/*
* Copyright 2004 The WebRTC Project Authors. All rights reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include <signal.h>
#include <stdarg.h>
#include "webrtc/base/gunit.h"
#include "webrtc/base/logging.h"
#include "webrtc/base/physicalsocketserver.h"
#include "webrtc/base/scoped_ptr.h"
#include "webrtc/base/socket_unittest.h"
#include "webrtc/base/testutils.h"
#include "webrtc/base/thread.h"
namespace rtc {
class PhysicalSocketTest : public SocketTest {
};
TEST_F(PhysicalSocketTest, TestConnectIPv4) {
SocketTest::TestConnectIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectIPv6) {
SocketTest::TestConnectIPv6();
}
TEST_F(PhysicalSocketTest, TestConnectWithDnsLookupIPv4) {
SocketTest::TestConnectWithDnsLookupIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectWithDnsLookupIPv6) {
SocketTest::TestConnectWithDnsLookupIPv6();
}
TEST_F(PhysicalSocketTest, TestConnectFailIPv4) {
SocketTest::TestConnectFailIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectFailIPv6) {
SocketTest::TestConnectFailIPv6();
}
TEST_F(PhysicalSocketTest, TestConnectWithDnsLookupFailIPv4) {
SocketTest::TestConnectWithDnsLookupFailIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectWithDnsLookupFailIPv6) {
SocketTest::TestConnectWithDnsLookupFailIPv6();
}
TEST_F(PhysicalSocketTest, TestConnectWithClosedSocketIPv4) {
SocketTest::TestConnectWithClosedSocketIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectWithClosedSocketIPv6) {
SocketTest::TestConnectWithClosedSocketIPv6();
}
TEST_F(PhysicalSocketTest, TestConnectWhileNotClosedIPv4) {
SocketTest::TestConnectWhileNotClosedIPv4();
}
TEST_F(PhysicalSocketTest, TestConnectWhileNotClosedIPv6) {
SocketTest::TestConnectWhileNotClosedIPv6();
}
TEST_F(PhysicalSocketTest, TestServerCloseDuringConnectIPv4) {
SocketTest::TestServerCloseDuringConnectIPv4();
}
TEST_F(PhysicalSocketTest, TestServerCloseDuringConnectIPv6) {
SocketTest::TestServerCloseDuringConnectIPv6();
}
TEST_F(PhysicalSocketTest, TestClientCloseDuringConnectIPv4) {
SocketTest::TestClientCloseDuringConnectIPv4();
}
TEST_F(PhysicalSocketTest, TestClientCloseDuringConnectIPv6) {
SocketTest::TestClientCloseDuringConnectIPv6();
}
TEST_F(PhysicalSocketTest, TestServerCloseIPv4) {
SocketTest::TestServerCloseIPv4();
}
TEST_F(PhysicalSocketTest, TestServerCloseIPv6) {
SocketTest::TestServerCloseIPv6();
}
TEST_F(PhysicalSocketTest, TestCloseInClosedCallbackIPv4) {
SocketTest::TestCloseInClosedCallbackIPv4();
}
TEST_F(PhysicalSocketTest, TestCloseInClosedCallbackIPv6) {
SocketTest::TestCloseInClosedCallbackIPv6();
}
TEST_F(PhysicalSocketTest, TestSocketServerWaitIPv4) {
SocketTest::TestSocketServerWaitIPv4();
}
TEST_F(PhysicalSocketTest, TestSocketServerWaitIPv6) {
SocketTest::TestSocketServerWaitIPv6();
}
TEST_F(PhysicalSocketTest, TestTcpIPv4) {
SocketTest::TestTcpIPv4();
}
TEST_F(PhysicalSocketTest, TestTcpIPv6) {
SocketTest::TestTcpIPv6();
}
TEST_F(PhysicalSocketTest, TestUdpIPv4) {
SocketTest::TestUdpIPv4();
}
TEST_F(PhysicalSocketTest, TestUdpIPv6) {
SocketTest::TestUdpIPv6();
}
TEST_F(PhysicalSocketTest, TestUdpReadyToSendIPv4) {
SocketTest::TestUdpReadyToSendIPv4();
}
TEST_F(PhysicalSocketTest, TestUdpReadyToSendIPv6) {
SocketTest::TestUdpReadyToSendIPv6();
}
TEST_F(PhysicalSocketTest, TestGetSetOptionsIPv4) {
SocketTest::TestGetSetOptionsIPv4();
}
TEST_F(PhysicalSocketTest, TestGetSetOptionsIPv6) {
SocketTest::TestGetSetOptionsIPv6();
}
#if defined(WEBRTC_POSIX)
class PosixSignalDeliveryTest : public testing::Test {
public:
static void RecordSignal(int signum) {
signals_received_.push_back(signum);
signaled_thread_ = Thread::Current();
}
protected:
void SetUp() {
ss_.reset(new PhysicalSocketServer());
}
void TearDown() {
ss_.reset(NULL);
signals_received_.clear();
signaled_thread_ = NULL;
}
bool ExpectSignal(int signum) {
if (signals_received_.empty()) {
LOG(LS_ERROR) << "ExpectSignal(): No signal received";
return false;
}
if (signals_received_[0] != signum) {
LOG(LS_ERROR) << "ExpectSignal(): Received signal " <<
signals_received_[0] << ", expected " << signum;
return false;
}
signals_received_.erase(signals_received_.begin());
return true;
}
bool ExpectNone() {
bool ret = signals_received_.empty();
if (!ret) {
LOG(LS_ERROR) << "ExpectNone(): Received signal " << signals_received_[0]
<< ", expected none";
}
return ret;
}
static std::vector<int> signals_received_;
static Thread *signaled_thread_;
scoped_ptr<PhysicalSocketServer> ss_;
};
std::vector<int> PosixSignalDeliveryTest::signals_received_;
Thread *PosixSignalDeliveryTest::signaled_thread_ = NULL;
// Test receiving a synchronous signal while not in Wait() and then entering
// Wait() afterwards.
TEST_F(PosixSignalDeliveryTest, RaiseThenWait) {
ASSERT_TRUE(ss_->SetPosixSignalHandler(SIGTERM, &RecordSignal));
raise(SIGTERM);
EXPECT_TRUE(ss_->Wait(0, true));
EXPECT_TRUE(ExpectSignal(SIGTERM));
EXPECT_TRUE(ExpectNone());
}
// Test that we can handle getting tons of repeated signals and that we see all
// the different ones.
TEST_F(PosixSignalDeliveryTest, InsanelyManySignals) {
ss_->SetPosixSignalHandler(SIGTERM, &RecordSignal);
ss_->SetPosixSignalHandler(SIGINT, &RecordSignal);
for (int i = 0; i < 10000; ++i) {
raise(SIGTERM);
}
raise(SIGINT);
EXPECT_TRUE(ss_->Wait(0, true));
// Order will be lowest signal numbers first.
EXPECT_TRUE(ExpectSignal(SIGINT));
EXPECT_TRUE(ExpectSignal(SIGTERM));
EXPECT_TRUE(ExpectNone());
}
// Test that a signal during a Wait() call is detected.
TEST_F(PosixSignalDeliveryTest, SignalDuringWait) {
ss_->SetPosixSignalHandler(SIGALRM, &RecordSignal);
alarm(1);
EXPECT_TRUE(ss_->Wait(1500, true));
EXPECT_TRUE(ExpectSignal(SIGALRM));
EXPECT_TRUE(ExpectNone());
}
class RaiseSigTermRunnable : public Runnable {
void Run(Thread *thread) {
thread->socketserver()->Wait(1000, false);
// Allow SIGTERM. This will be the only thread with it not masked so it will
// be delivered to us.
sigset_t mask;
sigemptyset(&mask);
pthread_sigmask(SIG_SETMASK, &mask, NULL);
// Raise it.
raise(SIGTERM);
}
};
// Test that it works no matter what thread the kernel chooses to give the
// signal to (since it's not guaranteed to be the one that Wait() runs on).
TEST_F(PosixSignalDeliveryTest, SignalOnDifferentThread) {
ss_->SetPosixSignalHandler(SIGTERM, &RecordSignal);
// Mask out SIGTERM so that it can't be delivered to this thread.
sigset_t mask;
sigemptyset(&mask);
sigaddset(&mask, SIGTERM);
EXPECT_EQ(0, pthread_sigmask(SIG_SETMASK, &mask, NULL));
// Start a new thread that raises it. It will have to be delivered to that
// thread. Our implementation should safely handle it and dispatch
// RecordSignal() on this thread.
scoped_ptr<Thread> thread(new Thread());
scoped_ptr<RaiseSigTermRunnable> runnable(new RaiseSigTermRunnable());
thread->Start(runnable.get());
EXPECT_TRUE(ss_->Wait(1500, true));
EXPECT_TRUE(ExpectSignal(SIGTERM));
EXPECT_EQ(Thread::Current(), signaled_thread_);
EXPECT_TRUE(ExpectNone());
}
#endif
} // namespace rtc