Martin Hamilton JANET Web Cache Service Alex Rousskov NLANR Duane Wessels NLANR December 1998 Cache Digest specification - version 5 Status of this memo This draft document may be updated, replaced, or made obsolete by other documents at any time. It is inappropriate to use this draft as reference material or to cite them other than as work in progress. Cache Digests are experimental and subject to change. This isn't just an idle threat - the current specification *will* change soon! These changes are likely to affect both the underlying data format and the digest exchange mechanism. This document describes the Squid 2.[01] implementation, specifically that in Squid 2.1PATCH2. Abstract This document describes the Cache Digest exchange protocol and data format, as implemented by version 2 of the Squid WWW cache server. Cache Digests provide a mechanism for (primarily) WWW cache servers to cooperate without the latency and congestion problems associated with previous protocols such as ICP. 1. What are Cache Digests ? Cache Digests are a response to the problems of latency and congestion associated with previous inter-cache communications mechanisms such as the Internet Cache Protocol (ICP) [RFC 2186, RFC 2187] and the HyperText Cache Protocol [HTCP-ID]. Unlike most of these protocols, Cache Digests support peering between cache servers without a request-response exchange taking place. Instead, a summary of the contents of the server (the Digest) is fetched by other servers which peer with it. Using Cache Digests it is possible to determine with a relatively high degree of accuracy whether a given URL is cached by a particular server. This is done by feeding the URL and the HTTP method by which it is being requested into a hash function which returns a list of bits to test against in the Cache Digest [DIGESTS, BLOOM]. Cache Digests are both a protocol and a data format, in the sense that the construction of the Cache Digest itself is well defined, and there is a well defined protocol for fetching Cache Digests over a network - currently via HTTP. It's possible that Cache Digests could be exchanged via other mechanisms, in addition to HTTP, e.g. via FTP. The Cache Digest is calculated internally by the cache server and can exist as (for instance) a cached object like any other - subject to object refresh and expiry rules. Although Cache Digests as currently conceived are intended primarily for use in sharing summaries of which URLs are cached by a given server, this capability can be extended to cover other data sources. For example, an FTP mirror server might make a Cache Digest available which indicated matches for all of the URLs by which the resources it mirrored may be accessed. This is potentially a very powerful mechanism for eliminating redundancy and making better use of Internet server and bandwidth resources. Cache Digests have been implemented in version 2 of the Squid WWW Cache Server [SQUID], though they are still considered experimental and (at the time of writing) must be explicitly enabled when Squid is compiled. 2. Public keys Although we've spoken so far about URLs, the keys which are looked up in Cache Digests are actually formed by performing the MD5 [RFC 1321] digest function on the concatenation of: 1. a numeric code for the HTTP method used, and 2. the URL requested. Internally within Squid these MD5 values are referred to as 'public keys', and we'll reuse this terminology here to keep things simple. Legal values for the method number, and their corresponding HTTP methods, are: GET 1 POST 2 PUT 3 HEAD 4 CONNECT 5 TRACE 6 PURGE 7 The method value is stored as an 8 bit integer - see below for bit/byte ordering details. For example, the public key (MD5 digest value) for the 'http://www.w3.org/' URL fetched via the HTTP 'GET' method is: e06a56257d8879d9e968e83f2ded3df7 This is calculated on: ASCII: GET h t t p : / / w w w . w 3 . o r g / Hex: 01 68 74 74 70 3a 2f 2f 77 77 77 2e 77 33 2e 6f 72 67 2f [ Note that versions of Squid prior to 2.1PATCH2 packed the HTTP method value incorrectly. Unfortunately, the Cache Digests version was not updated in 2.1PATCH2. Thus, all Cache Digests with versions 0-3 and some with version 4 may contain the endian-ness bug. ] 3. The Cache Digest itself The Cache Digest is an array of bits. A hash function is used to derive the indices into the array which should be set (to register the presence of a public key) or tested (to look up a given public key in a given Digest). In Squid the number of bits in the Digest per public key is currently set to 5 by default. The size of the Digest itself depends on both the number of bits consumed per entry, and the number of public keys which may be stored in the Digest - referred to as its capacity. The number of bytes used for the digest can be written as: digest_size = int((capacity * bits_per_entry + 7) / 8); Note that these values must be communicated to any entity which is to make use of the Cache Digest - this is the function of the Cache Digest header (see below). 4. The Cache Digest hash function In order to register a given public key in a Cache Digest, a number of indices into the array (in Squid - four by default, though this may change) are calculated using a hash function. This carries out the following steps: 1) Calculate the public key from the HTTP method and URL. 2) Split the resulting 128 bit value into N chunks, say: temp_key[0] .. temp-key[N-1] 3) For each of these N chunks, the corresponding index into the cache digest is the digest value modulo the number of bits in the digest: hash_key[i] = temp_key[i] % (digest_size * 8); The resulting N indices are the result of the function. N is called the dimension of a hashing function. In the 'GET http://www.w3.org/' example above, the public key is: e06a56257d8879d9e968e83f2ded3df7 In the default Squid scheme (N is 4) we would split it into the following four chunks: temp_key[0] = 0xe06a5625; temp_key[1] = 0x7d8879d9; temp_key[2] = 0xe968e83f; temp_key[3] = 0x2ded3df7; And calculate the indices into the cache digest as follows: hash_key[0] = temp_key[0] % (digest_size * 8); hash_key[1] = temp_key[1] % (digest_size * 8); hash_key[2] = temp_key[2] % (digest_size * 8); hash_key[3] = temp_key[3] % (digest_size * 8); Giving us the following four lookup keys (assuming digest_size is 16 bytes): hash_keys[0] = 0x05; hash_keys[1] = 0x29; hash_keys[2] = 0x5f; hash_keys[3] = 0x17; Note that these are indices into a bit array! 5. Adding a public key to a Cache Digest Given a public key, the bit in the Cache Digest bit array associated with each of the indices (as calculated above) should be set. 6. Testing a Cache Digest for a given public key A given public key is considered to be a match if and only if all of the bits associated with it (as outlined above) in the Cache Digest are set to 1. 7. Deleting a public key You can't delete a single public key from the Digest without rebuilding it from scratch. Simply clearing the bits in the Digest associated with this public key may also clear (some of the) bits associated with other public keys. 8. Fetching a Cache Digest To fetch the Cache Digest from the Squid server listening for proxy HTTP requests on port 3128 of the host 'test.lut.ac.uk', a proxy HTTP request should be sent to it for the URL: http://test.lut.ac.uk:3128/squid-internal-periodic/store_digest Clients must use 'If-Modified-Since' requests if they have old Digests, to avoid inadvertently transferring the same Digest more than once. The Cache Digest response is formatted as a regular HTTP response with the Internet Media Type (MIME type): application/cache-digest The normal HTTP status codes should be used to deal with, for instance, authentication and access controls. A successful response would look something like: HTTP/1.0 200 OK Server: Squid/2.1.PATCH2+Martin Mime-Version: 1.0 Date: Sun, 13 Dec 1998 04:26:46 GMT Content-Type: application/cache-digest Content-Length: 142 Expires: Sun, 13 Dec 1998 05:26:46 GMT Last-Modified: Sun, 13 Dec 1998 04:26:46 GMT X-Cache: HIT from test.lut.ac.uk X-Cache-Lookup: HIT from test.lut.ac.uk:3128 Age: 284 Proxy-Connection: close <followed by body of response> The body of the response consists of the Cache Digest header, a fixed length (binary) data structure which specifies various aspects of the Digest, followed by the Cache Digest itself. The header and digest combined come to the total number of bytes specified in the HTTP Content-Length header - 142 in this case. Note that all numbers, including the bits of the Cache Digest itself and the header which precedes it, are transfered in 'network' (big-endian, most significant byte first) order. 9. Format of the Cache Digest Header The Cache Digest header is (currently!) a 128 byte data structure which contains the following fields: Field name Type Bytes Function -------------------------------------------------------------- Current version n 2 Version of this Digest Required version n 2 Minimum version required Capacity N 4 Number of URLs we can fit in Count N 4 Number of URLs actually in digest Deletion count N 4 Number of URL deletion attempts Size in bytes N 4 Size of digest, in bytes Bits per entry C 1 Number of bits per digest entry Hash func dimension C 1 Number of hash function chunks Reserved n 2 Reserved for future expansion Reserved N26 104 Reserved for future expansion Where: C: 8 bit (1 byte) wide unsigned integer/unsigned char n: 16 bit (2 byte) signed integer N: 32 bit (4 byte) signed integer As noted above, "Capacity" is the number of URLs we expected to be in the digest when we built it. Squid calculates this value based on the number of URLs which were cached by the server at the time the digest was calculated, and recalculates the digest at periodic intervals -- every hour by default. "Required version" is the minimum version the decoding algorithm must support to interpret the digest correctly. If a receiver does not support "Required version", the entire reply must be ignored. No attempts to guess a part of the header must be made in the latter case. The "Reserved" fields are currently unused and must be set to zero. 10. Security considerations If the contents of the Cache Digest are in any way sensitive, the Cache Administrator should take care to protect it from access by The Wrong People. Note that any methods which would normally be applied to secure an HTTP connection can be applied to Cache Digests, e.g. Message Digest Authentication [RFC 2069] or Secure Sockets Layer/TLS [TLS-ID]. Note that these access control issues also apply to Cache Digests which are cached alongside regular HTTP objects such as WWW pages - if not, it may be possible for third parties to download the Cache Digest of a server without the administrator of the server being aware that this has happened. For this reason it may be desirable to have a flag in the Cache Digest header which indicates whether redistribution is permitted/encouraged. Squid does not currently support such a flag, however. Since the algorithm is inherently imprecise, the resulting Digest is likely to contain some false hits for URLs which the cache doesn't actually contain (as well as some false misses). If the cache is configured so as to allow its peers to only request objects which are already cached (e.g. via Squid's miss_allow option), peers will have to take care not to assume that a Digest hit means that access to the server which generated it will be allowed - and should be robust in the even that access is denied. This may result in unintentional denial of service. Cache A can build a fake peer Digest for cache B and serve it to B's peers if requested. This way A can direct traffic toward/from B. The impact of this problem is minimized by the 'pull' model of transferring Cache Digests from one server to another, but this 'Trojan horse' attack is possible in a cache mesh. 11. Open issues The 'application/cache-digest' media type needs to be registered with IANA, for use with HTTP. There should be a standard URL for fetching Cache Digests from a server. That is, one which doesn't include '/squid-internal-periodic/'. How to decide the initial capacity? Squid works on the basis of the number of cached URLs when it periodically regenerates its Digest, by dividing the amount of cache disk space in use by the average object size. One cache may have more than one digest - e.g. very fresh objects, somewhat fresh objects, and stale objects. How to ask for a list of the digests the cache has? Rather than exchanging full digests, make "delta" or "diff" style exchanges of Digests. For example, when the number of bits changed since the previous version of the Digest was generated is below a given threshold. This implies some degree of synchronization between Digest aware cache servers, perhaps via DNS style serial numbers in the Cache Digest headers. Add info on how to verify that the Digest is not corrupted. It may be worth computing an end-to-end checksum for this - e.g. via MD5, since we already need the MD5 code in order to calculate public keys. What to do with Cache Digest protocol version numbers in the header. For example, version 3 implementations should not fetch digests from version 4 servers, since the set bits corresponding to a given URL will be different due to the change in HTTP method encoding. How to add custom info to the header. Despite the presence of "reserved" bytes, extending the current format is strongly discouraged. The next header format will allow for customizations. How to calculate the probability of a false hit. How often to rebuild a Digest. Squid currently has a hard wired default of rebuilding the Digest every hour. How many of the cached object URLs (or percentage of the Digest) to rebuild in any one chunk - or handle this in its entirety via a separate thread or (non-blocking) process. 12. Acknowledgments This work was supported by the Joint Informations Systems Committee (JISC) of the UK Higher Education funding Councils, as part of the JANET Web Cache Service, and by the US National Science Foundation under grants NCR-9521745 and NCR-9616602. 13. References [RFC 2186] D. Wessels and K. Claffy, "Internet Cache Protocol (ICP), version 2", RFC 2186, September 1997. <URL:ftp://ftp.ietf.org/rfc/rfc2186.txt> [RFC 2187] D. Wessels and K. Claffy, "Application of Internet Cache Protocol (ICP), version 2", RFC 2187, September 1997. <URL:ftp://ftp.ietf.org/rfc/rfc2187.txt> [HTCP-ID] P. Vixie and D. Wessels, "Hyper Text Caching Protocol (HTCP/0.0)", Internet Draft (work in progress), September 1998. [SUMMARY] L. Fan, P. Cao, J. Almeida, and A. Z. Broder, "Summary Cache: A Scalable Wide-Area Web Cache Sharing Protocol", Proceedings of SIGCOMM'98, <URL:http://www.cs.wisc.edu/%7ecao/papers/summarycache.html> [DIGESTS] A. Rousskov and D. Wessels, "Cache Digests", Computer Networks and ISDN Systems, Volume 30, Numbers 22-23, November 1998, <URL:http://ircache.nlanr.net/Papers/cache-digests.ps.gz> [BLOOM] B. Bloom, "Space/time trade-offs in hash coding with allowable errors", Communications of the ACM, volume 13, pp. 422-426, July 1970. [SQUID] D. Wessels, "Squid Homepage", December 1998. <URL:http://squid.nlanr.net/> [RFC 1321] R. Rivest, "The MD5 Message Digest Algorithm", RFC 1321, April 1992. <URL:http://ftp.ietf.org/rfc/rfc132.txt> [RFC 2069] J. Franks, P. Hallam-Baker, J. Hostetler, P. Leach, A. Luotonen, E. Sink and L. Stewart, "An Extension to HTTP: Digest Access Authentication", RFC 2069, January 1997. <URL:ftp://ftp.ietf.org/rfc/rfc2069.txt> [TLS-ID] T. Dierks and C. Allen, "The TLS Protocol, Version 1.0", Internet Draft (work in progress), November 1998. 14. Authors' addresses Martin Hamilton JANET Web Cache Service/Department of Computer Studies Loughborough University Leics. LE11 3TU, UK Email: martin@wwwcache.ja.net Alex Rousskov National Laboratory for Applied Network Research NCAR SCD, Room 22c 1850 Table Mesa Drive Boulder, CO 80303, USA Email: rousskov@nlanr.net Duane Wessels National Laboratory for Applied Network Research NCAR SCD, Room 24D 1850 Table Mesa Drive Boulder, CO 80303, USA Email: wessels@nlanr.net -- $Id: cache-digest-v5.dyn,v 1.3 2007/08/05 08:21:21 amosjeffries Exp $
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