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/* Copyright 2016 The TensorFlow Authors. 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.
==============================================================================*/
#include "tensorflow/cc/training/queue_runner.h"
#include <string>
#include <vector>
#include "tensorflow/cc/framework/scope.h"
#include "tensorflow/cc/ops/standard_ops.h"
#include "tensorflow/cc/training/coordinator.h"
#include "tensorflow/core/framework/graph.pb.h"
#include "tensorflow/core/framework/tensor.h"
#include "tensorflow/core/framework/tensor_shape.h"
#include "tensorflow/core/framework/types.pb.h"
#include "tensorflow/core/lib/core/error_codes.pb.h"
#include "tensorflow/core/lib/core/notification.h"
#include "tensorflow/core/lib/core/status_test_util.h"
#include "tensorflow/core/platform/env.h"
#include "tensorflow/core/platform/test.h"
#include "tensorflow/core/protobuf/queue_runner.pb.h"
#include "tensorflow/core/public/session.h"
namespace tensorflow {
namespace {
using error::Code;
using ops::Assign;
using ops::Const;
using ops::CountUpTo;
using ops::FIFOQueue;
using ops::QueueClose;
using ops::QueueDequeue;
using ops::QueueEnqueue;
using ops::RandomNormal;
using ops::Square;
using ops::Variable;
constexpr char kAssignOpName[] = "assign";
constexpr char kCancelOp0[] = "cancel0";
constexpr char kCancelOp1[] = "cancel1";
constexpr char kCloseOp0[] = "close0";
constexpr char kCloseOp1[] = "close1";
constexpr char kCountUpToOpName[] = "count";
constexpr char kDequeueOp0[] = "dequeue0";
constexpr char kDequeueOp1[] = "dequeue1";
constexpr char kEnqueueOp0[] = "enqueue0";
constexpr char kEnqueueOp1[] = "enqueue1";
constexpr char kIllegalOpName1[] = "would fail";
constexpr char kIllegalOpName2[] = "fail again";
constexpr char kQueueName[] = "unit_test";
constexpr char kQueueName0[] = "q0";
constexpr char kQueueName1[] = "q1";
constexpr char kSquareOpName[] = "square";
constexpr char kVarOpName[] = "var";
GraphDef BuildSimpleGraph() {
Scope root = Scope::NewRootScope();
auto init_value = Const(root, 0);
auto var = Variable(root.WithOpName(kVarOpName), TensorShape({}),
DataType::DT_INT32);
auto assign = Assign(root.WithOpName(kAssignOpName), var, init_value);
auto count = CountUpTo(root.WithOpName(kCountUpToOpName), var, 10);
Square(root.WithOpName(kSquareOpName), var); // NOLINT
GraphDef graph_def;
TF_EXPECT_OK(root.ToGraphDef(&graph_def));
return graph_def;
}
QueueRunnerDef BuildQueueRunnerDef(
const std::string& queue_name, const std::vector<std::string>& enqueue_ops,
const std::string& close_op, const std::string& cancel_op,
const std::vector<Code>& queue_closed_error_codes) {
QueueRunnerDef queue_runner_def;
*queue_runner_def.mutable_queue_name() = queue_name;
for (const std::string& enqueue_op : enqueue_ops) {
*queue_runner_def.mutable_enqueue_op_name()->Add() = enqueue_op;
}
*queue_runner_def.mutable_close_op_name() = close_op;
*queue_runner_def.mutable_cancel_op_name() = cancel_op;
for (const auto& error_code : queue_closed_error_codes) {
*queue_runner_def.mutable_queue_closed_exception_types()->Add() =
error_code;
}
return queue_runner_def;
}
std::unique_ptr<Session> BuildSessionAndInitVariable(
const GraphDef& graph_def) {
SessionOptions options;
std::unique_ptr<Session> session(NewSession(options));
TF_CHECK_OK(session->Create(graph_def));
TF_CHECK_OK(session->Run({}, {}, {kAssignOpName}, nullptr));
return session;
}
TEST(QueueRunnerTest, BasicTest) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName, {kCountUpToOpName}, kSquareOpName, "", {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_CHECK_OK(qr->Start(session.get()));
TF_EXPECT_OK(qr->Join());
std::vector<Tensor> outputs;
TF_EXPECT_OK(session->Run({}, {kSquareOpName}, {}, &outputs));
int square_value = *outputs[0].scalar<int>().data();
EXPECT_EQ(square_value, 100);
}
TEST(QueueRunnerTest, QueueClosedCode) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
// Start two queues so that multiple threads are in Run.
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName, {kCountUpToOpName, kCountUpToOpName}, kSquareOpName, "",
{Code::OUT_OF_RANGE, Code::CANCELLED});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_EXPECT_OK(qr->Start(session.get()));
TF_EXPECT_OK(qr->Join());
std::vector<Tensor> outputs;
TF_EXPECT_OK(session->Run({}, {kSquareOpName}, {}, &outputs));
int square_value = *outputs[0].scalar<int>().data();
EXPECT_EQ(square_value, 100);
}
TEST(QueueRunnerTest, QueueCloseFails) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
QueueRunnerDef queue_runner_def =
BuildQueueRunnerDef(kQueueName, {kCountUpToOpName}, kIllegalOpName1, "",
{Code::OUT_OF_RANGE});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_EXPECT_OK(qr->Start(session.get()));
auto status = qr->Join();
EXPECT_EQ(status.code(), Code::NOT_FOUND) << status;
}
TEST(QueueRunnerTest, CatchErrorInJoin) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName, {kIllegalOpName1, kIllegalOpName2}, kCountUpToOpName, "", {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_EXPECT_OK(qr->Start(session.get()));
EXPECT_EQ(qr->Join().code(), Code::NOT_FOUND);
}
GraphDef BuildDoubleQueueGraph() {
Scope root = Scope::NewRootScope();
auto q0 = FIFOQueue(root.WithOpName(kQueueName0), {DataType::DT_INT32});
auto ten = Const(root, 10);
auto enqueue0 = QueueEnqueue(root.WithOpName(kEnqueueOp0), q0, {ten});
auto close0 = QueueClose(root.WithOpName(kCloseOp0), q0);
auto cancel0 = QueueClose(root.WithOpName(kCancelOp0), q0,
QueueClose::CancelPendingEnqueues(true));
auto q1 = FIFOQueue(root.WithOpName(kQueueName1), {DataType::DT_INT32},
FIFOQueue::Capacity(3));
auto dequeue0 =
QueueDequeue(root.WithOpName(kDequeueOp0), q0, {DataType::DT_INT32});
auto enqueue1 = QueueEnqueue(root.WithOpName(kEnqueueOp1), q1, {dequeue0[0]});
auto dequeue1 =
QueueDequeue(root.WithOpName(kDequeueOp1), q1, {DataType::DT_INT32});
auto close1 = QueueClose(root.WithOpName(kCloseOp1), q1);
auto cancel1 = QueueClose(root.WithOpName(kCancelOp1), q1,
QueueClose::CancelPendingEnqueues(true));
GraphDef graph_def;
TF_EXPECT_OK(root.ToGraphDef(&graph_def));
return graph_def;
}
TEST(QueueRunnerTest, RealEnqueueDequeue) {
auto graph_def = BuildDoubleQueueGraph();
SessionOptions options;
std::unique_ptr<Session> session(NewSession(options));
TF_CHECK_OK(session->Create(graph_def));
QueueRunnerDef queue_runner_def =
BuildQueueRunnerDef(kQueueName, {kEnqueueOp1}, kCloseOp1, "", {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_CHECK_OK(qr->Start(session.get()));
TF_EXPECT_OK(session->Run({}, {}, {kEnqueueOp0}, nullptr));
TF_EXPECT_OK(session->Run({}, {}, {kEnqueueOp0}, nullptr));
// Closing queue 0 would also close the queue runner.
TF_EXPECT_OK(session->Run({}, {}, {kCloseOp0}, nullptr));
TF_EXPECT_OK(qr->Join());
std::vector<Tensor> dq1;
TF_EXPECT_OK(session->Run({}, {kDequeueOp1}, {}, &dq1));
EXPECT_EQ(*dq1[0].scalar<int>().data(), 10);
std::vector<Tensor> dq2;
TF_EXPECT_OK(session->Run({}, {kDequeueOp1}, {}, &dq2));
EXPECT_EQ(*dq2[0].scalar<int>().data(), 10);
EXPECT_EQ(session->Run({}, {kDequeueOp1}, {}, nullptr).code(),
Code::OUT_OF_RANGE);
}
void JoinThread(QueueRunner* queue_runner, bool* join_succeeded,
Notification* join_done) {
EXPECT_EQ(queue_runner->Join().code(), Code::CANCELLED);
*join_succeeded = true;
join_done->Notify();
}
TEST(QueueRunnerTest, SessionCloseCancelPendingEnqueue) {
auto graph_def = BuildDoubleQueueGraph();
SessionOptions options;
std::unique_ptr<Session> session(NewSession(options));
TF_CHECK_OK(session->Create(graph_def));
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName1, {kEnqueueOp1}, kCloseOp1, kCancelOp1, {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_CHECK_OK(qr->Start(session.get()));
TF_EXPECT_OK(session->Run({}, {}, {kEnqueueOp0}, nullptr));
std::vector<Tensor> dq1;
TF_EXPECT_OK(session->Run({}, {kDequeueOp1}, {}, &dq1));
EXPECT_EQ(*dq1[0].scalar<int>().data(), 10);
// The expected behavior is the QueueRunner::Join() call is blocked until
// Session::Close() is called.
bool join_succeeded = false;
Notification join_done;
Env::Default()->SchedClosure(
std::bind(&JoinThread, qr.get(), &join_succeeded, &join_done));
Env::Default()->SleepForMicroseconds(10000000);
EXPECT_EQ(join_succeeded, false);
// Closing the session is required to cancel pending enqueue nodes.
TF_EXPECT_OK(session->Close());
join_done.WaitForNotification();
EXPECT_EQ(join_succeeded, true);
}
TEST(QueueRunnerTest, EmptyEnqueueOps) {
QueueRunnerDef queue_runner_def =
BuildQueueRunnerDef(kQueueName, {}, kCountUpToOpName, "", {});
std::unique_ptr<QueueRunner> qr;
EXPECT_EQ(QueueRunner::New(queue_runner_def, &qr).code(),
Code::INVALID_ARGUMENT);
}
TEST(QueueRunnerTest, StartTimeout) {
GraphDef graph_def = BuildDoubleQueueGraph();
SessionOptions options;
std::unique_ptr<Session> session(NewSession(options));
TF_CHECK_OK(session->Create(graph_def));
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName1, {kEnqueueOp1}, kCloseOp1, kCancelOp1, {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
// This will timeout since queue0 is not fed and queue1 is fetching data from
// queue0.
EXPECT_EQ(qr->Start(session.get(), 1).code(), Code::DEADLINE_EXCEEDED);
TF_EXPECT_OK(session->Close());
}
TEST(QueueRunnerTest, TestCoordinatorStop) {
auto graph_def = BuildDoubleQueueGraph();
SessionOptions options;
std::unique_ptr<Session> session(NewSession(options));
TF_CHECK_OK(session->Create(graph_def));
QueueRunnerDef queue_runner0 =
BuildQueueRunnerDef(kQueueName0, {kEnqueueOp0}, kCloseOp0, kCancelOp0,
{Code::OUT_OF_RANGE, Code::CANCELLED});
QueueRunnerDef queue_runner1 =
BuildQueueRunnerDef(kQueueName1, {kEnqueueOp1}, kCloseOp1, kCancelOp1,
{Code::OUT_OF_RANGE, Code::CANCELLED});
Coordinator coord;
std::unique_ptr<QueueRunner> qr0;
TF_EXPECT_OK(QueueRunner::New(queue_runner0, &coord, &qr0));
TF_CHECK_OK(qr0->Start(session.get()));
std::unique_ptr<QueueRunner> qr1;
TF_EXPECT_OK(QueueRunner::New(queue_runner1, &coord, &qr1));
TF_CHECK_OK(qr1->Start(session.get()));
TF_EXPECT_OK(coord.RegisterRunner(std::move(qr0)));
TF_EXPECT_OK(coord.RegisterRunner(std::move(qr1)));
std::vector<Tensor> dq;
TF_EXPECT_OK(session->Run({}, {kDequeueOp1}, {}, &dq));
EXPECT_EQ(*dq[0].scalar<int>().data(), 10);
TF_EXPECT_OK(coord.RequestStop());
TF_EXPECT_OK(coord.Join());
}
TEST(QueueRunnerTest, CallbackCalledOnError) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName, {kIllegalOpName1, kIllegalOpName2}, kCountUpToOpName, "", {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
bool error_caught = false;
qr->AddErrorCallback([&error_caught](const Status&) { error_caught = true; });
TF_EXPECT_OK(qr->Start(session.get()));
EXPECT_FALSE(qr->Join().ok());
EXPECT_TRUE(error_caught);
}
TEST(QueueRunnerTest, RunMetaDataTest) {
Scope root = Scope::NewRootScope();
auto q0 = FIFOQueue(root.WithOpName(kQueueName), {DataType::DT_FLOAT});
Output rnd = RandomNormal(root.WithOpName("rnd"), {1, 1}, DataType::DT_FLOAT);
Output square = Square(root.WithOpName(kSquareOpName), rnd);
auto enqueue0 = QueueEnqueue(root.WithOpName(kEnqueueOp0), q0, {square});
auto close0 = QueueClose(root.WithOpName(kCloseOp0), q0);
auto cancel0 = QueueClose(root.WithOpName(kCancelOp0), q0,
QueueClose::CancelPendingEnqueues(true));
auto dequeue0 =
QueueDequeue(root.WithOpName(kDequeueOp0), q0, {DataType::DT_FLOAT});
GraphDef graph_def;
TF_EXPECT_OK(root.ToGraphDef(&graph_def));
for (auto& node : *graph_def.mutable_node()) {
node.set_device("/cpu:0");
}
SessionOptions sess_options;
sess_options.config.mutable_graph_options()->set_build_cost_model(1);
std::unique_ptr<Session> session(NewSession(sess_options));
TF_CHECK_OK(session->Create(graph_def));
QueueRunnerDef queue_runner_def =
BuildQueueRunnerDef(kQueueName, {kEnqueueOp0}, kCloseOp0, kCancelOp0, {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
RunOptions run_options;
TF_CHECK_OK(qr->StartAndCollectCostGraph(session.get(), run_options));
// Make sure there was at least one element enqueued in q0: this prevents a
// race condition where we close the queue before it was populated.
std::vector<Tensor> dq0;
TF_EXPECT_OK(session->Run({}, {kDequeueOp0}, {}, &dq0));
// Second call to run dequeue op is to make sure the cost graph has been
// stored.
TF_EXPECT_OK(session->Run({}, {kDequeueOp0}, {}, &dq0));
CostGraphDef cost_graph;
TF_CHECK_OK(qr->ExportCostGraph(&cost_graph));
EXPECT_TRUE(cost_graph.node_size() > 0);
qr->Stop(session.get());
}
TEST(QueueRunnerTest, NoRunMetaDataTest) {
GraphDef graph_def = BuildSimpleGraph();
auto session = BuildSessionAndInitVariable(graph_def);
QueueRunnerDef queue_runner_def = BuildQueueRunnerDef(
kQueueName, {kCountUpToOpName}, kSquareOpName, "", {});
std::unique_ptr<QueueRunner> qr;
TF_EXPECT_OK(QueueRunner::New(queue_runner_def, &qr));
TF_CHECK_OK(qr->Start(session.get()));
TF_EXPECT_OK(qr->Join());
CostGraphDef cost_graph;
EXPECT_EQ(qr->ExportCostGraph(&cost_graph).code(),
error::FAILED_PRECONDITION);
}
} // namespace
} // namespace tensorflow
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