doc/memdisk.txt - pub/scm/boot/syslinux/syslinux - Git at Google

 [This documentation is rather crufty at the moment.]

 MEMDISK is meant to allow booting legacy operating systems via PXE,
 and as a workaround for BIOSes where ISOLINUX image support doesn't
 work.

 MEMDISK simulates a disk by claiming a chunk of high memory for the
 disk and a (very small - 2K typical) chunk of low (DOS) memory for the
 driver itself, then hooking the INT 13h (disk driver) and INT 15h
 (memory query) BIOS interrupts.

 MEMDISK allows for an OS to detect the MEMDISK instance.  (See the
 "Additional technical information" section below.)

 To use it, type on the Syslinux command line:

 memdisk initrd=diskimg.img

 ... where diskimg.img is the disk image you want to boot from.

 [Obviously, the memdisk binary as well as your disk image file need to
 be present in the boot image directory.]

 ... or add to your syslinux.cfg/pxelinux.cfg/isolinux.cfg something like:

 label dos
     kernel memdisk
     append initrd=dosboot.img

 Note the following:

 a) The disk image can be uncompressed or compressed with gzip or zip.

 b) If the disk image is less than 4,194,304 bytes (4096K, 4 MB) it is
    assumed to be a floppy image and MEMDISK will try to guess its
    geometry based on the size of the file.  MEMDISK recognizes all the
    standard floppy sizes as well as common extended formats:

      163,840 bytes  (160K) c=40 h=1 s=8		5.25" SSSD
      184,320 bytes  (180K) c=40 h=1 s=9		5.25" SSSD
      327,680 bytes  (320K) c=40 h=2 s=8		5.25" DSDD
      368,640 bytes  (360K) c=40 h=2 s=9		5.25" DSDD
      655,360 bytes  (640K) c=80 h=2 s=8		3.5"  DSDD
      737,280 bytes  (720K) c=80 h=2 s=9		3.5"  DSDD
    1,222,800 bytes (1200K) c=80 h=2 s=15	5.25" DSHD
    1,474,560 bytes (1440K) c=80 h=2 s=18	3.5"  DSHD
    1,638,400 bytes (1600K) c=80 h=2 s=20	3.5"  DSHD (extended)
    1,720,320 bytes (1680K) c=80 h=2 s=21	3.5"  DSHD (extended)
    1,763,328 bytes (1722K) c=82 h=2 s=21	3.5"  DSHD (extended)
    1,784,832 bytes (1743K) c=83 h=2 s=21	3.5"  DSHD (extended)
    1,802,240 bytes (1760K) c=80 h=2 s=22	3.5"  DSHD (extended)
    1,884,160 bytes (1840K) c=80 h=2 s=23	3.5"  DSHD (extended)
    1,966,080 bytes (1920K) c=80 h=2 s=24	3.5"  DSHD (extended)
    2,949,120 bytes (2880K) c=80 h=2 s=36	3.5"  DSED
    3,194,880 bytes (3120K) c=80 h=2 s=39	3.5"  DSED (extended)
    3,276,800 bytes (3200K) c=80 h=2 s=40	3.5"  DSED (extended)
    3,604,480 bytes (3520K) c=80 h=2 s=44	3.5"  DSED (extended)
    3,932,160 bytes (3840K) c=80 h=2 s=48	3.5"  DSED (extended)

    A small perl script is included in the MEMDISK directory which can
    determine the geometry that MEMDISK would select for other sizes;
    in general MEMDISK will correctly detect most physical extended
    formats used, with 80 cylinders or slightly more.

    If the image is 4 MB or larger, it is assumed to be a hard disk
    image, and should typically have an MBR and a partition table.  It
    may optionally have a DOSEMU geometry header; in which case the
    header is used to determine the C/H/S geometry of the disk.
    Otherwise, the geometry is determined by examining the partition
    table, so the entire image should be partitioned for proper
    operation (it may be divided between multiple partitions, however.)

    You can also specify the geometry manually with the following command
    line options:

    c=#		Specify number of cylinders (max 1024[*])
    h=#		Specify number of heads (max 256[*])
    s=#		Specify number of sectors (max 63)
    floppy[=#]	The image is a floppy image[**]
    harddisk[=#]	The image is a hard disk image[**]
    iso		The image is an El Torito ISO9660 image (drive 0xE0)

    # represents a decimal number.

     [*] MS-DOS only allows max 255 heads, and only allows 255 cylinders
         on floppy disks.

    [**] Normally MEMDISK emulates the first floppy or hard disk.  This
         can be overridden by specifying an index, e.g. floppy=1 will
         simulate fd1 (B:). This may not work on all operating systems
         or BIOSes.

 c) The disk is normally writable (although, of course, there is
    nothing backing it up, so it only lasts until reset.)  If you want,
    you can mimic a write-protected disk by specifying the command line
    option:

    ro		Disk is readonly

 d) MEMDISK normally uses the BIOS "INT 15h mover" API to access high
    memory.  This is well-behaved with extended memory managers which load
    later.  Unfortunately it appears that the "DOS boot disk" from
    WinME/XP *deliberately* crash the system when this API is invoked.
    The following command-line options tells MEMDISK to enter protected
    mode directly, whenever possible:

    raw		Use raw access to protected mode memory.

    bigraw	Use raw access to protected mode memory, and leave the
 		CPU in "big real" mode afterwards.

    int		Use plain INT 15h access to protected memory.  This assumes
    		that anything which hooks INT 15h knows what it is doing.

    safeint	Use INT 15h access to protected memory, but invoke
 		INT 15h the way it was *before* MEMDISK was loaded.
 		This is the default since version 3.73.

 e) MEMDISK by default supports EDD/EBIOS on hard disks, but not on
    floppy disks.  This can be controlled with the options:

    edd		Enable EDD/EBIOS
    noedd	Disable EDD/EBIOS

 f) The following option can be used to pause to view the messages:

    pause	Wait for a keypress right before booting

 g) The following option can be used to set the real-mode stack size.
    The default is 512 bytes, but if there is a failure it might be
    interesting to set it to something larger:

    stack=size   Set the stack to "size" bytes

 h) Some systems without a floppy drive have been known to have
    problems with floppy images.  To avoid that those problems, first
    of all make sure you don't have a floppy drive configured on the
    BIOS screen.  If there is no option to configure that, or that
    doesn't work, you can use the option:

    nopass	Hide all real drives of the same type (floppy or hard disk)
    nopassany    Hide all real drives (floppy and hard disk)

 i) The following standard Linux option will mark memory as reserved.
    Please note that the Syslinux core already loads MEMDISK and its
    initrd below this point:

    mem=size	Mark available memory above this point as Reserved.


 Some interesting things to note:

 If you're using MEMDISK to boot DOS from a CD-ROM (using ISOLINUX),
 you might find the generic El Torito CD-ROM driver by Gary Tong and
 Bart Lagerweij useful.  It is now included with the Syslinux
 distribution, in the dosutil directory.  See the file
 dosutil/eltorito.txt for more information.

 Similarly, if you're booting DOS over the network using PXELINUX, you
 can use the "keeppxe" option and use the generic PXE (UNDI) NDIS
 network driver, which is part of the PROBOOT.EXE distribution from
 Intel:

 	http://www.intel.com/support/network/adapter/1000/software.htm


 Additional technical information:

 Starting with version 2.08, MEMDISK now supports an installation check
 API.  This works as follows:

 	EAX = 454D08xxh ("ME") (08h = parameter query)
 	ECX = 444Dxxxxh ("MD")
 	EDX = 5349xxnnh	("IS") (nn = drive #)
 	EBX = 3F4Bxxxxh ("K?")
 	INT 13h

 If drive nn is a MEMDISK, the registers will contain:

 	EAX = 4D21xxxxh	("!M")
 	ECX = 4D45xxxxh ("EM")
 	EDX = 4944xxxxh ("DI")
 	EBX = 4B53xxxxh ("SK")

 	ES:DI -> MEMDISK info structures

 The low parts of EAX/ECX/EDX/EBX have the normal return values for INT
 13h, AH=08h, i.e. information of the disk geometry etc.

 See Ralf Brown's interrupt list,
 http://www.cs.cmu.edu/afs/cs.cmu.edu/user/ralf/pub/WWW/files.html or
 http://www.ctyme.com/rbrown.htm, for a detailed description.

 The MEMDISK info structure currently contains:

 	[ES:DI]		word	Total size of structure (currently 30 bytes)
 	[ES:DI+2]	byte	MEMDISK minor version
 	[ES:DI+3]	byte	MEMDISK major version
 	[ES:DI+4]	dword	Pointer to MEMDISK data in high memory
 	[ES:DI+8]	dword	Size of MEMDISK data in sectors
 	[ES:DI+12]	16:16	Far pointer to command line
 	[ES:DI+16]	16:16	Old INT 13h pointer
 	[ES:DI+20]	16:16	Old INT 15h pointer
 	[ES:DI+24]	word	Amount of DOS memory before MEMDISK loaded
 	[ES:DI+26]	byte	Boot loader ID
 	[ES:DI+27]	byte	Sector size as a power of 2
 				(If zero, assume 512-byte sectors)
 	[ES:DI+28]	word	If nonzero, offset (vs ES) to installed DPT
 				This pointer+16 contains the original INT 1Eh

 Sizes of this structure:

 3.71+		30 bytes	Added DPT pointer
 3.00-3.70	27 bytes	Added boot loader ID
 pre-3.00	26 bytes

 In addition, the following fields are available at [ES:0]:

 	[ES:0]		word	Offset of INT 13h routine (segment == ES)
 	[ES:2]		word	Offset of INT 15h routine (segment == ES)

 The program mdiskchk.c in the sample directory is an example on how
 this API can be used.

 The following code can be used to "disable" MEMDISK.  Note that it
 does not free the handler in DOS memory, and that running this from
 DOS will probably crash your machine (DOS doesn't like drives suddenly
 disappearing from underneath.)  This is also not necessarily the best
 method for this.

 	mov eax, 454D0800h
 	mov ecx, 444D0000h
 	mov edx, 53490000h
 	mov dl,drive_number
 	mov ebx, 3F4B0000h
 	int 13h

 	shr eax, 16
 	cmp ax, 4D21h
 	jne not_memdisk
 	shr ecx, 16
 	cmp cx, 4D45h
 	jne not_memdisk
 	shr edx, 16
 	cmp dx, 4944h
 	jne not_memdisk
 	shr ebx, 16
 	cmp bx, 4B53h
 	jne not_memdisk

 	cli
 	mov bx,[es:0]		; INT 13h handler offset
 	mov eax,[es:di+16]	; Old INT 13h handler
 	mov byte [es:bx], 0EAh	; FAR JMP
 	mov [es:bx+1], eax

 	mov bx,[es:2]		; INT 15h handler offset
 	mov eax,[es:di+20]	; Old INT 15h handler
 	mov byte [es:bx], 0EAh	; FAR JMP
 	mov [es:bx+1], eax
 	sti

 MEMDISK supports the Win9x "safe hook" structure for OS detection.
 (See "Safe Master Boot Record INT 13h Hook Routines," available at
 http://www.osronline.com/ddkx/w98ddk/storage_5l6g.htm as of
 December 7th, 2009.)  An OS driver can take a look at the INTerrupt table
 and try to walk along the chain of those hooks that implement the "safe hook"
 structure.  For each hook discovered, a vendor can be identified and the OS
 driver can take appropriate action.  The OS driver can mark the "flags" field
 of the "safe hook" to indicate that the driver has reviewed it already.  This
 prevents accidental re-detection, for example.

 MEMDISK adds one additional extension field to the "safe hook" structure, a
 pointer to a special MEMDISK structure called the "mBFT."  The mBFT is the
 "MEMDISK Boot Firmware Table" (akin to the iSCSI iBFT and the AoE aBFT).  An
 OS driver looking at MEMDISK's "safe hook" should know that this field will
 be present based on the fact that MEMDISK is the vendor identifier.

 The mBFT is little more than an ACPI table to prefix MEMDISK's traditional
 MEMDISK info structure (the "MDI").  The ACPI table's details are:

   OEM ID. . . .: MEMDSK
   OEM Table ID : Syslinux

 There is a 1-byte checksum field which covers the length of the mBFT all
 the way through to the end of the MEMDISK info structure.

 There is also a physical pointer to the "safe hook" structure associated
 with the MEMDISK instance.  An OS driver might use the following logic:

   1. Walk INT 13h "safe hook" chain as far as possible, marking hooks as
      having been reviewed.  For MEMDISK hooks, the driver then follows the
      pointer to the mBFT and gathers the RAM disk details from the included
      MDI.
   2. The OS driver scans low memory for valid mBFTs.  MEMDISK instances that
      have been "disconnected" from the INT 13h "safe hook" chain can be thus
      discovered.  Looking at their associated "safe hook" structure will
      reveal if they were indeed reviewed by the previous stage.
	[This documentation is rather crufty at the moment.]

	MEMDISK is meant to allow booting legacy operating systems via PXE,
	and as a workaround for BIOSes where ISOLINUX image support doesn't
	work.

	MEMDISK simulates a disk by claiming a chunk of high memory for the
	disk and a (very small - 2K typical) chunk of low (DOS) memory for the
	driver itself, then hooking the INT 13h (disk driver) and INT 15h
	(memory query) BIOS interrupts.

	MEMDISK allows for an OS to detect the MEMDISK instance. (See the
	"Additional technical information" section below.)

	To use it, type on the Syslinux command line:

	memdisk initrd=diskimg.img

	... where diskimg.img is the disk image you want to boot from.

	[Obviously, the memdisk binary as well as your disk image file need to
	be present in the boot image directory.]

	... or add to your syslinux.cfg/pxelinux.cfg/isolinux.cfg something like:

	label dos
	kernel memdisk
	append initrd=dosboot.img

	Note the following:

	a) The disk image can be uncompressed or compressed with gzip or zip.

	b) If the disk image is less than 4,194,304 bytes (4096K, 4 MB) it is
	assumed to be a floppy image and MEMDISK will try to guess its
	geometry based on the size of the file. MEMDISK recognizes all the
	standard floppy sizes as well as common extended formats:

	163,840 bytes (160K) c=40 h=1 s=8 5.25" SSSD
	184,320 bytes (180K) c=40 h=1 s=9 5.25" SSSD
	327,680 bytes (320K) c=40 h=2 s=8 5.25" DSDD
	368,640 bytes (360K) c=40 h=2 s=9 5.25" DSDD
	655,360 bytes (640K) c=80 h=2 s=8 3.5" DSDD
	737,280 bytes (720K) c=80 h=2 s=9 3.5" DSDD
	1,222,800 bytes (1200K) c=80 h=2 s=15 5.25" DSHD
	1,474,560 bytes (1440K) c=80 h=2 s=18 3.5" DSHD
	1,638,400 bytes (1600K) c=80 h=2 s=20 3.5" DSHD (extended)
	1,720,320 bytes (1680K) c=80 h=2 s=21 3.5" DSHD (extended)
	1,763,328 bytes (1722K) c=82 h=2 s=21 3.5" DSHD (extended)
	1,784,832 bytes (1743K) c=83 h=2 s=21 3.5" DSHD (extended)
	1,802,240 bytes (1760K) c=80 h=2 s=22 3.5" DSHD (extended)
	1,884,160 bytes (1840K) c=80 h=2 s=23 3.5" DSHD (extended)
	1,966,080 bytes (1920K) c=80 h=2 s=24 3.5" DSHD (extended)
	2,949,120 bytes (2880K) c=80 h=2 s=36 3.5" DSED
	3,194,880 bytes (3120K) c=80 h=2 s=39 3.5" DSED (extended)
	3,276,800 bytes (3200K) c=80 h=2 s=40 3.5" DSED (extended)
	3,604,480 bytes (3520K) c=80 h=2 s=44 3.5" DSED (extended)
	3,932,160 bytes (3840K) c=80 h=2 s=48 3.5" DSED (extended)

	A small perl script is included in the MEMDISK directory which can
	determine the geometry that MEMDISK would select for other sizes;
	in general MEMDISK will correctly detect most physical extended
	formats used, with 80 cylinders or slightly more.

	If the image is 4 MB or larger, it is assumed to be a hard disk
	image, and should typically have an MBR and a partition table. It
	may optionally have a DOSEMU geometry header; in which case the
	header is used to determine the C/H/S geometry of the disk.
	Otherwise, the geometry is determined by examining the partition
	table, so the entire image should be partitioned for proper
	operation (it may be divided between multiple partitions, however.)

	You can also specify the geometry manually with the following command
	line options:

	c=# Specify number of cylinders (max 1024[*])
	h=# Specify number of heads (max 256[*])
	s=# Specify number of sectors (max 63)
	floppy[=#] The image is a floppy image[**]
	harddisk[=#] The image is a hard disk image[**]
	iso The image is an El Torito ISO9660 image (drive 0xE0)

	# represents a decimal number.

	[*] MS-DOS only allows max 255 heads, and only allows 255 cylinders
	on floppy disks.

	[**] Normally MEMDISK emulates the first floppy or hard disk. This
	can be overridden by specifying an index, e.g. floppy=1 will
	simulate fd1 (B:). This may not work on all operating systems
	or BIOSes.

	c) The disk is normally writable (although, of course, there is
	nothing backing it up, so it only lasts until reset.) If you want,
	you can mimic a write-protected disk by specifying the command line
	option:

	ro Disk is readonly

	d) MEMDISK normally uses the BIOS "INT 15h mover" API to access high
	memory. This is well-behaved with extended memory managers which load
	later. Unfortunately it appears that the "DOS boot disk" from
	WinME/XP deliberately crash the system when this API is invoked.
	The following command-line options tells MEMDISK to enter protected
	mode directly, whenever possible:

	raw Use raw access to protected mode memory.

	bigraw Use raw access to protected mode memory, and leave the
	CPU in "big real" mode afterwards.

	int Use plain INT 15h access to protected memory. This assumes
	that anything which hooks INT 15h knows what it is doing.

	safeint Use INT 15h access to protected memory, but invoke
	INT 15h the way it was before MEMDISK was loaded.
	This is the default since version 3.73.

	e) MEMDISK by default supports EDD/EBIOS on hard disks, but not on
	floppy disks. This can be controlled with the options:

	edd Enable EDD/EBIOS
	noedd Disable EDD/EBIOS

	f) The following option can be used to pause to view the messages:

	pause Wait for a keypress right before booting

	g) The following option can be used to set the real-mode stack size.
	The default is 512 bytes, but if there is a failure it might be
	interesting to set it to something larger:

	stack=size Set the stack to "size" bytes

	h) Some systems without a floppy drive have been known to have
	problems with floppy images. To avoid that those problems, first
	of all make sure you don't have a floppy drive configured on the
	BIOS screen. If there is no option to configure that, or that
	doesn't work, you can use the option:

	nopass Hide all real drives of the same type (floppy or hard disk)
	nopassany Hide all real drives (floppy and hard disk)

	i) The following standard Linux option will mark memory as reserved.
	Please note that the Syslinux core already loads MEMDISK and its
	initrd below this point:

	mem=size Mark available memory above this point as Reserved.


	Some interesting things to note:

	If you're using MEMDISK to boot DOS from a CD-ROM (using ISOLINUX),
	you might find the generic El Torito CD-ROM driver by Gary Tong and
	Bart Lagerweij useful. It is now included with the Syslinux
	distribution, in the dosutil directory. See the file
	dosutil/eltorito.txt for more information.

	Similarly, if you're booting DOS over the network using PXELINUX, you
	can use the "keeppxe" option and use the generic PXE (UNDI) NDIS
	network driver, which is part of the PROBOOT.EXE distribution from
	Intel:

	http://www.intel.com/support/network/adapter/1000/software.htm


	Additional technical information:

	Starting with version 2.08, MEMDISK now supports an installation check
	API. This works as follows:

	EAX = 454D08xxh ("ME") (08h = parameter query)
	ECX = 444Dxxxxh ("MD")
	EDX = 5349xxnnh ("IS") (nn = drive #)
	EBX = 3F4Bxxxxh ("K?")
	INT 13h

	If drive nn is a MEMDISK, the registers will contain:

	EAX = 4D21xxxxh ("!M")
	ECX = 4D45xxxxh ("EM")
	EDX = 4944xxxxh ("DI")
	EBX = 4B53xxxxh ("SK")

	ES:DI -> MEMDISK info structures

	The low parts of EAX/ECX/EDX/EBX have the normal return values for INT
	13h, AH=08h, i.e. information of the disk geometry etc.

	See Ralf Brown's interrupt list,
	http://www.cs.cmu.edu/afs/cs.cmu.edu/user/ralf/pub/WWW/files.html or
	http://www.ctyme.com/rbrown.htm, for a detailed description.

	The MEMDISK info structure currently contains:

	[ES:DI] word Total size of structure (currently 30 bytes)
	[ES:DI+2] byte MEMDISK minor version
	[ES:DI+3] byte MEMDISK major version
	[ES:DI+4] dword Pointer to MEMDISK data in high memory
	[ES:DI+8] dword Size of MEMDISK data in sectors
	[ES:DI+12] 16:16 Far pointer to command line
	[ES:DI+16] 16:16 Old INT 13h pointer
	[ES:DI+20] 16:16 Old INT 15h pointer
	[ES:DI+24] word Amount of DOS memory before MEMDISK loaded
	[ES:DI+26] byte Boot loader ID
	[ES:DI+27] byte Sector size as a power of 2
	(If zero, assume 512-byte sectors)
	[ES:DI+28] word If nonzero, offset (vs ES) to installed DPT
	This pointer+16 contains the original INT 1Eh

	Sizes of this structure:

	3.71+ 30 bytes Added DPT pointer
	3.00-3.70 27 bytes Added boot loader ID
	pre-3.00 26 bytes

	In addition, the following fields are available at [ES:0]:

	[ES:0] word Offset of INT 13h routine (segment == ES)
	[ES:2] word Offset of INT 15h routine (segment == ES)

	The program mdiskchk.c in the sample directory is an example on how
	this API can be used.

	The following code can be used to "disable" MEMDISK. Note that it
	does not free the handler in DOS memory, and that running this from
	DOS will probably crash your machine (DOS doesn't like drives suddenly
	disappearing from underneath.) This is also not necessarily the best
	method for this.

	mov eax, 454D0800h
	mov ecx, 444D0000h
	mov edx, 53490000h
	mov dl,drive_number
	mov ebx, 3F4B0000h
	int 13h

	shr eax, 16
	cmp ax, 4D21h
	jne not_memdisk
	shr ecx, 16
	cmp cx, 4D45h
	jne not_memdisk
	shr edx, 16
	cmp dx, 4944h
	jne not_memdisk
	shr ebx, 16
	cmp bx, 4B53h
	jne not_memdisk

	cli
	mov bx,[es:0] ; INT 13h handler offset
	mov eax,[es:di+16] ; Old INT 13h handler
	mov byte [es:bx], 0EAh ; FAR JMP
	mov [es:bx+1], eax

	mov bx,[es:2] ; INT 15h handler offset
	mov eax,[es:di+20] ; Old INT 15h handler
	mov byte [es:bx], 0EAh ; FAR JMP
	mov [es:bx+1], eax
	sti

	MEMDISK supports the Win9x "safe hook" structure for OS detection.
	(See "Safe Master Boot Record INT 13h Hook Routines," available at
	http://www.osronline.com/ddkx/w98ddk/storage_5l6g.htm as of
	December 7th, 2009.) An OS driver can take a look at the INTerrupt table
	and try to walk along the chain of those hooks that implement the "safe hook"
	structure. For each hook discovered, a vendor can be identified and the OS
	driver can take appropriate action. The OS driver can mark the "flags" field
	of the "safe hook" to indicate that the driver has reviewed it already. This
	prevents accidental re-detection, for example.

	MEMDISK adds one additional extension field to the "safe hook" structure, a
	pointer to a special MEMDISK structure called the "mBFT." The mBFT is the
	"MEMDISK Boot Firmware Table" (akin to the iSCSI iBFT and the AoE aBFT). An
	OS driver looking at MEMDISK's "safe hook" should know that this field will
	be present based on the fact that MEMDISK is the vendor identifier.

	The mBFT is little more than an ACPI table to prefix MEMDISK's traditional
	MEMDISK info structure (the "MDI"). The ACPI table's details are:

	OEM ID. . . .: MEMDSK
	OEM Table ID : Syslinux

	There is a 1-byte checksum field which covers the length of the mBFT all
	the way through to the end of the MEMDISK info structure.

	There is also a physical pointer to the "safe hook" structure associated
	with the MEMDISK instance. An OS driver might use the following logic:

	1. Walk INT 13h "safe hook" chain as far as possible, marking hooks as
	having been reviewed. For MEMDISK hooks, the driver then follows the
	pointer to the mBFT and gathers the RAM disk details from the included
	MDI.
	2. The OS driver scans low memory for valid mBFTs. MEMDISK instances that
	have been "disconnected" from the INT 13h "safe hook" chain can be thus
	discovered. Looking at their associated "safe hook" structure will
	reveal if they were indeed reviewed by the previous stage.