Network Working Group D. Wessels
Request for Comments: 2187 K. Claffy
Category: Informational National Laboratory for Applied
Network Research/UCSD
September 1997
Application of Internet Cache Protocol (ICP), version 2
Status of this Memo
This memo provides information for the Internet community. This memo
does not specify an Internet standard of any kind. Distribution of
this memo is unlimited.
Abstract
This document describes the application of ICPv2 (Internet Cache
Protocol version 2, RFC2186) to Web caching. ICPv2 is a lightweight
message format used for communication among Web caches. Several
independent caching implementations now use ICP[3,5], making it
important to codify the existing practical uses of ICP for those
trying to implement, deploy, and extend its use.
ICP queries and replies refer to the existence of URLs (or objects)
in neighbor caches. Caches exchange ICP messages and use the
gathered information to select the most appropriate location from
which to retrieve an object. A companion document (RFC2186)
describes the format and syntax of the protocol itself. In this
document we focus on issues of ICP deployment, efficiency, security,
and interaction with other aspects of Web traffic behavior.
Table of Contents
1. Introduction................................................. 22. Web Cache Hierarchies........................................ 33. What is the Added Value of ICP?.............................. 54. Example Configuration of ICP Hierarchy....................... 54.1. Configuring the `proxy.customer.org' cache................. 64.2. Configuring the `cache.isp.com' cache...................... 65. Applying the Protocol........................................ 75.1. Sending ICP Queries........................................ 85.2. Receiving ICP Queries and Sending Replies.................. 105.3. Receiving ICP Replies...................................... 115.4. ICP Options................................................ 136. Firewalls.................................................... 147. Multicast.................................................... 148. Lessons Learned.............................................. 168.1. Differences Between ICP and HTTP........................... 16
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8.2. Parents, Siblings, Hits and Misses......................... 168.3. Different Roles of ICP..................................... 178.4. Protocol Design Flaws of ICPv2............................. 179. Security Considerations...................................... 189.1. Inserting Bogus ICP Queries................................ 199.2. Inserting Bogus ICP Replies................................ 199.3. Eavesdropping.............................................. 209.4. Blocking ICP Messages...................................... 209.5. Delaying ICP Messages...................................... 209.6. Denial of Service.......................................... 209.7. Altering ICP Fields........................................ 219.8. Summary.................................................... 2210. References................................................... 2311. Acknowledgments.............................................. 2412. Authors' Addresses........................................... 24
ICP is a lightweight message format used for communicating among Web
caches. ICP is used to exchange hints about the existence of URLs in
neighbor caches. Caches exchange ICP queries and replies to gather
information for use in selecting the most appropriate location from
which to retrieve an object.
This document describes the implementation of ICP in software. For a
description of the protocol and message format, please refer to the
companion document (RFC2186). We avoid making judgments about
whether or how ICP should be used in particular Web caching
configurations. ICP may be a "net win" in some situations, and a
"net loss" in others. We recognize that certain practices described
in this document are suboptimal. Some of these exist for historical
reasons. Some aspects have been improved in later versions. Since
this document only serves to describe current practices, we focus on
documenting rather than evaluating. However, we do address known
security problems and other shortcomings.
The remainder of this document is written as follows. We first
describe Web cache hierarchies, explain motivation for using ICP, and
demonstrate how to configure its use in cache hierarchies. We then
provide a step-by-step description of an ICP query-response
transaction. We then discuss ICP interaction with firewalls, and
briefly touch on multicasting ICP. We end with lessons with have
learned during the protocol development and deployement thus far, and
the canonical security considerations.
ICP was initially developed by Peter Danzig, et. al. at the
University of Southern California as a central part of hierarchical
caching in the Harvest research project[3].
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A single Web cache will reduce the amount of traffic generated by the
clients behind it. Similarly, a group of Web caches can benefit by
sharing another cache in much the same way. Researchers on the
Harvest project envisioned that it would be important to connect Web
caches hierarchically. In a cache hierarchy (or mesh) one cache
establishes peering relationships with its neighbor caches. There
are two types of relationship: parent and sibling. A parent cache is
essentially one level up in a cache hierarchy. A sibling cache is on
the same level. The terms "neighbor" and "peer" are used to refer to
either parents or siblings which are a single "cache-hop" away.
Figure 1 shows a simple hierarchy configuration.
But what does it mean to be "on the same level" or "one level up?"
The general flow of document requests is up the hierarchy. When a
cache does not hold a requested object, it may ask via ICP whether
any of its neighbor caches has the object. If any of the neighbors
does have the requested object (i.e., a "neighbor hit"), then the
cache will request it from them. If none of the neighbors has the
object (a "neighbor miss"), then the cache must forward the request
either to a parent, or directly to the origin server. The essential
difference between a parent and sibling is that a "neighbor hit" may
be fetched from either one, but a "neighbor miss" may NOT be fetched
from a sibling. In other words, in a sibling relationship, a cache
can only ask to retrieve objects that the sibling already has cached,
whereas the same cache can ask a parent to retrieve any object
regardless of whether or not it is cached. A parent cache's role is
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T H E I N T E R N E T
===========================
| ||
| ||
| ||
| ||
| +----------------------+
| | |
| | PARENT |
| | CACHE |
| | |
| +----------------------+
| ||
DIRECT ||
RETRIEVALS ||
| ||
| HITS
| AND
| MISSES
| RESOLVED
| ||
| ||
| ||
V \/
+------------------+ +------------------+
| | | |
| LOCAL |/--------HITS-------| SIBLING |
| CACHE |\------RESOLVED-----| CACHE |
| | | |
+------------------+ +------------------+
| | | | |
| | | | |
| | | | |
V V V V V
===================
CACHE CLIENTS
FIGURE 1: A Simple Web cache hierarchy. The local cache can retrieve
hits from sibling caches, hits and misses from parent caches, and
some requests directly from origin servers.
to provide "transit" for the request if necessary, and accordingly
parent caches are ideally located within or on the way to a transit
Internet service provider (ISP).
Squid and Harvest allow for complex hierarchical configurations. For
example, one could specify that a given neighbor be used for only a
certain class of requests, such as URLs from a specific DNS domain.
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Additionally, it is possible to treat a neighbor as a sibling for
some requests and as a parent for others.
The cache hierarchy model described here includes a number of
features to prevent top-level caches from becoming choke points. One
is the ability to restrict parents as just described previously (by
domains). Another optimization is that the cache only forwards
cachable requests to its neighbors. A large class of Web requests
are inherently uncachable, including: requests requiring certain
types of authentication, session-encrypted data, highly personalized
responses, and certain types of database queries. Lower level caches
should handle these requests directly rather than burdening parent
caches.
Although it is possible to maintain cache hierarchies without using
ICP, the lack of ICP or something similar prohibits the existence of
sibling meta-communicative relationships, i.e., mechanisms to query
nearby caches about a given document.
One concern over the use of ICP is the additional delay that an ICP
query/reply exchange contributes to an HTTP transaction. However, if
the ICP query can locate the object in a nearby neighbor cache, then
the ICP delay may be more than offset by the faster delivery of the
data from the neighbor. In order to minimize ICP delays, the caches
(as well as the protocol itself) are designed to return ICP requests
quickly. Indeed, the application does minimal processing of the ICP
request, most ICP-related delay is due to transmission on the
network.
ICP also serves to provide an indication of neighbor reachability.
If ICP replies from a neighbor fail to arrive, then either the
network path is congested (or down), or the cache application is not
running on the ICP-queried neighbor machine. In either case, the
cache should not use this neighbor at this time. Additionally,
because an idle cache can turn around the replies faster than a busy
one, all other things being equal, ICP provides some form of load
balancing.
Configuring caches within a hierarchy requires establishing peering
relationships, which currently involves manual configuration at both
peering endpoints. One cache must indicate that the other is a
parent or sibling. The other cache will most likely have to add the
first cache to its access control lists.
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Below we show some sample configuration lines for a hypothetical
situation. We have two caches, one operated by an ISP, and another
operated by a customer. First we describe how the customer would
configure his cache to peer with the ISP. Second, we describe how
the ISP would allow the customer access to its cache.
In Squid, to configure parents and siblings in a hierarchy, a
`cache_host' directive is entered into the configuration file. The
format is:
cache_host hostname type http-port icp-port [options]
Where type is either `parent', `sibling', or `multicast'. For our
example, it would be:
cache_host cache.isp.com parent 8080 3130
This configuration will cause the customer cache to resolve most
cache misses through the parent (`cgi-bin' and non-GET requests would
be resolved directly). Utilizing the parent may be undesirable for
certain servers, such as servers also in the customer.org domain. To
always handle such local domains directly, the customer would add
this to his configuration file:
local_domain customer.org
It may also be the case that the customer wants to use the ISP cache
only for a specific subset of DNS domains. The need to limit
requests this way is actually more common for higher levels of cache
hierarchies, but it is illustrated here nonetheless. To limit the
ISP cache to a subset of DNS domains, the customer would use:
cache_host_domain cache.isp.com com net org
Then, any requests which are NOT in the .com, .net, or .org domains
would be handled directly.
To configure the query-receiving side of the cache peer
relationship one uses access lists, similar to those used in routing
peers. The access lists support a large degree of customization in
the peering relationship. If there are no access lines present, the
cache allows the request by default.
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Note that the cache.isp.com cache need not explicitly specify the
customer cache as a peer, nor is the type of relationship encoded
within the ICP query itself. The access control entries regulate the
relationships between this cache and its neighbors. For our example,
the ISP would use:
acl src Customer proxy.customer.org
http_access allow Customer
icp_access allow Customer
This defines an access control entry named `Customer' which specifies
a source IP address of the customer cache machine. The customer
cache would then be allowed to make any request to both the HTTP and
ICP ports (including cache misses). This configuration implies that
the ISP cache is a parent of the customer.
If the ISP wanted to enforce a sibling relationship, it would need to
deny access to cache misses. This would be done as follows:
miss_access deny Customer
Of course the ISP should also communicate this to the customer, so
that the customer will change his configuration from parent to
sibling. Otherwise, if the customer requests an object not in the
ISP cache, an error message is generated.
The following sections describe the ICP implementation in the
Harvest[3] (research version) and Squid Web cache[5] packages. In
terms of version numbers, this means version 1.4pl2 for Harvest and
version 1.1.10 for Squid.
The basic sequence of events in an ICP transaction is as follows:
1. Local cache receives an HTTP[1] request from a cache client.
2. The local cache sends ICP queries (section 5.1).
3. The peer cache(s) receive the queries and send ICP replies
(section 5.2).
4. The local cache receives the ICP replies and decides where to
forward the request (section 5.3).
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Not every HTTP request requires an ICP query to be sent. Obviously,
cache hits will not need ICP because the request is satisfied
immediately. For origin servers very close to the cache, we do not
want to use any neighbor caches. In Squid and Harvest, the
administrator specifies what constitutes a `local' server with the
`local_domain' and `local_ip' configuration options. The cache
always contacts a local server directly, never querying a peer cache.
There are other classes of requests that the cache (or the
administrator) may prefer to forward directly to the origin server.
In Squid and Harvest, one such class includes all non-GET request
methods. A Squid cache can also be configured to not use peers for
URLs matching the `hierarchy_stoplist'.
In order for an HTTP request to yield an ICP transaction, it must:
o not be a cache hit
o not be to a local server
o be a GET request, and
o not match the `hierarchy_stoplist' configuration.
We call this a "hierarchical" request. A "non-hierarchical" request
is one that doesn't generate any ICP traffic. To avoid processing
requests that are likely to lower cache efficiency, one can configure
the cache to not consult the hierarchy for URLs that contain certain
strings (e.g. `cgi_bin').
By default, a cache sends an ICP_OP_QUERY message to each peer,
unless any one of the following are true:
o Restrictions prevent querying a peer for this request, based on
the configuration directive `cache_host_domain', which specifies
a set of DNS domains (from the URLs) for which the peer should
or should not be queried. In Squid, a more flexible directive
('cache_host_acl') supports restrictions on other parts of the
request (method, port number, source, etc.).
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o The peer is a sibling, and the HTTP request includes a "Pragma:
no-cache" header. This is because the sibling would be asked to
transit the request, which is not allowed.
o The peer is configured to never be sent ICP queries (i.e. with
the `no-query' option).
If the determination yields only one queryable ICP peer, and the
Squid configuration directive `single_parent_bypass' is set, then one
can bypass waiting for the single ICP response and just send the HTTP
request directly to the peer cache.
The Squid configuration option `source_ping' configures a Squid cache
to send a ping to the original source simultaneous with its ICP
queries, in case the origin is closer than any of the caches.
Harvest and Squid want to maximize the chance to get a HIT reply from
one of the peers. Therefore, the cache waits for all ICP replies to
be received. Normally, we expect to receive an ICP reply for each
query sent, except:
o When the peer is believed to be down. If the peer is down Squid
and Harvest continue to send it ICP queries, but do not expect
the peer to reply. When an ICP reply is again received from the
peer, its status will be changed to up.
The determination of up/down status has varied a little bit as
the Harvest and Squid software evolved. Both Harvest and Squid
mark a peer down when it fails to reply to 20 consecutive ICP
queries. Squid also marks a peer down when a TCP connection
fails, and up again when a diagnostic TCP connection succeeds.
o When sending to a multicast address. In this case we'll
probably expect to receive more than one reply, and have no way
to definitively determine how many to expect. We discuss
multicast issues in section 7 below.
Because ICP uses UDP as underlying transport, ICP queries and replies
may sometimes be dropped by the network. The cache installs a
timeout event in case not all of the expected replies arrive. By
default Squid and Harvest use a two-second timeout. If object
retrieval has not commenced when the timeout occurs, a source is
selected as described in section 5.3.9 below.
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When an ICP_OP_QUERY message is received, the cache examines it and
decides which reply message is to be sent. It will send one of the
following reply opcodes, tested for use in the order listed:
The access controls are checked. If the peer is not allowed to make
this request, ICP_OP_DENIED is returned. Squid counts the number of
ICP_OP_DENIED messages sent to each peer. If more than 95% of more
than 100 replies have been denied, then no reply is sent at all.
This prevents misconfigured caches from endlessly sending unnecessary
ICP messages back and forth.
If the cache reaches this point without already matching one of the
previous opcodes, it means the request is allowed and we must
determine if it will be HIT or MISS, so we check if the URL exists in
the local cache. If so, and if the cached entry is fresh for at
least the next 30 seconds, we can return an ICP_OP_HIT message. The
stale/fresh determination uses the local refresh (or TTL) rules.
Note that a race condition exists for ICP_OP_HIT replies to sibling
peers. The ICP_OP_HIT means that a subsequent HTTP request for the
named URL would result in a cache hit. We assume that the HTTP
request will come very quickly after the ICP_OP_HIT. However, there
is a slight chance that the object might be purged from this cache
before the HTTP request is received. If this happens, and the
replying peer has applied Squid's `miss_access' configuration then
the user will receive a very confusing access denied message.
Before returning the ICP_OP_HIT message, we see if we can send an
ICP_OP_HIT_OBJ message instead. We can use ICP_OP_HIT_OBJ if:
o The ICP_OP_QUERY message had the ICP_FLAG_HIT_OBJ flag set.
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o The entire object (plus URL) will fit in an ICP message. The
maximum ICP message size is 16 Kbytes, but an application may
choose to set a smaller maximum value for ICP_OP_HIT_OBJ
replies.
Normally ICP replies are sent immediately after the query is
received, but the ICP_OP_HIT_OBJ message cannot be sent until the
object data is available to copy into the reply message. For Squid
and Harvest this means the object must be "swapped in" from disk if
it is not already in memory. Therefore, on average, an
ICP_OP_HIT_OBJ reply will have higher latency than ICP_OP_HIT.
At this point we have a cache miss. ICP has two types of miss
replies. If the cache does not want the peer to request the object
from it, it sends an ICP_OP_MISS_NOFETCH message.
Finally, an ICP_OP_MISS reply is returned as the default. If the
replying cache is a parent of the querying cache, the ICP_OP_MISS
indicates an invitation to fetch the URL through the replying cache.
Some ICP replies will be ignored; specifically, when any of the
following are true:
o The reply message originated from an unknown peer.
o The object named by the URL does not exist.
o The object is already being fetched.
If more than 95% of more than 100 replies from a peer cache have been
ICP_OP_DENIED, then such a high denial rate most likely indicates a
configuration error, either locally or at the peer. For this reason,
no further queries will be sent to the peer for the duration of the
cache process.
The object data is extracted from the ICP message and the retrieval
is complete. If there is some problem with the ICP_OP_HIT_OBJ
message (e.g. missing data) the reply will be treated like a standard
ICP_OP_HIT.
Object retrieval commences immediately from the origin server because
the ICP_OP_SECHO reply arrived prior to any ICP_OP_HIT's. If an
ICP_OP_HIT had arrived prior, this ICP_OP_SECHO reply would be
ignored because the retrieval has already started.
An ICP_OP_DECHO reply is handled like an ICP_OP_MISS. Non-ICP peers
must always be configured as parents; a non-ICP sibling makes no
sense. One serious problem with the ICP_OP_DECHO feature is that
since it bounces messages off the peer's UDP echo port, it does not
indicate that the peer cache is actually running -- only that network
connectivity exists between the pair.
If the peer is a sibling, the ICP_OP_MISS reply is ignored.
Otherwise, the peer may be "remembered" for future use in case no HIT
replies are received later (section 5.3.9).
Harvest and Squid remember the first parent to return an ICP_OP_MISS
message. With Squid, the parents may be weighted so that the "first
parent to miss" may not actually be the first reply received. We
call this the FIRST_PARENT_MISS. Remember that sibling misses are
entirely ignored, we only care about misses from parents. The parent
miss RTT's can be weighted because sometimes the closest parent is
not the one people want to use.
Also, recent versions of Squid may remember the parent with the
lowest RTT to the origin server, using the ICP_FLAG_SRC_RTT option.
We call this the CLOSEST_PARENT_MISS.
This reply is essentially ignored. A cache must not forward a
request to a peer that returns ICP_OP_MISS_NOFETCH.
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For ICP_OP_HIT and ICP_OP_SECHO the request is forwarded immediately.
For ICP_OP_HIT_OBJ there is no need to forward the request. For all
other reply opcodes, we wait until the expected number of replies
have been received. When we have all of the expected replies, or
when the query timeout occurs, it is time to forward the request.
Since MISS replies were received from all peers, we must either
select a parent cache or the origin server.
o If the peers are using the ICP_FLAG_SRC_RTT feature, we forward
the request to the peer with the lowest RTT to the origin
server. If the local cache is also measuring RTT's to origin
servers, and is closer than any of the parents, the request is
forwarded directly to the origin server.
o If there is a FIRST_PARENT_MISS parent available, the request
will be forwarded there.
o If the ICP query/reply exchange did not produce any appropriate
parents, the request will be sent directly to the origin server
(unless firewall restrictions prevent it).
This flag is off by default and will be set in an ICP_OP_QUERY
message only if these three criteria are met:
o It is enabled in the cache configuration file with `udp_hit_obj
on'.
o The peer must be using ICP version 2.
o The HTTP request must not include the "Pragma: no-cache" header.
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This flag is off by default and will be set in an ICP_OP_QUERY
message only if these two criteria are met:
o It is enabled in the cache configuration file with `query_icmp
on'.
o The peer must be using ICP version 2.
Operating a Web cache behind a firewall or in a private network poses
some interesting problems. The hard part is figuring out whether the
cache is able to connect to the origin server. Harvest and Squid
provide an `inside_firewall' configuration directive to list DNS
domains on the near side of a firewall. Everything else is assumed
to be on the far side of a firewall. Squid also has a `firewall_ip'
directive so that inside hosts can be specified by IP addresses as
well.
In a simple configuration, a Squid cache behind a firewall will have
only one parent cache (which is on the firewall itself). In this
case, Squid must use that parent for all servers beyond the firewall,
so there is no need to utilize ICP.
In a more complex configuration, there may be a number of peer caches
also behind the firewall. Here, ICP may be used to check for cache
hits in the peers. Occasionally, when ICP is being used, there may
not be any replies received. If the cache were not behind a
firewall, the request would be forwarded directly to the origin
server. But in this situation, the cache must pick a parent cache,
either randomly or due to configuration information. For example,
Squid allows a parent cache to be designated as a default choice when
no others are available.
For efficient distribution, a cache may deliver ICP queries to a
multicast address, and neighbor caches may join the multicast group
to receive such queries.
Current practice is that caches send ICP replies only to unicast
addresses, for several reasons:
o Multicasting ICP replies would not reduce the number of packets
sent.
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o It prevents other group members from receiving unexpected
replies.
o The reply should follow unicast routing paths to indicate
(unicast) connectivity between the receiver and the sender since
the subsequent HTTP request will be unicast routed.
Trust is an important aspect of inter-cache relationships. A Web
cache should not automatically trust any cache which replies to a
multicast ICP query. Caches should ignore ICP messages from
addresses not specifically configured as neighbors. Otherwise, one
could easily pollute a cache mesh by running an illegitimate cache
and having it join a group, return ICP_OP_HIT for all requests, and
then deliver bogus content.
When sending to multicast groups, cache administrators must be
careful to use the minimum multicast TTL required to reach all group
members. Joining a multicast group requires no special privileges
and there is no way to prevent anyone from joining "your" group. Two
groups of caches utilizing the same multicast address could overlap,
which would cause a cache to receive ICP replies from unknown
neighbors. The unknown neighbors would not be used to retrieve the
object data, but the cache would constantly receive ICP replies that
it must always ignore.
To prevent an overlapping cache mesh, caches should thus limit the
scope of their ICP queries with appropriate TTLs; an application such
as mtrace[6] can determine appropriate multicast TTLs.
As mentioned in section 5.1.3, we need to estimate the number of
expected replies for an ICP_OP_QUERY message. For unicast we expect
one reply for each query if the peer is up. However, for multicast
we generally expect more than one reply, but have no way of knowing
exactly how many replies to expect. Squid regularly (every 15
minutes) sends out test ICP_OP_QUERY messages to only the multicast
group peers. As with a real ICP query, a timeout event is installed
and the replies are counted until the timeout occurs. We have found
that the received count varies considerably. Therefore, the number
of replies to expect is calculated as a moving average, rounded down
to the nearest integer.
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ICP is notably different from HTTP. HTTP supports a rich and
sophisticated set of features. In contrast, ICP was designed to be
simple, small, and efficient. HTTP request and reply headers consist
of lines of ASCII text delimited by a CRLF pair, whereas ICP uses a
fixed size header and represents numbers in binary. The only thing
ICP and HTTP have in common is the URL.
Note that the ICP message does not even include the HTTP request
method. The original implementation assumed that only GET requests
would be cachable and there would be no need to locate non-GET
requests in neighbor caches. Thus, the current version of ICP does
not accommodate non-GET requests, although the next version of this
protocol will likely include a field for the request method.
HTTP defines features that are important for caching but not
expressible with the current ICP protocol. Among these are Pragma:
no-cache, If-Modified-Since, and all of the Cache-Control features of
HTTP/1.1. An ICP_OP_HIT_OBJ message may deliver an object which may
not obey all of the request header constraints. These differences
between ICP and HTTP are the reason we discourage the use of the
ICP_OP_HIT_OBJ feature.
Note that the ICP message does not have a field to indicate the
intent of the querying cache. That is, nowhere in the ICP request or
reply does it say that the two caches have a sibling or parent
relationship. A sibling cache can only respond with HIT or MISS, not
"you can retrieve this from me" or "you can not retrieve this from
me." The querying cache must apply the HIT or MISS reply to its
local configuration to prevent it from resolving misses through a
sibling cache. This constraint is awkward, because this aspect of
the relationship can be configured only in the cache originating the
requests, and indirectly via the access controls configured in the
queried cache as described earlier in section 4.2.
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There are two different understandings of what exactly the role of
ICP is in a cache mesh. One understanding is that ICP's role is only
object location, specifically, to provide hints about whether or not
a named object exists in a neighbor cache. An implied assumption is
that cache hits are highly desirable, and ICP is used to maximize the
chance of getting them. If an ICP message is lost due to congestion,
then nothing significant is lost; the request will be satisfied
regardless.
ICP is increasingly being tasked to fill a more complex role:
conveying cache usage policy. For example, many organizations (e.g.
universities) will install a Web cache on the border of their
network. Such organizations may be happy to establish sibling
relationships with other, nearby caches, subject to the following
terms:
o Any of the organization's customers or users may request any
object (cached or not).
o Anyone may request an object already in the cache.
o Anyone may request any object from the organization's servers
behind the cache.
o All other requests are denied; specifically, the organization
will not provide transit for requests in which neither the
client nor the server falls within its domain.
To successfully convey policy the ICP exchange must very accurately
predict the result (hit, miss) of a subsequent HTTP request. The
result may often depend on other request fields, such as Cache-
Control. So it's not possible for ICP to accurately predict the
result without more, or perhaps all, of the HTTP request.
We recognize certain flaws with the original design of ICP, and make
note of them so that future versions can avoid the same mistakes.
o The NULL-terminated URL in the payload field requires stepping
through the message an octet at a time to find some of the
fields (i.e. the beginning of object data in an ICP_OP_HIT_OBJ
message).
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o Two fields (Sender Host Address and Requester Host Address) are
IPv4 specific. However, neither of these fields are used in
practice; they are normally zero-filled. If IP addresses have a
role in the ICP message, there needs to be an address family
descriptor for each address, and clients need to be able to say
whether they want to hear IPv6 responses or not.
o Options are limited to 32 option flags and 32 bits of option
data. This should be more like TCP, with an option descriptor
followed by option data.
o Although currently used as the cache key, the URL string no
longer serves this role adequately. Some HTTP responses now
vary according to the requestor's User-Agent and other headers.
A cache key must incorporate all non-transport headers present
in the client's request. All non-hop-by-hop request headers
should be sent in an ICP query.
o ICPv2 uses different opcode values for queries and responses.
ICP should use the same opcode for both sides of a two-sided
transaction, with a "query/response" indicator telling which
side is which.
o ICPv2 does not include any authentication fields.
Security is an issue with ICP over UDP because of its connectionless
nature. Below we consider various vulnerabilities and methods of
attack, and their implications.
Our first line of defense is to check the source IP address of the
ICP message, e.g. as given by recvfrom(2). ICP query messages should
be processed if the access control rules allow the querying address
access to the cache. However, ICP reply messages must only be
accepted from known neighbors; a cache must ignore replies from
unknown addresses.
Because we trust the validity of an address in an IP packet, ICP is
susceptible to IP address spoofing. In this document we address some
consequences of IP address spoofing. Normally, spoofed addresses can
only be detected by routers, not by hosts. However, the IP
Authentication Header[7,8] can be used underneath ICP to provide
cryptographic authentication of the entire IP packet containing the
ICP protocol, thus eliminating the risk of IP address spoofing.
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RFC 2187 ICP September 1997
Here we are concerned with a third party generating ICP reply
messages which are returned to the querying cache before the real
reply arrives, or before any replies arrive. The third party may
insert bogus ICP replies which appear to come from legitimate
neighbors. There are three vulnerabilities:
o Preventing a certain neighbor from being used
If a third-party could send an ICP_OP_MISS_NOFETCH reply back
before the real reply arrived, the (falsified) neighbor would
not be used.
A third-party could blast a cache with ICP_OP_DENIED messages
until the threshold described in section 5.3.1 is reached,
thereby causing the neighbor relationship to be temporarily
terminated.
o Forcing a certain neighbor to be used
If a third-party could send an ICP_OP_HIT reply back before the
real reply arrived, the (falsified) neighbor would be used.
This may violate the terms of a sibling relationship; ICP_OP_HIT
replies mean a subsequent HTTP request will also be a hit.
Similarly, if bogus ICP_OP_SECHO messages can be generated, the
cache would retrieve requests directly from the origin server.
o Cache poisoning
The ICP_OP_HIT_OBJ message is especially sensitive to security
issues since it contains actual object data. In combination
with IP address spoofing, this option opens up the likely
possibility of having the cache polluted with invalid objects.
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RFC 2187 ICP September 1997
Multicasting ICP queries provides a very simple method for others to
"snoop" on ICP messages. If enabling multicast, cache administrators
should configure the application to use the minimum required
multicast TTL, using a tool such as mtrace[6]. Note that the IP
Encapsulating Security Payload [7,9] mechanism can be used to provide
protection against eavesdropping of ICP messages.
Eavesdropping on ICP traffic can provide third parties with a list of
URLs being browsed by cache users. Because the Requestor Host
Address is zero-filled by Squid and Harvest, the URLs cannot be
mapped back to individual host systems.
By default, Squid and Harvest do not send ICP messages for URLs
containing `cgi-bin' or `?'. These URLs sometimes contain sensitive
information as argument parameters. Cache administrators need to be
aware that altering the configuration to make ICP queries for such
URLs may expose sensitive information to outsiders, especially when
multicast is used.
Intentionally blocked (or discarded) ICP queries or replies will
appear to reflect link failure or congestion, and will prevent the
use of a neighbor as well as lead to timeouts (see section 5.1.4).
If all messages are blocked, the cache will assume the neighbor is
down and remove it from the selection algorithm. However, if, for
example, every other query is blocked, the neighbor will remain
"alive," but every other request will suffer the ICP timeout.
The neighbor selection algorithm normally waits for all ICP MISS
replies to arrive. Delaying queries or replies, so that they arrive
later than they normally would, will cause additional delay for the
subsequent HTTP request. Of course, if messages are delayed so that
they arrive after the timeout, the behavior is the same as "blocking"
above.
A denial-of-service attack, where the ICP port is flooded with a
continuous stream of bogus messages has three vulnerabilities:
o The application may log every bogus ICP message and eventually
fill up a disk partition.
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RFC 2187 ICP September 1997
o The socket receive queue may fill up, causing legitimate
messages to be dropped.
o The host may waste some CPU cycles receiving the bogus messages.
Here we assume a third party is able to change one or more of the ICP
reply message fields.
Opcode
Changing the opcode field is much like inserting bogus messages
described above. Changing a hit to a miss would prevent the peer
from being used. Changing a miss to a hit would force the peer to
be used.
Version
Altering the ICP version field may have unpredictable consequences
if the new version number is recognized and supported. The
receiving application should ignore messages with invalid version
numbers. At the time of this writing, both version numbers 2 and
3 are in use. These two versions use some fields (e.g. Options)
in a slightly different manner.
Message Length
An incorrect message length should be detected by the receiving
application as an invalid ICP message.
Request Number
The request number is often used as a part of the cache key.
Harvest does not use the request number. Squid uses the request
number in conjunction with the URL to create a cache key.
Altering the request number will cause a lookup of the cache key
to fail. This is similar to blocking the ICP reply altogether.
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RFC 2187 ICP September 1997
There is no requirement that a cache use both the URL and the
request number to locate HTTP requests with outstanding ICP
queries (however both Squid and Harvest do). The request number
must always be the same in the query and the reply. However, if
the querying cache uses only the request number to locate pending
requests, there is some possibility that a replying cache might
increment the request number in the reply to give the false
impression that the two caches are closer than they really are.
In other words, assuming that there are a few ICP requests "in
flight" at any given time, incrementing the reply request number
trick the querying cache into seeing a smaller round-trip time
than really exists.
Options
There is little risk in having the Options bitfields altered. Any
option bit must only be set in a reply if it was also set in a
query. Changing a bit from clear to set is detectable by the
querying cache, and such a message must be ignored. Changing a
bit from set to clear is allowed and has no negative side effects.
Option Data
ICP_FLAG_SRC_RTT is the only option which uses the Option Data
field. Altering the RTT values returned here can affect the
neighbor selection algorithm, either forcing or preventing the use
of a neighbor.
URL
The URL and Request Number are used to generate the cache key.
Altering the URL will cause a lookup of the cache key to fail, and
the ICP reply to be entirely ignored. This is similar to blocking
the ICP reply altogether.
o ICP_OP_HIT_OBJ is particularly vulnerable to security problems
because it includes object data. For this, and other reasons,
its use is discouraged.
o Falsifying, altering, inserting, or blocking ICP messages can
cause an HTTP request to fail only in two situations:
- If the cache is behind a firewall and cannot directly
connect to the origin server.
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RFC 2187 ICP September 1997
- If a false ICP_OP_HIT reply causes the HTTP request to be
forwarded to a sibling, where the request is a cache miss
and the sibling refuses to continue forwarding the request
on behalf of the originating cache.
o Falsifying, altering, inserting, or blocking ICP messages can
easily cause HTTP requests to be forwarded (or not forwarded) to
certain neighbors. If the neighbor cache has also been
compromised, then it could serve bogus content and pollute a
cache hierarchy.
o Blocking or delaying ICP messages can cause HTTP request to be
further delayed, but still satisfied.
[1] Fielding, R., et. al, "Hypertext Transfer Protocol -- HTTP/1.1",
RFC 2068, UC Irvine, January 1997.
[2] Berners-Lee, T., Masinter, L., and M. McCahill, "Uniform Resource
Locators (URL)", RFC 1738, CERN, Xerox PARC, University of Minnesota,
December 1994.
[3] Bowman M., Danzig P., Hardy D., Manber U., Schwartz M., and
Wessels D., "The Harvest Information Discovery and Access System",
Internet Research Task Force - Resource Discovery,
http://harvest.transarc.com/.
[4] Wessels D., Claffy K., "ICP and the Squid Web Cache", National
Laboratory for Applied Network Research,
http://www.nlanr.net/~wessels/Papers/icp-squid.ps.gz.
[5] Wessels D., "The Squid Internet Object Cache", National
Laboratory for Applied Network Research,
http://squid.nlanr.net/Squid/
[6] mtrace, Xerox PARC, ftp://ftp.parc.xerox.com/pub/net-
research/ipmulti/.
[7] Atkinson, R., "Security Architecture for the Internet Protocol",
RFC 1825, NRL, August 1995.
[8] Atkinson, R., "IP Authentication Header", RFC 1826, NRL, August
1995.
[9] Atkinson, R., "IP Encapsulating Security Payload (ESP)", RFC
1827, NRL, August 1995.
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RFC 2187 ICP September 1997
The authors wish to thank Paul A Vixie <paul@vix.com> for providing
excellent feedback on this document, Martin Hamilton
<martin@mrrl.lut.ac.uk> for pushing the development of multicast ICP,
Eric Rescorla <ekr@terisa.com> and Randall Atkinson <rja@home.net>
for assisting with security issues, and especially Allyn Romanow for
keeping us on the right track.
Duane Wessels
National Laboratory for Applied Network Research
10100 Hopkins Drive
La Jolla, CA 92093
EMail: wessels@nlanr.net
K. Claffy
National Laboratory for Applied Network Research
10100 Hopkins Drive
La Jolla, CA 92093
EMail: kc@nlanr.net
Wessels & Claffy Informational [Page 24]