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|
/*
* %CopyrightBegin%
*
* Copyright Ericsson AB and Kjell Winblad 1998-2018. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* %CopyrightEnd%
*/
/*
* Description: Implementation of ETS ordered_set table type with
* fine-grained synchronization.
*
* Author: Kjell Winblad
*
* This implementation is based on the contention adapting search tree
* (CA tree). The CA tree is a concurrent data structure that
* dynamically adapts its synchronization granularity based on how
* much contention is detected in locks. The following publication
* contains a detailed description of CA trees:
*
* A Contention Adapting Approach to Concurrent Ordered Sets
* Journal of Parallel and Distributed Computing, 2018
* Kjell Winblad and Konstantinos Sagonas
* https://doi.org/10.1016/j.jpdc.2017.11.007
*
* The following publication may also be interesting as it discusses
* how the CA tree can be used as an ETS ordered_set table type
* backend:
*
* More Scalable Ordered Set for ETS Using Adaptation
* In Thirteenth ACM SIGPLAN workshop on Erlang (2014)
* Kjell Winblad and Konstantinos Sagonas
* https://doi.org/10.1145/2633448.2633455
*
* This implementation of the ordered_set ETS table type is only
* activated when the options {write_concurrency, true}, public and
* ordered_set are passed to the ets:new/2 function. This
* implementation is expected to scale better than the default
* implementation (located in "erl_db_tree.c") when concurrent
* processes use the following ETS operations to operate on a table:
*
* delete/2, delete_object/2, first/1, insert/2 (single object),
* insert_new/2 (single object), lookup/2, lookup_element/2, member/2,
* next/2, take/2 and update_element/3 (single object).
*
* Currently, the implementation does not have scalable support for
* the other operations (e.g., select/2). These operations are handled
* by merging all locks so that all terms get protected by a single
* lock. This implementation may thus perform worse than the default
* implementation in some scenarios. For example, when concurrent
* processes access a table with the operations insert/2, delete/2 and
* select/2, the insert/2 and delete/2 operations will trigger splits
* of locks (to get more fine-grained synchronization) but this will
* quickly be undone by the select/2 operation if this operation is
* also called frequently.
*
* The default implementation has a static stack optimization (see
* get_static_stack in erl_db_tree.c). This implementation does not
* have such an optimization as it induces bad scalability when
* concurrent read operations are frequent (they all try to get hold
* of the same stack). The default implementation may thus perform
* better compared to this implementation in scenarios where the
* static stack optimization is useful. One such scenario is when only
* one process is accessing the table and this process is traversing
* the table with a sequence of next/2 calls.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include "erl_vm.h"
#include "global.h"
#include "erl_process.h"
#include "error.h"
#define ERTS_WANT_DB_INTERNAL__
#include "erl_db.h"
#include "bif.h"
#include "big.h"
#include "erl_binary.h"
#include "erl_db_catree.h"
#include "erl_db_tree.h"
#include "erl_db_tree_util.h"
#ifdef DEBUG
# define IF_DEBUG(X) X
#else
# define IF_DEBUG(X)
#endif
/*
** Forward declarations
*/
static SWord do_free_base_node_cont(DbTableCATree *tb, SWord num_left);
static SWord do_free_routing_nodes_catree_cont(DbTableCATree *tb, SWord num_left);
static DbTableCATreeNode *catree_first_base_node_from_free_list(DbTableCATree *tb);
/* Method interface functions */
static int db_first_catree(Process *p, DbTable *tbl,
Eterm *ret);
static int db_next_catree(Process *p, DbTable *tbl,
Eterm key, Eterm *ret);
static int db_last_catree(Process *p, DbTable *tbl,
Eterm *ret);
static int db_prev_catree(Process *p, DbTable *tbl,
Eterm key,
Eterm *ret);
static int db_put_catree(DbTable *tbl, Eterm obj, int key_clash_fail);
static int db_get_catree(Process *p, DbTable *tbl,
Eterm key, Eterm *ret);
static int db_member_catree(DbTable *tbl, Eterm key, Eterm *ret);
static int db_get_element_catree(Process *p, DbTable *tbl,
Eterm key,int ndex,
Eterm *ret);
static int db_erase_catree(DbTable *tbl, Eterm key, Eterm *ret);
static int db_erase_object_catree(DbTable *tbl, Eterm object,Eterm *ret);
static int db_slot_catree(Process *p, DbTable *tbl,
Eterm slot_term, Eterm *ret);
static int db_select_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, int reversed, Eterm *ret);
static int db_select_count_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret);
static int db_select_chunk_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Sint chunk_size,
int reversed, Eterm *ret);
static int db_select_continue_catree(Process *p, DbTable *tbl,
Eterm continuation, Eterm *ret);
static int db_select_count_continue_catree(Process *p, DbTable *tbl,
Eterm continuation, Eterm *ret);
static int db_select_delete_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret);
static int db_select_delete_continue_catree(Process *p, DbTable *tbl,
Eterm continuation, Eterm *ret);
static int db_select_replace_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret);
static int db_select_replace_continue_catree(Process *p, DbTable *tbl,
Eterm continuation, Eterm *ret);
static int db_take_catree(Process *, DbTable *, Eterm, Eterm *);
static void db_print_catree(fmtfn_t to, void *to_arg,
int show, DbTable *tbl);
static int db_free_table_catree(DbTable *tbl);
static SWord db_free_table_continue_catree(DbTable *tbl, SWord);
static void db_foreach_offheap_catree(DbTable *,
void (*)(ErlOffHeap *, void *),
void *);
static SWord db_delete_all_objects_catree(Process* p, DbTable* tbl, SWord reds);
static int
db_lookup_dbterm_catree(Process *, DbTable *, Eterm key, Eterm obj,
DbUpdateHandle*);
static void db_finalize_dbterm_catree(int cret, DbUpdateHandle *);
static void split_catree(DbTableCATree *tb,
DbTableCATreeNode* ERTS_RESTRICT base,
DbTableCATreeNode* ERTS_RESTRICT parent);
static void join_catree(DbTableCATree *tb,
DbTableCATreeNode *thiz,
DbTableCATreeNode *parent);
/*
** External interface
*/
DbTableMethod db_catree =
{
db_create_catree,
db_first_catree,
db_next_catree,
db_last_catree,
db_prev_catree,
db_put_catree,
db_get_catree,
db_get_element_catree,
db_member_catree,
db_erase_catree,
db_erase_object_catree,
db_slot_catree,
db_select_chunk_catree,
db_select_catree,
db_select_delete_catree,
db_select_continue_catree,
db_select_delete_continue_catree,
db_select_count_catree,
db_select_count_continue_catree,
db_select_replace_catree,
db_select_replace_continue_catree,
db_take_catree,
db_delete_all_objects_catree,
db_free_table_catree,
db_free_table_continue_catree,
db_print_catree,
db_foreach_offheap_catree,
db_lookup_dbterm_catree,
db_finalize_dbterm_catree
};
/*
* Constants
*/
#define ERL_DB_CATREE_LOCK_FAILURE_CONTRIBUTION 200
#define ERL_DB_CATREE_LOCK_SUCCESS_CONTRIBUTION (-1)
#define ERL_DB_CATREE_LOCK_MORE_THAN_ONE_CONTRIBUTION (-10)
#define ERL_DB_CATREE_HIGH_CONTENTION_LIMIT 1000
#define ERL_DB_CATREE_LOW_CONTENTION_LIMIT (-1000)
#define ERL_DB_CATREE_MAX_ROUTE_NODE_LAYER_HEIGHT 14
/*
* Internal CA tree related helper functions and macros
*/
#define GET_ROUTE_NODE_KEY(node) (node->u.route.key.term)
#define GET_BASE_NODE_LOCK(node) (&(node->u.base.lock))
#define GET_ROUTE_NODE_LOCK(node) (&(node->u.route.lock))
/* Helpers for reading and writing shared atomic variables */
/* No memory barrier */
#define GET_ROOT(tb) ((DbTableCATreeNode*)erts_atomic_read_nob(&(tb->root)))
#define GET_LEFT(ca_tree_route_node) ((DbTableCATreeNode*)erts_atomic_read_nob(&(ca_tree_route_node->u.route.left)))
#define GET_RIGHT(ca_tree_route_node) ((DbTableCATreeNode*)erts_atomic_read_nob(&(ca_tree_route_node->u.route.right)))
#define SET_ROOT(tb, v) erts_atomic_set_nob(&((tb)->root), (erts_aint_t)(v))
#define SET_LEFT(ca_tree_route_node, v) erts_atomic_set_nob(&(ca_tree_route_node->u.route.left), (erts_aint_t)(v));
#define SET_RIGHT(ca_tree_route_node, v) erts_atomic_set_nob(&(ca_tree_route_node->u.route.right), (erts_aint_t)(v));
/* Release or acquire barriers */
#define GET_ROOT_ACQB(tb) ((DbTableCATreeNode*)erts_atomic_read_acqb(&(tb->root)))
#define GET_LEFT_ACQB(ca_tree_route_node) ((DbTableCATreeNode*)erts_atomic_read_acqb(&(ca_tree_route_node->u.route.left)))
#define GET_RIGHT_ACQB(ca_tree_route_node) ((DbTableCATreeNode*)erts_atomic_read_acqb(&(ca_tree_route_node->u.route.right)))
#define SET_ROOT_RELB(tb, v) erts_atomic_set_relb(&((tb)->root), (erts_aint_t)(v))
#define SET_LEFT_RELB(ca_tree_route_node, v) erts_atomic_set_relb(&(ca_tree_route_node->u.route.left), (erts_aint_t)(v));
#define SET_RIGHT_RELB(ca_tree_route_node, v) erts_atomic_set_relb(&(ca_tree_route_node->u.route.right), (erts_aint_t)(v));
/* Compares a key to the key in a route node */
static ERTS_INLINE Sint cmp_key_route(Eterm key,
DbTableCATreeNode *obj)
{
return CMP(key, GET_ROUTE_NODE_KEY(obj));
}
/*
* Used by the split_tree function
*/
static ERTS_INLINE
int less_than_two_elements(TreeDbTerm *root)
{
return root == NULL || (root->left == NULL && root->right == NULL);
}
/*
* Inserts a TreeDbTerm into a tree. Returns the new root.
*/
static ERTS_INLINE
TreeDbTerm* insert_TreeDbTerm(DbTableCATree *tb,
TreeDbTerm *insert_to_root,
TreeDbTerm *value_to_insert) {
/* Non recursive insertion in AVL tree, building our own stack */
TreeDbTerm **tstack[STACK_NEED];
int tpos = 0;
int dstack[STACK_NEED+1];
int dpos = 0;
int state = 0;
TreeDbTerm * base = insert_to_root;
TreeDbTerm **this = &base;
Sint c;
Eterm key;
int dir;
TreeDbTerm *p1, *p2, *p;
key = GETKEY(tb, value_to_insert->dbterm.tpl);
dstack[dpos++] = DIR_END;
for (;;)
if (!*this) { /* Found our place */
state = 1;
*this = value_to_insert;
(*this)->balance = 0;
(*this)->left = (*this)->right = NULL;
break;
} else if ((c = cmp_key(&tb->common, key, *this)) < 0) {
/* go lefts */
dstack[dpos++] = DIR_LEFT;
tstack[tpos++] = this;
this = &((*this)->left);
} else { /* go right */
dstack[dpos++] = DIR_RIGHT;
tstack[tpos++] = this;
this = &((*this)->right);
}
while (state && ( dir = dstack[--dpos] ) != DIR_END) {
this = tstack[--tpos];
p = *this;
if (dir == DIR_LEFT) {
switch (p->balance) {
case 1:
p->balance = 0;
state = 0;
break;
case 0:
p->balance = -1;
break;
case -1: /* The icky case */
p1 = p->left;
if (p1->balance == -1) { /* Single LL rotation */
p->left = p1->right;
p1->right = p;
p->balance = 0;
(*this) = p1;
} else { /* Double RR rotation */
p2 = p1->right;
p1->right = p2->left;
p2->left = p1;
p->left = p2->right;
p2->right = p;
p->balance = (p2->balance == -1) ? +1 : 0;
p1->balance = (p2->balance == 1) ? -1 : 0;
(*this) = p2;
}
(*this)->balance = 0;
state = 0;
break;
}
} else { /* dir == DIR_RIGHT */
switch (p->balance) {
case -1:
p->balance = 0;
state = 0;
break;
case 0:
p->balance = 1;
break;
case 1:
p1 = p->right;
if (p1->balance == 1) { /* Single RR rotation */
p->right = p1->left;
p1->left = p;
p->balance = 0;
(*this) = p1;
} else { /* Double RL rotation */
p2 = p1->left;
p1->left = p2->right;
p2->right = p1;
p->right = p2->left;
p2->left = p;
p->balance = (p2->balance == 1) ? -1 : 0;
p1->balance = (p2->balance == -1) ? 1 : 0;
(*this) = p2;
}
(*this)->balance = 0;
state = 0;
break;
}
}
}
return base;
}
/*
* Split an AVL tree into two trees. The function stores the node
* containing the "split key" in the write back parameter
* split_key_wb. The function stores the left tree containing the keys
* that are smaller than the "split key" in the write back parameter
* left_wb and the tree containing the rest of the keys in the write
* back parameter right_wb.
*/
static void split_tree(DbTableCATree *tb,
TreeDbTerm *root,
TreeDbTerm **split_key_node_wb,
TreeDbTerm **left_wb,
TreeDbTerm **right_wb) {
TreeDbTerm * split_node = NULL;
TreeDbTerm * left_root;
TreeDbTerm * right_root;
if (root->left == NULL) { /* To get non empty split */
*right_wb = root->right;
*split_key_node_wb = root->right;
root->right = NULL;
root->balance = 0;
*left_wb = root;
return;
}
split_node = root;
left_root = split_node->left;
split_node->left = NULL;
right_root = split_node->right;
split_node->right = NULL;
right_root = insert_TreeDbTerm(tb, right_root, split_node);
*split_key_node_wb = split_node;
*left_wb = left_root;
*right_wb = right_root;
}
/*
* Used by the join_trees function
*/
static ERTS_INLINE int compute_tree_hight(TreeDbTerm * root)
{
if(root == NULL) {
return 0;
} else {
TreeDbTerm * current_node = root;
int hight_so_far = 1;
while (current_node->left != NULL || current_node->right != NULL) {
if (current_node->balance == -1) {
current_node = current_node->left;
} else {
current_node = current_node->right;
}
hight_so_far = hight_so_far + 1;
}
return hight_so_far;
}
}
/*
* Used by the join_trees function
*/
static ERTS_INLINE
TreeDbTerm* linkout_min_or_max_tree_node(TreeDbTerm **root, int is_min)
{
TreeDbTerm **tstack[STACK_NEED];
int tpos = 0;
int dstack[STACK_NEED+1];
int dpos = 0;
int state = 0;
TreeDbTerm **this = root;
int dir;
TreeDbTerm *q = NULL;
dstack[dpos++] = DIR_END;
for (;;) {
if (!*this) { /* Failure */
return NULL;
} else if (is_min && (*this)->left != NULL) {
dstack[dpos++] = DIR_LEFT;
tstack[tpos++] = this;
this = &((*this)->left);
} else if (!is_min && (*this)->right != NULL) {
dstack[dpos++] = DIR_RIGHT;
tstack[tpos++] = this;
this = &((*this)->right);
} else { /* Min value, found the one to splice out */
q = (*this);
if (q->right == NULL) {
(*this) = q->left;
state = 1;
} else if (q->left == NULL) {
(*this) = q->right;
state = 1;
}
break;
}
}
while (state && ( dir = dstack[--dpos] ) != DIR_END) {
this = tstack[--tpos];
if (dir == DIR_LEFT) {
state = tree_balance_left(this);
} else {
state = tree_balance_right(this);
}
}
return q;
}
#define LINKOUT_MIN_TREE_NODE(root) linkout_min_or_max_tree_node(root, 1)
#define LINKOUT_MAX_TREE_NODE(root) linkout_min_or_max_tree_node(root, 0)
/*
* Joins two AVL trees where all the keys in the left one are smaller
* then the keys in the right one and returns the resulting tree.
*
* The algorithm is described on page 474 in D. E. Knuth. The Art of
* Computer Programming: Sorting and Searching,
* vol. 3. Addison-Wesley, 2nd edition, 1998.
*/
static TreeDbTerm* join_trees(TreeDbTerm *left_root_param,
TreeDbTerm *right_root_param)
{
TreeDbTerm **tstack[STACK_NEED];
int tpos = 0;
int dstack[STACK_NEED+1];
int dpos = 0;
int state = 1;
TreeDbTerm **this;
int dir;
TreeDbTerm *p1, *p2, *p;
TreeDbTerm *left_root = left_root_param;
TreeDbTerm *right_root = right_root_param;
int left_height;
int right_height;
int current_height;
dstack[dpos++] = DIR_END;
if (left_root == NULL) {
return right_root;
} else if (right_root == NULL) {
return left_root;
}
left_height = compute_tree_hight(left_root);
right_height = compute_tree_hight(right_root);
if (left_height >= right_height) {
TreeDbTerm * new_root =
LINKOUT_MIN_TREE_NODE(&right_root);
int new_right_height = compute_tree_hight(right_root);
TreeDbTerm * current_node = left_root;
this = &left_root;
current_height = left_height;
while(current_height > new_right_height + 1) {
if (current_node->balance == -1) {
current_height = current_height - 2;
} else {
current_height = current_height - 1;
}
dstack[dpos++] = DIR_RIGHT;
tstack[tpos++] = this;
this = &((*this)->right);
current_node = current_node->right;
}
new_root->left = current_node;
new_root->right = right_root;
new_root->balance = new_right_height - current_height;
*this = new_root;
} else {
/* This case is symmetric to the previous case */
TreeDbTerm * new_root =
LINKOUT_MAX_TREE_NODE(&left_root);
int new_left_height = compute_tree_hight(left_root);
TreeDbTerm * current_node = right_root;
this = &right_root;
current_height = right_height;
while (current_height > new_left_height + 1) {
if (current_node->balance == 1) {
current_height = current_height - 2;
} else {
current_height = current_height - 1;
}
dstack[dpos++] = DIR_LEFT;
tstack[tpos++] = this;
this = &((*this)->left);
current_node = current_node->left;
}
new_root->right = current_node;
new_root->left = left_root;
new_root->balance = current_height - new_left_height;
*this = new_root;
}
/* Now we need to continue as if this was during the insert */
while (state && ( dir = dstack[--dpos] ) != DIR_END) {
this = tstack[--tpos];
p = *this;
if (dir == DIR_LEFT) {
switch (p->balance) {
case 1:
p->balance = 0;
state = 0;
break;
case 0:
p->balance = -1;
break;
case -1: /* The icky case */
p1 = p->left;
if (p1->balance == -1) { /* Single LL rotation */
p->left = p1->right;
p1->right = p;
p->balance = 0;
(*this) = p1;
} else { /* Double RR rotation */
p2 = p1->right;
p1->right = p2->left;
p2->left = p1;
p->left = p2->right;
p2->right = p;
p->balance = (p2->balance == -1) ? +1 : 0;
p1->balance = (p2->balance == 1) ? -1 : 0;
(*this) = p2;
}
(*this)->balance = 0;
state = 0;
break;
}
} else { /* dir == DIR_RIGHT */
switch (p->balance) {
case -1:
p->balance = 0;
state = 0;
break;
case 0:
p->balance = 1;
break;
case 1:
p1 = p->right;
if (p1->balance == 1) { /* Single RR rotation */
p->right = p1->left;
p1->left = p;
p->balance = 0;
(*this) = p1;
} else { /* Double RL rotation */
p2 = p1->left;
p1->left = p2->right;
p2->right = p1;
p->right = p2->left;
p2->left = p;
p->balance = (p2->balance == 1) ? -1 : 0;
p1->balance = (p2->balance == -1) ? 1 : 0;
(*this) = p2;
}
(*this)->balance = 0;
state = 0;
break;
}
}
}
/* Return the joined tree */
if (left_height >= right_height) {
return left_root;
} else {
return right_root;
}
}
#ifdef DEBUG
# define FORCE_RANDOM_SPLIT_JOIN
#endif
#ifdef FORCE_RANDOM_SPLIT_JOIN
static int dbg_fastrand(void)
{
static int g_seed = 648835;
g_seed = (214013*g_seed+2531011);
return (g_seed>>16)&0x7FFF;
}
static void dbg_maybe_force_splitjoin(DbTableCATreeNode* base_node)
{
switch (dbg_fastrand() % 8) {
case 1:
base_node->u.base.lock_statistics = 1+ERL_DB_CATREE_HIGH_CONTENTION_LIMIT;
break;
case 2:
base_node->u.base.lock_statistics = -1+ERL_DB_CATREE_LOW_CONTENTION_LIMIT;
break;
}
}
#else
# define dbg_maybe_force_splitjoin(N)
#endif /* FORCE_RANDOM_SPLIT_JOIN */
static ERTS_INLINE
int try_wlock_base_node(DbTableCATreeBaseNode *base_node)
{
return EBUSY == erts_rwmtx_tryrwlock(&base_node->lock);
}
/*
* Locks a base node without adjusting the lock statistics
*/
static ERTS_INLINE
void wlock_base_node_no_stats(DbTableCATreeNode *base_node)
{
ASSERT(base_node->is_base_node);
erts_rwmtx_rwlock(&base_node->u.base.lock);
}
/*
* Locks a base node and adjusts the lock statistics according to if
* the lock was contended or not
*/
static ERTS_INLINE
void wlock_base_node(DbTableCATreeNode *base_node)
{
ASSERT(base_node->is_base_node);
if (try_wlock_base_node(&base_node->u.base)) {
/* The lock is contended */
wlock_base_node_no_stats(base_node);
base_node->u.base.lock_statistics += ERL_DB_CATREE_LOCK_FAILURE_CONTRIBUTION;
} else {
base_node->u.base.lock_statistics += ERL_DB_CATREE_LOCK_SUCCESS_CONTRIBUTION;
}
}
static ERTS_INLINE
void wunlock_base_node(DbTableCATreeNode *base_node)
{
erts_rwmtx_rwunlock(&base_node->u.base.lock);
}
static ERTS_INLINE
void wunlock_adapt_base_node(DbTableCATree* tb,
DbTableCATreeNode* node,
DbTableCATreeNode* parent,
int current_level)
{
dbg_maybe_force_splitjoin(node);
if ((!node->u.base.root && parent && !(tb->common.status
& DB_CATREE_FORCE_SPLIT))
|| node->u.base.lock_statistics < ERL_DB_CATREE_LOW_CONTENTION_LIMIT) {
join_catree(tb, node, parent);
}
else if (node->u.base.lock_statistics > ERL_DB_CATREE_HIGH_CONTENTION_LIMIT
&& current_level < ERL_DB_CATREE_MAX_ROUTE_NODE_LAYER_HEIGHT) {
split_catree(tb, node, parent);
}
else {
wunlock_base_node(node);
}
}
static ERTS_INLINE
void rlock_base_node(DbTableCATreeNode *base_node)
{
ASSERT(base_node->is_base_node);
erts_rwmtx_rlock(&base_node->u.base.lock);
}
static ERTS_INLINE
void runlock_base_node(DbTableCATreeNode *base_node)
{
ASSERT(base_node->is_base_node);
erts_rwmtx_runlock(&base_node->u.base.lock);
}
static ERTS_INLINE
void lock_route_node(DbTableCATreeNode *route_node)
{
ASSERT(!route_node->is_base_node);
erts_mtx_lock(&route_node->u.route.lock);
}
static ERTS_INLINE
void unlock_route_node(DbTableCATreeNode *route_node)
{
ASSERT(!route_node->is_base_node);
erts_mtx_unlock(&route_node->u.route.lock);
}
static ERTS_INLINE
void init_root_iterator(DbTableCATree* tb, CATreeRootIterator* iter,
int read_only)
{
iter->tb = tb;
iter->read_only = read_only;
iter->locked_bnode = NULL;
iter->next_route_key = THE_NON_VALUE;
iter->search_key = NULL;
}
static ERTS_INLINE
void lock_iter_base_node(CATreeRootIterator* iter,
DbTableCATreeNode *base_node,
DbTableCATreeNode *parent,
int current_level)
{
ASSERT(!iter->locked_bnode);
if (iter->read_only)
rlock_base_node(base_node);
else {
wlock_base_node(base_node);
iter->bnode_parent = parent;
iter->bnode_level = current_level;
}
iter->locked_bnode = base_node;
}
static ERTS_INLINE
void unlock_iter_base_node(CATreeRootIterator* iter)
{
ASSERT(iter->locked_bnode);
if (iter->read_only)
runlock_base_node(iter->locked_bnode);
else if (iter->locked_bnode->u.base.is_valid) {
wunlock_adapt_base_node(iter->tb, iter->locked_bnode,
iter->bnode_parent, iter->bnode_level);
}
else
wunlock_base_node(iter->locked_bnode);
iter->locked_bnode = NULL;
}
static ERTS_INLINE
void destroy_root_iterator(CATreeRootIterator* iter)
{
if (iter->locked_bnode)
unlock_iter_base_node(iter);
if (iter->search_key)
erts_free(ERTS_ALC_T_DB_TMP, iter->search_key);
}
typedef struct
{
DbTableCATreeNode *parent;
int current_level;
} FindBaseNode;
static ERTS_INLINE
DbTableCATreeNode* find_base_node(DbTableCATree* tb, Eterm key,
FindBaseNode* fbn)
{
DbTableCATreeNode* ERTS_RESTRICT node = GET_ROOT_ACQB(tb);
if (fbn) {
fbn->parent = NULL;
fbn->current_level = 0;
}
while (!node->is_base_node) {
if (fbn) {
fbn->current_level++;
fbn->parent = node;
}
if (cmp_key_route(key, node) < 0) {
node = GET_LEFT_ACQB(node);
} else {
node = GET_RIGHT_ACQB(node);
}
}
return node;
}
static ERTS_INLINE
DbTableCATreeNode* find_rlock_valid_base_node(DbTableCATree* tb, Eterm key)
{
DbTableCATreeNode* base_node;
while (1) {
base_node = find_base_node(tb, key, NULL);
rlock_base_node(base_node);
if (base_node->u.base.is_valid)
break;
runlock_base_node(base_node);
}
return base_node;
}
static ERTS_INLINE
DbTableCATreeNode* find_wlock_valid_base_node(DbTableCATree* tb, Eterm key,
FindBaseNode* fbn)
{
DbTableCATreeNode* base_node;
while (1) {
base_node = find_base_node(tb, key, fbn);
wlock_base_node(base_node);
if (base_node->u.base.is_valid)
break;
wunlock_base_node(base_node);
}
return base_node;
}
static ERTS_INLINE
Eterm copy_route_key(DbRouteKey* dst, Eterm key, Uint key_size)
{
dst->size = key_size;
if (key_size != 0) {
Eterm* hp = &dst->heap[0];
ErlOffHeap tmp_offheap;
tmp_offheap.first = NULL;
dst->term = copy_struct(key, key_size, &hp, &tmp_offheap);
dst->oh = tmp_offheap.first;
}
else {
ASSERT(is_immed(key));
dst->term = key;
dst->oh = NULL;
}
return dst->term;
}
static ERTS_INLINE
void destroy_route_key(DbRouteKey* key)
{
if (key->oh) {
ErlOffHeap oh;
oh.first = key->oh;
erts_cleanup_offheap(&oh);
}
}
#ifdef ERTS_ENABLE_LOCK_CHECK
# define LC_ORDER(ORDER) ORDER
#else
# define LC_ORDER(ORDER) NIL
#endif
#define sizeof_base_node() \
offsetof(DbTableCATreeNode, u.base.end_of_struct__)
static DbTableCATreeNode *create_base_node(DbTableCATree *tb,
TreeDbTerm* root)
{
DbTableCATreeNode *p;
erts_rwmtx_opt_t rwmtx_opt = ERTS_RWMTX_OPT_DEFAULT_INITER;
p = erts_db_alloc(ERTS_ALC_T_DB_TABLE, (DbTable *) tb,
sizeof_base_node());
p->is_base_node = 1;
p->u.base.root = root;
if (tb->common.type & DB_FREQ_READ)
rwmtx_opt.type = ERTS_RWMTX_TYPE_FREQUENT_READ;
if (erts_ets_rwmtx_spin_count >= 0)
rwmtx_opt.main_spincount = erts_ets_rwmtx_spin_count;
erts_rwmtx_init_opt(&p->u.base.lock, &rwmtx_opt,
"erl_db_catree_base_node",
NIL,
ERTS_LOCK_FLAGS_CATEGORY_DB);
p->u.base.lock_statistics = ((tb->common.status & DB_CATREE_FORCE_SPLIT)
? INT_MAX : 0);
p->u.base.is_valid = 1;
return p;
}
static ERTS_INLINE Uint sizeof_route_node(Uint key_size)
{
return (offsetof(DbTableCATreeNode, u.route.key.heap)
+ key_size*sizeof(Eterm));
}
static DbTableCATreeNode*
create_route_node(DbTableCATree *tb,
DbTableCATreeNode *left,
DbTableCATreeNode *right,
DbTerm * keyTerm,
DbTableCATreeNode* lc_parent)
{
Eterm key = GETKEY(tb,keyTerm->tpl);
int key_size = size_object(key);
DbTableCATreeNode* p = erts_db_alloc(ERTS_ALC_T_DB_TABLE,
(DbTable *) tb,
sizeof_route_node(key_size));
copy_route_key(&p->u.route.key, key, key_size);
p->is_base_node = 0;
p->u.route.is_valid = 1;
erts_atomic_init_nob(&p->u.route.left, (erts_aint_t)left);
erts_atomic_init_nob(&p->u.route.right, (erts_aint_t)right);
#ifdef ERTS_ENABLE_LOCK_CHECK
/* Route node lock order is inverse tree depth (from leafs toward root) */
p->u.route.lc_order = (lc_parent == NULL ? MAX_SMALL :
lc_parent->u.route.lc_order - 1);
/*
* This assert may eventually fail as we don't increase 'lc_order' in join
* operations when route nodes move up in the tree.
* Tough luck if you run a lock-checking VM for such a long time on 32-bit.
*/
ERTS_LC_ASSERT(p->u.route.lc_order >= 0);
#endif
erts_mtx_init(&p->u.route.lock, "erl_db_catree_route_node",
LC_ORDER(make_small(p->u.route.lc_order)),
ERTS_LOCK_FLAGS_CATEGORY_DB);
return p;
}
static void do_free_base_node(void* vptr)
{
DbTableCATreeNode *p = (DbTableCATreeNode *)vptr;
ASSERT(p->is_base_node);
erts_rwmtx_destroy(&p->u.base.lock);
erts_free(ERTS_ALC_T_DB_TABLE, p);
}
static void free_catree_base_node(DbTableCATree* tb, DbTableCATreeNode* p)
{
ASSERT(p->is_base_node);
ERTS_DB_ALC_MEM_UPDATE_(tb, sizeof_base_node(), 0);
do_free_base_node(p);
}
static void do_free_route_node(void *vptr)
{
DbTableCATreeNode *p = (DbTableCATreeNode *)vptr;
ASSERT(!p->is_base_node);
erts_mtx_destroy(&p->u.route.lock);
destroy_route_key(&p->u.route.key);
erts_free(ERTS_ALC_T_DB_TABLE, p);
}
static void free_catree_route_node(DbTableCATree* tb, DbTableCATreeNode* p)
{
ASSERT(!p->is_base_node);
ERTS_DB_ALC_MEM_UPDATE_(tb, sizeof_route_node(p->u.route.key.size), 0);
do_free_route_node(p);
}
/*
* Returns the parent routing node of the specified
* route node 'child' if such a parent exists
* or NULL if 'child' is attached to the root.
*/
static ERTS_INLINE DbTableCATreeNode *
parent_of(DbTableCATree *tb,
DbTableCATreeNode *child)
{
Eterm key = GET_ROUTE_NODE_KEY(child);
DbTableCATreeNode *current = GET_ROOT_ACQB(tb);
DbTableCATreeNode *prev = NULL;
while (current != child) {
prev = current;
if (cmp_key_route(key, current) < 0) {
current = GET_LEFT_ACQB(current);
} else {
current = GET_RIGHT_ACQB(current);
}
}
return prev;
}
static ERTS_INLINE DbTableCATreeNode *
leftmost_base_node(DbTableCATreeNode *root)
{
DbTableCATreeNode *node = root;
while (!node->is_base_node) {
node = GET_LEFT_ACQB(node);
}
return node;
}
static ERTS_INLINE DbTableCATreeNode *
rightmost_base_node(DbTableCATreeNode *root)
{
DbTableCATreeNode *node = root;
while (!node->is_base_node) {
node = GET_RIGHT_ACQB(node);
}
return node;
}
static ERTS_INLINE DbTableCATreeNode *
leftmost_route_node(DbTableCATreeNode *root)
{
DbTableCATreeNode *node = root;
DbTableCATreeNode *prev_node = NULL;
while (!node->is_base_node) {
prev_node = node;
node = GET_LEFT_ACQB(node);
}
return prev_node;
}
static ERTS_INLINE DbTableCATreeNode*
rightmost_route_node(DbTableCATreeNode *root)
{
DbTableCATreeNode * node = root;
DbTableCATreeNode * prev_node = NULL;
while (!node->is_base_node) {
prev_node = node;
node = GET_RIGHT_ACQB(node);
}
return prev_node;
}
static ERTS_INLINE
void init_tree_stack(DbTreeStack *stack,
TreeDbTerm **stack_array,
Uint init_slot)
{
stack->array = stack_array;
stack->pos = 0;
stack->slot = init_slot;
}
static void join_catree(DbTableCATree *tb,
DbTableCATreeNode *thiz,
DbTableCATreeNode *parent)
{
DbTableCATreeNode *gparent;
DbTableCATreeNode *neighbor;
DbTableCATreeNode *new_neighbor;
DbTableCATreeNode *neighbor_parent;
ASSERT(thiz->is_base_node);
if (parent == NULL) {
thiz->u.base.lock_statistics = 0;
wunlock_base_node(thiz);
return;
}
ASSERT(!parent->is_base_node);
if (GET_LEFT(parent) == thiz) {
neighbor = leftmost_base_node(GET_RIGHT_ACQB(parent));
if (try_wlock_base_node(&neighbor->u.base)) {
/* Failed to acquire lock */
thiz->u.base.lock_statistics = 0;
wunlock_base_node(thiz);
return;
} else if (!neighbor->u.base.is_valid) {
thiz->u.base.lock_statistics = 0;
wunlock_base_node(thiz);
wunlock_base_node(neighbor);
return;
} else {
lock_route_node(parent);
parent->u.route.is_valid = 0;
neighbor->u.base.is_valid = 0;
thiz->u.base.is_valid = 0;
gparent = NULL;
do {
if (gparent != NULL) {
unlock_route_node(gparent);
}
gparent = parent_of(tb, parent);
if (gparent != NULL)
lock_route_node(gparent);
} while (gparent != NULL && !gparent->u.route.is_valid);
if (gparent == NULL) {
SET_ROOT_RELB(tb, GET_RIGHT(parent));
} else if (GET_LEFT(gparent) == parent) {
SET_LEFT_RELB(gparent, GET_RIGHT(parent));
} else {
SET_RIGHT_RELB(gparent, GET_RIGHT(parent));
}
unlock_route_node(parent);
if (gparent != NULL) {
unlock_route_node(gparent);
}
{
TreeDbTerm* new_root = join_trees(thiz->u.base.root,
neighbor->u.base.root);
new_neighbor = create_base_node(tb, new_root);
}
if (GET_RIGHT(parent) == neighbor) {
neighbor_parent = gparent;
} else {
neighbor_parent = leftmost_route_node(GET_RIGHT(parent));
}
}
} else { /* Symetric case */
ASSERT(GET_RIGHT(parent) == thiz);
neighbor = rightmost_base_node(GET_LEFT_ACQB(parent));
if (try_wlock_base_node(&neighbor->u.base)) {
/* Failed to acquire lock */
thiz->u.base.lock_statistics = 0;
wunlock_base_node(thiz);
return;
} else if (!neighbor->u.base.is_valid) {
thiz->u.base.lock_statistics = 0;
wunlock_base_node(thiz);
wunlock_base_node(neighbor);
return;
} else {
lock_route_node(parent);
parent->u.route.is_valid = 0;
neighbor->u.base.is_valid = 0;
thiz->u.base.is_valid = 0;
gparent = NULL;
do {
if (gparent != NULL) {
unlock_route_node(gparent);
}
gparent = parent_of(tb, parent);
if (gparent != NULL) {
lock_route_node(gparent);
} else {
gparent = NULL;
}
} while (gparent != NULL && !gparent->u.route.is_valid);
if (gparent == NULL) {
SET_ROOT_RELB(tb, GET_LEFT(parent));
} else if (GET_RIGHT(gparent) == parent) {
SET_RIGHT_RELB(gparent, GET_LEFT(parent));
} else {
SET_LEFT_RELB(gparent, GET_LEFT(parent));
}
unlock_route_node(parent);
if (gparent != NULL) {
unlock_route_node(gparent);
}
{
TreeDbTerm* new_root = join_trees(neighbor->u.base.root,
thiz->u.base.root);
new_neighbor = create_base_node(tb, new_root);
}
if (GET_LEFT(parent) == neighbor) {
neighbor_parent = gparent;
} else {
neighbor_parent =
rightmost_route_node(GET_LEFT(parent));
}
}
}
/* Link in new neighbor and free nodes that are no longer in the tree */
if (neighbor_parent == NULL) {
SET_ROOT_RELB(tb, new_neighbor);
} else if (GET_LEFT(neighbor_parent) == neighbor) {
SET_LEFT_RELB(neighbor_parent, new_neighbor);
} else {
SET_RIGHT_RELB(neighbor_parent, new_neighbor);
}
wunlock_base_node(thiz);
wunlock_base_node(neighbor);
/* Free the parent and base */
erts_schedule_db_free(&tb->common,
do_free_route_node,
parent,
&parent->u.route.free_item,
sizeof_route_node(parent->u.route.key.size));
erts_schedule_db_free(&tb->common,
do_free_base_node,
thiz,
&thiz->u.base.free_item,
sizeof_base_node());
erts_schedule_db_free(&tb->common,
do_free_base_node,
neighbor,
&neighbor->u.base.free_item,
sizeof_base_node());
}
static void split_catree(DbTableCATree *tb,
DbTableCATreeNode* ERTS_RESTRICT base,
DbTableCATreeNode* ERTS_RESTRICT parent)
{
TreeDbTerm *splitOutWriteBack;
DbTableCATreeNode* ERTS_RESTRICT new_left;
DbTableCATreeNode* ERTS_RESTRICT new_right;
DbTableCATreeNode* ERTS_RESTRICT new_route;
if (less_than_two_elements(base->u.base.root)) {
if (!(tb->common.status & DB_CATREE_FORCE_SPLIT))
base->u.base.lock_statistics = 0;
wunlock_base_node(base);
return;
} else {
TreeDbTerm *left_tree;
TreeDbTerm *right_tree;
split_tree(tb, base->u.base.root, &splitOutWriteBack,
&left_tree, &right_tree);
new_left = create_base_node(tb, left_tree);
new_right = create_base_node(tb, right_tree);
new_route = create_route_node(tb,
new_left,
new_right,
&splitOutWriteBack->dbterm,
parent);
if (parent == NULL) {
SET_ROOT_RELB(tb, new_route);
} else if(GET_LEFT(parent) == base) {
SET_LEFT_RELB(parent, new_route);
} else {
SET_RIGHT_RELB(parent, new_route);
}
base->u.base.is_valid = 0;
wunlock_base_node(base);
erts_schedule_db_free(&tb->common,
do_free_base_node,
base,
&base->u.base.free_item,
sizeof_base_node());
}
}
/*
* Helper functions for removing the table
*/
static void catree_add_base_node_to_free_list(
DbTableCATree *tb,
DbTableCATreeNode *base_node_container)
{
base_node_container->u.base.next =
tb->base_nodes_to_free_list;
tb->base_nodes_to_free_list = base_node_container;
}
static void catree_deque_base_node_from_free_list(DbTableCATree *tb)
{
if (tb->base_nodes_to_free_list == NULL) {
return; /* List empty */
} else {
DbTableCATreeNode *first = tb->base_nodes_to_free_list;
tb->base_nodes_to_free_list = first->u.base.next;
}
}
static DbTableCATreeNode *catree_first_base_node_from_free_list(
DbTableCATree *tb)
{
return tb->base_nodes_to_free_list;
}
static SWord do_free_routing_nodes_catree_cont(DbTableCATree *tb, SWord num_left)
{
DbTableCATreeNode *root;
DbTableCATreeNode *p;
for (;;) {
root = POP_NODE(&tb->free_stack_rnodes);
if (root == NULL) break;
else if(root->is_base_node) {
catree_add_base_node_to_free_list(tb, root);
break;
}
for (;;) {
if ((GET_LEFT(root) != NULL) &&
(p = GET_LEFT(root))->is_base_node) {
SET_LEFT(root, NULL);
catree_add_base_node_to_free_list(tb, p);
} else if ((GET_RIGHT(root) != NULL) &&
(p = GET_RIGHT(root))->is_base_node) {
SET_RIGHT(root, NULL);
catree_add_base_node_to_free_list(tb, p);
} else if ((p = GET_LEFT(root)) != NULL) {
SET_LEFT(root, NULL);
PUSH_NODE(&tb->free_stack_rnodes, root);
root = p;
} else if ((p = GET_RIGHT(root)) != NULL) {
SET_RIGHT(root, NULL);
PUSH_NODE(&tb->free_stack_rnodes, root);
root = p;
} else {
free_catree_route_node(tb, root);
if (--num_left >= 0) {
break;
} else {
return num_left; /* Done enough for now */
}
}
}
}
return num_left;
}
static SWord do_free_base_node_cont(DbTableCATree *tb, SWord num_left)
{
TreeDbTerm *root;
TreeDbTerm *p;
DbTableCATreeNode *base_node_container =
catree_first_base_node_from_free_list(tb);
for (;;) {
root = POP_NODE(&tb->free_stack_elems);
if (root == NULL) break;
for (;;) {
if ((p = root->left) != NULL) {
root->left = NULL;
PUSH_NODE(&tb->free_stack_elems, root);
root = p;
} else if ((p = root->right) != NULL) {
root->right = NULL;
PUSH_NODE(&tb->free_stack_elems, root);
root = p;
} else {
free_term((DbTable*)tb, root);
if (--num_left >= 0) {
break;
} else {
return num_left; /* Done enough for now */
}
}
}
}
catree_deque_base_node_from_free_list(tb);
free_catree_base_node(tb, base_node_container);
base_node_container = catree_first_base_node_from_free_list(tb);
if (base_node_container != NULL) {
PUSH_NODE(&tb->free_stack_elems, base_node_container->u.base.root);
}
return num_left;
}
/*
** Initialization function
*/
void db_initialize_catree(void)
{
return;
};
/*
** Table interface routines (i.e., what's called by the bif's)
*/
int db_create_catree(Process *p, DbTable *tbl)
{
DbTableCATree *tb = &tbl->catree;
DbTableCATreeNode *root;
root = create_base_node(tb, NULL);
tb->deletion = 0;
tb->base_nodes_to_free_list = NULL;
erts_atomic_init_relb(&(tb->root), (erts_aint_t)root);
return DB_ERROR_NONE;
}
static int db_first_catree(Process *p, DbTable *tbl, Eterm *ret)
{
TreeDbTerm *root;
CATreeRootIterator iter;
int result;
init_root_iterator(&tbl->catree, &iter, 1);
root = *catree_find_first_root(&iter);
if (!root) {
TreeDbTerm **pp = catree_find_next_root(&iter, NULL);
root = pp ? *pp : NULL;
}
result = db_first_tree_common(p, tbl, root, ret, NULL);
destroy_root_iterator(&iter);
return result;
}
static int db_next_catree(Process *p, DbTable *tbl, Eterm key, Eterm *ret)
{
DbTreeStack stack;
TreeDbTerm * stack_array[STACK_NEED];
TreeDbTerm **rootp;
CATreeRootIterator iter;
int result;
init_root_iterator(&tbl->catree, &iter, 1);
iter.next_route_key = key;
rootp = catree_find_next_root(&iter, NULL);
do {
init_tree_stack(&stack, stack_array, 0);
result = db_next_tree_common(p, tbl, (rootp ? *rootp : NULL), key, ret, &stack);
if (result != DB_ERROR_NONE || *ret != am_EOT)
break;
rootp = catree_find_next_root(&iter, NULL);
} while (rootp);
destroy_root_iterator(&iter);
return result;
}
static int db_last_catree(Process *p, DbTable *tbl, Eterm *ret)
{
TreeDbTerm *root;
CATreeRootIterator iter;
int result;
init_root_iterator(&tbl->catree, &iter, 1);
root = *catree_find_last_root(&iter);
if (!root) {
TreeDbTerm **pp = catree_find_prev_root(&iter, NULL);
root = pp ? *pp : NULL;
}
result = db_last_tree_common(p, tbl, root, ret, NULL);
destroy_root_iterator(&iter);
return result;
}
static int db_prev_catree(Process *p, DbTable *tbl, Eterm key, Eterm *ret)
{
DbTreeStack stack;
TreeDbTerm * stack_array[STACK_NEED];
TreeDbTerm **rootp;
CATreeRootIterator iter;
int result;
init_root_iterator(&tbl->catree, &iter, 1);
iter.next_route_key = key;
rootp = catree_find_prev_root(&iter, NULL);
do {
init_tree_stack(&stack, stack_array, 0);
result = db_prev_tree_common(p, tbl, (rootp ? *rootp : NULL), key, ret,
&stack);
if (result != DB_ERROR_NONE || *ret != am_EOT)
break;
rootp = catree_find_prev_root(&iter, NULL);
} while (rootp);
destroy_root_iterator(&iter);
return result;
}
static int db_put_catree(DbTable *tbl, Eterm obj, int key_clash_fail)
{
DbTableCATree *tb = &tbl->catree;
Eterm key = GETKEY(&tb->common, tuple_val(obj));
FindBaseNode fbn;
DbTableCATreeNode* node = find_wlock_valid_base_node(tb, key, &fbn);
int result = db_put_tree_common(&tb->common, &node->u.base.root, obj,
key_clash_fail, NULL);
wunlock_adapt_base_node(tb, node, fbn.parent, fbn.current_level);
return result;
}
static int db_get_catree(Process *p, DbTable *tbl, Eterm key, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
DbTableCATreeNode* node = find_rlock_valid_base_node(tb, key);
int result = db_get_tree_common(p, &tb->common,
node->u.base.root,
key, ret, NULL);
runlock_base_node(node);
return result;
}
TreeDbTerm** catree_find_root(Eterm key, CATreeRootIterator* iter)
{
FindBaseNode fbn;
DbTableCATreeNode* base_node;
while (1) {
base_node = find_base_node(iter->tb, key, &fbn);
lock_iter_base_node(iter, base_node, fbn.parent, fbn.current_level);
if (base_node->u.base.is_valid)
break;
unlock_iter_base_node(iter);
}
return &base_node->u.base.root;
}
static Eterm save_iter_search_key(CATreeRootIterator* iter, Eterm key)
{
Uint key_size;
if (is_immed(key))
return key;
if (iter->search_key) {
if (key == iter->search_key->term)
return key; /* already saved */
destroy_route_key(iter->search_key);
}
key_size = size_object(key);
if (!iter->search_key || key_size > iter->search_key->size) {
iter->search_key = erts_realloc(ERTS_ALC_T_DB_TMP,
iter->search_key,
(offsetof(DbRouteKey, heap)
+ key_size*sizeof(Eterm)));
}
return copy_route_key(iter->search_key, key, key_size);
}
TreeDbTerm** catree_find_nextprev_root(CATreeRootIterator *iter,
int forward,
Eterm *search_keyp)
{
#ifdef DEBUG
DbTableCATreeNode *rejected_invalid = NULL;
DbTableCATreeNode *rejected_empty = NULL;
#endif
DbTableCATreeNode *node;
DbTableCATreeNode *parent;
DbTableCATreeNode* next_route_node;
Eterm route_key = iter->next_route_key;
int current_level;
if (iter->locked_bnode) {
if (search_keyp)
*search_keyp = save_iter_search_key(iter, *search_keyp);
unlock_iter_base_node(iter);
}
if (is_non_value(route_key))
return NULL;
while (1) {
node = GET_ROOT_ACQB(iter->tb);
current_level = 0;
parent = NULL;
next_route_node = NULL;
while (!node->is_base_node) {
current_level++;
parent = node;
if (forward) {
if (cmp_key_route(route_key,node) < 0) {
next_route_node = node;
node = GET_LEFT_ACQB(node);
} else {
node = GET_RIGHT_ACQB(node);
}
}
else {
if (cmp_key_route(route_key,node) > 0) {
next_route_node = node;
node = GET_RIGHT_ACQB(node);
} else {
node = GET_LEFT_ACQB(node);
}
}
}
ASSERT(node != rejected_invalid);
lock_iter_base_node(iter, node, parent, current_level);
if (node->u.base.is_valid) {
ASSERT(node != rejected_empty);
if (node->u.base.root) {
iter->next_route_key = (next_route_node ?
next_route_node->u.route.key.term :
THE_NON_VALUE);
iter->locked_bnode = node;
return &node->u.base.root;
}
if (!next_route_node) {
unlock_iter_base_node(iter);
return NULL;
}
route_key = next_route_node->u.route.key.term;
IF_DEBUG(rejected_empty = node);
}
else
IF_DEBUG(rejected_invalid = node);
/* Retry */
unlock_iter_base_node(iter);
}
}
TreeDbTerm** catree_find_next_root(CATreeRootIterator *iter, Eterm* keyp)
{
return catree_find_nextprev_root(iter, 1, keyp);
}
TreeDbTerm** catree_find_prev_root(CATreeRootIterator *iter, Eterm* keyp)
{
return catree_find_nextprev_root(iter, 0, keyp);
}
/* @brief Find root of tree where object with smallest key of all larger than
* partially bound key may reside. Can be used as a starting point for
* a reverse iteration with pb_key.
*
* @param pb_key The partially bound key. Example {42, '$1'}
* @param iter An initialized root iterator.
*
* @return Pointer to found root pointer. May not be NULL.
*/
TreeDbTerm** catree_find_next_from_pb_key_root(Eterm pb_key,
CATreeRootIterator* iter)
{
#ifdef DEBUG
DbTableCATreeNode *rejected_base = NULL;
#endif
DbTableCATreeNode *node;
DbTableCATreeNode *parent;
DbTableCATreeNode* next_route_node;
int current_level;
ASSERT(!iter->locked_bnode);
while (1) {
node = GET_ROOT_ACQB(iter->tb);
current_level = 0;
parent = NULL;
next_route_node = NULL;
while (!node->is_base_node) {
current_level++;
parent = node;
if (cmp_partly_bound(pb_key, GET_ROUTE_NODE_KEY(node)) >= 0) {
next_route_node = node;
node = GET_RIGHT_ACQB(node);
} else {
node = GET_LEFT_ACQB(node);
}
}
ASSERT(node != rejected_base);
lock_iter_base_node(iter, node, parent, current_level);
if (node->u.base.is_valid) {
iter->next_route_key = (next_route_node ?
next_route_node->u.route.key.term :
THE_NON_VALUE);
return &node->u.base.root;
}
/* Retry */
unlock_iter_base_node(iter);
#ifdef DEBUG
rejected_base = node;
#endif
}
}
/* @brief Find root of tree where object with largest key of all smaller than
* partially bound key may reside. Can be used as a starting point for
* a forward iteration with pb_key.
*
* @param pb_key The partially bound key. Example {42, '$1'}
* @param iter An initialized root iterator.
*
* @return Pointer to found root pointer. May not be NULL.
*/
TreeDbTerm** catree_find_prev_from_pb_key_root(Eterm key,
CATreeRootIterator* iter)
{
#ifdef DEBUG
DbTableCATreeNode *rejected_base = NULL;
#endif
DbTableCATreeNode *node;
DbTableCATreeNode *parent;
DbTableCATreeNode* next_route_node;
int current_level;
ASSERT(!iter->locked_bnode);
while (1) {
node = GET_ROOT_ACQB(iter->tb);
current_level = 0;
parent = NULL;
next_route_node = NULL;
while (!node->is_base_node) {
current_level++;
parent = node;
if (cmp_partly_bound(key, GET_ROUTE_NODE_KEY(node)) <= 0) {
next_route_node = node;
node = GET_LEFT_ACQB(node);
} else {
node = GET_RIGHT_ACQB(node);
}
}
ASSERT(node != rejected_base);
lock_iter_base_node(iter, node, parent, current_level);
if (node->u.base.is_valid) {
iter->next_route_key = (next_route_node ?
next_route_node->u.route.key.term :
THE_NON_VALUE);
return &node->u.base.root;
}
/* Retry */
unlock_iter_base_node(iter);
#ifdef DEBUG
rejected_base = node;
#endif
}
}
static TreeDbTerm** catree_find_firstlast_root(CATreeRootIterator* iter,
int first)
{
#ifdef DEBUG
DbTableCATreeNode *rejected_base = NULL;
#endif
DbTableCATreeNode *node;
DbTableCATreeNode* next_route_node;
int current_level;
while (1) {
node = GET_ROOT_ACQB(iter->tb);
current_level = 0;
next_route_node = NULL;
while (!node->is_base_node) {
current_level++;
next_route_node = node;
node = first ? GET_LEFT_ACQB(node) : GET_RIGHT_ACQB(node);
}
ASSERT(node != rejected_base);
lock_iter_base_node(iter, node, next_route_node, current_level);
if (node->u.base.is_valid) {
iter->next_route_key = (next_route_node ?
next_route_node->u.route.key.term :
THE_NON_VALUE);
return &node->u.base.root;
}
/* Retry */
unlock_iter_base_node(iter);
#ifdef DEBUG
rejected_base = node;
#endif
}
}
TreeDbTerm** catree_find_first_root(CATreeRootIterator* iter)
{
return catree_find_firstlast_root(iter, 1);
}
TreeDbTerm** catree_find_last_root(CATreeRootIterator* iter)
{
return catree_find_firstlast_root(iter, 0);
}
static int db_member_catree(DbTable *tbl, Eterm key, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
DbTableCATreeNode* node = find_rlock_valid_base_node(tb, key);
int result = db_member_tree_common(&tb->common,
node->u.base.root,
key, ret, NULL);
runlock_base_node(node);
return result;
}
static int db_get_element_catree(Process *p, DbTable *tbl,
Eterm key, int ndex, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
DbTableCATreeNode* node = find_rlock_valid_base_node(tb, key);
int result = db_get_element_tree_common(p, &tb->common,
node->u.base.root,
key, ndex, ret, NULL);
runlock_base_node(node);
return result;
}
static int db_erase_catree(DbTable *tbl, Eterm key, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
FindBaseNode fbn;
DbTableCATreeNode* node = find_wlock_valid_base_node(tb, key, &fbn);
int result = db_erase_tree_common(tbl, &node->u.base.root, key,
ret, NULL);
wunlock_adapt_base_node(tb, node, fbn.parent, fbn.current_level);
return result;
}
static int db_erase_object_catree(DbTable *tbl, Eterm object, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
Eterm key = GETKEY(&tb->common, tuple_val(object));
FindBaseNode fbn;
DbTableCATreeNode* node = find_wlock_valid_base_node(tb, key, &fbn);
int result = db_erase_object_tree_common(tbl,
&node->u.base.root,
object,
ret,
NULL);
wunlock_adapt_base_node(tb, node, fbn.parent, fbn.current_level);
return result;
}
static int db_slot_catree(Process *p, DbTable *tbl,
Eterm slot_term, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_slot_tree_common(p, tbl, *catree_find_first_root(&iter),
slot_term, ret, NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_continue_catree(Process *p,
DbTable *tbl,
Eterm continuation,
Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_select_continue_tree_common(p, &tbl->common,
continuation, ret, NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, int reverse, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_select_tree_common(p, tbl, tid, pattern, reverse, ret,
NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_count_continue_catree(Process *p,
DbTable *tbl,
Eterm continuation,
Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_select_count_continue_tree_common(p, tbl,
continuation, ret, NULL,
&iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_count_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_select_count_tree_common(p, tbl,
tid, pattern, ret, NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_chunk_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Sint chunk_size,
int reversed, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 1);
result = db_select_chunk_tree_common(p, tbl,
tid, pattern, chunk_size, reversed, ret,
NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_delete_continue_catree(Process *p,
DbTable *tbl,
Eterm continuation,
Eterm *ret)
{
DbTreeStack stack;
TreeDbTerm * stack_array[STACK_NEED];
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 0);
init_tree_stack(&stack, stack_array, 0);
result = db_select_delete_continue_tree_common(p, tbl, continuation, ret,
&stack, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_delete_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret)
{
DbTreeStack stack;
TreeDbTerm * stack_array[STACK_NEED];
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 0);
init_tree_stack(&stack, stack_array, 0);
result = db_select_delete_tree_common(p, tbl,
tid, pattern, ret, &stack,
&iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_replace_catree(Process *p, DbTable *tbl, Eterm tid,
Eterm pattern, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 0);
result = db_select_replace_tree_common(p, tbl,
tid, pattern, ret, NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_select_replace_continue_catree(Process *p, DbTable *tbl,
Eterm continuation, Eterm *ret)
{
int result;
CATreeRootIterator iter;
init_root_iterator(&tbl->catree, &iter, 0);
result = db_select_replace_continue_tree_common(p, tbl, continuation, ret,
NULL, &iter);
destroy_root_iterator(&iter);
return result;
}
static int db_take_catree(Process *p, DbTable *tbl, Eterm key, Eterm *ret)
{
DbTableCATree *tb = &tbl->catree;
FindBaseNode fbn;
DbTableCATreeNode* node = find_wlock_valid_base_node(tb, key, &fbn);
int result = db_take_tree_common(p, tbl, &node->u.base.root, key,
ret, NULL);
wunlock_adapt_base_node(tb, node, fbn.parent, fbn.current_level);
return result;
}
/*
** Other interface routines (not directly coupled to one bif)
*/
/* Display tree contents (for dump) */
static void db_print_catree(fmtfn_t to, void *to_arg,
int show, DbTable *tbl)
{
CATreeRootIterator iter;
TreeDbTerm** root;
init_root_iterator(&tbl->catree, &iter, 1);
root = catree_find_first_root(&iter);
do {
db_print_tree_common(to, to_arg, show, *root, tbl);
root = catree_find_next_root(&iter, NULL);
} while (root);
destroy_root_iterator(&iter);
}
/* Release all memory occupied by a single table */
static int db_free_table_catree(DbTable *tbl)
{
while (db_free_table_continue_catree(tbl, ERTS_SWORD_MAX) < 0)
;
return 1;
}
static SWord db_free_table_continue_catree(DbTable *tbl, SWord reds)
{
DbTableCATreeNode *first_base_node;
DbTableCATree *tb = &tbl->catree;
if (!tb->deletion) {
tb->deletion = 1;
tb->free_stack_elems.array =
erts_db_alloc(ERTS_ALC_T_DB_STK,
(DbTable *) tb,
sizeof(TreeDbTerm *) * STACK_NEED);
tb->free_stack_elems.pos = 0;
tb->free_stack_elems.slot = 0;
tb->free_stack_rnodes.array =
erts_db_alloc(ERTS_ALC_T_DB_STK,
(DbTable *) tb,
sizeof(DbTableCATreeNode *) * STACK_NEED);
tb->free_stack_rnodes.pos = 0;
tb->free_stack_rnodes.size = STACK_NEED;
PUSH_NODE(&tb->free_stack_rnodes, GET_ROOT(tb));
tb->is_routing_nodes_freed = 0;
tb->base_nodes_to_free_list = NULL;
}
if ( ! tb->is_routing_nodes_freed ) {
reds = do_free_routing_nodes_catree_cont(tb, reds);
if (reds < 0) {
return reds; /* Not finished */
} else {
tb->is_routing_nodes_freed = 1; /* Ready with the routing nodes */
first_base_node = catree_first_base_node_from_free_list(tb);
PUSH_NODE(&tb->free_stack_elems, first_base_node->u.base.root);
}
}
while (catree_first_base_node_from_free_list(tb) != NULL) {
reds = do_free_base_node_cont(tb, reds);
if (reds < 0) {
return reds; /* Continue later */
}
}
/* Time to free the main structure*/
erts_db_free(ERTS_ALC_T_DB_STK,
(DbTable *) tb,
(void *) tb->free_stack_elems.array,
sizeof(TreeDbTerm *) * STACK_NEED);
erts_db_free(ERTS_ALC_T_DB_STK,
(DbTable *) tb,
(void *) tb->free_stack_rnodes.array,
sizeof(DbTableCATreeNode *) * STACK_NEED);
return 1;
}
static SWord db_delete_all_objects_catree(Process* p, DbTable* tbl, SWord reds)
{
reds = db_free_table_continue_catree(tbl, reds);
if (reds < 0)
return reds;
db_create_catree(p, tbl);
erts_atomic_set_nob(&tbl->catree.common.nitems, 0);
return reds;
}
static void db_foreach_offheap_catree(DbTable *tbl,
void (*func)(ErlOffHeap *, void *),
void *arg)
{
CATreeRootIterator iter;
TreeDbTerm** root;
init_root_iterator(&tbl->catree, &iter, 1);
root = catree_find_first_root(&iter);
do {
db_foreach_offheap_tree_common(*root, func, arg);
root = catree_find_next_root(&iter, NULL);
} while (root);
destroy_root_iterator(&iter);
}
static int db_lookup_dbterm_catree(Process *p, DbTable *tbl, Eterm key, Eterm obj,
DbUpdateHandle *handle)
{
DbTableCATree *tb = &tbl->catree;
FindBaseNode fbn;
DbTableCATreeNode* node = find_wlock_valid_base_node(tb, key, &fbn);
int res = db_lookup_dbterm_tree_common(p, tbl, &node->u.base.root, key,
obj, handle, NULL);
if (res == 0) {
wunlock_adapt_base_node(tb, node, fbn.parent, fbn.current_level);
} else {
/* db_finalize_dbterm_catree will unlock */
handle->u.catree.base_node = node;
handle->u.catree.parent = fbn.parent;
handle->u.catree.current_level = fbn.current_level;
}
return res;
}
static void db_finalize_dbterm_catree(int cret, DbUpdateHandle *handle)
{
DbTableCATree *tb = &(handle->tb->catree);
db_finalize_dbterm_tree_common(cret, handle, NULL);
wunlock_adapt_base_node(tb, handle->u.catree.base_node,
handle->u.catree.parent,
handle->u.catree.current_level);
return;
}
#ifdef ERTS_ENABLE_LOCK_COUNT
static void erts_lcnt_enable_db_catree_lock_count_helper(DbTableCATree *tb,
DbTableCATreeNode *node,
int enable)
{
erts_lcnt_ref_t *lcnt_ref;
erts_lock_flags_t lock_type;
if (node->is_base_node) {
lcnt_ref = &GET_BASE_NODE_LOCK(node)->lcnt;
lock_type = ERTS_LOCK_TYPE_RWMUTEX;
} else {
erts_lcnt_enable_db_catree_lock_count_helper(tb, GET_LEFT(node), enable);
erts_lcnt_enable_db_catree_lock_count_helper(tb, GET_RIGHT(node), enable);
lcnt_ref = &GET_ROUTE_NODE_LOCK(node)->lcnt;
lock_type = ERTS_LOCK_TYPE_MUTEX;
}
if (enable) {
erts_lcnt_install_new_lock_info(lcnt_ref, "db_hash_slot", tb->common.the_name,
lock_type | ERTS_LOCK_FLAGS_CATEGORY_DB);
} else {
erts_lcnt_uninstall(lcnt_ref);
}
}
void erts_lcnt_enable_db_catree_lock_count(DbTableCATree *tb, int enable)
{
erts_lcnt_enable_db_catree_lock_count_helper(tb, GET_ROOT(tb), enable);
}
#endif /* ERTS_ENABLE_LOCK_COUNT */
void db_catree_force_split(DbTableCATree* tb, int on)
{
CATreeRootIterator iter;
TreeDbTerm** root;
init_root_iterator(tb, &iter, 1);
root = catree_find_first_root(&iter);
do {
iter.locked_bnode->u.base.lock_statistics = (on ? INT_MAX : 0);
root = catree_find_next_root(&iter, NULL);
} while (root);
destroy_root_iterator(&iter);
if (on)
tb->common.status |= DB_CATREE_FORCE_SPLIT;
else
tb->common.status &= ~DB_CATREE_FORCE_SPLIT;
}
void db_calc_stats_catree(DbTableCATree* tb, DbCATreeStats* stats)
{
DbTableCATreeNode* stack[ERL_DB_CATREE_MAX_ROUTE_NODE_LAYER_HEIGHT];
DbTableCATreeNode* node;
Uint depth = 0;
stats->route_nodes = 0;
stats->base_nodes = 0;
stats->max_depth = 0;
node = GET_ROOT(tb);
do {
while (!node->is_base_node) {
stats->route_nodes++;
ASSERT(depth < sizeof(stack)/sizeof(*stack));
stack[depth++] = node; /* PUSH parent */
if (stats->max_depth < depth)
stats->max_depth = depth;
node = GET_LEFT(node);
}
stats->base_nodes++;
while (depth > 0) {
DbTableCATreeNode* parent = stack[depth-1];
if (node == GET_LEFT(parent)) {
node = GET_RIGHT(parent);
break;
}
else {
ASSERT(node == GET_RIGHT(parent));
node = parent;
depth--; /* POP parent */
}
}
} while (depth > 0);
}
#ifdef HARDDEBUG
/*
* Not called, but kept as it might come to use
*/
static inline int my_check_table_tree(TreeDbTerm *t)
{
int lh, rh;
if (t == NULL)
return 0;
lh = my_check_table_tree(t->left);
rh = my_check_table_tree(t->right);
if ((rh - lh) != t->balance) {
erts_fprintf(stderr, "Invalid tree balance for this node:\n");
erts_fprintf(stderr,"balance = %d, left = 0x%08X, right = 0x%08X\n",
t->balance, t->left, t->right);
erts_fprintf(stderr,"\nDump:\n---------------------------------\n");
erts_fprintf(stderr,"\n---------------------------------\n");
abort();
}
return ((rh > lh) ? rh : lh) + 1;
}
#endif
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