* Therefore, if \c head->next is \c NULL or \c tail_prev->prev is \c NULL,
* the list is empty.
*
+ * Do note that this means that the list nodes will contain pointers into the
+ * list structure itself and as a result you may not \c realloc() an \c
+ * exec_list or any structure in which an \c exec_list is embedded.
+ *
* To anyone familiar with "exec lists" on the Amiga, this structure should
* be immediately recognizable. See the following link for the original Amiga
* operating system documentation on the subject.
#ifndef __cplusplus
#include <stddef.h>
-#include <talloc.h>
-#else
-extern "C" {
-#include <talloc.h>
-}
#endif
-
#include <assert.h>
+#include "util/ralloc.h"
+
struct exec_node {
struct exec_node *next;
struct exec_node *prev;
#ifdef __cplusplus
- /* Callers of this talloc-based new need not call delete. It's
- * easier to just talloc_free 'ctx' (or any of its ancestors). */
- static void* operator new(size_t size, void *ctx)
- {
- void *node;
-
- node = talloc_size(ctx, size);
- assert(node != NULL);
-
- return node;
- }
-
- /* If the user *does* call delete, that's OK, we will just
- * talloc_free in that case. */
- static void operator delete(void *node)
- {
- talloc_free(node);
- }
+ DECLARE_RALLOC_CXX_OPERATORS(exec_node)
exec_node() : next(NULL), prev(NULL)
{
/* empty */
}
- const exec_node *get_next() const
- {
- return next;
- }
-
- exec_node *get_next()
- {
- return next;
- }
-
- const exec_node *get_prev() const
- {
- return prev;
- }
+ const exec_node *get_next() const;
+ exec_node *get_next();
- exec_node *get_prev()
- {
- return prev;
- }
+ const exec_node *get_prev() const;
+ exec_node *get_prev();
- void remove()
- {
- next->prev = prev;
- prev->next = next;
- next = NULL;
- prev = NULL;
- }
+ void remove();
/**
* Link a node with itself
*
* This creates a sort of degenerate list that is occasionally useful.
*/
- void self_link()
- {
- next = this;
- prev = this;
- }
+ void self_link();
/**
* Insert a node in the list after the current node
*/
- void insert_after(exec_node *after)
- {
- after->next = this->next;
- after->prev = this;
-
- this->next->prev = after;
- this->next = after;
- }
+ void insert_after(exec_node *after);
/**
* Insert a node in the list before the current node
*/
- void insert_before(exec_node *before)
- {
- before->next = this;
- before->prev = this->prev;
-
- this->prev->next = before;
- this->prev = before;
- }
+ void insert_before(exec_node *before);
/**
* Insert another list in the list before the current node
/**
* Replace the current node with the given node.
*/
- void replace_with(exec_node *replacement)
- {
- replacement->prev = this->prev;
- replacement->next = this->next;
-
- this->prev->next = replacement;
- this->next->prev = replacement;
- }
+ void replace_with(exec_node *replacement);
/**
* Is this the sentinel at the tail of the list?
*/
- bool is_tail_sentinel() const
- {
- return this->next == NULL;
- }
+ bool is_tail_sentinel() const;
/**
* Is this the sentinel at the head of the list?
*/
- bool is_head_sentinel() const
- {
- return this->prev == NULL;
- }
+ bool is_head_sentinel() const;
#endif
};
+static inline void
+exec_node_init(struct exec_node *n)
+{
+ n->next = NULL;
+ n->prev = NULL;
+}
+
+static inline const struct exec_node *
+exec_node_get_next_const(const struct exec_node *n)
+{
+ return n->next;
+}
+
+static inline struct exec_node *
+exec_node_get_next(struct exec_node *n)
+{
+ return n->next;
+}
+
+static inline const struct exec_node *
+exec_node_get_prev_const(const struct exec_node *n)
+{
+ return n->prev;
+}
+
+static inline struct exec_node *
+exec_node_get_prev(struct exec_node *n)
+{
+ return n->prev;
+}
+
+static inline void
+exec_node_remove(struct exec_node *n)
+{
+ n->next->prev = n->prev;
+ n->prev->next = n->next;
+ n->next = NULL;
+ n->prev = NULL;
+}
+
+static inline void
+exec_node_self_link(struct exec_node *n)
+{
+ n->next = n;
+ n->prev = n;
+}
+
+static inline void
+exec_node_insert_after(struct exec_node *n, struct exec_node *after)
+{
+ after->next = n->next;
+ after->prev = n;
+
+ n->next->prev = after;
+ n->next = after;
+}
+
+static inline void
+exec_node_insert_node_before(struct exec_node *n, struct exec_node *before)
+{
+ before->next = n;
+ before->prev = n->prev;
+
+ n->prev->next = before;
+ n->prev = before;
+}
+
+static inline void
+exec_node_replace_with(struct exec_node *n, struct exec_node *replacement)
+{
+ replacement->prev = n->prev;
+ replacement->next = n->next;
+
+ n->prev->next = replacement;
+ n->next->prev = replacement;
+}
+
+static inline bool
+exec_node_is_tail_sentinel(const struct exec_node *n)
+{
+ return n->next == NULL;
+}
+
+static inline bool
+exec_node_is_head_sentinel(const struct exec_node *n)
+{
+ return n->prev == NULL;
+}
+
+#ifdef __cplusplus
+inline const exec_node *exec_node::get_next() const
+{
+ return exec_node_get_next_const(this);
+}
+
+inline exec_node *exec_node::get_next()
+{
+ return exec_node_get_next(this);
+}
+
+inline const exec_node *exec_node::get_prev() const
+{
+ return exec_node_get_prev_const(this);
+}
+
+inline exec_node *exec_node::get_prev()
+{
+ return exec_node_get_prev(this);
+}
+
+inline void exec_node::remove()
+{
+ exec_node_remove(this);
+}
+
+inline void exec_node::self_link()
+{
+ exec_node_self_link(this);
+}
+
+inline void exec_node::insert_after(exec_node *after)
+{
+ exec_node_insert_after(this, after);
+}
+
+inline void exec_node::insert_before(exec_node *before)
+{
+ exec_node_insert_node_before(this, before);
+}
+
+inline void exec_node::replace_with(exec_node *replacement)
+{
+ exec_node_replace_with(this, replacement);
+}
+
+inline bool exec_node::is_tail_sentinel() const
+{
+ return exec_node_is_tail_sentinel(this);
+}
+
+inline bool exec_node::is_head_sentinel() const
+{
+ return exec_node_is_head_sentinel(this);
+}
+#endif
#ifdef __cplusplus
/* This macro will not work correctly if `t' uses virtual inheritance. If you
#ifdef __cplusplus
struct exec_node;
+#endif
-class iterator {
-public:
- void next()
- {
- }
+struct exec_list {
+ struct exec_node *head;
+ struct exec_node *tail;
+ struct exec_node *tail_pred;
- void *get()
- {
- return NULL;
- }
+#ifdef __cplusplus
+ DECLARE_RALLOC_CXX_OPERATORS(exec_list)
- bool has_next() const
+ exec_list()
{
- return false;
+ make_empty();
}
-};
-class exec_list_iterator : public iterator {
-public:
- exec_list_iterator(exec_node *n) : node(n), _next(n->next)
- {
- /* empty */
- }
+ void make_empty();
- void next()
- {
- node = _next;
- _next = node->next;
- }
+ bool is_empty() const;
- void remove()
- {
- node->remove();
- }
+ const exec_node *get_head() const;
+ exec_node *get_head();
- exec_node *get()
- {
- return node;
- }
+ const exec_node *get_tail() const;
+ exec_node *get_tail();
- bool has_next() const
- {
- return _next != NULL;
- }
+ unsigned length() const;
-private:
- exec_node *node;
- exec_node *_next;
-};
+ void push_head(exec_node *n);
+ void push_tail(exec_node *n);
+ void push_degenerate_list_at_head(exec_node *n);
+
+ /**
+ * Remove the first node from a list and return it
+ *
+ * \return
+ * The first node in the list or \c NULL if the list is empty.
+ *
+ * \sa exec_list::get_head
+ */
+ exec_node *pop_head();
+
+ /**
+ * Move all of the nodes from this list to the target list
+ */
+ void move_nodes_to(exec_list *target);
+
+ /**
+ * Append all nodes from the source list to the end of the target list
+ */
+ void append_list(exec_list *source);
-#define foreach_iter(iter_type, iter, container) \
- for (iter_type iter = (container) . iterator(); iter.has_next(); iter.next())
+ /**
+ * Prepend all nodes from the source list to the beginning of the target
+ * list
+ */
+ void prepend_list(exec_list *source);
#endif
+};
+static inline void
+exec_list_make_empty(struct exec_list *list)
+{
+ list->head = (struct exec_node *) & list->tail;
+ list->tail = NULL;
+ list->tail_pred = (struct exec_node *) & list->head;
+}
-struct exec_list {
- struct exec_node *head;
- struct exec_node *tail;
- struct exec_node *tail_pred;
+static inline bool
+exec_list_is_empty(const struct exec_list *list)
+{
+ /* There are three ways to test whether a list is empty or not.
+ *
+ * - Check to see if the \c head points to the \c tail.
+ * - Check to see if the \c tail_pred points to the \c head.
+ * - Check to see if the \c head is the sentinel node by test whether its
+ * \c next pointer is \c NULL.
+ *
+ * The first two methods tend to generate better code on modern systems
+ * because they save a pointer dereference.
+ */
+ return list->head == (struct exec_node *) &list->tail;
+}
-#ifdef __cplusplus
- /* Callers of this talloc-based new need not call delete. It's
- * easier to just talloc_free 'ctx' (or any of its ancestors). */
- static void* operator new(size_t size, void *ctx)
- {
- void *node;
+static inline const struct exec_node *
+exec_list_get_head_const(const struct exec_list *list)
+{
+ return !exec_list_is_empty(list) ? list->head : NULL;
+}
- node = talloc_size(ctx, size);
- assert(node != NULL);
+static inline struct exec_node *
+exec_list_get_head(struct exec_list *list)
+{
+ return !exec_list_is_empty(list) ? list->head : NULL;
+}
- return node;
- }
+static inline const struct exec_node *
+exec_list_get_tail_const(const struct exec_list *list)
+{
+ return !exec_list_is_empty(list) ? list->tail_pred : NULL;
+}
- /* If the user *does* call delete, that's OK, we will just
- * talloc_free in that case. */
- static void operator delete(void *node)
- {
- talloc_free(node);
- }
+static inline struct exec_node *
+exec_list_get_tail(struct exec_list *list)
+{
+ return !exec_list_is_empty(list) ? list->tail_pred : NULL;
+}
- exec_list()
- {
- make_empty();
- }
+static inline unsigned
+exec_list_length(const struct exec_list *list)
+{
+ unsigned size = 0;
+ struct exec_node *node;
- void make_empty()
- {
- head = (exec_node *) & tail;
- tail = NULL;
- tail_pred = (exec_node *) & head;
+ for (node = list->head; node->next != NULL; node = node->next) {
+ size++;
}
- bool is_empty() const
- {
- /* There are three ways to test whether a list is empty or not.
- *
- * - Check to see if the \c head points to the \c tail.
- * - Check to see if the \c tail_pred points to the \c head.
- * - Check to see if the \c head is the sentinel node by test whether its
- * \c next pointer is \c NULL.
- *
- * The first two methods tend to generate better code on modern systems
- * because they save a pointer dereference.
- */
- return head == (exec_node *) &tail;
- }
+ return size;
+}
- const exec_node *get_head() const
- {
- return !is_empty() ? head : NULL;
- }
+static inline void
+exec_list_push_head(struct exec_list *list, struct exec_node *n)
+{
+ n->next = list->head;
+ n->prev = (struct exec_node *) &list->head;
- exec_node *get_head()
- {
- return !is_empty() ? head : NULL;
- }
+ n->next->prev = n;
+ list->head = n;
+}
- const exec_node *get_tail() const
- {
- return !is_empty() ? tail_pred : NULL;
- }
+static inline void
+exec_list_push_tail(struct exec_list *list, struct exec_node *n)
+{
+ n->next = (struct exec_node *) &list->tail;
+ n->prev = list->tail_pred;
- exec_node *get_tail()
- {
- return !is_empty() ? tail_pred : NULL;
- }
+ n->prev->next = n;
+ list->tail_pred = n;
+}
- void push_head(exec_node *n)
- {
- n->next = head;
- n->prev = (exec_node *) &head;
+static inline void
+exec_list_push_degenerate_list_at_head(struct exec_list *list, struct exec_node *n)
+{
+ assert(n->prev->next == n);
- n->next->prev = n;
- head = n;
- }
+ n->prev->next = list->head;
+ list->head->prev = n->prev;
+ n->prev = (struct exec_node *) &list->head;
+ list->head = n;
+}
- void push_tail(exec_node *n)
- {
- n->next = (exec_node *) &tail;
- n->prev = tail_pred;
+static inline struct exec_node *
+exec_list_pop_head(struct exec_list *list)
+{
+ struct exec_node *const n = exec_list_get_head(list);
+ if (n != NULL)
+ exec_node_remove(n);
- n->prev->next = n;
- tail_pred = n;
- }
+ return n;
+}
- void push_degenerate_list_at_head(exec_node *n)
- {
- assert(n->prev->next == n);
+static inline void
+exec_list_move_nodes_to(struct exec_list *list, struct exec_list *target)
+{
+ if (exec_list_is_empty(list)) {
+ exec_list_make_empty(target);
+ } else {
+ target->head = list->head;
+ target->tail = NULL;
+ target->tail_pred = list->tail_pred;
+
+ target->head->prev = (struct exec_node *) &target->head;
+ target->tail_pred->next = (struct exec_node *) &target->tail;
- n->prev->next = head;
- head->prev = n->prev;
- n->prev = (exec_node *) &head;
- head = n;
+ exec_list_make_empty(list);
}
+}
- /**
- * Remove the first node from a list and return it
- *
- * \return
- * The first node in the list or \c NULL if the list is empty.
- *
- * \sa exec_list::get_head
+static inline void
+exec_list_append(struct exec_list *list, struct exec_list *source)
+{
+ if (exec_list_is_empty(source))
+ return;
+
+ /* Link the first node of the source with the last node of the target list.
*/
- exec_node *pop_head()
- {
- exec_node *const n = this->get_head();
- if (n != NULL)
- n->remove();
+ list->tail_pred->next = source->head;
+ source->head->prev = list->tail_pred;
- return n;
- }
+ /* Make the tail of the source list be the tail of the target list.
+ */
+ list->tail_pred = source->tail_pred;
+ list->tail_pred->next = (struct exec_node *) &list->tail;
- /**
- * Move all of the nodes from this list to the target list
+ /* Make the source list empty for good measure.
*/
- void move_nodes_to(exec_list *target)
- {
- if (is_empty()) {
- target->make_empty();
- } else {
- target->head = head;
- target->tail = NULL;
- target->tail_pred = tail_pred;
-
- target->head->prev = (exec_node *) &target->head;
- target->tail_pred->next = (exec_node *) &target->tail;
-
- make_empty();
- }
- }
+ exec_list_make_empty(source);
+}
- /**
- * Append all nodes from the source list to the target list
+static inline void
+exec_list_prepend(struct exec_list *list, struct exec_list *source)
+{
+ exec_list_append(source, list);
+ exec_list_move_nodes_to(source, list);
+}
+
+static inline void
+exec_node_insert_list_before(struct exec_node *n, struct exec_list *before)
+{
+ if (exec_list_is_empty(before))
+ return;
+
+ before->tail_pred->next = n;
+ before->head->prev = n->prev;
+
+ n->prev->next = before->head;
+ n->prev = before->tail_pred;
+
+ exec_list_make_empty(before);
+}
+
+static inline void
+exec_list_validate(const struct exec_list *list)
+{
+ const struct exec_node *node;
+
+ assert(list->head->prev == (const struct exec_node *) &list->head);
+ assert(list->tail == NULL);
+ assert(list->tail_pred->next == (const struct exec_node *) &list->tail);
+
+ /* We could try to use one of the interators below for this but they all
+ * either require C++ or assume the exec_node is embedded in a structure
+ * which is not the case for this function.
*/
- void
- append_list(exec_list *source)
- {
- if (source->is_empty())
- return;
-
- /* Link the first node of the source with the last node of the target list.
- */
- this->tail_pred->next = source->head;
- source->head->prev = this->tail_pred;
-
- /* Make the tail of the source list be the tail of the target list.
- */
- this->tail_pred = source->tail_pred;
- this->tail_pred->next = (exec_node *) &this->tail;
-
- /* Make the source list empty for good measure.
- */
- source->make_empty();
+ for (node = list->head; node->next != NULL; node = node->next) {
+ assert(node->next->prev == node);
+ assert(node->prev->next == node);
}
+}
- exec_list_iterator iterator()
- {
- return exec_list_iterator(head);
- }
+#ifdef __cplusplus
+inline void exec_list::make_empty()
+{
+ exec_list_make_empty(this);
+}
- exec_list_iterator iterator() const
- {
- return exec_list_iterator((exec_node *) head);
- }
-#endif
-};
+inline bool exec_list::is_empty() const
+{
+ return exec_list_is_empty(this);
+}
+inline const exec_node *exec_list::get_head() const
+{
+ return exec_list_get_head_const(this);
+}
-#ifdef __cplusplus
-inline void exec_node::insert_before(exec_list *before)
+inline exec_node *exec_list::get_head()
{
- if (before->is_empty())
- return;
+ return exec_list_get_head(this);
+}
+
+inline const exec_node *exec_list::get_tail() const
+{
+ return exec_list_get_tail_const(this);
+}
+
+inline exec_node *exec_list::get_tail()
+{
+ return exec_list_get_tail(this);
+}
+
+inline unsigned exec_list::length() const
+{
+ return exec_list_length(this);
+}
+
+inline void exec_list::push_head(exec_node *n)
+{
+ exec_list_push_head(this, n);
+}
+
+inline void exec_list::push_tail(exec_node *n)
+{
+ exec_list_push_tail(this, n);
+}
+
+inline void exec_list::push_degenerate_list_at_head(exec_node *n)
+{
+ exec_list_push_degenerate_list_at_head(this, n);
+}
+
+inline exec_node *exec_list::pop_head()
+{
+ return exec_list_pop_head(this);
+}
- before->tail_pred->next = this;
- before->head->prev = this->prev;
+inline void exec_list::move_nodes_to(exec_list *target)
+{
+ exec_list_move_nodes_to(this, target);
+}
+
+inline void exec_list::append_list(exec_list *source)
+{
+ exec_list_append(this, source);
+}
- this->prev->next = before->head;
- this->prev = before->tail_pred;
+inline void exec_list::prepend_list(exec_list *source)
+{
+ exec_list_prepend(this, source);
+}
- before->make_empty();
+inline void exec_node::insert_before(exec_list *before)
+{
+ exec_node_insert_list_before(this, before);
}
#endif
+#define foreach_in_list(__type, __inst, __list) \
+ for (__type *(__inst) = (__type *)(__list)->head; \
+ !(__inst)->is_tail_sentinel(); \
+ (__inst) = (__type *)(__inst)->next)
+
+#define foreach_in_list_reverse(__type, __inst, __list) \
+ for (__type *(__inst) = (__type *)(__list)->tail_pred; \
+ !(__inst)->is_head_sentinel(); \
+ (__inst) = (__type *)(__inst)->prev)
+
/**
* This version is safe even if the current node is removed.
*/
-#define foreach_list_safe(__node, __list) \
- for (exec_node * __node = (__list)->head, * __next = __node->next \
- ; __next != NULL \
- ; __node = __next, __next = __next->next)
-
-#define foreach_list(__node, __list) \
- for (exec_node * __node = (__list)->head \
- ; (__node)->next != NULL \
- ; (__node) = (__node)->next)
-
-#define foreach_list_const(__node, __list) \
- for (const exec_node * __node = (__list)->head \
- ; (__node)->next != NULL \
- ; (__node) = (__node)->next)
+#define foreach_in_list_safe(__type, __node, __list) \
+ for (__type *__node = (__type *)(__list)->head, \
+ *__next = (__type *)__node->next; \
+ __next != NULL; \
+ __node = __next, __next = (__type *)__next->next)
+
+#define foreach_in_list_reverse_safe(__type, __node, __list) \
+ for (__type *__node = (__type *)(__list)->tail_pred, \
+ *__prev = (__type *)__node->prev; \
+ __prev != NULL; \
+ __node = __prev, __prev = (__type *)__prev->prev)
+
+#define foreach_in_list_use_after(__type, __inst, __list) \
+ __type *(__inst); \
+ for ((__inst) = (__type *)(__list)->head; \
+ !(__inst)->is_tail_sentinel(); \
+ (__inst) = (__type *)(__inst)->next)
+/**
+ * Iterate through two lists at once. Stops at the end of the shorter list.
+ *
+ * This is safe against either current node being removed or replaced.
+ */
+#define foreach_two_lists(__node1, __list1, __node2, __list2) \
+ for (struct exec_node * __node1 = (__list1)->head, \
+ * __node2 = (__list2)->head, \
+ * __next1 = __node1->next, \
+ * __next2 = __node2->next \
+ ; __next1 != NULL && __next2 != NULL \
+ ; __node1 = __next1, \
+ __node2 = __next2, \
+ __next1 = __next1->next, \
+ __next2 = __next2->next)
#define foreach_list_typed(__type, __node, __field, __list) \
for (__type * __node = \
(__node)->__field.next != NULL; \
(__node) = exec_node_data(__type, (__node)->__field.next, __field))
-#define foreach_list_typed_const(__type, __node, __field, __list) \
- for (const __type * __node = \
- exec_node_data(__type, (__list)->head, __field); \
- (__node)->__field.next != NULL; \
- (__node) = exec_node_data(__type, (__node)->__field.next, __field))
+#define foreach_list_typed_reverse(__type, __node, __field, __list) \
+ for (__type * __node = \
+ exec_node_data(__type, (__list)->tail_pred, __field); \
+ (__node)->__field.prev != NULL; \
+ (__node) = exec_node_data(__type, (__node)->__field.prev, __field))
+
+#define foreach_list_typed_safe(__type, __node, __field, __list) \
+ for (__type * __node = \
+ exec_node_data(__type, (__list)->head, __field), \
+ * __next = \
+ exec_node_data(__type, (__node)->__field.next, __field); \
+ (__node)->__field.next != NULL; \
+ __node = __next, __next = \
+ exec_node_data(__type, (__next)->__field.next, __field))
+
+#define foreach_list_typed_safe_reverse(__type, __node, __field, __list) \
+ for (__type * __node = \
+ exec_node_data(__type, (__list)->tail_pred, __field), \
+ * __prev = \
+ exec_node_data(__type, (__node)->__field.prev, __field); \
+ (__node)->__field.prev != NULL; \
+ __node = __prev, __prev = \
+ exec_node_data(__type, (__prev)->__field.prev, __field))
#endif /* LIST_CONTAINER_H */