src/cdrom.c - seabios - Gitiles

 // 16bit code to access cdrom drives.
 //
 // Copyright (C) 2008  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 "disk.h" // cdrom_13
 #include "util.h" // memset
 #include "bregs.h" // struct bregs
 #include "biosvar.h" // GET_EBDA
 #include "atabits.h" // ATA_TYPE_ATAPI


 /****************************************************************
  * CDROM functions
  ****************************************************************/

 // read disk drive size
 static void
 cdrom_1315(struct bregs *regs, u8 device)
 {
     disk_ret(regs, DISK_RET_EADDRNOTFOUND);
 }

 // lock
 static void
 cdrom_134500(struct bregs *regs, u8 device)
 {
     u16 ebda_seg = get_ebda_seg();
     u8 locks = GET_EBDA2(ebda_seg, cdrom_locks[device]);
     if (locks == 0xff) {
         regs->al = 1;
         disk_ret(regs, DISK_RET_ETOOMANYLOCKS);
         return;
     }
     SET_EBDA2(ebda_seg, cdrom_locks[device], locks + 1);
     regs->al = 1;
     disk_ret(regs, DISK_RET_SUCCESS);
 }

 // unlock
 static void
 cdrom_134501(struct bregs *regs, u8 device)
 {
     u16 ebda_seg = get_ebda_seg();
     u8 locks = GET_EBDA2(ebda_seg, cdrom_locks[device]);
     if (locks == 0x00) {
         regs->al = 0;
         disk_ret(regs, DISK_RET_ENOTLOCKED);
         return;
     }
     locks--;
     SET_EBDA2(ebda_seg, cdrom_locks[device], locks);
     regs->al = (locks ? 1 : 0);
     disk_ret(regs, DISK_RET_SUCCESS);
 }

 // status
 static void
 cdrom_134502(struct bregs *regs, u8 device)
 {
     u8 locks = GET_EBDA(cdrom_locks[device]);
     regs->al = (locks ? 1 : 0);
     disk_ret(regs, DISK_RET_SUCCESS);
 }

 static void
 cdrom_1345XX(struct bregs *regs, u8 device)
 {
     disk_ret(regs, DISK_RET_EPARAM);
 }

 // IBM/MS lock/unlock drive
 static void
 cdrom_1345(struct bregs *regs, u8 device)
 {
     switch (regs->al) {
     case 0x00: cdrom_134500(regs, device); break;
     case 0x01: cdrom_134501(regs, device); break;
     case 0x02: cdrom_134502(regs, device); break;
     default:   cdrom_1345XX(regs, device); break;
     }
 }

 // IBM/MS eject media
 static void
 cdrom_1346(struct bregs *regs, u8 device)
 {
     u8 locks = GET_EBDA(cdrom_locks[device]);
     if (locks != 0) {
         disk_ret(regs, DISK_RET_ELOCKED);
         return;
     }

     // FIXME should handle 0x31 no media in device
     // FIXME should handle 0xb5 valid request failed

     // Call removable media eject
     struct bregs br;
     memset(&br, 0, sizeof(br));
     br.ah = 0x52;
     call16_int(0x15, &br);

     if (br.ah || br.flags & F_CF) {
         disk_ret(regs, DISK_RET_ELOCKED);
         return;
     }
     disk_ret(regs, DISK_RET_SUCCESS);
 }

 // IBM/MS extended media change
 static void
 cdrom_1349(struct bregs *regs, u8 device)
 {
     set_fail(regs);
     // always send changed ??
     regs->ah = DISK_RET_ECHANGED;
 }

 static void
 cdrom_ok(struct bregs *regs, u8 device)
 {
     disk_ret(regs, DISK_RET_SUCCESS);
 }

 static void
 cdrom_wp(struct bregs *regs, u8 device)
 {
     disk_ret(regs, DISK_RET_EWRITEPROTECT);
 }

 void
 cdrom_13(struct bregs *regs, u8 device)
 {
     //debug_stub(regs);

     switch (regs->ah) {
     case 0x15: cdrom_1315(regs, device); break;
     case 0x45: cdrom_1345(regs, device); break;
     case 0x46: cdrom_1346(regs, device); break;
     case 0x49: cdrom_1349(regs, device); break;

     // These functions are the same as for hard disks
     case 0x01:
     case 0x41:
     case 0x42:
     case 0x44:
     case 0x47:
     case 0x48:
     case 0x4e:
         disk_13(regs, device);
         break;

     // all these functions return SUCCESS
     case 0x00: // disk controller reset
     case 0x09: // initialize drive parameters
     case 0x0c: // seek to specified cylinder
     case 0x0d: // alternate disk reset
     case 0x10: // check drive ready
     case 0x11: // recalibrate
     case 0x14: // controller internal diagnostic
     case 0x16: // detect disk change
         cdrom_ok(regs, device);
         break;

     // all these functions return disk write-protected
     case 0x03: // write disk sectors
     case 0x05: // format disk track
     case 0x43: // IBM/MS extended write
         cdrom_wp(regs, device);
         break;

     default:   disk_13XX(regs, device); break;
     }
 }


 /****************************************************************
  * CD emulation
  ****************************************************************/

 static void
 cdemu_1302(struct bregs *regs, u8 device)
 {
     cdemu_access(regs, device, ATA_CMD_READ_SECTORS);
 }

 static void
 cdemu_1304(struct bregs *regs, u8 device)
 {
     cdemu_access(regs, device, 0);
 }

 // read disk drive parameters
 static void
 cdemu_1308(struct bregs *regs, u8 device)
 {
     u16 ebda_seg = get_ebda_seg();
     u16 nlc   = GET_EBDA2(ebda_seg, cdemu.cylinders) - 1;
     u16 nlh   = GET_EBDA2(ebda_seg, cdemu.heads) - 1;
     u16 nlspt = GET_EBDA2(ebda_seg, cdemu.spt);

     regs->al = 0x00;
     regs->bl = 0x00;
     regs->ch = nlc & 0xff;
     regs->cl = ((nlc >> 2) & 0xc0) | (nlspt & 0x3f);
     regs->dh = nlh;
     // FIXME ElTorito Various. should send the real count of drives 1 or 2
     // FIXME ElTorito Harddisk. should send the HD count
     regs->dl = 0x02;
     u8 media = GET_EBDA2(ebda_seg, cdemu.media);
     if (media <= 3)
         regs->bl = media * 2;

     regs->es = SEG_BIOS;
     regs->di = (u32)&diskette_param_table2;

     disk_ret(regs, DISK_RET_SUCCESS);
 }

 void
 cdemu_13(struct bregs *regs)
 {
     //debug_stub(regs);

     u16 ebda_seg = get_ebda_seg();
     u8 device  = GET_EBDA2(ebda_seg, cdemu.controller_index) * 2;
     device += GET_EBDA2(ebda_seg, cdemu.device_spec);

     switch (regs->ah) {
     case 0x02: cdemu_1302(regs, device); break;
     case 0x04: cdemu_1304(regs, device); break;
     case 0x08: cdemu_1308(regs, device); break;

     // These functions are the same as standard CDROM.
     case 0x00:
     case 0x01:
     case 0x03:
     case 0x05:
     case 0x09:
     case 0x0c:
     case 0x0d:
     case 0x10:
     case 0x11:
     case 0x14:
     case 0x15:
     case 0x16:
         cdrom_13(regs, device);
         break;

     default:   disk_13XX(regs, device); break;
     }
 }

 struct eltorito_s {
     u8 size;
     u8 media;
     u8 emulated_drive;
     u8 controller_index;
     u32 ilba;
     u16 device_spec;
     u16 buffer_segment;
     u16 load_segment;
     u16 sector_count;
     u8 cylinders;
     u8 sectors;
     u8 heads;
 };

 #define SET_INT13ET(regs,var,val)                                      \
     SET_FARVAR((regs)->ds, ((struct eltorito_s*)((regs)->si+0))->var, (val))

 // ElTorito - Terminate disk emu
 void
 cdemu_134b(struct bregs *regs)
 {
     // FIXME ElTorito Hardcoded
     u16 ebda_seg = get_ebda_seg();
     SET_INT13ET(regs, size, 0x13);
     SET_INT13ET(regs, media, GET_EBDA2(ebda_seg, cdemu.media));
     SET_INT13ET(regs, emulated_drive, GET_EBDA2(ebda_seg, cdemu.emulated_drive));
     SET_INT13ET(regs, controller_index
                 , GET_EBDA2(ebda_seg, cdemu.controller_index));
     SET_INT13ET(regs, ilba, GET_EBDA2(ebda_seg, cdemu.ilba));
     SET_INT13ET(regs, device_spec, GET_EBDA2(ebda_seg, cdemu.device_spec));
     SET_INT13ET(regs, buffer_segment, GET_EBDA2(ebda_seg, cdemu.buffer_segment));
     SET_INT13ET(regs, load_segment, GET_EBDA2(ebda_seg, cdemu.load_segment));
     SET_INT13ET(regs, sector_count, GET_EBDA2(ebda_seg, cdemu.sector_count));
     SET_INT13ET(regs, cylinders, GET_EBDA2(ebda_seg, cdemu.cylinders));
     SET_INT13ET(regs, sectors, GET_EBDA2(ebda_seg, cdemu.spt));
     SET_INT13ET(regs, heads, GET_EBDA2(ebda_seg, cdemu.heads));

     // If we have to terminate emulation
     if (regs->al == 0x00) {
         // FIXME ElTorito Various. Should be handled accordingly to spec
         SET_EBDA2(ebda_seg, cdemu.active, 0x00); // bye bye
     }

     disk_ret(regs, DISK_RET_SUCCESS);
 }


 /****************************************************************
  * CD booting
  ****************************************************************/

 // Request SENSE
 static int
 atapi_get_sense(int device, u8 *asc, u8 *ascq)
 {
     u8 atacmd[12], buffer[18];
     memset(atacmd, 0, sizeof(atacmd));
     atacmd[0] = ATA_CMD_REQUEST_SENSE;
     atacmd[4] = sizeof(buffer);
     int ret = ata_cmd_packet(device, atacmd, sizeof(atacmd), sizeof(buffer)
                              , MAKE_FLATPTR(GET_SEG(SS), buffer));
     if (ret)
         return ret;

     *asc = buffer[12];
     *ascq = buffer[13];

     return 0;
 }

 // Request capacity
 static int
 atapi_read_capacity(int device, u32 *blksize, u32 *sectors)
 {
     u8 packet[12], buf[8];
     memset(packet, 0, sizeof(packet));
     packet[0] = 0x25; /* READ CAPACITY */
     int ret = ata_cmd_packet(device, packet, sizeof(packet), sizeof(buf)
                              , MAKE_FLATPTR(GET_SEG(SS), buf));
     if (ret)
         return ret;

     *blksize = (((u32)buf[4] << 24) | ((u32)buf[5] << 16)
                 | ((u32)buf[6] << 8) | ((u32)buf[7] << 0));
     *sectors = (((u32)buf[0] << 24) | ((u32)buf[1] << 16)
                 | ((u32)buf[2] << 8) | ((u32)buf[3] << 0));

     return 0;
 }

 static int
 atapi_is_ready(u16 device)
 {
     dprintf(6, "atapi_is_ready (device=%d)\n", device);

     /* Retry READ CAPACITY for 5 seconds unless MEDIUM NOT PRESENT is
      * reported by the device.  If the device reports "IN PROGRESS",
      * 30 seconds is added. */
     u32 blksize, sectors;
     int in_progress = 0;
     u64 end = calc_future_tsc(5000);
     for (;;) {
         if (rdtscll() > end) {
             dprintf(1, "read capacity failed\n");
             return -1;
         }

         int ret = atapi_read_capacity(device, &blksize, &sectors);
         if (!ret)
             // Success
             break;

         u8 asc, ascq;
         ret = atapi_get_sense(device, &asc, &ascq);
         if (ret)
             // Error - retry.
             continue;

         // Sense succeeded.
         if (asc == 0x3a) { /* MEDIUM NOT PRESENT */
             dprintf(1, "Device reports MEDIUM NOT PRESENT\n");
             return -1;
         }

         if (asc == 0x04 && ascq == 0x01 && !in_progress) {
             /* IN PROGRESS OF BECOMING READY */
             printf("Waiting for device to detect medium... ");
             /* Allow 30 seconds more */
             end = calc_future_tsc(30000);
             in_progress = 1;
         }
     }

     if (blksize != GET_GLOBAL(ATA.devices[device].blksize)) {
         printf("Unsupported sector size %u\n", blksize);
         return -1;
     }

     dprintf(6, "sectors=%u\n", sectors);
     printf("%dMB medium detected\n", sectors>>(20-11));
     return 0;
 }

 int
 cdrom_boot(int cdid)
 {
     // Verify device is a cdrom.
     if (cdid >= ATA.cdcount)
         return 1;
     int driveid = GET_GLOBAL(ATA.idmap[1][cdid]);
     if (GET_GLOBAL(ATA.devices[driveid].device) != ATA_DEVICE_CDROM)
         return 2;

     int ret = atapi_is_ready(driveid);
     if (ret)
         dprintf(1, "atapi_is_ready returned %d\n", ret);

     // Read the Boot Record Volume Descriptor
     u8 buffer[2048];
     struct disk_op_s dop;
     dop.driveid = driveid;
     dop.lba = 0x11;
     dop.count = 1;
     dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
     ret = cdrom_read(&dop);
     if (ret)
         return 3;

     // Validity checks
     if (buffer[0])
         return 4;
     if (strcmp((char*)&buffer[1], "CD001\001EL TORITO SPECIFICATION") != 0)
         return 5;

     // ok, now we calculate the Boot catalog address
     u32 lba = *(u32*)&buffer[0x47];

     // And we read the Boot Catalog
     dop.lba = lba;
     ret = cdrom_read(&dop);
     if (ret)
         return 7;

     // Validation entry
     if (buffer[0x00] != 0x01)
         return 8;   // Header
     if (buffer[0x01] != 0x00)
         return 9;   // Platform
     if (buffer[0x1E] != 0x55)
         return 10;  // key 1
     if (buffer[0x1F] != 0xAA)
         return 10;  // key 2

     // Initial/Default Entry
     if (buffer[0x20] != 0x88)
         return 11; // Bootable

     u16 ebda_seg = get_ebda_seg();
     u8 media = buffer[0x21];
     SET_EBDA2(ebda_seg, cdemu.media, media);

     SET_EBDA2(ebda_seg, cdemu.controller_index, driveid/2);
     SET_EBDA2(ebda_seg, cdemu.device_spec, driveid%2);

     u16 boot_segment = *(u16*)&buffer[0x22];
     if (!boot_segment)
         boot_segment = 0x07C0;
     SET_EBDA2(ebda_seg, cdemu.load_segment, boot_segment);
     SET_EBDA2(ebda_seg, cdemu.buffer_segment, 0x0000);

     u16 nbsectors = *(u16*)&buffer[0x26];
     SET_EBDA2(ebda_seg, cdemu.sector_count, nbsectors);

     lba = *(u32*)&buffer[0x28];
     SET_EBDA2(ebda_seg, cdemu.ilba, lba);

     // And we read the image in memory
     dop.lba = lba;
     dop.count = DIV_ROUND_UP(nbsectors, 4);
     dop.buf_fl = MAKE_FLATPTR(boot_segment, 0);
     ret = cdrom_read(&dop);
     if (ret)
         return 12;

     if (media == 0) {
         // No emulation requested - return success.
         SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0xE0 + cdid);
         return 0;
     }

     // Emulation of a floppy/harddisk requested
     if (! CONFIG_CDROM_EMU)
         return 13;

     // Set emulated drive id and increase bios installed hardware
     // number of devices
     if (media < 4) {
         // Floppy emulation
         SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0x00);
         SETBITS_BDA(equipment_list_flags, 0x41);

         switch (media) {
         case 0x01:  // 1.2M floppy
             SET_EBDA2(ebda_seg, cdemu.spt, 15);
             SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
             SET_EBDA2(ebda_seg, cdemu.heads, 2);
             break;
         case 0x02:  // 1.44M floppy
             SET_EBDA2(ebda_seg, cdemu.spt, 18);
             SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
             SET_EBDA2(ebda_seg, cdemu.heads, 2);
             break;
         case 0x03:  // 2.88M floppy
             SET_EBDA2(ebda_seg, cdemu.spt, 36);
             SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
             SET_EBDA2(ebda_seg, cdemu.heads, 2);
             break;
         }
     } else {
         // Harddrive emulation
         SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0x80);
         SET_BDA(hdcount, GET_BDA(hdcount) + 1);

         // Peak at partition table to get chs.
         struct mbr_s *mbr = (void*)0;
         u8 sptcyl = GET_FARVAR(boot_segment, mbr->partitions[0].last.sptcyl);
         u8 cyllow = GET_FARVAR(boot_segment, mbr->partitions[0].last.cyllow);
         u8 heads = GET_FARVAR(boot_segment, mbr->partitions[0].last.heads);

         SET_EBDA2(ebda_seg, cdemu.spt, sptcyl & 0x3f);
         SET_EBDA2(ebda_seg, cdemu.cylinders, ((sptcyl<<2)&0x300) + cyllow + 1);
         SET_EBDA2(ebda_seg, cdemu.heads, heads + 1);
     }

     // everything is ok, so from now on, the emulation is active
     SET_EBDA2(ebda_seg, cdemu.active, 0x01);
     dprintf(6, "cdemu media=%d\n", media);

     return 0;
 }
	// 16bit code to access cdrom drives.
	//
	// Copyright (C) 2008 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 "disk.h" // cdrom_13
	#include "util.h" // memset
	#include "bregs.h" // struct bregs
	#include "biosvar.h" // GET_EBDA
	#include "atabits.h" // ATA_TYPE_ATAPI


	/****************************************************************
	* CDROM functions
	****************************************************************/

	// read disk drive size
	static void
	cdrom_1315(struct bregs *regs, u8 device)
	{
	disk_ret(regs, DISK_RET_EADDRNOTFOUND);
	}

	// lock
	static void
	cdrom_134500(struct bregs *regs, u8 device)
	{
	u16 ebda_seg = get_ebda_seg();
	u8 locks = GET_EBDA2(ebda_seg, cdrom_locks[device]);
	if (locks == 0xff) {
	regs->al = 1;
	disk_ret(regs, DISK_RET_ETOOMANYLOCKS);
	return;
	}
	SET_EBDA2(ebda_seg, cdrom_locks[device], locks + 1);
	regs->al = 1;
	disk_ret(regs, DISK_RET_SUCCESS);
	}

	// unlock
	static void
	cdrom_134501(struct bregs *regs, u8 device)
	{
	u16 ebda_seg = get_ebda_seg();
	u8 locks = GET_EBDA2(ebda_seg, cdrom_locks[device]);
	if (locks == 0x00) {
	regs->al = 0;
	disk_ret(regs, DISK_RET_ENOTLOCKED);
	return;
	}
	locks--;
	SET_EBDA2(ebda_seg, cdrom_locks[device], locks);
	regs->al = (locks ? 1 : 0);
	disk_ret(regs, DISK_RET_SUCCESS);
	}

	// status
	static void
	cdrom_134502(struct bregs *regs, u8 device)
	{
	u8 locks = GET_EBDA(cdrom_locks[device]);
	regs->al = (locks ? 1 : 0);
	disk_ret(regs, DISK_RET_SUCCESS);
	}

	static void
	cdrom_1345XX(struct bregs *regs, u8 device)
	{
	disk_ret(regs, DISK_RET_EPARAM);
	}

	// IBM/MS lock/unlock drive
	static void
	cdrom_1345(struct bregs *regs, u8 device)
	{
	switch (regs->al) {
	case 0x00: cdrom_134500(regs, device); break;
	case 0x01: cdrom_134501(regs, device); break;
	case 0x02: cdrom_134502(regs, device); break;
	default: cdrom_1345XX(regs, device); break;
	}
	}

	// IBM/MS eject media
	static void
	cdrom_1346(struct bregs *regs, u8 device)
	{
	u8 locks = GET_EBDA(cdrom_locks[device]);
	if (locks != 0) {
	disk_ret(regs, DISK_RET_ELOCKED);
	return;
	}

	// FIXME should handle 0x31 no media in device
	// FIXME should handle 0xb5 valid request failed

	// Call removable media eject
	struct bregs br;
	memset(&br, 0, sizeof(br));
	br.ah = 0x52;
	call16_int(0x15, &br);

	if (br.ah \|\| br.flags & F_CF) {
	disk_ret(regs, DISK_RET_ELOCKED);
	return;
	}
	disk_ret(regs, DISK_RET_SUCCESS);
	}

	// IBM/MS extended media change
	static void
	cdrom_1349(struct bregs *regs, u8 device)
	{
	set_fail(regs);
	// always send changed ??
	regs->ah = DISK_RET_ECHANGED;
	}

	static void
	cdrom_ok(struct bregs *regs, u8 device)
	{
	disk_ret(regs, DISK_RET_SUCCESS);
	}

	static void
	cdrom_wp(struct bregs *regs, u8 device)
	{
	disk_ret(regs, DISK_RET_EWRITEPROTECT);
	}

	void
	cdrom_13(struct bregs *regs, u8 device)
	{
	//debug_stub(regs);

	switch (regs->ah) {
	case 0x15: cdrom_1315(regs, device); break;
	case 0x45: cdrom_1345(regs, device); break;
	case 0x46: cdrom_1346(regs, device); break;
	case 0x49: cdrom_1349(regs, device); break;

	// These functions are the same as for hard disks
	case 0x01:
	case 0x41:
	case 0x42:
	case 0x44:
	case 0x47:
	case 0x48:
	case 0x4e:
	disk_13(regs, device);
	break;

	// all these functions return SUCCESS
	case 0x00: // disk controller reset
	case 0x09: // initialize drive parameters
	case 0x0c: // seek to specified cylinder
	case 0x0d: // alternate disk reset
	case 0x10: // check drive ready
	case 0x11: // recalibrate
	case 0x14: // controller internal diagnostic
	case 0x16: // detect disk change
	cdrom_ok(regs, device);
	break;

	// all these functions return disk write-protected
	case 0x03: // write disk sectors
	case 0x05: // format disk track
	case 0x43: // IBM/MS extended write
	cdrom_wp(regs, device);
	break;

	default: disk_13XX(regs, device); break;
	}
	}


	/****************************************************************
	* CD emulation
	****************************************************************/

	static void
	cdemu_1302(struct bregs *regs, u8 device)
	{
	cdemu_access(regs, device, ATA_CMD_READ_SECTORS);
	}

	static void
	cdemu_1304(struct bregs *regs, u8 device)
	{
	cdemu_access(regs, device, 0);
	}

	// read disk drive parameters
	static void
	cdemu_1308(struct bregs *regs, u8 device)
	{
	u16 ebda_seg = get_ebda_seg();
	u16 nlc = GET_EBDA2(ebda_seg, cdemu.cylinders) - 1;
	u16 nlh = GET_EBDA2(ebda_seg, cdemu.heads) - 1;
	u16 nlspt = GET_EBDA2(ebda_seg, cdemu.spt);

	regs->al = 0x00;
	regs->bl = 0x00;
	regs->ch = nlc & 0xff;
	regs->cl = ((nlc >> 2) & 0xc0) \| (nlspt & 0x3f);
	regs->dh = nlh;
	// FIXME ElTorito Various. should send the real count of drives 1 or 2
	// FIXME ElTorito Harddisk. should send the HD count
	regs->dl = 0x02;
	u8 media = GET_EBDA2(ebda_seg, cdemu.media);
	if (media <= 3)
	regs->bl = media * 2;

	regs->es = SEG_BIOS;
	regs->di = (u32)&diskette_param_table2;

	disk_ret(regs, DISK_RET_SUCCESS);
	}

	void
	cdemu_13(struct bregs *regs)
	{
	//debug_stub(regs);

	u16 ebda_seg = get_ebda_seg();
	u8 device = GET_EBDA2(ebda_seg, cdemu.controller_index) * 2;
	device += GET_EBDA2(ebda_seg, cdemu.device_spec);

	switch (regs->ah) {
	case 0x02: cdemu_1302(regs, device); break;
	case 0x04: cdemu_1304(regs, device); break;
	case 0x08: cdemu_1308(regs, device); break;

	// These functions are the same as standard CDROM.
	case 0x00:
	case 0x01:
	case 0x03:
	case 0x05:
	case 0x09:
	case 0x0c:
	case 0x0d:
	case 0x10:
	case 0x11:
	case 0x14:
	case 0x15:
	case 0x16:
	cdrom_13(regs, device);
	break;

	default: disk_13XX(regs, device); break;
	}
	}

	struct eltorito_s {
	u8 size;
	u8 media;
	u8 emulated_drive;
	u8 controller_index;
	u32 ilba;
	u16 device_spec;
	u16 buffer_segment;
	u16 load_segment;
	u16 sector_count;
	u8 cylinders;
	u8 sectors;
	u8 heads;
	};

	#define SET_INT13ET(regs,var,val) \
	SET_FARVAR((regs)->ds, ((struct eltorito_s*)((regs)->si+0))->var, (val))

	// ElTorito - Terminate disk emu
	void
	cdemu_134b(struct bregs *regs)
	{
	// FIXME ElTorito Hardcoded
	u16 ebda_seg = get_ebda_seg();
	SET_INT13ET(regs, size, 0x13);
	SET_INT13ET(regs, media, GET_EBDA2(ebda_seg, cdemu.media));
	SET_INT13ET(regs, emulated_drive, GET_EBDA2(ebda_seg, cdemu.emulated_drive));
	SET_INT13ET(regs, controller_index
	, GET_EBDA2(ebda_seg, cdemu.controller_index));
	SET_INT13ET(regs, ilba, GET_EBDA2(ebda_seg, cdemu.ilba));
	SET_INT13ET(regs, device_spec, GET_EBDA2(ebda_seg, cdemu.device_spec));
	SET_INT13ET(regs, buffer_segment, GET_EBDA2(ebda_seg, cdemu.buffer_segment));
	SET_INT13ET(regs, load_segment, GET_EBDA2(ebda_seg, cdemu.load_segment));
	SET_INT13ET(regs, sector_count, GET_EBDA2(ebda_seg, cdemu.sector_count));
	SET_INT13ET(regs, cylinders, GET_EBDA2(ebda_seg, cdemu.cylinders));
	SET_INT13ET(regs, sectors, GET_EBDA2(ebda_seg, cdemu.spt));
	SET_INT13ET(regs, heads, GET_EBDA2(ebda_seg, cdemu.heads));

	// If we have to terminate emulation
	if (regs->al == 0x00) {
	// FIXME ElTorito Various. Should be handled accordingly to spec
	SET_EBDA2(ebda_seg, cdemu.active, 0x00); // bye bye
	}

	disk_ret(regs, DISK_RET_SUCCESS);
	}


	/****************************************************************
	* CD booting
	****************************************************************/

	// Request SENSE
	static int
	atapi_get_sense(int device, u8 asc, u8 ascq)
	{
	u8 atacmd[12], buffer[18];
	memset(atacmd, 0, sizeof(atacmd));
	atacmd[0] = ATA_CMD_REQUEST_SENSE;
	atacmd[4] = sizeof(buffer);
	int ret = ata_cmd_packet(device, atacmd, sizeof(atacmd), sizeof(buffer)
	, MAKE_FLATPTR(GET_SEG(SS), buffer));
	if (ret)
	return ret;

	*asc = buffer[12];
	*ascq = buffer[13];

	return 0;
	}

	// Request capacity
	static int
	atapi_read_capacity(int device, u32 blksize, u32 sectors)
	{
	u8 packet[12], buf[8];
	memset(packet, 0, sizeof(packet));
	packet[0] = 0x25; /* READ CAPACITY */
	int ret = ata_cmd_packet(device, packet, sizeof(packet), sizeof(buf)
	, MAKE_FLATPTR(GET_SEG(SS), buf));
	if (ret)
	return ret;

	*blksize = (((u32)buf[4] << 24) \| ((u32)buf[5] << 16)
	\| ((u32)buf[6] << 8) \| ((u32)buf[7] << 0));
	*sectors = (((u32)buf[0] << 24) \| ((u32)buf[1] << 16)
	\| ((u32)buf[2] << 8) \| ((u32)buf[3] << 0));

	return 0;
	}

	static int
	atapi_is_ready(u16 device)
	{
	dprintf(6, "atapi_is_ready (device=%d)\n", device);

	/* Retry READ CAPACITY for 5 seconds unless MEDIUM NOT PRESENT is
	* reported by the device. If the device reports "IN PROGRESS",
	* 30 seconds is added. */
	u32 blksize, sectors;
	int in_progress = 0;
	u64 end = calc_future_tsc(5000);
	for (;;) {
	if (rdtscll() > end) {
	dprintf(1, "read capacity failed\n");
	return -1;
	}

	int ret = atapi_read_capacity(device, &blksize, &sectors);
	if (!ret)
	// Success
	break;

	u8 asc, ascq;
	ret = atapi_get_sense(device, &asc, &ascq);
	if (ret)
	// Error - retry.
	continue;

	// Sense succeeded.
	if (asc == 0x3a) { /* MEDIUM NOT PRESENT */
	dprintf(1, "Device reports MEDIUM NOT PRESENT\n");
	return -1;
	}

	if (asc == 0x04 && ascq == 0x01 && !in_progress) {
	/* IN PROGRESS OF BECOMING READY */
	printf("Waiting for device to detect medium... ");
	/* Allow 30 seconds more */
	end = calc_future_tsc(30000);
	in_progress = 1;
	}
	}

	if (blksize != GET_GLOBAL(ATA.devices[device].blksize)) {
	printf("Unsupported sector size %u\n", blksize);
	return -1;
	}

	dprintf(6, "sectors=%u\n", sectors);
	printf("%dMB medium detected\n", sectors>>(20-11));
	return 0;
	}

	int
	cdrom_boot(int cdid)
	{
	// Verify device is a cdrom.
	if (cdid >= ATA.cdcount)
	return 1;
	int driveid = GET_GLOBAL(ATA.idmap[1][cdid]);
	if (GET_GLOBAL(ATA.devices[driveid].device) != ATA_DEVICE_CDROM)
	return 2;

	int ret = atapi_is_ready(driveid);
	if (ret)
	dprintf(1, "atapi_is_ready returned %d\n", ret);

	// Read the Boot Record Volume Descriptor
	u8 buffer[2048];
	struct disk_op_s dop;
	dop.driveid = driveid;
	dop.lba = 0x11;
	dop.count = 1;
	dop.buf_fl = MAKE_FLATPTR(GET_SEG(SS), buffer);
	ret = cdrom_read(&dop);
	if (ret)
	return 3;

	// Validity checks
	if (buffer[0])
	return 4;
	if (strcmp((char*)&buffer[1], "CD001\001EL TORITO SPECIFICATION") != 0)
	return 5;

	// ok, now we calculate the Boot catalog address
	u32 lba = (u32)&buffer[0x47];

	// And we read the Boot Catalog
	dop.lba = lba;
	ret = cdrom_read(&dop);
	if (ret)
	return 7;

	// Validation entry
	if (buffer[0x00] != 0x01)
	return 8; // Header
	if (buffer[0x01] != 0x00)
	return 9; // Platform
	if (buffer[0x1E] != 0x55)
	return 10; // key 1
	if (buffer[0x1F] != 0xAA)
	return 10; // key 2

	// Initial/Default Entry
	if (buffer[0x20] != 0x88)
	return 11; // Bootable

	u16 ebda_seg = get_ebda_seg();
	u8 media = buffer[0x21];
	SET_EBDA2(ebda_seg, cdemu.media, media);

	SET_EBDA2(ebda_seg, cdemu.controller_index, driveid/2);
	SET_EBDA2(ebda_seg, cdemu.device_spec, driveid%2);

	u16 boot_segment = (u16)&buffer[0x22];
	if (!boot_segment)
	boot_segment = 0x07C0;
	SET_EBDA2(ebda_seg, cdemu.load_segment, boot_segment);
	SET_EBDA2(ebda_seg, cdemu.buffer_segment, 0x0000);

	u16 nbsectors = (u16)&buffer[0x26];
	SET_EBDA2(ebda_seg, cdemu.sector_count, nbsectors);

	lba = (u32)&buffer[0x28];
	SET_EBDA2(ebda_seg, cdemu.ilba, lba);

	// And we read the image in memory
	dop.lba = lba;
	dop.count = DIV_ROUND_UP(nbsectors, 4);
	dop.buf_fl = MAKE_FLATPTR(boot_segment, 0);
	ret = cdrom_read(&dop);
	if (ret)
	return 12;

	if (media == 0) {
	// No emulation requested - return success.
	SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0xE0 + cdid);
	return 0;
	}

	// Emulation of a floppy/harddisk requested
	if (! CONFIG_CDROM_EMU)
	return 13;

	// Set emulated drive id and increase bios installed hardware
	// number of devices
	if (media < 4) {
	// Floppy emulation
	SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0x00);
	SETBITS_BDA(equipment_list_flags, 0x41);

	switch (media) {
	case 0x01: // 1.2M floppy
	SET_EBDA2(ebda_seg, cdemu.spt, 15);
	SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
	SET_EBDA2(ebda_seg, cdemu.heads, 2);
	break;
	case 0x02: // 1.44M floppy
	SET_EBDA2(ebda_seg, cdemu.spt, 18);
	SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
	SET_EBDA2(ebda_seg, cdemu.heads, 2);
	break;
	case 0x03: // 2.88M floppy
	SET_EBDA2(ebda_seg, cdemu.spt, 36);
	SET_EBDA2(ebda_seg, cdemu.cylinders, 80);
	SET_EBDA2(ebda_seg, cdemu.heads, 2);
	break;
	}
	} else {
	// Harddrive emulation
	SET_EBDA2(ebda_seg, cdemu.emulated_drive, 0x80);
	SET_BDA(hdcount, GET_BDA(hdcount) + 1);

	// Peak at partition table to get chs.
	struct mbr_s mbr = (void)0;
	u8 sptcyl = GET_FARVAR(boot_segment, mbr->partitions[0].last.sptcyl);
	u8 cyllow = GET_FARVAR(boot_segment, mbr->partitions[0].last.cyllow);
	u8 heads = GET_FARVAR(boot_segment, mbr->partitions[0].last.heads);

	SET_EBDA2(ebda_seg, cdemu.spt, sptcyl & 0x3f);
	SET_EBDA2(ebda_seg, cdemu.cylinders, ((sptcyl<<2)&0x300) + cyllow + 1);
	SET_EBDA2(ebda_seg, cdemu.heads, heads + 1);
	}

	// everything is ok, so from now on, the emulation is active
	SET_EBDA2(ebda_seg, cdemu.active, 0x01);
	dprintf(6, "cdemu media=%d\n", media);

	return 0;
	}