man/man4/factotum.4 - plan9 - Git at Google

 .TH FACTOTUM 4
 .SH NAME
 factotum \- authentication agent
 .SH SYNOPSIS
 .B factotum
 [
 .B -DdkSun
 ] [
 .B -a authaddr
 ] [
 .B -s
 .I srvname
 ]
 .\" [
 .\" .B -m
 .\" .I mtpt
 .\" ]
 .PP
 .B factotum
 .B -g
 .IB attribute = value
 .B ...
 .IB attribute ?
 .B ...
 .\" .PP
 .\" .B auth/fgui
 .SH DESCRIPTION
 .I Factotum
 is a user-level file system that
 acts as the authentication agent for a user.
 It does so by managing a set of
 .IR keys .
 A key is a collection of information used to authenticate a particular action.
 Stored as a list of
 .IB attribute = value
 pairs, a key typically contains a user, an authentication domain, a protocol, and
 some secret data.
 .PP
 .I Factotum
 presents the following files:
 .TF needkey
 .TP
 .B rpc
 each open represents a new private channel to
 .I factotum
 .TP
 .B proto
 when read lists the protocols available
 .TP
 .B confirm
 for confiming the use of key
 .TP
 .B needkey
 allows external programs to control the addition of new keys
 .TP
 .B log
 a log of actions
 .TP
 .B ctl
 for maintaining keys; when read, it returns a list of keys.
 For secret attributes, only the attribute name follow by a
 .L ?
 is returned.
 .PD
 .PP
 In any authentication, the caller typically acts as a client
 and the callee as a server.  The server determines
 the authentication domain, sometimes after a negotiation with
 the client.  Authentication always requires the client to
 prove its identity to the server.  Under some protocols, the
 authentication is mutual.
 Proof is accomplished using secret information kept by factotum
 in conjunction with a cryptographic protocol.
 .PP
 .I Factotum
 can act in the role of client for any process possessing the
 same user id as it.  For select protocols such as
 .B p9sk1
 it can also act as a client for other processes provided
 its user id may speak for the other process' user id (see
 Plan 9's
 \fIauthsrv\fR(6)).
 .I Factotum
 can act in the role of server for any process.
 .PP
 .IR Factotum 's
 structure is independent of
 any particular authentication protocol.
 .I Factotum
 supports the following protocols:
 .TF mschap
 .TP
 .B p9any
 a metaprotocol used to negotiate which actual protocol to use.
 .TP
 .B p9sk1
 a Plan 9 shared key protocol.
 .TP
 .B p9sk2
 a variant of
 .B p9sk1.
 .TP
 .B p9cr
 a Plan 9 protocol that can use either
 .B p9sk1
 keys or SecureID tokens.
 .TP
 .B apop
 the challenge/response protocol used by POP3 mail servers.
 .TP
 .B cram
 the challenge/response protocol also used by POP3 mail servers.
 .TP
 .B chap
 the challenge/response protocols used by PPP and PPTP.
 .TP
 .B dsa
 DSA signatures, used by SSH
 .TP
 .B mschap
 a proprietary Microsoft protocol also used by PPP and PPTP.
 .TP
 .B rsa
 RSA encryption and signatures, used by SSH and TLS.
 .TP
 .B pass
 passwords in the clear.
 .TP
 .B vnc
 .IR vnc (1)'s
 challenge/response.
 .TP
 .B wep
 WEP passwords for wireless ethernet cards.
 .PD
 The ``Protocols'' section below describes these protocols in more detail.
 .PP
 The options to
 .I factotum
 are:
 .TP
 .B \-a
 supplies the address of the authentication server to use.
 Without this option, it will attempt to find an authentication server by
 querying the connection server, the file
 .BR <mtpt>/ndb ,
 and finally the network database in
 .BR /lib/ndb .
 .TP
 .B \-m
 specifies the mount point to use, by default
 .BR /mnt .
 .TP
 .B \-s
 specifies the service name to use.
 Without this option,
 .I factotum
 does not create a service file in
 .BR /srv .
 .TP
 .B \-D
 turns on 9P tracing, written to standard error.
 .TP
 .B \-d
 turns on debugging, written to standard error.
 .TP
 .B \-g
 causes the agent to prompt for the key, write it
 to the
 .B ctl
 file, and exit.
 The agent will prompt for values for any of the
 attributes ending with a question mark
 .RB ( ? )
 and will append all the supplied
 .I attribute = value
 pairs.  See the section on key templates below.
 .TP
 .B \-n
 don't look for a secstore.
 .TP
 .B \-S
 indicates that the agent is running on a
 cpu server.  On starting, it will attempt to get a
 .B 9psk1
 key from NVRAM using
 .B readnvram
 (see
 .IR authsrv (3)),
 prompting for anything it needs.
 It will never subsequently prompt for a
 key that it doesn't have.
 This option is typically used by
 the kernel at boot time.
 .TP
 .B \-k
 causes the NVRAM to be written.
 It is only valid with the
 .B \-S
 option.
 This option is typically used by
 the kernel at boot time.
 .TP
 .B \-u
 causes the agent to prompt for user
 id and writes it to
 .BR /dev/hostowner .
 It is mutually exclusive with
 .B \-k
 and
 .BR \-S .
 This option is typically used by
 the kernel at boot time.
 .PD
 .\" .PP
 .\" .I Fgui
 .\" is a graphic user interface for confirming key usage and
 .\" entering new keys.  It hides the window in which it starts
 .\" and waits reading requests from
 .\" .B confirm
 .\" and
 .\" .BR needkey .
 .\" For each requests, it unhides itself and waits for
 .\" user input.
 .\" See the sections on key confirmation and key prompting below.
 .SS "Key Tuples
 .PP
 A
 .I "key tuple
 is a space delimited list of
 .IB attribute = value
 pairs.  An attribute whose name begins with an exclamation point
 .RB ( ! )
 does not appear when reading the
 .B ctl
 file.
 Here are some examples:
 .EX
     proto=p9sk1 dom=avayalabs.com user=presotto !password=lucent
     proto=apop server=mit.edu user=rsc !password=nerdsRus
     proto=pass user=tb service=ssh !password=does.it.matter
 .EE
 The ``Protocols'' section below describes the attributes
 specific to each supported protocol.
 .PP
 All keys can have additional attibutes that act either as comments
 or as selectors to distinguish them in the
 .IR auth (3)
 library calls.
 .PP
 The factotum owner can use any key stored by factotum.
 Any key may have one or more
 .B owner
 attributes listing the users who can use the key
 as though they were the owner.
 For example, the TLS and SSH host keys on a server
 often have an attribute
 .B owner=*
 to allow any user (and in particular,
 .L none )
 to run the TLS or SSH server-side protocol.
 .PP
 Any key may have a
 .B role
 attribute for restricting how it can be used.
 If this attribute is missing, the key can be used in any role.
 Common values are:
 .TP
 .B client
 for authenticating outbound calls
 .TP
 .B server
 for authenticating inbound calls
 .TP
 .B speaksfor
 for authenticating processes whose
 user id does not match
 .IR factotum 's.
 .TP
 .B encrypt
 for encrypting data
 .TP
 .B decrypt
 for decrypting data
 .TP
 .B sign
 for cryptographically signing data
 .TP
 .B verify
 for verifying cryptographic signatures
 .PD
 .PP
 Whenever
 .I factotum
 runs as a server, it must have a
 .B p9sk1
 key in order to communicate with the authentication
 server for validating passwords and challenge/responses of
 other users.
 .SS "Key Templates
 Key templates are used by routines that interface to
 .I factotum
 such as
 .B auth_proxy
 and
 .B auth_challenge
 (see
 .IR auth (3))
 to specify which key and protocol to use for an authentication.
 Like a key tuple, a key template is also a list of
 .IB attribute = value
 pairs.
 It must specify at least the protocol and enough
 other attributes to uniquely identify a key, or set of keys, to use.
 The keys chosen are those that match all the attributes specified
 in the template.  The possible attribute/value formats are:
 .TP 1i
 .IB attr = val
 The attribute
 .I attr
 must exist in the key and its value must exactly
 match
 .I val
 .TP 1i
 .IB attr ?
 The attribute
 .I attr
 must exist in the key but its value doesn't matter.
 .TP 1i
 .I attr
 The attribute
 .I attr
 must exist in the key with a null value
 .PD
 .PP
 Key templates are also used by factotum to request a key either via
 an RPC error or via the
 .B needkey
 interface.
 The possible attribute/value formats are:
 .TP 1i
 .IB attr = val
 This pair must remain unchanged
 .TP 1i
 .IB attr ?
 This attribute needs a value
 .TP 1i
 .I attr
 The pair must remain unchanged
 .PD
 .SS "Control and Key Management
 .PP
 A number of messages can be written to the control file.
 The mesages are:
 .TP
 .B "key \fIattribute-value-list\fP
 add a new key.  This will replace any old key whose
 public, i.e. non ! attributes, match.
 .TP
 .B "delkey \fIattribute-value-list\fP
 delete a key whose attributes match those given.
 .TP
 .B debug
 toggle debugging on and off, i.e., the debugging also
 turned on by the
 .B \-d
 option.
 .PP
 By default when factotum starts it looks for a
 .IR secstore (1)
 account on $auth for the user and, if one exists,
 prompts for a secstore password in order to fetch
 the file
 .IR factotum ,
 which should contain control file commands.
 An example would be
 .EX
   key dom=x.com proto=p9sk1 user=boyd !hex=26E522ADE2BBB2A229
   key proto=rsa service=ssh size=1024 ek=3B !dk=...
 .EE
 where the first line sets a password for
 challenge/response authentication, strong against dictionary
 attack by being a long random string, and the second line
 sets a public/private keypair for ssh authentication,
 generated by
 .B ssh_genkey
 (see
 .IR ssh (1)).
 .PD
 .SS "Confirming key use
 .PP
 The
 .B confirm
 file provides a connection from
 .I factotum
 to a confirmation server, normally the program
 .IR auth/fgui .
 Whenever a key with the
 .B confirm
 attribute is used,
 .I factotum
 requires confirmation of its use.  If no process has
 .B confirm
 opened, use of the key will be denied.
 However, if the file is opened a request can be read from it
 with the following format:
 .PP
 .B confirm
 .BI tag= tagno
 .I "<key template>
 .PP
 The reply, written back to
 .BR confirm ,
 consists of string:
 .PP
 .BI tag= tagno
 .BI answer= xxx
 .PP
 If
 .I xxx
 is the string
 .B yes
 then the use is confirmed and the authentication will proceed.
 Otherwise, it fails.
 .PP
 .B Confirm
 is exclusive open and can only be opened by a process with
 the same user id as
 .IR factotum .
 .SS "Prompting for keys
 .PP
 The
 .B needkey
 file provides a connection from
 .I factotum
 to a key server, normally the program
 .IR auth/fgui .
 Whenever
 .I factotum
 needs a new key, it first checks to see if
 .B needkey
 is opened.  If it isn't, it returns a error to its client.
 If the file is opened a request can be read from it
 with the following format:
 .PP
 .B needkey
 .BI tag= tagno
 .I "<key template>
 .PP
 It is up to the reader to then query the user for any missing fields,
 write the key tuple into the
 .B ctl
 file, and then reply by writing into the
 .B needkey
 file the string:
 .PP
 .BI tag= tagno
 .PP
 .B Needkey
 is exclusive open and can only be opened by a process with
 the same user id as
 .IR factotum .
 .SS "The RPC Protocol
 Authentication is performed by
 .IP 1)
 opening
 .BR rpc
 .IP 2)
 setting up the protocol and key to be used (see the
 .B start
 RPC below),
 .IP 3)
 shuttling messages back and forth between
 .IR factotum
 and the other party (see the
 .B read
 and
 .B write
 RPC's) until done
 .IP 4)
 if successful, reading back an
 .I AuthInfo
 structure (see
 .IR authsrv (3)).
 .PP
 The RPC protocol is normally embodied by one of the
 routines in
 .IR auth (3).
 We describe it here should anyone want to extend
 the library.
 .PP
 An RPC consists of writing a request message to
 .B rpc
 followed by reading a reply message back.
 RPC's are strictly ordered; requests and replies of
 different RPC's cannot be interleaved.
 Messages consist of a verb, a single space, and data.
 The data format depends on the verb.  The request verbs are:
 .TP
 .B "start \fIattribute-value-list\fP
 start a new authentication.
 .I Attribute-value-pair-list
 must include a
 .B proto
 attribute, a
 .B role
 attribute with value
 .B client
 or
 .BR server ,
 and enough other attibutes to uniquely identify a key to use.
 A
 .B start
 RPC is required before any others.    The possible replies are:
 .RS
 .TP
 .B ok
 start succeeded.
 .TP
 .B "error \fIstring\fP
 where
 .I string
 is the reason.
 .RE
 .PD
 .TP
 .B read
 get data from
 .I factotum
 to send to the other party.  The possible replies are:
 .RS
 .TP
 .B ok
 read succeeded, this is zero length message.
 .TP
 .B "ok \fIdata\fP
 read succeeded, the data follows the space and is
 unformatted.
 .TP
 .B "done
 authentication has succeeded, no further RPC's are
 necessary
 .TP
 .B "done haveai
 authentication has succeeded, an
 .B AuthInfo
 structure (see
 .IR auth (3))
 can be retrieved with an
 .B authinfo
 RPC
 .TP
 .B "phase \fIstring\fP
 its not your turn to read, get some data from
 the other party and return it with a write RPC.
 .TP
 .B "error \fIstring\fP
 authentication failed,
 .I string
 is the reason.
 .TP
 .B "protocol not started
 a
 .B start
 RPC needs to precede reads and writes
 .TP
 .B "needkey \fIattribute-value-list\fP
 a key matching the argument is needed.  This argument
 may be passed as an argument to
 .I factotum
 .B -g
 in order to prompt for a key.  After that, the
 authentication may proceed, i.e., the read restarted.
 .PD
 .RE
 .TP
 .B "write \fIdata\fP
 send data from the other party to
 .IR factotum .
 The possible replies are:
 .RS
 .TP
 .B "ok
 the write succeeded
 .TP
 .B "needkey \fIattribute-value-list\fP
 see above
 .TP
 .B "toosmall \fIn\fP
 the write is too short, get more data from the
 other party and retry the write.
 .I n
 specifies the maximun total number of bytes.
 .TP
 .B "phase \fIstring\fP
 its not your turn to write, get some data from
 .I factotum
 first.
 .TP
 .B "done
 see above
 .TP
 .B "done haveai
 see above
 .RE
 .TP
 .B readhex\fR, \fPwritehex
 like
 .B read
 and
 .BR write ,
 except that an
 .B ok
 response to
 .B readhex
 returns the data encoded as
 a long hexadecimal string,
 and the argument to
 .B writehex
 is expected to be a long hexadecimal string.
 These are useful for manually debugging of binary protocols.
 .TP
 .B authinfo
 retrieve the AuthInfo structure.
 The possible replies are:
 .RS
 .TP
 .B "ok \fIdata\fP
 .I data
 is a marshaled form of the AuthInfo structure.
 .TP
 .B "error \fIstring\fP
 where
 .I string
 is the reason for the error.
 .PD
 .RE
 .TP
 .B attr
 retrieve the attributes used in the
 .B start
 RPC.
 The possible replies are:
 .RS
 .TP
 .B "ok \fIattribute-value-list\fP
 .TP
 .B "error \fIstring\fP
 where
 .I string
 is the reason for the error.
 .PD
 .RE
 .SS Protocols
 Factotum supports many authentication types, each
 with its own roles and required key attributes.
 .PP
 .IR P9any ,
 .IR p9sk1 ,
 .IR p9sk2 ,
 and
 .I p9cr
 are used to authenticate to Plan 9 systems;
 valid
 .BR role s
 are
 .B client
 and
 .BR server .
 All require
 .B proto=p9sk1
 keys with
 .BR user ,
 .B dom
 (authentication domain),
 and
 .B !password
 attributes.
 .PP
 .I P9sk1
 and
 .I p9sk2
 are the Plan 9 shared-key authentication protocols.
 .I P9sk2
 is a deprecated form of
 .I p9sk1
 that neglects to authenticate the server.
 .PP
 .I P9any
 is a meta-protocol that negotiates a protocol
 .RB ( p9sk1
 or
 .BR p9sk2 )
 and an authentication domain and then invokes the
 given protocol with a
 .B dom=
 attribute.
 .PP
 .IR P9any ,
 .IR p9sk1 ,
 and
 .I p9sk2
 are intended to be proxied via
 .I auth_proxy
 (see
 .IR auth (3)).
 .\" The protocols follow
 .\" .IR p9any (7)
 .\" and
 .\" .IR p9sk1 (7).
 .\" XXX - write about how server keys are selected and used
 .\" XXX - write about protocol itself
 .\" XXX - write about server ai
 .PP
 .I P9cr
 is a textual challenge-response protocol;
 roles are
 .B client
 and
 .BR server .
 It uses
 .I p9sk1
 keys as described above.
 The protocol with
 .I factotum
 is textual:
 client writes a user name,
 server responds with a challenge,
 client writes a response,
 server responds with
 .B ok
 or
 .BR bad .
 Typically this information is wrapped in other protocols
 before being sent over the network.
 .PP
 .I Vnc
 is the challenge-response protocol used by
 .IR vnc (1);
 valid roles are
 .B client
 and
 .BR server .
 The client protocol requires a
 .B proto=vnc
 key with attribute
 .BR !password .
 Conventionally, client keys also have
 .B user
 and
 .B server
 attributes.
 The server protocol requires a
 .I p9sk1
 key as described above.
 The protocol with
 .I factotum
 is the same as
 .IR p9cr ,
 except that the challenge and response are not textual.
 .PP
 .I Apop
 and
 .I cram
 are challenge-response protocols typically
 used to authenticate
 to mail servers.
 The client protocols require
 .B proto=apop
 or
 .B proto=cram
 keys with
 .B user
 and
 .B !password
 attributes.
 Conventionally, client keys also have
 .B server
 attributes.
 The server protocol requires a
 .I p9sk1
 key as described above.
 The protocol with
 .I factotum
 is textual:
 server writes a challenge of the form
 .IB random @ domain \fR,
 client responds with user name
 and then a hexadecimal response
 (two separate writes),
 and then the server responds with
 .B ok
 or
 .BR bad .
 .PP
 .I Chap
 and
 .I mschap
 are challenge-response protocols used in PPP sessions;
 valid roles are
 .B client
 and
 .BR server .
 The client protocols require
 .B proto=chap
 or
 .B proto=mschap
 keys with
 .B user
 and
 .B !password
 attributes.
 Conventionally, client keys also have
 .B server
 attributes.
 The server protocol requires a
 .I p9sk1
 key as described above.
 The protocol with factotum is:
 server writes an 8-byte binary challenge,
 client responds with user name
 and then a
 .B Chapreply
 or
 .B MSchapreply
 structure (defined in
 .B <auth.h> ).
 .PP
 .I Pass
 is a client-only protocol that hands out passwords
 from
 .B proto=pass
 keys with
 .B user
 and
 .B !password
 attributes.
 The protocol is a single read that returns
 a string: a space-separated quoted user name and password
 that can be parsed with
 .I tokenize
 (see
 .IR getfields (3)).
 Conventionally, client keys have distinguishing attributes
 like
 .B service
 and
 .B server
 that can be specified in the
 .B start
 message to select a key.
 .PP
 .I Wep
 is a client-only pseudo-protocol that initializes the encryption
 key on a wireless ethernet device.
 It uses
 .B proto=wep
 keys with
 .BR !key1 ,
 .BR !key2 ,
 or
 .B !key3
 attributes.
 The protocol with
 .I factotum
 is:
 the client writes a device name
 that must begin with
 .LR #l .
 In response,
 .I factotum
 opens the device's control file, sets the wireless secret using the key,
 and turns on encryption.
 If the key has an
 .B essid
 attribute,
 .I factotum
 uses it to set the wireless station ID.
 .PP
 .I Rsa
 is an implementation of the RSA protocol.
 Valid roles are
 .BR decrypt ,
 .BR encrypt ,
 .BR sign ,
 and
 .BR verify .
 .I Rsa
 uses
 .B proto=rsa
 keys with
 .B ek
 and
 .B n
 attributes, large integers specifying the public half
 of the key.
 If a key is to be used for decryption or signing,
 then it must also have attributes
 .BR !p ,
 .BR !q ,
 .BR !kp ,
 .BR !kq ,
 .BR !c2 ,
 and
 .BR !dk
 specifying the private half of the key;
 see
 .IR rsa (3).
 Conventionally,
 .I rsa
 keys also have
 .B service
 attributes specifying the context in which the key is used:
 .B ssh
 (SSH version 1),
 .B ssh-rsa
 (SSH version 2),
 or
 .B tls
 (SSL and TLS).
 If an SSH key has a
 .B comment
 attribute, that comment is presented to remote SSH servers
 during key negotiation.
 The protocol for
 encryption (decryption) is:
 write the message, then read back the encrypted (decrypted) form.
 The protocol for signing is:
 write a hash of the actual message,
 then read back the signature.
 The protocol for verifying a signature is:
 write the message hash,
 write the purported signature,
 then read back
 .B ok
 or
 .B bad
 telling whether the signature could be verified.
 The hash defaults to SHA1 but can be specified by a
 .B hash
 attribute on the key.
 Valid hash functions are
 .B md5
 and
 .BR sha1 .
 The hash function must be known to
 .I factotum
 because the signature encodes the type of hash used.
 The
 .B encrypt
 and
 .B verify
 operations are included as a convenience;
 .I factotum
 is not using any private information to perform them.
 .PP
 .I Dsa
 is an implementation of the NIST digital signature algorithm.
 Valid roles are
 .B sign
 and
 .BR verify .
 It uses
 .B proto=dsa
 keys with
 .BR p ,
 .BR q ,
 .BR alpha ,
 and
 .B key
 attributes.
 If the key is to be used for signing, it must also have a
 .B !secret
 attribute; see
 .IR dsa (3).
 Conventionally,
 .I dsa
 keys
 also have
 .B service
 attributes specifying the context in which the key is used:
 .B ssh-dss
 (SSH version 2)
 is the only one.
 If an SSH key has a
 .B comment
 attribute, that comment is presented to SSH servers during
 key negotiation.
 The protocol for signing and verifying
 is the same as the RSA protocol.
 Unlike
 .IR rsa ,
 the
 .I dsa
 protocol ignores the
 .B hash
 attribute; it always uses SHA1.
 .PP
 .I Httpdigest
 is a client-only MD5-based challenge-response protocol used in HTTP; see RFC 2617.
 It uses
 .B proto=httpdigest
 keys with
 .BR user ,
 .BR realm ,
 and
 .BR !password
 attributes.
 The protocol with factotum is textual:
 write the challenge, read the response.
 The challenge is a string with three space-separated fields
 .IR nonce ,
 .IR method ,
 and
 .IR uri ,
 parseable with
 .IR tokenize .
 The response is a hexadecimal string of length 32.
 .SH SOURCE
 .B \*9/src/cmd/auth/factotum
 .SH SEE ALSO
 .IR ssh-agent (1)
	.TH FACTOTUM 4
	.SH NAME
	factotum \- authentication agent
	.SH SYNOPSIS
	.B factotum
	[
	.B -DdkSun
	] [
	.B -a authaddr
	] [
	.B -s
	.I srvname
	]
	.\" [
	.\" .B -m
	.\" .I mtpt
	.\" ]
	.PP
	.B factotum
	.B -g
	.IB attribute = value
	.B ...
	.IB attribute ?
	.B ...
	.\" .PP
	.\" .B auth/fgui
	.SH DESCRIPTION
	.I Factotum
	is a user-level file system that
	acts as the authentication agent for a user.
	It does so by managing a set of
	.IR keys .
	A key is a collection of information used to authenticate a particular action.
	Stored as a list of
	.IB attribute = value
	pairs, a key typically contains a user, an authentication domain, a protocol, and
	some secret data.
	.PP
	.I Factotum
	presents the following files:
	.TF needkey
	.TP
	.B rpc
	each open represents a new private channel to
	.I factotum
	.TP
	.B proto
	when read lists the protocols available
	.TP
	.B confirm
	for confiming the use of key
	.TP
	.B needkey
	allows external programs to control the addition of new keys
	.TP
	.B log
	a log of actions
	.TP
	.B ctl
	for maintaining keys; when read, it returns a list of keys.
	For secret attributes, only the attribute name follow by a
	.L ?
	is returned.
	.PD
	.PP
	In any authentication, the caller typically acts as a client
	and the callee as a server. The server determines
	the authentication domain, sometimes after a negotiation with
	the client. Authentication always requires the client to
	prove its identity to the server. Under some protocols, the
	authentication is mutual.
	Proof is accomplished using secret information kept by factotum
	in conjunction with a cryptographic protocol.
	.PP
	.I Factotum
	can act in the role of client for any process possessing the
	same user id as it. For select protocols such as
	.B p9sk1
	it can also act as a client for other processes provided
	its user id may speak for the other process' user id (see
	Plan 9's
	\fIauthsrv\fR(6)).
	.I Factotum
	can act in the role of server for any process.
	.PP
	.IR Factotum 's
	structure is independent of
	any particular authentication protocol.
	.I Factotum
	supports the following protocols:
	.TF mschap
	.TP
	.B p9any
	a metaprotocol used to negotiate which actual protocol to use.
	.TP
	.B p9sk1
	a Plan 9 shared key protocol.
	.TP
	.B p9sk2
	a variant of
	.B p9sk1.
	.TP
	.B p9cr
	a Plan 9 protocol that can use either
	.B p9sk1
	keys or SecureID tokens.
	.TP
	.B apop
	the challenge/response protocol used by POP3 mail servers.
	.TP
	.B cram
	the challenge/response protocol also used by POP3 mail servers.
	.TP
	.B chap
	the challenge/response protocols used by PPP and PPTP.
	.TP
	.B dsa
	DSA signatures, used by SSH
	.TP
	.B mschap
	a proprietary Microsoft protocol also used by PPP and PPTP.
	.TP
	.B rsa
	RSA encryption and signatures, used by SSH and TLS.
	.TP
	.B pass
	passwords in the clear.
	.TP
	.B vnc
	.IR vnc (1)'s
	challenge/response.
	.TP
	.B wep
	WEP passwords for wireless ethernet cards.
	.PD
	The ``Protocols'' section below describes these protocols in more detail.
	.PP
	The options to
	.I factotum
	are:
	.TP
	.B \-a
	supplies the address of the authentication server to use.
	Without this option, it will attempt to find an authentication server by
	querying the connection server, the file
	.BR <mtpt>/ndb ,
	and finally the network database in
	.BR /lib/ndb .
	.TP
	.B \-m
	specifies the mount point to use, by default
	.BR /mnt .
	.TP
	.B \-s
	specifies the service name to use.
	Without this option,
	.I factotum
	does not create a service file in
	.BR /srv .
	.TP
	.B \-D
	turns on 9P tracing, written to standard error.
	.TP
	.B \-d
	turns on debugging, written to standard error.
	.TP
	.B \-g
	causes the agent to prompt for the key, write it
	to the
	.B ctl
	file, and exit.
	The agent will prompt for values for any of the
	attributes ending with a question mark
	.RB ( ? )
	and will append all the supplied
	.I attribute = value
	pairs. See the section on key templates below.
	.TP
	.B \-n
	don't look for a secstore.
	.TP
	.B \-S
	indicates that the agent is running on a
	cpu server. On starting, it will attempt to get a
	.B 9psk1
	key from NVRAM using
	.B readnvram
	(see
	.IR authsrv (3)),
	prompting for anything it needs.
	It will never subsequently prompt for a
	key that it doesn't have.
	This option is typically used by
	the kernel at boot time.
	.TP
	.B \-k
	causes the NVRAM to be written.
	It is only valid with the
	.B \-S
	option.
	This option is typically used by
	the kernel at boot time.
	.TP
	.B \-u
	causes the agent to prompt for user
	id and writes it to
	.BR /dev/hostowner .
	It is mutually exclusive with
	.B \-k
	and
	.BR \-S .
	This option is typically used by
	the kernel at boot time.
	.PD
	.\" .PP
	.\" .I Fgui
	.\" is a graphic user interface for confirming key usage and
	.\" entering new keys. It hides the window in which it starts
	.\" and waits reading requests from
	.\" .B confirm
	.\" and
	.\" .BR needkey .
	.\" For each requests, it unhides itself and waits for
	.\" user input.
	.\" See the sections on key confirmation and key prompting below.
	.SS "Key Tuples
	.PP
	A
	.I "key tuple
	is a space delimited list of
	.IB attribute = value
	pairs. An attribute whose name begins with an exclamation point
	.RB ( ! )
	does not appear when reading the
	.B ctl
	file.
	Here are some examples:
	.EX
	proto=p9sk1 dom=avayalabs.com user=presotto !password=lucent
	proto=apop server=mit.edu user=rsc !password=nerdsRus
	proto=pass user=tb service=ssh !password=does.it.matter
	.EE
	The ``Protocols'' section below describes the attributes
	specific to each supported protocol.
	.PP
	All keys can have additional attibutes that act either as comments
	or as selectors to distinguish them in the
	.IR auth (3)
	library calls.
	.PP
	The factotum owner can use any key stored by factotum.
	Any key may have one or more
	.B owner
	attributes listing the users who can use the key
	as though they were the owner.
	For example, the TLS and SSH host keys on a server
	often have an attribute
	.B owner=*
	to allow any user (and in particular,
	.L none )
	to run the TLS or SSH server-side protocol.
	.PP
	Any key may have a
	.B role
	attribute for restricting how it can be used.
	If this attribute is missing, the key can be used in any role.
	Common values are:
	.TP
	.B client
	for authenticating outbound calls
	.TP
	.B server
	for authenticating inbound calls
	.TP
	.B speaksfor
	for authenticating processes whose
	user id does not match
	.IR factotum 's.
	.TP
	.B encrypt
	for encrypting data
	.TP
	.B decrypt
	for decrypting data
	.TP
	.B sign
	for cryptographically signing data
	.TP
	.B verify
	for verifying cryptographic signatures
	.PD
	.PP
	Whenever
	.I factotum
	runs as a server, it must have a
	.B p9sk1
	key in order to communicate with the authentication
	server for validating passwords and challenge/responses of
	other users.
	.SS "Key Templates
	Key templates are used by routines that interface to
	.I factotum
	such as
	.B auth_proxy
	and
	.B auth_challenge
	(see
	.IR auth (3))
	to specify which key and protocol to use for an authentication.
	Like a key tuple, a key template is also a list of
	.IB attribute = value
	pairs.
	It must specify at least the protocol and enough
	other attributes to uniquely identify a key, or set of keys, to use.
	The keys chosen are those that match all the attributes specified
	in the template. The possible attribute/value formats are:
	.TP 1i
	.IB attr = val
	The attribute
	.I attr
	must exist in the key and its value must exactly
	match
	.I val
	.TP 1i
	.IB attr ?
	The attribute
	.I attr
	must exist in the key but its value doesn't matter.
	.TP 1i
	.I attr
	The attribute
	.I attr
	must exist in the key with a null value
	.PD
	.PP
	Key templates are also used by factotum to request a key either via
	an RPC error or via the
	.B needkey
	interface.
	The possible attribute/value formats are:
	.TP 1i
	.IB attr = val
	This pair must remain unchanged
	.TP 1i
	.IB attr ?
	This attribute needs a value
	.TP 1i
	.I attr
	The pair must remain unchanged
	.PD
	.SS "Control and Key Management
	.PP
	A number of messages can be written to the control file.
	The mesages are:
	.TP
	.B "key \fIattribute-value-list\fP
	add a new key. This will replace any old key whose
	public, i.e. non ! attributes, match.
	.TP
	.B "delkey \fIattribute-value-list\fP
	delete a key whose attributes match those given.
	.TP
	.B debug
	toggle debugging on and off, i.e., the debugging also
	turned on by the
	.B \-d
	option.
	.PP
	By default when factotum starts it looks for a
	.IR secstore (1)
	account on $auth for the user and, if one exists,
	prompts for a secstore password in order to fetch
	the file
	.IR factotum ,
	which should contain control file commands.
	An example would be
	.EX
	key dom=x.com proto=p9sk1 user=boyd !hex=26E522ADE2BBB2A229
	key proto=rsa service=ssh size=1024 ek=3B !dk=...
	.EE
	where the first line sets a password for
	challenge/response authentication, strong against dictionary
	attack by being a long random string, and the second line
	sets a public/private keypair for ssh authentication,
	generated by
	.B ssh_genkey
	(see
	.IR ssh (1)).
	.PD
	.SS "Confirming key use
	.PP
	The
	.B confirm
	file provides a connection from
	.I factotum
	to a confirmation server, normally the program
	.IR auth/fgui .
	Whenever a key with the
	.B confirm
	attribute is used,
	.I factotum
	requires confirmation of its use. If no process has
	.B confirm
	opened, use of the key will be denied.
	However, if the file is opened a request can be read from it
	with the following format:
	.PP
	.B confirm
	.BI tag= tagno
	.I "<key template>
	.PP
	The reply, written back to
	.BR confirm ,
	consists of string:
	.PP
	.BI tag= tagno
	.BI answer= xxx
	.PP
	If
	.I xxx
	is the string
	.B yes
	then the use is confirmed and the authentication will proceed.
	Otherwise, it fails.
	.PP
	.B Confirm
	is exclusive open and can only be opened by a process with
	the same user id as
	.IR factotum .
	.SS "Prompting for keys
	.PP
	The
	.B needkey
	file provides a connection from
	.I factotum
	to a key server, normally the program
	.IR auth/fgui .
	Whenever
	.I factotum
	needs a new key, it first checks to see if
	.B needkey
	is opened. If it isn't, it returns a error to its client.
	If the file is opened a request can be read from it
	with the following format:
	.PP
	.B needkey
	.BI tag= tagno
	.I "<key template>
	.PP
	It is up to the reader to then query the user for any missing fields,
	write the key tuple into the
	.B ctl
	file, and then reply by writing into the
	.B needkey
	file the string:
	.PP
	.BI tag= tagno
	.PP
	.B Needkey
	is exclusive open and can only be opened by a process with
	the same user id as
	.IR factotum .
	.SS "The RPC Protocol
	Authentication is performed by
	.IP 1)
	opening
	.BR rpc
	.IP 2)
	setting up the protocol and key to be used (see the
	.B start
	RPC below),
	.IP 3)
	shuttling messages back and forth between
	.IR factotum
	and the other party (see the
	.B read
	and
	.B write
	RPC's) until done
	.IP 4)
	if successful, reading back an
	.I AuthInfo
	structure (see
	.IR authsrv (3)).
	.PP
	The RPC protocol is normally embodied by one of the
	routines in
	.IR auth (3).
	We describe it here should anyone want to extend
	the library.
	.PP
	An RPC consists of writing a request message to
	.B rpc
	followed by reading a reply message back.
	RPC's are strictly ordered; requests and replies of
	different RPC's cannot be interleaved.
	Messages consist of a verb, a single space, and data.
	The data format depends on the verb. The request verbs are:
	.TP
	.B "start \fIattribute-value-list\fP
	start a new authentication.
	.I Attribute-value-pair-list
	must include a
	.B proto
	attribute, a
	.B role
	attribute with value
	.B client
	or
	.BR server ,
	and enough other attibutes to uniquely identify a key to use.
	A
	.B start
	RPC is required before any others. The possible replies are:
	.RS
	.TP
	.B ok
	start succeeded.
	.TP
	.B "error \fIstring\fP
	where
	.I string
	is the reason.
	.RE
	.PD
	.TP
	.B read
	get data from
	.I factotum
	to send to the other party. The possible replies are:
	.RS
	.TP
	.B ok
	read succeeded, this is zero length message.
	.TP
	.B "ok \fIdata\fP
	read succeeded, the data follows the space and is
	unformatted.
	.TP
	.B "done
	authentication has succeeded, no further RPC's are
	necessary
	.TP
	.B "done haveai
	authentication has succeeded, an
	.B AuthInfo
	structure (see
	.IR auth (3))
	can be retrieved with an
	.B authinfo
	RPC
	.TP
	.B "phase \fIstring\fP
	its not your turn to read, get some data from
	the other party and return it with a write RPC.
	.TP
	.B "error \fIstring\fP
	authentication failed,
	.I string
	is the reason.
	.TP
	.B "protocol not started
	a
	.B start
	RPC needs to precede reads and writes
	.TP
	.B "needkey \fIattribute-value-list\fP
	a key matching the argument is needed. This argument
	may be passed as an argument to
	.I factotum
	.B -g
	in order to prompt for a key. After that, the
	authentication may proceed, i.e., the read restarted.
	.PD
	.RE
	.TP
	.B "write \fIdata\fP
	send data from the other party to
	.IR factotum .
	The possible replies are:
	.RS
	.TP
	.B "ok
	the write succeeded
	.TP
	.B "needkey \fIattribute-value-list\fP
	see above
	.TP
	.B "toosmall \fIn\fP
	the write is too short, get more data from the
	other party and retry the write.
	.I n
	specifies the maximun total number of bytes.
	.TP
	.B "phase \fIstring\fP
	its not your turn to write, get some data from
	.I factotum
	first.
	.TP
	.B "done
	see above
	.TP
	.B "done haveai
	see above
	.RE
	.TP
	.B readhex\fR, \fPwritehex
	like
	.B read
	and
	.BR write ,
	except that an
	.B ok
	response to
	.B readhex
	returns the data encoded as
	a long hexadecimal string,
	and the argument to
	.B writehex
	is expected to be a long hexadecimal string.
	These are useful for manually debugging of binary protocols.
	.TP
	.B authinfo
	retrieve the AuthInfo structure.
	The possible replies are:
	.RS
	.TP
	.B "ok \fIdata\fP
	.I data
	is a marshaled form of the AuthInfo structure.
	.TP
	.B "error \fIstring\fP
	where
	.I string
	is the reason for the error.
	.PD
	.RE
	.TP
	.B attr
	retrieve the attributes used in the
	.B start
	RPC.
	The possible replies are:
	.RS
	.TP
	.B "ok \fIattribute-value-list\fP
	.TP
	.B "error \fIstring\fP
	where
	.I string
	is the reason for the error.
	.PD
	.RE
	.SS Protocols
	Factotum supports many authentication types, each
	with its own roles and required key attributes.
	.PP
	.IR P9any ,
	.IR p9sk1 ,
	.IR p9sk2 ,
	and
	.I p9cr
	are used to authenticate to Plan 9 systems;
	valid
	.BR role s
	are
	.B client
	and
	.BR server .
	All require
	.B proto=p9sk1
	keys with
	.BR user ,
	.B dom
	(authentication domain),
	and
	.B !password
	attributes.
	.PP
	.I P9sk1
	and
	.I p9sk2
	are the Plan 9 shared-key authentication protocols.
	.I P9sk2
	is a deprecated form of
	.I p9sk1
	that neglects to authenticate the server.
	.PP
	.I P9any
	is a meta-protocol that negotiates a protocol
	.RB ( p9sk1
	or
	.BR p9sk2 )
	and an authentication domain and then invokes the
	given protocol with a
	.B dom=
	attribute.
	.PP
	.IR P9any ,
	.IR p9sk1 ,
	and
	.I p9sk2
	are intended to be proxied via
	.I auth_proxy
	(see
	.IR auth (3)).
	.\" The protocols follow
	.\" .IR p9any (7)
	.\" and
	.\" .IR p9sk1 (7).
	.\" XXX - write about how server keys are selected and used
	.\" XXX - write about protocol itself
	.\" XXX - write about server ai
	.PP
	.I P9cr
	is a textual challenge-response protocol;
	roles are
	.B client
	and
	.BR server .
	It uses
	.I p9sk1
	keys as described above.
	The protocol with
	.I factotum
	is textual:
	client writes a user name,
	server responds with a challenge,
	client writes a response,
	server responds with
	.B ok
	or
	.BR bad .
	Typically this information is wrapped in other protocols
	before being sent over the network.
	.PP
	.I Vnc
	is the challenge-response protocol used by
	.IR vnc (1);
	valid roles are
	.B client
	and
	.BR server .
	The client protocol requires a
	.B proto=vnc
	key with attribute
	.BR !password .
	Conventionally, client keys also have
	.B user
	and
	.B server
	attributes.
	The server protocol requires a
	.I p9sk1
	key as described above.
	The protocol with
	.I factotum
	is the same as
	.IR p9cr ,
	except that the challenge and response are not textual.
	.PP
	.I Apop
	and
	.I cram
	are challenge-response protocols typically
	used to authenticate
	to mail servers.
	The client protocols require
	.B proto=apop
	or
	.B proto=cram
	keys with
	.B user
	and
	.B !password
	attributes.
	Conventionally, client keys also have
	.B server
	attributes.
	The server protocol requires a
	.I p9sk1
	key as described above.
	The protocol with
	.I factotum
	is textual:
	server writes a challenge of the form
	.IB random @ domain \fR,
	client responds with user name
	and then a hexadecimal response
	(two separate writes),
	and then the server responds with
	.B ok
	or
	.BR bad .
	.PP
	.I Chap
	and
	.I mschap
	are challenge-response protocols used in PPP sessions;
	valid roles are
	.B client
	and
	.BR server .
	The client protocols require
	.B proto=chap
	or
	.B proto=mschap
	keys with
	.B user
	and
	.B !password
	attributes.
	Conventionally, client keys also have
	.B server
	attributes.
	The server protocol requires a
	.I p9sk1
	key as described above.
	The protocol with factotum is:
	server writes an 8-byte binary challenge,
	client responds with user name
	and then a
	.B Chapreply
	or
	.B MSchapreply
	structure (defined in
	.B <auth.h> ).
	.PP
	.I Pass
	is a client-only protocol that hands out passwords
	from
	.B proto=pass
	keys with
	.B user
	and
	.B !password
	attributes.
	The protocol is a single read that returns
	a string: a space-separated quoted user name and password
	that can be parsed with
	.I tokenize
	(see
	.IR getfields (3)).
	Conventionally, client keys have distinguishing attributes
	like
	.B service
	and
	.B server
	that can be specified in the
	.B start
	message to select a key.
	.PP
	.I Wep
	is a client-only pseudo-protocol that initializes the encryption
	key on a wireless ethernet device.
	It uses
	.B proto=wep
	keys with
	.BR !key1 ,
	.BR !key2 ,
	or
	.B !key3
	attributes.
	The protocol with
	.I factotum
	is:
	the client writes a device name
	that must begin with
	.LR #l .
	In response,
	.I factotum
	opens the device's control file, sets the wireless secret using the key,
	and turns on encryption.
	If the key has an
	.B essid
	attribute,
	.I factotum
	uses it to set the wireless station ID.
	.PP
	.I Rsa
	is an implementation of the RSA protocol.
	Valid roles are
	.BR decrypt ,
	.BR encrypt ,
	.BR sign ,
	and
	.BR verify .
	.I Rsa
	uses
	.B proto=rsa
	keys with
	.B ek
	and
	.B n
	attributes, large integers specifying the public half
	of the key.
	If a key is to be used for decryption or signing,
	then it must also have attributes
	.BR !p ,
	.BR !q ,
	.BR !kp ,
	.BR !kq ,
	.BR !c2 ,
	and
	.BR !dk
	specifying the private half of the key;
	see
	.IR rsa (3).
	Conventionally,
	.I rsa
	keys also have
	.B service
	attributes specifying the context in which the key is used:
	.B ssh
	(SSH version 1),
	.B ssh-rsa
	(SSH version 2),
	or
	.B tls
	(SSL and TLS).
	If an SSH key has a
	.B comment
	attribute, that comment is presented to remote SSH servers
	during key negotiation.
	The protocol for
	encryption (decryption) is:
	write the message, then read back the encrypted (decrypted) form.
	The protocol for signing is:
	write a hash of the actual message,
	then read back the signature.
	The protocol for verifying a signature is:
	write the message hash,
	write the purported signature,
	then read back
	.B ok
	or
	.B bad
	telling whether the signature could be verified.
	The hash defaults to SHA1 but can be specified by a
	.B hash
	attribute on the key.
	Valid hash functions are
	.B md5
	and
	.BR sha1 .
	The hash function must be known to
	.I factotum
	because the signature encodes the type of hash used.
	The
	.B encrypt
	and
	.B verify
	operations are included as a convenience;
	.I factotum
	is not using any private information to perform them.
	.PP
	.I Dsa
	is an implementation of the NIST digital signature algorithm.
	Valid roles are
	.B sign
	and
	.BR verify .
	It uses
	.B proto=dsa
	keys with
	.BR p ,
	.BR q ,
	.BR alpha ,
	and
	.B key
	attributes.
	If the key is to be used for signing, it must also have a
	.B !secret
	attribute; see
	.IR dsa (3).
	Conventionally,
	.I dsa
	keys
	also have
	.B service
	attributes specifying the context in which the key is used:
	.B ssh-dss
	(SSH version 2)
	is the only one.
	If an SSH key has a
	.B comment
	attribute, that comment is presented to SSH servers during
	key negotiation.
	The protocol for signing and verifying
	is the same as the RSA protocol.
	Unlike
	.IR rsa ,
	the
	.I dsa
	protocol ignores the
	.B hash
	attribute; it always uses SHA1.
	.PP
	.I Httpdigest
	is a client-only MD5-based challenge-response protocol used in HTTP; see RFC 2617.
	It uses
	.B proto=httpdigest
	keys with
	.BR user ,
	.BR realm ,
	and
	.BR !password
	attributes.
	The protocol with factotum is textual:
	write the challenge, read the response.
	The challenge is a string with three space-separated fields
	.IR nonce ,
	.IR method ,
	and
	.IR uri ,
	parseable with
	.IR tokenize .
	The response is a hexadecimal string of length 32.
	.SH SOURCE
	.B \*9/src/cmd/auth/factotum
	.SH SEE ALSO
	.IR ssh-agent (1)