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pacman/lib/libalpm/alpm_list.c

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/*
* alpm_list.c
*
* Copyright (c) 2002-2007 by Judd Vinet <jvinet@zeroflux.org>
*
* This program 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.
*
* This program 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 this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "config.h"
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
/* libalpm */
#include "alpm_list.h"
#include "util.h"
/**
* @addtogroup alpm_list List Functions
* @brief Functions to manipulate alpm_list_t lists.
*
* These functions are designed to create, destroy, and modify lists of
* type alpm_list_t. This is an internal list type used by libalpm that is
* publicly exposed for use by frontends if desired.
*
* @{ */
/* Allocation */
/**
* @brief Allocate a new alpm_list_t.
*
* @return a new alpm_list_t item, or NULL on failure
*/
alpm_list_t SYMEXPORT *alpm_list_new()
{
alpm_list_t *list = NULL;
list = malloc(sizeof(alpm_list_t));
if(list) {
list->data = NULL;
list->prev = list; /* maintain a back reference to the tail pointer */
list->next = NULL;
}
return(list);
}
/**
* @brief Free a list, but not the contained data.
*
* @param list the list to free
*/
void SYMEXPORT alpm_list_free(alpm_list_t *list)
{
alpm_list_t *it = list;
while(it) {
alpm_list_t *tmp = it->next;
free(it);
it = tmp;
}
}
/**
* @brief Free the internal data of a list structure.
*
* @param list the list to free
* @param fn a free function for the internal data
*/
void SYMEXPORT alpm_list_free_inner(alpm_list_t *list, alpm_list_fn_free fn)
{
alpm_list_t *it = list;
while(it) {
if(fn && it->data) {
fn(it->data);
}
it = it->next;
}
}
/* Mutators */
/**
* @brief Add a new item to the end of the list.
*
* @param list the list to add to
* @param data the new item to be added to the list
*
* @return the resultant list
*/
alpm_list_t SYMEXPORT *alpm_list_add(alpm_list_t *list, void *data)
{
alpm_list_t *ptr, *lp;
ptr = list;
if(ptr == NULL) {
ptr = alpm_list_new();
if(ptr == NULL) {
return(NULL);
}
}
lp = alpm_list_last(ptr);
if(lp == ptr && lp->data == NULL) {
/* nada */
} else {
lp->next = alpm_list_new();
if(lp->next == NULL) {
return(NULL);
}
lp->next->prev = lp;
lp = lp->next;
list->prev = lp;
}
lp->data = data;
return(ptr);
}
/**
* @brief Add items to a list in sorted order.
*
* @param list the list to add to
* @param data the new item to be added to the list
* @param fn the comparison function to use to determine order
*
* @return the resultant list
*/
alpm_list_t SYMEXPORT *alpm_list_add_sorted(alpm_list_t *list, void *data, alpm_list_fn_cmp fn)
{
if(!fn) {
return alpm_list_add(list, data);
} else {
alpm_list_t *add = NULL, *prev = NULL, *next = list;
add = alpm_list_new();
add->data = data;
/* Find insertion point. */
while(next) {
if(fn(add->data, next->data) <= 0) break;
prev = next;
next = next->next;
}
/* Insert node before insertion point. */
add->prev = prev;
add->next = next;
if(next != NULL) {
next->prev = add; /* Not at end. */
}
if(prev != NULL) {
prev->next = add; /* In middle. */
} else {
list = add; /* At beginning, or new list */
}
if(next == NULL) {
/* At end, adjust tail pointer on head node */
list->prev = add;
}
return(list);
}
}
/**
* @brief Join two lists.
* The two lists must be independent. Do not free the original lists after
* calling this function, as this is not a copy operation. The list pointers
* passed in should be considered invalid after calling this function.
*
* @param first the first list
* @param second the second list
*
* @return the resultant joined list
*/
alpm_list_t SYMEXPORT *alpm_list_join(alpm_list_t *first, alpm_list_t *second)
{
alpm_list_t *tmp;
if (first == NULL) {
return second;
}
if (second == NULL) {
return first;
}
/* tmp is the last element of the first list */
tmp = first->prev;
/* link the first list to the second */
tmp->next = second;
/* link the second list to the first */
first->prev = second->prev;
/* set the back reference to the tail */
second->prev = tmp;
return(first);
}
/**
* @brief Merge the two sorted sublists into one sorted list.
*
* @param left the first list
* @param right the second list
* @param fn comparison function for determining merge order
*
* @return the resultant list
*/
alpm_list_t SYMEXPORT *alpm_list_mmerge(alpm_list_t *left, alpm_list_t *right, alpm_list_fn_cmp fn)
{
alpm_list_t *newlist, *lp;
if (left == NULL)
return right;
if (right == NULL)
return left;
if (fn(left->data, right->data) <= 0) {
newlist = left;
left = left->next;
}
else {
newlist = right;
right = right->next;
}
newlist->prev = NULL;
newlist->next = NULL;
lp = newlist;
while ((left != NULL) && (right != NULL)) {
if (fn(left->data, right->data) <= 0) {
lp->next = left;
left->prev = lp;
left = left->next;
}
else {
lp->next = right;
right->prev = lp;
right = right->next;
}
lp = lp->next;
lp->next = NULL;
}
if (left != NULL) {
lp->next = left;
left->prev = lp;
}
else if (right != NULL) {
lp->next = right;
right->prev = lp;
}
/* Find our tail pointer
* TODO maintain this in the algorithm itself */
lp = newlist;
while(lp && lp->next) {
lp = lp->next;
}
newlist->prev = lp;
return(newlist);
}
/**
* @brief Sort a list of size `n` using mergesort algorithm.
*
* @param list the list to sort
* @param n the size of the list
* @param fn the comparison function for determining order
*
* @return the resultant list
*/
alpm_list_t SYMEXPORT *alpm_list_msort(alpm_list_t *list, int n, alpm_list_fn_cmp fn)
{
if (n > 1) {
alpm_list_t *left = list;
alpm_list_t *lastleft = alpm_list_nth(list, n/2 - 1);
alpm_list_t *right = lastleft->next;
/* terminate first list */
lastleft->next = NULL;
left = alpm_list_msort(left, n/2, fn);
right = alpm_list_msort(right, n - (n/2), fn);
list = alpm_list_mmerge(left, right, fn);
}
return(list);
}
/**
* @brief Remove an item from the list.
*
* @param haystack the list to remove the item from
* @param needle the data member of the item we're removing
* @param fn the comparison function for searching
* @param data output parameter containing data of the removed item
*
* @return the resultant list
*/
alpm_list_t SYMEXPORT *alpm_list_remove(alpm_list_t *haystack, const void *needle, alpm_list_fn_cmp fn, void **data)
{
alpm_list_t *i = haystack, *tmp = NULL;
if(data) {
*data = NULL;
}
while(i) {
if(i->data == NULL) {
continue;
}
tmp = i->next;
if(fn(needle, i->data) == 0) {
/* we found a matching item */
if(i == haystack) {
/* Special case: removing the head node which has a back reference to
* the tail node */
haystack = i->next;
if(haystack) {
haystack->prev = i->prev;
}
i->prev = NULL;
} else if(i == haystack->prev) {
/* Special case: removing the tail node, so we need to fix the back
* reference on the head node. We also know tail != head. */
if(i->prev) {
/* i->next should always be null */
i->prev->next = i->next;
haystack->prev = i->prev;
i->prev = NULL;
}
} else {
/* Normal case, non-head and non-tail node */
if(i->next) {
i->next->prev = i->prev;
}
if(i->prev) {
i->prev->next = i->next;
}
}
if(data) {
*data = i->data;
}
i->data = NULL;
free(i);
i = NULL;
} else {
i = tmp;
}
}
return(haystack);
}
/**
* @brief Create a new list without any duplicates.
*
* This does NOT copy data members.
*
* @param list the list to copy
*
* @return a new list containing non-duplicate items
*/
alpm_list_t SYMEXPORT *alpm_list_remove_dupes(const alpm_list_t *list)
{
const alpm_list_t *lp = list;
alpm_list_t *newlist = NULL;
while(lp) {
if(!alpm_list_find_ptr(newlist, lp->data)) {
newlist = alpm_list_add(newlist, lp->data);
}
lp = lp->next;
}
return(newlist);
}
/**
* @brief Copy a string list, including data.
*
* @param list the list to copy
*
* @return a copy of the original list
*/
alpm_list_t SYMEXPORT *alpm_list_strdup(const alpm_list_t *list)
{
const alpm_list_t *lp = list;
alpm_list_t *newlist = NULL;
while(lp) {
newlist = alpm_list_add(newlist, strdup(lp->data));
lp = lp->next;
}
return(newlist);
}
/**
* @brief Copy a list, without copying data.
*
* @param list the list to copy
*
* @return a copy of the original list
*/
alpm_list_t SYMEXPORT *alpm_list_copy(const alpm_list_t *list)
{
const alpm_list_t *lp = list;
alpm_list_t *newlist = NULL;
while(lp) {
newlist = alpm_list_add(newlist, lp->data);
lp = lp->next;
}
return(newlist);
}
/**
* @brief Copy a list and copy the data.
* Note that the data elements to be copied should not contain pointers
* and should also be of constant size.
*
* @param list the list to copy
* @param size the size of each data element
*
* @return a copy of the original list, data copied as well
*/
alpm_list_t SYMEXPORT *alpm_list_copy_data(const alpm_list_t *list,
size_t size)
{
const alpm_list_t *lp = list;
alpm_list_t *newlist = NULL;
while(lp) {
void *newdata = calloc(1, size);
if(newdata) {
memcpy(newdata, lp->data, size);
newlist = alpm_list_add(newlist, newdata);
lp = lp->next;
}
}
return(newlist);
}
/**
* @brief Create a new list in reverse order.
*
* @param list the list to copy
*
* @return a new list in reverse order
*/
alpm_list_t SYMEXPORT *alpm_list_reverse(alpm_list_t *list)
{
const alpm_list_t *lp;
alpm_list_t *newlist = NULL;
lp = alpm_list_last(list);
if(list) {
/* break our reverse circular list */
list->prev = NULL;
}
while(lp) {
newlist = alpm_list_add(newlist, lp->data);
lp = lp->prev;
}
return(newlist);
}
/* Accessors */
/**
* @brief Get the first element of a list.
*
* @param list the list
*
* @return the first element in the list
*/
inline alpm_list_t SYMEXPORT *alpm_list_first(const alpm_list_t *list)
{
return((alpm_list_t*)list);
}
/**
* @brief Return nth element from list (starting from 0).
*
* @param list the list
* @param n the index of the item to find
*
* @return an alpm_list_t node for index `n`
*/
alpm_list_t SYMEXPORT *alpm_list_nth(const alpm_list_t *list, int n)
{
const alpm_list_t *i = list;
while(n--) {
i = i->next;
}
return((alpm_list_t*)i);
}
/**
* @brief Get the next element of a list.
*
* @param node the list node
*
* @return the next element, or NULL when no more elements exist
*/
inline alpm_list_t SYMEXPORT *alpm_list_next(const alpm_list_t *node)
{
return(node->next);
}
/**
* @brief Get the last item in the list.
*
* @param list the list
*
* @return the last element in the list
*/
alpm_list_t SYMEXPORT *alpm_list_last(const alpm_list_t *list)
{
if(list) {
return(list->prev);
} else {
return(NULL);
}
}
/**
* @brief Get the data member of a list node.
*
* @param node the list node
*
* @return the contained data, or NULL if none
*/
void SYMEXPORT *alpm_list_getdata(const alpm_list_t *node)
{
if(node == NULL) return(NULL);
return(node->data);
}
/* Misc */
/**
* @brief Get the number of items in a list.
*
* @param list the list
*
* @return the number of list items
*/
int SYMEXPORT alpm_list_count(const alpm_list_t *list)
{
unsigned int i = 0;
const alpm_list_t *lp = list;
while(lp) {
++i;
lp = lp->next;
}
return(i);
}
/**
* @brief Find an item in a list.
*
* @param needle the item to search
* @param haystack the list
* @param fn the comparison function for searching (!= NULL)
*
* @return `needle` if found, NULL otherwise
*/
void SYMEXPORT *alpm_list_find(const alpm_list_t *haystack, const void *needle,
alpm_list_fn_cmp fn)
{
const alpm_list_t *lp = haystack;
while(lp) {
if(lp->data && fn(lp->data, needle) == 0) {
return(lp->data);
}
lp = lp->next;
}
return(NULL);
}
/* trivial helper function for alpm_list_find_ptr */
static int ptrcmp(const void *p, const void *q)
{
return(p != q);
}
/**
* @brief Find an item in a list.
*
* Search for the item whos data matches that of the `needle`.
*
* @param needle the data to search for (== comparison)
* @param haystack the list
*
* @return `needle` if found, NULL otherwise
*/
void SYMEXPORT *alpm_list_find_ptr(const alpm_list_t *haystack, const void *needle)
{
return(alpm_list_find(haystack, needle, ptrcmp));
}
/**
* @brief Find a string in a list.
*
* @param needle the string to search for
* @param haystack the list
*
* @return `needle` if found, NULL otherwise
*/
char SYMEXPORT *alpm_list_find_str(const alpm_list_t *haystack, const char *needle)
{
return((char *)alpm_list_find(haystack, (const void*)needle, (alpm_list_fn_cmp)strcmp));
}
/**
* @brief Find the items in list `lhs` that are not present in list `rhs`.
*
* Entries are not duplicated. Operation is O(m*n). The first list is stepped
* through one node at a time, and for each node in the first list, each node
* in the second list is compared to it.
*
* @param lhs the first list
* @param rhs the second list
* @param fn the comparison function
*
* @return a list containing all items in `lhs` not present in `rhs`
*/
alpm_list_t SYMEXPORT *alpm_list_diff(const alpm_list_t *lhs,
const alpm_list_t *rhs, alpm_list_fn_cmp fn)
{
const alpm_list_t *i, *j;
alpm_list_t *ret = NULL;
for(i = lhs; i; i = i->next) {
int found = 0;
for(j = rhs; j; j = j->next) {
if(fn(i->data, j->data) == 0) {
found = 1;
break;
}
}
if(!found) {
ret = alpm_list_add(ret, i->data);
}
}
return(ret);
}
/** @} */
/* vim: set ts=2 sw=2 noet: */