mirror_zfs/lib/list.c
Brian Behlendorf 16b719f006 Allow spl_config.h to be included by dependant packages (updated)
We need dependent packages to be able to include spl_config.h to
build properly.  This was partially solved in commit 0cbaeb1 by using
AH_BOTTOM to #undef common #defines (PACKAGE, VERSION, etc) which
autoconf always adds and cannot be easily removed.  This solution
works as long as the spl_config.h is included before your projects
config.h.  That turns out to be easier said than done.  In particular,
this is a problem when your package includes its config.h using the
-include gcc option which ensures the first thing included is your
config.h.

To handle all cases cleanly I have removed the AH_BOTTOM hack and
replaced it with an AC_CONFIG_HEADERS command.  This command runs
immediately after spl_config.h is written and with a little awk-foo
it strips the offending #defines from the file.  This eliminates
the problem entirely and makes header safe for inclusion.

Also in this change I have removed the few places in the code where
spl_config.h is included.  It is now added to the gcc compile line
to ensure the config results are always available.

Finally, I have also disabled the verbose kernel builds.  If you
want them back you can always build with 'make V=1'.  Since things
are working now they don't need to be on by default.
2010-03-22 14:45:33 -07:00

830 lines
20 KiB
C

/*****************************************************************************
* $Id: list.c 3709 2006-11-29 00:51:22Z dun $
*****************************************************************************
* Copyright (C) 2001-2002 The Regents of the University of California.
* Produced at Lawrence Livermore National Laboratory (cf, DISCLAIMER).
* Written by Chris Dunlap <cdunlap@llnl.gov>.
*
* This file is from LSD-Tools, the LLNL Software Development Toolbox.
*
* LSD-Tools is free software; you can redistribute it and/or modify it under
* the terms of the GNU General Public License as published by the Free
* Software Foundation; either version 2 of the License, or (at your option)
* any later version.
*
* LSD-Tools is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along
* with LSD-Tools; if not, write to the Free Software Foundation, Inc.,
* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
*****************************************************************************
* Refer to "list.h" for documentation on public functions.
*****************************************************************************/
#ifdef WITH_PTHREADS
# include <pthread.h>
#endif /* WITH_PTHREADS */
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include "list.h"
/*********************
* lsd_fatal_error *
*********************/
#ifdef WITH_LSD_FATAL_ERROR_FUNC
# undef lsd_fatal_error
extern void lsd_fatal_error(char *file, int line, char *mesg);
#else /* !WITH_LSD_FATAL_ERROR_FUNC */
# ifndef lsd_fatal_error
# include <errno.h>
# include <stdio.h>
# include <string.h>
# define lsd_fatal_error(file, line, mesg) \
do { \
fprintf(stderr, "ERROR: [%s:%d] %s: %s\n", \
file, line, mesg, strerror(errno)); \
} while (0)
# endif /* !lsd_fatal_error */
#endif /* !WITH_LSD_FATAL_ERROR_FUNC */
/*********************
* lsd_nomem_error *
*********************/
#ifdef WITH_LSD_NOMEM_ERROR_FUNC
# undef lsd_nomem_error
extern void * lsd_nomem_error(char *file, int line, char *mesg);
#else /* !WITH_LSD_NOMEM_ERROR_FUNC */
# ifndef lsd_nomem_error
# define lsd_nomem_error(file, line, mesg) (NULL)
# endif /* !lsd_nomem_error */
#endif /* !WITH_LSD_NOMEM_ERROR_FUNC */
/***************
* Constants *
***************/
#define LIST_ALLOC 32
#define LIST_MAGIC 0xDEADBEEF
/****************
* Data Types *
****************/
struct listNode {
void *data; /* node's data */
struct listNode *next; /* next node in list */
};
struct listIterator {
struct list *list; /* the list being iterated */
struct listNode *pos; /* the next node to be iterated */
struct listNode **prev; /* addr of 'next' ptr to prv It node */
struct listIterator *iNext; /* iterator chain for list_destroy() */
#ifndef NDEBUG
unsigned int magic; /* sentinel for asserting validity */
#endif /* !NDEBUG */
};
struct list {
struct listNode *head; /* head of the list */
struct listNode **tail; /* addr of last node's 'next' ptr */
struct listIterator *iNext; /* iterator chain for list_destroy() */
ListDelF fDel; /* function to delete node data */
int count; /* number of nodes in list */
#ifdef WITH_PTHREADS
pthread_mutex_t mutex; /* mutex to protect access to list */
#endif /* WITH_PTHREADS */
#ifndef NDEBUG
unsigned int magic; /* sentinel for asserting validity */
#endif /* !NDEBUG */
};
typedef struct listNode * ListNode;
/****************
* Prototypes *
****************/
static void * list_node_create (List l, ListNode *pp, void *x);
static void * list_node_destroy (List l, ListNode *pp);
static List list_alloc (void);
static void list_free (List l);
static ListNode list_node_alloc (void);
static void list_node_free (ListNode p);
static ListIterator list_iterator_alloc (void);
static void list_iterator_free (ListIterator i);
static void * list_alloc_aux (int size, void *pfreelist);
static void list_free_aux (void *x, void *pfreelist);
/***************
* Variables *
***************/
static List list_free_lists = NULL;
static ListNode list_free_nodes = NULL;
static ListIterator list_free_iterators = NULL;
#ifdef WITH_PTHREADS
static pthread_mutex_t list_free_lock = PTHREAD_MUTEX_INITIALIZER;
#endif /* WITH_PTHREADS */
/************
* Macros *
************/
#ifdef WITH_PTHREADS
# define list_mutex_init(mutex) \
do { \
int e = pthread_mutex_init(mutex, NULL); \
if (e != 0) { \
errno = e; \
lsd_fatal_error(__FILE__, __LINE__, "list mutex init"); \
abort(); \
} \
} while (0)
# define list_mutex_lock(mutex) \
do { \
int e = pthread_mutex_lock(mutex); \
if (e != 0) { \
errno = e; \
lsd_fatal_error(__FILE__, __LINE__, "list mutex lock"); \
abort(); \
} \
} while (0)
# define list_mutex_unlock(mutex) \
do { \
int e = pthread_mutex_unlock(mutex); \
if (e != 0) { \
errno = e; \
lsd_fatal_error(__FILE__, __LINE__, "list mutex unlock"); \
abort(); \
} \
} while (0)
# define list_mutex_destroy(mutex) \
do { \
int e = pthread_mutex_destroy(mutex); \
if (e != 0) { \
errno = e; \
lsd_fatal_error(__FILE__, __LINE__, "list mutex destroy"); \
abort(); \
} \
} while (0)
# ifndef NDEBUG
static int list_mutex_is_locked (pthread_mutex_t *mutex);
# endif /* !NDEBUG */
#else /* !WITH_PTHREADS */
# define list_mutex_init(mutex)
# define list_mutex_lock(mutex)
# define list_mutex_unlock(mutex)
# define list_mutex_destroy(mutex)
# define list_mutex_is_locked(mutex) (1)
#endif /* !WITH_PTHREADS */
/***************
* Functions *
***************/
List
list_create (ListDelF f)
{
List l;
if (!(l = list_alloc()))
return(lsd_nomem_error(__FILE__, __LINE__, "list create"));
l->head = NULL;
l->tail = &l->head;
l->iNext = NULL;
l->fDel = f;
l->count = 0;
list_mutex_init(&l->mutex);
assert(l->magic = LIST_MAGIC); /* set magic via assert abuse */
return(l);
}
void
list_destroy (List l)
{
ListIterator i, iTmp;
ListNode p, pTmp;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
i = l->iNext;
while (i) {
assert(i->magic == LIST_MAGIC);
iTmp = i->iNext;
assert(i->magic = ~LIST_MAGIC); /* clear magic via assert abuse */
list_iterator_free(i);
i = iTmp;
}
p = l->head;
while (p) {
pTmp = p->next;
if (p->data && l->fDel)
l->fDel(p->data);
list_node_free(p);
p = pTmp;
}
assert(l->magic = ~LIST_MAGIC); /* clear magic via assert abuse */
list_mutex_unlock(&l->mutex);
list_mutex_destroy(&l->mutex);
list_free(l);
return;
}
int
list_is_empty (List l)
{
int n;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
n = l->count;
list_mutex_unlock(&l->mutex);
return(n == 0);
}
int
list_count (List l)
{
int n;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
n = l->count;
list_mutex_unlock(&l->mutex);
return(n);
}
void *
list_append (List l, void *x)
{
void *v;
assert(l != NULL);
assert(x != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_create(l, l->tail, x);
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_prepend (List l, void *x)
{
void *v;
assert(l != NULL);
assert(x != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_create(l, &l->head, x);
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_find_first (List l, ListFindF f, void *key)
{
ListNode p;
void *v = NULL;
assert(l != NULL);
assert(f != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
for (p=l->head; p; p=p->next) {
if (f(p->data, key)) {
v = p->data;
break;
}
}
list_mutex_unlock(&l->mutex);
return(v);
}
int
list_delete_all (List l, ListFindF f, void *key)
{
ListNode *pp;
void *v;
int n = 0;
assert(l != NULL);
assert(f != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
pp = &l->head;
while (*pp) {
if (f((*pp)->data, key)) {
if ((v = list_node_destroy(l, pp))) {
if (l->fDel)
l->fDel(v);
n++;
}
}
else {
pp = &(*pp)->next;
}
}
list_mutex_unlock(&l->mutex);
return(n);
}
int
list_for_each (List l, ListForF f, void *arg)
{
ListNode p;
int n = 0;
assert(l != NULL);
assert(f != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
for (p=l->head; p; p=p->next) {
n++;
if (f(p->data, arg) < 0) {
n = -n;
break;
}
}
list_mutex_unlock(&l->mutex);
return(n);
}
void
list_sort (List l, ListCmpF f)
{
/* Note: Time complexity O(n^2).
*/
ListNode *pp, *ppPrev, *ppPos, pTmp;
ListIterator i;
assert(l != NULL);
assert(f != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
if (l->count > 1) {
ppPrev = &l->head;
pp = &(*ppPrev)->next;
while (*pp) {
if (f((*pp)->data, (*ppPrev)->data) < 0) {
ppPos = &l->head;
while (f((*pp)->data, (*ppPos)->data) >= 0)
ppPos = &(*ppPos)->next;
pTmp = (*pp)->next;
(*pp)->next = *ppPos;
*ppPos = *pp;
*pp = pTmp;
if (ppPrev == ppPos)
ppPrev = &(*ppPrev)->next;
}
else {
ppPrev = pp;
pp = &(*pp)->next;
}
}
l->tail = pp;
for (i=l->iNext; i; i=i->iNext) {
assert(i->magic == LIST_MAGIC);
i->pos = i->list->head;
i->prev = &i->list->head;
}
}
list_mutex_unlock(&l->mutex);
return;
}
void *
list_push (List l, void *x)
{
void *v;
assert(l != NULL);
assert(x != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_create(l, &l->head, x);
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_pop (List l)
{
void *v;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_destroy(l, &l->head);
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_peek (List l)
{
void *v;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = (l->head) ? l->head->data : NULL;
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_enqueue (List l, void *x)
{
void *v;
assert(l != NULL);
assert(x != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_create(l, l->tail, x);
list_mutex_unlock(&l->mutex);
return(v);
}
void *
list_dequeue (List l)
{
void *v;
assert(l != NULL);
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
v = list_node_destroy(l, &l->head);
list_mutex_unlock(&l->mutex);
return(v);
}
ListIterator
list_iterator_create (List l)
{
ListIterator i;
assert(l != NULL);
if (!(i = list_iterator_alloc()))
return(lsd_nomem_error(__FILE__, __LINE__, "list iterator create"));
i->list = l;
list_mutex_lock(&l->mutex);
assert(l->magic == LIST_MAGIC);
i->pos = l->head;
i->prev = &l->head;
i->iNext = l->iNext;
l->iNext = i;
assert(i->magic = LIST_MAGIC); /* set magic via assert abuse */
list_mutex_unlock(&l->mutex);
return(i);
}
void
list_iterator_reset (ListIterator i)
{
assert(i != NULL);
assert(i->magic == LIST_MAGIC);
list_mutex_lock(&i->list->mutex);
assert(i->list->magic == LIST_MAGIC);
i->pos = i->list->head;
i->prev = &i->list->head;
list_mutex_unlock(&i->list->mutex);
return;
}
void
list_iterator_destroy (ListIterator i)
{
ListIterator *pi;
assert(i != NULL);
assert(i->magic == LIST_MAGIC);
list_mutex_lock(&i->list->mutex);
assert(i->list->magic == LIST_MAGIC);
for (pi=&i->list->iNext; *pi; pi=&(*pi)->iNext) {
assert((*pi)->magic == LIST_MAGIC);
if (*pi == i) {
*pi = (*pi)->iNext;
break;
}
}
list_mutex_unlock(&i->list->mutex);
assert(i->magic = ~LIST_MAGIC); /* clear magic via assert abuse */
list_iterator_free(i);
return;
}
void *
list_next (ListIterator i)
{
ListNode p;
assert(i != NULL);
assert(i->magic == LIST_MAGIC);
list_mutex_lock(&i->list->mutex);
assert(i->list->magic == LIST_MAGIC);
if ((p = i->pos))
i->pos = p->next;
if (*i->prev != p)
i->prev = &(*i->prev)->next;
list_mutex_unlock(&i->list->mutex);
return(p ? p->data : NULL);
}
void *
list_insert (ListIterator i, void *x)
{
void *v;
assert(i != NULL);
assert(x != NULL);
assert(i->magic == LIST_MAGIC);
list_mutex_lock(&i->list->mutex);
assert(i->list->magic == LIST_MAGIC);
v = list_node_create(i->list, i->prev, x);
list_mutex_unlock(&i->list->mutex);
return(v);
}
void *
list_find (ListIterator i, ListFindF f, void *key)
{
void *v;
assert(i != NULL);
assert(f != NULL);
assert(i->magic == LIST_MAGIC);
while ((v=list_next(i)) && !f(v,key)) {;}
return(v);
}
void *
list_remove (ListIterator i)
{
void *v = NULL;
assert(i != NULL);
assert(i->magic == LIST_MAGIC);
list_mutex_lock(&i->list->mutex);
assert(i->list->magic == LIST_MAGIC);
if (*i->prev != i->pos)
v = list_node_destroy(i->list, i->prev);
list_mutex_unlock(&i->list->mutex);
return(v);
}
int
list_delete (ListIterator i)
{
void *v;
assert(i != NULL);
assert(i->magic == LIST_MAGIC);
if ((v = list_remove(i))) {
if (i->list->fDel)
i->list->fDel(v);
return(1);
}
return(0);
}
static void *
list_node_create (List l, ListNode *pp, void *x)
{
/* Inserts data pointed to by [x] into list [l] after [pp],
* the address of the previous node's "next" ptr.
* Returns a ptr to data [x], or NULL if insertion fails.
* This routine assumes the list is already locked upon entry.
*/
ListNode p;
ListIterator i;
assert(l != NULL);
assert(l->magic == LIST_MAGIC);
assert(list_mutex_is_locked(&l->mutex));
assert(pp != NULL);
assert(x != NULL);
if (!(p = list_node_alloc()))
return(lsd_nomem_error(__FILE__, __LINE__, "list node create"));
p->data = x;
if (!(p->next = *pp))
l->tail = &p->next;
*pp = p;
l->count++;
for (i=l->iNext; i; i=i->iNext) {
assert(i->magic == LIST_MAGIC);
if (i->prev == pp)
i->prev = &p->next;
else if (i->pos == p->next)
i->pos = p;
assert((i->pos == *i->prev) || (i->pos == (*i->prev)->next));
}
return(x);
}
static void *
list_node_destroy (List l, ListNode *pp)
{
/* Removes the node pointed to by [*pp] from from list [l],
* where [pp] is the address of the previous node's "next" ptr.
* Returns the data ptr associated with list item being removed,
* or NULL if [*pp] points to the NULL element.
* This routine assumes the list is already locked upon entry.
*/
void *v;
ListNode p;
ListIterator i;
assert(l != NULL);
assert(l->magic == LIST_MAGIC);
assert(list_mutex_is_locked(&l->mutex));
assert(pp != NULL);
if (!(p = *pp))
return(NULL);
v = p->data;
if (!(*pp = p->next))
l->tail = pp;
l->count--;
for (i=l->iNext; i; i=i->iNext) {
assert(i->magic == LIST_MAGIC);
if (i->pos == p)
i->pos = p->next, i->prev = pp;
else if (i->prev == &p->next)
i->prev = pp;
assert((i->pos == *i->prev) || (i->pos == (*i->prev)->next));
}
list_node_free(p);
return(v);
}
static List
list_alloc (void)
{
return(list_alloc_aux(sizeof(struct list), &list_free_lists));
}
static void
list_free (List l)
{
list_free_aux(l, &list_free_lists);
return;
}
static ListNode
list_node_alloc (void)
{
return(list_alloc_aux(sizeof(struct listNode), &list_free_nodes));
}
static void
list_node_free (ListNode p)
{
list_free_aux(p, &list_free_nodes);
return;
}
static ListIterator
list_iterator_alloc (void)
{
return(list_alloc_aux(sizeof(struct listIterator), &list_free_iterators));
}
static void
list_iterator_free (ListIterator i)
{
list_free_aux(i, &list_free_iterators);
return;
}
static void *
list_alloc_aux (int size, void *pfreelist)
{
/* Allocates an object of [size] bytes from the freelist [*pfreelist].
* Memory is added to the freelist in chunks of size LIST_ALLOC.
* Returns a ptr to the object, or NULL if the memory request fails.
*/
void **px;
void **pfree = pfreelist;
void **plast;
assert(sizeof(char) == 1);
assert(size >= (int)sizeof(void *));
assert(pfreelist != NULL);
assert(LIST_ALLOC > 0);
list_mutex_lock(&list_free_lock);
if (!*pfree) {
if ((*pfree = malloc(LIST_ALLOC * size))) {
px = *pfree;
plast = (void **) ((char *) *pfree + ((LIST_ALLOC - 1) * size));
while (px < plast)
*px = (char *) px + size, px = *px;
*plast = NULL;
}
}
if ((px = *pfree))
*pfree = *px;
else
errno = ENOMEM;
list_mutex_unlock(&list_free_lock);
return(px);
}
static void
list_free_aux (void *x, void *pfreelist)
{
/* Frees the object [x], returning it to the freelist [*pfreelist].
*/
void **px = x;
void **pfree = pfreelist;
assert(x != NULL);
assert(pfreelist != NULL);
list_mutex_lock(&list_free_lock);
*px = *pfree;
*pfree = px;
list_mutex_unlock(&list_free_lock);
return;
}
#ifndef NDEBUG
#ifdef WITH_PTHREADS
static int
list_mutex_is_locked (pthread_mutex_t *mutex)
{
/* Returns true if the mutex is locked; o/w, returns false.
*/
int rc;
assert(mutex != NULL);
rc = pthread_mutex_trylock(mutex);
return(rc == EBUSY ? 1 : 0);
}
#endif /* WITH_PTHREADS */
#endif /* !NDEBUG */