	for (pprev = &BootList; pprev; pprev = &(pprev)->next) {
	struct bootentry_s pos = pprev;
	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;
	}
	be->next = *pprev;
	*pprev = be;
	}

	// 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, DEFAULT_PRIO)
	, SEGOFF(seg, ip).segoff
	, desc ? MAKE_FLATPTR(seg, desc) : "Legacy option rom");
	}

	void
	boot_add_floppy(struct drive_s drive_g, const char desc, int prio)
	{
	bootentry_add(IPL_TYPE_FLOPPY, defPrio(prio, DefaultFloppyPrio)
	, (u32)drive_g, desc);
	}

	void
	boot_add_hd(struct drive_s drive_g, const char desc, int prio)
	{
	bootentry_add(IPL_TYPE_HARDDISK, defPrio(prio, DefaultHDPrio)
	, (u32)drive_g, desc);
	}

	void
	boot_add_cd(struct drive_s drive_g, const char desc, int prio)
	{
	bootentry_add(IPL_TYPE_CDROM, defPrio(prio, DefaultCDPrio)
	, (u32)drive_g, 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);
	}


	/****************************************************************
	* Boot menu and BCV execution
	****************************************************************/

	// Show IPL option menu.
	static void
	interactive_bootmenu(void)
	{
	if (! CONFIG_BOOTMENU \|\| ! qemu_cfg_show_boot_menu())
	return;

	while (get_keystroke(0) >= 0)
	;

	printf("Press F12 for boot menu.\n\n");

	enable_bootsplash();
	int scan_code = get_keystroke(CONFIG_BOOTMENU_WAIT);
	disable_bootsplash();
	if (scan_code != 0x86)
	/* not F12 */
	return;

	while (get_keystroke(0) >= 0)
	;

	printf("Select boot device:\n\n");
	wait_threads();

	// Show menu items
	struct bootentry_s *pos = BootList;
	int maxmenu = 0;
	while (pos) {
	char desc[60];
	maxmenu++;
	printf("%d. %s\n", maxmenu
	, strtcpy(desc, pos->description, ARRAY_SIZE(desc)));
	pos = pos->next;
	}

	// Get key press
	for (;;) {
	scan_code = get_keystroke(1000);
	if (scan_code >= 1 && scan_code <= maxmenu+1)
	break;
	}
	printf("\n");
	if (scan_code == 0x01)
	// ESC
	return;

	// Find entry and make top priority.
	int choice = scan_code - 1;
	struct bootentry_s **pprev = &BootList;
	while (--choice)
	pprev = &(*pprev)->next;
	pos = *pprev;
	*pprev = pos->next;
	pos->next = BootList;
	BootList = pos;
	pos->priority = 0;
	}

	// 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
	boot_prep(void)
	{
	if (! CONFIG_BOOT) {
	wait_threads();
	return;
	}

	// XXX - show available drives?

	// Allow user to modify BCV/IPL order.
	interactive_bootmenu();
	wait_threads();

	// Map drives and populate BEV list
	struct bootentry_s *pos = BootList;
	while (pos) {
	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;
	}
	pos = pos->next;
	}

	// 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;
	call16(&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;
	}
	}

	/* 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_g)
	{
	if (! CONFIG_CDROM_BOOT)
	return;
	printf("Booting from DVD/CD...\n");

	int status = cdrom_boot(drive_g);
	if (status) {
	printf("Boot failed: Could not read from CDROM (code %04x)\n", status);
	return;
	}

	u16 ebda_seg = get_ebda_seg();
	u8 bootdrv = GET_EBDA2(ebda_seg, cdemu.emulated_extdrive);
	u16 bootseg = GET_EBDA2(ebda_seg, cdemu.load_segment);
	/* 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 \|\| !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);
	}

	// Determine next boot method and attempt a boot using it.
	static void
	do_boot(u16 seq_nr)
	{
	if (! CONFIG_BOOT)
	panic("Boot support not compiled in.\n");

	if (seq_nr >= BEVCount) {
	printf("No bootable device.\n");
	// Loop with irqs enabled - this allows ctrl+alt+delete to work.
	for (;;)
	wait_irq();
	}

	// 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;
	}

	// Boot failed: invoke the boot recovery function
	struct bregs br;
	memset(&br, 0, sizeof(br));
	br.flags = F_IF;
	call16_int(0x18, &br);
	}

	// Boot Failure recovery: try the next device.
	void VISIBLE32FLAT
	handle_18(void)
	{
	debug_serial_setup();
	debug_enter(NULL, DEBUG_HDL_18);
	u16 ebda_seg = get_ebda_seg();
	u16 seq = GET_EBDA2(ebda_seg, boot_sequence) + 1;
	SET_EBDA2(ebda_seg, boot_sequence, seq);
	do_boot(seq);
	}

	// INT 19h Boot Load Service Entry Point
	void VISIBLE32FLAT
	handle_19(void)
	{
	debug_serial_setup();
	debug_enter(NULL, DEBUG_HDL_19);
	SET_EBDA(boot_sequence, 0);
	do_boot(0);
	}