#include <stdint.h>
#include "rcuja-internal.h"
-#include "bitfield.h"
#ifndef abs
#define abs_int(a) ((int) (a) > 0 ? (int) (a) : -((int) (a)))
return ptr;
}
+static
+struct cds_ja_inode_flag *ja_linear_node_get_left(const struct cds_ja_type *type,
+ struct cds_ja_inode *node,
+ unsigned int n)
+{
+ uint8_t nr_child;
+ uint8_t *values;
+ struct cds_ja_inode_flag **pointers;
+ struct cds_ja_inode_flag *ptr;
+ unsigned int i, match_idx;
+ int match_v = -1;
+
+ assert(type->type_class == RCU_JA_LINEAR || type->type_class == RCU_JA_POOL);
+
+ nr_child = ja_linear_node_get_nr_child(type, node);
+ cmm_smp_rmb(); /* read nr_child before values and pointers */
+ assert(nr_child <= type->max_linear_child);
+ assert(type->type_class != RCU_JA_LINEAR || nr_child >= type->min_child);
+
+ values = &node->u.data[1];
+ for (i = 0; i < nr_child; i++) {
+ unsigned int v;
+
+ v = CMM_LOAD_SHARED(values[i]);
+ if (v < n && (int) v > match_v) {
+ match_v = v;
+ match_idx = i;
+ }
+ }
+ if (match_v < 0) {
+ return NULL;
+ }
+ pointers = (struct cds_ja_inode_flag **) align_ptr_size(&values[type->max_linear_child]);
+ ptr = rcu_dereference(pointers[match_idx]);
+ return ptr;
+}
+
static
void ja_linear_node_get_ith_pos(const struct cds_ja_type *type,
struct cds_ja_inode *node,
&node->u.data[(unsigned int) i << type->pool_size_order];
}
+static
+struct cds_ja_inode_flag *ja_pool_node_get_left(const struct cds_ja_type *type,
+ struct cds_ja_inode *node,
+ unsigned int n)
+{
+ unsigned int pool_nr;
+ int match_v = -1;
+ struct cds_ja_inode_flag *match_node_flag = NULL;
+
+ assert(type->type_class == RCU_JA_POOL);
+
+ for (pool_nr = 0; pool_nr < (1U << type->nr_pool_order); pool_nr++) {
+ struct cds_ja_inode *pool =
+ ja_pool_node_get_ith_pool(type,
+ node, pool_nr);
+ uint8_t nr_child =
+ ja_linear_node_get_nr_child(type, pool);
+ unsigned int j;
+
+ for (j = 0; j < nr_child; j++) {
+ struct cds_ja_inode_flag *iter;
+ uint8_t v;
+
+ ja_linear_node_get_ith_pos(type, pool,
+ j, &v, &iter);
+ if (!iter)
+ continue;
+ if (v < n && (int) v > match_v) {
+ match_v = v;
+ match_node_flag = iter;
+ }
+ }
+ }
+ return match_node_flag;
+}
+
static
struct cds_ja_inode_flag *ja_pigeon_node_get_nth(const struct cds_ja_type *type,
struct cds_ja_inode *node,
return child_node_flag;
}
+static
+struct cds_ja_inode_flag *ja_pigeon_node_get_left(const struct cds_ja_type *type,
+ struct cds_ja_inode *node,
+ unsigned int n)
+{
+ struct cds_ja_inode_flag **child_node_flag_ptr;
+ struct cds_ja_inode_flag *child_node_flag;
+ int i;
+
+ assert(type->type_class == RCU_JA_PIGEON);
+
+ /* n - 1 is first value left of n */
+ for (i = n - 1; i >= 0; i--) {
+ child_node_flag_ptr = &((struct cds_ja_inode_flag **) node->u.data)[i];
+ child_node_flag = rcu_dereference(*child_node_flag_ptr);
+ if (child_node_flag) {
+ dbg_printf("ja_pigeon_node_get_left child_node_flag %p\n",
+ child_node_flag);
+ return child_node_flag;
+ }
+ }
+ return NULL;
+}
+
static
struct cds_ja_inode_flag *ja_pigeon_node_get_ith_pos(const struct cds_ja_type *type,
struct cds_ja_inode *node,
}
}
+static
+struct cds_ja_inode_flag *ja_node_get_left(struct cds_ja_inode_flag *node_flag,
+ unsigned int n)
+{
+ unsigned int type_index;
+ struct cds_ja_inode *node;
+ const struct cds_ja_type *type;
+
+ node = ja_node_ptr(node_flag);
+ assert(node != NULL);
+ type_index = ja_node_type(node_flag);
+ type = &ja_types[type_index];
+
+ switch (type->type_class) {
+ case RCU_JA_LINEAR:
+ return ja_linear_node_get_left(type, node, n);
+ case RCU_JA_POOL:
+ return ja_pool_node_get_left(type, node, n);
+ case RCU_JA_PIGEON:
+ return ja_pigeon_node_get_left(type, node, n);
+ default:
+ assert(0);
+ return (void *) -1UL;
+ }
+}
+
+static
+struct cds_ja_inode_flag *ja_node_get_rightmost(struct cds_ja_inode_flag *node_flag)
+{
+ return ja_node_get_left(node_flag, JA_ENTRY_PER_NODE);
+}
+
static
int ja_linear_node_set_nth(const struct cds_ja_type *type,
struct cds_ja_inode *node,
return head;
}
+struct cds_hlist_head cds_ja_lookup_lower_equal(struct cds_ja *ja, uint64_t key)
+{
+ int tree_depth, level;
+ struct cds_ja_inode_flag *node_flag, *cur_node_depth[JA_MAX_DEPTH];
+ struct cds_hlist_head head = { NULL };
+
+ if (caa_unlikely(key > ja->key_max || !key))
+ return head;
+
+ memset(cur_node_depth, 0, sizeof(cur_node_depth));
+ tree_depth = ja->tree_depth;
+ node_flag = rcu_dereference(ja->root);
+ cur_node_depth[0] = node_flag;
+
+ /* level 0: root node */
+ if (!ja_node_ptr(node_flag))
+ return head;
+
+ for (level = 1; level < tree_depth; level++) {
+ uint8_t iter_key;
+
+ iter_key = (uint8_t) (key >> (JA_BITS_PER_BYTE * (tree_depth - level - 1)));
+ node_flag = ja_node_get_nth(node_flag, NULL, iter_key);
+ if (!ja_node_ptr(node_flag))
+ break;
+ cur_node_depth[level] = node_flag;
+ dbg_printf("cds_ja_lookup iter key lookup %u finds node_flag %p\n",
+ (unsigned int) iter_key, node_flag);
+ }
+
+ if (level == tree_depth) {
+ /* Last level lookup succeded. We got an equal match. */
+ head.next = (struct cds_hlist_node *) node_flag;
+ return head;
+ }
+
+ /*
+ * Find highest value left of current node.
+ * Current node is cur_node_depth[level].
+ * Start at current level. If we cannot find any key left of
+ * ours, go one level up, seek highest value left of current
+ * (recursively), and when we find one, get the rightmost child
+ * of its rightmost child (recursively).
+ */
+ for (; level > 0; level--) {
+ uint8_t iter_key;
+
+ iter_key = (uint8_t) (key >> (JA_BITS_PER_BYTE * (tree_depth - level - 1)));
+ node_flag = ja_node_get_left(cur_node_depth[level - 1],
+ iter_key);
+ /* If found left sibling, find rightmost child. */
+ if (ja_node_ptr(node_flag))
+ break;
+ }
+
+ if (!level) {
+ /* Reached the root and could not find a left sibling. */
+ return head;
+ }
+
+ level++;
+
+ /*
+ * From this point, we are guaranteed to be able to find a
+ * "lower than" match. ja_attach_node() and ja_detach_node()
+ * both guarantee that it is not possible for a lookup to reach
+ * a dead-end.
+ */
+
+ /* Find rightmost child of rightmost child (recursively). */
+ for (; level < tree_depth; level++) {
+ node_flag = ja_node_get_rightmost(node_flag);
+ /* If found left sibling, find rightmost child. */
+ if (!ja_node_ptr(node_flag))
+ break;
+ }
+
+ assert(level == tree_depth);
+
+ head.next = (struct cds_hlist_node *) node_flag;
+ return head;
+}
+
/*
* We reached an unpopulated node. Create it and the children we need,
* and then attach the entire branch to the current node. This may
* parent lock (if needed). Then we can proceed to create the new
* branch. Publish the new branch, and release locks.
* TODO: we currently always take the parent lock even when not needed.
+ *
+ * ja_attach_node() ensures that a lookup will _never_ see a branch that
+ * leads to a dead-end: before attaching a branch, the entire content of
+ * the new branch is populated, thus creating a cluster, before
+ * attaching the cluster to the rest of the tree, thus making it visible
+ * to lookups.
*/
static
int ja_attach_node(struct cds_ja *ja,
* However, when a child is removed from "linear" nodes, its pointer
* is set to NULL. We therefore check, while holding the locks, if this
* pointer is NULL, and return -ENOENT to the caller if it is the case.
+ *
+ * ja_detach_node() ensures that a lookup will _never_ see a branch that
+ * leads to a dead-end: when removing branch, it makes sure to perform
+ * the "cut" at the highest node that has only one child, effectively
+ * replacing it with a NULL pointer.
*/
static
int ja_detach_node(struct cds_ja *ja,
__attribute__((visibility("protected")))
void rcuja_free_all_children(struct cds_ja_shadow_node *shadow_node,
struct cds_ja_inode_flag *node_flag,
- void (*free_node_cb)(struct rcu_head *head))
+ void (*rcu_free_node)(struct cds_ja_node *node))
{
- const struct rcu_flavor_struct *flavor;
unsigned int type_index;
struct cds_ja_inode *node;
const struct cds_ja_type *type;
- flavor = cds_lfht_rcu_flavor(shadow_node->ja->ht);
node = ja_node_ptr(node_flag);
assert(node != NULL);
type_index = ja_node_type(node_flag);
continue;
head.next = (struct cds_hlist_node *) iter;
cds_hlist_for_each_entry_safe(entry, pos, tmp, &head, list) {
- flavor->update_call_rcu(&entry->head, free_node_cb);
+ rcu_free_node(entry);
}
}
break;
continue;
head.next = (struct cds_hlist_node *) iter;
cds_hlist_for_each_entry_safe(entry, pos, tmp, &head, list) {
- flavor->update_call_rcu(&entry->head, free_node_cb);
+ rcu_free_node(entry);
}
}
}
continue;
head.next = (struct cds_hlist_node *) iter;
cds_hlist_for_each_entry_safe(entry, pos, tmp, &head, list) {
- flavor->update_call_rcu(&entry->head, free_node_cb);
+ rcu_free_node(entry);
}
}
break;
}
static
-void print_ja_debug_info(struct cds_ja *ja)
+int ja_final_checks(struct cds_ja *ja)
{
double fallback_ratio;
unsigned long na, nf, nr_fallback;
+ int ret = 0;
fallback_ratio = (double) uatomic_read(&ja->nr_fallback);
fallback_ratio /= (double) uatomic_read(&ja->nr_nodes_allocated);
na = uatomic_read(&ja->nr_nodes_allocated);
nf = uatomic_read(&ja->nr_nodes_freed);
+ dbg_printf("Nodes allocated: %lu, Nodes freed: %lu.\n", na, nf);
+ if (nr_fallback)
+ print_debug_fallback_distribution(ja);
+
if (na != nf) {
fprintf(stderr, "[error] Judy array leaked %ld nodes. Allocated: %lu, freed: %lu.\n",
(long) na - nf, na, nf);
+ ret = -1;
}
- dbg_printf("Nodes allocated: %lu, Nodes freed: %lu.\n", na, nf);
- if (nr_fallback)
- print_debug_fallback_distribution(ja);
+ return ret;
}
/*
* being destroyed (ensured by the caller).
*/
int cds_ja_destroy(struct cds_ja *ja,
- void (*free_node_cb)(struct rcu_head *head))
+ void (*rcu_free_node)(struct cds_ja_node *node))
{
const struct rcu_flavor_struct *flavor;
int ret;
flavor = cds_lfht_rcu_flavor(ja->ht);
rcuja_shadow_prune(ja->ht,
RCUJA_SHADOW_CLEAR_FREE_NODE | RCUJA_SHADOW_CLEAR_FREE_LOCK,
- free_node_cb);
+ rcu_free_node);
flavor->thread_offline();
ret = rcuja_delete_ht(ja->ht);
if (ret)
flavor->barrier();
flavor->thread_online();
- print_ja_debug_info(ja);
+ ret = ja_final_checks(ja);
free(ja);
- return 0;
+ return ret;
}