Internet Research Task Force (IRTF) M. Demmer
Request for Comments: 7242 UC Berkeley
Category: Experimental J. Ott
ISSN: 2070-1721 Aalto University
S. Perreault
This document describes the protocol for the TCP-based convergence
layer for Delay-Tolerant Networking (DTN). It is the product of the
IRTF's DTN Research Group (DTNRG).
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for examination, experimental implementation, and
evaluation.
This document defines an Experimental Protocol for the Internet
community. This document is a product of the Internet Research Task
Force (IRTF). The IRTF publishes the results of Internet-related
research and development activities. These results might not be
suitable for deployment. This RFC represents the consensus of the
Delay-Tolerant Networking Research Group of the Internet Research
Task Force (IRTF). Documents approved for publication by the IRSG
are not a candidate for any level of Internet Standard; see Section 2
of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc7242.
Copyright Notice
Copyright (c) 2014 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document.
This document describes the TCP-based convergence-layer protocol for
Delay-Tolerant Networking. Delay-Tolerant Networking is an end-to-
end architecture providing communications in and/or through highly
stressed environments, including those with intermittent
connectivity, long and/or variable delays, and high bit error rates.
More detailed descriptions of the rationale and capabilities of these
networks can be found in "Delay-Tolerant Network Architecture"
[RFC4838].
An important goal of the DTN architecture is to accommodate a wide
range of networking technologies and environments. The protocol used
for DTN communications is the Bundle Protocol (BP) [RFC5050], an
application-layer protocol that is used to construct a store-and-
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forward overlay network. As described in the Bundle Protocol
specification [RFC5050], it requires the services of a "convergence-
layer adapter" (CLA) to send and receive bundles using the service of
some "native" link, network, or Internet protocol. This document
describes one such convergence-layer adapter that uses the well-known
Transmission Control Protocol (TCP). This convergence layer is
referred to as TCPCL.
The locations of the TCPCL and the BP in the Internet model protocol
stack are shown in Figure 1. In particular, when BP is using TCP as
its bearer with TCPCL as its convergence layer, both BP and TCPCL
reside at the application layer of the Internet model.
Figure 1: The Locations of the Bundle Protocol and the TCP
Convergence-Layer Protocol in the Internet Protocol Stack
This document describes the format of the protocol data units passed
between entities participating in TCPCL communications. This
document does not address:
o The format of protocol data units of the Bundle Protocol, as those
are defined elsewhere [RFC5050].
o Mechanisms for locating or identifying other bundle nodes within
an internet.
Note that this document describes version 3 of the protocol.
Versions 0, 1, and 2 were never specified in an Internet-Draft, RFC,
or any other public document. These prior versions of the protocol
were, however, implemented in the DTN reference implementation
[DTNIMPL] in prior releases; hence, the current version number
reflects the existence of those prior versions.
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This is an experimental protocol produced within the IRTF's Delay-
Tolerant Networking Research Group (DTNRG). It represents the
consensus of all active contributors to this group. If this protocol
is used on the Internet, IETF standard protocols for security and
congestion control should be used.
2. Definitions
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in [RFC2119].
The terms defined in Section 3.1 of [RFC5050] are used extensively in
this document.
2.1. Definitions Specific to the TCPCL Protocol
This section contains definitions that are interpreted to be specific
to the operation of the TCPCL protocol, as described below.
TCP Connection -- A TCP connection refers to a transport connection
using TCP as the transport protocol.
TCPCL Connection -- A TCPCL connection (as opposed to a TCP
connection) is a TCPCL communication relationship between two
bundle nodes. The lifetime of a TCPCL connection is bound to
the lifetime of an underlying TCP connection. Therefore, a
TCPCL connection is initiated when a bundle node initiates a TCP
connection to be established for the purposes of bundle
communication. A TCPCL connection is terminated when the TCP
connection ends, due either to one or both nodes actively
terminating the TCP connection or due to network errors causing
a failure of the TCP connection. For the remainder of this
document, the term "connection" without the prefix "TCPCL" shall
refer to a TCPCL connection.
Connection parameters -- The connection parameters are a set of
values used to affect the operation of the TCPCL for a given
connection. The manner in which these parameters are conveyed
to the bundle node and thereby to the TCPCL is implementation
dependent. However, the mechanism by which two bundle nodes
exchange and negotiate the values to be used for a given session
is described in Section 4.2.
Transmission -- Transmission refers to the procedures and mechanisms
(described below) for conveyance of a bundle from one node to
another.
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3. General Protocol Description
The service of this protocol is the transmission of DTN bundles over
TCP. This document specifies the encapsulation of bundles,
procedures for TCP setup and teardown, and a set of messages and node
requirements. The general operation of the protocol is as follows.
First, one node establishes a TCPCL connection to the other by
initiating a TCP connection. After setup of the TCP connection is
complete, an initial contact header is exchanged in both directions
to set parameters of the TCPCL connection and exchange a singleton
endpoint identifier for each node (not the singleton Endpoint
Identifier (EID) of any application running on the node) to denote
the bundle-layer identity of each DTN node. This is used to assist
in routing and forwarding messages, e.g., to prevent loops.
Once the TCPCL connection is established and configured in this way,
bundles can be transmitted in either direction. Each bundle is
transmitted in one or more logical segments of formatted bundle data.
Each logical data segment consists of a DATA_SEGMENT message header,
a Self-Delimiting Numeric Value (SDNV) as defined in [RFC5050] (see
also [RFC6256]) containing the length of the segment, and finally the
byte range of the bundle data. The choice of the length to use for
segments is an implementation matter. The first segment for a bundle
must set the 'start' flag, and the last one must set the 'end' flag
in the DATA_SEGMENT message header.
If multiple bundles are transmitted on a single TCPCL connection,
they MUST be transmitted consecutively. Interleaving data segments
from different bundles is not allowed. Bundle interleaving can be
accomplished by fragmentation at the BP layer.
An optional feature of the protocol is for the receiving node to send
acknowledgments as bundle data segments arrive (ACK_SEGMENT). The
rationale behind these acknowledgments is to enable the sender node
to determine how much of the bundle has been received, so that in
case the connection is interrupted, it can perform reactive
fragmentation to avoid re-sending the already transmitted part of the
bundle.
When acknowledgments are enabled, then for each data segment that is
received, the receiving node sends an ACK_SEGMENT code followed by an
SDNV containing the cumulative length of the bundle that has been
received. The sending node may transmit multiple DATA_SEGMENT
messages without necessarily waiting for the corresponding
ACK_SEGMENT responses. This enables pipelining of messages on a
channel. In addition, there is no explicit flow control on the TCPCL
layer.
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Another optional feature is that a receiver may interrupt the
transmission of a bundle at any point in time by replying with a
REFUSE_BUNDLE message, which causes the sender to stop transmission
of the current bundle, after completing transmission of a partially
sent data segment. Note: This enables a cross-layer optimization in
that it allows a receiver that detects that it already has received a
certain bundle to interrupt transmission as early as possible and
thus save transmission capacity for other bundles.
For connections that are idle, a KEEPALIVE message may optionally be
sent at a negotiated interval. This is used to convey liveness
information.
Finally, before connections close, a SHUTDOWN message is sent on the
channel. After sending a SHUTDOWN message, the sender of this
message may send further acknowledgments (ACK_SEGMENT or
REFUSE_BUNDLE) but no further data messages (DATA_SEGMENT). A
SHUTDOWN message may also be used to refuse a connection setup by a
peer.
3.1. Bidirectional Use of TCP Connection
There are specific messages for sending and receiving operations (in
addition to connection setup/teardown). TCPCL is symmetric, i.e.,
both sides can start sending data segments in a connection, and one
side's bundle transfer does not have to complete before the other
side can start sending data segments on its own. Hence, the protocol
allows for a bi-directional mode of communication.
Note that in the case of concurrent bidirectional transmission,
acknowledgment segments may be interleaved with data segments.
3.2. Example Message Exchange
The following figure visually depicts the protocol exchange for a
simple session, showing the connection establishment and the
transmission of a single bundle split into three data segments (of
lengths L1, L2, and L3) from Node A to Node B.
Note that the sending node may transmit multiple DATA_SEGMENT
messages without necessarily waiting for the corresponding
ACK_SEGMENT responses. This enables pipelining of messages on a
channel. Although this example only demonstrates a single bundle
transmission, it is also possible to pipeline multiple DATA_SEGMENT
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messages for different bundles without necessarily waiting for
ACK_SEGMENT messages to be returned for each one. However,
interleaving data segments from different bundles is not allowed.
No errors or rejections are shown in this example.
Figure 2: A Simple Visual Example of the Flow of Protocol Messages on
a Single TCP Session between Two Nodes (A and B)
4. Connection Establishment
For bundle transmissions to occur using the TCPCL, a TCPCL connection
must first be established between communicating nodes. It is up to
the implementation to decide how and when connection setup is
triggered. For example, some connections may be opened proactively
and maintained for as long as is possible given the network
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conditions, while other connections may be opened only when there is
a bundle that is queued for transmission and the routing algorithm
selects a certain next-hop node.
To establish a TCPCL connection, a node must first establish a TCP
connection with the intended peer node, typically by using the
services provided by the operating system. Port number 4556 has been
assigned by IANA as the well-known port number for the TCP
convergence layer. Other port numbers MAY be used per local
configuration. Determining a peer's port number (if different from
the well-known TCPCL port) is up to the implementation.
If the node is unable to establish a TCP connection for any reason,
then it is an implementation matter to determine how to handle the
connection failure. A node MAY decide to re-attempt to establish the
connection. If it does so, it MUST NOT overwhelm its target with
repeated connection attempts. Therefore, the node MUST retry the
connection setup only after some delay (a 1-second minimum is
RECOMMENDED), and it SHOULD use a (binary) exponential backoff
mechanism to increase this delay in case of repeated failures. In
case a SHUTDOWN message specifying a reconnection delay is received,
that delay is used as the initial delay. The default initial delay
SHOULD be at least 1 second but SHOULD be configurable since it will
be application and network type dependent.
The node MAY declare failure after one or more connection attempts
and MAY attempt to find an alternate route for bundle data. Such
decisions are up to the higher layer (i.e., the BP).
Once a TCP connection is established, each node MUST immediately
transmit a contact header over the TCP connection. The format of the
contact header is described in Section 4.1.
Upon receipt of the contact header, both nodes perform the validation
and negotiation procedures defined in Section 4.2
After receiving the contact header from the other node, either node
MAY also refuse the connection by sending a SHUTDOWN message. If
connection setup is refused, a reason MUST be included in the
SHUTDOWN message.
4.1. Contact Header
Once a TCP connection is established, both parties exchange a contact
header. This section describes the format of the contact header and
the meaning of its fields.
magic: A four-byte field that always contains the byte sequence 0x64
0x74 0x6e 0x21, i.e., the text string "dtn!" in US-ASCII.
version: A one-byte field value containing the value 3 (current
version of the protocol).
flags: A one-byte field containing optional connection flags. The
first four bits are unused and MUST be set to zero upon
transmission and MUST be ignored upon reception. The last four
bits are interpreted as shown in Table 1 below.
keepalive_interval: A two-byte integer field containing the number
of seconds between exchanges of KEEPALIVE messages on the
connection (see Section 5.6). This value is in network byte
order, as are all other multi-byte fields described in this
protocol.
local EID length: A variable-length SDNV field containing the length
of the endpoint identifier (EID) for some singleton endpoint in
which the sending node is a member. A four-byte SDNV is
depicted for clarity of the figure.
local EID: A byte string containing the EID of some singleton
endpoint in which the sending node is a member, in the canonical
format of <scheme name>:<scheme-specific part>. An eight-byte
EID is shown for clarity of the figure.
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+----------+--------------------------------------------------------+
| Value | Meaning |
+----------+--------------------------------------------------------+
| 00000001 | Request acknowledgment of bundle segments. |
| 00000010 | Request enabling of reactive fragmentation. |
| 00000100 | Indicate support for bundle refusal. This flag MUST |
| | NOT be set to '1' unless support for acknowledgments |
| | is also indicated. |
| 00001000 | Request sending of LENGTH messages. |
+----------+--------------------------------------------------------+
Table 1: Contact Header Flags
The manner in which values are configured and chosen for the various
flags and parameters in the contact header is implementation
dependent.
4.2. Validation and Parameter Negotiation
Upon reception of the contact header, each node follows the following
procedures to ensure the validity of the TCPCL connection and to
negotiate values for the connection parameters.
If the magic string is not present or is not valid, the connection
MUST be terminated. The intent of the magic string is to provide
some protection against an inadvertent TCP connection by a different
protocol than the one described in this document. To prevent a flood
of repeated connections from a misconfigured application, a node MAY
elect to hold an invalid connection open and idle for some time
before closing it.
If a node receives a contact header containing a version that is
greater than the current version of the protocol that the node
implements, then the node SHOULD interpret all fields and messages as
it would normally. If a node receives a contact header with a
version that is lower than the version of the protocol that the node
implements, the node may either terminate the connection due to the
version mismatch or may adapt its operation to conform to the older
version of the protocol. This decision is an implementation matter.
A node calculates the parameters for a TCPCL connection by
negotiating the values from its own preferences (conveyed by the
contact header it sent) with the preferences of the peer node
(expressed in the contact header that it received). This negotiation
MUST proceed in the following manner:
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o The parameter for requesting acknowledgment of bundle segments is
set to true iff the corresponding flag is set in both contact
headers.
o The parameter for enabling reactive fragmentation is set to true
iff the corresponding flag is set in both contact headers.
o The bundle refusal capability is set to true if the corresponding
flag is set in both contact headers and if segment acknowledgment
has been enabled.
o The keepalive_interval parameter is set to the minimum value from
both contact headers. If one or both contact headers contains the
value zero, then the keepalive feature (described in Section 5.6)
is disabled.
o The flag requesting sending of LENGTH messages is handled as
described in Section 5.5.
Once this process of parameter negotiation is completed, the protocol
defines no additional mechanism to change the parameters of an
established connection; to effect such a change, the connection MUST
be terminated and a new connection established.
5. Established Connection Operation
This section describes the protocol operation for the duration of an
established connection, including the mechanisms for transmitting
bundles over the connection.
5.1. Message Type Codes
After the initial exchange of a contact header, all messages
transmitted over the connection are identified by a one-byte header
with the following structure:
type: Indicates the type of the message as per Table 2 below
flags: Optional flags defined based on message type.
The types and values for the message type code are as follows.
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+----------------+---------+----------------------------------------+
| Type | Code | Description |
+----------------+---------+----------------------------------------+
| | 0x0 | Reserved. |
| | | |
| DATA_SEGMENT | 0x1 | Indicates the transmission of a |
| | | segment of bundle data, as described |
| | | in Section 5.2. |
| | | |
| ACK_SEGMENT | 0x2 | Acknowledges reception of a data |
| | | segment, as described in Section 5.3 |
| | | |
| REFUSE_BUNDLE | 0x3 | Indicates that the transmission of the |
| | | current bundle shall be stopped, as |
| | | described in Section 5.4. |
| | | |
| KEEPALIVE | 0x4 | KEEPALIVE message for the connection, |
| | | as described in Section 5.6. |
| | | |
| SHUTDOWN | 0x5 | Indicates that one of the nodes |
| | | participating in the connection wishes |
| | | to cleanly terminate the connection, |
| | | as described in Section 6. |
| | | |
| LENGTH | 0x6 | Contains the length (in bytes) of the |
| | | next bundle, as described in Section |
| | | 5.5. |
| | | |
| | 0x7-0xf | Unassigned. |
| | | |
+----------------+---------+----------------------------------------+
Table 2: TCPCL Message Types
5.2. Bundle Data Transmission (DATA_SEGMENT)
Each bundle is transmitted in one or more data segments. The format
of a DATA_SEGMENT message follows:
The type portion of the message header contains the value 0x1.
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The flags portion of the message header byte contains two optional
values in the two low-order bits, denoted 'S' and 'E' above. The 'S'
bit MUST be set to one if it precedes the transmission of the first
segment of a new bundle. The 'E' bit MUST be set to one when
transmitting the last segment of a bundle.
Following the message header, the length field is an SDNV containing
the number of bytes of bundle data that are transmitted in this
segment. Following this length is the actual data contents.
Determining the size of the segment is an implementation matter. In
particular, a node may, based on local policy or configuration, only
ever transmit bundle data in a single segment, in which case both the
'S' and 'E' bits MUST be set to one.
In the Bundle Protocol specification [RFC5050], a single bundle
comprises a primary bundle block, a payload block, and zero or more
additional bundle blocks. The relationship between the protocol
blocks and the convergence-layer segments is an implementation-
specific decision. In particular, a segment MAY contain more than
one protocol block; alternatively, a single protocol block (such as
the payload) MAY be split into multiple segments.
However, a single segment MUST NOT contain data of more than a single
bundle.
Once a transmission of a bundle has commenced, the node MUST only
send segments containing sequential portions of that bundle until it
sends a segment with the 'E' bit set.
5.3. Bundle Acknowledgments (ACK_SEGMENT)
Although the TCP transport provides reliable transfer of data between
transport peers, the typical BSD sockets interface provides no means
to inform a sending application of when the receiving application has
processed some amount of transmitted data. Thus, after transmitting
some data, a Bundle Protocol agent needs an additional mechanism to
determine whether the receiving agent has successfully received the
segment.
To this end, the TCPCL protocol offers an optional feature whereby a
receiving node transmits acknowledgments of reception of data
segments. This feature is enabled if, and only if, during the
exchange of contact headers, both parties set the flag to indicate
that segment acknowledgments are enabled (see Section 4.1). If so,
then the receiver MUST transmit a bundle acknowledgment message when
it successfully receives each data segment.
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The format of a bundle acknowledgment is as follows:
To transmit an acknowledgment, a node first transmits a message
header with the ACK_SEGMENT type code and all flags set to zero, then
transmits an SDNV containing the cumulative length in bytes of the
received segment(s) of the current bundle. The length MUST fall on a
segment boundary. That is, only full segments can be acknowledged.
For example, suppose the sending node transmits four segments of
bundle data with lengths 100, 200, 500, and 1000, respectively.
After receiving the first segment, the node sends an acknowledgment
of length 100. After the second segment is received, the node sends
an acknowledgment of length 300. The third and fourth
acknowledgments are of length 800 and 1800, respectively.
5.4. Bundle Refusal (REFUSE_BUNDLE)
As bundles may be large, the TCPCL supports an optional mechanisms by
which a receiving node may indicate to the sender that it does not
want to receive the corresponding bundle.
To do so, upon receiving a DATA_SEGMENT message, the node MAY
transmit a REFUSE_BUNDLE message. As data segments and
acknowledgments may cross on the wire, the bundle that is being
refused is implicitly identified by the sequence in which
acknowledgements and refusals are received.
The format of the REFUSE_BUNDLE message is as follows:
The RCode field, which stands for "reason code", contains a value
indicating why the bundle was refused. The following table contains
semantics for some values. Other values may be registered with IANA,
as defined in Section 8.
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+---------+---------------------------------------------------------+
| RCode | Semantics |
+---------+---------------------------------------------------------+
| 0x0 | Reason for refusal is unknown or not specified. |
| 0x1 | The receiver now has the complete bundle. The sender |
| | may now consider the bundle as completely received. |
| 0x2 | The receiver's resources are exhausted. The sender |
| | SHOULD apply reactive bundle fragmentation before |
| | retrying. |
| 0x3 | The receiver has encountered a problem that requires |
| | the bundle to be retransmitted in its entirety. |
| 0x4-0x7 | Unassigned. |
| 0x8-0xf | Reserved for future usage. |
+---------+---------------------------------------------------------+
Table 3: REFUSE_BUNDLE Reason Codes
The receiver MUST, for each bundle preceding the one to be refused,
have either acknowledged all DATA_SEGMENTs or refused the bundle.
This allows the sender to identify the bundles accepted and refused
by means of a simple FIFO list of segments and acknowledgments.
The bundle refusal MAY be sent before the entire data segment is
received. If a sender receives a REFUSE_BUNDLE message, the sender
MUST complete the transmission of any partially sent DATA_SEGMENT
message (so that the receiver stays in sync). The sender MUST NOT
commence transmission of any further segments of the rejected bundle
subsequently. Note, however, that this requirement does not ensure
that a node will not receive another DATA_SEGMENT for the same bundle
after transmitting a REFUSE_BUNDLE message since messages may cross
on the wire; if this happens, subsequent segments of the bundle
SHOULD also be refused with a REFUSE_BUNDLE message.
Note: If a bundle transmission is aborted in this way, the receiver
may not receive a segment with the 'E' flag set to '1' for the
aborted bundle. The beginning of the next bundle is identified by
the 'S' bit set to '1', indicating the start of a new bundle.
5.5. Bundle Length (LENGTH)
The LENGTH message contains the total length, in bytes, of the next
bundle, formatted as an SDNV. Its purpose is to allow nodes to
preemptively refuse bundles that would exceed their resources. It is
an optimization.
LENGTH messages MUST NOT be sent unless the corresponding flag bit is
set in the contact header. If the flag bit is set, LENGTH messages
MAY be sent at the sender's discretion. LENGTH messages MUST NOT be
sent unless the next DATA_SEGMENT message has the 'S' bit set to "1"
(i.e., just before the start of a new bundle).
A receiver MAY send a BUNDLE_REFUSE message as soon as it receives a
LENGTH message without waiting for the next DATA_SEGMENT message.
The sender MUST be prepared for this and MUST associate the refusal
with the right bundle.
5.6. KEEPALIVE Feature (KEEPALIVE)
The protocol includes a provision for transmission of KEEPALIVE
messages over the TCP connection to help determine if the connection
has been disrupted.
As described in Section 4.1, one of the parameters in the contact
header is the keepalive_interval. Both sides populate this field
with their requested intervals (in seconds) between KEEPALIVE
messages.
The format of a KEEPALIVE message is a one-byte message type code of
KEEPALIVE (as described in Table 2) with no additional data. Both
sides SHOULD send a KEEPALIVE message whenever the negotiated
interval has elapsed with no transmission of any message (KEEPALIVE
or other).
If no message (KEEPALIVE or other) has been received for at least
twice the keepalive_interval, then either party MAY terminate the
session by transmitting a one-byte SHUTDOWN message (as described in
Table 2) and by closing the TCP connection.
Note: The keepalive_interval should not be chosen too short as TCP
retransmissions may occur in case of packet loss. Those will have to
be triggered by a timeout (TCP retransmission timeout (RTO)), which
is dependent on the measured RTT for the TCP connection so that
KEEPALIVE messages may experience noticeable latency.
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6. Connection Termination
This section describes the procedures for ending a TCPCL connection.
6.1. Shutdown Message (SHUTDOWN)
To cleanly shut down a connection, a SHUTDOWN message MUST be
transmitted by either node at any point following complete
transmission of any other message. In case acknowledgments have been
negotiated, a node SHOULD acknowledge all received data segments
first and then shut down the connection.
It is possible for a node to convey additional information regarding
the reason for connection termination. To do so, the node MUST set
the 'R' bit in the message header flags and transmit a one-byte
reason code immediately following the message header. The specified
values of the reason code are:
+-----------+------------------+------------------------------------+
| Code | Meaning | Description |
+-----------+------------------+------------------------------------+
| 0x00 | Idle timeout | The connection is being closed due |
| | | to idleness. |
| | | |
| 0x01 | Version mismatch | The node cannot conform to the |
| | | specified TCPCL protocol version. |
| | | |
| 0x02 | Busy | The node is too busy to handle the |
| | | current connection. |
| | | |
| 0x03-0xff | | Unassigned. |
+-----------+------------------+------------------------------------+
Table 4: SHUTDOWN Reason Codes
It is also possible to convey a requested reconnection delay to
indicate how long the other node must wait before attempting
connection re-establishment. To do so, the node sets the 'D' bit in
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the message header flags and then transmits an SDNV specifying the
requested delay, in seconds, following the message header (and
optionally, the SHUTDOWN reason code). The value 0 SHALL be
interpreted as an infinite delay, i.e., that the connecting node MUST
NOT re-establish the connection. In contrast, if the node does not
wish to request a delay, it SHOULD omit the reconnection delay field
(and set the 'D' bit to zero). Note that in the figure above, the
reconnection delay SDNV is represented as a two-byte field for
convenience.
A connection shutdown MAY occur immediately after TCP connection
establishment or reception of a contact header (and prior to any
further data exchange). This may, for example, be used to notify
that the node is currently not able or willing to communicate.
However, a node MUST always send the contact header to its peer
before sending a SHUTDOWN message.
If either node terminates a connection prematurely in this manner, it
SHOULD send a SHUTDOWN message and MUST indicate a reason code unless
the incoming connection did not include the magic string. If a node
does not want its peer to reopen the connection immediately, it
SHOULD set the 'D' bit in the flags and include a reconnection delay
to indicate when the peer is allowed to attempt another connection
setup.
If a connection is to be terminated before another protocol message
has completed, then the node MUST NOT transmit the SHUTDOWN message
but still SHOULD close the TCP connection. In particular, if the
connection is to be closed (for whatever reason) while a node is in
the process of transmitting a bundle data segment, the receiving node
is still expecting segment data and might erroneously interpret the
SHUTDOWN message to be part of the data segment.
6.2. Idle Connection Shutdown
The protocol includes a provision for clean shutdown of idle TCP
connections. Determining the length of time to wait before closing
idle connections, if they are to be closed at all, is an
implementation and configuration matter.
If there is a configured time to close idle links and if no bundle
data (other than KEEPALIVE messages) has been received for at least
that amount of time, then either node MAY terminate the connection by
transmitting a SHUTDOWN message indicating the reason code of 'Idle
timeout' (as described in Table 4). After receiving a SHUTDOWN
message in response, both sides may close the TCP connection.
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7. Security Considerations
One security consideration for this protocol relates to the fact that
nodes present their endpoint identifier as part of the connection
header exchange. It would be possible for a node to fake this value
and present the identity of a singleton endpoint in which the node is
not a member, essentially masquerading as another DTN node. If this
identifier is used without further verification as a means to
determine which bundles are transmitted over the connection, then the
node that has falsified its identity may be able to obtain bundles
that it should not have. Therefore, a node SHALL NOT use the
endpoint identifier conveyed in the TCPCL connection message to
derive a peer node's identity unless it can ascertain it via other
means.
These concerns may be mitigated through the use of the Bundle
Security Protocol [RFC6257]. In particular, the Bundle
Authentication Block defines mechanism for secure exchange of bundles
between DTN nodes. Thus, an implementation could delay trusting the
presented endpoint identifier until the node can securely validate
that its peer is in fact the only member of the given singleton
endpoint.
In general, TCPCL does not provide any security services. The
mechanisms defined in [RFC6257] are to be used instead.
Nothing in TCPCL prevents the use of the Transport Layer Security
(TLS) protocol [RFC5246] to secure a connection.
Another consideration for this protocol relates to denial-of-service
attacks. A node may send a large amount of data over a TCP
connection, requiring the receiving node to handle the data, attempt
to stop the flood of data by sending a REFUSE_BUNDLE message, or
forcibly terminate the connection. This burden could cause denial of
service on other, well-behaving connections. There is also nothing
to prevent a malicious node from continually establishing connections
and repeatedly trying to send copious amounts of bundle data. A
listening node MAY take countermeasures such as ignoring TCP SYN
messages, closing TCP connections as soon as they are established,
waiting before sending the contact header, sending a SHUTDOWN message
quickly or with a delay, etc.
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8. IANA Considerations
In this section, registration procedures are as defined in [RFC5226].
8.1. Port Number
Port number 4556 has been assigned as the default port for the TCP
convergence layer.
IANA has created, under the "Bundle Protocol" registry, a sub-
registry titled "Bundle Protocol TCP Convergence-Layer Version
Numbers" and initialized it with the following:
IANA has created, under the "Bundle Protocol" registry, a sub-
registry titled "Bundle Protocol TCP Convergence-Layer Message Types"
and initialized it with the contents of Table 2. The registration
procedure is RFC Required.
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8.4. REFUSE_BUNDLE Reason Codes
IANA has created, under the "Bundle Protocol" registry, a sub-
registry titled "Bundle Protocol TCP Convergence-Layer REFUSE_BUNDLE
Reason Codes" and initialized it with the contents of Table 3. The
registration procedure is RFC Required.
8.5. SHUTDOWN Reason Codes
IANA has created, under the "Bundle Protocol" registry, a sub-
registry titled "Bundle Protocol TCP Convergence-Layer SHUTDOWN
Reason Codes" and initialized it with the contents of Table 4. The
registration procedure is RFC Required.
9. Acknowledgments
The authors would like to thank the following individuals who have
participated in the drafting, review, and discussion of this memo:
Alex McMahon, Brenton Walker, Darren Long, Dirk Kutscher, Elwyn
Davies, Jean-Philippe Dionne, Joseph Ishac, Keith Scott, Kevin Fall,
Lloyd Wood, Marc Blanchet, Peter Lovell, Scott Burleigh, Stephen
Farrell, Vint Cerf, and William Ivancic.
10. References
10.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC5050] Scott, K. and S. Burleigh, "Bundle Protocol
Specification", RFC 5050, November 2007.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
[RFC4838] Cerf, V., Burleigh, S., Hooke, A., Torgerson, L., Durst,
R., Scott, K., Fall, K., and H. Weiss, "Delay-Tolerant
Networking Architecture", RFC 4838, April 2007.
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[RFC5246] Dierks, T. and E. Rescorla, "The Transport Layer Security
(TLS) Protocol Version 1.2", RFC 5246, August 2008.
[RFC6256] Eddy, W. and E. Davies, "Using Self-Delimiting Numeric
Values in Protocols", RFC 6256, May 2011.
[RFC6257] Symington, S., Farrell, S., Weiss, H., and P. Lovell,
"Bundle Security Protocol Specification", RFC 6257, May
2011.
Authors' Addresses
Michael J. Demmer
University of California, Berkeley
Computer Science Division
445 Soda Hall
Berkeley, CA 94720-1776
US
