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patch 7.4.2057

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Problem:    eval.c is too big.
Solution:   Move List functions to list.c
This commit is contained in:
Bram Moolenaar
2016-07-17 15:46:27 +02:00
parent 1abc52c159
commit da861d631d
10 changed files with 940 additions and 892 deletions
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887
src/list.c Normal file
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@@ -0,0 +1,887 @@
/* vi:set ts=8 sts=4 sw=4:
*
* VIM - Vi IMproved by Bram Moolenaar
*
* Do ":help uganda" in Vim to read copying and usage conditions.
* Do ":help credits" in Vim to see a list of people who contributed.
* See README.txt for an overview of the Vim source code.
*/
/*
* list.c: List support
*/
#include "vim.h"
#if defined(FEAT_EVAL) || defined(PROTO)
/* List heads for garbage collection. */
static list_T *first_list = NULL; /* list of all lists */
/*
* Add a watcher to a list.
*/
void
list_add_watch(list_T *l, listwatch_T *lw)
{
lw->lw_next = l->lv_watch;
l->lv_watch = lw;
}
/*
* Remove a watcher from a list.
* No warning when it isn't found...
*/
void
list_rem_watch(list_T *l, listwatch_T *lwrem)
{
listwatch_T *lw, **lwp;
lwp = &l->lv_watch;
for (lw = l->lv_watch; lw != NULL; lw = lw->lw_next)
{
if (lw == lwrem)
{
*lwp = lw->lw_next;
break;
}
lwp = &lw->lw_next;
}
}
/*
* Just before removing an item from a list: advance watchers to the next
* item.
*/
void
list_fix_watch(list_T *l, listitem_T *item)
{
listwatch_T *lw;
for (lw = l->lv_watch; lw != NULL; lw = lw->lw_next)
if (lw->lw_item == item)
lw->lw_item = item->li_next;
}
/*
* Allocate an empty header for a list.
* Caller should take care of the reference count.
*/
list_T *
list_alloc(void)
{
list_T *l;
l = (list_T *)alloc_clear(sizeof(list_T));
if (l != NULL)
{
/* Prepend the list to the list of lists for garbage collection. */
if (first_list != NULL)
first_list->lv_used_prev = l;
l->lv_used_prev = NULL;
l->lv_used_next = first_list;
first_list = l;
}
return l;
}
/*
* Allocate an empty list for a return value, with reference count set.
* Returns OK or FAIL.
*/
int
rettv_list_alloc(typval_T *rettv)
{
list_T *l = list_alloc();
if (l == NULL)
return FAIL;
rettv->vval.v_list = l;
rettv->v_type = VAR_LIST;
rettv->v_lock = 0;
++l->lv_refcount;
return OK;
}
/*
* Unreference a list: decrement the reference count and free it when it
* becomes zero.
*/
void
list_unref(list_T *l)
{
if (l != NULL && --l->lv_refcount <= 0)
list_free(l);
}
/*
* Free a list, including all non-container items it points to.
* Ignores the reference count.
*/
static void
list_free_contents(list_T *l)
{
listitem_T *item;
for (item = l->lv_first; item != NULL; item = l->lv_first)
{
/* Remove the item before deleting it. */
l->lv_first = item->li_next;
clear_tv(&item->li_tv);
vim_free(item);
}
}
/*
* Go through the list of lists and free items without the copyID.
* But don't free a list that has a watcher (used in a for loop), these
* are not referenced anywhere.
*/
int
list_free_nonref(int copyID)
{
list_T *ll;
int did_free = FALSE;
for (ll = first_list; ll != NULL; ll = ll->lv_used_next)
if ((ll->lv_copyID & COPYID_MASK) != (copyID & COPYID_MASK)
&& ll->lv_watch == NULL)
{
/* Free the List and ordinary items it contains, but don't recurse
* into Lists and Dictionaries, they will be in the list of dicts
* or list of lists. */
list_free_contents(ll);
did_free = TRUE;
}
return did_free;
}
static void
list_free_list(list_T *l)
{
/* Remove the list from the list of lists for garbage collection. */
if (l->lv_used_prev == NULL)
first_list = l->lv_used_next;
else
l->lv_used_prev->lv_used_next = l->lv_used_next;
if (l->lv_used_next != NULL)
l->lv_used_next->lv_used_prev = l->lv_used_prev;
vim_free(l);
}
void
list_free_items(int copyID)
{
list_T *ll, *ll_next;
for (ll = first_list; ll != NULL; ll = ll_next)
{
ll_next = ll->lv_used_next;
if ((ll->lv_copyID & COPYID_MASK) != (copyID & COPYID_MASK)
&& ll->lv_watch == NULL)
{
/* Free the List and ordinary items it contains, but don't recurse
* into Lists and Dictionaries, they will be in the list of dicts
* or list of lists. */
list_free_list(ll);
}
}
}
void
list_free(list_T *l)
{
if (!in_free_unref_items)
{
list_free_contents(l);
list_free_list(l);
}
}
/*
* Allocate a list item.
* It is not initialized, don't forget to set v_lock.
*/
listitem_T *
listitem_alloc(void)
{
return (listitem_T *)alloc(sizeof(listitem_T));
}
/*
* Free a list item. Also clears the value. Does not notify watchers.
*/
void
listitem_free(listitem_T *item)
{
clear_tv(&item->li_tv);
vim_free(item);
}
/*
* Remove a list item from a List and free it. Also clears the value.
*/
void
listitem_remove(list_T *l, listitem_T *item)
{
vimlist_remove(l, item, item);
listitem_free(item);
}
/*
* Get the number of items in a list.
*/
long
list_len(list_T *l)
{
if (l == NULL)
return 0L;
return l->lv_len;
}
/*
* Return TRUE when two lists have exactly the same values.
*/
int
list_equal(
list_T *l1,
list_T *l2,
int ic, /* ignore case for strings */
int recursive) /* TRUE when used recursively */
{
listitem_T *item1, *item2;
if (l1 == NULL || l2 == NULL)
return FALSE;
if (l1 == l2)
return TRUE;
if (list_len(l1) != list_len(l2))
return FALSE;
for (item1 = l1->lv_first, item2 = l2->lv_first;
item1 != NULL && item2 != NULL;
item1 = item1->li_next, item2 = item2->li_next)
if (!tv_equal(&item1->li_tv, &item2->li_tv, ic, recursive))
return FALSE;
return item1 == NULL && item2 == NULL;
}
/*
* Locate item with index "n" in list "l" and return it.
* A negative index is counted from the end; -1 is the last item.
* Returns NULL when "n" is out of range.
*/
listitem_T *
list_find(list_T *l, long n)
{
listitem_T *item;
long idx;
if (l == NULL)
return NULL;
/* Negative index is relative to the end. */
if (n < 0)
n = l->lv_len + n;
/* Check for index out of range. */
if (n < 0 || n >= l->lv_len)
return NULL;
/* When there is a cached index may start search from there. */
if (l->lv_idx_item != NULL)
{
if (n < l->lv_idx / 2)
{
/* closest to the start of the list */
item = l->lv_first;
idx = 0;
}
else if (n > (l->lv_idx + l->lv_len) / 2)
{
/* closest to the end of the list */
item = l->lv_last;
idx = l->lv_len - 1;
}
else
{
/* closest to the cached index */
item = l->lv_idx_item;
idx = l->lv_idx;
}
}
else
{
if (n < l->lv_len / 2)
{
/* closest to the start of the list */
item = l->lv_first;
idx = 0;
}
else
{
/* closest to the end of the list */
item = l->lv_last;
idx = l->lv_len - 1;
}
}
while (n > idx)
{
/* search forward */
item = item->li_next;
++idx;
}
while (n < idx)
{
/* search backward */
item = item->li_prev;
--idx;
}
/* cache the used index */
l->lv_idx = idx;
l->lv_idx_item = item;
return item;
}
/*
* Get list item "l[idx]" as a number.
*/
long
list_find_nr(
list_T *l,
long idx,
int *errorp) /* set to TRUE when something wrong */
{
listitem_T *li;
li = list_find(l, idx);
if (li == NULL)
{
if (errorp != NULL)
*errorp = TRUE;
return -1L;
}
return (long)get_tv_number_chk(&li->li_tv, errorp);
}
/*
* Get list item "l[idx - 1]" as a string. Returns NULL for failure.
*/
char_u *
list_find_str(list_T *l, long idx)
{
listitem_T *li;
li = list_find(l, idx - 1);
if (li == NULL)
{
EMSGN(_(e_listidx), idx);
return NULL;
}
return get_tv_string(&li->li_tv);
}
/*
* Locate "item" list "l" and return its index.
* Returns -1 when "item" is not in the list.
*/
long
list_idx_of_item(list_T *l, listitem_T *item)
{
long idx = 0;
listitem_T *li;
if (l == NULL)
return -1;
idx = 0;
for (li = l->lv_first; li != NULL && li != item; li = li->li_next)
++idx;
if (li == NULL)
return -1;
return idx;
}
/*
* Append item "item" to the end of list "l".
*/
void
list_append(list_T *l, listitem_T *item)
{
if (l->lv_last == NULL)
{
/* empty list */
l->lv_first = item;
l->lv_last = item;
item->li_prev = NULL;
}
else
{
l->lv_last->li_next = item;
item->li_prev = l->lv_last;
l->lv_last = item;
}
++l->lv_len;
item->li_next = NULL;
}
/*
* Append typval_T "tv" to the end of list "l".
* Return FAIL when out of memory.
*/
int
list_append_tv(list_T *l, typval_T *tv)
{
listitem_T *li = listitem_alloc();
if (li == NULL)
return FAIL;
copy_tv(tv, &li->li_tv);
list_append(l, li);
return OK;
}
/*
* Add a dictionary to a list. Used by getqflist().
* Return FAIL when out of memory.
*/
int
list_append_dict(list_T *list, dict_T *dict)
{
listitem_T *li = listitem_alloc();
if (li == NULL)
return FAIL;
li->li_tv.v_type = VAR_DICT;
li->li_tv.v_lock = 0;
li->li_tv.vval.v_dict = dict;
list_append(list, li);
++dict->dv_refcount;
return OK;
}
/*
* Make a copy of "str" and append it as an item to list "l".
* When "len" >= 0 use "str[len]".
* Returns FAIL when out of memory.
*/
int
list_append_string(list_T *l, char_u *str, int len)
{
listitem_T *li = listitem_alloc();
if (li == NULL)
return FAIL;
list_append(l, li);
li->li_tv.v_type = VAR_STRING;
li->li_tv.v_lock = 0;
if (str == NULL)
li->li_tv.vval.v_string = NULL;
else if ((li->li_tv.vval.v_string = (len >= 0 ? vim_strnsave(str, len)
: vim_strsave(str))) == NULL)
return FAIL;
return OK;
}
/*
* Append "n" to list "l".
* Returns FAIL when out of memory.
*/
int
list_append_number(list_T *l, varnumber_T n)
{
listitem_T *li;
li = listitem_alloc();
if (li == NULL)
return FAIL;
li->li_tv.v_type = VAR_NUMBER;
li->li_tv.v_lock = 0;
li->li_tv.vval.v_number = n;
list_append(l, li);
return OK;
}
/*
* Insert typval_T "tv" in list "l" before "item".
* If "item" is NULL append at the end.
* Return FAIL when out of memory.
*/
int
list_insert_tv(list_T *l, typval_T *tv, listitem_T *item)
{
listitem_T *ni = listitem_alloc();
if (ni == NULL)
return FAIL;
copy_tv(tv, &ni->li_tv);
list_insert(l, ni, item);
return OK;
}
void
list_insert(list_T *l, listitem_T *ni, listitem_T *item)
{
if (item == NULL)
/* Append new item at end of list. */
list_append(l, ni);
else
{
/* Insert new item before existing item. */
ni->li_prev = item->li_prev;
ni->li_next = item;
if (item->li_prev == NULL)
{
l->lv_first = ni;
++l->lv_idx;
}
else
{
item->li_prev->li_next = ni;
l->lv_idx_item = NULL;
}
item->li_prev = ni;
++l->lv_len;
}
}
/*
* Extend "l1" with "l2".
* If "bef" is NULL append at the end, otherwise insert before this item.
* Returns FAIL when out of memory.
*/
int
list_extend(list_T *l1, list_T *l2, listitem_T *bef)
{
listitem_T *item;
int todo = l2->lv_len;
/* We also quit the loop when we have inserted the original item count of
* the list, avoid a hang when we extend a list with itself. */
for (item = l2->lv_first; item != NULL && --todo >= 0; item = item->li_next)
if (list_insert_tv(l1, &item->li_tv, bef) == FAIL)
return FAIL;
return OK;
}
/*
* Concatenate lists "l1" and "l2" into a new list, stored in "tv".
* Return FAIL when out of memory.
*/
int
list_concat(list_T *l1, list_T *l2, typval_T *tv)
{
list_T *l;
if (l1 == NULL || l2 == NULL)
return FAIL;
/* make a copy of the first list. */
l = list_copy(l1, FALSE, 0);
if (l == NULL)
return FAIL;
tv->v_type = VAR_LIST;
tv->vval.v_list = l;
/* append all items from the second list */
return list_extend(l, l2, NULL);
}
/*
* Make a copy of list "orig". Shallow if "deep" is FALSE.
* The refcount of the new list is set to 1.
* See item_copy() for "copyID".
* Returns NULL when out of memory.
*/
list_T *
list_copy(list_T *orig, int deep, int copyID)
{
list_T *copy;
listitem_T *item;
listitem_T *ni;
if (orig == NULL)
return NULL;
copy = list_alloc();
if (copy != NULL)
{
if (copyID != 0)
{
/* Do this before adding the items, because one of the items may
* refer back to this list. */
orig->lv_copyID = copyID;
orig->lv_copylist = copy;
}
for (item = orig->lv_first; item != NULL && !got_int;
item = item->li_next)
{
ni = listitem_alloc();
if (ni == NULL)
break;
if (deep)
{
if (item_copy(&item->li_tv, &ni->li_tv, deep, copyID) == FAIL)
{
vim_free(ni);
break;
}
}
else
copy_tv(&item->li_tv, &ni->li_tv);
list_append(copy, ni);
}
++copy->lv_refcount;
if (item != NULL)
{
list_unref(copy);
copy = NULL;
}
}
return copy;
}
/*
* Remove items "item" to "item2" from list "l".
* Does not free the listitem or the value!
* This used to be called list_remove, but that conflicts with a Sun header
* file.
*/
void
vimlist_remove(list_T *l, listitem_T *item, listitem_T *item2)
{
listitem_T *ip;
/* notify watchers */
for (ip = item; ip != NULL; ip = ip->li_next)
{
--l->lv_len;
list_fix_watch(l, ip);
if (ip == item2)
break;
}
if (item2->li_next == NULL)
l->lv_last = item->li_prev;
else
item2->li_next->li_prev = item->li_prev;
if (item->li_prev == NULL)
l->lv_first = item2->li_next;
else
item->li_prev->li_next = item2->li_next;
l->lv_idx_item = NULL;
}
/*
* Return an allocated string with the string representation of a list.
* May return NULL.
*/
char_u *
list2string(typval_T *tv, int copyID, int restore_copyID)
{
garray_T ga;
if (tv->vval.v_list == NULL)
return NULL;
ga_init2(&ga, (int)sizeof(char), 80);
ga_append(&ga, '[');
if (list_join(&ga, tv->vval.v_list, (char_u *)", ",
FALSE, restore_copyID, copyID) == FAIL)
{
vim_free(ga.ga_data);
return NULL;
}
ga_append(&ga, ']');
ga_append(&ga, NUL);
return (char_u *)ga.ga_data;
}
typedef struct join_S {
char_u *s;
char_u *tofree;
} join_T;
static int
list_join_inner(
garray_T *gap, /* to store the result in */
list_T *l,
char_u *sep,
int echo_style,
int restore_copyID,
int copyID,
garray_T *join_gap) /* to keep each list item string */
{
int i;
join_T *p;
int len;
int sumlen = 0;
int first = TRUE;
char_u *tofree;
char_u numbuf[NUMBUFLEN];
listitem_T *item;
char_u *s;
/* Stringify each item in the list. */
for (item = l->lv_first; item != NULL && !got_int; item = item->li_next)
{
s = echo_string_core(&item->li_tv, &tofree, numbuf, copyID,
echo_style, restore_copyID, FALSE);
if (s == NULL)
return FAIL;
len = (int)STRLEN(s);
sumlen += len;
(void)ga_grow(join_gap, 1);
p = ((join_T *)join_gap->ga_data) + (join_gap->ga_len++);
if (tofree != NULL || s != numbuf)
{
p->s = s;
p->tofree = tofree;
}
else
{
p->s = vim_strnsave(s, len);
p->tofree = p->s;
}
line_breakcheck();
if (did_echo_string_emsg) /* recursion error, bail out */
break;
}
/* Allocate result buffer with its total size, avoid re-allocation and
* multiple copy operations. Add 2 for a tailing ']' and NUL. */
if (join_gap->ga_len >= 2)
sumlen += (int)STRLEN(sep) * (join_gap->ga_len - 1);
if (ga_grow(gap, sumlen + 2) == FAIL)
return FAIL;
for (i = 0; i < join_gap->ga_len && !got_int; ++i)
{
if (first)
first = FALSE;
else
ga_concat(gap, sep);
p = ((join_T *)join_gap->ga_data) + i;
if (p->s != NULL)
ga_concat(gap, p->s);
line_breakcheck();
}
return OK;
}
/*
* Join list "l" into a string in "*gap", using separator "sep".
* When "echo_style" is TRUE use String as echoed, otherwise as inside a List.
* Return FAIL or OK.
*/
int
list_join(
garray_T *gap,
list_T *l,
char_u *sep,
int echo_style,
int restore_copyID,
int copyID)
{
garray_T join_ga;
int retval;
join_T *p;
int i;
if (l->lv_len < 1)
return OK; /* nothing to do */
ga_init2(&join_ga, (int)sizeof(join_T), l->lv_len);
retval = list_join_inner(gap, l, sep, echo_style, restore_copyID,
copyID, &join_ga);
/* Dispose each item in join_ga. */
if (join_ga.ga_data != NULL)
{
p = (join_T *)join_ga.ga_data;
for (i = 0; i < join_ga.ga_len; ++i)
{
vim_free(p->tofree);
++p;
}
ga_clear(&join_ga);
}
return retval;
}
/*
* Allocate a variable for a List and fill it from "*arg".
* Return OK or FAIL.
*/
int
get_list_tv(char_u **arg, typval_T *rettv, int evaluate)
{
list_T *l = NULL;
typval_T tv;
listitem_T *item;
if (evaluate)
{
l = list_alloc();
if (l == NULL)
return FAIL;
}
*arg = skipwhite(*arg + 1);
while (**arg != ']' && **arg != NUL)
{
if (eval1(arg, &tv, evaluate) == FAIL) /* recursive! */
goto failret;
if (evaluate)
{
item = listitem_alloc();
if (item != NULL)
{
item->li_tv = tv;
item->li_tv.v_lock = 0;
list_append(l, item);
}
else
clear_tv(&tv);
}
if (**arg == ']')
break;
if (**arg != ',')
{
EMSG2(_("E696: Missing comma in List: %s"), *arg);
goto failret;
}
*arg = skipwhite(*arg + 1);
}
if (**arg != ']')
{
EMSG2(_("E697: Missing end of List ']': %s"), *arg);
failret:
if (evaluate)
list_free(l);
return FAIL;
}
*arg = skipwhite(*arg + 1);
if (evaluate)
{
rettv->v_type = VAR_LIST;
rettv->vval.v_list = l;
++l->lv_refcount;
}
return OK;
}
#endif /* defined(FEAT_MODIFY_FNAME) || defined(FEAT_EVAL) */