kicad/potrace/lists.h

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/* Copyright (C) 2001-2015 Peter Selinger.
* This file is part of Potrace. It is free software and it is covered
* by the GNU General Public License. See the file COPYING for details. */
#ifndef _PS_LISTS_H
#define _PS_LISTS_H
/* here we define some general list macros. Because they are macros,
* they should work on any datatype with a "->next" component. Some of
* them use a "hook". If elt and list are of type t* then hook is of
* type t**. A hook stands for an insertion point in the list, i.e.,
* either before the first element, or between two elements, or after
* the last element. If an operation "sets the hook" for an element,
* then the hook is set to just before the element. One can insert
* something at a hook. One can also unlink at a hook: this means,
* unlink the element just after the hook. By "to unlink", we mean the
* element is removed from the list, but not deleted. Thus, it and its
* components still need to be freed. */
/* Note: these macros are somewhat experimental. Only the ones that
* are actually *used* have been tested. So be careful to test any
* that you use. Looking at the output of the preprocessor, "gcc -E"
* (possibly piped though "indent"), might help too. Also: these
* macros define some internal (local) variables that start with
* "_". */
/* we enclose macro definitions whose body consists of more than one
* statement in MACRO_BEGIN and MACRO_END, rather than '{' and '}'. The
* reason is that we want to be able to use the macro in a context
* such as "if (...) macro(...); else ...". If we didn't use this obscure
* trick, we'd have to omit the ";" in such cases. */
#define MACRO_BEGIN do {
#define MACRO_END } \
while( 0 )
/* ---------------------------------------------------------------------- */
/* macros for singly-linked lists */
/* traverse list. At the end, elt is set to NULL. */
#define list_forall( elt, list ) for( elt = list; elt!=NULL; elt = elt->next )
/* set elt to the first element of list satisfying boolean condition
* c, or NULL if not found */
#define list_find( elt, list, c ) \
MACRO_BEGIN list_forall( elt, list ) if( c ) \
break; \
MACRO_END
/* like forall, except also set hook for elt. */
#define list_forall2( elt, list, hook ) \
for( elt = list, hook = &list; elt!=NULL; hook = &elt->next, elt = elt->next )
/* same as list_find, except also set hook for elt. */
#define list_find2( elt, list, c, hook ) \
MACRO_BEGIN list_forall2( elt, list, hook ) if( c ) \
break; \
MACRO_END
/* same, except only use hook. */
#define _list_forall_hook( list, hook ) \
for( hook = &list; *hook!=NULL; hook = &(*hook)->next )
/* same, except only use hook. Note: c may only refer to *hook, not elt. */
#define _list_find_hook( list, c, hook ) \
MACRO_BEGIN _list_forall_hook( list, hook ) if( c ) \
break; \
MACRO_END
/* insert element after hook */
#define list_insert_athook( elt, hook ) \
MACRO_BEGIN elt->next = *hook; *hook = elt; MACRO_END
/* insert element before hook */
#define list_insert_beforehook( elt, hook ) \
MACRO_BEGIN elt->next = *hook; *hook = elt; hook = &elt->next; MACRO_END
/* unlink element after hook, let elt be unlinked element, or NULL.
* hook remains. */
#define list_unlink_athook( list, elt, hook ) \
MACRO_BEGIN \
elt = hook ? *hook : NULL; if( elt ) { *hook = elt->next; elt->next = NULL; } \
MACRO_END
/* unlink the specific element, if it is in the list. Otherwise, set
* elt to NULL */
#define list_unlink( listtype, list, elt ) \
MACRO_BEGIN \
listtype * *_hook; \
_list_find_hook( list, *_hook==elt, _hook ); \
list_unlink_athook( list, elt, _hook ); \
MACRO_END
/* prepend elt to list */
#define list_prepend( list, elt ) \
MACRO_BEGIN elt->next = list; list = elt; MACRO_END
/* append elt to list. */
#define list_append( listtype, list, elt ) \
MACRO_BEGIN \
listtype * *_hook; \
_list_forall_hook( list, _hook ) {} \
list_insert_athook( elt, _hook ); \
MACRO_END
/* unlink the first element that satisfies the condition. */
#define list_unlink_cond( listtype, list, elt, c ) \
MACRO_BEGIN \
listtype * *_hook; \
list_find2( elt, list, c, _hook ); \
list_unlink_athook( list, elt, _hook ); \
MACRO_END
/* let elt be the nth element of the list, starting to count from 0.
* Return NULL if out of bounds. */
#define list_nth( elt, list, n ) \
MACRO_BEGIN \
int _x; /* only evaluate n once */ \
for( _x = (n), elt = list; _x && elt; _x--, elt = elt->next ) {} \
MACRO_END
/* let elt be the nth element of the list, starting to count from 0.
* Return NULL if out of bounds. */
#define list_nth_hook( elt, list, n, hook ) \
MACRO_BEGIN \
int _x; /* only evaluate n once */ \
for( _x = (n), elt = list, hook = &list; _x && elt; \
_x--, hook = &elt->next, elt = elt->next ) {} \
MACRO_END
/* set n to the length of the list */
#define list_length( listtype, list, n ) \
MACRO_BEGIN \
listtype * _elt; \
n = 0; \
list_forall( _elt, list ) \
n++; \
MACRO_END
/* set n to the index of the first element satisfying cond, or -1 if
* none found. Also set elt to the element, or NULL if none found. */
#define list_index( list, n, elt, c ) \
MACRO_BEGIN \
n = 0; \
list_forall( elt, list ) { \
if( c ) \
break; \
n++; \
} \
if( !elt ) \
n = -1; \
MACRO_END
/* set n to the number of elements in the list that satisfy condition c */
#define list_count( list, n, elt, c ) \
MACRO_BEGIN \
n = 0; \
list_forall( elt, list ) { \
if( c ) \
n++; \
} \
MACRO_END
/* let elt be each element of the list, unlinked. At the end, set list=NULL. */
#define list_forall_unlink( elt, list ) \
for( elt = list; elt ? (list = elt->next, elt->next = NULL), 1 : 0; elt = list )
/* reverse a list (efficient) */
#define list_reverse( listtype, list ) \
MACRO_BEGIN \
listtype * _list1 = NULL, *elt; \
list_forall_unlink( elt, list ) \
list_prepend( _list1, elt ); \
list = _list1; \
MACRO_END
/* insert the element ELT just before the first element TMP of the
* list for which COND holds. Here COND must be a condition of ELT and
* TMP. Typical usage is to insert an element into an ordered list:
* for instance, list_insert_ordered(listtype, list, elt, tmp,
* elt->size <= tmp->size). Note: if we give a "less than or equal"
* condition, the new element will be inserted just before a sequence
* of equal elements. If we give a "less than" condition, the new
* element will be inserted just after a list of equal elements.
* Note: it is much more efficient to construct a list with
* list_prepend and then order it with list_merge_sort, than to
* construct it with list_insert_ordered. */
#define list_insert_ordered( listtype, list, elt, tmp, cond ) \
MACRO_BEGIN \
listtype * *_hook; \
_list_find_hook( list, ( tmp = *_hook, (cond) ), _hook ); \
list_insert_athook( elt, _hook ); \
MACRO_END
/* sort the given list, according to the comparison condition.
* Typical usage is list_sort(listtype, list, a, b, a->size <
* b->size). Note: if we give "less than or equal" condition, each
* segment of equal elements will be reversed in order. If we give a
* "less than" condition, each segment of equal elements will retain
* the original order. The latter is slower but sometimes
* prettier. Average running time: n*n/2. */
#define list_sort( listtype, list, a, b, cond ) \
MACRO_BEGIN \
listtype * _newlist = NULL; \
list_forall_unlink( a, list ) \
list_insert_ordered( listtype, _newlist, a, b, cond ); \
list = _newlist; \
MACRO_END
/* a much faster sort algorithm (merge sort, n log n worst case). It
* is required that the list type has an additional, unused next1
* component. Note there is no curious reversal of order of equal
* elements as for list_sort. */
#define list_mergesort( listtype, list, a, b, cond ) \
MACRO_BEGIN \
listtype * _elt, **_hook1; \
\
for( _elt = list; _elt; _elt = _elt->next1 ) { \
_elt->next1 = _elt->next; \
_elt->next = NULL; \
} \
do { \
_hook1 = &(list); \
while( (a = *_hook1) != NULL && (b = a->next1) != NULL ) { \
_elt = b->next1; \
_list_merge_cond( listtype, a, b, cond, *_hook1 ); \
_hook1 = &( (*_hook1)->next1 ); \
*_hook1 = _elt; \
} \
} \
while( _hook1 != &(list) ); \
MACRO_END
/* merge two sorted lists. Store result at &result */
#define _list_merge_cond( listtype, a, b, cond, result ) \
MACRO_BEGIN \
listtype * *_hook; \
_hook = &(result); \
while( 1 ) { \
if( a==NULL ) { \
*_hook = b; \
break; \
} \
else if( b==NULL ) { \
*_hook = a; \
break; \
} \
else if( cond ) { \
*_hook = a; \
_hook = &(a->next); \
a = a->next; \
} \
else { \
*_hook = b; \
_hook = &(b->next); \
b = b->next; \
} \
} \
MACRO_END
/* ---------------------------------------------------------------------- */
/* macros for doubly-linked lists */
#define dlist_append( head, end, elt ) \
MACRO_BEGIN \
elt->prev = end; \
elt->next = NULL; \
if( end ) { \
end->next = elt; \
} \
else { \
head = elt; \
} \
end = elt; \
MACRO_END
/* let elt be each element of the list, unlinked. At the end, set list=NULL. */
#define dlist_forall_unlink( elt, head, end ) \
for( elt = head; \
elt ? (head = elt->next, elt->next = NULL, elt->prev = NULL), 1 : (end = NULL, 0); \
elt = head )
/* unlink the first element of the list */
#define dlist_unlink_first( head, end, elt ) \
MACRO_BEGIN \
elt = head; \
if( head ) { \
head = head->next; \
if( head ) { \
head->prev = NULL; \
} \
else { \
end = NULL; \
} \
elt->prev = NULL; \
elt->next = NULL; \
} \
MACRO_END
#endif /* _PS_LISTS_H */