doc/nbi-spec.txt - pub/scm/utils/kernel/kexec/kexec-tools.git - Git at Google

   Draft Net Boot Image Proposal 0.3
   Jamie Honan and Gero Kuhlmann, gero@minix.han.de
   June 15, 1997

   This is the specification of the "tagged image" format
   ______________________________________________________________________

   Table of Contents


   1. Note

   2. Preamble - the why

   3. The target

   4. Net Boot Process Description.

   5. Image Format with Initial Magic Number.

   6. Boot prom entry points.

   7. Example of a boot image.

   8. Terms

   9. References


   ______________________________________________________________________

   11..  NNoottee


   In order to provide more functionality to the boot rom code I changed
   Jamie's draft a little bit. All my changes are preceded and followed
   by ((ggkk)).


   Gero Kuhlmann


   22..  PPrreeaammbbllee -- tthhee wwhhyy


   Whilst researching what other boot proms do (at least those
   implementing TCP/IP protocols) it is clear that each 'does their own
   thing' in terms of what they expect in a boot image.


   If we could all agree on working toward an open standard, O/S
   suppliers and boot rom suppliers can build their products to this
   norm, and be confident that they will work with each other.


   This is a description of how I will implement the boot rom for Linux.
   I  believe it to be flexible enough for any OS that will be loaded
   when a PC boots from a network in the TCP/IP environment.


   It would be good if this could be turned into some form of standard.


   This is very much a first draft. I am inviting comment.


   The ideas presented here should be independant of any implementation.
   In the end, where there is a conflict between the final of this draft,
   and an implementation, this description should prevail.


   The terms I use are defined at the end.


   ((ggkk))IMPORTANT NOTE: The scope of this document starts at the point
   where the net boot process gains control from the BIOS, to where the
   booted image reaches a state from which there is no return to the net
   boot program possible.((ggkk))


   33..  TThhee ttaarrggeett


   The target is to have a PC retrieve a boot image from a network in the
   TCP/IP environment.


   ((ggkk))The boot may take place from a network adaptor rom, from a boot
   floppy.((ggkk))


   44..  NNeett BBoooott PPrroocceessss DDeessccrriippttiioonn..


   ((ggkk))The net boot process is started as a result of the PC boot
   process. The net boot program can reside on a rom, e.g. on an adaptor
   card, or in ram as a result of reading off disk.((ggkk))


   The boot process may execute in any mode (e.g. 8086, 80386) it
   desires.  When it jumps to the start location in the boot image, it
   must be in 8086 mode and be capable of going into any mode supported
   by the underlying processor.


   The image cannot be loaded into address spaces below 10000h, or
   between A0000h through FFFFFh, or between 98000h through 9FFFFh.
   ((ggkk))Only when the image is not going to return to the boot process,
   all the memory is available to it once it has been started, so it can
   relocate parts of itself to these areas.((ggkk))


   The boot process must be capable of loading the image into all other
   memory locations. Specifically, where the machine supports this, this
   means memory over 100000h.


   The net boot process must execute the bootp protocol, followed by the
   tftp protocol, as defined in the relevant rfc's.


   The file name used in the tftp protocol must be that given by the
   bootp record.


   If less than 512 bytes are loaded, the net boot process attempts to
   display on the screen any ascii data at the start of the image. The
   net boot process then exits in the normal manner. For a boot prom,
   this will allow normal disk booting. ((ggkk))Reference to DOS deleted.((ggkk))


   When the first 512 bytes have been loaded, the boot process checks for
   an initial magic number, which is defined later. If this number is
   present, the net process continues loading under the control of the
   image format. The image, which is described later, tells the net boot
   process where to put this record and all subsequent data.


   If no initial magic number is present the net boot process checks for
   a second magic number at offset 510. If the magic number 510 = 55h,
   511 = AAh, then the net process continues. If this second magic number
   is not present, then the net boot process terminates the tftp
   protocol, displays an error message and exits in the normal manner.


   If no initial magic number is present and the second one is, the net
   boot process relocates the 512 bytes to location 7c00h. The net boot
   process continues to load any further image data to 10000h up. This
   data can overwrite the first 512 boot bytes. If the image reaches
   98000h, then any further data is continued to be loaded above 100000h.
   When all the data has been loaded, the net boot process jumps to
   location 0:7c00.


   ((ggkk))When the net boot program calls the image, it places 2 far
   pointers onto the stack, in standard intel order (e.g.  segment:offset
   representation).  The first far pointer which immediately follows the
   return address on the stack, points to the loaded boot image header.
   The second far pointer which is placed above the first one, shows to
   the memory area where the net boot process saved the bootp reply.


   If the boot image is flagged as being returnable to the boot process,
   the boot program has to provide the boot image with interrupt vector
   78h. It's an interface to services provided by the net boot program
   (see below for further description).


   If the boot image is not flagged as being returnable to the boot
   process, before the boot image is called, the boot program has to set
   the system into a state in which it was before the net boot process
   has started.((ggkk))


   55..  IImmaaggee FFoorrmmaatt wwiitthh IInniittiiaall MMaaggiicc NNuummbbeerr..


   The first 512 bytes of the image file contain the image header, and
   image loading information records. This contains all the information
   needed by the net boot process as to where data is to be loaded.

   The magic number (in time-honoured tradition (well why not?)) is:


   ______________________________________________________________________
           0 = 36h
           1 = 13h
           2 = 03h
           3 = 1Bh
   ______________________________________________________________________


   Apart from the two magic numbers, all words and double words are in PC
   native endian.


   Including the initial magic number the header record is:


   ______________________________________________________________________
           +---------------------+
           |                     |
           | Initial Magic No.   |  4 bytes
           +---------------------+
           |                     |
           | Flags and length    |  double word
           +---------------------+
           |                     |
           | Location Address    |  double word in ds:bx format
           +---------------------+
           |                     |
           | Execute Address     |  double word in cs:ip format
           +---------------------+
   ______________________________________________________________________


   The Location address is where to place the 512 bytes. The net boot
   process does this before loading the rest of the image. The location
   address cannot be one of the reserved locations mentioned above, but
   must be an address lower than 100000h.


   The rest of the image must not overwrite these initial 512 bytes,
   placed at the required location. The writing of data by the net boot
   process into these 512 bytes is deprecated. These 512 bytes must be
   available for the image to interogate once it is loaded and running.


   The execute address is the location in cs:ip of the initial
   instruction once the full image has been loaded. This must be lower
   than 100000h, since the initial instructions will be executed in 8086
   mode. When the jump (actaully a far call) is made to the boot image,
   the stack contains a far return address, with a far pointer parameter
   above that, pointing to the location of this header.

   The flags and length field is broken up in the following way:


   Bits 0 to 3 (lowest 4 bits) define the length of the non vendor header
   in double words. Currently the value is 4.


   Bits 4 to 7 define the length required by the vendor extra information
   in double words. A value of zero indicates no extra vendor
   information.


   ((ggkk))Bit 8 is set if the boot image can return to the net boot process
   after execution. If this bit is not set the boot image does never
   return to the net boot process, and the net boot program has to set
   the system into a clean state before calling the boot image.


   Bits 9 to 31 are reserved for future use and must be set to zero.((ggkk))


   After this header, and any vendor header, come the image loading
   information records. These specify where data is to be loaded, how
   long it is, and communicates to the loaded image what sort of data it
   is.


   The format of each image loading information record is :


   ______________________________________________________________________
             +---------------------+
             | Flags, tags and     |  double word
             | lengths             |
             +---------------------+
             |                     |
             | Load Address        |  double word
             +---------------------+
             |                     |
             | Image Length        |  double word
             +---------------------+
             |                     |
             | Memory Length       |  double word
             +---------------------+
   ______________________________________________________________________


   Each image loading information record follows the previous, or the
   header.


   The memory length, image length and load address fields are unsigned
   32 numbers. They do not have the segment:offset format used by the
   8086.


   The flags, tags and lengths field is broken up as follows:


   Bits 0 to 3 (lowest 4 bits) are the length of the non vendor part of
   this header in double words. Currently this value is 4.


   Bits 4 to 7 indicate the length of any vendor information, in double
   words.


   Bits 8 to 15 are for vendor's tags. The vendor tag is a private number
   that the loaded image can use to determine what sort of image is at
   this particular location.


   Bits 16 to 23 are for future expansion and should be set to zero.


   Bits 24 to 31 are for flags, which are defined later.


   Vendors may place further information after this information record,
   and before the next. Each information record may have a different
   vendor length.


   There are two restrictions on vendor information.


   One is that the header and all information records that the net boot
   process is to use fall within the first 512 bytes.


   The second restriction is that the net boot process must ignore all
   vendor additions. The net boot process may not overwrite vendor
   supplied information, or other undefined data in the initial 512
   bytes.


   The flags are used to modify the load address field, and to indicate
   that this is the last information record that the net boot process
   should use.


   Bit 24 works in conjunction with bit 25 to specify the meaning of the
   load address.


   ______________________________________________________________________
             B24    B25

              0     0    load address is an absolute 32 number

              1     0    add the load address to the location one past the last byte
                         of the memory area required by the last image loaded.
                         If the first image, then add to 512 plus the location
                         where the 512 bytes were placed

              0     1    subtract the load address from the one past the
                         last writeable location in memory. Thus 1 would
                         be the last location one could write in memory.

              1     1    load address is subtracted from the start of
                         the last image loaded. If the first image, then
                         subtract from the start of where the 512 bytes were
                         placed
   ______________________________________________________________________


   (For convenience bit 24 is byte 0 of the flag field)


   Bit 26 is the end marker for the net boot process. It is set when this
   is the last information record the net boot process should look at.
   More records may be present, but the net boot process will not look at
   them. (Vendors can continue information records out past the 512
   boundary for private use in this manner).


   The image length tells the net boot process how many bytes are to be
   loaded.  Zero is a valid value. This can be used to mark memory areas
   such as shared memory for interprocessor communication, flash eproms,
   data in eproms.


   The image length can also be different from the memory length. This
   allows decompression programs to fluff up the kernel image. It also
   allows a file system to be larger then the loaded file system image.


   Bits 27 through 31 are not defined as yet and must be set to zero
   until they are.


   66..  BBoooott pprroomm eennttrryy ppooiinnttss..


   ((ggkk))As mentioned above the net boot process has to provide interrupt
   78h as an entry point in case, the returnable flag (bit 9 of the flags
   field in the image header) of the boot image has been set.  When
   calling this interface interrupt, the caller has to load the AH
   register with a value indicating the type of operation requested:


   ______________________________________________________________________
          00h  -  Installation check
                  Input:  none
                  Output: AX  -  returns the value 474Bh
                          BX  -  flags indicating what further services are
                                 provided by the net boot program:
                                  Bit 0 - packet driver interface (see below)
                                  Bits 1 to 15 are unused and have to be zero

          01h  -  Cleanup and terminate the boot process services. This will
                  also remove the services provided by interrupt 87h.
                  Input:  none
                  Output: none
   ______________________________________________________________________


   Further functions are not yet defined. These functions are only
   available to boot images which have the first magic number at the
   beginning of the image header, and have the returnable flag set in the
   flags field.


   In order to provide compatibility with net boot programs written to
   match an earlier version of this document, the loaded image should
   check for the existence of interrupt 78h by looking at it's vector. If
   that's 0:0, or if it does not return a proper magic ID after calling
   the installation check function, the boot image has to assume that the
   net boot program does not support this services interrupt.


   If the bit 0 of register BX of function 00h is set, the boot program
   has to provide a packet driver <http://www.crynwr.com> interface at
   interrupt 79h as described in the packet driver interface standard,
   version 1.09, published by FTP Software, Inc., which is not repeated
   here. It serves as an interface to the system's network card. It is
   important to note that the net boot process has to provide a clean
   packet driver interface without any handles being defined when the
   boot image gets started. It is expected that the boot image sets up
   it's own TCP/IP or other network's stack on top of this packet driver
   interface.  When the boot image returns to the net boot process, it
   has to return a clean packet driver interface as well, without any
   handles being defined.((ggkk))


   77..  EExxaammppllee ooff aa bboooott iimmaaggee..


   Here is an example of how the boot image would look for Linux:


   ______________________________________________________________________
             0x1B031336,  /* magic number */
             0x4,         /* length of header is 16 bytes, no vendor info */
             0x90000000,  /* location in ds:bx format */
             0x90000200,  /* execute address in cs:ip format */

                          /* 2048 setup.S bytes */
             0x4,         /* flags, not end, absolute address, 16 bytes this
                             record, no vendor info */
             0x90200,     /* load address - note format */
             0x800,       /* 4 8 512 byte blocks for linux */
             0x800,

                          /* kernel image */
             0x4,         /* flags, not end, absolute address, 16 bytes this
                             record, no vendor info */
             0x10000,     /* load address - note format */
             0x80000,     /* 512K (this could be shorter */
             0x80000,

                          /* ramdisk for root file system */
             0x04000004,  /* flags = last, absolute address, 16 bytes this
                             record, no vendor info *//
             0x100000,    /* load address - in extended memory */
             0x80000,     /* 512K for instance */
             0x80000,

                          /* Then follows linux specific information */
   ______________________________________________________________________


   88..  TTeerrmmss


   When I say 'the net boot process', I mean the act of loading the image
   into memory, setting up any tables, up until the jump to the required
   location in the image.


   The net booting program executes the net boot process. The net boot
   program may be a rom, but not neccassarily. It is a set of
   instructions and data residing on the booting machine.


   The image, or boot image,  consists of the data loaded by the net boot
   process.


   When I say 'the PC boot process', I mean the general PC rom bios boot
   process, the setting up of hardware, the scanning for adaptor roms,
   the execution of adaptor roms, the loading in of the initial boot
   track. The PC boot process will include the net boot process, if one
   is present.


   When I say client, I mean the PC booting up.


   When I say 'image host', I mean the host where the boot image is
   comming from.  This may not have the same architecture as the client.


   The bootp protocol is defined in RFC951 and RFC1084. The tftp protocol
   is defined in RFC783. These are available on many sites.  See Comer
   1991 for details on how to obtain them.


   A bootp server is the machine that answers the bootp request. It is
   not neccessarily the image host.


   "Can" and "may" means doesn't have to, but is allowed to and might.
   "Must" means just that. "Cannot" means must not.


   99..  RReeffeerreenncceess


   Comer, D.E. 1991, Internetworking with TCP/IP Vol I: Principles,
   Protocols, and Architecture Second Edition, Prentice Hall, Englewood
   Cliffs, N.J., 1991


   Stevens, W.R 1990, Unix Network Programming, Prentice Hall, Englewood
   Cliffs, N.J., 1990
	Draft Net Boot Image Proposal 0.3
	Jamie Honan and Gero Kuhlmann, gero@minix.han.de
	June 15, 1997

	This is the specification of the "tagged image" format
	______________________________________________________________________

	Table of Contents


	1. Note

	2. Preamble - the why

	3. The target

	4. Net Boot Process Description.

	5. Image Format with Initial Magic Number.

	6. Boot prom entry points.

	7. Example of a boot image.

	8. Terms

	9. References



	______________________________________________________________________

	11.. NNoottee


	In order to provide more functionality to the boot rom code I changed
	Jamie's draft a little bit. All my changes are preceded and followed
	by ((ggkk)).



	Gero Kuhlmann


	22.. PPrreeaammbbllee -- tthhee wwhhyy


	Whilst researching what other boot proms do (at least those
	implementing TCP/IP protocols) it is clear that each 'does their own
	thing' in terms of what they expect in a boot image.



	If we could all agree on working toward an open standard, O/S
	suppliers and boot rom suppliers can build their products to this
	norm, and be confident that they will work with each other.



	This is a description of how I will implement the boot rom for Linux.
	I believe it to be flexible enough for any OS that will be loaded
	when a PC boots from a network in the TCP/IP environment.




	It would be good if this could be turned into some form of standard.



	This is very much a first draft. I am inviting comment.



	The ideas presented here should be independant of any implementation.
	In the end, where there is a conflict between the final of this draft,
	and an implementation, this description should prevail.



	The terms I use are defined at the end.



	((ggkk))IMPORTANT NOTE: The scope of this document starts at the point
	where the net boot process gains control from the BIOS, to where the
	booted image reaches a state from which there is no return to the net
	boot program possible.((ggkk))


	33.. TThhee ttaarrggeett


	The target is to have a PC retrieve a boot image from a network in the
	TCP/IP environment.



	((ggkk))The boot may take place from a network adaptor rom, from a boot
	floppy.((ggkk))


	44.. NNeett BBoooott PPrroocceessss DDeessccrriippttiioonn..


	((ggkk))The net boot process is started as a result of the PC boot
	process. The net boot program can reside on a rom, e.g. on an adaptor
	card, or in ram as a result of reading off disk.((ggkk))



	The boot process may execute in any mode (e.g. 8086, 80386) it
	desires. When it jumps to the start location in the boot image, it
	must be in 8086 mode and be capable of going into any mode supported
	by the underlying processor.



	The image cannot be loaded into address spaces below 10000h, or
	between A0000h through FFFFFh, or between 98000h through 9FFFFh.
	((ggkk))Only when the image is not going to return to the boot process,
	all the memory is available to it once it has been started, so it can
	relocate parts of itself to these areas.((ggkk))



	The boot process must be capable of loading the image into all other
	memory locations. Specifically, where the machine supports this, this
	means memory over 100000h.



	The net boot process must execute the bootp protocol, followed by the
	tftp protocol, as defined in the relevant rfc's.



	The file name used in the tftp protocol must be that given by the
	bootp record.



	If less than 512 bytes are loaded, the net boot process attempts to
	display on the screen any ascii data at the start of the image. The
	net boot process then exits in the normal manner. For a boot prom,
	this will allow normal disk booting. ((ggkk))Reference to DOS deleted.((ggkk))



	When the first 512 bytes have been loaded, the boot process checks for
	an initial magic number, which is defined later. If this number is
	present, the net process continues loading under the control of the
	image format. The image, which is described later, tells the net boot
	process where to put this record and all subsequent data.



	If no initial magic number is present the net boot process checks for
	a second magic number at offset 510. If the magic number 510 = 55h,
	511 = AAh, then the net process continues. If this second magic number
	is not present, then the net boot process terminates the tftp
	protocol, displays an error message and exits in the normal manner.



	If no initial magic number is present and the second one is, the net
	boot process relocates the 512 bytes to location 7c00h. The net boot
	process continues to load any further image data to 10000h up. This
	data can overwrite the first 512 boot bytes. If the image reaches
	98000h, then any further data is continued to be loaded above 100000h.
	When all the data has been loaded, the net boot process jumps to
	location 0:7c00.



	((ggkk))When the net boot program calls the image, it places 2 far
	pointers onto the stack, in standard intel order (e.g. segment:offset
	representation). The first far pointer which immediately follows the
	return address on the stack, points to the loaded boot image header.
	The second far pointer which is placed above the first one, shows to
	the memory area where the net boot process saved the bootp reply.



	If the boot image is flagged as being returnable to the boot process,
	the boot program has to provide the boot image with interrupt vector
	78h. It's an interface to services provided by the net boot program
	(see below for further description).



	If the boot image is not flagged as being returnable to the boot
	process, before the boot image is called, the boot program has to set
	the system into a state in which it was before the net boot process
	has started.((ggkk))



	55.. IImmaaggee FFoorrmmaatt wwiitthh IInniittiiaall MMaaggiicc NNuummbbeerr..


	The first 512 bytes of the image file contain the image header, and
	image loading information records. This contains all the information
	needed by the net boot process as to where data is to be loaded.

	The magic number (in time-honoured tradition (well why not?)) is:


	______________________________________________________________________
	0 = 36h
	1 = 13h
	2 = 03h
	3 = 1Bh
	______________________________________________________________________



	Apart from the two magic numbers, all words and double words are in PC
	native endian.



	Including the initial magic number the header record is:


	______________________________________________________________________
	+---------------------+
	\| \|
	\| Initial Magic No. \| 4 bytes
	+---------------------+
	\| \|
	\| Flags and length \| double word
	+---------------------+
	\| \|
	\| Location Address \| double word in ds:bx format
	+---------------------+
	\| \|
	\| Execute Address \| double word in cs:ip format
	+---------------------+
	______________________________________________________________________



	The Location address is where to place the 512 bytes. The net boot
	process does this before loading the rest of the image. The location
	address cannot be one of the reserved locations mentioned above, but
	must be an address lower than 100000h.



	The rest of the image must not overwrite these initial 512 bytes,
	placed at the required location. The writing of data by the net boot
	process into these 512 bytes is deprecated. These 512 bytes must be
	available for the image to interogate once it is loaded and running.



	The execute address is the location in cs:ip of the initial
	instruction once the full image has been loaded. This must be lower
	than 100000h, since the initial instructions will be executed in 8086
	mode. When the jump (actaully a far call) is made to the boot image,
	the stack contains a far return address, with a far pointer parameter
	above that, pointing to the location of this header.

	The flags and length field is broken up in the following way:



	Bits 0 to 3 (lowest 4 bits) define the length of the non vendor header
	in double words. Currently the value is 4.



	Bits 4 to 7 define the length required by the vendor extra information
	in double words. A value of zero indicates no extra vendor
	information.



	((ggkk))Bit 8 is set if the boot image can return to the net boot process
	after execution. If this bit is not set the boot image does never
	return to the net boot process, and the net boot program has to set
	the system into a clean state before calling the boot image.



	Bits 9 to 31 are reserved for future use and must be set to zero.((ggkk))



	After this header, and any vendor header, come the image loading
	information records. These specify where data is to be loaded, how
	long it is, and communicates to the loaded image what sort of data it
	is.



	The format of each image loading information record is :



	______________________________________________________________________
	+---------------------+
	\| Flags, tags and \| double word
	\| lengths \|
	+---------------------+
	\| \|
	\| Load Address \| double word
	+---------------------+
	\| \|
	\| Image Length \| double word
	+---------------------+
	\| \|
	\| Memory Length \| double word
	+---------------------+
	______________________________________________________________________



	Each image loading information record follows the previous, or the
	header.



	The memory length, image length and load address fields are unsigned
	32 numbers. They do not have the segment:offset format used by the
	8086.



	The flags, tags and lengths field is broken up as follows:



	Bits 0 to 3 (lowest 4 bits) are the length of the non vendor part of
	this header in double words. Currently this value is 4.



	Bits 4 to 7 indicate the length of any vendor information, in double
	words.



	Bits 8 to 15 are for vendor's tags. The vendor tag is a private number
	that the loaded image can use to determine what sort of image is at
	this particular location.



	Bits 16 to 23 are for future expansion and should be set to zero.



	Bits 24 to 31 are for flags, which are defined later.



	Vendors may place further information after this information record,
	and before the next. Each information record may have a different
	vendor length.



	There are two restrictions on vendor information.



	One is that the header and all information records that the net boot
	process is to use fall within the first 512 bytes.



	The second restriction is that the net boot process must ignore all
	vendor additions. The net boot process may not overwrite vendor
	supplied information, or other undefined data in the initial 512
	bytes.



	The flags are used to modify the load address field, and to indicate
	that this is the last information record that the net boot process
	should use.



	Bit 24 works in conjunction with bit 25 to specify the meaning of the
	load address.








	______________________________________________________________________
	B24 B25

	0 0 load address is an absolute 32 number

	1 0 add the load address to the location one past the last byte
	of the memory area required by the last image loaded.
	If the first image, then add to 512 plus the location
	where the 512 bytes were placed

	0 1 subtract the load address from the one past the
	last writeable location in memory. Thus 1 would
	be the last location one could write in memory.

	1 1 load address is subtracted from the start of
	the last image loaded. If the first image, then
	subtract from the start of where the 512 bytes were
	placed
	______________________________________________________________________



	(For convenience bit 24 is byte 0 of the flag field)



	Bit 26 is the end marker for the net boot process. It is set when this
	is the last information record the net boot process should look at.
	More records may be present, but the net boot process will not look at
	them. (Vendors can continue information records out past the 512
	boundary for private use in this manner).



	The image length tells the net boot process how many bytes are to be
	loaded. Zero is a valid value. This can be used to mark memory areas
	such as shared memory for interprocessor communication, flash eproms,
	data in eproms.



	The image length can also be different from the memory length. This
	allows decompression programs to fluff up the kernel image. It also
	allows a file system to be larger then the loaded file system image.



	Bits 27 through 31 are not defined as yet and must be set to zero
	until they are.


	66.. BBoooott pprroomm eennttrryy ppooiinnttss..


	((ggkk))As mentioned above the net boot process has to provide interrupt
	78h as an entry point in case, the returnable flag (bit 9 of the flags
	field in the image header) of the boot image has been set. When
	calling this interface interrupt, the caller has to load the AH
	register with a value indicating the type of operation requested:







	______________________________________________________________________
	00h - Installation check
	Input: none
	Output: AX - returns the value 474Bh
	BX - flags indicating what further services are
	provided by the net boot program:
	Bit 0 - packet driver interface (see below)
	Bits 1 to 15 are unused and have to be zero

	01h - Cleanup and terminate the boot process services. This will
	also remove the services provided by interrupt 87h.
	Input: none
	Output: none
	______________________________________________________________________





	Further functions are not yet defined. These functions are only
	available to boot images which have the first magic number at the
	beginning of the image header, and have the returnable flag set in the
	flags field.



	In order to provide compatibility with net boot programs written to
	match an earlier version of this document, the loaded image should
	check for the existence of interrupt 78h by looking at it's vector. If
	that's 0:0, or if it does not return a proper magic ID after calling
	the installation check function, the boot image has to assume that the
	net boot program does not support this services interrupt.



	If the bit 0 of register BX of function 00h is set, the boot program
	has to provide a packet driver <http://www.crynwr.com> interface at
	interrupt 79h as described in the packet driver interface standard,
	version 1.09, published by FTP Software, Inc., which is not repeated
	here. It serves as an interface to the system's network card. It is
	important to note that the net boot process has to provide a clean
	packet driver interface without any handles being defined when the
	boot image gets started. It is expected that the boot image sets up
	it's own TCP/IP or other network's stack on top of this packet driver
	interface. When the boot image returns to the net boot process, it
	has to return a clean packet driver interface as well, without any
	handles being defined.((ggkk))


	77.. EExxaammppllee ooff aa bboooott iimmaaggee..


	Here is an example of how the boot image would look for Linux:













	______________________________________________________________________
	0x1B031336, /* magic number */
	0x4, /* length of header is 16 bytes, no vendor info */
	0x90000000, /* location in ds:bx format */
	0x90000200, /* execute address in cs:ip format */

	/* 2048 setup.S bytes */
	0x4, /* flags, not end, absolute address, 16 bytes this
	record, no vendor info */
	0x90200, /* load address - note format */
	0x800, /* 4 8 512 byte blocks for linux */
	0x800,

	/* kernel image */
	0x4, /* flags, not end, absolute address, 16 bytes this
	record, no vendor info */
	0x10000, /* load address - note format */
	0x80000, /* 512K (this could be shorter */
	0x80000,

	/* ramdisk for root file system */
	0x04000004, /* flags = last, absolute address, 16 bytes this
	record, no vendor info *//
	0x100000, /* load address - in extended memory */
	0x80000, /* 512K for instance */
	0x80000,

	/* Then follows linux specific information */
	______________________________________________________________________




	88.. TTeerrmmss


	When I say 'the net boot process', I mean the act of loading the image
	into memory, setting up any tables, up until the jump to the required
	location in the image.



	The net booting program executes the net boot process. The net boot
	program may be a rom, but not neccassarily. It is a set of
	instructions and data residing on the booting machine.



	The image, or boot image, consists of the data loaded by the net boot
	process.



	When I say 'the PC boot process', I mean the general PC rom bios boot
	process, the setting up of hardware, the scanning for adaptor roms,
	the execution of adaptor roms, the loading in of the initial boot
	track. The PC boot process will include the net boot process, if one
	is present.



	When I say client, I mean the PC booting up.




	When I say 'image host', I mean the host where the boot image is
	comming from. This may not have the same architecture as the client.



	The bootp protocol is defined in RFC951 and RFC1084. The tftp protocol
	is defined in RFC783. These are available on many sites. See Comer
	1991 for details on how to obtain them.



	A bootp server is the machine that answers the bootp request. It is
	not neccessarily the image host.



	"Can" and "may" means doesn't have to, but is allowed to and might.
	"Must" means just that. "Cannot" means must not.


	99.. RReeffeerreenncceess


	Comer, D.E. 1991, Internetworking with TCP/IP Vol I: Principles,
	Protocols, and Architecture Second Edition, Prentice Hall, Englewood
	Cliffs, N.J., 1991



	Stevens, W.R 1990, Unix Network Programming, Prentice Hall, Englewood
	Cliffs, N.J., 1990