One document matched: draft-ietf-rsvp-diagnostic-msgs-06.txt
Differences from draft-ietf-rsvp-diagnostic-msgs-05.txt
INTERNET-DRAFT Andreas Terzis
Expires: August 1999 UCLA
<draft-ietf-rsvp-diagnostic-msgs-06.txt> Bob Braden
ISI
Subramaniam Vincent
Cisco Systems
Lixia Zhang
UCLA
February 1999
RSVP Diagnostic Messages
<draft-ietf-rsvp-diagnostic-msgs-06.txt>
Status of this Memo
This document is an Internet-Draft and is in full conformance with all
provisions of Section 10 of RFC2026.
Internet-Drafts are working documents of the Internet Engineering Task
Force (IETF), its areas, and its working groups. Note that other groups
may also distribute working documents as Internet-Drafts.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference material
or to cite them other than as "work in progress."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt
The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html.
Abstract
This document specifies the RSVP diagnostic facility, which allows a
user to collect information about the RSVP state along the path. This
specification describes the functionality, diagnostic message formats,
and processing rules.
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Changes
A summary of the changes from the previous version (05) of this document
follows:
- Added text in the Overview Section, to explain the role of the
LAST-HOP node. Section 4.1 was also updated with rules for DREQ
processing at RSVP nodes downstream of the LAST-HOP.
- The Next-Hop RSVP_HOP object was moved out of the DIAGNOSTIC
object. It's new place is directly after the Session object and
before the DIAGNOSTIC object. This was done to simplify implementa-
tion and to comply with object order in other RSVP messages. The IP
address of this RSVP_HOP object now carries the address of the
interface from which the DREQ is sent. While the IP address is not
(currently) used, this was done to conform with the use of RSVP_HOP
objects in other RSVP messages.
- A minimum value for the Path MTU field is defined.
- In the description of the DIAG_SELECT object, new text is added
explaining where the information requested by object types can be
collected from.
- The text explaining the use of the Previous RSVP-Hop Router Address
in the DIAG_RESPONSE object was changed. The previous version
incorrectly said that this address was the address of the interface
through which the DREQ would be forwarded. It is actually the
address *to* which the DREQ message will be forwarded.
- In the DIAGNOSTIC object, the LAST-HOP IP address was moved in
front of the SENDER_TEMPLATE.
- The H bit was removed. The existence of the ROUTE object signifies
whether the DREQ should be returned hop-by-hop.
- The "MTU too big" error was renamed to "packet too big" to reflect
more closely the situation under which it is generated.
- Section 4.1 (DREQ Packet Forwarding) was revamped
- The Send_DREP() section was rewritten
- Section 4.2 (DREP Forwarding) was updated.
- Section 4.3 (MTU Selection and Adjustment) was updated.
1. Introduction
In the basic RSVP protocol [RSVP], error messages are the only means for
an end host to receive feedback regarding a failure in setting up either
path state or reservation state. An error message carries back only the
information from the failed point, without any information about the
state at other hops before or after the failure. In the absence of
failures, a host receives no feedback regarding the details of a reser-
vation that has been put in place, such as whether, or where, or how,
its own reservation request is being merged with that of others. Such
missing information can be highly desirable for debugging purpose, or
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for network resource management in general.
This document specifies the RSVP diagnostic facility, which is designed
to fill this information gap. The diagnostic facility can be used to
collect and report RSVP state information along the path from a receiver
to a specific sender. It uses Diagnostic messages that are independent
of other RSVP control messages and produce no side-effects; that is,
they do not change any RSVP state at either nodes or hosts. Similarly,
they provide not an error report but rather a collection of requested
RSVP state information.
The RSVP diagnostic facility was designed with the following goals:
- To collect RSVP state information from every RSVP-capable hop along
a path defined by path state, either for an existing reservation or
before a reservation request is made. More specifically, we want
to be able to collect information about flowspecs, refresh timer
values, and reservation merging at each hop along the path.
- To collect the IP hop count across each non-RSVP cloud.
- To avoid diagnostic packet implosion or explosion.
The following is specifically identified as a non-goal:
- Checking the resource availability along a path. Such functional-
ity may be useful for future reservation requests, but it would
require modifications to existing admission control modules that is
beyond the scope of RSVP.
2. Overview
The diagnostic facility introduces two new RSVP message types: Diagnos-
tic Request (DREQ) and Diagnostic Reply (DREP). A DREQ message can be
originated by a client in a "requester" host, which may or may not be a
participant of the RSVP session to be diagnosed. A client in the
requester host invokes the RSVP diagnostic facility by generating a DREQ
packet and sending it towards the LAST-HOP node, which should be on the
RSVP path to be diagnosed. This DREQ packet specifies the RSVP session
and a sender host for that session. Starting from the LAST-HOP, the DREQ
packet collects information hop-by-hop as it is forwarded towards the
sender (see Figure 1), until it reaches the ending node. Specifically,
each RSVP-capable hop adds to the DREQ message a response
(DIAG_RESPONSE) object containing local RSVP state for the specified
RSVP session.
When the DREQ packet reaches the ending node, the message type is
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changed to Diagnostic Reply (DREP) and the completed response is sent to
the original requester node. Partial responses may also be returned
before the DREQ packet reaches the ending node if an error condition
along the path, such as "no path state", prevents further forwarding of
the DREQ packet. To avoid packet implosion or explosion, all diagnostic
packets are forwarded via unicast only.
Thus, there are generally three nodes (hosts and/or routers) involved in
performing the diagnostic function: the requester node, the starting
node, and the ending node, as shown in Figure 1. It is possible that
the client invoking the diagnosis function may reside directly on the
starting node, in which case that the first two nodes are the same. The
starting node is named "LAST-HOP", meaning the last-hop of the path seg-
ment to be diagnosed. The LAST-HOP node can be either a receiver node
or an intermediate node along the path. The ending node is usually the
specified sender host. However, the client can limit the length of the
path segment to be diagnosed by specifying a hop-count limit in the DREQ
message.
LAST-HOP Ending
Receiver node node Sender
__ __ __ __ __
| |---------| |------>| |--> ...-->| |--> ...---->| |
|__| |__| DREQ |__| DREQ |__| DREQ |__|
^ . |
| . |
| DREQ . DREP | DREP
| . |
_|_ DREP V V
Requester | | <------------------------------------
(client) |___|
Figure 1
DREP packets can be unicast from the ending node back to the requester
either directly or hop-by-hop along the reverse of the path taken by the
DREQ message to the LAST-HOP, and thence to the requester. The direct
return is faster and more efficient, but the hop-by-hop reverse-path
route may be the only choice if the packets have to cross firewalls.
Hop-by-hop return is accomplished using an optional ROUTE object, which
is built incrementally to contain a list of node addresses that the DREQ
packet has passed through. The ROUTE object is then used in reverse as
a source route to forward the DREP hop-by-hop back to the LAST-HOP node.
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A DREQ message always consists of a single unfragmented IP datagram. On
the other hand, one DREQ message can generate multiple DREP packets,
each containing a fragment of the total DREQ message. When the path
consists of many hops, the total length of a DREP message will exceed
the MTU size before reaching the sender; thus, the message has to be
fragmented. Relying on IP fragmentation and reassembly, however, can be
problematic, especially when DREP messages are returned to the requester
hop-by-hop, in which case fragmentation/reassembly would have to be per-
formed at every hop. To avoid such excessive overhead, we let the
requester define a default path MTU size that is carried in every DREQ
packet. If an intermediate node finds that the default MTU size is big-
ger than the MTU of the incoming interface, it reduces the default MTU
size to the MTU size of the incoming interface. If an intermediate node
detects that a DREQ packet size is larger than the default MTU size, it
returns to the requester (in either manner described above) a DREP frag-
ment containing accumulated responses. It then removes these responses
from the DREQ and continues to forward it. The requester node can
reassemble the resulting DREP fragments into a complete DREP message.
When discussing diagnostic packet handling, this document uses direction
terminology that is consistent with the RSVP functional specification
[RSVP], relative to the direction of data packet flow. Thus, a DREQ
packet enters a node through an "outgoing interface" and is forwarded
towards the sender through an "incoming interface", because DREQ packets
travel in the reverse direction to the data flow.
Notice that DREQ packets can be forwarded only after the RSVP path state
has been set up. If no path state exists, one may resort to the tracer-
oute or mtrace facility to examine whether the unicast/multicast routing
is working correctly.
3. Diagnostic Packet Format
Like other RSVP messages, DREQ and DREP messages consist of an RSVP Com-
mon Header followed by a variable set of typed RSVP data objects. The
following sequence must be used:
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+-----------------------------------+
| RSVP Common Header |
+-----------------------------------+
| Session object |
+-----------------------------------+
| Next-Hop RSVP_HOP object |
+-----------------------------------+
| DIAGNOSTIC object |
+-----------------------------------+
| (optional) DIAG_SELECT object |
+-----------------------------------+
| (optional) ROUTE object |
+-----------------------------------+
| zero or more DIAG_RESPONSE objects|
+-----------------------------------+
The session object identifies the RSVP session for which the state
information is being collected. We describe each of the other parts.
3.1. RSVP Message Common Header
The RSVP message common header is defined in [RSVP]. The following spe-
cific exceptions and extensions are needed for DREP and DREQ.
Type field: define:
Type = 8: DREQ Diagnostic Request
Type = 9: DREP Diagnostic Reply
RSVP length:
If this is a DREP message and the MF flag in the DIAGNOSTIC object
(see below) is set, this field indicates the length of this single
DREP fragment rather than the total length of the complete DREP reply
message (which cannot generally be known in advance).
3.2. Next-Hop RSVP_HOP Object
This RSVP_HOP object carries the LIH of the interface through which the
DREQ should be received at the upstream node. This object is updated
hop-by hop. It is used for the same reasons that a RESV message contains
an RSVP_HOP object: to distinguish logical interfaces and avoid problems
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caused by routing asymmetries and non-RSVP clouds.
While the IP address is not really used during DREQ processing we
decided, for consistency with the use of RSVP_HOP object in other RSVP
messages, the IP address in the RSVP_HOP object to contain the address
of the interface through which a DREQ was sent.
3.3. DIAGNOSTIC Object
A DIAGNOSTIC object contains the common diagnostic control information
in both DREQ and DREP messages.
o IPv4 DIAGNOSTIC object: Class = 30, C-Type = 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Max-RSVP-hops | RSVP-hop-count| Reserved |MF|
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Request ID |
+---------------+---------------+---------------+---------------+
| Path MTU | Fragment Offset |
+---------------+---------------+---------------+---------------+
| LAST-HOP Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| SENDER_TEMPLATE object |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| Requester FILTER_SPEC object |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Here all IP addresses use the 4 byte IPv4 format, both explicitly in the
LAST-HOP Address and by using the IPv4 forms of the embedded FILTER_SPEC
and RSVP_HOP objects.
o IPv6 DIAGNOSTIC object: Class = 30, C-Type = 2
The format is the same, except all explicit and embedded IP addresses
are 16 byte IPv6 addresses.
The fields are as follows:
Max-RSVP-hops
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An octet specifying the maximum number of RSVP hops over which infor-
mation will be collected. If an error condition in the middle of the
path prevents the DREQ packet from reaching the specified ending
node, the Max-RSVP-hops field may be used to perform an expanding-
length search to reach the point just before the problem. If this
value is 1, the starting node and the ending node of the query will
be the same. If it is zero, there is no hop limit.
RSVP-hop-count
Records the number of RSVP hops that have been traversed so far. If
the starting and ending nodes are the same, this value will be 1 in
the resulting DREP message.
Fragment Offset
Indicates where this DREP fragment belongs in the complete DREP mes-
sage, measured in octets. The first fragment has offset zero. Frag-
ment Offset is used to determine if a DREQ message containing zero
DIAG_RESPONSE objects should be processed at an RSVP capable node.
MF flag
Flag means "more fragments". It must be set to zero (0) in all DREQ
messages. It must be set to one (1) in all DREP packets that carry
partial results and are returned by intermediate nodes due to the MTU
limit. When the DREQ message is converted to a DREP message in the
ending node, the MF flag must remain zero.
Request ID
Identifies an individual DREQ message and the corresponding DREP mes-
sage (or all the fragments of the reply message).
One possible way to defining the Request ID would use 16 bits to
specify the ID of the process making the query and 16 bits to distin-
guish different queries from this process.
Path MTU
Specifies a default MTU size in octets for DREP and DREQ messages.
This value should not be smaller than the size of the "base" DREQ
packet. A "base" DREQ packet is one that contains a Common Header, a
Session object , a Next-Hop RSVP_HOP object, a DIAGNOSTIC object, an
empty ROUTE object and a single default DIAG_RESPONSE (see below).
The assumption made here is that a diagnostic packet of this size can
always be forwarded without being fragmented.
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LAST-HOP Address
The IP address of the LAST-HOP node. The DREQ message starts col-
lecting information at this node and proceeds toward the sender.
SENDER_TEMPLATE object
This IPv4/IPv6 SENDER_TEMPLATE object contains the IP address and the
port of a sender for the session being diagnosed. The DREQ packet is
forwarded hop-by-hop towards this address.
Requester FILTER_SPEC Object
This IPv4/IPv6 FILTER_SPEC object contains the IP address and the
port from which the request originated and to which the DREP mes-
sage(s) should be sent.
3.4. DIAG_SELECT Object
o DIAG_SELECT Class = 33, C-Type = 0.
A Diagnostic message may optionally contain a DIAG_SELECT object to
specify which specific RSVP objects should be reported in a
DIAG_RESPONSE object. In the absence of a DIAG_SELECT object, the
DIAG_RESPONSE object added by the node will contain a default set of
object types (see DIAG_RESPONSE object below).
The DIAG_SELECT object contains a list of [Class, C-type] pairs, in the
following format:
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| class | C-Type | class | C-Type |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
// //
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| class | C-Type | class | C-Type |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
When a DIAG_SELECT object is included in a DREQ message, each RSVP node
along the path will add a DIAG_RESPONSE object containing response
objects (see below) whose classes and C-Types match entries in the
DIAG_SELECT list (and are from matching path and reservation state). A
C-type octet of zero is a 'wildcard', matching any C-Type associated
with the associated class.
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Depending on the type of objects requested, a node can find the associ-
ated information in the path or reservation state stored for the session
described in the SESSION object. Specifically, information for the
RSVP_HOP,SENDER_TEMPLATE, SENDER_TSPEC, ADSPEC and FILTER_SPEC objects
can be extracted from the node's path state, while information for the
FLOWSPEC, CONFIRM, STYLE and SCOPE objects can be found in the node's
reservation state (if existent).
If the number of [Class, C-Type] pairs is odd, the last two octets of
the DIAG_SELECT object must be zero. A maximum DIAG_SELECT object is
one that contains the [Class, C-type] pairs for all the RSVP objects
that can be requested in a Diagnostic query.
3.5. ROUTE Object
A diagnostic message may contain a ROUTE object, which is used to record
the route of the DREQ message and as a source route for returning the
DREP message(s) hop-by-hop.
o IPv4 ROUTE object: Class = 31, C-Type = 1.
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| reserved | R-pointer |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ RSVP Node List |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
This message signifies how the reply should be returned. If it does not
exist in the DREQ packet then DREP packets should be sent to the
response address directly. If it does exist, DREP packets must be
returned hop-by-hop along the reverse path to the LAST-HOP node and
thence to the requester node.
An empty ROUTE object is one that has an empty RSVP Node list and R-
pointer is equal to zero.
RSVP Node List
A list of RSVP node IPv4 addresses. The number of addresses in this
list can be computed from the object size.
R-pointer
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Used in DREP messages only (see Section 4.2 for details), but it is
incremented as each hop adds its incoming interface address in the
ROUTE object.
o IPv6 ROUTE object: Class = 31, C-Type = 2
The same, except RSVP Node List contains IPv6 addresses.
In a DREQ message, RSVP Node List specifies all RSVP hops between the
LAST-HOP address specified in the DIAGNOSTIC object, and the last RSVP
node the DREQ message has visited. In a DREP message, RSVP Node List
specifies all RSVP hops between the LAST-HOP and the node that returns
this DREP message.
3.6. DIAG_RESPONSE Object
Each RSVP node attaches DIAG_RESPONSE object to each DREQ message it
receives, before forwarding the message. The DIAG_RESPONSE object con-
tains the state to be reported for this node. It has a fixed-format
header and then a variable list of RSVP state objects, or "response
objects".
o IPv4 DIAG_RESPONSE object: Class = 32, C-Type = 1.
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| DREQ Arrival Time |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Incoming Interface Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Outgoing Interface Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Previous-RSVP-Hop Router Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| D-TTL |M|R-err| K | Timer value |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
| (optional) TUNNEL object |
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
// Response objects //
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
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o IPv6 DIAG_RESPONSE object: Class = 32, C-Type = 2.
This object has the same format, except that all explicit and embedded
IP addresses are IPv6 addresses.
The fields are as follows:
DREQ Arrival Time
A 32-bit NTP timestamp specifying the time the DREQ message arrived
at this node. The 32-bit form of an NTP timestamp consists of the
middle 32 bits of the full 64-bit form, that is, the low 16 bits of
the integer part and the high 16 bits of the fractional part.
Incoming Interface Address
Specifies the IP address of the interface on which messages from the
sender are expected to arrive, or 0 if unknown.
Outgoing Interface Address
Specifies the IP address of the interface through which the DREQ mes-
sage arrived and to which messages from the given sender and for the
specified session address flow, or 0 if unknown.
Previous-RSVP-Hop Router Address
Specifies the IP address from which this node receives RSVP PATH mes-
sages for this source, or 0 if unknown. This is also the interface
to which the DREQ will be forwarded.
D-TTL
The number of IP hops this DREQ message traveled from the down-stream
RSVP node to the current node.
M flag
A single-bit flag which indicates whether the reservation described
by the response objects, is merged with reservations from other down-
stream interfaces when being forwarded upstream.
R-error
A 3-bit field that indicates error conditions at a node. Currently
defined values are:
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0x00: no error
0x01: No PATH state
0x02: packet too big
0x04: ROUTE object too big
K
The refresh timer multiple (defined in [RSVP]).
Timer value
The local refresh timer value in seconds.
The set of response objects to be included at the end of the
DIAG_RESPONSE object is determined by a DIAG_SELECT object, if one is
present. If no DIAG_SELECT object is present, the response objects
belong to the default list of classes:
SENDER_TSPEC object FILTER_SPEC object FLOWSPEC object
STYLE object
Any C-Type present in the local RSVP state will be used. These response
objects may be in any order but they must all be at the end of the
DIAG_RESPONSE object.
A default DIAG_RESPONSE object is one containing the default list of
classes described above.
3.7. TUNNEL Object
The optional TUNNEL object should be inserted when a DREQ message
arrives at an RSVP node that acts as a tunnel exit point.
The TUNNEL object provides mapping between the end-to-end RSVP session
that is being diagnosed and the RSVP session over the tunnel. This map-
ping information allows the diagnosis client to conduct diagnosis over
the involved tunnel session, by invoking a separate Diagnostic query for
the corresponding Tunnel Session and Tunnel Sender. Keep in mind, how-
ever, that multiple end-to-end sessions may all map to one pre-config-
ured tunnel session that may have totally different parameter settings.
The tunnel object is defined in the RSVP Tunnel Specification [RSVPTUN].
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4. Diagnostic Packet Forwarding Rules
4.1. DREQ Packet Forwarding
DREQ messages are forwarded hop-by-hop via unicast from the LAST-HOP
address to the Sender address, as specified in the DIAGNOSTIC object.
If an RSVP capable node, other than the LAST-HOP node, receives a DREQ
message that contains no DIAG_RESPONSE objects and has a zero Fragment
Offset, the node should forward the DREQ packet towards the LAST-HOP
without doing any of the processing mentioned below. The reason is that
such conditions apply only for nodes downstream of the LAST-HOP where no
information should be collected.
Processing begins when a DREQ message, DREQ_in, arrives at a node. The
following processing is performed before DREQ_in is forwarded:
1. Create a new DIAG_RESPONSE object. Compute the IP hop count from
the previous RSVP hop. This is done by subtracting the value of the
TTL value in the IP header from Send_TTL in the RSVP common header.
Save the result in the D-TTL field of the DIAG_RESPONSE object.
2. Set the DREQ Arrival Time and the Outgoing Interface Address in the
DIAG_RESPONSE object. If this node is the LAST-HOP, then the Out-
going Interface Address field in the DIAG_RESPONSE object contains
the following value depending on the session being diagnosed.
* If the session in question is a unicast session, then the Out-
going Interface Address field contains the address of the
interface LAST-HOP uses to send PATH messages and data to the
receiver specified by the session address.
* Otherwise, if it is a multicast session and there is at least
one receiver for this session, LAST_HOP should use the address
of one of local interfaces used to reach one of the receivers.
* Otherwise Outgoing Interface Address should be zero.
If no PATH state exists for the specified session, set R-error =
0x01 (No PATH state).
3. Increment the RSVP-hop-count field in the DIAGNOSTIC message object
by one.
4. If the "No PATH state" bit is set, goto Send_DREP.
5. Set the rest of the fields in the DIAG_RESPONSE object. If DREQ_in
contains a DIAG_SELECT object, the response object classes are
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those specified in the DIAG_SELECT; otherwise, they are
SENDER_TSPEC, FILTER_SPEC, STYLE, and FLOWSPEC objects. If no
reservation state exists for the specified RSVP session, the
DIAG_RESPONSE object will contain no FILTER_SPEC or FLOWSPEC or
STYLE object. If neither PATH nor reservation state exists for the
specified RSVP session, then no response objects will be appended
to the DIAG_RESPONSE object.
6. If RSVP-hop-count is equal to Max-RSVP-hops or this node is the
sender, go to Send_DREP.
7. If the Path MTU value is larger than the MTU size of the incoming
interface for the sender being diagnosed, change the Path MTU value
to the MTU value of the incoming interface.
8. If the size of DREQ_in plus the size of the new DIAG_RESPONSE
object plus the size of an IP address ,if a ROUTE object exists, is
larger than Path MTU set the "packet too big" (0x02) error bit in
DIAG_RESPONSE, goto Send_DREP.
9. If a ROUTE object exists, append the "Incoming Interface Address"
to the end of the ROUTE object, increment R-Pointer by one, update
the Next-Hop RSVP_HOP object, append the new DIAG_RESPONSE object
to the list of DIAG_RESPONSE object and update the message length
field in the RSVP common header accordingly. Finally, forward
DREQ_in to the next hop towards the sender, after recomputing the
checksum. Return.
Send_DREP:
1. If the size of DREQ_in plus the size of the new DIAG_RESPONSE
object plus the size of an IP address ,if a ROUTE object exists, is
larger than Path MTU set the "packet too big" (0x02) error bit in
DIAG_RESPONSE, otherwise goto step 11.
2. Make a copy of DREQ_in and change the type field in RSVP common
header from DREQ to DREP. Trim all DIAG_RESPONSE objects from
DREQ_in and adjust the Fragment Offset.
3. If a ROUTE object is present in the DREP message, decrement the R-
pointer and set target address to the last address in the ROUTE
object, otherwise set target address to the requester address. Set
the MF bit, recompute the checksum and send the DREP message back
to the target address.
4. If the size of DREQ_in plus the size of DIAG_RESPONSE plus the size
of an IP address ,if a ROUTE object exists, is smaller than Path
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MTU goto Step 9.
5. Make a copy of DREQ_in and change the type field in RSVP common
header from DREQ to DREP. If a ROUTE object exists, replace the
ROUTE object in DREQ_in with an empty ROUTE object. Turn on the
"ROUTE object too big" (0x04) error bit in the DIAG_RESPONSE.
6. If the "No PATH state" (0x01) error bit is set or if RSVP-hop-count
is equal to Max-RSVP-hops or if this node is the sender, goto Step
8.
7. If a ROUTE object exists, append the "Incoming Interface Address"
to the end of the ROUTE object, increment R-Pointer by one, update
the Next-Hop RSVP_HOP object, append the new DIAG_RESPONSE object
to the list of DIAG_RESPONSE object, update the message length
field in the RSVP common header accordingly and adjust the Fragment
Offset. Finally, forward DREQ_in to the next hop towards the
sender, after recomputing the checksum.
8. Append the DIAG_RESPONSE object to the end of DREP. Set target
address to the requester address. Turn on the MF bit. Update the
packet length, recompute the checksum in the DREP message and send
it towards the target address. Return
9. If the "No PATH state" (0x01) error bit is set or if RSVP-hop-count
is equal to Max-RSVP-hops or if this node is the sender, goto Step
11.
10. If a ROUTE object exists, append the "Incoming Interface Address"
to the end of the ROUTE object, increment R-Pointer by one, update
the Next-Hop RSVP_HOP object, append the new DIAG_RESPONSE object
to the list of DIAG_RESPONSE object and update the message length
field in the RSVP common header accordingly. Finally, forward
DREQ_in to the next hop towards the sender, after recomputing the
checksum. Return.
11. Append the DIAG_RESPONSE object to the end of DREQ_in. If a ROUTE
object is present in the message, decrement the R-pointer and set
target address to the last address in the ROUTE object, otherwise
set target address to the requester address. Change the Type Field
in the Common header from DREQ to DREP.Update the packet length,
recompute the checksum in the DREP message and send it towards the
target address. The MF bit in this case must be off.
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4.2. DREP Forwarding
When a ROUTE object is present, DREP messages are forwarded hop-by-hop
towards the requester, by reversing the route as listed in the ROUTE
object. Otherwise, DREP messages are sent directly to the original
requester.
When a node receives a DREP message, it simply decreases R-pointer by
one (address length), recomputes the checksum and forwards the message
to the address pointed by R-pointer in the route list. If a node, other
than the LAST-HOP, receives a DREP packet where R-pointer is equal to
zero, it must send it directly to the requester.
When the LAST-HOP node receives a DREP message, it sends the message to
the requester.
4.3. MTU Selection and Adjustment
Because the DREQ message carries the allowed MTU size of previous hops
that the DREP messages will later traverse, this unique feature allows
the easy semantic fragmentation as described above. Whenever the DREQ
message approaches the size of Path MTU, it can be trimmed before being
forwarded again.
When a requester sends a DREQ message, the Path MTU field in the DIAG-
NOSTIC object can be set to a configured default value. It is possible
that the original Path MTU value is chosen larger than the actual MTU
value along some portion of the path being traced. Therefore each
intermediate RSVP node must check the MTU value when processing a DREQ
message. If the specified MTU value is larger than the MTU of the
incoming interface (that the DREQ message will be forwarded to), the
node changes the MTU value in the header to the smaller value.
Whenever a DREQ message size becomes larger than the Path MTU value, an
intermediate RSVP node makes a copy of the message, converts it to a
DREP message to send back, and then trims off the partial results from
the DREQ message. If in this case also the DREQ cannot be forwarded
upstream due to a large ROUTE object, the "ROUTE object too big" is set
and the ROUTE object is trimmed. As a result of the ROUTE object trim-
ming, DREP(s) will come hop-by-hop up to this node and will then immedi-
ately forwarded to the requester address.
Even if the steps shown above are followed there are a few cases where
fragmentation at the IP layer will happen. For example, non-RSVP hops
with smaller MTUs may exist before LAST-HOP is reached, or if the
response is sent directly back to requester (as opposed to hop by hop)
the DREP may take a different route to the requester than the DREQ took
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from the requester. Another case is when there exists a link with MTU
smaller than the minimum Path MTU value defined in Section 3.2.
4.4. Errors
If an error condition prevents a DREP message from being forwarded fur-
ther, the message is simply dropped.
If an error condition, such as lack of PATH state, prevents a DREQ mes-
sage from being forwarded further, the node must change the current mes-
sage to DREP type and return it to the response address.
5. Problem Diagnosis by Using RSVP Diagnostic Facility
5.1. Across Firewalls
Firewalls may cause problems in diagnostic message forwarding. Let us
look at two different cases.
First, let us assume that the querier resides on a receiving host of the
session to be examined. In this case, firewalls should not prevent the
forwarding of the diagnostic messages in a hop-by-hop manner, assuming
that proper holes have been punched on the firewall to allow hop-by-hop
forwarding of other RSVP messages. The querier may start by not includ-
ing a ROUTE object, which can give a faster response delivery and
reduced overhead at intermediate nodes. However if no response is
received, the querier may resend the DREQ message with a ROUTE object,
specifying that a hop-by-hop reply should be sent.
If the requester is a third party host and is separated from the LAST-
HOP address by a firewall (either the requester is behind a firewall, or
the LAST-HOP is a node behind a firewall, or both), at this time we do
not know any other solution but to change the LAST-HOP to a node that is
on the same side of the firewall as the requester.
5.2. Examination of RSVP Timers
One can easily collect information about the current timer value at each
RSVP hop along the way. This will be very helpful in situations when
the reservation state goes up and down frequently, to find out whether
the state changes are due to improper setting of timer values, or K val-
ues (when across lossy links), or frequent routing changes.
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5.3. Discovering Non-RSVP Clouds
The D-TTL field in each DIAG_RESPONSE object shows the number of routing
hops between adjacent RSVP nodes. Therefore any value greater than one
indicates a non-RSVP clouds in between. Together with the arrival
timestamps (assuming NTP works), this value can also give some vague,
though not necessarily accurate, indication of how big that cloud might
be. One might also find out all the intermediate non-RSVP nodes by run-
ning either unicast or multicast trace route.
5.4. Discovering Reservation Merges
The flowspec value in a DIAG_RESPONSE object specifies the amount of
resources being reserved for the data stream defined by the filter spec
in the same data block. When this value of adjacent DIAG_RESPONSE
objects differs, that is, a downstream node Rd has a smaller value than
its immediate upstream node Ru, it indicates a merge of reservation with
RSVP request(s) from other down stream interface(s) at Rd. Further, in
case of SE style reservation, one can examine how the different SE
scopes get merged at each hop.
In particular, if a receiver sends a DREQ message before sending its own
reservation, it can discover (1) how many RSVP hops there are along the
path between the specified sender and itself, (2) how many of the hops
already have some reservation by other receivers, and (3) possibly a
rough prediction of how its reservation request might get merged with
other existing ones.
5.5. Error Diagnosis
In addition to examining the state of a working reservation, RSVP diag-
nostic messages are more likely to be invoked when things are not work-
ing correctly. For example, a receiver has reserved an adequate pipe
for a specified incoming data stream, yet the observed delay or loss
ratio is much higher than expected. In this case the receiver can use
the diagnostic facility to examine the reservation state at each RSVP
hop along the way to find out whether the RSVP state is set up cor-
rectly, whether there is any blackhole along the way that caused RSVP
message losses, or whether there are non-RSVP clouds, and where they
are, that may have caused the performance problem.
5.6. Crossing "Legacy" RSVP Routers
Since this diagnosis facility was developed and added to RSVP after a
number of RSVP implementations were in place, it is possible, or even
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likely, that when performing RSVP diagnosis, one may encounter one or
more RSVP-capable nodes that do not understand diagnostic messages and
drop them. When this happens, the invoking client will get no response
from its requests.
One way to by-pass such "legacy" RSVP nodes is to perform RSVP diagnosis
repeatedly, guided by information from traceroute, or mtrace in case of
multicast. When an RSVP diagnostic query times out (see next section),
one may first use traceroute to get the list of nodes along the path,
and then gradually increase the value of Max-RSVP-hops field in the DREQ
message, starting from a low value until one no longer receives a
response. One can then try RSVP diagnosis again by starting with the
first node (which is further upstream towards the sender) after the
unresponding one.
There are two problem with the method mentioned above in the case of
unicast sessions. Both problems are related to the fact that traceroute
information provides the path from the requester to the sender. The
first problem is that the LAST-HOP may not on the path from the
requester to the sender. In this case we can get information only from
the portion of the path from the LAST-HOP to the sender which intersects
with the path from the requester to the sender. If routers that are not
on the intersection of the two paths don't have PATH state for the ses-
sion being diagnosed then they will reply with R-error=0x01. The
requester can overcome this problem by sending a DREQ to every router on
the path (from itself to the sender) until it reaches the first router
that belongs to the path from the sender to the LAST-HOP.
The second problem is that traceroute provides the path from the
requester to the sender which, due to routing asymmetries, may be dif-
ferent than the path traffic from the sender to the LAST-HOP uses. There
is (at least) one case where this asymmetry will cause the diagnosis to
fail. We present this case below.
draft-ietf-rsvp-diagnostic-msgs-06.txt [Page 20]
INTERNET-DRAFT August 1999
Downstream Path Sender
__ __ __ __
Receiver +------| |<------| |<-- ...---| |-----| |
__ __ / |__| |__| |__| |__|
| |--....--|X |_/ ^
|__| |__| \ Router B |
Black \ __ |
Hole +----->| |---->---+
|__| Upstream Path
Router A
Figure 2
Here the first hop upstream of the black hole is different on the
upstream path and the downstream path. Traceroute will indicate router A
as the previous hop (instead of router B which is the right one). Send-
ing a DREQ to router A will result in A responding with R-error 0x01 (No
PATH State). If the two paths converge again then the requester can use
the solution proposed above to get any (partial) information from the
rest of the path.
We don't have, for the moment, any complete solutions for the problem-
atic scenarios described here.
6. Comments on Diagnostic Client Implementation.
Following the design principle that nodes in the network should not hold
more than necessary state, RSVP nodes are responsible only for forward-
ing Diagnostic messages and filling DIAG_RESPONSE objects. Additional
diagnostic functionality should be carried out by the diagnostic
clients. Furthermore, if the diagnostic function is invoked from a
third-party host, we should not require that host be running RSVP daemon
to perform the function. Below we sketch out the basic functions that a
diagnostic client daemon should carry out.
1. Take input from the user about the session to be diagnosed, the
last-hop and the sender address, the Max-RSVP-hops, and possibly
the DIAG_SELECT list, create a DREQ message and send to the LAST-
HOP RSVP node using raw IP message with protocol number 46 (RSVP).
If the user specified that the response should be sent hop-by-hop
include an empty ROUTE object to the DREQ message sent. Set the
Path_MTU to the smaller of the user request and the MTU of the link
through which the DREQ will be sent.
The port of the UDP socket on which the Diagnostic Client is
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INTERNET-DRAFT August 1999
listening for replies should be included in the Requester FIL-
TER_SPEC object.
2. Set a retransmission timer, waiting for the reply (one or more DREP
messages). Listen to the specified UDP port for responses from the
LAST-HOP RSVP node.
The LAST-HOP RSVP node, upon receiving DREP messages, sends them to
the the Diagnostic Client as UDP packets, using the port supplied
in the Requester FILTER_SPEC object.
3. Upon receiving a DREP message to an outstanding diagnostic request,
the client should clear the retransmission timer, check to see if
the reply contains the complete result of the requested diagnosis.
If so, it should pass the result up to the invoking entity immedi-
ately.
4. Reassemble DREP fragments. If the first reply to an outstanding
diagnostic request contains only a fragment of the expected result,
the client should set up a reassembly timer in a way similar to IP
packet reassembly timer. If the timer goes off before all frag-
ments arrive, the client should pass the partial result to the
invoking entity.
5. Use retransmission and reassembly timers to gracefully handle
packet losses and reply fragment scenarios.
In the absence of response to the first diagnostic request, a
client should retransmit the request a few times. If all the
retransmissions also fail, the client should invoke traceroute or
mtrace to obtain the list of hops along the path segment to be
diagnosed, and then perform an iteration of diagnosis with increas-
ing hop count as suggested in Section 5.6 in order to cross RSVP-
capable but diagnosis-incapable nodes.
6. If all the above efforts fail, the client must notify the invoking
entity.
7. Security Considerations
RSVP Diagnostics, as any other diagnostic tool, can be a security threat
since it can reveal possibly sensitive RSVP state information to
unwanted third parties.
We feel that the threat is minimal, since as explained in the Introduc-
tion Diagnostics messages produce no side-effects and therefore they
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INTERNET-DRAFT August 1999
cannot change RSVP state in the nodes. In this respect RSVP Diagnostics
is less a security threat than other diagnostic tools and protocols such
as SNMP.
Furthermore, processing of Diagnostic messages can be disabled if it is
felt that is a security threat.
8. Acknowledgments
The idea of developing a diagnostic facility for RSVP was first sug-
gested by Mark Handley of UCL. Many thanks to Lee Breslau of Xerox PARC
and John Krawczyk of Baynetworks for their valuable comments on the
first draft of this memo. Lee Breslau, Bob Braden, and John Krawczyk
contributed further comments after March 1996 IETF. Steven Berson pro-
vided valuable comments on various drafts of the memo. We would also
like to acknowledge Intel for providing a research grant as a partial
support for this work. Subramaniam Vincent did most of this work while a
graduate research assistant at the USC Information Sciences Institute
(ISI).
9. References
[RSVP] Braden, R. Ed. et al, "Resource ReserVation Protocol -- Version 1
Functional Specification", RFC 2205, September 1997.
[RSVPTUN] A. Terzis, J. Krawczyk, J. Wroclawski, L. Zhang. "RSVP Opera-
tion Over IP Tunnels ", Internet Draft. draft-ietf-rsvp-tunnel-02.txt,
February, 1999.
10. Authors' Addresses
Andreas Terzis
UCLA
4677 Boelter Hall
Los Angeles, CA 90095
Phone: 310-267-2190
Email: terzis@cs.ucla.edu
Bob Braden
USC Information Sciences Institute
4676 Admiralty Way
Marina del Rey, CA 90292
draft-ietf-rsvp-diagnostic-msgs-06.txt [Page 23]
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Phone: 310 822-1511
EMail: braden@isi.edu
Subramaniam Vincent
Cisco Systems
275, E Tasman Drive, MS SJC04/2/1
San Jose, CA 95134.
Phone: 408 525 3474
Email: svincent@cisco.com
Lixia Zhang
UCLA
4531G Boelter Hall
Los Angeles, CA 90095
Phone: 310-825-2695
EMail: lixia@cs.ucla.edu
draft-ietf-rsvp-diagnostic-msgs-06.txt [Page 24]
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