/**
* Runs an In-Memory Data Grid client example.
*
* @param client A client reference.
*/
void clientDataExample(TGridClientPtr& client) {
TGridClientComputePtr cc = client->compute();
TGridClientNodeList nodes = cc->nodes();
if (nodes.empty()) {
cerr << "Failed to connect to grid in cache example, make sure that it is started and connection "
"properties are correct." << endl;
GridClientFactory::stopAll();
return;
}
cout << "Current grid topology: " << nodes.size() << endl;
// Random node ID.
GridUuid randNodeId = nodes[0]->getNodeId();
// Get client projection of grid partitioned cache.
TGridClientDataPtr rmtCache = client->data(CACHE_NAME);
TGridClientVariantSet keys;
// Put some values to the cache.
for (int32_t i = 0; i < KEYS_CNT; i++) {
ostringstream oss;
oss << "val-" << i;
string v = oss.str();
string key = boost::lexical_cast<string>(i);
rmtCache->put(key, v);
GridUuid nodeId = rmtCache->affinity(key);
cout << ">>> Storing key " << key << " on node " << nodeId << endl;
keys.push_back(key);
}
TGridClientNodeList nodelst;
TGridClientNodePtr p = client->compute()->node(randNodeId);
nodelst.push_back(p);
// Pin a remote node for communication. All further communication
// on returned projection will happen through this pinned node.
TGridClientDataPtr prj = rmtCache->pinNodes(nodelst);
GridClientVariant key0 = GridClientVariant(boost::lexical_cast<string>(0));
GridClientVariant key6 = GridClientVariant(boost::lexical_cast<string>(6));
GridClientVariant val = prj->get(key0);
cout << ">>> Loaded single value: " << val.debugString() << endl;
TGridClientVariantMap vals = prj->getAll(keys);
cout << ">>> Loaded multiple values, size: " << vals.size() << endl;
for (TGridClientVariantMap::const_iterator iter = vals.begin(); iter != vals.end(); ++iter)
cout << ">>> Loaded cache entry [key=" << iter->first <<
", val=" << iter->second << ']' << endl;
TGridBoolFuturePtr futPut = prj->putAsync(key0, "new value for 0");
cout << ">>> Result of asynchronous put: " << (futPut->get() ? "success" : "failure") << endl;
unordered_map<GridUuid, TGridClientVariantMap> keyVals;
GridUuid nodeId = rmtCache->affinity(key0);
for (int32_t i = 0; i < KEYS_CNT; i++) {
ostringstream oss;
oss << "updated-val-" << i;
string v = oss.str();
string key = boost::lexical_cast<string>(i);
keyVals[nodeId][key] = v;
}
for (unordered_map<GridUuid, TGridClientVariantMap>::iterator iter = keyVals.begin();
iter != keyVals.end(); ++iter)
rmtCache->putAll(iter->second);
vector<TGridBoolFuturePtr> futs;
for (unordered_map<GridUuid, TGridClientVariantMap>::iterator iter = keyVals.begin();
iter != keyVals.end(); ++iter) {
TGridBoolFuturePtr fut = rmtCache->putAllAsync(iter->second);
futs.push_back(fut);
}
for (vector<TGridBoolFuturePtr>::iterator iter = futs.begin(); iter != futs.end(); ++iter)
cout << ">>> Result of async putAll: " << (iter->get()->get() ? "success" : "failure") << endl;
cout << ">>> Value for key " << key0.debugString() << " is " <<
rmtCache->get(key0).debugString() << endl;
// Asynchronous gets, too.
TGridClientFutureVariant futVal = rmtCache->getAsync(key0);
cout << ">>> Asynchronous value for key " << key0.debugString() << " is " <<
futVal->get().debugString() << endl;
// Multiple values can be fetched at once. Here we batch our get
// requests by affinity nodes to ensure least amount of network trips.
for (unordered_map<GridUuid, TGridClientVariantMap>::iterator iter = keyVals.begin();
iter != keyVals.end(); ++iter) {
GridUuid uuid = iter->first;
TGridClientVariantMap m = iter->second;
TGridClientVariantSet keys;
for (TGridClientVariantMap::const_iterator miter = m.begin(); miter != m.end(); ++miter )
keys.push_back(miter->first);
// Since all keys in our getAll(...) call are mapped to the same primary node,
// grid cache client will pick this node for the request, so we only have one
// network trip here.
TGridClientVariantMap map = rmtCache->getAll(keys);
cout << ">>> Values from node [nodeId=" + uuid.uuid() + ", values=[" << endl;
for (TGridClientVariantMap::const_iterator miter = map.begin(); miter != map.end(); ++miter) {
if (miter != map.begin())
cout << ", " << endl;
cout << "[key=" << miter->first << ", value=" << miter->second << ']';
}
cout << ']' << endl;
}
// Multiple values may be retrieved asynchronously, too.
// Here we retrieve all keys at once. Since this request
// will be sent to some grid node, this node may not be
// the primary node for all keys and additional network
// trips will have to be made within grid.
TGridClientVariantMap map = rmtCache->getAllAsync(keys)->get();
cout << ">>> Values retrieved asynchronously: " << endl;
for (TGridClientVariantMap::const_iterator miter = map.begin(); miter != map.end(); ++miter) {
if (miter != map.begin())
cout << ", " << endl;
cout << "[key=" << miter->first << ", value=" << miter->second << ']';
}
cout << endl;
// Contents of cache may be removed one by one synchronously.
// Again, this operation is affinity aware and only the primary
// node for the key is contacted.
bool res = rmtCache->remove(key0);
cout << ">>> Result of removal: " << (res ? "success" : "failure") << endl;
// ... and asynchronously.
TGridBoolFuturePtr futRes = rmtCache->removeAsync(boost::lexical_cast<string>(1));
cout << ">>> Result of asynchronous removal: " << (futRes->get() ? "success" : "failure") << endl;
// Multiple entries may be removed at once synchronously...
TGridClientVariantSet keysRemove;
keysRemove.push_back(boost::lexical_cast<string>(2));
keysRemove.push_back(boost::lexical_cast<string>(3));
bool rmvRslt = rmtCache->removeAll(keysRemove);
cout << ">>> Result of removeAll: " << (rmvRslt ? "success" : "failure") << endl;
// ... and asynchronously.
keysRemove.clear();
keysRemove.push_back(boost::lexical_cast<string>(4));
keysRemove.push_back(boost::lexical_cast<string>(5));
TGridBoolFuturePtr rmvFut = rmtCache->removeAllAsync(keysRemove);
cout << ">>> Result of asynchronous removeAll: " << (rmvFut->get() ? "success" : "failure") << endl;
// Values may also be replaced.
res = rmtCache->replace(key6, "newer value for 6");
cout << ">>> Result for replace for existent key6 is " << (res ? "success" : "failure") << endl;
// Asynchronous replace is supported, too. This one is expected to fail, since key0 doesn't exist.
futRes = rmtCache->replaceAsync(key0, "newest value for 0");
res = futRes->get();
cout << ">>> Result for asynchronous replace for nonexistent key0 is " <<
(res ? "success" : "failure") << endl;
rmtCache->put(key0, boost::lexical_cast<string>(0));
// Compare and set are implemented, too.
res = rmtCache->cas(key0, "newest cas value for 0", boost::lexical_cast<string>(0));
cout << ">>> Result for put using cas is " << (res ? "success" : "failure") << endl;
// CAS can be asynchronous.
futRes = rmtCache->casAsync(key0, boost::lexical_cast<string>(0), "newest cas value for 0");
res = futRes->get();
// Expected to fail.
cout << ">>> Result for put using asynchronous cas is "
<< (res? "success" : "failure") << endl;
// It's possible to obtain cache metrics using data client API.
GridClientDataMetrics metrics = rmtCache->metrics();
cout << ">>> Cache metrics : " << metrics << endl;
TGridClientFutureDataMetrics futMetrics = rmtCache->metricsAsync();
cout << ">>> Cache asynchronous metrics: " << futMetrics->get() << endl;
key0 = GridClientVariant("0");
GridClientVariant val0("new value for 0");
rmtCache->put(key0, val0);
randNodeId = nodes[0]->getNodeId();
TGridClientComputePtr clientCompute = client->compute();
cout << "RandNodeId is " << randNodeId.uuid() << endl;
p = clientCompute->node(randNodeId);
TGridClientComputePtr compPrj = clientCompute->projection(*p);
GridClientVariant rslt = compPrj->affinityExecute("org.gridgain.examples.client.api.GridClientExampleTask", CACHE_NAME, key0);
cout << ">>> Affinity execute : there are totally " << rslt.toString() << " test entries on the grid" <<
endl;
futVal = compPrj->affinityExecuteAsync("org.gridgain.examples.client.api.GridClientExampleTask", CACHE_NAME, key0);
cout << ">>> Affinity execute async : there are totally " << futVal->get().toString() <<
" test entries on the grid" << endl;
}
void clientComputeExample(TGridClientPtr client) {
TGridClientComputePtr clientCompute = client->compute();
TGridClientNodeList nodes = clientCompute->nodes();
if (nodes.empty()) {
cerr << "Failed to connect to grid in compute example, make sure that it is started and connection "
"properties are correct." << endl;
GridClientFactory::stopAll();
return;
}
cout << "Current grid topology: " << nodes.size() << endl;
GridUuid randNodeId = nodes[0]->getNodeId();
cout << "RandNodeId is " << randNodeId.uuid() << endl;
TGridClientNodePtr p = clientCompute->node(randNodeId);
TGridClientComputePtr prj = clientCompute->projection(*p);
GridClientVariant rslt = prj->execute("org.gridgain.examples.client.GridClientExampleTask");
cout << ">>> GridClientNode projection : there are totally " << rslt.toString() <<
" test entries on the grid" << endl;
TGridClientNodeList prjNodes;
prjNodes.push_back(p);
prj = clientCompute->projection(prjNodes);
rslt = prj->execute("org.gridgain.examples.client.GridClientExampleTask");
cout << ">>> Collection execution : there are totally " << rslt.toString() <<
" test entries on the grid" << endl;
GridUuidNodePredicate* uuidPredicate = new GridUuidNodePredicate(randNodeId);
TGridClientNodePredicatePtr predPtr(uuidPredicate);
prj = clientCompute->projection(predPtr);
rslt = prj->execute("org.gridgain.examples.client.GridClientExampleTask");
cout << ">>> Predicate execution : there are totally " << rslt.toString() <<
" test entries on the grid" << endl;
// Balancing - may be random or round-robin. Users can create
// custom load balancers as well.
TGridClientLoadBalancerPtr balancer(new GridClientRandomBalancer());
prj = clientCompute->projection(predPtr, balancer);
rslt = prj->execute("org.gridgain.examples.client.GridClientExampleTask");
cout << ">>> Predicate execution with balancer : there are totally " << rslt.toString() <<
" test entries on the grid" << endl;
// Now let's try round-robin load balancer.
balancer = TGridClientLoadBalancerPtr(new GridClientRoundRobinBalancer());
prj = prj->projection(prjNodes, balancer);
rslt = prj->execute("org.gridgain.examples.client.GridClientExampleTask");
cout << ">>> GridClientNode projection : there are totally " << rslt.toString() <<
" test entries on the grid" << endl;
TGridClientFutureVariant futVal = prj->executeAsync("org.gridgain.examples.client.GridClientExampleTask");
futVal->get();
if (futVal->success())
cout << ">>> Execute async : there are totally " << futVal->result().toString() <<
" test entries on the grid" << endl;
else
cout << ">>> Execute async failed" << endl;
TGridClientDataPtr rmtCache = client->data("partitioned");
GridClientVariant key0((int32_t)0);
GridClientVariant val0("new value for 0");
rmtCache->put(key0, val0);
rslt = prj->affinityExecute("org.gridgain.examples.client.GridClientExampleTask", "partitioned", key0);
cout << ">>> Affinity execute : there are totally " << rslt.toString() << " test entries on the grid" <<
endl;
futVal = prj->affinityExecuteAsync("org.gridgain.examples.client.GridClientExampleTask", "partitioned", key0);
futVal->get();
if (futVal->success())
cout << ">>> Affinity execute async : there are totally " << futVal->result().toString() <<
" test entries on the grid" << endl;
else
cout << ">>> Affinity execute async failed" << endl;
vector<GridUuid> uuids;
uuids.push_back(randNodeId);
nodes = prj->nodes(uuids);
cout << ">>> Nodes with UUID " << randNodeId.uuid() << " : ";
for (size_t i = 0 ; i < nodes.size(); i++) {
if (i != 0)
cout << ", ";
cout << *(nodes[i]);
}
cout << endl;
// Nodes may also be filtered with predicate. Here
// we create projection which only contains local node.
GridUuidNodePredicate* uuidNodePredicate = new GridUuidNodePredicate(randNodeId);
TGridClientNodePredicatePtr predFullPtr(uuidNodePredicate);
nodes = prj->nodes(predFullPtr);
cout << ">>> Nodes filtered with predicate : ";
for (size_t i = 0 ; i < nodes.size(); i++) {
if (i != 0)
cout << ", ";
cout << *(nodes[i]);
}
cout << endl;
// Information about nodes may be refreshed explicitly.
TGridClientNodePtr clntNode = prj->refreshNode(randNodeId, true, true);
cout << ">>> Refreshed node : " << *clntNode << endl;
TGridClientNodeFuturePtr futClntNode = prj->refreshNodeAsync(randNodeId, false, false);
futClntNode->get();
if (futClntNode->success())
cout << ">>> Refreshed node asynchronously : " << *(futClntNode->result()) << endl;
else
cout << ">>> Refresh node asynchronously failed." << endl;
// Nodes may also be refreshed by IP address.
string clntAddr = "127.0.0.1";
vector<GridSocketAddress> addrs = clntNode->availableAddresses(TCP);
if (addrs.size() > 0)
clntAddr = addrs[0].host();
clntNode = prj->refreshNode(clntAddr, true, true);
cout << ">>> Refreshed node by IP : " << *clntNode << endl;
// Asynchronous version.
futClntNode = prj->refreshNodeAsync(clntAddr, false, false);
futClntNode->get();
if (futClntNode->success())
cout << ">>> Refreshed node by IP asynchronously : " << *futClntNode->result() << endl;
else
cout << ">>> Refreshed node by IP asynchronously failed." << endl;
// Topology as a whole may be refreshed, too.
TGridClientNodeList top = prj->refreshTopology(true, true);
cout << ">>> Refreshed topology : ";
for (size_t i = 0 ; i < top.size(); i++) {
if (i != 0)
cout << ", ";
cout << *top[i];
}
cout << endl;
// Asynchronous version.
TGridClientNodeFutureList topFut = prj->refreshTopologyAsync(false, false);
topFut->get();
if (topFut->success()) {
cout << ">>> Refreshed topology asynchronously : ";
top = topFut->result();
for (size_t i = 0 ; i < top.size(); i++) {
if (i != 0)
cout << ", ";
cout << *top[i];
}
cout << endl;
}
else
cout << ">>> Refresh topology asynchronously failed." << endl;
try {
vector<string> log = prj->log(0, 1);
cout << ">>> First log lines : " << endl;
cout << log[0] << endl;
cout << log[1] << endl;
// Log entries may be fetched asynchronously.
TGridFutureStringList futLog = prj->logAsync(1, 2);
futLog->get();
if (futLog->success()) {
log = futLog->result();
cout << ">>> First log lines fetched asynchronously : " << endl;
cout << log[0] << endl;
cout << log[1] << endl;
}
else
cout << ">>> First log lines fetching asynchronously failed " << endl;
// Log file name can also be specified explicitly.
log = prj->log("work/log/gridgain.log", 0, 1);
cout << ">>> First log lines from log file work/log/gridgain.log : " << endl;
cout << log[0] << endl;
cout << log[1] << endl;
// Asynchronous version supported as well.
futLog = prj->logAsync("work/log/gridgain.log", 1, 2);
futLog->get();
if (futLog->success()) {
log = futLog->result();
cout << ">>> First log lines from log file work/log/gridgain.log fetched asynchronously : " << endl;
cout << log[0] << endl;
cout << log[1] << endl;
}
else
cout << ">>> First log lines from log file work/log/gridgain.log fetching asynchronously failed " << endl;
}
catch (GridClientException&) {
cout << "Log file was not found " << endl;
}
cout << "In the end of example" << endl;
}
