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chromium / chromium / src / 749dbc028fba2cd10796a1a1ef338ec9ce2accff / . / net / proxy_resolution / multi_threaded_proxy_resolver_unittest.cc
blob: 41930536828761ee64cc3fd6586028357d28e1a7 [file] [log] [blame]
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/proxy_resolution/multi_threaded_proxy_resolver.h"
#include <utility>
#include <vector>
#include "base/bind.h"
#include "base/run_loop.h"
#include "base/stl_util.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/strings/utf_string_conversions.h"
#include "base/synchronization/condition_variable.h"
#include "base/synchronization/lock.h"
#include "base/threading/platform_thread.h"
#include "base/threading/thread_checker_impl.h"
#include "net/base/net_errors.h"
#include "net/base/network_isolation_key.h"
#include "net/base/schemeful_site.h"
#include "net/base/test_completion_callback.h"
#include "net/log/net_log_event_type.h"
#include "net/log/net_log_with_source.h"
#include "net/log/test_net_log.h"
#include "net/log/test_net_log_util.h"
#include "net/proxy_resolution/mock_proxy_resolver.h"
#include "net/proxy_resolution/proxy_info.h"
#include "net/proxy_resolution/proxy_resolver_factory.h"
#include "net/test/gtest_util.h"
#include "net/test/test_with_task_environment.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "url/gurl.h"
using net::test::IsError;
using net::test::IsOk;
using base::ASCIIToUTF16;
namespace net {
namespace {
// A synchronous mock ProxyResolver implementation, which can be used in
// conjunction with MultiThreadedProxyResolver.
// - returns a single-item proxy list with the query's host.
class MockProxyResolver : public ProxyResolver {
public:
MockProxyResolver() = default;
// ProxyResolver implementation.
int GetProxyForURL(const GURL& query_url,
const NetworkIsolationKey& network_isolation_key,
ProxyInfo* results,
CompletionOnceCallback callback,
std::unique_ptr<Request>* request,
const NetLogWithSource& net_log) override {
last_query_url_ = query_url;
last_network_isolation_key_ = network_isolation_key;
if (!resolve_latency_.is_zero())
base::PlatformThread::Sleep(resolve_latency_);
EXPECT_TRUE(worker_thread_checker_.CalledOnValidThread());
EXPECT_TRUE(callback.is_null());
EXPECT_TRUE(request == nullptr);
// Write something into |net_log| (doesn't really have any meaning.)
net_log.BeginEvent(NetLogEventType::PAC_JAVASCRIPT_ALERT);
results->UseNamedProxy(query_url.host());
// Return a success code which represents the request's order.
return request_count_++;
}
int request_count() const { return request_count_; }
void SetResolveLatency(base::TimeDelta latency) {
resolve_latency_ = latency;
}
// Return the most recent values passed to GetProxyForURL(), if any.
const GURL& last_query_url() const { return last_query_url_; }
const NetworkIsolationKey& last_network_isolation_key() const {
return last_network_isolation_key_;
}
private:
base::ThreadCheckerImpl worker_thread_checker_;
int request_count_ = 0;
base::TimeDelta resolve_latency_;
GURL last_query_url_;
NetworkIsolationKey last_network_isolation_key_;
};
// A mock synchronous ProxyResolver which can be set to block upon reaching
// GetProxyForURL().
class BlockableProxyResolver : public MockProxyResolver {
public:
enum class State {
NONE,
BLOCKED,
WILL_BLOCK,
};
BlockableProxyResolver() : state_(State::NONE), condition_(&lock_) {}
~BlockableProxyResolver() override {
base::AutoLock lock(lock_);
EXPECT_NE(State::BLOCKED, state_);
}
// Causes the next call into GetProxyForURL() to block. Must be followed by
// a call to Unblock().
void Block() {
base::AutoLock lock(lock_);
EXPECT_EQ(State::NONE, state_);
state_ = State::WILL_BLOCK;
condition_.Broadcast();
}
// Unblocks the ProxyResolver. The ProxyResolver must already be in a
// blocked state prior to calling.
void Unblock() {
base::AutoLock lock(lock_);
EXPECT_EQ(State::BLOCKED, state_);
state_ = State::NONE;
condition_.Broadcast();
}
// Waits until the proxy resolver is blocked within GetProxyForURL().
void WaitUntilBlocked() {
base::AutoLock lock(lock_);
while (state_ != State::BLOCKED)
condition_.Wait();
}
int GetProxyForURL(const GURL& query_url,
const NetworkIsolationKey& network_isolation_key,
ProxyInfo* results,
CompletionOnceCallback callback,
std::unique_ptr<Request>* request,
const NetLogWithSource& net_log) override {
{
base::AutoLock lock(lock_);
EXPECT_NE(State::BLOCKED, state_);
if (state_ == State::WILL_BLOCK) {
state_ = State::BLOCKED;
condition_.Broadcast();
while (state_ == State::BLOCKED)
condition_.Wait();
}
}
return MockProxyResolver::GetProxyForURL(query_url, network_isolation_key,
results, std::move(callback),
request, net_log);
}
private:
State state_;
base::Lock lock_;
base::ConditionVariable condition_;
DISALLOW_COPY_AND_ASSIGN(BlockableProxyResolver);
};
// This factory returns new instances of BlockableProxyResolver.
class BlockableProxyResolverFactory : public ProxyResolverFactory {
public:
BlockableProxyResolverFactory() : ProxyResolverFactory(false) {}
~BlockableProxyResolverFactory() override = default;
int CreateProxyResolver(const scoped_refptr<PacFileData>& script_data,
std::unique_ptr<ProxyResolver>* result,
CompletionOnceCallback callback,
std::unique_ptr<Request>* request) override {
BlockableProxyResolver* resolver = new BlockableProxyResolver;
result->reset(resolver);
base::AutoLock lock(lock_);
resolvers_.push_back(resolver);
script_data_.push_back(script_data);
return OK;
}
std::vector<BlockableProxyResolver*> resolvers() {
base::AutoLock lock(lock_);
return resolvers_;
}
const std::vector<scoped_refptr<PacFileData>> script_data() {
base::AutoLock lock(lock_);
return script_data_;
}
private:
std::vector<BlockableProxyResolver*> resolvers_;
std::vector<scoped_refptr<PacFileData>> script_data_;
base::Lock lock_;
};
class SingleShotMultiThreadedProxyResolverFactory
: public MultiThreadedProxyResolverFactory {
public:
SingleShotMultiThreadedProxyResolverFactory(
size_t max_num_threads,
std::unique_ptr<ProxyResolverFactory> factory)
: MultiThreadedProxyResolverFactory(max_num_threads, false),
factory_(std::move(factory)) {}
std::unique_ptr<ProxyResolverFactory> CreateProxyResolverFactory() override {
DCHECK(factory_);
return std::move(factory_);
}
private:
std::unique_ptr<ProxyResolverFactory> factory_;
};
class MultiThreadedProxyResolverTest : public TestWithTaskEnvironment {
public:
void Init(size_t num_threads) {
std::unique_ptr<BlockableProxyResolverFactory> factory_owner(
new BlockableProxyResolverFactory);
factory_ = factory_owner.get();
resolver_factory_.reset(new SingleShotMultiThreadedProxyResolverFactory(
num_threads, std::move(factory_owner)));
TestCompletionCallback ready_callback;
std::unique_ptr<ProxyResolverFactory::Request> request;
resolver_factory_->CreateProxyResolver(
PacFileData::FromUTF8("pac script bytes"), &resolver_,
ready_callback.callback(), &request);
EXPECT_TRUE(request);
ASSERT_THAT(ready_callback.WaitForResult(), IsOk());
// Verify that the script data reaches the synchronous resolver factory.
ASSERT_EQ(1u, factory_->script_data().size());
EXPECT_EQ(ASCIIToUTF16("pac script bytes"),
factory_->script_data()[0]->utf16());
}
void ClearResolver() { resolver_.reset(); }
BlockableProxyResolverFactory& factory() {
DCHECK(factory_);
return *factory_;
}
ProxyResolver& resolver() {
DCHECK(resolver_);
return *resolver_;
}
private:
BlockableProxyResolverFactory* factory_ = nullptr;
std::unique_ptr<ProxyResolverFactory> factory_owner_;
std::unique_ptr<MultiThreadedProxyResolverFactory> resolver_factory_;
std::unique_ptr<ProxyResolver> resolver_;
};
TEST_F(MultiThreadedProxyResolverTest, SingleThread_Basic) {
const size_t kNumThreads = 1u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
// Start request 0.
int rv;
TestCompletionCallback callback0;
RecordingBoundTestNetLog log0;
ProxyInfo results0;
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results0, callback0.callback(), nullptr,
log0.bound());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait for request 0 to finish.
rv = callback0.WaitForResult();
EXPECT_EQ(0, rv);
EXPECT_EQ("PROXY request0:80", results0.ToPacString());
// The mock proxy resolver should have written 1 log entry. And
// on completion, this should have been copied into |log0|.
// We also have 1 log entry that was emitted by the
// MultiThreadedProxyResolver.
auto entries0 = log0.GetEntries();
ASSERT_EQ(2u, entries0.size());
EXPECT_EQ(NetLogEventType::SUBMITTED_TO_RESOLVER_THREAD, entries0[0].type);
// Start 3 more requests (request1 to request3).
TestCompletionCallback callback1;
ProxyInfo results1;
rv = resolver().GetProxyForURL(GURL("http://request1"), NetworkIsolationKey(),
&results1, callback1.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
TestCompletionCallback callback2;
ProxyInfo results2;
rv = resolver().GetProxyForURL(GURL("http://request2"), NetworkIsolationKey(),
&results2, callback2.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
TestCompletionCallback callback3;
ProxyInfo results3;
rv = resolver().GetProxyForURL(GURL("http://request3"), NetworkIsolationKey(),
&results3, callback3.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait for the requests to finish (they must finish in the order they were
// started, which is what we check for from their magic return value)
rv = callback1.WaitForResult();
EXPECT_EQ(1, rv);
EXPECT_EQ("PROXY request1:80", results1.ToPacString());
rv = callback2.WaitForResult();
EXPECT_EQ(2, rv);
EXPECT_EQ("PROXY request2:80", results2.ToPacString());
rv = callback3.WaitForResult();
EXPECT_EQ(3, rv);
EXPECT_EQ("PROXY request3:80", results3.ToPacString());
}
// Tests that the NetLog is updated to include the time the request was waiting
// to be scheduled to a thread.
TEST_F(MultiThreadedProxyResolverTest,
SingleThread_UpdatesNetLogWithThreadWait) {
const size_t kNumThreads = 1u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
int rv;
// Block the proxy resolver, so no request can complete.
factory().resolvers()[0]->Block();
// Start request 0.
std::unique_ptr<ProxyResolver::Request> request0;
TestCompletionCallback callback0;
ProxyInfo results0;
RecordingBoundTestNetLog log0;
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results0, callback0.callback(), &request0,
log0.bound());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Start 2 more requests (request1 and request2).
TestCompletionCallback callback1;
ProxyInfo results1;
RecordingBoundTestNetLog log1;
rv = resolver().GetProxyForURL(GURL("http://request1"), NetworkIsolationKey(),
&results1, callback1.callback(), nullptr,
log1.bound());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
std::unique_ptr<ProxyResolver::Request> request2;
TestCompletionCallback callback2;
ProxyInfo results2;
RecordingBoundTestNetLog log2;
rv = resolver().GetProxyForURL(GURL("http://request2"), NetworkIsolationKey(),
&results2, callback2.callback(), &request2,
log2.bound());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Unblock the worker thread so the requests can continue running.
factory().resolvers()[0]->WaitUntilBlocked();
factory().resolvers()[0]->Unblock();
// Check that request 0 completed as expected.
// The NetLog has 1 entry that came from the MultiThreadedProxyResolver, and
// 1 entry from the mock proxy resolver.
EXPECT_EQ(0, callback0.WaitForResult());
EXPECT_EQ("PROXY request0:80", results0.ToPacString());
auto entries0 = log0.GetEntries();
ASSERT_EQ(2u, entries0.size());
EXPECT_EQ(NetLogEventType::SUBMITTED_TO_RESOLVER_THREAD, entries0[0].type);
// Check that request 1 completed as expected.
EXPECT_EQ(1, callback1.WaitForResult());
EXPECT_EQ("PROXY request1:80", results1.ToPacString());
auto entries1 = log1.GetEntries();
ASSERT_EQ(4u, entries1.size());
EXPECT_TRUE(LogContainsBeginEvent(
entries1, 0, NetLogEventType::WAITING_FOR_PROXY_RESOLVER_THREAD));
EXPECT_TRUE(LogContainsEndEvent(
entries1, 1, NetLogEventType::WAITING_FOR_PROXY_RESOLVER_THREAD));
// Check that request 2 completed as expected.
EXPECT_EQ(2, callback2.WaitForResult());
EXPECT_EQ("PROXY request2:80", results2.ToPacString());
auto entries2 = log2.GetEntries();
ASSERT_EQ(4u, entries2.size());
EXPECT_TRUE(LogContainsBeginEvent(
entries2, 0, NetLogEventType::WAITING_FOR_PROXY_RESOLVER_THREAD));
EXPECT_TRUE(LogContainsEndEvent(
entries2, 1, NetLogEventType::WAITING_FOR_PROXY_RESOLVER_THREAD));
}
// Cancel a request which is in progress, and then cancel a request which
// is pending.
TEST_F(MultiThreadedProxyResolverTest, SingleThread_CancelRequest) {
const size_t kNumThreads = 1u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
int rv;
// Block the proxy resolver, so no request can complete.
factory().resolvers()[0]->Block();
// Start request 0.
std::unique_ptr<ProxyResolver::Request> request0;
TestCompletionCallback callback0;
ProxyInfo results0;
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results0, callback0.callback(), &request0,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait until requests 0 reaches the worker thread.
factory().resolvers()[0]->WaitUntilBlocked();
// Start 3 more requests (request1 : request3).
TestCompletionCallback callback1;
ProxyInfo results1;
rv = resolver().GetProxyForURL(GURL("http://request1"), NetworkIsolationKey(),
&results1, callback1.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
std::unique_ptr<ProxyResolver::Request> request2;
TestCompletionCallback callback2;
ProxyInfo results2;
rv = resolver().GetProxyForURL(GURL("http://request2"), NetworkIsolationKey(),
&results2, callback2.callback(), &request2,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
TestCompletionCallback callback3;
ProxyInfo results3;
rv = resolver().GetProxyForURL(GURL("http://request3"), NetworkIsolationKey(),
&results3, callback3.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Cancel request0 (inprogress) and request2 (pending).
request0.reset();
request2.reset();
// Unblock the worker thread so the requests can continue running.
factory().resolvers()[0]->Unblock();
// Wait for requests 1 and 3 to finish.
rv = callback1.WaitForResult();
EXPECT_EQ(1, rv);
EXPECT_EQ("PROXY request1:80", results1.ToPacString());
rv = callback3.WaitForResult();
// Note that since request2 was cancelled before reaching the resolver,
// the request count is 2 and not 3 here.
EXPECT_EQ(2, rv);
EXPECT_EQ("PROXY request3:80", results3.ToPacString());
// Requests 0 and 2 which were cancelled, hence their completion callbacks
// were never summoned.
EXPECT_FALSE(callback0.have_result());
EXPECT_FALSE(callback2.have_result());
}
// Make sure the NetworkIsolationKey makes it to the resolver.
TEST_F(MultiThreadedProxyResolverTest, SingleThread_WithNetworkIsolationKey) {
const SchemefulSite kSite(GURL("https://origin.test/"));
const net::NetworkIsolationKey kNetworkIsolationKey(kSite, kSite);
const GURL kUrl("https://url.test/");
const size_t kNumThreads = 1u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
int rv;
// Block the proxy resolver, so no request can complete.
factory().resolvers()[0]->Block();
// Start request.
std::unique_ptr<ProxyResolver::Request> request;
TestCompletionCallback callback;
ProxyInfo results;
rv = resolver().GetProxyForURL(kUrl, kNetworkIsolationKey, &results,
callback.callback(), &request,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait until request reaches the worker thread.
factory().resolvers()[0]->WaitUntilBlocked();
factory().resolvers()[0]->Unblock();
EXPECT_EQ(0, callback.WaitForResult());
EXPECT_EQ(kUrl, factory().resolvers()[0]->last_query_url());
EXPECT_EQ(kNetworkIsolationKey,
factory().resolvers()[0]->last_network_isolation_key());
}
// Test that deleting MultiThreadedProxyResolver while requests are
// outstanding cancels them (and doesn't leak anything).
TEST_F(MultiThreadedProxyResolverTest, SingleThread_CancelRequestByDeleting) {
const size_t kNumThreads = 1u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
ASSERT_EQ(1u, factory().resolvers().size());
// Block the proxy resolver, so no request can complete.
factory().resolvers()[0]->Block();
int rv;
// Start 3 requests.
TestCompletionCallback callback0;
ProxyInfo results0;
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results0, callback0.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
TestCompletionCallback callback1;
ProxyInfo results1;
rv = resolver().GetProxyForURL(GURL("http://request1"), NetworkIsolationKey(),
&results1, callback1.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
TestCompletionCallback callback2;
ProxyInfo results2;
rv = resolver().GetProxyForURL(GURL("http://request2"), NetworkIsolationKey(),
&results2, callback2.callback(), nullptr,
NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait until request 0 reaches the worker thread.
factory().resolvers()[0]->WaitUntilBlocked();
// Add some latency, to improve the chance that when
// MultiThreadedProxyResolver is deleted below we are still running inside
// of the worker thread. The test will pass regardless, so this race doesn't
// cause flakiness. However the destruction during execution is a more
// interesting case to test.
factory().resolvers()[0]->SetResolveLatency(
base::TimeDelta::FromMilliseconds(100));
// Unblock the worker thread and delete the underlying
// MultiThreadedProxyResolver immediately.
factory().resolvers()[0]->Unblock();
ClearResolver();
// Give any posted tasks a chance to run (in case there is badness).
base::RunLoop().RunUntilIdle();
// Check that none of the outstanding requests were completed.
EXPECT_FALSE(callback0.have_result());
EXPECT_FALSE(callback1.have_result());
EXPECT_FALSE(callback2.have_result());
}
// Tests setting the PAC script once, lazily creating new threads, and
// cancelling requests.
TEST_F(MultiThreadedProxyResolverTest, ThreeThreads_Basic) {
const size_t kNumThreads = 3u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
// Verify that it reaches the synchronous resolver.
// One thread has been provisioned (i.e. one ProxyResolver was created).
ASSERT_EQ(1u, factory().resolvers().size());
const int kNumRequests = 8;
int rv;
TestCompletionCallback callback[kNumRequests];
ProxyInfo results[kNumRequests];
std::unique_ptr<ProxyResolver::Request> request[kNumRequests];
// Start request 0 -- this should run on thread 0 as there is nothing else
// going on right now.
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results[0], callback[0].callback(),
&request[0], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
// Wait for request 0 to finish.
rv = callback[0].WaitForResult();
EXPECT_EQ(0, rv);
EXPECT_EQ("PROXY request0:80", results[0].ToPacString());
ASSERT_EQ(1u, factory().resolvers().size());
EXPECT_EQ(1, factory().resolvers()[0]->request_count());
base::RunLoop().RunUntilIdle();
// We now block the first resolver to ensure a request is sent to the second
// thread.
factory().resolvers()[0]->Block();
rv = resolver().GetProxyForURL(GURL("http://request1"), NetworkIsolationKey(),
&results[1], callback[1].callback(),
&request[1], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
factory().resolvers()[0]->WaitUntilBlocked();
rv = resolver().GetProxyForURL(GURL("http://request2"), NetworkIsolationKey(),
&results[2], callback[2].callback(),
&request[2], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
EXPECT_EQ(0, callback[2].WaitForResult());
ASSERT_EQ(2u, factory().resolvers().size());
// We now block the second resolver as well to ensure a request is sent to the
// third thread.
factory().resolvers()[1]->Block();
rv = resolver().GetProxyForURL(GURL("http://request3"), NetworkIsolationKey(),
&results[3], callback[3].callback(),
&request[3], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
factory().resolvers()[1]->WaitUntilBlocked();
rv = resolver().GetProxyForURL(GURL("http://request4"), NetworkIsolationKey(),
&results[4], callback[4].callback(),
&request[4], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
EXPECT_EQ(0, callback[4].WaitForResult());
// We should now have a total of 3 threads, each with its own ProxyResolver
// that will get initialized with the same data.
ASSERT_EQ(3u, factory().resolvers().size());
ASSERT_EQ(3u, factory().script_data().size());
for (int i = 0; i < 3; ++i) {
EXPECT_EQ(ASCIIToUTF16("pac script bytes"),
factory().script_data()[i]->utf16())
<< "i=" << i;
}
// Start and cancel two requests. Since the first two threads are still
// blocked, they'll both be serviced by the third thread. The first request
// will reach the resolver, but the second will still be queued when canceled.
// Start a third request so we can be sure the resolver has completed running
// the first request.
rv = resolver().GetProxyForURL(GURL("http://request5"), NetworkIsolationKey(),
&results[5], callback[5].callback(),
&request[5], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
rv = resolver().GetProxyForURL(GURL("http://request6"), NetworkIsolationKey(),
&results[6], callback[6].callback(),
&request[6], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
rv = resolver().GetProxyForURL(GURL("http://request7"), NetworkIsolationKey(),
&results[7], callback[7].callback(),
&request[7], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
request[5].reset();
request[6].reset();
EXPECT_EQ(2, callback[7].WaitForResult());
// Check that the cancelled requests never invoked their callback.
EXPECT_FALSE(callback[5].have_result());
EXPECT_FALSE(callback[6].have_result());
// Unblock the first two threads and wait for their requests to complete.
factory().resolvers()[0]->Unblock();
factory().resolvers()[1]->Unblock();
EXPECT_EQ(1, callback[1].WaitForResult());
EXPECT_EQ(1, callback[3].WaitForResult());
EXPECT_EQ(2, factory().resolvers()[0]->request_count());
EXPECT_EQ(2, factory().resolvers()[1]->request_count());
EXPECT_EQ(3, factory().resolvers()[2]->request_count());
}
// Tests using two threads. The first request hangs the first thread. Checks
// that other requests are able to complete while this first request remains
// stalled.
TEST_F(MultiThreadedProxyResolverTest, OneThreadBlocked) {
const size_t kNumThreads = 2u;
ASSERT_NO_FATAL_FAILURE(Init(kNumThreads));
int rv;
// One thread has been provisioned (i.e. one ProxyResolver was created).
ASSERT_EQ(1u, factory().resolvers().size());
EXPECT_EQ(ASCIIToUTF16("pac script bytes"),
factory().script_data()[0]->utf16());
const int kNumRequests = 4;
TestCompletionCallback callback[kNumRequests];
ProxyInfo results[kNumRequests];
std::unique_ptr<ProxyResolver::Request> request[kNumRequests];
// Start a request that will block the first thread.
factory().resolvers()[0]->Block();
rv = resolver().GetProxyForURL(GURL("http://request0"), NetworkIsolationKey(),
&results[0], callback[0].callback(),
&request[0], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
factory().resolvers()[0]->WaitUntilBlocked();
// Start 3 more requests -- they should all be serviced by thread #2
// since thread #1 is blocked.
for (int i = 1; i < kNumRequests; ++i) {
rv = resolver().GetProxyForURL(
GURL(base::StringPrintf("http://request%d", i)), NetworkIsolationKey(),
&results[i], callback[i].callback(), &request[i], NetLogWithSource());
EXPECT_THAT(rv, IsError(ERR_IO_PENDING));
}
// Wait for the three requests to complete (they should complete in FIFO
// order).
for (int i = 1; i < kNumRequests; ++i) {
EXPECT_EQ(i - 1, callback[i].WaitForResult());
}
// Unblock the first thread.
factory().resolvers()[0]->Unblock();
EXPECT_EQ(0, callback[0].WaitForResult());
// All in all, the first thread should have seen just 1 request. And the
// second thread 3 requests.
ASSERT_EQ(2u, factory().resolvers().size());
EXPECT_EQ(1, factory().resolvers()[0]->request_count());
EXPECT_EQ(3, factory().resolvers()[1]->request_count());
}
class FailingProxyResolverFactory : public ProxyResolverFactory {
public:
FailingProxyResolverFactory() : ProxyResolverFactory(false) {}
// ProxyResolverFactory override.
int CreateProxyResolver(const scoped_refptr<PacFileData>& script_data,
std::unique_ptr<ProxyResolver>* result,
CompletionOnceCallback callback,
std::unique_ptr<Request>* request) override {
return ERR_PAC_SCRIPT_FAILED;
}
};
// Test that an error when creating the synchronous resolver causes the
// MultiThreadedProxyResolverFactory create request to fail with that error.
TEST_F(MultiThreadedProxyResolverTest, ProxyResolverFactoryError) {
const size_t kNumThreads = 1u;
SingleShotMultiThreadedProxyResolverFactory resolver_factory(
kNumThreads, std::make_unique<FailingProxyResolverFactory>());
TestCompletionCallback ready_callback;
std::unique_ptr<ProxyResolverFactory::Request> request;
std::unique_ptr<ProxyResolver> resolver;
EXPECT_EQ(ERR_IO_PENDING,
resolver_factory.CreateProxyResolver(
PacFileData::FromUTF8("pac script bytes"), &resolver,
ready_callback.callback(), &request));
EXPECT_TRUE(request);
EXPECT_THAT(ready_callback.WaitForResult(), IsError(ERR_PAC_SCRIPT_FAILED));
EXPECT_FALSE(resolver);
}
void Fail(int error) {
FAIL() << "Unexpected callback with error " << error;
}
// Test that cancelling an in-progress create request works correctly.
TEST_F(MultiThreadedProxyResolverTest, CancelCreate) {
const size_t kNumThreads = 1u;
{
SingleShotMultiThreadedProxyResolverFactory resolver_factory(
kNumThreads, std::make_unique<BlockableProxyResolverFactory>());
std::unique_ptr<ProxyResolverFactory::Request> request;
std::unique_ptr<ProxyResolver> resolver;
EXPECT_EQ(ERR_IO_PENDING, resolver_factory.CreateProxyResolver(
PacFileData::FromUTF8("pac script bytes"),
&resolver, base::BindOnce(&Fail), &request));
EXPECT_TRUE(request);
request.reset();
}
// The factory destructor will block until the worker thread stops, but it may
// post tasks to the origin message loop which are still pending. Run them
// now to ensure it works as expected.
base::RunLoop().RunUntilIdle();
}
void DeleteRequest(CompletionOnceCallback callback,
std::unique_ptr<ProxyResolverFactory::Request>* request,
int result) {
std::move(callback).Run(result);
request->reset();
}
// Test that delete the Request during the factory callback works correctly.
TEST_F(MultiThreadedProxyResolverTest, DeleteRequestInFactoryCallback) {
const size_t kNumThreads = 1u;
SingleShotMultiThreadedProxyResolverFactory resolver_factory(
kNumThreads, std::make_unique<BlockableProxyResolverFactory>());
std::unique_ptr<ProxyResolverFactory::Request> request;
std::unique_ptr<ProxyResolver> resolver;
TestCompletionCallback callback;
EXPECT_EQ(ERR_IO_PENDING,
resolver_factory.CreateProxyResolver(
PacFileData::FromUTF8("pac script bytes"), &resolver,
base::BindOnce(&DeleteRequest, callback.callback(),
base::Unretained(&request)),
&request));
EXPECT_TRUE(request);
EXPECT_THAT(callback.WaitForResult(), IsOk());
}
// Test that deleting the factory with a request in-progress works correctly.
TEST_F(MultiThreadedProxyResolverTest, DestroyFactoryWithRequestsInProgress) {
const size_t kNumThreads = 1u;
std::unique_ptr<ProxyResolverFactory::Request> request;
std::unique_ptr<ProxyResolver> resolver;
{
SingleShotMultiThreadedProxyResolverFactory resolver_factory(
kNumThreads, std::make_unique<BlockableProxyResolverFactory>());
EXPECT_EQ(ERR_IO_PENDING, resolver_factory.CreateProxyResolver(
PacFileData::FromUTF8("pac script bytes"),
&resolver, base::BindOnce(&Fail), &request));
EXPECT_TRUE(request);
}
// The factory destructor will block until the worker thread stops, but it may
// post tasks to the origin message loop which are still pending. Run them
// now to ensure it works as expected.
base::RunLoop().RunUntilIdle();
}
} // namespace
} // namespace net