[deliverable/linux.git] / arch / s390 / numa / toptree.c

/*
 * NUMA support for s390
 *
 * A tree structure used for machine topology mangling
 *
 * Copyright IBM Corp. 2015
 */

#include <linux/kernel.h>
#include <linux/cpumask.h>
#include <linux/list.h>
#include <linux/list_sort.h>
#include <linux/slab.h>
#include <asm/numa.h>

#include "toptree.h"

/**
 * toptree_alloc - Allocate and initialize a new tree node.
 * @level: The node's vertical level; level 0 contains the leaves.
 * @id: ID number, explicitly not unique beyond scope of node's siblings
 *
 * Allocate a new tree node and initialize it.
 *
 * RETURNS:
 * Pointer to the new tree node or NULL on error
 */
struct toptree *toptree_alloc(int level, int id)
{
	struct toptree *res = kzalloc(sizeof(struct toptree), GFP_KERNEL);

	if (!res)
		return res;

	INIT_LIST_HEAD(&res->children);
	INIT_LIST_HEAD(&res->sibling);
	cpumask_clear(&res->mask);
	res->level = level;
	res->id = id;
	return res;
}

/**
 * toptree_remove - Remove a tree node from a tree
 * @cand: Pointer to the node to remove
 *
 * The node is detached from its parent node. The parent node's
 * masks will be updated to reflect the loss of the child.
 */
static void toptree_remove(struct toptree *cand)
{
	struct toptree *oldparent;

	list_del_init(&cand->sibling);
	oldparent = cand->parent;
	cand->parent = NULL;
	toptree_update_mask(oldparent);
}

/**
 * toptree_free - discard a tree node
 * @cand: Pointer to the tree node to discard
 *
 * Checks if @cand is attached to a parent node. Detaches it
 * cleanly using toptree_remove. Possible children are freed
 * recursively. In the end @cand itself is freed.
 */
void toptree_free(struct toptree *cand)
{
	struct toptree *child, *tmp;

	if (cand->parent)
		toptree_remove(cand);
	toptree_for_each_child_safe(child, tmp, cand)
		toptree_free(child);
	kfree(cand);
}

/**
 * toptree_update_mask - Update node bitmasks
 * @cand: Pointer to a tree node
 *
 * The node's cpumask will be updated by combining all children's
 * masks. Then toptree_update_mask is called recursively for the
 * parent if applicable.
 *
 * NOTE:
 * This must not be called on leaves. If called on a leaf, its
 * CPU mask is cleared and lost.
 */
void toptree_update_mask(struct toptree *cand)
{
	struct toptree *child;

	cpumask_clear(&cand->mask);
	list_for_each_entry(child, &cand->children, sibling)
		cpumask_or(&cand->mask, &cand->mask, &child->mask);
	if (cand->parent)
		toptree_update_mask(cand->parent);
}

/**
 * toptree_insert - Insert a tree node into tree
 * @cand: Pointer to the node to insert
 * @target: Pointer to the node to which @cand will added as a child
 *
 * Insert a tree node into a tree. Masks will be updated automatically.
 *
 * RETURNS:
 * 0 on success, -1 if NULL is passed as argument or the node levels
 * don't fit.
 */
static int toptree_insert(struct toptree *cand, struct toptree *target)
{
	if (!cand || !target)
		return -1;
	if (target->level != (cand->level + 1))
		return -1;
	list_add_tail(&cand->sibling, &target->children);
	cand->parent = target;
	toptree_update_mask(target);
	return 0;
}

/**
 * toptree_move_children - Move all child nodes of a node to a new place
 * @cand: Pointer to the node whose children are to be moved
 * @target: Pointer to the node to which @cand's children will be attached
 *
 * Take all child nodes of @cand and move them using toptree_move.
 */
static void toptree_move_children(struct toptree *cand, struct toptree *target)
{
	struct toptree *child, *tmp;

	toptree_for_each_child_safe(child, tmp, cand)
		toptree_move(child, target);
}

/**
 * toptree_unify - Merge children with same ID
 * @cand: Pointer to node whose direct children should be made unique
 *
 * When mangling the tree it is possible that a node has two or more children
 * which have the same ID. This routine merges these children into one and
 * moves all children of the merged nodes into the unified node.
 */
void toptree_unify(struct toptree *cand)
{
	struct toptree *child, *tmp, *cand_copy;

	/* Threads cannot be split, cores are not split */
	if (cand->level < 2)
		return;

	cand_copy = toptree_alloc(cand->level, 0);
	toptree_for_each_child_safe(child, tmp, cand) {
		struct toptree *tmpchild;

		if (!cpumask_empty(&child->mask)) {
			tmpchild = toptree_get_child(cand_copy, child->id);
			toptree_move_children(child, tmpchild);
		}
		toptree_free(child);
	}
	toptree_move_children(cand_copy, cand);
	toptree_free(cand_copy);

	toptree_for_each_child(child, cand)
		toptree_unify(child);
}

/**
 * toptree_move - Move a node to another context
 * @cand: Pointer to the node to move
 * @target: Pointer to the node where @cand should go
 *
 * In the easiest case @cand is exactly on the level below @target
 * and will be immediately moved to the target.
 *
 * If @target's level is not the direct parent level of @cand,
 * nodes for the missing levels are created and put between
 * @cand and @target. The "stacking" nodes' IDs are taken from
 * @cand's parents.
 *
 * After this it is likely to have redundant nodes in the tree
 * which are addressed by means of toptree_unify.
 */
void toptree_move(struct toptree *cand, struct toptree *target)
{
	struct toptree *stack_target, *real_insert_point, *ptr, *tmp;

	if (cand->level + 1 == target->level) {
		toptree_remove(cand);
		toptree_insert(cand, target);
		return;
	}

	real_insert_point = NULL;
	ptr = cand;
	stack_target = NULL;

	do {
		tmp = stack_target;
		stack_target = toptree_alloc(ptr->level + 1,
					     ptr->parent->id);
		toptree_insert(tmp, stack_target);
		if (!real_insert_point)
			real_insert_point = stack_target;
		ptr = ptr->parent;
	} while (stack_target->level < (target->level - 1));

	toptree_remove(cand);
	toptree_insert(cand, real_insert_point);
	toptree_insert(stack_target, target);
}

/**
 * toptree_get_child - Access a tree node's child by its ID
 * @cand: Pointer to tree node whose child is to access
 * @id: The desired child's ID
 *
 * @cand's children are searched for a child with matching ID.
 * If no match can be found, a new child with the desired ID
 * is created and returned.
 */
struct toptree *toptree_get_child(struct toptree *cand, int id)
{
	struct toptree *child;

	toptree_for_each_child(child, cand)
		if (child->id == id)
			return child;
	child = toptree_alloc(cand->level-1, id);
	toptree_insert(child, cand);
	return child;
}

/**
 * toptree_first - Find the first descendant on specified level
 * @context: Pointer to tree node whose descendants are to be used
 * @level: The level of interest
 *
 * RETURNS:
 * @context's first descendant on the specified level, or NULL
 * if there is no matching descendant
 */
struct toptree *toptree_first(struct toptree *context, int level)
{
	struct toptree *child, *tmp;

	if (context->level == level)
		return context;

	if (!list_empty(&context->children)) {
		list_for_each_entry(child, &context->children, sibling) {
			tmp = toptree_first(child, level);
			if (tmp)
				return tmp;
		}
	}
	return NULL;
}

/**
 * toptree_next_sibling - Return next sibling
 * @cur: Pointer to a tree node
 *
 * RETURNS:
 * If @cur has a parent and is not the last in the parent's children list,
 * the next sibling is returned. Or NULL when there are no siblings left.
 */
static struct toptree *toptree_next_sibling(struct toptree *cur)
{
	if (cur->parent == NULL)
		return NULL;

	if (cur == list_last_entry(&cur->parent->children,
				   struct toptree, sibling))
		return NULL;
	return (struct toptree *) list_next_entry(cur, sibling);
}

/**
 * toptree_next - Tree traversal function
 * @cur: Pointer to current element
 * @context: Pointer to the root node of the tree or subtree to
 * be traversed.
 * @level: The level of interest.
 *
 * RETURNS:
 * Pointer to the next node on level @level
 * or NULL when there is no next node.
 */
struct toptree *toptree_next(struct toptree *cur, struct toptree *context,
			     int level)
{
	struct toptree *cur_context, *tmp;

	if (!cur)
		return NULL;

	if (context->level == level)
		return NULL;

	tmp = toptree_next_sibling(cur);
	if (tmp != NULL)
		return tmp;

	cur_context = cur;
	while (cur_context->level < context->level - 1) {
		/* Step up */
		cur_context = cur_context->parent;
		/* Step aside */
		tmp = toptree_next_sibling(cur_context);
		if (tmp != NULL) {
			/* Step down */
			tmp = toptree_first(tmp, level);
			if (tmp != NULL)
				return tmp;
		}
	}
	return NULL;
}

/**
 * toptree_count - Count descendants on specified level
 * @context: Pointer to node whose descendants are to be considered
 * @level: Only descendants on the specified level will be counted
 *
 * RETURNS:
 * Number of descendants on the specified level
 */
int toptree_count(struct toptree *context, int level)
{
	struct toptree *cur;
	int cnt = 0;

	toptree_for_each(cur, context, level)
		cnt++;
	return cnt;
}
Commit	Line	Data
e8054b65 PH	1	/*
	2	* NUMA support for s390
	3	*
	4	* A tree structure used for machine topology mangling
	5	*
	6	* Copyright IBM Corp. 2015
	7	*/
	8
	9	#include <linux/kernel.h>
	10	#include <linux/cpumask.h>
	11	#include <linux/list.h>
	12	#include <linux/list_sort.h>
	13	#include <linux/slab.h>
	14	#include <asm/numa.h>
	15
	16	#include "toptree.h"
	17
	18	/**
	19	* toptree_alloc - Allocate and initialize a new tree node.
	20	* @level: The node's vertical level; level 0 contains the leaves.
	21	* @id: ID number, explicitly not unique beyond scope of node's siblings
	22	*
	23	* Allocate a new tree node and initialize it.
	24	*
	25	* RETURNS:
	26	* Pointer to the new tree node or NULL on error
	27	*/
	28	struct toptree *toptree_alloc(int level, int id)
	29	{
	30	struct toptree *res = kzalloc(sizeof(struct toptree), GFP_KERNEL);
	31
	32	if (!res)
	33	return res;
	34
	35	INIT_LIST_HEAD(&res->children);
	36	INIT_LIST_HEAD(&res->sibling);
	37	cpumask_clear(&res->mask);
	38	res->level = level;
	39	res->id = id;
	40	return res;
	41	}
	42
	43	/**
	44	* toptree_remove - Remove a tree node from a tree
	45	* @cand: Pointer to the node to remove
	46	*
	47	* The node is detached from its parent node. The parent node's
	48	* masks will be updated to reflect the loss of the child.
	49	*/
	50	static void toptree_remove(struct toptree *cand)
	51	{
	52	struct toptree *oldparent;
	53
	54	list_del_init(&cand->sibling);
	55	oldparent = cand->parent;
	56	cand->parent = NULL;
	57	toptree_update_mask(oldparent);
	58	}
	59
	60	/**
	61	* toptree_free - discard a tree node
	62	* @cand: Pointer to the tree node to discard
	63	*
	64	* Checks if @cand is attached to a parent node. Detaches it
65	* cleanly using toptree_remove. Possible children are freed
66	* recursively. In the end @cand itself is freed.
67	*/
68	void toptree_free(struct toptree *cand)
69	{
70	struct toptree child, tmp;
71
72	if (cand->parent)
73	toptree_remove(cand);
74	toptree_for_each_child_safe(child, tmp, cand)
75	toptree_free(child);
76	kfree(cand);
77	}
78
79	/**
80	* toptree_update_mask - Update node bitmasks
81	* @cand: Pointer to a tree node
82	*
83	* The node's cpumask will be updated by combining all children's
84	* masks. Then toptree_update_mask is called recursively for the
85	* parent if applicable.
86	*
87	* NOTE:
88	* This must not be called on leaves. If called on a leaf, its
89	* CPU mask is cleared and lost.
90	*/
91	void toptree_update_mask(struct toptree *cand)
92	{
93	struct toptree *child;
94
95	cpumask_clear(&cand->mask);
96	list_for_each_entry(child, &cand->children, sibling)
97	cpumask_or(&cand->mask, &cand->mask, &child->mask);
98	if (cand->parent)
99	toptree_update_mask(cand->parent);
100	}
101
102	/**
103	* toptree_insert - Insert a tree node into tree
104	* @cand: Pointer to the node to insert
105	* @target: Pointer to the node to which @cand will added as a child
106	*
107	* Insert a tree node into a tree. Masks will be updated automatically.
108	*
109	* RETURNS:
110	* 0 on success, -1 if NULL is passed as argument or the node levels
111	* don't fit.
112	*/
113	static int toptree_insert(struct toptree cand, struct toptree target)
114	{
115	if (!cand \|\| !target)
116	return -1;
117	if (target->level != (cand->level + 1))
118	return -1;
119	list_add_tail(&cand->sibling, &target->children);
120	cand->parent = target;
121	toptree_update_mask(target);
122	return 0;
123	}
124
125	/**
126	* toptree_move_children - Move all child nodes of a node to a new place
127	* @cand: Pointer to the node whose children are to be moved
128	* @target: Pointer to the node to which @cand's children will be attached
129	*
130	* Take all child nodes of @cand and move them using toptree_move.
131	*/
132	static void toptree_move_children(struct toptree cand, struct toptree target)
133	{
134	struct toptree child, tmp;
135
136	toptree_for_each_child_safe(child, tmp, cand)
137	toptree_move(child, target);
138	}
139
140	/**
141	* toptree_unify - Merge children with same ID
142	* @cand: Pointer to node whose direct children should be made unique
143	*
144	* When mangling the tree it is possible that a node has two or more children
145	* which have the same ID. This routine merges these children into one and
146	* moves all children of the merged nodes into the unified node.
147	*/
148	void toptree_unify(struct toptree *cand)
149	{
150	struct toptree child, tmp, *cand_copy;
151
152	/* Threads cannot be split, cores are not split */
153	if (cand->level < 2)
154	return;
155
156	cand_copy = toptree_alloc(cand->level, 0);
157	toptree_for_each_child_safe(child, tmp, cand) {
158	struct toptree *tmpchild;
159
160	if (!cpumask_empty(&child->mask)) {
161	tmpchild = toptree_get_child(cand_copy, child->id);
162	toptree_move_children(child, tmpchild);
163	}
164	toptree_free(child);
165	}
166	toptree_move_children(cand_copy, cand);
167	toptree_free(cand_copy);
168
169	toptree_for_each_child(child, cand)
170	toptree_unify(child);
171	}
172
173	/**
174	* toptree_move - Move a node to another context
175	* @cand: Pointer to the node to move
176	* @target: Pointer to the node where @cand should go
177	*
178	* In the easiest case @cand is exactly on the level below @target
179	* and will be immediately moved to the target.
180	*
181	* If @target's level is not the direct parent level of @cand,
182	* nodes for the missing levels are created and put between
183	* @cand and @target. The "stacking" nodes' IDs are taken from
184	* @cand's parents.
185	*
186	* After this it is likely to have redundant nodes in the tree
187	* which are addressed by means of toptree_unify.
188	*/
189	void toptree_move(struct toptree cand, struct toptree target)
190	{
191	struct toptree stack_target, real_insert_point, ptr, tmp;
192
193	if (cand->level + 1 == target->level) {
194	toptree_remove(cand);
195	toptree_insert(cand, target);
196	return;
197	}
198
199	real_insert_point = NULL;
200	ptr = cand;
201	stack_target = NULL;
202
203	do {
204	tmp = stack_target;
205	stack_target = toptree_alloc(ptr->level + 1,
206	ptr->parent->id);
207	toptree_insert(tmp, stack_target);
208	if (!real_insert_point)
209	real_insert_point = stack_target;
210	ptr = ptr->parent;
211	} while (stack_target->level < (target->level - 1));
212
213	toptree_remove(cand);
214	toptree_insert(cand, real_insert_point);
215	toptree_insert(stack_target, target);
216	}
217
218	/**
219	* toptree_get_child - Access a tree node's child by its ID
220	* @cand: Pointer to tree node whose child is to access
221	* @id: The desired child's ID
222	*
223	* @cand's children are searched for a child with matching ID.
224	* If no match can be found, a new child with the desired ID
225	* is created and returned.
226	*/
227	struct toptree toptree_get_child(struct toptree cand, int id)
228	{
229	struct toptree *child;
230
231	toptree_for_each_child(child, cand)
232	if (child->id == id)
233	return child;
234	child = toptree_alloc(cand->level-1, id);
235	toptree_insert(child, cand);
236	return child;
237	}
238
239	/**
240	* toptree_first - Find the first descendant on specified level
241	* @context: Pointer to tree node whose descendants are to be used
242	* @level: The level of interest
243	*
244	* RETURNS:
245	* @context's first descendant on the specified level, or NULL
246	* if there is no matching descendant
247	*/
248	struct toptree toptree_first(struct toptree context, int level)
249	{
250	struct toptree child, tmp;
251
252	if (context->level == level)
253	return context;
254
255	if (!list_empty(&context->children)) {
256	list_for_each_entry(child, &context->children, sibling) {
257	tmp = toptree_first(child, level);
258	if (tmp)
259	return tmp;
260	}
261	}
262	return NULL;
263	}
264
265	/**
266	* toptree_next_sibling - Return next sibling
267	* @cur: Pointer to a tree node
268	*
269	* RETURNS:
270	* If @cur has a parent and is not the last in the parent's children list,
271	* the next sibling is returned. Or NULL when there are no siblings left.
272	*/
273	static struct toptree toptree_next_sibling(struct toptree cur)
274	{
275	if (cur->parent == NULL)
276	return NULL;
277
278	if (cur == list_last_entry(&cur->parent->children,
279	struct toptree, sibling))
280	return NULL;
281	return (struct toptree *) list_next_entry(cur, sibling);
282	}
283
284	/**
285	* toptree_next - Tree traversal function
286	* @cur: Pointer to current element
287	* @context: Pointer to the root node of the tree or subtree to
288	* be traversed.
289	* @level: The level of interest.
290	*
291	* RETURNS:
292	* Pointer to the next node on level @level
293	* or NULL when there is no next node.
294	*/
295	struct toptree toptree_next(struct toptree cur, struct toptree *context,
296	int level)
297	{
298	struct toptree cur_context, tmp;
299
300	if (!cur)
301	return NULL;
302
303	if (context->level == level)
304	return NULL;
305
306	tmp = toptree_next_sibling(cur);
307	if (tmp != NULL)
308	return tmp;
309
310	cur_context = cur;
311	while (cur_context->level < context->level - 1) {
312	/* Step up */
313	cur_context = cur_context->parent;
314	/* Step aside */
315	tmp = toptree_next_sibling(cur_context);
316	if (tmp != NULL) {
317	/* Step down */
318	tmp = toptree_first(tmp, level);
319	if (tmp != NULL)
320	return tmp;
321	}
322	}
323	return NULL;
324	}
325
326	/**
327	* toptree_count - Count descendants on specified level
328	* @context: Pointer to node whose descendants are to be considered
329	* @level: Only descendants on the specified level will be counted
330	*
331	* RETURNS:
332	* Number of descendants on the specified level
333	*/
334	int toptree_count(struct toptree *context, int level)
335	{
336	struct toptree *cur;
337	int cnt = 0;
338
339	toptree_for_each(cur, context, level)
340	cnt++;
341	return cnt;
342	}