void Worker::executeWorkOrderHelper(const TaggedMessage &tagged_message,
CompletionMessageProtoT *proto) {
std::chrono::time_point<std::chrono::steady_clock> start, end;
WorkerMessage worker_message(
*static_cast<const WorkerMessage *>(tagged_message.message()));
DCHECK(worker_message.getWorkOrder() != nullptr);
const size_t query_id_for_workorder = worker_message.getWorkOrder()->getQueryID();
// Start measuring the execution time.
start = std::chrono::steady_clock::now();
worker_message.getWorkOrder()->execute();
end = std::chrono::steady_clock::now();
delete worker_message.getWorkOrder();
const uint64_t execution_time_microseconds =
std::chrono::duration_cast<std::chrono::microseconds>(end - start)
.count();
// Construct the proto message.
proto->set_operator_index(worker_message.getRelationalOpIndex());
proto->set_query_id(query_id_for_workorder);
proto->set_worker_thread_index(worker_thread_index_);
proto->set_execution_time_in_microseconds(execution_time_microseconds);
}
QueryManager::QueryStatusCode QueryManager::processMessage(
const TaggedMessage &tagged_message) {
dag_node_index op_index;
switch (tagged_message.message_type()) {
case kWorkOrderCompleteMessage: {
serialization::WorkOrderCompletionMessage proto;
CHECK(proto.ParseFromArray(tagged_message.message(),
tagged_message.message_bytes()));
op_index = proto.operator_index();
processWorkOrderCompleteMessage(proto.operator_index());
break;
}
case kRebuildWorkOrderCompleteMessage: {
serialization::WorkOrderCompletionMessage proto;
CHECK(proto.ParseFromArray(tagged_message.message(),
tagged_message.message_bytes()));
op_index = proto.operator_index();
processRebuildWorkOrderCompleteMessage(proto.operator_index());
break;
}
case kCatalogRelationNewBlockMessage: {
serialization::CatalogRelationNewBlockMessage proto;
CHECK(proto.ParseFromArray(tagged_message.message(),
tagged_message.message_bytes()));
const block_id block = proto.block_id();
CatalogRelation *relation =
static_cast<CatalogDatabase*>(catalog_database_)->getRelationByIdMutable(proto.relation_id());
relation->addBlock(block);
if (proto.has_partition_id()) {
relation->getPartitionSchemeMutable()->addBlockToPartition(
proto.partition_id(), block);
}
return QueryStatusCode::kNone;
}
case kDataPipelineMessage: {
// Possible message senders include InsertDestinations and some
// operators which modify existing blocks.
serialization::DataPipelineMessage proto;
CHECK(proto.ParseFromArray(tagged_message.message(),
tagged_message.message_bytes()));
op_index = proto.operator_index();
processDataPipelineMessage(proto.operator_index(),
proto.block_id(),
proto.relation_id());
break;
}
case kWorkOrdersAvailableMessage: {
serialization::WorkOrdersAvailableMessage proto;
CHECK(proto.ParseFromArray(tagged_message.message(),
tagged_message.message_bytes()));
op_index = proto.operator_index();
// Check if new work orders are available.
fetchNormalWorkOrders(op_index);
// Dispatch the WorkerMessages to the workers. We prefer to start the search
// for the schedulable WorkOrders beginning from 'op_index'. The first
// candidate worker to receive the next WorkOrder is the one that sent the
// response message to Foreman.
// TODO(zuyu): Improve the data locality for the next WorkOrder.
break;
}
case kWorkOrderFeedbackMessage: {
WorkOrder::FeedbackMessage msg(
const_cast<void *>(tagged_message.message()),
tagged_message.message_bytes());
op_index = msg.header().rel_op_index;
processFeedbackMessage(msg);
break;
}
default:
LOG(FATAL) << "Unknown message type found in QueryManager";
}
if (query_exec_state_->hasExecutionFinished(op_index)) {
return QueryStatusCode::kOperatorExecuted;
}
// As kQueryExecuted takes precedence over kOperatorExecuted, we check again.
if (query_exec_state_->hasQueryExecutionFinished()) {
return QueryStatusCode::kQueryExecuted;
}
return QueryStatusCode::kNone;
}
