/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 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: Monitor and link implementation.
*
* Author: Rickard Green
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "sys.h"
#include <stddef.h>
#include "global.h"
#include "erl_node_tables.h"
#include "erl_monitor_link.h"
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Red-black tree implementation used for monitors and links. *
\* */
static ERTS_INLINE Eterm
ml_get_key(ErtsMonLnkNode *mln)
{
char *ptr = (char *) mln;
ptr += mln->key_offset;
#ifdef ERTS_ML_DEBUG
switch (mln->type) {
case ERTS_MON_TYPE_PROC:
case ERTS_MON_TYPE_PORT:
case ERTS_MON_TYPE_DIST_PROC:
case ERTS_MON_TYPE_TIME_OFFSET:
case ERTS_MON_TYPE_RESOURCE: {
ErtsMonitorData *mdp = erts_monitor_to_data(mln);
ERTS_ML_ASSERT(&mdp->ref == (Eterm *) ptr);
break;
}
case ERTS_LNK_TYPE_PROC:
case ERTS_LNK_TYPE_DIST_PROC:
case ERTS_LNK_TYPE_PORT:
case ERTS_MON_TYPE_NODE:
case ERTS_MON_TYPE_NODES:
case ERTS_MON_TYPE_SUSPEND:
ERTS_ML_ASSERT(&mln->other.item == (Eterm *) ptr);
break;
default:
ERTS_INTERNAL_ERROR("Invalid type");
break;
}
#endif
return *((Eterm *) ptr);
}
/*
* Comparison functions for valid *and only valid* keys. That
* is, if the set of valid keys is changed, this function needs
* to be updated...
*
* Note that this function does *not* order terms according to
* term order, and that the order may vary between emulator
* restarts...
*/
static int
ml_cmp_keys(Eterm key1, Eterm key2)
{
/*
* A monitor key is either an internal pid, a (nodename) atom,
* a small (monitor nodes bitmask), an ordinary internal ref,
* or an external ref.
*
* Order between monitors with keys of different types:
* internal pid < atom < small < internal ref < external ref
*
* A link key is either a pid, an internal port
*
* Order between links with keys of different types:
* internal pid < internal port < external pid
*
*/
ERTS_ML_ASSERT(is_internal_pid(key1)
|| is_internal_port(key1)
|| is_atom(key1)
|| is_small(key1)
|| is_external_pid(key1)
|| is_internal_ordinary_ref(key1)
|| is_external_ref(key1));
ERTS_ML_ASSERT(is_internal_pid(key2)
|| is_internal_port(key2)
|| is_atom(key2)
|| is_small(key2)
|| is_external_pid(key2)
|| is_internal_ordinary_ref(key2)
|| is_external_ref(key2));
if (is_immed(key1)) {
int key1_tag, key2_tag;
ERTS_ML_ASSERT(is_internal_pid(key1)
|| is_internal_port(key1)
|| is_atom(key1)
|| is_small(key1));
if (key1 == key2)
return 0;
if (is_boxed(key2))
return -1;
ERTS_ML_ASSERT(is_internal_pid(key2)
|| is_internal_port(key2)
|| is_atom(key2)
|| is_small(key2));
key1_tag = (int) (key1 & _TAG_IMMED1_MASK);
key2_tag = (int) (key2 & _TAG_IMMED1_MASK);
if (key1_tag != key2_tag)
return key1_tag - key2_tag;
ASSERT((is_atom(key1) && is_atom(key2))
|| (is_small(key1) && is_small(key2))
|| (is_internal_pid(key1) && is_internal_pid(key2))
|| (is_internal_port(key1) && is_internal_port(key2)));
return key1 < key2 ? -1 : 1;
}
else {
Eterm *w1, hdr1;
ERTS_ML_ASSERT(is_boxed(key1));
w1 = boxed_val(key1);
hdr1 = *w1;
if ((hdr1 & _TAG_HEADER_MASK) == _TAG_HEADER_REF) {
Eterm *w2;
if (!is_internal_ref(key2))
return is_immed(key2) ? 1 : -1;
w2 = internal_ref_val(key2);
ERTS_ML_ASSERT(w1[0] == ERTS_REF_THING_HEADER);
ERTS_ML_ASSERT(w2[0] == ERTS_REF_THING_HEADER);
return sys_memcmp((void *) &w1[1], (void *) &w2[1],
(ERTS_REF_THING_SIZE - 1)*sizeof(Eterm));
}
ERTS_ML_ASSERT(is_external(key1));
if (is_not_external(key2))
return 1;
else {
Uint ndw1, ndw2;
ExternalThing *et1, *et2;
ErlNode *n1, *n2;
ERTS_ML_ASSERT((is_external_ref(key1) && is_external_ref(key2))
|| (is_external_pid(key1) && is_external_pid(key2)));
et1 = (ExternalThing *) w1;
et2 = (ExternalThing *) external_val(key2);
n1 = et1->node;
n2 = et2->node;
if (n1 != n2) {
if (n1->sysname != n2->sysname)
return n1->sysname < n2->sysname ? -1 : 1;
ASSERT(n1->creation != n2->creation);
return n1->creation < n2->creation ? -1 : 1;
}
ndw1 = external_thing_data_words(et1);
ndw2 = external_thing_data_words(et1);
if (ndw1 != ndw2)
return ndw1 < ndw2 ? -1 : 1;
return sys_memcmp((void *) &et1->data.ui[0],
(void *) &et2->data.ui[0],
ndw1*sizeof(Eterm));
}
}
}
#define ERTS_ML_TPFLG_RED (((UWord) 1) << 0)
#define ERTS_ML_TPFLGS_MASK (ERTS_ML_TPFLG_RED)
#define ERTS_RBT_PREFIX mon_lnk
#define ERTS_RBT_T ErtsMonLnkNode
#define ERTS_RBT_KEY_T Eterm
#define ERTS_RBT_FLAGS_T UWord
#define ERTS_RBT_INIT_EMPTY_TNODE(T) \
do { \
(T)->node.tree.parent = (UWord) NULL; \
(T)->node.tree.right = NULL; \
(T)->node.tree.left = NULL; \
} while (0)
#define ERTS_RBT_IS_RED(T) \
(!!((T)->node.tree.parent & ERTS_ML_TPFLG_RED))
#define ERTS_RBT_SET_RED(T) \
((T)->node.tree.parent |= ERTS_ML_TPFLG_RED)
#define ERTS_RBT_IS_BLACK(T) \
(!ERTS_RBT_IS_RED((T)))
#define ERTS_RBT_SET_BLACK(T) \
((T)->node.tree.parent &= ~ERTS_ML_TPFLG_RED)
#define ERTS_RBT_GET_FLAGS(T) \
((T)->node.tree.parent & ERTS_ML_TPFLGS_MASK)
#define ERTS_RBT_SET_FLAGS(T, F) \
do { \
ERTS_ML_ASSERT((((UWord) (F)) & ~ERTS_ML_TPFLGS_MASK) == 0); \
(T)->node.tree.parent &= ~ERTS_ML_TPFLGS_MASK; \
(T)->node.tree.parent |= (F); \
} while (0)
#define ERTS_RBT_GET_PARENT(T) \
((ERTS_RBT_T *) ((T)->node.tree.parent & ~ERTS_ML_TPFLGS_MASK))
#define ERTS_RBT_SET_PARENT(T, P) \
do { \
ERTS_ML_ASSERT((((UWord) (P)) & ERTS_ML_TPFLGS_MASK) == 0); \
(T)->node.tree.parent &= ERTS_ML_TPFLGS_MASK; \
(T)->node.tree.parent |= (UWord) (P); \
} while (0)
#define ERTS_RBT_GET_RIGHT(T) ((T)->node.tree.right)
#define ERTS_RBT_SET_RIGHT(T, R) ((T)->node.tree.right = (R))
#define ERTS_RBT_GET_LEFT(T) ((T)->node.tree.left)
#define ERTS_RBT_SET_LEFT(T, L) ((T)->node.tree.left = (L))
#define ERTS_RBT_GET_KEY(T) (ml_get_key((T)))
#define ERTS_RBT_CMP_KEYS(KX, KY) (ml_cmp_keys((KX), (KY)))
#define ERTS_RBT_WANT_DELETE
#define ERTS_RBT_WANT_LOOKUP
#define ERTS_RBT_WANT_LOOKUP_INSERT
#define ERTS_RBT_WANT_LOOKUP_CREATE
#define ERTS_RBT_WANT_INSERT
#define ERTS_RBT_WANT_REPLACE
#define ERTS_RBT_WANT_FOREACH
#define ERTS_RBT_WANT_FOREACH_YIELDING
#define ERTS_RBT_WANT_FOREACH_DESTROY
#define ERTS_RBT_WANT_FOREACH_DESTROY_YIELDING
#define ERTS_RBT_UNDEF
#include "erl_rbtree.h"
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Tree Operations *
\* */
static ErtsMonLnkNode *
ml_rbt_lookup(ErtsMonLnkNode *root, Eterm ref)
{
ErtsMonLnkNode *ml = mon_lnk_rbt_lookup(root, ref);
ASSERT(!ml || (ml->flags & ERTS_ML_FLG_IN_TABLE));
return ml;
}
static ErtsMonLnkNode *
ml_rbt_lookup_insert(ErtsMonLnkNode **root, ErtsMonLnkNode *ml)
{
ErtsMonLnkNode *res;
ERTS_ML_ASSERT(!(ml->flags & ERTS_ML_FLG_IN_TABLE));
res = mon_lnk_rbt_lookup_insert(root, ml);
if (!res)
ml->flags |= ERTS_ML_FLG_IN_TABLE;
return res;
}
static ErtsMonLnkNode *
ml_rbt_lookup_create(ErtsMonLnkNode ** root, Eterm key,
ErtsMonLnkNode *(*create)(Eterm, void *),
void *carg, int *created)
{
ErtsMonLnkNode *ml;
ml = mon_lnk_rbt_lookup_create(root, key, create, carg, created);
if (*created)
ml->flags |= ERTS_ML_FLG_IN_TABLE;
return ml;
}
static void
ml_rbt_insert(ErtsMonLnkNode **root, ErtsMonLnkNode *ml)
{
#ifdef ERTS_ML_DEBUG
ErtsMonLnkNode *res;
ERTS_ML_ASSERT(!(ml->flags & ERTS_ML_FLG_IN_TABLE));
res = ml_rbt_lookup(*root, ml_get_key(ml));
ERTS_ML_ASSERT(res == NULL);
#endif
mon_lnk_rbt_insert(root, ml);
ml->flags |= ERTS_ML_FLG_IN_TABLE;
}
static void
ml_rbt_replace(ErtsMonLnkNode **root, ErtsMonLnkNode *old, ErtsMonLnkNode *new)
{
ERTS_ML_ASSERT(old->flags & ERTS_ML_FLG_IN_TABLE);
ERTS_ML_ASSERT(!(new->flags & ERTS_ML_FLG_IN_TABLE));
mon_lnk_rbt_replace(root, old, new);
old->flags &= ~ERTS_ML_FLG_IN_TABLE;
new->flags |= ERTS_ML_FLG_IN_TABLE;
}
static void
ml_rbt_delete(ErtsMonLnkNode **root, ErtsMonLnkNode *ml)
{
ERTS_ML_ASSERT(ml->flags & ERTS_ML_FLG_IN_TABLE);
mon_lnk_rbt_delete(root, ml);
ml->flags &= ~ERTS_ML_FLG_IN_TABLE;
}
static void
ml_rbt_foreach(ErtsMonLnkNode *root,
void (*func)(ErtsMonLnkNode *, void *),
void *arg)
{
mon_lnk_rbt_foreach(root, func, arg);
}
typedef struct {
ErtsMonLnkNode *root;
mon_lnk_rbt_yield_state_t rbt_ystate;
} ErtsMonLnkYieldState;
static int
ml_rbt_foreach_yielding(ErtsMonLnkNode *root,
void (*func)(ErtsMonLnkNode *, void *),
void *arg,
void **vyspp,
Sint limit)
{
int res;
ErtsMonLnkYieldState ys = {root, ERTS_RBT_YIELD_STAT_INITER};
ErtsMonLnkYieldState *ysp;
ysp = (ErtsMonLnkYieldState *) *vyspp;
if (!ysp)
ysp = &ys;
res = mon_lnk_rbt_foreach_yielding(ysp->root, func, arg,
&ysp->rbt_ystate, limit);
if (res == 0) {
if (ysp != &ys)
erts_free(ERTS_ALC_T_ML_YIELD_STATE, ysp);
*vyspp = NULL;
}
else {
if (ysp == &ys) {
ysp = erts_alloc(ERTS_ALC_T_ML_YIELD_STATE,
sizeof(ErtsMonLnkYieldState));
sys_memcpy((void *) ysp, (void *) &ys,
sizeof(ErtsMonLnkYieldState));
}
*vyspp = (void *) ysp;
}
return res;
}
typedef struct {
void (*func)(ErtsMonLnkNode *, void *);
void *arg;
} ErtsMonLnkForeachDeleteContext;
static void
rbt_wrap_foreach_delete(ErtsMonLnkNode *ml, void *vctxt)
{
ErtsMonLnkForeachDeleteContext *ctxt = vctxt;
ERTS_ML_ASSERT(ml->flags & ERTS_ML_FLG_IN_TABLE);
ml->flags &= ~ERTS_ML_FLG_IN_TABLE;
ctxt->func(ml, ctxt->arg);
}
static void
ml_rbt_foreach_delete(ErtsMonLnkNode **root,
void (*func)(ErtsMonLnkNode *, void *),
void *arg)
{
ErtsMonLnkForeachDeleteContext ctxt;
ctxt.func = func;
ctxt.arg = arg;
mon_lnk_rbt_foreach_destroy(root,
rbt_wrap_foreach_delete,
(void *) &ctxt);
}
static int
ml_rbt_foreach_delete_yielding(ErtsMonLnkNode **root,
void (*func)(ErtsMonLnkNode *, void *),
void *arg,
void **vyspp,
Sint limit)
{
int res;
ErtsMonLnkYieldState ys = {*root, ERTS_RBT_YIELD_STAT_INITER};
ErtsMonLnkYieldState *ysp;
ErtsMonLnkForeachDeleteContext ctxt;
ctxt.func = func;
ctxt.arg = arg;
ysp = (ErtsMonLnkYieldState *) *vyspp;
if (!ysp) {
*root = NULL;
ysp = &ys;
}
res = mon_lnk_rbt_foreach_destroy_yielding(&ysp->root,
rbt_wrap_foreach_delete,
(void *) &ctxt,
&ysp->rbt_ystate,
limit);
if (res == 0) {
if (ysp != &ys)
erts_free(ERTS_ALC_T_ML_YIELD_STATE, ysp);
*vyspp = NULL;
}
else {
if (ysp == &ys) {
ysp = erts_alloc(ERTS_ALC_T_ML_YIELD_STATE,
sizeof(ErtsMonLnkYieldState));
sys_memcpy((void *) ysp, (void *) &ys,
sizeof(ErtsMonLnkYieldState));
}
*vyspp = (void *) ysp;
}
return res;
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* List Operations *
\* */
static int
ml_dl_list_foreach_yielding(ErtsMonLnkNode *list,
void (*func)(ErtsMonLnkNode *, void *),
void *arg,
void **vyspp,
Sint limit)
{
Sint cnt = 0;
ErtsMonLnkNode *ml = (ErtsMonLnkNode *) *vyspp;
ERTS_ML_ASSERT(!ml || list);
if (!ml)
ml = list;
if (ml) {
do {
ERTS_ML_ASSERT(ml->flags & ERTS_ML_FLG_IN_TABLE);
func(ml, arg);
ml = ml->node.list.next;
cnt++;
} while (ml != list && cnt < limit);
if (ml != list) {
*vyspp = (void *) ml;
return 1; /* yield */
}
}
*vyspp = NULL;
return 0; /* done */
}
static int
ml_dl_list_foreach_delete_yielding(ErtsMonLnkNode **list,
void (*func)(ErtsMonLnkNode *, void *),
void *arg,
void **vyspp,
Sint limit)
{
Sint cnt = 0;
ErtsMonLnkNode *first = *list;
ErtsMonLnkNode *ml = (ErtsMonLnkNode *) *vyspp;
ERTS_ML_ASSERT(!ml || first);
if (!ml)
ml = first;
if (ml) {
do {
ErtsMonLnkNode *next = ml->node.list.next;
ERTS_ML_ASSERT(ml->flags & ERTS_ML_FLG_IN_TABLE);
ml->flags &= ~ERTS_ML_FLG_IN_TABLE;
func(ml, arg);
ml = next;
cnt++;
} while (ml != first && cnt < limit);
if (ml != first) {
*vyspp = (void *) ml;
return 1; /* yield */
}
}
*vyspp = NULL;
*list = NULL;
return 0; /* done */
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Misc *
\* */
ErtsMonLnkDist *
erts_mon_link_dist_create(Eterm nodename)
{
ErtsMonLnkDist *mld = erts_alloc(ERTS_ALC_T_ML_DIST,
sizeof(ErtsMonLnkDist));
mld->nodename = nodename;
mld->connection_id = ~((Uint32) 0);
erts_atomic_init_nob(&mld->refc, 1);
erts_mtx_init(&mld->mtx, "dist_entry_links", nodename,
ERTS_LOCK_FLAGS_CATEGORY_DISTRIBUTION);
mld->alive = !0;
mld->links = NULL;
mld->monitors = NULL;
mld->orig_name_monitors = NULL;
return mld;
}
void
erts_mon_link_dist_destroy__(ErtsMonLnkDist *mld)
{
ERTS_ML_ASSERT(erts_atomic_read_nob(&mld->refc) == 0);
ERTS_ML_ASSERT(!mld->alive);
ERTS_ML_ASSERT(!mld->links);
ERTS_ML_ASSERT(!mld->monitors);
ERTS_ML_ASSERT(!mld->orig_name_monitors);
erts_mtx_destroy(&mld->mtx);
erts_free(ERTS_ALC_T_ML_DIST, mld);
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Monitor Operations *
\* */
#ifdef ERTS_ML_DEBUG
size_t erts_monitor_origin_offset;
size_t erts_monitor_origin_key_offset;
size_t erts_monitor_target_offset;
size_t erts_monitor_target_key_offset;
size_t erts_monitor_node_key_offset;
#endif
static ERTS_INLINE void
monitor_init(void)
{
#ifdef ERTS_ML_DEBUG
erts_monitor_origin_offset = offsetof(ErtsMonitorData, origin);
erts_monitor_origin_key_offset = offsetof(ErtsMonitorData, ref);
ASSERT(erts_monitor_origin_key_offset >= erts_monitor_origin_offset);
erts_monitor_origin_key_offset -= erts_monitor_origin_offset;
erts_monitor_target_offset = offsetof(ErtsMonitorData, target);
erts_monitor_target_key_offset = offsetof(ErtsMonitorData, ref);
ASSERT(erts_monitor_target_key_offset >= erts_monitor_target_offset);
erts_monitor_target_key_offset -= erts_monitor_target_offset;
erts_monitor_node_key_offset = offsetof(ErtsMonitor, other.item);
#endif
}
ErtsMonitor *
erts_monitor_tree_lookup(ErtsMonitor *root, Eterm key)
{
ERTS_ML_ASSERT(is_internal_ordinary_ref(key)
|| is_external_ref(key)
|| is_atom(key)
|| is_small(key)
|| is_internal_pid(key));
return (ErtsMonitor *) ml_rbt_lookup((ErtsMonLnkNode *) root, key);
}
ErtsMonitor *
erts_monotor_tree_lookup_insert(ErtsMonitor **root, ErtsMonitor *mon)
{
return (ErtsMonitor *) ml_rbt_lookup_insert((ErtsMonLnkNode **) root,
(ErtsMonLnkNode *) mon);
}
typedef struct {
Uint16 type;
Eterm origin;
} ErtsMonitorCreateCtxt;
static ErtsMonLnkNode *
create_monitor(Eterm target, void *vcctxt)
{
ErtsMonitorCreateCtxt *cctxt = vcctxt;
ErtsMonitorData *mdp = erts_monitor_create(cctxt->type,
NIL,
cctxt->origin,
target,
NIL);
ERTS_ML_ASSERT(ml_cmp_keys(ml_get_key(&mdp->origin), target) == 0);
return (ErtsMonLnkNode *) &mdp->origin;
}
ErtsMonitor *
erts_monitor_tree_lookup_create(ErtsMonitor **root, int *created, Uint16 type,
Eterm origin, Eterm target)
{
ErtsMonitor *res;
ErtsMonitorCreateCtxt cctxt = {type, origin};
ERTS_ML_ASSERT(type == ERTS_MON_TYPE_NODE
|| type == ERTS_MON_TYPE_NODES
|| type == ERTS_MON_TYPE_SUSPEND);
res = (ErtsMonitor *) ml_rbt_lookup_create((ErtsMonLnkNode **) root,
target, create_monitor,
(void *) &cctxt,
created);
ERTS_ML_ASSERT(res && erts_monitor_is_origin(res));
return res;
}
void
erts_monitor_tree_insert(ErtsMonitor **root, ErtsMonitor *mon)
{
ml_rbt_insert((ErtsMonLnkNode **) root, (ErtsMonLnkNode *) mon);
}
void
erts_monitor_tree_replace(ErtsMonitor **root, ErtsMonitor *old, ErtsMonitor *new)
{
ml_rbt_replace((ErtsMonLnkNode **) root,
(ErtsMonLnkNode *) old,
(ErtsMonLnkNode *) new);
}
void
erts_monitor_tree_delete(ErtsMonitor **root, ErtsMonitor *mon)
{
ml_rbt_delete((ErtsMonLnkNode **) root, (ErtsMonLnkNode *) mon);
}
void
erts_monitor_tree_foreach(ErtsMonitor *root,
void (*func)(ErtsMonitor *, void *),
void *arg)
{
ml_rbt_foreach((ErtsMonLnkNode *) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg);
}
int
erts_monitor_tree_foreach_yielding(ErtsMonitor *root,
void (*func)(ErtsMonitor *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_rbt_foreach_yielding((ErtsMonLnkNode *) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
void
erts_monitor_tree_foreach_delete(ErtsMonitor **root,
void (*func)(ErtsMonitor *, void *),
void *arg)
{
ml_rbt_foreach_delete((ErtsMonLnkNode **) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg);
}
int
erts_monitor_tree_foreach_delete_yielding(ErtsMonitor **root,
void (*func)(ErtsMonitor *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_rbt_foreach_delete_yielding((ErtsMonLnkNode **) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
void
erts_monitor_list_foreach(ErtsMonitor *list,
void (*func)(ErtsMonitor *, void *),
void *arg)
{
void *ystate = NULL;
while (ml_dl_list_foreach_yielding((ErtsMonLnkNode *) list,
(void (*)(ErtsMonLnkNode *, void *)) func,
arg, &ystate, (Sint) INT_MAX));
}
int
erts_monitor_list_foreach_yielding(ErtsMonitor *list,
void (*func)(ErtsMonitor *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_dl_list_foreach_yielding((ErtsMonLnkNode *) list,
(void (*)(ErtsMonLnkNode *, void *)) func,
arg, vyspp, limit);
}
void
erts_monitor_list_foreach_delete(ErtsMonitor **list,
void (*func)(ErtsMonitor *, void *),
void *arg)
{
void *ystate = NULL;
while (ml_dl_list_foreach_delete_yielding((ErtsMonLnkNode **) list,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, &ystate, (Sint) INT_MAX));
}
int
erts_monitor_list_foreach_delete_yielding(ErtsMonitor **list,
void (*func)(ErtsMonitor *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_dl_list_foreach_delete_yielding((ErtsMonLnkNode **) list,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
ErtsMonitorData *
erts_monitor_create(Uint16 type, Eterm ref, Eterm orgn, Eterm trgt, Eterm name)
{
ErtsMonitorData *mdp;
switch (type) {
case ERTS_MON_TYPE_PROC:
case ERTS_MON_TYPE_PORT:
if (is_nil(name)) {
ErtsMonitorDataHeap *mdhp;
ErtsORefThing *ortp;
case ERTS_MON_TYPE_TIME_OFFSET:
ERTS_ML_ASSERT(is_nil(name));
ERTS_ML_ASSERT(is_immed(orgn) && is_immed(trgt));
ERTS_ML_ASSERT(is_internal_ordinary_ref(ref));
mdhp = erts_alloc(ERTS_ALC_T_MONITOR, sizeof(ErtsMonitorDataHeap));
mdp = &mdhp->md;
ERTS_ML_ASSERT(((void *) mdp) == ((void *) mdhp));
ortp = (ErtsORefThing *) (char *) internal_ref_val(ref);
mdhp->oref_thing = *ortp;
mdp->ref = make_internal_ref(&mdhp->oref_thing.header);
mdp->origin.other.item = trgt;
mdp->origin.offset = (Uint16) offsetof(ErtsMonitorData, origin);
mdp->origin.key_offset = (Uint16) offsetof(ErtsMonitorData, ref);
ERTS_ML_ASSERT(mdp->origin.key_offset >= mdp->origin.offset);
mdp->origin.key_offset -= mdp->origin.offset;
mdp->origin.flags = (Uint16) 0;
mdp->origin.type = type;
mdp->target.other.item = orgn;
mdp->target.offset = (Uint16) offsetof(ErtsMonitorData, target);
mdp->target.key_offset = (Uint16) offsetof(ErtsMonitorData, ref);
ERTS_ML_ASSERT(mdp->target.key_offset >= mdp->target.offset);
mdp->target.key_offset -= mdp->target.offset;
mdp->target.flags = ERTS_ML_FLG_TARGET;
mdp->target.type = type;
break;
}
case ERTS_MON_TYPE_DIST_PROC:
case ERTS_MON_TYPE_RESOURCE:
case ERTS_MON_TYPE_NODE:
case ERTS_MON_TYPE_NODES: {
ErtsMonitorDataExtended *mdep;
Uint size = sizeof(ErtsMonitorDataExtended) - sizeof(Eterm);
Uint rsz, osz, tsz;
Eterm *hp;
ErlOffHeap oh;
Uint16 name_flag = is_nil(name) ? ((Uint16) 0) : ERTS_ML_FLG_NAME;
rsz = is_immed(ref) ? 0 : size_object(ref);
tsz = is_immed(trgt) ? 0 : size_object(trgt);
if (type == ERTS_MON_TYPE_RESOURCE)
osz = 0;
else
osz = is_immed(orgn) ? 0 : size_object(orgn);
size += (rsz + osz + tsz) * sizeof(Eterm);
mdep = erts_alloc(ERTS_ALC_T_MONITOR_EXT, size);
ERTS_INIT_OFF_HEAP(&oh);
hp = &mdep->heap[0];
mdp = &mdep->md;
ERTS_ML_ASSERT(((void *) mdp) == ((void *) mdep));
mdp->ref = rsz ? copy_struct(ref, rsz, &hp, &oh) : ref;
mdp->origin.other.item = tsz ? copy_struct(trgt, tsz, &hp, &oh) : trgt;
mdp->origin.offset = (Uint16) offsetof(ErtsMonitorData, origin);
mdp->origin.flags = ERTS_ML_FLG_EXTENDED|name_flag;
mdp->origin.type = type;
if (type == ERTS_MON_TYPE_RESOURCE)
mdp->target.other.ptr = (void *) orgn;
else
mdp->target.other.item = osz ? copy_struct(orgn, osz, &hp, &oh) : orgn;
mdp->target.offset = (Uint16) offsetof(ErtsMonitorData, target);
mdp->target.flags = ERTS_ML_FLG_TARGET|ERTS_ML_FLG_EXTENDED|name_flag;
mdp->target.type = type;
if (type == ERTS_MON_TYPE_NODE || type == ERTS_MON_TYPE_NODES) {
mdep->u.refc = 0;
mdp->origin.key_offset = (Uint16) offsetof(ErtsMonitor, other.item);
mdp->target.key_offset = (Uint16) offsetof(ErtsMonitor, other.item);
ERTS_ML_ASSERT(!oh.first);
mdep->uptr.node_monitors = NULL;
}
else {
mdep->u.name = name;
mdp->origin.key_offset = (Uint16) offsetof(ErtsMonitorData, ref);
ERTS_ML_ASSERT(mdp->origin.key_offset >= mdp->origin.offset);
mdp->origin.key_offset -= mdp->origin.offset;
mdp->target.key_offset = (Uint16) offsetof(ErtsMonitorData, ref);
ERTS_ML_ASSERT(mdp->target.key_offset >= mdp->target.offset);
mdp->target.key_offset -= mdp->target.offset;
mdep->uptr.ohhp = oh.first;
}
mdep->dist = NULL;
break;
}
case ERTS_MON_TYPE_SUSPEND: {
ErtsMonitorSuspend *msp;
ERTS_ML_ASSERT(is_nil(name));
ERTS_ML_ASSERT(is_nil(ref));
ERTS_ML_ASSERT(is_internal_pid(orgn) && is_internal_pid(trgt));
msp = erts_alloc(ERTS_ALC_T_MONITOR_SUSPEND,
sizeof(ErtsMonitorSuspend));
mdp = &msp->md;
ERTS_ML_ASSERT(((void *) mdp) == ((void *) msp));
mdp->ref = NIL;
mdp->origin.other.item = trgt;
mdp->origin.offset = (Uint16) offsetof(ErtsMonitorData, origin);
mdp->origin.key_offset = (Uint16) offsetof(ErtsMonitor, other.item);
ERTS_ML_ASSERT(mdp->origin.key_offset >= mdp->origin.offset);
mdp->origin.flags = (Uint16) ERTS_ML_FLG_EXTENDED;
mdp->origin.type = type;
mdp->target.other.item = orgn;
mdp->target.offset = (Uint16) offsetof(ErtsMonitorData, target);
mdp->target.key_offset = (Uint16) offsetof(ErtsMonitor, other.item);
mdp->target.flags = ERTS_ML_FLG_TARGET|ERTS_ML_FLG_EXTENDED;
mdp->target.type = type;
msp->next = NULL;
erts_atomic_init_relb(&msp->state, 0);
break;
}
default:
ERTS_INTERNAL_ERROR("Invalid monitor type");
mdp = NULL;
break;
}
erts_atomic32_init_nob(&mdp->refc, 2);
return mdp;
}
/*
* erts_monitor_destroy__() should only be called from
* erts_monitor_release() or erts_monitor_release_both().
*/
void
erts_monitor_destroy__(ErtsMonitorData *mdp)
{
ERTS_ML_ASSERT(erts_atomic32_read_nob(&mdp->refc) == 0);
ERTS_ML_ASSERT(!(mdp->origin.flags & ERTS_ML_FLG_IN_TABLE));
ERTS_ML_ASSERT(!(mdp->target.flags & ERTS_ML_FLG_IN_TABLE));
ERTS_ML_ASSERT((mdp->origin.flags & ERTS_ML_FLGS_SAME)
== (mdp->target.flags & ERTS_ML_FLGS_SAME));
if (!(mdp->origin.flags & ERTS_ML_FLG_EXTENDED))
erts_free(ERTS_ALC_T_MONITOR, mdp);
else if (mdp->origin.type == ERTS_MON_TYPE_SUSPEND)
erts_free(ERTS_ALC_T_MONITOR_SUSPEND, mdp);
else {
ErtsMonitorDataExtended *mdep = (ErtsMonitorDataExtended *) mdp;
ErlOffHeap oh;
if (mdp->origin.type == ERTS_MON_TYPE_NODE)
ERTS_ML_ASSERT(!mdep->uptr.node_monitors);
else if (mdep->uptr.ohhp) {
ERTS_INIT_OFF_HEAP(&oh);
oh.first = mdep->uptr.ohhp;
erts_cleanup_offheap(&oh);
}
if (mdep->dist)
erts_mon_link_dist_dec_refc(mdep->dist);
erts_free(ERTS_ALC_T_MONITOR_EXT, mdp);
}
}
void
erts_monitor_set_dead_dist(ErtsMonitor *mon, Eterm nodename)
{
ErtsMonitorDataExtended *mdep;
mdep = (ErtsMonitorDataExtended *) erts_monitor_to_data(mon);
ERTS_ML_ASSERT(mon->flags & ERTS_ML_FLG_EXTENDED);
ERTS_ML_ASSERT(mon->type == ERTS_MON_TYPE_DIST_PROC);
ERTS_ML_ASSERT(!mdep->dist);
mdep->dist = erts_mon_link_dist_create(nodename);
mdep->dist->alive = 0;
}
Uint
erts_monitor_size(ErtsMonitor *mon)
{
Uint size, refc;
ErtsMonitorData *mdp = erts_monitor_to_data(mon);
if (!(mon->flags & ERTS_ML_FLG_EXTENDED))
size = sizeof(ErtsMonitorDataHeap);
else if (mon->type == ERTS_MON_TYPE_SUSPEND)
size = sizeof(ErtsMonitorSuspend);
else {
ErtsMonitorDataExtended *mdep;
Uint hsz = 0;
mdep = (ErtsMonitorDataExtended *) mdp;
if (mon->type != ERTS_MON_TYPE_NODE
&& mon->type != ERTS_MON_TYPE_NODES) {
if (!is_immed(mdep->md.ref))
hsz += NC_HEAP_SIZE(mdep->md.ref);
if (mon->type == ERTS_MON_TYPE_DIST_PROC) {
if (!is_immed(mdep->md.origin.other.item))
hsz += NC_HEAP_SIZE(mdep->md.origin.other.item);
if (!is_immed(mdep->md.target.other.item))
hsz += NC_HEAP_SIZE(mdep->md.target.other.item);
}
}
size = sizeof(ErtsMonitorDataExtended) + (hsz - 1)*sizeof(Eterm);
}
refc = (Uint) erts_atomic32_read_nob(&mdp->refc);
ASSERT(refc > 0);
return size / refc;
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Link Operations *
* *
\* */
#ifdef ERTS_ML_DEBUG
size_t erts_link_a_offset;
size_t erts_link_b_offset;
size_t erts_link_key_offset;
#endif
static ERTS_INLINE void
link_init(void)
{
#ifdef ERTS_ML_DEBUG
erts_link_a_offset = offsetof(ErtsLinkData, a);
erts_link_b_offset = offsetof(ErtsLinkData, b);
erts_link_key_offset = offsetof(ErtsLink, other.item);
#endif
}
ErtsLink *
erts_link_tree_lookup(ErtsLink *root, Eterm key)
{
ASSERT(is_pid(key) || is_internal_port(key));
return (ErtsLink *) ml_rbt_lookup((ErtsMonLnkNode *) root, key);
}
ErtsLink *
erts_link_tree_lookup_insert(ErtsLink **root, ErtsLink *lnk)
{
return (ErtsLink *) ml_rbt_lookup_insert((ErtsMonLnkNode **) root,
(ErtsMonLnkNode *) lnk);
}
typedef struct {
Uint16 type;
Eterm a;
} ErtsLinkCreateCtxt;
static ErtsMonLnkNode *
create_link(Eterm b, void *vcctxt)
{
ErtsLinkCreateCtxt *cctxt = vcctxt;
ErtsLinkData *ldp = erts_link_create(cctxt->type, cctxt->a, b);
ERTS_ML_ASSERT(ml_cmp_keys(ldp->a.other.item, b) == 0);
return (ErtsMonLnkNode *) &ldp->a;
}
ErtsLink *erts_link_tree_lookup_create(ErtsLink **root, int *created,
Uint16 type, Eterm this,
Eterm other)
{
ErtsLinkCreateCtxt cctxt;
cctxt.type = type;
cctxt.a = this;
return (ErtsLink *) ml_rbt_lookup_create((ErtsMonLnkNode **) root,
other, create_link,
(void *) &cctxt,
created);
}
void
erts_link_tree_insert(ErtsLink **root, ErtsLink *lnk)
{
ml_rbt_insert((ErtsMonLnkNode **) root, (ErtsMonLnkNode *) lnk);
}
void
erts_link_tree_replace(ErtsLink **root, ErtsLink *old, ErtsLink *new)
{
ml_rbt_replace((ErtsMonLnkNode **) root,
(ErtsMonLnkNode *) old,
(ErtsMonLnkNode *) new);
}
void
erts_link_tree_delete(ErtsLink **root, ErtsLink *lnk)
{
ml_rbt_delete((ErtsMonLnkNode **) root, (ErtsMonLnkNode *) lnk);
}
void
erts_link_tree_foreach(ErtsLink *root,
void (*func)(ErtsLink *, void *),
void *arg)
{
ml_rbt_foreach((ErtsMonLnkNode *) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg);
}
int
erts_link_tree_foreach_yielding(ErtsLink *root,
void (*func)(ErtsLink *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_rbt_foreach_yielding((ErtsMonLnkNode *) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
void
erts_link_tree_foreach_delete(ErtsLink **root,
void (*func)(ErtsLink *, void *),
void *arg)
{
ml_rbt_foreach_delete((ErtsMonLnkNode **) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg);
}
int
erts_link_tree_foreach_delete_yielding(ErtsLink **root,
void (*func)(ErtsLink *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_rbt_foreach_delete_yielding((ErtsMonLnkNode **) root,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
void
erts_link_list_foreach(ErtsLink *list,
void (*func)(ErtsLink *, void *),
void *arg)
{
void *ystate = NULL;
while (ml_dl_list_foreach_yielding((ErtsMonLnkNode *) list,
(void (*)(ErtsMonLnkNode *, void *)) func,
arg, &ystate, (Sint) INT_MAX));
}
int
erts_link_list_foreach_yielding(ErtsLink *list,
void (*func)(ErtsLink *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_dl_list_foreach_yielding((ErtsMonLnkNode *) list,
(void (*)(ErtsMonLnkNode *, void *)) func,
arg, vyspp, limit);
}
void
erts_link_list_foreach_delete(ErtsLink **list,
void (*func)(ErtsLink *, void *),
void *arg)
{
void *ystate = NULL;
while (ml_dl_list_foreach_delete_yielding((ErtsMonLnkNode **) list,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, &ystate, (Sint) INT_MAX));
}
int
erts_link_list_foreach_delete_yielding(ErtsLink **list,
void (*func)(ErtsLink *, void *),
void *arg,
void **vyspp,
Sint limit)
{
return ml_dl_list_foreach_delete_yielding((ErtsMonLnkNode **) list,
(void (*)(ErtsMonLnkNode*, void*)) func,
arg, vyspp, limit);
}
ErtsLinkData *
erts_link_create(Uint16 type, Eterm a, Eterm b)
{
ErtsLinkData *ldp;
#ifdef ERTS_ML_DEBUG
switch (type) {
case ERTS_LNK_TYPE_PROC:
ERTS_ML_ASSERT(is_internal_pid(a) && is_internal_pid(a));
break;
case ERTS_LNK_TYPE_PORT:
ERTS_ML_ASSERT(is_internal_pid(a) || is_internal_pid(b));
ERTS_ML_ASSERT(is_internal_port(a) || is_internal_port(b));
break;
case ERTS_LNK_TYPE_DIST_PROC:
ERTS_ML_ASSERT(is_internal_pid(a) || is_internal_pid(b));
ERTS_ML_ASSERT(is_external_pid(a) || is_external_pid(b));
break;
default:
ERTS_INTERNAL_ERROR("Invalid link type");
break;
}
#endif
if (type != ERTS_LNK_TYPE_DIST_PROC) {
ldp = erts_alloc(ERTS_ALC_T_LINK, sizeof(ErtsLinkData));
ldp->a.other.item = b;
ldp->a.flags = (Uint16) 0;
ldp->b.other.item = a;
ldp->b.flags = (Uint16) 0;
}
else {
ErtsLinkDataExtended *ldep;
Uint size, hsz;
Eterm *hp;
ErlOffHeap oh;
if (is_internal_pid(a))
hsz = NC_HEAP_SIZE(b);
else
hsz = NC_HEAP_SIZE(a);
ERTS_ML_ASSERT(hsz > 0);
size = sizeof(ErtsLinkDataExtended) - sizeof(Eterm);
size += hsz*sizeof(Eterm);
ldp = erts_alloc(ERTS_ALC_T_LINK_EXT, size);
ldp->a.flags = ERTS_ML_FLG_EXTENDED;
ldp->b.flags = ERTS_ML_FLG_EXTENDED;
ldep = (ErtsLinkDataExtended *) ldp;
hp = &ldep->heap[0];
ERTS_INIT_OFF_HEAP(&oh);
if (is_internal_pid(a)) {
ldp->a.other.item = STORE_NC(&hp, &oh, b);
ldp->b.other.item = a;
}
else {
ldp->a.other.item = b;
ldp->b.other.item = STORE_NC(&hp, &oh, a);
}
ldep->ohhp = oh.first;
ldep->dist = NULL;
}
erts_atomic32_init_nob(&ldp->refc, 2);
ldp->a.key_offset = (Uint16) offsetof(ErtsLink, other.item);
ldp->a.offset = (Uint16) offsetof(ErtsLinkData, a);
ldp->a.type = type;
ldp->b.key_offset = (Uint16) offsetof(ErtsLink, other.item);
ldp->b.offset = (Uint16) offsetof(ErtsLinkData, b);
ldp->b.type = type;
return ldp;
}
/*
* erts_link_destroy__() should only be called from
* erts_link_release() or erts_link_release_both().
*/
void
erts_link_destroy__(ErtsLinkData *ldp)
{
ERTS_ML_ASSERT(erts_atomic32_read_nob(&ldp->refc) == 0);
ERTS_ML_ASSERT(!(ldp->a.flags & ERTS_ML_FLG_IN_TABLE));
ERTS_ML_ASSERT(!(ldp->b.flags & ERTS_ML_FLG_IN_TABLE));
ERTS_ML_ASSERT((ldp->a.flags & ERTS_ML_FLGS_SAME)
== (ldp->b.flags & ERTS_ML_FLGS_SAME));
if (!(ldp->a.flags & ERTS_ML_FLG_EXTENDED))
erts_free(ERTS_ALC_T_LINK, ldp);
else {
ErtsLinkDataExtended *ldep = (ErtsLinkDataExtended *) ldp;
ErlOffHeap oh;
if (ldep->ohhp) {
ERTS_INIT_OFF_HEAP(&oh);
oh.first = ldep->ohhp;
erts_cleanup_offheap(&oh);
}
if (ldep->dist)
erts_mon_link_dist_dec_refc(ldep->dist);
erts_free(ERTS_ALC_T_LINK_EXT, ldep);
}
}
void
erts_link_set_dead_dist(ErtsLink *lnk, Eterm nodename)
{
ErtsLinkDataExtended *ldep;
ldep = (ErtsLinkDataExtended *) erts_link_to_data(lnk);
ERTS_ML_ASSERT(lnk->flags & ERTS_ML_FLG_EXTENDED);
ERTS_ML_ASSERT(lnk->type == ERTS_LNK_TYPE_DIST_PROC);
ERTS_ML_ASSERT(!ldep->dist);
ldep->dist = erts_mon_link_dist_create(nodename);
ldep->dist->alive = 0;
}
Uint
erts_link_size(ErtsLink *lnk)
{
Uint size, refc;
ErtsLinkData *ldp = erts_link_to_data(lnk);
if (!(lnk->flags & ERTS_ML_FLG_EXTENDED))
size = sizeof(ErtsLinkData);
else {
ErtsLinkDataExtended *ldep = (ErtsLinkDataExtended *) ldp;
ASSERT(lnk->type == ERTS_LNK_TYPE_DIST_PROC);
ASSERT(is_external_pid_header(ldep->heap[0]));
size = sizeof(ErtsLinkDataExtended);
size += thing_arityval(ldep->heap[0])*sizeof(Eterm);
}
refc = (Uint) erts_atomic32_read_nob(&ldp->refc);
ASSERT(refc > 0);
return size / refc;
}
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\
* Misc *
\* */
void
erts_monitor_link_init(void)
{
monitor_init();
link_init();
}
