The hostmask/netmask system. Copyright(C) 2001 by Andrew Miller(A1kmm) $Id: hostmask.txt,v 1.1 2001/05/02 09:09:52 a1kmm Exp $ Contents ======== * Section 1: Motivation * Section 2: Underlying mechanism - 2.1: General overview. - 2.2: IPv4 netmasks. - 2.3: IPv6 netmasks. - 2.4: Hostmasks. * Section 3: Exposed abstraction layer - 3.1: Parsing masks. - 3.2: Adding configuration items. - 3.3: Initialising or rehashing. - 3.4: Finding IP/host confs. - 3.5: Deleting entries. - 3.6: Reporting entries. Section 1: Motivation ===================== Looking up config hostnames and IP addresses(such as for I-lines and K-lines) needs to be implemented efficiently. It turns out a hash based algorithm like that employed here performs well on the average case, which is what we should be the most concerned about. A profiling comparison with the mtrie code using data from a real network confirmed that this algorithm performs much better. Section 2: Underlying mechanism =============================== 2.1: General overview --------------------- In short, a hash-table with linked lists for buckets is used to locate the correct hostname/netmask entries. In order to support CIDR IPs and wildcard masks, the entire key cannot be hashed, and there is a need to rehash. The means for deciding how much to hash differs between hostmasks and IPv4/6 netmasks. 2.2: IPv4 netmasks ------------------ In order to hash IPv4 netmasks for addition to the hash, the mask is first processed to a 32 bit address and a number of bits used. All unused bits are set to 0. The mask could be in the forms: 1.2.3.4 => 1.2.3.4 32 1.2.3.* => 1.2.3.0 24 1.2 => 1.2.0.0 16 1.2.3.64/26 => 1.2.3.64 26 The number of whole bytes is then calculated, and only those bytes are hashed. (e.g. 1.2.3.64/26 and 1.2.3.0/24 hash the same). When a complete IPv4 address is given so that an IPv4 match can be found, the entire IP address is first hashed, and looked up in the table. Then the most significant three bytes are hashed, followed by the most significant two, the most significant one, and finally the 'identity hash' bucket is searched(to match masks like 192/7). 2.3: IPv6 netmasks ------------------ As per IPv4 netmasks, except that instead of rehashing with a one byte granularity, a 16 bit(two byte) granularity is used, as 16 rehashes is considered too great a fixed offset to be justified for a (possible) slight reduction in hash collisions. 2.4: Hostmasks -------------- On adding a hostmask to the hash, all of the hostmask right of the next dot after the last wildcard character in the string is hashed, or in the case that there are no wildcards in the hostmask, the entire string is hashed. On searching for a hostmask match, the entire hostname is hashed, followed by the entire hostmask after the first dot, followed by the entire hostmask after the second dot, and so on. Finally, the 'identity' hash bucket is checked, to catch hostnames like *test*. Section 3: Exposed abstraction layer ==================================== Section 3.1: Parsing masks -------------------------- Call "parse_netmask()" with the netmask and a pointer to an irc_inaddr structure to be filled in, as well as a pointer to an integer where the number of bits will be placed. Always check the return value. If it returns HM_HOST, it means that the mask is probably a hostname mask. If it returns HM_IPV4, it means it was an IPv4 address. If it returns HM_IPV6, it means it was an IPv6 address. If parse_netmask returns HM_HOST, no change is made to the irc_inaddr structure or the number of bits. Section 3.2: Adding configuration items --------------------------------------- Call "add_conf_by_address" with the hostname or IP mask, the username, and the ConfItem* to associate with this mask. Section 3.3: Initialising and rehashing ---------------------------------------- To initialise, call init_host_hash(). This only needs to be done once on startup. On rehash, to wipe out the old unwanted conf, and free them if there are no references to them, call clear_out_address_conf(). Section 3.4: Finding IP/host confs ---------------------------------- Call find_address_conf() with the hostname, the username, the address, and the address family. To find a d-line, call find_dline() with the address and address family. Section 3.5: Deletiing entries ------------------------------ Call delete_one_address_conf() with the hostname and the ConfItem*. Section 3.6: Reporting entries ------------------------------ Call report_dlines, report_exemptlines, report_Klines() or report_Ilines() with the client pointer to report to. Note these walk the hash, which is inefficient, but these are not called often enough to justify the memory and maintenance clockcycles to for more efficient data structure.