Network Working Group M.T. Rose
Internet-Draft Invisible Worlds, Inc.
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The Blocks eXtensible eXchange Protocol Framework
draft-mrose-blocks-protocol-04.txt
Status of this Memo
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Copyright Notice
Copyright (C) The Internet Society (2000). All Rights Reserved.
Abstract
This memo describes a generic application protocol framework for
connection-oriented, asynchronous request/response interactions. The
framework permits multiplexing of independent request/response
streams over a single transport connection, supporting both textual
and binary messages.
To subscribe to the Blocks discussion list, send e-mail[12]; there
is also a developers' site[13].
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . 4
2. The Blocks eXtensible eXchange Protocol . . . . . . . . . 5
2.1 Roles . . . . . . . . . . . . . . . . . . . . . . . . . . 5
2.2 Messages and Frames . . . . . . . . . . . . . . . . . . . 6
2.2.1 Message Syntax . . . . . . . . . . . . . . . . . . . . . . 7
2.2.1.1 Frame Header . . . . . . . . . . . . . . . . . . . . . . . 8
2.2.1.2 Frame Payload . . . . . . . . . . . . . . . . . . . . . . 10
2.2.1.3 Frame Trailer . . . . . . . . . . . . . . . . . . . . . . 10
2.2.2 Frame Semantics . . . . . . . . . . . . . . . . . . . . . 11
2.3 Channel Management . . . . . . . . . . . . . . . . . . . . 12
2.3.1 Message Semantics . . . . . . . . . . . . . . . . . . . . 12
2.3.1.1 The Start Message . . . . . . . . . . . . . . . . . . . . 12
2.3.1.2 The Greeting Message . . . . . . . . . . . . . . . . . . . 15
2.3.1.3 The Error Message . . . . . . . . . . . . . . . . . . . . 16
2.4 Session Establishment and Release . . . . . . . . . . . . 17
2.5 Flow Control . . . . . . . . . . . . . . . . . . . . . . . 19
2.5.1 Channel Creation . . . . . . . . . . . . . . . . . . . . . 19
2.5.2 Sending REQ or RSP Messages . . . . . . . . . . . . . . . 20
2.5.3 Receiving REQ or RSP Messages . . . . . . . . . . . . . . 20
2.5.4 Processing SEQ Messages . . . . . . . . . . . . . . . . . 21
2.5.5 Use of Flow Control . . . . . . . . . . . . . . . . . . . 22
2.6 Parallelism . . . . . . . . . . . . . . . . . . . . . . . 23
2.6.1 Within a single channel . . . . . . . . . . . . . . . . . 23
2.6.2 Between different channels . . . . . . . . . . . . . . . . 23
2.6.3 Pre-emptive responses . . . . . . . . . . . . . . . . . . 23
2.6.4 Interference . . . . . . . . . . . . . . . . . . . . . . . 23
2.7 Peer-to-Peer Behavior . . . . . . . . . . . . . . . . . . 24
3. Transport Security . . . . . . . . . . . . . . . . . . . . 25
3.1 The TLS Transport Security Profile . . . . . . . . . . . . 28
3.1.1 Profile Identification and Initialization . . . . . . . . 28
3.1.2 Request and Response Messages . . . . . . . . . . . . . . 29
3.1.3 Message Semantics . . . . . . . . . . . . . . . . . . . . 30
3.1.3.1 The Ready Message . . . . . . . . . . . . . . . . . . . . 30
3.1.3.2 The Proceed Message . . . . . . . . . . . . . . . . . . . 30
4. User Authentication . . . . . . . . . . . . . . . . . . . 31
4.1 The SASL Family of Profiles . . . . . . . . . . . . . . . 32
4.1.1 Profile Identification and Initialization . . . . . . . . 33
4.1.2 Request and Response Messages . . . . . . . . . . . . . . 35
4.1.3 Message Semantics . . . . . . . . . . . . . . . . . . . . 36
5. Profile Registration Template . . . . . . . . . . . . . . 37
6. Initial Profile Registrations . . . . . . . . . . . . . . 38
6.1 BXXP Channel Management . . . . . . . . . . . . . . . . . 38
6.2 BXXP Channel Management DTD . . . . . . . . . . . . . . . 39
6.3 Registration: TLS Transport Security Profile . . . . . . . 41
6.4 TLS Transport Security Profile DTD . . . . . . . . . . . . 42
6.5 Registration: SASL Family of Profiles . . . . . . . . . . 43
6.6 SASL Family of Profiles DTD . . . . . . . . . . . . . . . 44
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7. Reply Codes . . . . . . . . . . . . . . . . . . . . . . . 45
8. Security Considerations . . . . . . . . . . . . . . . . . 46
9. IANA Considerations . . . . . . . . . . . . . . . . . . . 47
References . . . . . . . . . . . . . . . . . . . . . . . . 48
Author's Address . . . . . . . . . . . . . . . . . . . . . 49
A. Acknowledgements . . . . . . . . . . . . . . . . . . . . . 50
Full Copyright Statement . . . . . . . . . . . . . . . . . 51
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1. Introduction
This memo describes a generic application protocol framework for
connection-oriented, asynchronous request/response interactions over
TCP[1]. Consult [2] for a description of the framework's design
principles and a discussion of other transport mappings.
At the core of the BXXP framework is a framing mechanism that allows
for peer-to-peer exchanges of requests and responses. The framing
mechanism permits multiplexing multiple, simultaneous, and
independent exchanges over a single transport connection with flow
control and segmentation. Requests and responses are either textual
(structured using XML[3]) or arbitrary (structured using MIME[4]).
Frames are exchanged in the context of a "channel". Each channel has
an associated "profile" that defines the syntax and semantics of the
messages exchanged. Implicit in the operation of BXXP is the notion
of channel management. In addition to defining BXXP's channel
management profile, this document defines:
o the TLS[5] transport security profile; and,
o the SASL[6] family of profiles.
Other profiles, such as those used for data exchange, are defined by
an application protocol designer. A registration template is
provided for this purpose.
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2. The Blocks eXtensible eXchange Protocol
BXXP is a message-oriented protocol. Arbitrary octets are
encapsulated within a frame and tagged as either a request or a
response. All interactions occur in the context of a channel -- a
binding to a well-defined aspect of the application, such as
transport security, user authentication, or data exchange.
During the creation of a channel, the requestor supplies one or more
proposed profiles for that channel. If the responder creates the
channel, it selects one of the profiles and returns it in a
response; otherwise, it may indicate that none of the profiles are
acceptable, and decline creation of the channel.
There are no other management capabilities for channels other than
creation, as channel usage falls into one of two categories:
initial tuning: these are used by profiles that perform
initialization once the BXXP session is established (e.g.,
negotiating the use of transport security); although several
request/response exchanges may be required to perform the
initialization, these channels become inactive early in the BXXP
session and remain so for the duration.
continuous: these are used by profiles that support data exchange;
typically, these channels are created after the initial tuning
channels have gone quiet.
2.1 Roles
Although BXXP is a peer-to-peer protocol, it is convenient to label
each peer in the context of the role it is performing at a given
time:
o When a BXXP session is established, we designate the peer that
awaits new connections as acting in the listening role, and the
other peer, which establishes a connection to the listener, as
acting in the initiating role. In the examples which follow,
these are referred to as "I:" and "L:", respectively.
o We designate a BXXP peer making a request as a client (or
requestor); similarly, we designate the other BXXP peer as a
server (or responder). In the examples which follow, these are
referred to as "C:" and "S:", respectively.
Typically, a BXXP peer acting in the server role is also acting in a
listening role. However, because BXXP is peer-to-peer in nature, no
such requirement exists.
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2.2 Messages and Frames
In BXXP, there are three kinds of messages: requests, responses, and
sequence updates.
Each request or response conveys data, which is segmented as the
payload of one or more frames. Each frame consists of a header, the
payload, and a trailer. The header and trailer are each represented
using printable ASCII characters and are terminated with a CRLF
pair. Between the header and the trailer is the payload, consisting
of zero or more octets.
For example, here is a request message whose data is contained in a
single frame that contains a payload of 94 octets spread over 3
lines (each line of the data is terminated with a CRLF pair):
C: REQ . 1 14 94 0
C:
C:
C:
C:
C: END
Note that the header is two lines long (the second line is blank
signifying a lack of explicit MIME typing information).
The sequence update message is used to flow control request and
response messages, and is represented using printable ASCII
characters terminated by a CRLF pair.
For example, here is a sequence update message:
C: SEQ 1 0 65535
Note that the sequence update message doesn't have a header,
payload, or trailer -- it's simply a single line.
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2.2.1 Message Syntax
The ABNF for a message is:
message = frame / seq
frame = header payload trailer
header = req / rsp
req = "REQ" SP more SP serial SP seqno SP size SP channel
CR LF [[mime] CR LF]
rsp = "RSP" SP more SP serial SP seqno SP size SP status
CR LF [[mime] CR LF]
more = "." / "*"
; use of 0 for is reserved for the initial greeting
serial = 0..2147483647
seqno = 0..4294967295
size = 0..2147483647
; use of 0 for is reserved for BXXP channel management
channel = 0..255
; defaults are:
;
; Content-Type: text/xml
; Content-Transfer-Encoding: binary
;
mime =
status = "+" / "-"
payload = *OCTET
trailer = "END" CR LF
seq = "SEQ" SP channel SP ackno SP window CR LF
ackno = seqno
window = size
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2.2.1.1 Frame Header
The frame header consists of a three-character keyword (one of:
"REQ" or "RSP"), followed by a continuation indicator, a serial
number, a sequence number, a payload size, and one additional
parameter. A single space character (decimal code 32, " ") separates
each component. The header is terminated with a CRLF pair.
The "REQ" keyword indicates that this frame is part of a request
message. Following the "REQ" keyword, the continuation indicator,
the serial number, the sequence number, and the payload size is the
channel number for the request.
The "RSP" keyword indicates that this frame is part of a response
message. Following the "RSP" keyword, the continuation indicator,
the serial number, the sequence number, and the payload size is the
status indicator for the response.
The continuation indicator (one of: decimal code 42, "*", or decimal
code 46, ".") specifies whether this is the final frame of the
message:
intermediate ("*"): at least one other frame follows for the
message; or,
complete ("."): this frame completes the data for the message.
The serial number must be a non-negative integer (in the range
0..2147483647) and have a different value than all other outstanding
request messages (regardless of channel number).
The sequence number must be a non-negative integer (in the range
0..4294967295) and specifies the sequence number of the first octet
in the payload, for the associated channel.
The payload size must be a non-negative integer (in the range
0..2147483647) and specifies the exact number of octets in the
payload. (This does not include the trailer.)
The status indicator (one of: decimal code 43, "+", or decimal code
45, "-"), specifies whether the request corresponding to this
response was performed:
positive ("+"): the request was performed and the response's data
contains the corresponding the results; or,
negative ("-"): the request could not be performed (either for
transient or permanent reasons) and the response's data contains
the corresponding error information.
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There are several rules for identifying poorly-formed frames:
o if the header doesn't start with "REQ" or "RSP";
o if the header starts with "REQ" or "RSP", but any of the
continuation indicator, serial number, sequence number, or
payload size cannot be determined or is invalid;
o if the header starts with "REQ", but the channel number cannot be
determined or is invalid;
o if the header starts with "RSP", but the status indicator cannot
be determined or is invalid;
o if the header starts with "RSP", but the serial number does not
refer to an outstanding request message;
o if the value of the sequence number doesn't correspond to the
expected value for the associated channel (c.f., Section 2.5.3);
o if the header starts with "REQ" and refers to a message for which
at least one other "REQ" frame has been received, and if the
continuation indicator of the immediately-previous received frame
for this message is intermediate ("*"), and if the channel
numbers aren't identical; or,
o if the header starts with "RSP" and refers to a message for which
at least one other "RSP" frame has been received, and if the
status indicator of this frame and the immediately-previous
received frame for this message are not identical.
If a frame is poorly-formed, then the connection is closed without
generating a response, and it is recommended that a diagnostic entry
be logged.
The final frame in a message has a continuation indicator of
complete ("."), whilst all earlier frames (if any) have a
continuation indicator of intermediate ("*"). Note that any of these
frames may have an empty payload, e.g.,
S: RSP * 1 284 25 +
S:
S: ...
S: ...
S: ...
S: END
S: RSP . 1 309 0 +
S:
S: END
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2.2.1.2 Frame Payload
The data conveyed with a message is structured according to the
rules of MIME. Accordingly, the header of the first frame for a
message may include "entity-headers" (c.f., MIME[4]'s Section 3). If
none, or only some, of the entity-headers are present:
o the default "Content-Type" is "text/xml"; and,
o the default "Content-Transfer-Encoding" is "binary".
Hence, in the absence of typing information, a message's data is a
well-formed XML[3] document.
Note that the "entity-headers" (and the empty line that follows) are
part of the of the header, not the payload. Thus, they do not
contribute to the size of the payload.
2.2.1.3 Frame Trailer
The frame trailer consists of "END" followed by a CRLF pair.
When receiving a frame, if the characters immediately following the
payload don't correspond to a trailer, then the connection is closed
without generating a response, and it is recommended that a
diagnostic entry be logged.
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2.2.2 Frame Semantics
The semantics of the payload of each frame is channel-specific.
Accordingly, the profile associated with a channel must define:
o the initialization messages, if any, exchanged during channel
creation;
o the set of request and response messages may be carried in the
payload of the channel; and,
o the semantics of these messages.
A profile registration template (Section 5) organizes this
information.
Note that if a profile uses XML to structure its messages, then only
XML's baseline facilities (as described in the XML 1.0
specification[3]) are allowed. Additional XML features (e.g.,
namespaces) are made available only by being referenced and allowed
in a given profile's specification.
In particular this limitation allows use of only the five predefined
general entities references ("&", "<", ">", "'", and
""") and numeric entity references in the messages exchanged.
Finally, because the profile registration template defines the
messages exchanged over a channel, the XML documents exchanged in
each message needn't have either a "XML" declaration (e.g., ) or a "DOCTYPE" declaration (e.g., ).
Of course, all other XML 1.0 instructions (e.g., CDATA blocks,
processing instructions, and so on) are allowed.
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2.3 Channel Management
When a BXXP session starts, only channel number 0 is defined, which
is used for channel management. Section 6.1 contains the profile
registration for BXXP channel management.
2.3.1 Message Semantics
2.3.1.1 The Start Message
When a BXXP peer wants to create a channel, it sends a "start"
element as data on channel 0, e.g.,
I: REQ . 1 14 94 0
I:
I:
I:
I:
I: END
The "start" element has a "number" attribute, an optional
"serverName" attribute, and one or more "profile" elements:
o the "number" attribute indicates the channel number (in the range
1..255) used to identify the channel in future messages;
o the "serverName" attribute, an arbitrary string, indicates the
desired server name for this BXXP session; and,
o each "profile" element contained within the "start" element
identifies a profile, and, optionally, contains an arbitrary XML
element exchanged during channel creation as its content.
To avoid conflict in assigning channel numbers when requesting the
creation of a channel, BXXP peers acting in the initiating role use
only positive integers that are odd-numbered; similarly, BXXP peers
acting in the listening role use only positive integers that are
even-numbered.
The "serverName" attribute for the first successful "start" element
received by a BXXP peer is memorable. (If the attribute isn't
present or it's value is empty, then the sending BXXP peer is
requesting a configuration-specific default value.) The BXXP peer
decides whether to operate as the indicated "serverName"; if not, an
"error" element is returned as data in a negative "RSP" message.
When a BXXP peer receives a "start" element as data on channel 0, it
examines each of the proposed profiles, and decides whether to use
one of them to create the channel. If so, the appropriate "profile"
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element is returned as data in a positive "RSP" message; otherwise,
an "error" element is returned as data in a negative "RSP" message.
When creating the channel, the value of the "serverName" attribute
from the first successful "start" element is consulted to provide
configuration information, e.g., the desired server-side certificate
when starting the TLS transport security profile (Section 3.1).
For example, a successful channel creation might look like this:
I: REQ . 1 14 171 0
I:
I:
I:
I:
I:
I: END
L: RSP . 1 284 61 +
L:
L:
L: END
Similarly, an unsuccessful channel creation might look like this:
I: REQ . 1 14 94 0
I:
I:
I:
I:
I: END
L: RSP . 1 284 89 -
L:
L: number attribute
L: in <start> element must be odd-valued
L: END
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Finally, here's an example in which an initialization element is
exchanged during channel creation:
C: REQ . 1 14 120 0
C:
C:
C:
C:
C:
C:
C: END
S: RSP . 1 84 83 +
S:
S:
S:
S:
S: END
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2.3.1.2 The Greeting Message
When a BXXP session is established, each BXXP peer signifies its
availability by immediately sending a positive "RSP" message with a
serial number of zero that contains a "greeting" element, e.g.,
L:
I:
L: RSP . 0 0 84 +
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
Note that this example implies that the BXXP peer in the initiating
role waits until the BXXP peer in the listening role sends its
greeting -- this is an artifact of the presentation; in fact, both
BXXP peers send their response messages independently.
The "greeting" element has two optional attributes ("features" and
"localize") and zero or more "profile" elements, one for each
profile supported by the BXXP peer acting in a server role:
o the "features" attribute, if present, contains one or more
feature tokens, each indicating an optional feature of the
channel management profile supported by the BXXP peer;
o the "localize" attribute, if present, contains one or more
language tokens, each identifying a desirable language tag to be
used by the remote BXXP peer when generating textual diagnostics
for the "error" element (the tokens are ordered from most to
least desirable); and,
o each "profile" element contained within the "greeting" element
identifies a profile, and unlike the "profile" elements that
occur within the "start" element, the content of each "profile"
element may not contain an optional initialization element.
At present, there are no optional features defined for the channel
management profile.
Each token in the value of the "localize" attribute is defined
according to [7]. If not present, the default is "i-default".
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2.3.1.3 The Error Message
When a BXXP peer declines the creation of a channel, it returns an
"error" element as data in a negative "RSP" message, e.g.,
I: REQ . 1 14 89 0
I:
I:
I:
I:
I: END
L: RSP . 1 284 67 -
L:
L: all requested profiles are
L: unsupported
L: END
The "error" element has a "code" attribute, an optional "xml:lang"
attribute, and an optional textual diagnostic as its content:
o the "code" attribute is a three digit reply code meaningful to
programs (c.f., Section 7);
o the "xml:lang" attribute identifies the language that the
element's content is written in (the value is suggested, but not
mandated, by the "localize" attribute of the "greeting" element
sent by the remote BXXP peer); and,
o the textual diagnostic (which may be multiline) is meaningful to
implementers, perhaps administrators, and possibly even users.
Note that if the textual diagnostic is present, then the "xml:lang"
attribute is absent only if the language indicated as the remote
BXXP's first choice is used.
In addition, a BXXP peer returns an "error" element whenever:
o it receives a "REQ" message containing an unexpected element; or,
o a BXXP session is established, the BXXP peer is acting in the
listening role, and that BXXP peer is unavailable (in this case,
the BXXP acting in the listening role does not send a "greeting"
element).
In the latter case, both BXXP peers close the connection, and it is
recommended that a diagnostic entry be logged by both BXXP peers.
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2.4 Session Establishment and Release
When a BXXP session is established, each BXXP peer signifies its
availability by immediately sending a positive "RSP" message with a
serial number of zero that contains a "greeting" element, e.g.,
L:
I:
L: RSP . 0 0 84 +
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
which, for the BXXP peer acting in the listening role, indicates
that it is available.
Alternatively, if the BXXP peer acting in the listening role is
unavailable, it returns a negative response, e.g.,
L:
I:
L: RSP . 0 0 22 -
L:
L:
L: END
I:
L:
L:
and the "greeting" element sent by the BXXP peer acting in the
initiating role is ignored. It is recommended that a diagnostic
entry be logged by both BXXP peers.
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When a BXXP peer wants to release the BXXP session, it sends a "REQ"
message on channel 0 with no data. The other BXXP peer may accept
the request (by sending a positive "RSP" message), e.g.,
C: REQ . 1 14 0 0
C:
C: END
S: RSP . 1 284 0 +
S:
S: END
C:
S:
L:
If the other BXXP peer sends a negative "RSP" message, then the
connection should remain open, if possible.
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2.5 Flow Control
Although the underlying transport service imposes flow control on a
per-connection basis, if multiple channels are simultaneously in use
on a connection, BXXP must provide a mechanism to avoid starvation
and deadlock. To achieve this, BXXP re-introduces mechanisms used by
the TCP: sequence numbers and window-based flow control. Briefly,
each channel has a sliding window that indicates the number of
payload octets that a peer may transmit before receiving further
permission.
Every payload octet sent in each direction on a channel has an
associated sequence number. Numbering of payload octets within a
frame is such that the first payload octet is the lowest numbered,
and the following payload octets are numbered consecutively.
The actual sequence number space is finite, though very large,
ranging from 0..4294967295 (2**32 - 1). Since the space is finite,
all arithmetic dealing with sequence numbers is performed modulo
2**32. This unsigned arithmetic preserves the relationship of
sequence numbers as they cycle from 2**32 - 1 to 0 again.
2.5.1 Channel Creation
When a channel is created, the sequence number associated with the
first payload octet of the first frame is 0, and the initial window
size for that channel is 4096 octets. After channel creation, a BXXP
peer may update the window size by sending a "SEQ" message (Section
2.5.4).
If a BXXP peer is requested to create a channel and it is unable to
allocate at least 4096 octets for that channel, it must decline
creation of the channel (Section 2.3.1.3). Similarly, during
establishment of the BXXP session, if the BXXP peer acting in the
listening role is unable to allocate at least 4096 octets for
channel 0, then it must return a negative response (Section 2.4)
instead of a greeting.
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2.5.2 Sending REQ or RSP Messages
Before a message is sent, the sending BXXP peer must ensure that the
size of the payload is within the window advertised by the receiving
BXXP peer. If not, it has three choices:
o if the window would allow for at least one payload octet to be
sent, the BXXP peer may segment the message and start by sending
a smaller frame (up to the size of the remaining window);
o the BXXP peer may delay sending the message until the window
becomes larger; or,
o the BXXP peer may signal to its application that it is unable to
send the message, allowing the application to try again at a
later time (or perhaps signaling its application when a larger
window is available.)
The choice is implementation-dependent, although it is recommended
that the application using BXXP be given a mechanism for influencing
the decision.
2.5.3 Receiving REQ or RSP Messages
When a frame is received, the sum of its sequence number and payload
size, modulo 4294967296 (2**32), gives the expected sequence number
associated with the first payload octet of the next frame received.
Accordingly, when receiving a frame if the sequence number isn't the
expected value for this channel, then the BXXP peers have lost
synchronization, then the connection is closed without generating a
response, and it is recommended that a diagnostic entry be logged.
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2.5.4 Processing SEQ Messages
As an application accepts responsibility for incoming frames, its
BXXP peer should send "SEQ" messages to advertise a new window.
The "SEQ" message has three parameters:
o a channel number;
o an acknowledgement number, that indicates the value of the next
sequence number that the sender is expecting to receive on this
channel; and,
o a window size, that indicates the number of payload octets
beginning with the one indicated by the acknowledgement number
that the sender is expecting to receive on this channel.
A single space character (decimal code 32, " ") separates each
component. The "SEQ" message is terminated with a CRLF pair.
When a "SEQ" message is received, if any of the channel number,
acknowledgement number, or window size cannot be determined or is
invalid, then the connection is closed without generating a
response, and it is recommended that a diagnostic entry be logged.
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2.5.5 Use of Flow Control
The key to successful use of flow control within BXXP is to balance
performance and fairness:
o large messages should be segmented into multiple frames (e.g.,
the BXXP segment size should be no larger than TCP's negotiated
maximum segment size minus some small constant);
o frames for different channels with traffic ready to send should
be sent in a round-robin fashion; and,
o a "SEQ" message should be sent each time a "REQ" or "RSP" message
is received (if the transport service presents multiple messages
to a BXXP peer simultaneously, then a single consolidating "SEQ"
message may be sent).
In order to avoid pathological interactions with the transport
service, it is important that a BXXP peer advertise windows based on
available buffer space, to allow data to be read from the transport
service as soon as available. Further, "SEQ" messages for a channel
should have higher priority than "REQ" or "RSP messages for that
channel.
Finally, implementations may wish to provide queue management
facilities to the application using BXXP, e.g., channel priorities.
In particular, implementations should not allow a given channel to
monopolize the underlying transport window (e.g., slow readers
should get small windows).
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2.6 Parallelism
2.6.1 Within a single channel
A BXXP peer acting in the client role may send multiple "REQ"
messages for the same channel without waiting to receive the
corresponding "RSP" messages. A BXXP peer acting in the server role
must process all "REQ" messages for a given channel in the same
order as they are received. As a consequence, that BXXP peer must
generate the corresponding "RSP" messages in the same order as the
"REQ" messages are received.
2.6.2 Between different channels
A BXXP peer acting in the client role may send multiple "REQ"
messages for different channels without waiting to receive the
corresponding "RSP" messages. A BXXP peer acting in the server role
may process "REQ" messages received for different channels in
parallel. As a consequence, although the "RSP" messages for a given
channel are generating according to the order in which the
corresponding "REQ" messages are received, there is no ordering
constraint between "RSP" messages for different channels.
2.6.3 Pre-emptive responses
A BXXP peer acting in the server role may send a negative response
to a request before it receives the final "REQ" frame of a request.
If it does so, that BXXP peer is obliged to ignore any subsequent
"REQ" frames for that request, up to and including the final "REQ"
frame.
If a BXXP peer acting in the client role receives a negative "RSP"
frame before it sends the final "REQ" frame for a request, then it
is required to send a "REQ" frame with a continuation status of
complete (".") and having a zero-length payload.
2.6.4 Interference
If the processing of a particular frame has sequencing impacts on
other frames (either intra-channel or inter-channel), then the
corresponding profile should define this behavior, e.g., a profile
whose messages alter the underlying transport service.
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2.7 Peer-to-Peer Behavior
BXXP is a peer-to-peer protocol -- as such both peers must be
prepared to receive both "REQ" and "RSP" frames. Accordingly, an
initiating BXXP peer capable of acting only in the client role must
behave gracefully if it receives a "REQ" message. Accordingly, all
profiles must provide an appropriate error message for responding to
unwanted requests.
As a consequence of the peer-to-peer nature of BXXP, serial numbers
are unidirectionally-significant. That is, the serial numbers in
"REQ" messages sent by a BXXP peer acting in the initiating role are
unrelated to the serial numbers in "REQ" messages sent by a BXXP
peer acting in the listening role.
For example, these two frames
I: REQ . 1 14 94 0
I:
I:
I:
I:
I: END
L: REQ . 1 284 89 0
L:
L:
L:
L:
L: END
have no fundamental relationship to each other.
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3. Transport Security
When a BXXP session starts, plaintext transfer, without privacy, is
provided. Accordingly, transport security in BXXP is achieved using
an initial tuning profile.
This document defines one profile:
o the TLS transport security profile, based on TLS version one[5].
Other profiles may be defined and deployed on a bilateral basis.
When a channel associated with transport security begins the
underlying negotiation process, all channels (including channel 0),
are closed on the BXXP session. Upon completion of the negotiation
process, regardless of its outcome, a new greeting is issued by both
BXXP peers.
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A BXXP peer may choose to issue different greetings based on whether
privacy is in use, e.g.,
L:
I:
L: RSP . 0 0 84 +
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
I: REQ . 1 14 120 0
I:
I:
I:
I:
I:
I:
I: END
L: RSP . 1 84 83 +
L:
L:
L:
L:
L: END
... successful transport security negotiation ...
L: RSP . 0 0 224 +
L:
L:
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
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Of course, not all BXXP peers need be as single-minded:
L:
I:
L: RSP . 0 0 284 +
L:
L:
L:
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
I: REQ . 1 14 120 0
I:
I:
I:
I:
I:
I:
I: END
L: RSP . 1 284 83 +
L:
L:
L:
L:
L: END
... failed transport security negotiation ...
L: RSP . 0 0 284 +
L:
L:
L:
L:
L:
L:
L:
L: END
I: RSP . 0 0 14 +
I:
I:
I: END
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3.1 The TLS Transport Security Profile
Section 6.3 contains the registration for this profile.
3.1.1 Profile Identification and Initialization
The TLS transport security profile is identified as:
http://xml.resource.org/profiles/TLS
in the BXXP "profile" element during channel creation.
During channel creation, the corresponding "profile" element in the
BXXP "start" element may contain a "ready" element. If channel
creation is successful, then before sending the corresponding "RSP"
message, the BXXP peer processes the "ready" element and includes
the resulting response in the "RSP" message, e.g.,
C: REQ . 1 14 120 0
C:
C:
C:
C:
C:
C:
C: END
S: RSP . 1 84 83 +
S:
S:
S:
S:
S: END
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Note that it is possible for the channel to be created, but for the
encapsulated operation to fail, e.g.,
C: REQ . 1 14 135 0
C:
C:
C:
C:
C:
C:
C: END
S: RSP . 1 84 156 +
S:
S:
S: version attribute
S: poorly formed in <ready> element
S:
S: END
In this case, a positive "RSP" message is returned (as channel
creation succeeded), but the encapsulated response contains an
indication as to why the operation failed.
3.1.2 Request and Response Messages
Section 6.4 defines the messages that are used in the TLS transport
security profile:
o "REQ" messages carry only the "ready" element as data;
o positive "RSP" messages carry only the "proceed" element as data;
and,
o negative "RSP" messages carry only the "error" element as data.
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3.1.3 Message Semantics
3.1.3.1 The Ready Message
The "ready" element has an optional "version" attribute and no
content:
o the "version" element defines the earliest version of TLS
acceptable for use.
When a BXXP peer sends the "ready" element, it no longer sends any
traffic on any channel until a corresponding "RSP" message is
received; similarly, before processing a "ready" element, the
receiving BXXP peer waits until any pending "RSP" messages have been
generated and sent.
3.1.3.2 The Proceed Message
The "proceed" element has no attributes and no content. It is sent
in response to the "ready" element. When a BXXP peer receives the
"ready" element, it begins the underlying negotiation process for
transport security.
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4. User Authentication
When a BXXP session starts, anonymous access, without trace
information, is provided. Accordingly, user authentication in BXXP
is achieved using an initial tuning profile.
This document defines a family of profiles based on SASL mechanisms:
o each mechanism in the IANA SASL registry[14] has an associated
profile.
Other profiles may be defined and deployed on a bilateral basis.
Whenever a successful authentication occurs, on any channel, the
authenticated identity is updated for all existing and future
channels on the BXXP session; further, no additional attempts at
authentication are allowed.
Note that regardless of transport security and user authentication,
authorization is an internal matter for each BXXP peer. As such,
each peer may choose to restrict the operations it allows based on
the authentication credentials provided (i.e., unauthorized
operations are rejected with error code 530).
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4.1 The SASL Family of Profiles
Section 6.5 contains the registration for this profile.
Note that SASL may provide both user authentication and transport
security. Once transport security is successfully negotiated for a
BXXP session, then a SASL security layer may not be negotiated;
similarly, once any SASL negotiation is successful, a transport
security profile may not be started or otherwise used.
Section 4 of the SASL specification[6] requires the following
information be supplied by a protocol definition:
service name: "bxxp" will be registered with the IANA as a GSSAPI
service name when this draft is published as an RFC.
initiation sequence: Creating a channel using a BXXP profile
corresponding to a SASL mechanism starts the exchange. An
optional parameter corresponding to the "initial response" sent
by the client is carried within a "blob" element during channel
creation.
exchange sequence: "Challenges" and "responses" are carried in the
"blob" element during data exchange. The "status" attribute of
the "blob" element is used both by a server indicating a
successful completion of the exchange, and a client aborting the
exchange, The server indicates failure of the exchange by sending
an "error" element.
security layer negotiation: Prior to beginning the negotiation of a
security layer, any pending "RSP" messages are generated and
sent; further, once negotiation begins, no traffic is sent on any
other channels until the negotiation completes.
If a security layer is successfully negotiated, it takes effect
immediately following the message that concludes the server's
successful completion reply. When a security layer takes effect,
all channels (including channel 0), are closed on the BXXP
session, and a new greeting is issued by both BXXP peers.
use of the authorization identity: This is made available to all
channels for the duration of the BXXP session.
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4.1.1 Profile Identification and Initialization
Each SASL mechanism registered with the IANA is identified as:
http://xml.resource.org/profiles/sasl/MECHANISM
where "MECHANISM" is the token assigned to that mechanism by the
IANA.
Note that during channel creation, a BXXP peer may provide multiple
profiles to the remote peer, e.g.,
C: REQ . 1 14 171 0
C:
C:
C:
C:
C:
C: END
S: RSP . 1 284 61 +
S:
S:
S: END
During channel creation, the corresponding "profile" element in the
BXXP "start" element may provide data in a "blob" element. Note that
it is possible for the channel to be created, but for the
encapsulated operation to fail, e.g.,
C: REQ . 1 14 145 0
C:
C:
C:
C: AGJsb2NrbWFzdGVy
C:
C:
C: END
S: RSP . 1 284 140 +
S:
S:
S: authentication mechanism is
S: too weak
S:
S: END
In this case, a positive "RSP" message is returned (as channel
creation succeeded), but the encapsulated response contains an
indication as to why the operation failed.
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Otherwise, the server returns a challenge (or signifies success),
e.g.,
C: REQ . 1 14 145 0
C:
C:
C:
C: AGJsb2NrbWFzdGVy
C:
C:
C: END
S: RSP . 1 284 144 +
S:
S:
S: b3RwLXNoYTEgOTk5NyBwaXh5bWlzYXM4NTgwNSBleHQ=
S:
S: END
If a challenge is received, then the client responds and awaits a
reply, e.g.,
C: REQ . 2 0 67 1
C:
C: d29yZDpmZXJuIGhhbmcgYnJvdyBib25nIGhlcmQgdG9n
C: END
S: RSP . 2 0 13 +
S:
S:
S: END
Of course, the client could abort the authentication process by
sending "" instead.
Alternatively, the server might reject the response with an error:
e.g.,
C: REQ . 2 0 67 1
C:
C: d29yZDpmZXJuIGhhbmcgYnJvdyBib25nIGhlcmQgdG9n
C: END
S: RSP . 2 0 22 -
S:
S:
S: END
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Finally, depending on the SASL mechanism, an initialization element
may be exchanged unidirectionally during channel creation, e.g.,
C: REQ . 1 14 107 0
C:
C:
C:
C:
C: END
S: RSP . 1 284 148 +
S:
S:
S: PDE4OTYuNjk3MTcwOTUyQHBvc3RvZmZpY2UucmVzdG9uLm1jaS5uZXQ+
S:
S: END
Note that this example implies that the "blob" element in the
server's reply appears on two lines -- this is an artifact of the
presentation; in fact, only one line is used.
4.1.2 Request and Response Messages
Section 6.6 defines the messages that are used for each profile in
the SASL family:
o "REQ" messages carry only the "blob" element as data;
o positive "RSP" messages carry only the "blob" element as data;
and,
o negative "RSP" messages carry only the "error" element as data.
Because many SASL mechanisms exchange binary data, the content of
the "blob" element is always a base64-encoded string.
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4.1.3 Message Semantics
The "blob" element has an optional "status" attribute, and arbitrary
octets as its content:
o the "status" attribute, if present, takes one of three values:
abort: used by a client to indicate that it is aborting the
authentication process;
complete: used by a server to indicate that the exchange is
complete and successful; or,
continue: used by either a client or server, otherwise.
Finally, note that SASL's EXTERNAL mechanism works with an "external
authentication" service, which is provided by one of:
o a transport security profile, capable of providing authentication
information (e.g., Section 3.1), being active on the connection;
o a network service, capable of providing strong authentication
(e.g., IPSec[10]), underlying the connection; or,
o a locally-defined security service.
For authentication to succeed, two conditions must hold:
o an external authentication service must be active; and,
o if present, the authentication identity must be consistent with
the credentials provided by the external authentication service
(if the authentication identity is empty, then an authorization
identity is automatically derived from the credentials provided
by the external authentication service).
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5. Profile Registration Template
When a profile is registered, the following information is supplied:
Profile Identification: specify a URI[8] that authoritatively
identifies this profile.
Elements Exchanged during Channel Creation: specify the elements
that may be exchanged during channel creation (note that if the
profile doesn't exchange XML elements, then initialization
information may not be exchanged during channel creation).
Messages in "REQ" frames: specify the datatypes that may be present
in a request.
Messages in positive "RSP" frames: specify the datatypes that may be
present in a positive response.
Messages in negative "RSP" frames: specify the datatypes that may be
present in negative response.
Message Syntax: specify the syntax of the datatypes exchanged by the
profile.
Message Semantics: specify the semantics of the datatypes exchanged
by the profile.
Note that "datatype" refers to any MIME media type, whilst "element"
refers to any well-formed XML document.
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6. Initial Profile Registrations
6.1 BXXP Channel Management
Profile Identification: not applicable
Elements Exchanged during Channel Creation: not applicable
Messages in "REQ" frames: "start"
Messages in positive "RSP" frames: "greeting" or "profile"
Messages in negative "RSP" frames: "error"
Message Syntax: c.f., Section 6.2
Message Semantics: c.f., Section 2.3.1
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6.2 BXXP Channel Management DTD
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6.3 Registration: TLS Transport Security Profile
Profile Identification: http://xml.resource.org/profiles/TLS
Elements Exchanged during Channel Creation: "ready"
Messages in "REQ" frames: "ready"
Messages in positive "RSP" frames: "proceed"
Messages in negative "RSP" frames: "error"
Message Syntax: c.f., Section 6.4
Message Semantics: c.f., Section 3.1.3
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6.4 TLS Transport Security Profile DTD
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6.5 Registration: SASL Family of Profiles
Profile Identification:
http://xml.resource.org/profiles/sasl/MECHANISM, where
"MECHANISM" is a token registered with the IANA[15]
Elements Exchanged during Channel Creation: "blob"
Messages in "REQ" frames: "blob"
Messages in positive "RSP" frames: "blob"
Messages in negative "RSP" frames: "error"
Message Syntax: c.f., Section 6.6
Message Semantics: c.f., Section 4.1.3
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6.6 SASL Family of Profiles DTD
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7. Reply Codes
code meaning
==== =======
421 service not available
450 requested action not taken
(e.g., lock already in use)
451 requested action aborted
(e.g., local error in processing)
454 temporary authentication failure
500 general syntax error
(e.g., poorly-formed XML)
501 syntax error in parameters
(e.g., non-valid XML)
504 parameter not implemented
530 authentication required
534 authentication mechanism insufficient
(e.g., too weak, sequence exhausted, etc.)
535 authentication failure
537 action not authorized for user
538 authentication mechanism requires encryption
550 requested action not taken
(e.g., no requested profiles are acceptable)
553 parameter invalid
554 transaction failed
(e.g., policy violation)
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8. Security Considerations
The BXXP framing mechanism, per se, provides no protection against
attack; however, judicious use of initial tuning profiles provides
varying degrees of assurance:
1. If one of the profiles from the SASL family is used, refer to
[6]'s Section 9 for a discussion of security considerations.
2. If the TLS transport security profile is used (or if a SASL
security layer is negotiated), then:
1. A man-in-the-middle may remove the security-related profiles
from the BXXP greeting or generate an error response to the
"ready" element of the TLS transport security profile. A
BXXP peer may be configurable to refuse to proceed without
an acceptable level of privacy.
2. A man-in-the-middle may cause a down-negotiation to the
weakest cipher suite available. A BXXP peer should be
configurable to refuse weak cipher suites.
3. A man-in-the-middle may modify any protocol interactions
prior to a successful negotiation. Upon completing the
negotiation, a BXXP peer must discard previously cached
information about the BXXP session.
As different TLS ciphersuites provide varying levels of
security, administrators should carefully choose which
ciphersuites are provisioned.
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9. IANA Considerations
The IANA registers "bxxp" as a GSSAPI[11] service name.
The IANA maintains a list of:
o BXXP reply codes, c.f., Section 7; and,
o BXXP profiles that are defined in the RFC series.
The IANA makes the registrations specified in Section 6.3 and
Section 6.5.
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References
[1] Postel, J., "Transmission Control Protocol", RFC 793, STD 7,
Sep 1981.
[2] Rose, M.T., "On the Design of Application Protocols",
draft-mrose-blocks-appldesign-02 (work in progress), April
2000.
[3] World Wide Web Consortium, "Extensible Markup Language (XML)
1.0", W3C XML, February 1998,
.
[4] Freed, N. and N. Borenstein, "Multipurpose Internet Mail
Extensions (MIME) Part One: Format of Internet Message
Bodies", RFC 2045, November 1996.
[5] Dierks, T. and C. Allen, "The TLS Protocol Version 1.0", RFC
2246, January 1999.
[6] Myers, J.G., "Simple Authentication and Security Layer
(SASL)", RFC 2222, October 1997.
[7] Alvestrand, H., "Tags for the Identification of Languages",
RFC 1766, March 1995.
[8] Berners-Lee, T., Fielding, R.T. and L. Masinter, "Uniform
Resource Identifiers (URI): Generic Syntax", RFC 2396, August
1998.
[9] Newman, C., "The One-Time-Password SASL Mechanism", RFC 2444,
October 1998.
[10] Kent, S. and R. Atkinson, "Security Architecture for the
Internet Protocol", RFC 2401, November 1998.
[11] Linn, J., "Generic Security Service Application Program
Interface, Version 2", RFC 2078, January 1997.
[12] mailto:blocks-request@invisible.net
[13] http://mappa.mundi.net/
[14] http://www.isi.edu/in-notes/iana/assignments/sasl-mechanisms
[15] http://www.iana.org/
[16] mailto:ddc@lcs.mit.edu
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[17] mailto:dcrocker@brandenburg.com
[18] mailto:deering@cisco.com
[19] mailto:gazzetta@invisible.net
[20] mailto:dannyg@dannyg.com
[21] mailto:Robert.Herriot@pahv.xerox.com
[22] mailto:ben@algroup.co.uk
[23] mailto:carl@invisible.net
[24] mailto:michaelm@netsol.com
[25] mailto:pvm@a21.com
[26] mailto:rlmorgan@washington.edu
[27] mailto:fmorton@invisible.net
[28] mailto:dnew@san.rr.com
[29] mailto:chris.newman@innosoft.com
[30] mailto:craig@bbn.com
[31] mailto:paul@vix.com
[32] mailto:woods@invisible.net
Author's Address
Marshall T. Rose
Invisible Worlds, Inc.
1179 North McDowell Boulevard
Petaluma, CA 94954-6559
US
Phone: +1 707 789 3700
EMail: mrose@invisible.net
URI: http://invisible.net/
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Appendix A. Acknowledgements
The author gratefully acknowledges the contributions of: David
Clark[16], Dave Crocker[17], Steve Deering[18], Marco Gazzetta[19],
Danny Goodman[20], Robert Herriot[21], Ben Laurie[22], Carl
Malamud[23], Michael Mealling[24], Paul Mockapetris[25], RL 'Bob'
Morgan[26], Frank Morton[27], Darren New[28], Chris Newman[29],
Craig Partridge[30], Paul Vixie[31], and Daniel Woods[32]. In
particular, Dave Crocker provided helpful suggestions on the nature
of flow control and segmentation in the framing protocol.
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Full Copyright Statement
Copyright (C) The Internet Society (2000). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph
are included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
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Rose Expires October 30, 2000 [Page 51]
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Internet-Draft The BXXP Framework May 2000
Acknowledgement
Funding for the RFC editor function is currently provided by the
Internet Society.
Rose Expires October 30, 2000 [Page 52]
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