webrtc/base/testclient.cc - src - Git at Google

 /*
  *  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 "webrtc/base/testclient.h"
 #include "webrtc/base/thread.h"
 #include "webrtc/base/timeutils.h"

 namespace rtc {

 // DESIGN: Each packet received is put it into a list of packets.
 //         Callers can retrieve received packets from any thread by calling
 //         NextPacket.

 TestClient::TestClient(AsyncPacketSocket* socket)
     : socket_(socket), ready_to_send_(false), prev_packet_timestamp_(-1) {
   packets_ = new std::vector<Packet*>();
   socket_->SignalReadPacket.connect(this, &TestClient::OnPacket);
   socket_->SignalReadyToSend.connect(this, &TestClient::OnReadyToSend);
 }

 TestClient::~TestClient() {
   delete socket_;
   for (unsigned i = 0; i < packets_->size(); i++)
     delete (*packets_)[i];
   delete packets_;
 }

 bool TestClient::CheckConnState(AsyncPacketSocket::State state) {
   // Wait for our timeout value until the socket reaches the desired state.
   int64_t end = TimeAfter(kTimeoutMs);
   while (socket_->GetState() != state && TimeUntil(end) > 0) {
     Thread::Current()->ProcessMessages(1);
   }
   return (socket_->GetState() == state);
 }

 int TestClient::Send(const char* buf, size_t size) {
   rtc::PacketOptions options;
   return socket_->Send(buf, size, options);
 }

 int TestClient::SendTo(const char* buf, size_t size,
                        const SocketAddress& dest) {
   rtc::PacketOptions options;
   return socket_->SendTo(buf, size, dest, options);
 }

 TestClient::Packet* TestClient::NextPacket(int timeout_ms) {
   // If no packets are currently available, we go into a get/dispatch loop for
   // at most timeout_ms.  If, during the loop, a packet arrives, then we can
   // stop early and return it.

   // Note that the case where no packet arrives is important.  We often want to
   // test that a packet does not arrive.

   // Note also that we only try to pump our current thread's message queue.
   // Pumping another thread's queue could lead to messages being dispatched from
   // the wrong thread to non-thread-safe objects.

   int64_t end = TimeAfter(timeout_ms);
   while (TimeUntil(end) > 0) {
     {
       CritScope cs(&crit_);
       if (packets_->size() != 0) {
         break;
       }
     }
     Thread::Current()->ProcessMessages(1);
   }

   // Return the first packet placed in the queue.
   Packet* packet = NULL;
   CritScope cs(&crit_);
   if (packets_->size() > 0) {
     packet = packets_->front();
     packets_->erase(packets_->begin());
   }

   return packet;
 }

 bool TestClient::CheckNextPacket(const char* buf, size_t size,
                                  SocketAddress* addr) {
   bool res = false;
   Packet* packet = NextPacket(kTimeoutMs);
   if (packet) {
     res = (packet->size == size && memcmp(packet->buf, buf, size) == 0 &&
            CheckTimestamp(packet->packet_time.timestamp));
     if (addr)
       *addr = packet->addr;
     delete packet;
   }
   return res;
 }

 bool TestClient::CheckTimestamp(int64_t packet_timestamp) {
   bool res = true;
   if (packet_timestamp == -1) {
     res = false;
   }
   if (prev_packet_timestamp_ != -1) {
     if (packet_timestamp < prev_packet_timestamp_) {
       res = false;
     }
   }
   prev_packet_timestamp_ = packet_timestamp;
   return res;
 }

 bool TestClient::CheckNoPacket() {
   bool res;
   Packet* packet = NextPacket(kNoPacketTimeoutMs);
   res = (packet == NULL);
   delete packet;
   return res;
 }

 int TestClient::GetError() {
   return socket_->GetError();
 }

 int TestClient::SetOption(Socket::Option opt, int value) {
   return socket_->SetOption(opt, value);
 }

 bool TestClient::ready_to_send() const {
   return ready_to_send_;
 }

 void TestClient::OnPacket(AsyncPacketSocket* socket, const char* buf,
                           size_t size, const SocketAddress& remote_addr,
                           const PacketTime& packet_time) {
   CritScope cs(&crit_);
   packets_->push_back(new Packet(remote_addr, buf, size, packet_time));
 }

 void TestClient::OnReadyToSend(AsyncPacketSocket* socket) {
   ready_to_send_ = true;
 }

 TestClient::Packet::Packet(const SocketAddress& a,
                            const char* b,
                            size_t s,
                            const PacketTime& packet_time)
     : addr(a), buf(0), size(s), packet_time(packet_time) {
   buf = new char[size];
   memcpy(buf, b, size);
 }

 TestClient::Packet::Packet(const Packet& p)
     : addr(p.addr), buf(0), size(p.size), packet_time(p.packet_time) {
   buf = new char[size];
   memcpy(buf, p.buf, size);
 }

 TestClient::Packet::~Packet() {
   delete[] buf;
 }

 }  // namespace rtc
	/*
	* 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 "webrtc/base/testclient.h"
	#include "webrtc/base/thread.h"
	#include "webrtc/base/timeutils.h"

	namespace rtc {

	// DESIGN: Each packet received is put it into a list of packets.
	// Callers can retrieve received packets from any thread by calling
	// NextPacket.

	TestClient::TestClient(AsyncPacketSocket* socket)
	: socket_(socket), ready_to_send_(false), prev_packet_timestamp_(-1) {
	packets_ = new std::vector<Packet*>();
	socket_->SignalReadPacket.connect(this, &TestClient::OnPacket);
	socket_->SignalReadyToSend.connect(this, &TestClient::OnReadyToSend);
	}

	TestClient::~TestClient() {
	delete socket_;
	for (unsigned i = 0; i < packets_->size(); i++)
	delete (*packets_)[i];
	delete packets_;
	}

	bool TestClient::CheckConnState(AsyncPacketSocket::State state) {
	// Wait for our timeout value until the socket reaches the desired state.
	int64_t end = TimeAfter(kTimeoutMs);
	while (socket_->GetState() != state && TimeUntil(end) > 0) {
	Thread::Current()->ProcessMessages(1);
	}
	return (socket_->GetState() == state);
	}

	int TestClient::Send(const char* buf, size_t size) {
	rtc::PacketOptions options;
	return socket_->Send(buf, size, options);
	}

	int TestClient::SendTo(const char* buf, size_t size,
	const SocketAddress& dest) {
	rtc::PacketOptions options;
	return socket_->SendTo(buf, size, dest, options);
	}

	TestClient::Packet* TestClient::NextPacket(int timeout_ms) {
	// If no packets are currently available, we go into a get/dispatch loop for
	// at most timeout_ms. If, during the loop, a packet arrives, then we can
	// stop early and return it.

	// Note that the case where no packet arrives is important. We often want to
	// test that a packet does not arrive.

	// Note also that we only try to pump our current thread's message queue.
	// Pumping another thread's queue could lead to messages being dispatched from
	// the wrong thread to non-thread-safe objects.

	int64_t end = TimeAfter(timeout_ms);
	while (TimeUntil(end) > 0) {
	{
	CritScope cs(&crit_);
	if (packets_->size() != 0) {
	break;
	}
	}
	Thread::Current()->ProcessMessages(1);
	}

	// Return the first packet placed in the queue.
	Packet* packet = NULL;
	CritScope cs(&crit_);
	if (packets_->size() > 0) {
	packet = packets_->front();
	packets_->erase(packets_->begin());
	}

	return packet;
	}

	bool TestClient::CheckNextPacket(const char* buf, size_t size,
	SocketAddress* addr) {
	bool res = false;
	Packet* packet = NextPacket(kTimeoutMs);
	if (packet) {
	res = (packet->size == size && memcmp(packet->buf, buf, size) == 0 &&
	CheckTimestamp(packet->packet_time.timestamp));
	if (addr)
	*addr = packet->addr;
	delete packet;
	}
	return res;
	}

	bool TestClient::CheckTimestamp(int64_t packet_timestamp) {
	bool res = true;
	if (packet_timestamp == -1) {
	res = false;
	}
	if (prev_packet_timestamp_ != -1) {
	if (packet_timestamp < prev_packet_timestamp_) {
	res = false;
	}
	}
	prev_packet_timestamp_ = packet_timestamp;
	return res;
	}

	bool TestClient::CheckNoPacket() {
	bool res;
	Packet* packet = NextPacket(kNoPacketTimeoutMs);
	res = (packet == NULL);
	delete packet;
	return res;
	}

	int TestClient::GetError() {
	return socket_->GetError();
	}

	int TestClient::SetOption(Socket::Option opt, int value) {
	return socket_->SetOption(opt, value);
	}

	bool TestClient::ready_to_send() const {
	return ready_to_send_;
	}

	void TestClient::OnPacket(AsyncPacketSocket* socket, const char* buf,
	size_t size, const SocketAddress& remote_addr,
	const PacketTime& packet_time) {
	CritScope cs(&crit_);
	packets_->push_back(new Packet(remote_addr, buf, size, packet_time));
	}

	void TestClient::OnReadyToSend(AsyncPacketSocket* socket) {
	ready_to_send_ = true;
	}

	TestClient::Packet::Packet(const SocketAddress& a,
	const char* b,
	size_t s,
	const PacketTime& packet_time)
	: addr(a), buf(0), size(s), packet_time(packet_time) {
	buf = new char[size];
	memcpy(buf, b, size);
	}

	TestClient::Packet::Packet(const Packet& p)
	: addr(p.addr), buf(0), size(p.size), packet_time(p.packet_time) {
	buf = new char[size];
	memcpy(buf, p.buf, size);
	}

	TestClient::Packet::~Packet() {
	delete[] buf;
	}

	} // namespace rtc