c_iter
v_serviceTakeNewGroups(
v_service service)
{
c_iter result;
v_group group;
c_set newGroups;
assert(service != NULL);
assert(C_TYPECHECK(service, v_service));
result = c_iterNew(NULL);
v_observerLock(v_observer(service));
newGroups = (c_set)v_observer(service)->eventData;
if (newGroups != NULL) {
group = v_group(c_take(newGroups));
while (group != NULL) {
c_iterInsert(result, group);
group = v_group(c_take(newGroups));
}
}
v_observerUnlock(v_observer(service));
return result;
}
u_result
u_dispatcherNotify(
u_dispatcher _this)
{
v_observer ko;
u_result result = U_RESULT_OK;
if (_this != NULL) {
result = u_entityReadClaim(u_entity(_this), (v_entity*)(&ko));
if (result == U_RESULT_OK) {
assert(ko);
/* Wakeup the dispatch thread */
v_observerLock(ko);
v_observerNotify(ko, NULL, NULL);
v_observerUnlock(ko);
result = u_entityRelease(u_entity(_this));
if (result != U_RESULT_OK) {
OS_REPORT(OS_ERROR, "u_dispatcherNotify", 0,
"Release observer failed.");
}
} else {
OS_REPORT(OS_WARNING, "u_dispatcherNotify", 0,
"Failed to claim Dispatcher.");
}
} else {
OS_REPORT(OS_ERROR,"u_dispatcherNotify",0,
"Illegal parameter.");
result = U_RESULT_ILL_PARAM;
}
return result;
}
void
v_serviceRenewLease(
v_service service,
v_duration leasePeriod)
{
assert(service != NULL);
assert(C_TYPECHECK(service, v_service));
v_observerLock(v_observer(service));
v_leaseRenew(service->lease, &leasePeriod);
v_observerUnlock(v_observer(service));
}
u_result
u_dispatcherDeinit(
u_dispatcher _this)
{
v_observer ko;
u_listener listener;
os_threadId tid;
u_result result = U_RESULT_OK;
if (_this != NULL) {
os_mutexLock(&_this->mutex);
listener = u_listener(c_iterTakeFirst(_this->listeners));
while (listener != NULL) {
u_listenerFree(listener);
listener = u_listener(c_iterTakeFirst(_this->listeners));
}
c_iterFree(_this->listeners);
_this->listeners = NULL; /* Flags the dispatch thread to stop */
if (os_threadIdToInteger(_this->threadId) != 0U) {
tid = _this->threadId;
result = u_entityReadClaim(u_entity(_this), (v_entity*)(&ko));
if(result != U_RESULT_OK) {
/* This is a valid situation when a participant has been
* freed prior to the freeing of a dispatcher within the
* participant.
*/
os_mutexUnlock(&_this->mutex);
os_threadWaitExit(tid, NULL);
os_mutexDestroy(&_this->mutex);
/*return U_RESULT_INTERNAL_ERROR;*/
} else {
/* Wakeup the dispatch thread */
v_observerLock(ko);
v_observerNotify(ko, NULL, NULL);
v_observerUnlock(ko);
u_entityRelease(u_entity(_this));
os_mutexUnlock(&_this->mutex);
os_threadWaitExit(tid, NULL);
os_mutexDestroy(&_this->mutex);
}
} else {
os_mutexUnlock(&_this->mutex);
os_mutexDestroy(&_this->mutex);
}
result = u_entityDeinit(u_entity(_this));
} else {
OS_REPORT(OS_ERROR,"u_dispatcherDeinit",0,
"Illegal parameter.");
result = U_RESULT_ILL_PARAM;
}
return result;
}
u_result
u_dispatcherRemoveListener(
u_dispatcher _this,
u_dispatcherListener listener)
{
u_listener ul;
v_observer ko;
os_threadId tid;
u_result result = U_RESULT_OK;
struct compareArg arg;
if ((_this != NULL) && (listener != NULL)) {
os_mutexLock(&_this->mutex);
arg.listener = listener;
ul = (u_listener) c_iterResolve(_this->listeners, compare, &arg);
tid = _this->threadId;
if (ul != NULL) {
c_iterTake(_this->listeners, ul);
if (c_iterLength(_this->listeners) == 0) {
result = u_entityReadClaim(u_entity(_this), (v_entity*)(&ko));
if(result == U_RESULT_OK) {
assert(ko);
/* Wakeup the dispatch thread */
v_observerLock(ko);
v_observerNotify(ko, NULL, NULL);
v_observerUnlock(ko);
result = u_entityRelease(u_entity(_this));
if (result != U_RESULT_OK) {
OS_REPORT(OS_ERROR, "u_dispatcherRemoveListener", 0,
"Release observer failed.");
}
} else {
OS_REPORT(OS_WARNING, "u_dispatcherRemoveListener", 0,
"Failed to claim Dispatcher.");
}
}
u_listenerFree(ul);
}
os_mutexUnlock(&_this->mutex);
if ((c_iterLength(_this->listeners) == 0)
&& (os_threadIdToInteger(tid) != 0U)) {
os_threadWaitExit(tid, NULL);
}
} else {
OS_REPORT(OS_ERROR,"u_dispatcherInsertListener",0,
"Illegal parameter.");
result = U_RESULT_ILL_PARAM;
}
return result;
}
void
v_serviceFillNewGroups(
v_service service)
{
c_set newGroups;
C_STRUCT(v_event) ge;
v_group g, oldGroup;
c_iter oldGroups;
v_kernel kernel;
assert(service != NULL);
assert(C_TYPECHECK(service, v_service));
kernel = v_objectKernel(service);
newGroups = (c_voidp)c_setNew(v_kernelType(kernel, K_GROUP));
if (newGroups != NULL) {
addAllGroups(newGroups, kernel->groupSet);
v_observerLock(v_observer(service));
g = v_group(c_read(newGroups)); /* need a group for the event */
if(v_observer(service)->eventData != NULL){
oldGroups = ospl_c_select((c_set)v_observer(service)->eventData, 0);
oldGroup = v_group(c_iterTakeFirst(oldGroups));
while(oldGroup){
newGroups = c_setInsert(newGroups, oldGroup);
c_free(oldGroup);
oldGroup = v_group(c_iterTakeFirst(oldGroups));
}
c_iterFree(oldGroups);
}
/* just for safety, when assertion are compiled out, free the prev set */
c_free((c_object)v_observer(service)->eventData);
v_observer(service)->eventData = (c_voidp)newGroups;
ge.kind = V_EVENT_NEW_GROUP;
ge.source = v_publicHandle(v_public(kernel));
ge.userData = g;
v_observerNotify(v_observer(service), &ge, NULL);
v_observerUnlock(v_observer(service));
c_free(g);
}
}
void
v_groupStreamConnectNewGroups(
v_groupStream stream,
v_group group)
{
struct groupConnected data;
assert(stream != NULL);
assert(C_TYPECHECK(stream,v_groupStream));
v_observerLock(v_observer(stream));
/*
* This means the group is interesting for this
* groupActionStream. Now I have to check if the stream is already
* connected to this group, because we wouldn't want to connect
* multiple times to one single group.
*/
data.connected = FALSE;
data.group = group;
c_walk(stream->groups, (c_action)isGroupConnected, &data);
if(data.connected == FALSE){
/*
* The stream is not connected to the group yet, so connect now.
*/
v_groupStreamSubscribeGroup(stream, group);
}
v_observerUnlock(v_observer(stream));
if(data.connected == FALSE){
v_groupStreamHistoricalData(group, stream);
}
return;
}
void
cmx_readerSnapshotNewAction(
v_entity e,
c_voidp args)
{
v_dataReader reader;
c_iter instances;
v_dataReaderInstance instance;
v_dataReaderSample sample, prev;
v_query query;
c_bool release;
sd_serializer ser;
sd_serializedData data;
struct cmx_readerSnapshotArg* arg;
release = FALSE;
arg = (struct cmx_readerSnapshotArg*)args;
reader = NULL;
instances = NULL;
ser = NULL;
switch(v_object(e)->kind){
case K_DATAREADER:
reader = v_dataReader(e);
arg->success = TRUE;
arg->snapshot = cmx_readerSnapshot(os_malloc(C_SIZEOF(cmx_readerSnapshot)));
v_observerLock(v_observer(reader));
if(reader->index->objects){
instances = c_select(reader->index->notEmptyList, 0);
}
break;
case K_QUERY:
case K_DATAREADERQUERY:
query = v_query(e);
reader = v_dataReader(v_querySource(query));
if(reader != NULL){
release = TRUE;
arg->success = TRUE;
arg->snapshot = cmx_readerSnapshot(os_malloc(C_SIZEOF(cmx_readerSnapshot)));
v_observerLock(v_observer(reader));
switch(v_object(query)->kind){
case K_DATAREADERQUERY:
if(v_dataReaderQuery(query)->instanceQ){
instances = c_select((c_collection)(v_dataReaderQuery(query)->instanceQ), 0);
}
break;
default:
OS_REPORT_1(OS_ERROR, CM_XML_CONTEXT, 0,
"cmx_readerSnapshotNewAction unknown kind (%d).",
v_object(query)->kind);
break;
}
}
break;
default:
break;
}
if(arg->success == TRUE){
arg->snapshot->samples = c_iterNew(NULL);
}
if(instances != NULL){
instance = v_dataReaderInstance(c_iterTakeFirst(instances));
while(instance != NULL){
sample = c_keep(v_dataReaderInstanceHead(instance));
if(sample != NULL){
prev = sample->prev;
sample->prev = NULL;
if(ser == NULL){
ser = sd_serializerXMLNewTyped(c_getType(c_object(sample)));
}
data = sd_serializerSerialize(ser, c_object(sample));
arg->snapshot->samples = c_iterInsert(arg->snapshot->samples,
sd_serializerToString(ser, data));
sd_serializedDataFree(data);
sample->prev = prev;
c_free(sample);
}
c_free(instance);
instance = v_dataReaderInstance(c_iterTakeFirst(instances));
}
c_iterFree(instances);
}
if(reader != NULL){
v_observerUnlock(v_observer(reader));
if(release == TRUE){
c_free(reader);
}
}
if(ser != NULL){
sd_serializerFree(ser);
}
}
void
cmx_readerDataTypeAction(
v_entity entity,
c_voidp args)
{
sd_serializer ser;
sd_serializedData data;
c_type type;
v_dataReader r;
v_query query;
v_topic topic;
struct cmx_readerArg *arg;
arg = (struct cmx_readerArg *)args;
type = NULL;
switch(v_object(entity)->kind){
case K_DATAREADER:
r = v_dataReader(entity);
v_observerLock(v_observer(r));
topic = v_dataReaderGetTopic(r);
type = v_topicDataType(topic);
c_free(topic);
v_observerUnlock(v_observer(r));
break;
case K_DATAREADERQUERY:
query = v_query(entity);
r = v_dataReader(v_querySource(query));
v_observerLock(v_observer(r));
topic = v_dataReaderGetTopic(r);
type = v_topicDataType(topic);
c_free(topic);
v_observerUnlock(v_observer(r));
c_free(r);
break;
case K_NETWORKREADER:
OS_REPORT(OS_ERROR, CM_XML_CONTEXT, 0,
"Resolving data type of networkReader unsupported.\n");
assert(FALSE);
break;
case K_GROUPQUEUE:
OS_REPORT(OS_ERROR, CM_XML_CONTEXT, 0,
"Resolving data type of groupQueue unsupported.\n");
assert(FALSE);
break;
default:
OS_REPORT(OS_ERROR, CM_XML_CONTEXT, 0,
"Trying to resolve dataType of unknown reader type.\n");
assert(FALSE);
break;
}
if(type != NULL){
ser = sd_serializerXMLMetadataNew(c_getBase(type));
data = sd_serializerSerialize(ser, type);
arg->result = sd_serializerToString(ser, data);
sd_serializedDataFree(data);
sd_serializerFree(ser);
}
}
void
v_groupStreamNotify(
v_groupStream stream,
v_event e,
c_voidp userData)
{
struct groupConnected data;
c_iter partitions;
c_bool interested;
v_partition partition, found;
OS_UNUSED_ARG(userData);
assert(stream != NULL);
assert(C_TYPECHECK(stream,v_groupStream));
if (e) {
if (e->kind == V_EVENT_NEW_GROUP) {
v_observerLock(v_observer(stream));
/*
* Check if group fits interest. This extra steps are needed because
* the groupActionStream does not create the groups that match the
* subscriber qos partition expression on creation. It only needs to
* connect to new groups once they are created. This is a different
* approach then for a data reader.
*/
partition = v_group(e->userData)->partition;
/*
* Because already existing partitions are created and added to the
* subscriber of the groupActionStream at creation time, these
* partitions can be resolved from the subscriber. This is necessary to
* determine whether the groupActionStream should connect to the new
* group or if it is already connected.
*/
partitions = v_subscriberLookupPartitions(v_reader(stream)->subscriber,
v_partitionName(partition));
interested = FALSE;
found = v_partition(c_iterTakeFirst(partitions));
while(found){
if(interested == FALSE){
if(strcmp(v_partitionName(partition),
v_partitionName(found)) == 0){
interested = TRUE;
}
}
c_free(found);
found = v_partition(c_iterTakeFirst(partitions));
}
c_iterFree(partitions);
if(interested == TRUE){
/*
* This means the group is interesting for this
* groupActionStream. Now I have to check if the stream is already
* connected to this group, because we wouldn't want to connect
* multiple times to one single group.
*/
data.connected = FALSE;
data.group = v_group(e->userData);
c_walk(stream->groups, (c_action)isGroupConnected, &data);
if(data.connected == FALSE){
/*
* The stream is not connected to the group yet, so connect now.
*/
v_groupStreamSubscribeGroup(stream, v_group(e->userData));
}
}
v_observerUnlock(v_observer(stream));
}
}
return;
}
void
cmx_readerSnapshotNewAction(
v_public p,
c_voidp args)
{
v_dataReader reader;
c_iter instances;
v_dataReaderInstance instance;
v_dataReaderSample sample;
v_query query;
c_bool release;
sd_serializer ser;
sd_serializedData data;
struct cmx_readerSnapshotArg* arg;
release = FALSE;
arg = (struct cmx_readerSnapshotArg*)args;
reader = NULL;
instances = NULL;
ser = NULL;
switch(v_object(p)->kind){
case K_DATAREADER:
reader = v_dataReader(p);
arg->success = TRUE;
arg->snapshot = cmx_readerSnapshot(os_malloc(C_SIZEOF(cmx_readerSnapshot)));
v_observerLock(v_observer(reader));
if(reader->index->objects){
instances = ospl_c_select(reader->index->notEmptyList, 0);
}
break;
case K_QUERY:
case K_DATAREADERQUERY:
query = v_query(p);
reader = v_dataReader(v_querySource(query));
if(reader != NULL){
release = TRUE;
arg->success = TRUE;
arg->snapshot = cmx_readerSnapshot(os_malloc(C_SIZEOF(cmx_readerSnapshot)));
v_observerLock(v_observer(reader));
switch(v_object(query)->kind){
case K_DATAREADERQUERY:
if(v_dataReaderQuery(query)->instanceQ){
instances = ospl_c_select((c_collection)(v_dataReaderQuery(query)->instanceQ), 0);
}
break;
default:
OS_REPORT(OS_ERROR, CM_XML_CONTEXT, 0,
"cmx_readerSnapshotNewAction unknown kind (%d).",
v_object(query)->kind);
break;
}
}
break;
default:
break;
}
if(arg->success == TRUE){
arg->snapshot->samples = c_iterNew(NULL);
}
if(instances != NULL){
v_dataReaderSample sampleShallowCopy = NULL;
instance = v_dataReaderInstance(c_iterTakeFirst(instances));
while(instance != NULL){
v_state ivState = instance->_parent._parent.state & (L_DISPOSED | L_NOWRITERS | L_NEW);
sample = v_dataReaderInstanceOldest(instance);
if (sample != NULL) {
do {
v_state state = ivState | ((sample->_parent.sampleState & (L_READ | L_LAZYREAD)) ? L_READ : 0);
if (sampleShallowCopy == NULL) {
sampleShallowCopy = c_new(c_getType(c_object(sample)));
}
memcpy(sampleShallowCopy, sample, c_typeSize(c_getType(sampleShallowCopy)));
sampleShallowCopy->newer = NULL;
sampleShallowCopy->_parent.sampleState &= ~(L_DISPOSED | L_NOWRITERS | L_NEW | L_READ | L_LAZYREAD);
sampleShallowCopy->_parent.sampleState |= state;
if(ser == NULL){
ser = sd_serializerXMLNewTyped(c_getType(c_object(sampleShallowCopy)));
}
data = sd_serializerSerialize(ser, c_object(sampleShallowCopy));
arg->snapshot->samples = c_iterInsert(arg->snapshot->samples, sd_serializerToString(ser, data));
sd_serializedDataFree(data);
sample = sample->newer;
} while (sample != NULL);
}
c_free(instance);
instance = v_dataReaderInstance(c_iterTakeFirst(instances));
}
c_iterFree(instances);
if (sampleShallowCopy != NULL) {
memset(sampleShallowCopy, 0, c_typeSize(c_getType(sampleShallowCopy)));
c_free(sampleShallowCopy);
}
}
if(reader != NULL){
v_observerUnlock(v_observer(reader));
if(release == TRUE){
c_free(reader);
}
}
if(ser != NULL){
sd_serializerFree(ser);
}
}
