685 lines
28 KiB
Plaintext
Executable File
685 lines
28 KiB
Plaintext
Executable File
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Network Working Group Bill Croft (Stanford University)
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Request for Comments: 951 John Gilmore (Sun Microsystems)
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September 1985
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BOOTSTRAP PROTOCOL (BOOTP)
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1. Status of this Memo
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This RFC suggests a proposed protocol for the ARPA-Internet
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community, and requests discussion and suggestions for improvements.
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Distribution of this memo is unlimited.
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2. Overview
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This RFC describes an IP/UDP bootstrap protocol (BOOTP) which allows
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a diskless client machine to discover its own IP address, the address
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of a server host, and the name of a file to be loaded into memory and
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executed. The bootstrap operation can be thought of as consisting of
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TWO PHASES. This RFC describes the first phase, which could be
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labeled 'address determination and bootfile selection'. After this
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address and filename information is obtained, control passes to the
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second phase of the bootstrap where a file transfer occurs. The file
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transfer will typically use the TFTP protocol [9], since it is
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intended that both phases reside in PROM on the client. However
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BOOTP could also work with other protocols such as SFTP [3] or
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FTP [6].
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We suggest that the client's PROM software provide a way to do a
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complete bootstrap without 'user' interaction. This is the type of
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boot that would occur during an unattended power-up. A mechanism
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should be provided for the user to manually supply the necessary
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address and filename information to bypass the BOOTP protocol and
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enter the file transfer phase directly. If non-volatile storage is
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available, we suggest keeping default settings there and bypassing
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the BOOTP protocol unless these settings cause the file transfer
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phase to fail. If the cached information fails, the bootstrap should
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fall back to phase 1 and use BOOTP.
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Here is a brief outline of the protocol:
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1. A single packet exchange is performed. Timeouts are used to
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retransmit until a reply is received. The same packet field
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layout is used in both directions. Fixed length fields of maximum
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reasonable length are used to simplify structure definition and
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parsing.
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2. An 'opcode' field exists with two values. The client
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broadcasts a 'bootrequest' packet. The server then answers with a
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'bootreply' packet. The bootrequest contains the client's
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hardware address and its IP address, if known.
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Croft & Gilmore [Page 1]
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RFC 951 September 1985
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Bootstrap Protocol
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3. The request can optionally contain the name of the server the
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client wishes to respond. This is so the client can force the
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boot to occur from a specific host (e.g. if multiple versions of
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the same bootfile exist or if the server is in a far distant
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net/domain). The client does not have to deal with name / domain
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services; instead this function is pushed off to the BOOTP server.
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4. The request can optionally contain the 'generic' filename to be
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booted. For example 'unix' or 'ethertip'. When the server sends
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the bootreply, it replaces this field with the fully qualified
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path name of the appropriate boot file. In determining this name,
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the server may consult his own database correlating the client's
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address and filename request, with a particular boot file
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customized for that client. If the bootrequest filename is a null
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string, then the server returns a filename field indicating the
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'default' file to be loaded for that client.
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5. In the case of clients who do not know their IP addresses, the
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server must also have a database relating hardware address to IP
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address. This client IP address is then placed into a field in
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the bootreply.
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6. Certain network topologies (such as Stanford's) may be such
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that a given physical cable does not have a TFTP server directly
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attached to it (e.g. all the gateways and hosts on a certain cable
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may be diskless). With the cooperation of neighboring gateways,
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BOOTP can allow clients to boot off of servers several hops away,
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through these gateways. See the section 'Booting Through
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Gateways' below. This part of the protocol requires no special
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action on the part of the client. Implementation is optional and
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requires a small amount of additional code in gateways and
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servers.
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3. Packet Format
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All numbers shown are decimal, unless indicated otherwise. The BOOTP
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packet is enclosed in a standard IP [8] UDP [7] datagram. For
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simplicity it is assumed that the BOOTP packet is never fragmented.
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Any numeric fields shown are packed in 'standard network byte order',
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i.e. high order bits are sent first.
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In the IP header of a bootrequest, the client fills in its own IP
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source address if known, otherwise zero. When the server address is
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unknown, the IP destination address will be the 'broadcast address'
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255.255.255.255. This address means 'broadcast on the local cable,
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(I don't know my net number)' [4].
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Croft & Gilmore [Page 2]
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RFC 951 September 1985
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Bootstrap Protocol
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The UDP header contains source and destination port numbers. The
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BOOTP protocol uses two reserved port numbers, 'BOOTP client' (68)
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and 'BOOTP server' (67). The client sends requests using 'BOOTP
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server' as the destination port; this is usually a broadcast. The
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server sends replies using 'BOOTP client' as the destination port;
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depending on the kernel or driver facilities in the server, this may
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or may not be a broadcast (this is explained further in the section
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titled 'Chicken/Egg issues' below). The reason TWO reserved ports
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are used, is to avoid 'waking up' and scheduling the BOOTP server
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daemons, when a bootreply must be broadcast to a client. Since the
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server and other hosts won't be listening on the 'BOOTP client' port,
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any such incoming broadcasts will be filtered out at the kernel
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level. We could not simply allow the client to pick a 'random' port
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number for the UDP source port field; since the server reply may be
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broadcast, a randomly chosen port number could confuse other hosts
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that happened to be listening on that port.
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The UDP length field is set to the length of the UDP plus BOOTP
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portions of the packet. The UDP checksum field can be set to zero by
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the client (or server) if desired, to avoid this extra overhead in a
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PROM implementation. In the 'Packet Processing' section below the
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phrase '[UDP checksum.]' is used whenever the checksum might be
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verified/computed.
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FIELD BYTES DESCRIPTION
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----- ----- -----------
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op 1 packet op code / message type.
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1 = BOOTREQUEST, 2 = BOOTREPLY
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htype 1 hardware address type,
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see ARP section in "Assigned Numbers" RFC.
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'1' = 10mb ethernet
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hlen 1 hardware address length
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(eg '6' for 10mb ethernet).
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hops 1 client sets to zero,
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optionally used by gateways
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in cross-gateway booting.
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xid 4 transaction ID, a random number,
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used to match this boot request with the
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responses it generates.
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secs 2 filled in by client, seconds elapsed since
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client started trying to boot.
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Croft & Gilmore [Page 3]
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RFC 951 September 1985
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Bootstrap Protocol
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-- 2 unused
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ciaddr 4 client IP address;
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filled in by client in bootrequest if known.
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yiaddr 4 'your' (client) IP address;
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filled by server if client doesn't
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know its own address (ciaddr was 0).
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siaddr 4 server IP address;
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returned in bootreply by server.
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giaddr 4 gateway IP address,
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used in optional cross-gateway booting.
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chaddr 16 client hardware address,
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filled in by client.
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sname 64 optional server host name,
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null terminated string.
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file 128 boot file name, null terminated string;
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'generic' name or null in bootrequest,
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fully qualified directory-path
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name in bootreply.
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vend 64 optional vendor-specific area,
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e.g. could be hardware type/serial on request,
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or 'capability' / remote file system handle
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on reply. This info may be set aside for use
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by a third phase bootstrap or kernel.
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4. Chicken / Egg Issues
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How can the server send an IP datagram to the client, if the client
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doesnt know its own IP address (yet)? Whenever a bootreply is being
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sent, the transmitting machine performs the following operations:
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1. If the client knows its own IP address ('ciaddr' field is
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nonzero), then the IP can be sent 'as normal', since the client
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will respond to ARPs [5].
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2. If the client does not yet know its IP address (ciaddr zero),
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then the client cannot respond to ARPs sent by the transmitter of
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the bootreply. There are two options:
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a. If the transmitter has the necessary kernel or driver hooks
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Croft & Gilmore [Page 4]
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RFC 951 September 1985
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Bootstrap Protocol
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to 'manually' construct an ARP address cache entry, then it can
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fill in an entry using the 'chaddr' and 'yiaddr' fields. Of
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course, this entry should have a timeout on it, just like any
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other entry made by the normal ARP code itself. The
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transmitter of the bootreply can then simply send the bootreply
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to the client's IP address. UNIX (4.2 BSD) has this
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capability.
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b. If the transmitter lacks these kernel hooks, it can simply
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send the bootreply to the IP broadcast address on the
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appropriate interface. This is only one additional broadcast
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over the previous case.
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5. Client Use of ARP
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The client PROM must contain a simple implementation of ARP, e.g. the
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address cache could be just one entry in size. This will allow a
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second-phase-only boot (TFTP) to be performed when the client knows
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the IP addresses and bootfile name.
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Any time the client is expecting to receive a TFTP or BOOTP reply, it
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should be prepared to answer an ARP request for its own IP to
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hardware address mapping (if known).
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Since the bootreply will contain (in the hardware encapsulation) the
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hardware source address of the server/gateway, the client MAY be able
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to avoid sending an ARP request for the server/gateway IP address to
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be used in the following TFTP phase. However this should be treated
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only as a special case, since it is desirable to still allow a
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second-phase-only boot as described above.
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6. Comparison to RARP
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An earlier protocol, Reverse Address Resolution Protocol (RARP) [1]
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was proposed to allow a client to determine its IP address, given
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that it knew its hardware address. However RARP had the disadvantage
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that it was a hardware link level protocol (not IP/UDP based). This
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means that RARP could only be implemented on hosts containing special
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kernel or driver modifications to access these 'raw' packets. Since
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there are many network kernels existent now, with each source
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maintained by different organizations, a boot protocol that does not
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require kernel modifications is a decided advantage.
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BOOTP provides this hardware to IP address lookup function, in
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addition to the other useful features described in the sections
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above.
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Croft & Gilmore [Page 5]
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RFC 951 September 1985
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Bootstrap Protocol
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7. Packet Processing
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7.1. Client Transmission
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Before setting up the packet for the first time, it is a good idea
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to clear the entire packet buffer to all zeros; this will place
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all fields in their default state. The client then creates a
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packet with the following fields.
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The IP destination address is set to 255.255.255.255. (the
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broadcast address) or to the server's IP address (if known). The
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IP source address and 'ciaddr' are set to the client's IP address
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if known, else 0. The UDP header is set with the proper length;
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source port = 'BOOTP client' port destination port = 'BOOTP
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server' port.
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'op' is set to '1', BOOTREQUEST. 'htype' is set to the hardware
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address type as assigned in the ARP section of the "Assigned
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Numbers" RFC. 'hlen' is set to the length of the hardware address,
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e.g. '6' for 10mb ethernet.
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'xid' is set to a 'random' transaction id. 'secs' is set to the
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number of seconds that have elapsed since the client has started
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booting. This will let the servers know how long a client has
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been trying. As the number gets larger, certain servers may feel
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more 'sympathetic' towards a client they don't normally service.
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If a client lacks a suitable clock, it could construct a rough
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estimate using a loop timer. Or it could choose to simply send
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this field as always a fixed value, say 100 seconds.
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If the client knows its IP address, 'ciaddr' (and the IP source
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address) are set to this value. 'chaddr' is filled in with the
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client's hardware address.
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If the client wishes to restrict booting to a particular server
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name, it may place a null-terminated string in 'sname'. The name
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used should be any of the allowable names or nicknames of the
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desired host.
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The client has several options for filling the 'file' name field.
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If left null, the meaning is 'I want to boot the default file for
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my machine'. A null file name can also mean 'I am only interested
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in finding out client/server/gateway IP addresses, I dont care
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about file names'.
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The field can also be a 'generic' name such as 'unix' or
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Croft & Gilmore [Page 6]
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RFC 951 September 1985
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Bootstrap Protocol
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'gateway'; this means 'boot the named program configured for my
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machine'. Finally the field can be a fully directory qualified
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path name.
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The 'vend' field can be filled in by the client with
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vendor-specific strings or structures. For example the machine
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hardware type or serial number may be placed here. However the
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operation of the BOOTP server should not DEPEND on this
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information existing.
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If the 'vend' field is used, it is recommended that a 4 byte
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'magic number' be the first item within 'vend'. This lets a
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server determine what kind of information it is seeing in this
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field. Numbers can be assigned by the usual 'magic number'
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process --you pick one and it's magic. A different magic number
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could be used for bootreply's than bootrequest's to allow the
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client to take special action with the reply information.
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[UDP checksum.]
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7.2. Client Retransmission Strategy
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If no reply is received for a certain length of time, the client
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should retransmit the request. The time interval must be chosen
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carefully so as not to flood the network. Consider the case of a
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cable containing 100 machines that are just coming up after a
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power failure. Simply retransmitting the request every four
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seconds will inundate the net.
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As a possible strategy, you might consider backing off
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exponentially, similar to the way ethernet backs off on a
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collision. So for example if the first packet is at time 0:00,
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the second would be at :04, then :08, then :16, then :32, then
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:64. You should also randomize each time; this would be done
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similar to the ethernet specification by starting with a mask and
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'and'ing that with with a random number to get the first backoff.
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On each succeeding backoff, the mask is increased in length by one
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bit. This doubles the average delay on each backoff.
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After the 'average' backoff reaches about 60 seconds, it should be
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increased no further, but still randomized.
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Before each retransmission, the client should update the 'secs'
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field. [UDP checksum.]
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Croft & Gilmore [Page 7]
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RFC 951 September 1985
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Bootstrap Protocol
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7.3. Server Receives BOOTREQUEST
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[UDP checksum.] If the UDP destination port does not match the
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'BOOTP server' port, discard the packet.
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If the server name field (sname) is null (no particular server
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specified), or sname is specified and matches our name or
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nickname, then continue with packet processing.
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If the sname field is specified, but does not match 'us', then
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there are several options:
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1. You may choose to simply discard this packet.
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2. If a name lookup on sname shows it to be on this same cable,
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discard the packet.
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3. If sname is on a different net, you may choose to forward
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the packet to that address. If so, check the 'giaddr' (gateway
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address) field. If 'giaddr' is zero, fill it in with my
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address or the address of a gateway that can be used to get to
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that net. Then forward the packet.
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If the client IP address (ciaddr) is zero, then the client does
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not know its own IP address. Attempt to lookup the client
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hardware address (chaddr, hlen, htype) in our database. If no
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match is found, discard the packet. Otherwise we now have an IP
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address for this client; fill it into the 'yiaddr' (your IP
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address) field.
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We now check the boot file name field (file). The field will be
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null if the client is not interested in filenames, or wants the
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default bootfile. If the field is non-null, it is used as a
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lookup key in a database, along with the client's IP address. If
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there is a default file or generic file (possibly indexed by the
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client address) or a fully-specified path name that matches, then
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replace the 'file' field with the fully-specified path name of the
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selected boot file. If the field is non-null and no match was
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found, then the client is asking for a file we dont have; discard
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the packet, perhaps some other BOOTP server will have it.
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The 'vend' vendor-specific data field should now be checked and if
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a recognized type of data is provided, client-specific actions
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should be taken, and a response placed in the 'vend' data field of
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the reply packet. For example, a workstation client could provide
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Croft & Gilmore [Page 8]
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RFC 951 September 1985
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Bootstrap Protocol
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an authentication key and receive from the server a capability for
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remote file access, or a set of configuration options, which can
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be passed to the operating system that will shortly be booted in.
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Place my (server) IP address in the 'siaddr' field. Set the 'op'
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field to BOOTREPLY. The UDP destination port is set to 'BOOTP
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client'. If the client address 'ciaddr' is nonzero, send the
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packet there; else if the gateway address 'giaddr' is nonzero, set
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the UDP destination port to 'BOOTP server' and send the packet to
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'giaddr'; else the client is on one of our cables but it doesnt
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know its own IP address yet --use a method described in the 'Egg'
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section above to send it to the client. If 'Egg' is used and we
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have multiple interfaces on this host, use the 'yiaddr' (your IP
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address) field to figure out which net (cable/interface) to send
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the packet to. [UDP checksum.]
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7.4. Server/Gateway Receives BOOTREPLY
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[UDP checksum.] If 'yiaddr' (your [the client's] IP address)
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refers to one of our cables, use one of the 'Egg' methods above to
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forward it to the client. Be sure to send it to the 'BOOTP
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client' UDP destination port.
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7.5. Client Reception
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Don't forget to process ARP requests for my own IP address (if I
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know it). [UDP checksum.] The client should discard incoming
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packets that: are not IP/UDPs addressed to the boot port; are not
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BOOTREPLYs; do not match my IP address (if I know it) or my
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hardware address; do not match my transaction id. Otherwise we
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have received a successful reply. 'yiaddr' will contain my IP
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address, if I didnt know it before. 'file' is the name of the
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file name to TFTP 'read request'. The server address is in
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'siaddr'. If 'giaddr' (gateway address) is nonzero, then the
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packets should be forwarded there first, in order to get to the
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server.
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8. Booting Through Gateways
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This part of the protocol is optional and requires some additional
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code in cooperating gateways and servers, but it allows cross-gateway
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booting. This is mainly useful when gateways are diskless machines.
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Gateways containing disks (e.g. a UNIX machine acting as a gateway),
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might as well run their own BOOTP/TFTP servers.
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Gateways listening to broadcast BOOTREQUESTs may decide to forward or
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rebroadcast these requests 'when appropriate'. For example, the
|
||
|
||
|
||
Croft & Gilmore [Page 9]
|
||
|
||
|
||
|
||
RFC 951 September 1985
|
||
Bootstrap Protocol
|
||
|
||
|
||
gateway could have, as part of his configuration tables, a list of
|
||
other networks or hosts to receive a copy of any broadcast
|
||
BOOTREQUESTs. Even though a 'hops' field exists, it is a poor idea
|
||
to simply globally rebroadcast the requests, since broadcast loops
|
||
will almost certainly occur.
|
||
|
||
The forwarding could begin immediately, or wait until the 'secs'
|
||
(seconds client has been trying) field passes a certain threshold.
|
||
|
||
If a gateway does decide to forward the request, it should look at
|
||
the 'giaddr' (gateway IP address) field. If zero, it should plug its
|
||
own IP address (on the receiving cable) into this field. It may also
|
||
use the 'hops' field to optionally control how far the packet is
|
||
reforwarded. Hops should be incremented on each forwarding. For
|
||
example, if hops passes '3', the packet should probably be discarded.
|
||
[UDP checksum.]
|
||
|
||
Here we have recommended placing this special forwarding function in
|
||
the gateways. But that does not have to be the case. As long as
|
||
some 'BOOTP forwarding agent' exists on the net with the booting
|
||
client, the agent can do the forwarding when appropriate. Thus this
|
||
service may or may not be co-located with the gateway.
|
||
|
||
In the case of a forwarding agent not located in the gateway, the
|
||
agent could save himself some work by plugging the broadcast address
|
||
of the interface receiving the bootrequest into the 'giaddr' field.
|
||
Thus the reply would get forwarded using normal gateways, not
|
||
involving the forwarding agent. Of course the disadvantage here is
|
||
that you lose the ability to use the 'Egg' non-broadcast method of
|
||
sending the reply, causing extra overhead for every host on the
|
||
client cable.
|
||
|
||
9. Sample BOOTP Server Database
|
||
|
||
As a suggestion, we show a sample text file database that the BOOTP
|
||
server program might use. The database has two sections, delimited
|
||
by a line containing an percent in column 1. The first section
|
||
contains a 'default directory' and mappings from generic names to
|
||
directory/pathnames. The first generic name in this section is the
|
||
'default file' you get when the bootrequest contains a null 'file'
|
||
string.
|
||
|
||
The second section maps hardware addresstype/address into an
|
||
ipaddress. Optionally you can also overide the default generic name
|
||
by supplying a ipaddress specific genericname. A 'suffix' item is
|
||
also an option; if supplied, any generic names specified by the
|
||
client will be accessed by first appending 'suffix' to the 'pathname'
|
||
|
||
|
||
Croft & Gilmore [Page 10]
|
||
|
||
|
||
|
||
RFC 951 September 1985
|
||
Bootstrap Protocol
|
||
|
||
|
||
appropriate to that generic name. If that file is not found, then
|
||
the plain 'pathname' will be tried. This 'suffix' option allows a
|
||
whole set of custom generics to be setup without a lot of effort.
|
||
Below is shown the general format; fields are delimited by one or
|
||
more spaces or tabs; trailing empty fields may be omitted; blank
|
||
lines and lines beginning with '#' are ignored.
|
||
|
||
# comment line
|
||
|
||
homedirectory
|
||
genericname1 pathname1
|
||
genericname2 pathname2
|
||
...
|
||
|
||
% end of generic names, start of address mappings
|
||
|
||
hostname1 hardwaretype hardwareaddr1 ipaddr1 genericname suffix
|
||
hostname2 hardwaretype hardwareaddr2 ipaddr2 genericname suffix
|
||
...
|
||
|
||
Here is a specific example. Note the 'hardwaretype' number is the
|
||
same as that shown in the ARP section of the 'Assigned Numbers' RFC.
|
||
The 'hardwaretype' and 'ipaddr' numbers are in decimal;
|
||
'hardwareaddr' is in hex.
|
||
|
||
# last updated by smith
|
||
|
||
/usr/boot
|
||
vmunix vmunix
|
||
tip ethertip
|
||
watch /usr/diag/etherwatch
|
||
gate gate.
|
||
|
||
% end of generic names, start of address mappings
|
||
|
||
hamilton 1 02.60.8c.06.34.98 36.19.0.5
|
||
burr 1 02.60.8c.34.11.78 36.44.0.12
|
||
101-gateway 1 02.60.8c.23.ab.35 36.44.0.32 gate 101
|
||
mjh-gateway 1 02.60.8c.12.32.bc 36.42.0.64 gate mjh
|
||
welch-tipa 1 02.60.8c.22.65.32 36.47.0.14 tip
|
||
welch-tipb 1 02.60.8c.12.15.c8 36.46.0.12 tip
|
||
|
||
In the example above, if 'mjh-gateway' does a default boot, it will
|
||
get the file '/usr/boot/gate.mjh'.
|
||
|
||
|
||
|
||
|
||
|
||
Croft & Gilmore [Page 11]
|
||
|
||
|
||
|
||
RFC 951 September 1985
|
||
Bootstrap Protocol
|
||
|
||
|
||
10. Acknowledgements
|
||
|
||
Ross Finlayson (et. al.) produced two earlier RFC's discussing TFTP
|
||
bootstraping [2] using RARP [1].
|
||
|
||
We would also like to acknowledge the previous work and comments of
|
||
Noel Chiappa, Bob Lyon, Jeff Mogul, Mark Lewis, and David Plummer.
|
||
|
||
REFERENCES
|
||
|
||
1. Ross Finlayson, Timothy Mann, Jeffrey Mogul, Marvin Theimer. A
|
||
Reverse Address Resolution Protocol. RFC 903, NIC, June, 1984.
|
||
|
||
2. Ross Finlayson. Bootstrap Loading using TFTP. RFC 906, NIC,
|
||
June, 1984.
|
||
|
||
3. Mark Lottor. Simple File Transfer Protocol. RFC 913, NIC,
|
||
September, 1984.
|
||
|
||
4. Jeffrey Mogul. Broadcasting Internet Packets. RFC 919, NIC,
|
||
October, 1984.
|
||
|
||
5. David Plummer. An Ethernet Address Resolution Protocol. RFC
|
||
826, NIC, September, 1982.
|
||
|
||
6. Jon Postel. File Transfer Protocol. RFC 765, NIC, June, 1980.
|
||
|
||
7. Jon Postel. User Datagram Protocol. RFC 768, NIC, August, 1980.
|
||
|
||
8. Jon Postel. Internet Protocol. RFC 791, NIC, September, 1981.
|
||
|
||
9. K. R. Sollins, Noel Chiappa. The TFTP Protocol. RFC 783, NIC,
|
||
June, 1981.
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|
||
Croft & Gilmore [Page 12]
|
||
|