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1 /*
2  *  Copyright 2004 The WebRTC Project Authors. All rights reserved.
3  *
4  *  Use of this source code is governed by a BSD-style license
5  *  that can be found in the LICENSE file in the root of the source
6  *  tree. An additional intellectual property rights grant can be found
7  *  in the file PATENTS.  All contributing project authors may
8  *  be found in the AUTHORS file in the root of the source tree.
9  */
10 
11 #ifndef WEBRTC_BASE_TESTUTILS_H__
12 #define WEBRTC_BASE_TESTUTILS_H__
13 
14 // Utilities for testing rtc infrastructure in unittests
15 
16 #if defined(WEBRTC_LINUX) && !defined(WEBRTC_ANDROID)
17 #include <X11/Xlib.h>
18 #include <X11/extensions/Xrandr.h>
19 
20 // X defines a few macros that stomp on types that gunit.h uses.
21 #undef None
22 #undef Bool
23 #endif
24 
25 #include <algorithm>
26 #include <map>
27 #include <vector>
28 #include "webrtc/base/arraysize.h"
29 #include "webrtc/base/asyncsocket.h"
30 #include "webrtc/base/common.h"
31 #include "webrtc/base/gunit.h"
32 #include "webrtc/base/nethelpers.h"
33 #include "webrtc/base/pathutils.h"
34 #include "webrtc/base/stream.h"
35 #include "webrtc/base/stringencode.h"
36 #include "webrtc/base/stringutils.h"
37 #include "webrtc/base/thread.h"
38 
39 namespace testing {
40 
41 using namespace rtc;
42 
43 ///////////////////////////////////////////////////////////////////////////////
44 // StreamSink - Monitor asynchronously signalled events from StreamInterface
45 // or AsyncSocket (which should probably be a StreamInterface.
46 ///////////////////////////////////////////////////////////////////////////////
47 
48 // Note: Any event that is an error is treaded as SSE_ERROR instead of that
49 // event.
50 
51 enum StreamSinkEvent {
52   SSE_OPEN  = SE_OPEN,
53   SSE_READ  = SE_READ,
54   SSE_WRITE = SE_WRITE,
55   SSE_CLOSE = SE_CLOSE,
56   SSE_ERROR = 16
57 };
58 
59 class StreamSink : public sigslot::has_slots<> {
60  public:
Monitor(StreamInterface * stream)61   void Monitor(StreamInterface* stream) {
62    stream->SignalEvent.connect(this, &StreamSink::OnEvent);
63    events_.erase(stream);
64   }
Unmonitor(StreamInterface * stream)65   void Unmonitor(StreamInterface* stream) {
66    stream->SignalEvent.disconnect(this);
67    // In case you forgot to unmonitor a previous object with this address
68    events_.erase(stream);
69   }
70   bool Check(StreamInterface* stream, StreamSinkEvent event, bool reset = true) {
71     return DoCheck(stream, event, reset);
72   }
73   int Events(StreamInterface* stream, bool reset = true) {
74     return DoEvents(stream, reset);
75   }
76 
Monitor(AsyncSocket * socket)77   void Monitor(AsyncSocket* socket) {
78    socket->SignalConnectEvent.connect(this, &StreamSink::OnConnectEvent);
79    socket->SignalReadEvent.connect(this, &StreamSink::OnReadEvent);
80    socket->SignalWriteEvent.connect(this, &StreamSink::OnWriteEvent);
81    socket->SignalCloseEvent.connect(this, &StreamSink::OnCloseEvent);
82    // In case you forgot to unmonitor a previous object with this address
83    events_.erase(socket);
84   }
Unmonitor(AsyncSocket * socket)85   void Unmonitor(AsyncSocket* socket) {
86    socket->SignalConnectEvent.disconnect(this);
87    socket->SignalReadEvent.disconnect(this);
88    socket->SignalWriteEvent.disconnect(this);
89    socket->SignalCloseEvent.disconnect(this);
90    events_.erase(socket);
91   }
92   bool Check(AsyncSocket* socket, StreamSinkEvent event, bool reset = true) {
93     return DoCheck(socket, event, reset);
94   }
95   int Events(AsyncSocket* socket, bool reset = true) {
96     return DoEvents(socket, reset);
97   }
98 
99  private:
100   typedef std::map<void*,int> EventMap;
101 
OnEvent(StreamInterface * stream,int events,int error)102   void OnEvent(StreamInterface* stream, int events, int error) {
103     if (error) {
104       events = SSE_ERROR;
105     }
106     AddEvents(stream, events);
107   }
OnConnectEvent(AsyncSocket * socket)108   void OnConnectEvent(AsyncSocket* socket) {
109     AddEvents(socket, SSE_OPEN);
110   }
OnReadEvent(AsyncSocket * socket)111   void OnReadEvent(AsyncSocket* socket) {
112     AddEvents(socket, SSE_READ);
113   }
OnWriteEvent(AsyncSocket * socket)114   void OnWriteEvent(AsyncSocket* socket) {
115     AddEvents(socket, SSE_WRITE);
116   }
OnCloseEvent(AsyncSocket * socket,int error)117   void OnCloseEvent(AsyncSocket* socket, int error) {
118     AddEvents(socket, (0 == error) ? SSE_CLOSE : SSE_ERROR);
119   }
120 
AddEvents(void * obj,int events)121   void AddEvents(void* obj, int events) {
122     EventMap::iterator it = events_.find(obj);
123     if (events_.end() == it) {
124       events_.insert(EventMap::value_type(obj, events));
125     } else {
126       it->second |= events;
127     }
128   }
DoCheck(void * obj,StreamSinkEvent event,bool reset)129   bool DoCheck(void* obj, StreamSinkEvent event, bool reset) {
130     EventMap::iterator it = events_.find(obj);
131     if ((events_.end() == it) || (0 == (it->second & event))) {
132       return false;
133     }
134     if (reset) {
135       it->second &= ~event;
136     }
137     return true;
138   }
DoEvents(void * obj,bool reset)139   int DoEvents(void* obj, bool reset) {
140     EventMap::iterator it = events_.find(obj);
141     if (events_.end() == it)
142       return 0;
143     int events = it->second;
144     if (reset) {
145       it->second = 0;
146     }
147     return events;
148   }
149 
150   EventMap events_;
151 };
152 
153 ///////////////////////////////////////////////////////////////////////////////
154 // StreamSource - Implements stream interface and simulates asynchronous
155 // events on the stream, without a network.  Also buffers written data.
156 ///////////////////////////////////////////////////////////////////////////////
157 
158 class StreamSource : public StreamInterface {
159 public:
StreamSource()160   StreamSource() {
161     Clear();
162   }
163 
Clear()164   void Clear() {
165     readable_data_.clear();
166     written_data_.clear();
167     state_ = SS_CLOSED;
168     read_block_ = 0;
169     write_block_ = SIZE_UNKNOWN;
170   }
QueueString(const char * data)171   void QueueString(const char* data) {
172     QueueData(data, strlen(data));
173   }
QueueStringF(const char * format,...)174   void QueueStringF(const char* format, ...) {
175     va_list args;
176     va_start(args, format);
177     char buffer[1024];
178     size_t len = vsprintfn(buffer, sizeof(buffer), format, args);
179     ASSERT(len < sizeof(buffer) - 1);
180     va_end(args);
181     QueueData(buffer, len);
182   }
QueueData(const char * data,size_t len)183   void QueueData(const char* data, size_t len) {
184     readable_data_.insert(readable_data_.end(), data, data + len);
185     if ((SS_OPEN == state_) && (readable_data_.size() == len)) {
186       SignalEvent(this, SE_READ, 0);
187     }
188   }
ReadData()189   std::string ReadData() {
190     std::string data;
191     // avoid accessing written_data_[0] if it is undefined
192     if (written_data_.size() > 0) {
193       data.insert(0, &written_data_[0], written_data_.size());
194     }
195     written_data_.clear();
196     return data;
197   }
SetState(StreamState state)198   void SetState(StreamState state) {
199     int events = 0;
200     if ((SS_OPENING == state_) && (SS_OPEN == state)) {
201       events |= SE_OPEN;
202       if (!readable_data_.empty()) {
203         events |= SE_READ;
204       }
205     } else if ((SS_CLOSED != state_) && (SS_CLOSED == state)) {
206       events |= SE_CLOSE;
207     }
208     state_ = state;
209     if (events) {
210       SignalEvent(this, events, 0);
211     }
212   }
213   // Will cause Read to block when there are pos bytes in the read queue.
SetReadBlock(size_t pos)214   void SetReadBlock(size_t pos) { read_block_ = pos; }
215   // Will cause Write to block when there are pos bytes in the write queue.
SetWriteBlock(size_t pos)216   void SetWriteBlock(size_t pos) { write_block_ = pos; }
217 
GetState()218   virtual StreamState GetState() const { return state_; }
Read(void * buffer,size_t buffer_len,size_t * read,int * error)219   virtual StreamResult Read(void* buffer, size_t buffer_len,
220                             size_t* read, int* error) {
221     if (SS_CLOSED == state_) {
222       if (error) *error = -1;
223       return SR_ERROR;
224     }
225     if ((SS_OPENING == state_) || (readable_data_.size() <= read_block_)) {
226       return SR_BLOCK;
227     }
228     size_t count = std::min(buffer_len, readable_data_.size() - read_block_);
229     memcpy(buffer, &readable_data_[0], count);
230     size_t new_size = readable_data_.size() - count;
231     // Avoid undefined access beyond the last element of the vector.
232     // This only happens when new_size is 0.
233     if (count < readable_data_.size()) {
234       memmove(&readable_data_[0], &readable_data_[count], new_size);
235     }
236     readable_data_.resize(new_size);
237     if (read) *read = count;
238     return SR_SUCCESS;
239   }
Write(const void * data,size_t data_len,size_t * written,int * error)240   virtual StreamResult Write(const void* data, size_t data_len,
241                              size_t* written, int* error) {
242     if (SS_CLOSED == state_) {
243       if (error) *error = -1;
244       return SR_ERROR;
245     }
246     if (SS_OPENING == state_) {
247       return SR_BLOCK;
248     }
249     if (SIZE_UNKNOWN != write_block_) {
250       if (written_data_.size() >= write_block_) {
251         return SR_BLOCK;
252       }
253       if (data_len > (write_block_ - written_data_.size())) {
254         data_len = write_block_ - written_data_.size();
255       }
256     }
257     if (written) *written = data_len;
258     const char* cdata = static_cast<const char*>(data);
259     written_data_.insert(written_data_.end(), cdata, cdata + data_len);
260     return SR_SUCCESS;
261   }
Close()262   virtual void Close() { state_ = SS_CLOSED; }
263 
264 private:
265   typedef std::vector<char> Buffer;
266   Buffer readable_data_, written_data_;
267   StreamState state_;
268   size_t read_block_, write_block_;
269 };
270 
271 ///////////////////////////////////////////////////////////////////////////////
272 // SocketTestClient
273 // Creates a simulated client for testing.  Works on real and virtual networks.
274 ///////////////////////////////////////////////////////////////////////////////
275 
276 class SocketTestClient : public sigslot::has_slots<> {
277 public:
SocketTestClient()278   SocketTestClient() {
279     Init(NULL, AF_INET);
280   }
SocketTestClient(AsyncSocket * socket)281   SocketTestClient(AsyncSocket* socket) {
282     Init(socket, socket->GetLocalAddress().family());
283   }
SocketTestClient(const SocketAddress & address)284   SocketTestClient(const SocketAddress& address) {
285     Init(NULL, address.family());
286     socket_->Connect(address);
287   }
288 
socket()289   AsyncSocket* socket() { return socket_.get(); }
290 
QueueString(const char * data)291   void QueueString(const char* data) {
292     QueueData(data, strlen(data));
293   }
QueueStringF(const char * format,...)294   void QueueStringF(const char* format, ...) {
295     va_list args;
296     va_start(args, format);
297     char buffer[1024];
298     size_t len = vsprintfn(buffer, sizeof(buffer), format, args);
299     ASSERT(len < sizeof(buffer) - 1);
300     va_end(args);
301     QueueData(buffer, len);
302   }
QueueData(const char * data,size_t len)303   void QueueData(const char* data, size_t len) {
304     send_buffer_.insert(send_buffer_.end(), data, data + len);
305     if (Socket::CS_CONNECTED == socket_->GetState()) {
306       Flush();
307     }
308   }
ReadData()309   std::string ReadData() {
310     std::string data(&recv_buffer_[0], recv_buffer_.size());
311     recv_buffer_.clear();
312     return data;
313   }
314 
IsConnected()315   bool IsConnected() const {
316     return (Socket::CS_CONNECTED == socket_->GetState());
317   }
IsClosed()318   bool IsClosed() const {
319     return (Socket::CS_CLOSED == socket_->GetState());
320   }
321 
322 private:
323   typedef std::vector<char> Buffer;
324 
Init(AsyncSocket * socket,int family)325   void Init(AsyncSocket* socket, int family) {
326     if (!socket) {
327       socket = Thread::Current()->socketserver()
328           ->CreateAsyncSocket(family, SOCK_STREAM);
329     }
330     socket_.reset(socket);
331     socket_->SignalConnectEvent.connect(this,
332       &SocketTestClient::OnConnectEvent);
333     socket_->SignalReadEvent.connect(this, &SocketTestClient::OnReadEvent);
334     socket_->SignalWriteEvent.connect(this, &SocketTestClient::OnWriteEvent);
335     socket_->SignalCloseEvent.connect(this, &SocketTestClient::OnCloseEvent);
336   }
337 
Flush()338   void Flush() {
339     size_t sent = 0;
340     while (sent < send_buffer_.size()) {
341       int result = socket_->Send(&send_buffer_[sent],
342                                  send_buffer_.size() - sent);
343       if (result > 0) {
344         sent += result;
345       } else {
346         break;
347       }
348     }
349     size_t new_size = send_buffer_.size() - sent;
350     memmove(&send_buffer_[0], &send_buffer_[sent], new_size);
351     send_buffer_.resize(new_size);
352   }
353 
OnConnectEvent(AsyncSocket * socket)354   void OnConnectEvent(AsyncSocket* socket) {
355     if (!send_buffer_.empty()) {
356       Flush();
357     }
358   }
OnReadEvent(AsyncSocket * socket)359   void OnReadEvent(AsyncSocket* socket) {
360     char data[64 * 1024];
361     int result = socket_->Recv(data, arraysize(data));
362     if (result > 0) {
363       recv_buffer_.insert(recv_buffer_.end(), data, data + result);
364     }
365   }
OnWriteEvent(AsyncSocket * socket)366   void OnWriteEvent(AsyncSocket* socket) {
367     if (!send_buffer_.empty()) {
368       Flush();
369     }
370   }
OnCloseEvent(AsyncSocket * socket,int error)371   void OnCloseEvent(AsyncSocket* socket, int error) {
372   }
373 
374   scoped_ptr<AsyncSocket> socket_;
375   Buffer send_buffer_, recv_buffer_;
376 };
377 
378 ///////////////////////////////////////////////////////////////////////////////
379 // SocketTestServer
380 // Creates a simulated server for testing.  Works on real and virtual networks.
381 ///////////////////////////////////////////////////////////////////////////////
382 
383 class SocketTestServer : public sigslot::has_slots<> {
384  public:
SocketTestServer(const SocketAddress & address)385   SocketTestServer(const SocketAddress& address)
386       : socket_(Thread::Current()->socketserver()
387                 ->CreateAsyncSocket(address.family(), SOCK_STREAM))
388   {
389     socket_->SignalReadEvent.connect(this, &SocketTestServer::OnReadEvent);
390     socket_->Bind(address);
391     socket_->Listen(5);
392   }
~SocketTestServer()393   virtual ~SocketTestServer() {
394     clear();
395   }
396 
size()397   size_t size() const { return clients_.size(); }
client(size_t index)398   SocketTestClient* client(size_t index) const { return clients_[index]; }
399   SocketTestClient* operator[](size_t index) const { return client(index); }
400 
clear()401   void clear() {
402     for (size_t i=0; i<clients_.size(); ++i) {
403       delete clients_[i];
404     }
405     clients_.clear();
406   }
407 
408  private:
OnReadEvent(AsyncSocket * socket)409   void OnReadEvent(AsyncSocket* socket) {
410     AsyncSocket* accepted =
411       static_cast<AsyncSocket*>(socket_->Accept(NULL));
412     if (!accepted)
413       return;
414     clients_.push_back(new SocketTestClient(accepted));
415   }
416 
417   scoped_ptr<AsyncSocket> socket_;
418   std::vector<SocketTestClient*> clients_;
419 };
420 
421 ///////////////////////////////////////////////////////////////////////////////
422 // Generic Utilities
423 ///////////////////////////////////////////////////////////////////////////////
424 
ReadFile(const char * filename,std::string * contents)425 inline bool ReadFile(const char* filename, std::string* contents) {
426   FILE* fp = fopen(filename, "rb");
427   if (!fp)
428     return false;
429   char buffer[1024*64];
430   size_t read;
431   contents->clear();
432   while ((read = fread(buffer, 1, sizeof(buffer), fp))) {
433     contents->append(buffer, read);
434   }
435   bool success = (0 != feof(fp));
436   fclose(fp);
437   return success;
438 }
439 
440 // Look in parent dir for parallel directory.
GetSiblingDirectory(const std::string & parallel_dir)441 inline rtc::Pathname GetSiblingDirectory(
442     const std::string& parallel_dir) {
443   rtc::Pathname path = rtc::Filesystem::GetCurrentDirectory();
444   while (!path.empty()) {
445     rtc::Pathname potential_parallel_dir = path;
446     potential_parallel_dir.AppendFolder(parallel_dir);
447     if (rtc::Filesystem::IsFolder(potential_parallel_dir)) {
448       return potential_parallel_dir;
449     }
450 
451     path.SetFolder(path.parent_folder());
452   }
453   return path;
454 }
455 
GetGoogle3Directory()456 inline rtc::Pathname GetGoogle3Directory() {
457   return GetSiblingDirectory("google3");
458 }
459 
GetTalkDirectory()460 inline rtc::Pathname GetTalkDirectory() {
461   return GetSiblingDirectory("talk");
462 }
463 
464 ///////////////////////////////////////////////////////////////////////////////
465 // Unittest predicates which are similar to STREQ, but for raw memory
466 ///////////////////////////////////////////////////////////////////////////////
467 
CmpHelperMemEq(const char * expected_expression,const char * expected_length_expression,const char * actual_expression,const char * actual_length_expression,const void * expected,size_t expected_length,const void * actual,size_t actual_length)468 inline AssertionResult CmpHelperMemEq(const char* expected_expression,
469                                       const char* expected_length_expression,
470                                       const char* actual_expression,
471                                       const char* actual_length_expression,
472                                       const void* expected,
473                                       size_t expected_length,
474                                       const void* actual,
475                                       size_t actual_length)
476 {
477   if ((expected_length == actual_length)
478       && (0 == memcmp(expected, actual, expected_length))) {
479     return AssertionSuccess();
480   }
481 
482   Message msg;
483   msg << "Value of: " << actual_expression
484       << " [" << actual_length_expression << "]";
485   if (true) {  //!actual_value.Equals(actual_expression)) {
486     size_t buffer_size = actual_length * 2 + 1;
487     char* buffer = STACK_ARRAY(char, buffer_size);
488     hex_encode(buffer, buffer_size,
489                reinterpret_cast<const char*>(actual), actual_length);
490     msg << "\n  Actual: " << buffer << " [" << actual_length << "]";
491   }
492 
493   msg << "\nExpected: " << expected_expression
494       << " [" << expected_length_expression << "]";
495   if (true) {  //!expected_value.Equals(expected_expression)) {
496     size_t buffer_size = expected_length * 2 + 1;
497     char* buffer = STACK_ARRAY(char, buffer_size);
498     hex_encode(buffer, buffer_size,
499                reinterpret_cast<const char*>(expected), expected_length);
500     msg << "\nWhich is: " << buffer << " [" << expected_length << "]";
501   }
502 
503   return AssertionFailure(msg);
504 }
505 
CmpHelperFileEq(const char * expected_expression,const char * expected_length_expression,const char * actual_filename,const void * expected,size_t expected_length,const char * filename)506 inline AssertionResult CmpHelperFileEq(const char* expected_expression,
507                                        const char* expected_length_expression,
508                                        const char* actual_filename,
509                                        const void* expected,
510                                        size_t expected_length,
511                                        const char* filename)
512 {
513   std::string contents;
514   if (!ReadFile(filename, &contents)) {
515     Message msg;
516     msg << "File '" << filename << "' could not be read.";
517     return AssertionFailure(msg);
518   }
519   return CmpHelperMemEq(expected_expression, expected_length_expression,
520                         actual_filename, "",
521                         expected, expected_length,
522                         contents.c_str(), contents.size());
523 }
524 
525 #define EXPECT_MEMEQ(expected, expected_length, actual, actual_length) \
526   EXPECT_PRED_FORMAT4(::testing::CmpHelperMemEq, expected, expected_length, \
527                       actual, actual_length)
528 
529 #define ASSERT_MEMEQ(expected, expected_length, actual, actual_length) \
530   ASSERT_PRED_FORMAT4(::testing::CmpHelperMemEq, expected, expected_length, \
531                       actual, actual_length)
532 
533 #define EXPECT_FILEEQ(expected, expected_length, filename) \
534   EXPECT_PRED_FORMAT3(::testing::CmpHelperFileEq, expected, expected_length, \
535                       filename)
536 
537 #define ASSERT_FILEEQ(expected, expected_length, filename) \
538   ASSERT_PRED_FORMAT3(::testing::CmpHelperFileEq, expected, expected_length, \
539                       filename)
540 
541 ///////////////////////////////////////////////////////////////////////////////
542 // Helpers for initializing constant memory with integers in a particular byte
543 // order
544 ///////////////////////////////////////////////////////////////////////////////
545 
546 #define BYTE_CAST(x) static_cast<uint8_t>((x)&0xFF)
547 
548 // Declare a N-bit integer as a little-endian sequence of bytes
549 #define LE16(x) BYTE_CAST(((uint16_t)x) >> 0), BYTE_CAST(((uint16_t)x) >> 8)
550 
551 #define LE32(x) \
552   BYTE_CAST(((uint32_t)x) >> 0), BYTE_CAST(((uint32_t)x) >> 8), \
553       BYTE_CAST(((uint32_t)x) >> 16), BYTE_CAST(((uint32_t)x) >> 24)
554 
555 #define LE64(x) \
556   BYTE_CAST(((uint64_t)x) >> 0), BYTE_CAST(((uint64_t)x) >> 8),       \
557       BYTE_CAST(((uint64_t)x) >> 16), BYTE_CAST(((uint64_t)x) >> 24), \
558       BYTE_CAST(((uint64_t)x) >> 32), BYTE_CAST(((uint64_t)x) >> 40), \
559       BYTE_CAST(((uint64_t)x) >> 48), BYTE_CAST(((uint64_t)x) >> 56)
560 
561 // Declare a N-bit integer as a big-endian (Internet) sequence of bytes
562 #define BE16(x) BYTE_CAST(((uint16_t)x) >> 8), BYTE_CAST(((uint16_t)x) >> 0)
563 
564 #define BE32(x) \
565   BYTE_CAST(((uint32_t)x) >> 24), BYTE_CAST(((uint32_t)x) >> 16), \
566       BYTE_CAST(((uint32_t)x) >> 8), BYTE_CAST(((uint32_t)x) >> 0)
567 
568 #define BE64(x) \
569   BYTE_CAST(((uint64_t)x) >> 56), BYTE_CAST(((uint64_t)x) >> 48),     \
570       BYTE_CAST(((uint64_t)x) >> 40), BYTE_CAST(((uint64_t)x) >> 32), \
571       BYTE_CAST(((uint64_t)x) >> 24), BYTE_CAST(((uint64_t)x) >> 16), \
572       BYTE_CAST(((uint64_t)x) >> 8), BYTE_CAST(((uint64_t)x) >> 0)
573 
574 // Declare a N-bit integer as a this-endian (local machine) sequence of bytes
575 #ifndef BIG_ENDIAN
576 #define BIG_ENDIAN 1
577 #endif  // BIG_ENDIAN
578 
579 #if BIG_ENDIAN
580 #define TE16 BE16
581 #define TE32 BE32
582 #define TE64 BE64
583 #else  // !BIG_ENDIAN
584 #define TE16 LE16
585 #define TE32 LE32
586 #define TE64 LE64
587 #endif  // !BIG_ENDIAN
588 
589 ///////////////////////////////////////////////////////////////////////////////
590 
591 // Helpers for determining if X/screencasting is available (on linux).
592 
593 #define MAYBE_SKIP_SCREENCAST_TEST() \
594   if (!testing::IsScreencastingAvailable()) { \
595     LOG(LS_WARNING) << "Skipping test, since it doesn't have the requisite " \
596                     << "X environment for screen capture."; \
597     return; \
598   } \
599 
600 #if defined(WEBRTC_LINUX) && !defined(WEBRTC_ANDROID)
601 struct XDisplay {
XDisplayXDisplay602   XDisplay() : display_(XOpenDisplay(NULL)) { }
~XDisplayXDisplay603   ~XDisplay() { if (display_) XCloseDisplay(display_); }
IsValidXDisplay604   bool IsValid() const { return display_ != NULL; }
605   operator Display*() { return display_; }
606  private:
607   Display* display_;
608 };
609 #endif
610 
611 // Returns true if screencasting is available. When false, anything that uses
612 // screencasting features may fail.
IsScreencastingAvailable()613 inline bool IsScreencastingAvailable() {
614 #if defined(WEBRTC_LINUX) && !defined(WEBRTC_ANDROID)
615   XDisplay display;
616   if (!display.IsValid()) {
617     LOG(LS_WARNING) << "No X Display available.";
618     return false;
619   }
620   int ignored_int, major_version, minor_version;
621   if (!XRRQueryExtension(display, &ignored_int, &ignored_int) ||
622       !XRRQueryVersion(display, &major_version, &minor_version) ||
623       major_version < 1 ||
624       (major_version < 2 && minor_version < 3)) {
625     LOG(LS_WARNING) << "XRandr version: " << major_version << "."
626                     << minor_version;
627     LOG(LS_WARNING) << "XRandr is not supported or is too old (pre 1.3).";
628     return false;
629   }
630 #endif
631   return true;
632 }
633 }  // namespace testing
634 
635 #endif  // WEBRTC_BASE_TESTUTILS_H__
636