Extended boot record

EBR structure and values

EBRs have essentially the same structure as the MBR; except only the first two entries of the partition table are supposed to be used, besides having the mandatory boot record signature (or magic number) of 0xAA55 at the end of the sector. This 2-byte signature appears in a disk editor as 0x55 first and 0xAA last, because IBM-compatible PCs store hexadecimal words in little-endian order (see table below).

Structures

The IBM Boot Manager (included with OS/2 operating systems and some early versions of Partition Magic), adds at least one 9-byte entry (starting at offset 0x18A) to each EBR sector. The entry consists of a flag value byte (indicating if the partition is on the IBM Boot Manager menu) followed by an 8-byte ASCII string which is the name to be used on the menu. If the partition is not included on the boot menu (such as data only partitions), the flag byte is zero; in which case, the following 8-byte field may contain an ASCII representation of that partition's starting sector number (in hexadecimal).

The partition type of an extended partition is 0x05 (CHS addressing) or 0x0F (LBA addressing). DR DOS 6.0 and higher support secured extended partitions using 0xC5, which are invisible to other operating systems. Since non-LBA-enabled versions of DR-DOS up to including 7.03 do not recognize the 0x0F partition type and other operating systems do not recognize the 0xC5 type, this can also be utilized to occupy space up to the first 8 GB of the disk for use under DR-DOS (for logical drives in secured or non-secured partitions), and still use 0x0F to allocate the remainder of the disk for LBA-enabled operating systems in a non-conflictive fashion. Similar, Linux supports the concept of a second extended partition chain with type 0x85 — this type is hidden (unknown) for other operating systems supporting only one chain. Other extended partition types which may hold EBRs include the deliberately hidden types 0x15, 0x1F, 0x91 and 0x9B, the access-restricted types 0x5E and 0x5F, and the secured types 0xCF and 0xD5. However, these should be treated private to the operating systems and tools supporting them and should not be mounted otherwise.

The CHS addresses of a partition are hard to interpret without knowledge of the (virtual) disk geometry, because CHS to LBA translations are based on the number of heads and the number of sectors per track. However, the given LBA start address and the given partition size in sectors permit to calculate a disk geometry matching the given CHS addresses where that is at all possible. CHS addressing with 24 bits always uses 6 bits for up to 63 sectors per track (1…63), and INT 13h disk access generally uses 8 bits for up to 256 heads (0…255), leaving 10 bits for up to 1024 cylinders (0…1023). ATA CHS addresses always use 4 bits for up to 16 heads (0…15), this leaves 14 bits for up to 16383 cylinders (16383+1=2**14) in ATA-5 24 bits CHS address translations.

Values

The following are general rules that apply only to values found in the 4-byte fields of an EBR's partition table entries (cf. tables above). These values depend upon the partitioning tool(s) used to create or alter them, and in fact, most operating systems that use the extended partitioning scheme (including Microsoft MS-DOS and Windows, and Linux) ignore the "partition size" value in entries which point to another EBR sector. One exception is that value must be one or greater for Linux operating systems.

The first entry of an EBR partition table points to the logical partition belonging to that EBR:

Starting sector = relative offset between this EBR sector and the first sector of the logical partition

Note: This is often the same value for each EBR on the same hard disk; usually 63 for Windows XP or older.

Number of sectors = total count of sectors for this logical partition

Note: Any unused sectors between EBR and logical drive are not considered part of the logical drive.

The second entry of an EBR partition table will contain zero-bytes if it's the last EBR in the extended partition; otherwise, it points to the next EBR in the EBR chain.

Starting sector = relative address of next EBR within extended partition

in other words: Starting sector = LBA address of next EBR minus LBA address of extended partition's first EBR

Number of sectors = total count of sectors for next logical partition, but count starts from the next EBR sector

Note: Unlike the first entry in an EBR's partition table, this number of sectors count includes the next logical partition's EBR sector along with the other sectors in its otherwise unused track. (Compare Diagram 1 and 2 below.)

Remarks:
First, the diagrams above are not to scale: The thin white lines between each "EBR" and its logical "partition" represent the remainder of an unused area usually 63 sectors in length; including the single EBR sector (shown at a greatly exaggerated size).

Also, on some systems, a large gap of unused space may exist between the end of a logical partition and the next EBR, or between the last logical partition and the end of the whole extended partition itself, if any previously created logical partition has been deleted or resized (shrunk).

Naming

Linux and similar operating systems designate IDE hard disks as /dev/hda for the first hard disk, /dev/hdb for the second hard disk, and so on. Likewise SCSI and in later kernels also IDE and SATA hard disks are identified as /dev/sda for the first disk, etc.

The up to four partitions defined in the master boot record are designated as /dev/hda1 … /dev/hda4 for /dev/hda. The fifth partition in this scheme, e.g., /dev/hda5, corresponds to the first logical drive. The sixth partition /dev/hda6 would then correspond to the second logical drive, or in other words, the extended partition containers are not counted. Only the outermost extended partition defined in the MBR (one of /dev/hda1 … /dev/hda4) has a name in this scheme.

Examples

This shows an extended partition with 6,000 sectors and 3 logical partitions.
Remark: Neither a tiny extended partition with only 3 MB nor a hard drive with 20 sectors per track are realistic but these values have been chosen to make this example more readable.

Snapshot

The following output of a command line tool shows the layout of a disk with two logical drives. Details for the FAT and NTFS partitions stripped, the line annotated with Linux is /dev/hda6 with an extended file system. The begin of /dev/hda5 shows that the involved operating systems PC DOS 7, Windows NT, and Debian do not insist on any extended partition alignment with a gap:

.PHYSICALDRIVE0 (assuming geometry CHS 99999 255 63) id. [3189-3188] MBR CHS 0 0 1 at 0, end 0 0 1, size 1 unused CHS 0 0 2 at 1, end 0 0 63, size 62 1:*06: CHS 0 1 1 at 63, end 260 254 63, size 4192902 bigFAT 2: 05: CHS 261 0 1 at 4192965, end 757 254 63, size 7984305 => EXT 3: 17: CHS 758 0 1 at 12177270, end 1522 254 63, size 12289725 NTFS 4: 1C: CHS 1523 0 1 at 24466995, end 1825 254 63, size 4867695 FAT32 (extended offset 4192965) total 29334690 => EXT CHS 261 0 1 at 0, end 261 0 1, size 1 5: 06: CHS 261 0 2 at 1, end 384 254 63, size 1992059 bigFAT 6: 05: CHS 385 0 1 at 1992060, end 757 254 63, size 5992245 => EXT (extended offset 6185025) total 7984305 => EXT CHS 385 0 1 at 0, end 385 0 1, size 1 unused CHS 385 0 2 at 1, end 385 0 63, size 62 6: 83: CHS 385 1 1 at 63, end 757 254 63, size 5992182 Linux 7: 00: CHS 0 0 0 at 0, end 0 0 0, size 0 unused total 5992245 bigFAT CHS 0 1 1 at 63, end 260 254 63, size 4192902 PC DOS 7 (cluster size 64, number 65506) total 4192902 NTFS CHS 758 0 1 at 12177270, end 1522 254 63, size 12289725 [1C81-013D] (cluster size 8, number 1536215) total 12289725 FAT32 CHS 1523 0 1 at 24466995, end 1825 254 63, size 4867695 [C417-9E22] (cluster size 8, number 607271) total 4867695 bigFAT CHS 261 0 2 at 4192966, end 384 254 63, size 1992059 FAT SWAP (cluster size 32, number 62236) total 1992059

For another example see the "Linux Partition HOWTO".