hcreate, hdestroy, hsearch, hcreate_r, hdestroy_r, hsearch_r - hash table management
Standard C library (libc, -lc)
#include <search.h>
int hcreate(size_t nel);
void hdestroy(void);
ENTRY *hsearch(ENTRY item, ACTION action);
#define _GNU_SOURCE /* See feature_test_macros(7) */
#include <search.h>
int hcreate_r(size_t nel, struct hsearch_data *htab);
void hdestroy_r(struct hsearch_data *htab);
int hsearch_r(ENTRY item, ACTION action, ENTRY **retval,
struct hsearch_data *htab);The three functions hcreate(), hsearch(), and hdestroy() allow the caller to create and manage a hash search table containing entries consisting of a key (a string) and associated data. Using these functions, only one hash table can be used at a time.
The three functions hcreate_r(),
hsearch_r(), hdestroy_r() are
reentrant versions that allow a program to use more than one hash search
table at the same time. The last argument, htab, points to a
structure that describes the table on which the function is to operate.
The programmer should treat this structure as opaque (i.e., do not
attempt to directly access or modify the fields in this structure).
First a hash table must be created using hcreate().
The argument nel specifies the maximum number of entries in the
table. (This maximum cannot be changed later, so choose it wisely.) The
implementation may adjust this value upward to improve the performance
of the resulting hash table.
The hcreate_r() function performs the same task as
hcreate(), but for the table described by the structure
*htab. The structure pointed to by htab must be zeroed
before the first call to hcreate_r().
The function hdestroy() frees the memory occupied by
the hash table that was created by hcreate(). After
calling hdestroy(), a new hash table can be created
using hcreate(). The hdestroy_r()
function performs the analogous task for a hash table described by
*htab, which was previously created using
hcreate_r().
The hsearch() function searches the hash table for
an item with the same key as item (where "the same" is
determined using strcmp(3)), and if successful returns
a pointer to it.
The argument item is of type ENTRY, which is
defined in <search.h> as follows:
typedef struct entry {
char *key;
void *data;
} ENTRY;The field key points to a null-terminated string which is
the search key. The field data points to data that is
associated with that key.
The argument action determines what
hsearch() does after an unsuccessful search. This
argument must either have the value ENTER, meaning
insert a copy of item (and return a pointer to the new hash
table entry as the function result), or the value FIND,
meaning that NULL should be returned. (If action is
FIND, then data is ignored.)
The hsearch_r() function is like
hsearch() but operates on the hash table described by
*htab. The hsearch_r() function differs from
hsearch() in that a pointer to the found item is
returned in *retval, rather than as the function result.
hcreate() and hcreate_r() return
nonzero on success. They return 0 on error, with errno set to
indicate the error.
On success, hsearch() returns a pointer to an entry
in the hash table. hsearch() returns NULL on error,
that is, if action is ENTER and the hash table
is full, or action is FIND and item
cannot be found in the hash table. hsearch_r() returns
nonzero on success, and 0 on error. In the event of an error, these two
functions set errno to indicate the error.
The following program inserts 24 items into a hash table, then prints some of them.
#include <search.h>
#include <stdio.h>
#include <stdlib.h>
static char *data[] = { "alpha", "bravo", "charlie", "delta",
"echo", "foxtrot", "golf", "hotel", "india", "juliet",
"kilo", "lima", "mike", "november", "oscar", "papa",
"quebec", "romeo", "sierra", "tango", "uniform",
"victor", "whisky", "x-ray", "yankee", "zulu"
};
int
main(void)
{
ENTRY e;
ENTRY *ep;
hcreate(30);
for (size_t i = 0; i < 24; i++) {
e.key = data[i];
/* data is just an integer, instead of a
pointer to something */
e.data = (void *) i;
ep = hsearch(e, ENTER);
/* there should be no failures */
if (ep == NULL) {
fprintf(stderr, "entry failed\n");
exit(EXIT_FAILURE);
}
}
for (size_t i = 22; i < 26; i++) {
/* print two entries from the table, and
show that two are not in the table */
e.key = data[i];
ep = hsearch(e, FIND);
printf("%9.9s -> %9.9s:%d\n", e.key,
ep ? ep->key : "NULL", ep ? (int)(ep->data) : 0);
}
hdestroy();
exit(EXIT_SUCCESS);
}hcreate_r() and hdestroy_r() can fail for the following reasons:
htab is NULL.
hsearch() and hsearch_r() can fail for the following reasons:
action was ENTER, key was not
found in the table, and there was no room in the table to add a new
entry.
action was FIND, and key was not
found in the table.
POSIX.1 specifies only the ENOMEM error.
For an explanation of the terms used in this section, see attributes(7).
| Interface | Attribute | Value |
| Thread safety | MT-Unsafe race:hsearch | |
hcreate_r(), hsearch_r(), hdestroy_r() |
Thread safety | MT-Safe race:htab |
Hash table implementations are usually more efficient when the table
contains enough free space to minimize collisions. Typically, this means
that nel should be at least 25% larger than the maximum number
of elements that the caller expects to store in the table.
The hdestroy() and hdestroy_r()
functions do not free the buffers pointed to by the key and
data elements of the hash table entries. (It can't do this
because it doesn't know whether these buffers were allocated
dynamically.) If these buffers need to be freed (perhaps because the
program is repeatedly creating and destroying hash tables, rather than
creating a single table whose lifetime matches that of the program),
then the program must maintain bookkeeping data structures that allow it
to free them.
SVr4 and POSIX.1-2001 specify that action is significant
only for unsuccessful searches, so that an ENTER should
not do anything for a successful search. In libc and glibc (before glibc
2.3), the implementation violates the specification, updating the
data for the given key in this case.
Individual hash table entries can be added, but not deleted.