503f3b1a21
PR: 59
294 lines
13 KiB
Text
294 lines
13 KiB
Text
=pod
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=head1 NAME
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lh_new, lh_free, lh_insert, lh_delete, lh_retrieve, lh_doall, lh_doall_arg, lh_error - dynamic hash table
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=head1 SYNOPSIS
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#include <openssl/lhash.h>
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LHASH *lh_new(LHASH_HASH_FN_TYPE hash, LHASH_COMP_FN_TYPE compare);
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void lh_free(LHASH *table);
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void *lh_insert(LHASH *table, void *data);
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void *lh_delete(LHASH *table, void *data);
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void *lh_retrieve(LHASH *table, void *data);
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void lh_doall(LHASH *table, LHASH_DOALL_FN_TYPE func);
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void lh_doall_arg(LHASH *table, LHASH_DOALL_ARG_FN_TYPE func,
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void *arg);
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int lh_error(LHASH *table);
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typedef int (*LHASH_COMP_FN_TYPE)(const void *, const void *);
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typedef unsigned long (*LHASH_HASH_FN_TYPE)(const void *);
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typedef void (*LHASH_DOALL_FN_TYPE)(const void *);
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typedef void (*LHASH_DOALL_ARG_FN_TYPE)(const void *, const void *);
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=head1 DESCRIPTION
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This library implements dynamic hash tables. The hash table entries
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can be arbitrary structures. Usually they consist of key and value
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fields.
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lh_new() creates a new B<LHASH> structure to store arbitrary data
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entries, and provides the 'hash' and 'compare' callbacks to be used in
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organising the table's entries. The B<hash> callback takes a pointer
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to a table entry as its argument and returns an unsigned long hash
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value for its key field. The hash value is normally truncated to a
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power of 2, so make sure that your hash function returns well mixed
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low order bits. The B<compare> callback takes two arguments (pointers
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to two hash table entries), and returns 0 if their keys are equal,
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non-zero otherwise. If your hash table will contain items of some
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particular type and the B<hash> and B<compare> callbacks hash/compare
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these types, then the B<DECLARE_LHASH_HASH_FN> and
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B<IMPLEMENT_LHASH_COMP_FN> macros can be used to create callback
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wrappers of the prototypes required by lh_new(). These provide
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per-variable casts before calling the type-specific callbacks written
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by the application author. These macros, as well as those used for
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the "doall" callbacks, are defined as;
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#define DECLARE_LHASH_HASH_FN(f_name,o_type) \
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unsigned long f_name##_LHASH_HASH(const void *);
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#define IMPLEMENT_LHASH_HASH_FN(f_name,o_type) \
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unsigned long f_name##_LHASH_HASH(const void *arg) { \
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o_type a = (o_type)arg; \
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return f_name(a); }
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#define LHASH_HASH_FN(f_name) f_name##_LHASH_HASH
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#define DECLARE_LHASH_COMP_FN(f_name,o_type) \
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int f_name##_LHASH_COMP(const void *, const void *);
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#define IMPLEMENT_LHASH_COMP_FN(f_name,o_type) \
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int f_name##_LHASH_COMP(const void *arg1, const void *arg2) { \
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o_type a = (o_type)arg1; \
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o_type b = (o_type)arg2; \
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return f_name(a,b); }
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#define LHASH_COMP_FN(f_name) f_name##_LHASH_COMP
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#define DECLARE_LHASH_DOALL_FN(f_name,o_type) \
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void f_name##_LHASH_DOALL(const void *);
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#define IMPLEMENT_LHASH_DOALL_FN(f_name,o_type) \
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void f_name##_LHASH_DOALL(const void *arg) { \
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o_type a = (o_type)arg; \
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f_name(a); }
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#define LHASH_DOALL_FN(f_name) f_name##_LHASH_DOALL
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#define DECLARE_LHASH_DOALL_ARG_FN(f_name,o_type,a_type) \
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void f_name##_LHASH_DOALL_ARG(const void *, const void *);
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#define IMPLEMENT_LHASH_DOALL_ARG_FN(f_name,o_type,a_type) \
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void f_name##_LHASH_DOALL_ARG(const void *arg1, const void *arg2) { \
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o_type a = (o_type)arg1; \
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a_type b = (a_type)arg2; \
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f_name(a,b); }
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#define LHASH_DOALL_ARG_FN(f_name) f_name##_LHASH_DOALL_ARG
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An example of a hash table storing (pointers to) structures of type 'STUFF'
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could be defined as follows;
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/* Calculates the hash value of 'tohash' (implemented elsewhere) */
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unsigned long STUFF_hash(const STUFF *tohash);
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/* Orders 'arg1' and 'arg2' (implemented elsewhere) */
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int STUFF_cmp(const STUFF *arg1, const STUFF *arg2);
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/* Create the type-safe wrapper functions for use in the LHASH internals */
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static IMPLEMENT_LHASH_HASH_FN(STUFF_hash, const STUFF *)
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static IMPLEMENT_LHASH_COMP_FN(STUFF_cmp, const STUFF *);
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/* ... */
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int main(int argc, char *argv[]) {
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/* Create the new hash table using the hash/compare wrappers */
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LHASH *hashtable = lh_new(LHASH_HASH_FN(STUFF_hash),
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LHASH_COMP_FN(STUFF_cmp));
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/* ... */
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}
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lh_free() frees the B<LHASH> structure B<table>. Allocated hash table
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entries will not be freed; consider using lh_doall() to deallocate any
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remaining entries in the hash table (see below).
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lh_insert() inserts the structure pointed to by B<data> into B<table>.
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If there already is an entry with the same key, the old value is
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replaced. Note that lh_insert() stores pointers, the data are not
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copied.
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lh_delete() deletes an entry from B<table>.
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lh_retrieve() looks up an entry in B<table>. Normally, B<data> is
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a structure with the key field(s) set; the function will return a
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pointer to a fully populated structure.
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lh_doall() will, for every entry in the hash table, call B<func> with
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the data item as its parameter. For lh_doall() and lh_doall_arg(),
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function pointer casting should be avoided in the callbacks (see
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B<NOTE>) - instead, either declare the callbacks to match the
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prototype required in lh_new() or use the declare/implement macros to
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create type-safe wrappers that cast variables prior to calling your
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type-specific callbacks. An example of this is illustrated here where
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the callback is used to cleanup resources for items in the hash table
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prior to the hashtable itself being deallocated:
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/* Cleans up resources belonging to 'a' (this is implemented elsewhere) */
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void STUFF_cleanup(STUFF *a);
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/* Implement a prototype-compatible wrapper for "STUFF_cleanup" */
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IMPLEMENT_LHASH_DOALL_FN(STUFF_cleanup, STUFF *)
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/* ... then later in the code ... */
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/* So to run "STUFF_cleanup" against all items in a hash table ... */
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lh_doall(hashtable, LHASH_DOALL_FN(STUFF_cleanup));
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/* Then the hash table itself can be deallocated */
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lh_free(hashtable);
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When doing this, be careful if you delete entries from the hash table
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in your callbacks: the table may decrease in size, moving the item
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that you are currently on down lower in the hash table - this could
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cause some entries to be skipped during the iteration. The second
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best solution to this problem is to set hash-E<gt>down_load=0 before
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you start (which will stop the hash table ever decreasing in size).
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The best solution is probably to avoid deleting items from the hash
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table inside a "doall" callback!
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lh_doall_arg() is the same as lh_doall() except that B<func> will be
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called with B<arg> as the second argument and B<func> should be of
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type B<LHASH_DOALL_ARG_FN_TYPE> (a callback prototype that is passed
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both the table entry and an extra argument). As with lh_doall(), you
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can instead choose to declare your callback with a prototype matching
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the types you are dealing with and use the declare/implement macros to
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create compatible wrappers that cast variables before calling your
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type-specific callbacks. An example of this is demonstrated here
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(printing all hash table entries to a BIO that is provided by the
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caller):
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/* Prints item 'a' to 'output_bio' (this is implemented elsewhere) */
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void STUFF_print(const STUFF *a, BIO *output_bio);
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/* Implement a prototype-compatible wrapper for "STUFF_print" */
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static IMPLEMENT_LHASH_DOALL_ARG_FN(STUFF_print, const STUFF *, BIO *)
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/* ... then later in the code ... */
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/* Print out the entire hashtable to a particular BIO */
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lh_doall_arg(hashtable, LHASH_DOALL_ARG_FN(STUFF_print), logging_bio);
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lh_error() can be used to determine if an error occurred in the last
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operation. lh_error() is a macro.
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=head1 RETURN VALUES
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lh_new() returns B<NULL> on error, otherwise a pointer to the new
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B<LHASH> structure.
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When a hash table entry is replaced, lh_insert() returns the value
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being replaced. B<NULL> is returned on normal operation and on error.
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lh_delete() returns the entry being deleted. B<NULL> is returned if
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there is no such value in the hash table.
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lh_retrieve() returns the hash table entry if it has been found,
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B<NULL> otherwise.
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lh_error() returns 1 if an error occurred in the last operation, 0
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otherwise.
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lh_free(), lh_doall() and lh_doall_arg() return no values.
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=head1 NOTE
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The various LHASH macros and callback types exist to make it possible
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to write type-safe code without resorting to function-prototype
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casting - an evil that makes application code much harder to
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audit/verify and also opens the window of opportunity for stack
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corruption and other hard-to-find bugs. It also, apparently, violates
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ANSI-C.
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The LHASH code regards table entries as constant data. As such, it
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internally represents lh_insert()'d items with a "const void *"
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pointer type. This is why callbacks such as those used by lh_doall()
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and lh_doall_arg() declare their prototypes with "const", even for the
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parameters that pass back the table items' data pointers - for
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consistency, user-provided data is "const" at all times as far as the
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LHASH code is concerned. However, as callers are themselves providing
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these pointers, they can choose whether they too should be treating
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all such parameters as constant.
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As an example, a hash table may be maintained by code that, for
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reasons of encapsulation, has only "const" access to the data being
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indexed in the hash table (ie. it is returned as "const" from
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elsewhere in their code) - in this case the LHASH prototypes are
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appropriate as-is. Conversely, if the caller is responsible for the
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life-time of the data in question, then they may well wish to make
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modifications to table item passed back in the lh_doall() or
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lh_doall_arg() callbacks (see the "STUFF_cleanup" example above). If
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so, the caller can either cast the "const" away (if they're providing
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the raw callbacks themselves) or use the macros to declare/implement
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the wrapper functions without "const" types.
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Callers that only have "const" access to data they're indexing in a
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table, yet declare callbacks without constant types (or cast the
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"const" away themselves), are therefore creating their own risks/bugs
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without being encouraged to do so by the API. On a related note,
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those auditing code should pay special attention to any instances of
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DECLARE/IMPLEMENT_LHASH_DOALL_[ARG_]_FN macros that provide types
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without any "const" qualifiers.
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=head1 BUGS
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lh_insert() returns B<NULL> both for success and error.
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=head1 INTERNALS
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The following description is based on the SSLeay documentation:
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The B<lhash> library implements a hash table described in the
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I<Communications of the ACM> in 1991. What makes this hash table
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different is that as the table fills, the hash table is increased (or
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decreased) in size via OPENSSL_realloc(). When a 'resize' is done, instead of
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all hashes being redistributed over twice as many 'buckets', one
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bucket is split. So when an 'expand' is done, there is only a minimal
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cost to redistribute some values. Subsequent inserts will cause more
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single 'bucket' redistributions but there will never be a sudden large
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cost due to redistributing all the 'buckets'.
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The state for a particular hash table is kept in the B<LHASH> structure.
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The decision to increase or decrease the hash table size is made
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depending on the 'load' of the hash table. The load is the number of
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items in the hash table divided by the size of the hash table. The
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default values are as follows. If (hash->up_load E<lt> load) =E<gt>
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expand. if (hash-E<gt>down_load E<gt> load) =E<gt> contract. The
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B<up_load> has a default value of 1 and B<down_load> has a default value
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of 2. These numbers can be modified by the application by just
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playing with the B<up_load> and B<down_load> variables. The 'load' is
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kept in a form which is multiplied by 256. So
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hash-E<gt>up_load=8*256; will cause a load of 8 to be set.
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If you are interested in performance the field to watch is
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num_comp_calls. The hash library keeps track of the 'hash' value for
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each item so when a lookup is done, the 'hashes' are compared, if
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there is a match, then a full compare is done, and
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hash-E<gt>num_comp_calls is incremented. If num_comp_calls is not equal
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to num_delete plus num_retrieve it means that your hash function is
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generating hashes that are the same for different values. It is
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probably worth changing your hash function if this is the case because
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even if your hash table has 10 items in a 'bucket', it can be searched
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with 10 B<unsigned long> compares and 10 linked list traverses. This
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will be much less expensive that 10 calls to your compare function.
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lh_strhash() is a demo string hashing function:
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unsigned long lh_strhash(const char *c);
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Since the B<LHASH> routines would normally be passed structures, this
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routine would not normally be passed to lh_new(), rather it would be
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used in the function passed to lh_new().
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=head1 SEE ALSO
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L<lh_stats(3)|lh_stats(3)>
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=head1 HISTORY
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The B<lhash> library is available in all versions of SSLeay and OpenSSL.
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lh_error() was added in SSLeay 0.9.1b.
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This manpage is derived from the SSLeay documentation.
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In OpenSSL 0.9.7, all lhash functions that were passed function pointers
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were changed for better type safety, and the function types LHASH_COMP_FN_TYPE,
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LHASH_HASH_FN_TYPE, LHASH_DOALL_FN_TYPE and LHASH_DOALL_ARG_FN_TYPE
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became available.
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=cut
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