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Issue 1939683002: Test X11 header pollution (Closed) Base URL: https://chromium.googlesource.com/chromium/src.git@master
Patch Set: Created 4 years, 7 months ago
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1 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4
5 #include "content/common/gpu/media/dxva_video_decode_accelerator_win.h"
6
7 #include <memory>
8
9 #if !defined(OS_WIN)
10 #error This file should only be built on Windows.
11 #endif // !defined(OS_WIN)
12
13 #include <codecapi.h>
14 #include <dxgi1_2.h>
15 #include <ks.h>
16 #include <mfapi.h>
17 #include <mferror.h>
18 #include <ntverp.h>
19 #include <stddef.h>
20 #include <string.h>
21 #include <wmcodecdsp.h>
22
23 #include "base/base_paths_win.h"
24 #include "base/bind.h"
25 #include "base/callback.h"
26 #include "base/debug/alias.h"
27 #include "base/file_version_info.h"
28 #include "base/files/file_path.h"
29 #include "base/logging.h"
30 #include "base/macros.h"
31 #include "base/memory/shared_memory.h"
32 #include "base/message_loop/message_loop.h"
33 #include "base/path_service.h"
34 #include "base/trace_event/trace_event.h"
35 #include "base/win/windows_version.h"
36 #include "build/build_config.h"
37 #include "media/base/win/mf_initializer.h"
38 #include "media/video/video_decode_accelerator.h"
39 #include "third_party/angle/include/EGL/egl.h"
40 #include "third_party/angle/include/EGL/eglext.h"
41 #include "ui/gl/gl_bindings.h"
42 #include "ui/gl/gl_context.h"
43 #include "ui/gl/gl_fence.h"
44 #include "ui/gl/gl_surface_egl.h"
45
46 namespace {
47
48 // Path is appended on to the PROGRAM_FILES base path.
49 const wchar_t kVPXDecoderDLLPath[] = L"Intel\\Media SDK\\";
50
51 const wchar_t kVP8DecoderDLLName[] =
52 #if defined(ARCH_CPU_X86)
53 L"mfx_mft_vp8vd_32.dll";
54 #elif defined(ARCH_CPU_X86_64)
55 L"mfx_mft_vp8vd_64.dll";
56 #else
57 #error Unsupported Windows CPU Architecture
58 #endif
59
60 const wchar_t kVP9DecoderDLLName[] =
61 #if defined(ARCH_CPU_X86)
62 L"mfx_mft_vp9vd_32.dll";
63 #elif defined(ARCH_CPU_X86_64)
64 L"mfx_mft_vp9vd_64.dll";
65 #else
66 #error Unsupported Windows CPU Architecture
67 #endif
68
69 const CLSID CLSID_WebmMfVp8Dec = {
70 0x451e3cb7,
71 0x2622,
72 0x4ba5,
73 { 0x8e, 0x1d, 0x44, 0xb3, 0xc4, 0x1d, 0x09, 0x24 }
74 };
75
76 const CLSID CLSID_WebmMfVp9Dec = {
77 0x07ab4bd2,
78 0x1979,
79 0x4fcd,
80 { 0xa6, 0x97, 0xdf, 0x9a, 0xd1, 0x5b, 0x34, 0xfe }
81 };
82
83 const CLSID MEDIASUBTYPE_VP80 = {
84 0x30385056,
85 0x0000,
86 0x0010,
87 { 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71 }
88 };
89
90 const CLSID MEDIASUBTYPE_VP90 = {
91 0x30395056,
92 0x0000,
93 0x0010,
94 { 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71 }
95 };
96
97 // The CLSID of the video processor media foundation transform which we use for
98 // texture color conversion in DX11.
99 // Defined in mfidl.h in the Windows 10 SDK. ntverp.h provides VER_PRODUCTBUILD
100 // to detect which SDK we are compiling with.
101 #if VER_PRODUCTBUILD < 10011 // VER_PRODUCTBUILD for 10.0.10158.0 SDK.
102 DEFINE_GUID(CLSID_VideoProcessorMFT,
103 0x88753b26, 0x5b24, 0x49bd, 0xb2, 0xe7, 0xc, 0x44, 0x5c, 0x78,
104 0xc9, 0x82);
105 #endif
106
107 // MF_XVP_PLAYBACK_MODE
108 // Data type: UINT32 (treat as BOOL)
109 // If this attribute is TRUE, the video processor will run in playback mode
110 // where it allows callers to allocate output samples and allows last frame
111 // regeneration (repaint).
112 DEFINE_GUID(MF_XVP_PLAYBACK_MODE, 0x3c5d293f, 0xad67, 0x4e29, 0xaf, 0x12,
113 0xcf, 0x3e, 0x23, 0x8a, 0xcc, 0xe9);
114
115 // Defines the GUID for the Intel H264 DXVA device.
116 static const GUID DXVA2_Intel_ModeH264_E = {
117 0x604F8E68, 0x4951, 0x4c54,{ 0x88, 0xFE, 0xAB, 0xD2, 0x5C, 0x15, 0xB3, 0xD6}
118 };
119
120 // R600, R700, Evergreen and Cayman AMD cards. These support DXVA via UVD3
121 // or earlier, and don't handle resolutions higher than 1920 x 1088 well.
122 static const DWORD g_AMDUVD3GPUList[] = {
123 0x9400, 0x9401, 0x9402, 0x9403, 0x9405, 0x940a, 0x940b, 0x940f, 0x94c0,
124 0x94c1, 0x94c3, 0x94c4, 0x94c5, 0x94c6, 0x94c7, 0x94c8, 0x94c9, 0x94cb,
125 0x94cc, 0x94cd, 0x9580, 0x9581, 0x9583, 0x9586, 0x9587, 0x9588, 0x9589,
126 0x958a, 0x958b, 0x958c, 0x958d, 0x958e, 0x958f, 0x9500, 0x9501, 0x9504,
127 0x9505, 0x9506, 0x9507, 0x9508, 0x9509, 0x950f, 0x9511, 0x9515, 0x9517,
128 0x9519, 0x95c0, 0x95c2, 0x95c4, 0x95c5, 0x95c6, 0x95c7, 0x95c9, 0x95cc,
129 0x95cd, 0x95ce, 0x95cf, 0x9590, 0x9591, 0x9593, 0x9595, 0x9596, 0x9597,
130 0x9598, 0x9599, 0x959b, 0x9610, 0x9611, 0x9612, 0x9613, 0x9614, 0x9615,
131 0x9616, 0x9710, 0x9711, 0x9712, 0x9713, 0x9714, 0x9715, 0x9440, 0x9441,
132 0x9442, 0x9443, 0x9444, 0x9446, 0x944a, 0x944b, 0x944c, 0x944e, 0x9450,
133 0x9452, 0x9456, 0x945a, 0x945b, 0x945e, 0x9460, 0x9462, 0x946a, 0x946b,
134 0x947a, 0x947b, 0x9480, 0x9487, 0x9488, 0x9489, 0x948a, 0x948f, 0x9490,
135 0x9491, 0x9495, 0x9498, 0x949c, 0x949e, 0x949f, 0x9540, 0x9541, 0x9542,
136 0x954e, 0x954f, 0x9552, 0x9553, 0x9555, 0x9557, 0x955f, 0x94a0, 0x94a1,
137 0x94a3, 0x94b1, 0x94b3, 0x94b4, 0x94b5, 0x94b9, 0x68e0, 0x68e1, 0x68e4,
138 0x68e5, 0x68e8, 0x68e9, 0x68f1, 0x68f2, 0x68f8, 0x68f9, 0x68fa, 0x68fe,
139 0x68c0, 0x68c1, 0x68c7, 0x68c8, 0x68c9, 0x68d8, 0x68d9, 0x68da, 0x68de,
140 0x68a0, 0x68a1, 0x68a8, 0x68a9, 0x68b0, 0x68b8, 0x68b9, 0x68ba, 0x68be,
141 0x68bf, 0x6880, 0x6888, 0x6889, 0x688a, 0x688c, 0x688d, 0x6898, 0x6899,
142 0x689b, 0x689e, 0x689c, 0x689d, 0x9802, 0x9803, 0x9804, 0x9805, 0x9806,
143 0x9807, 0x9808, 0x9809, 0x980a, 0x9640, 0x9641, 0x9647, 0x9648, 0x964a,
144 0x964b, 0x964c, 0x964e, 0x964f, 0x9642, 0x9643, 0x9644, 0x9645, 0x9649,
145 0x6720, 0x6721, 0x6722, 0x6723, 0x6724, 0x6725, 0x6726, 0x6727, 0x6728,
146 0x6729, 0x6738, 0x6739, 0x673e, 0x6740, 0x6741, 0x6742, 0x6743, 0x6744,
147 0x6745, 0x6746, 0x6747, 0x6748, 0x6749, 0x674a, 0x6750, 0x6751, 0x6758,
148 0x6759, 0x675b, 0x675d, 0x675f, 0x6840, 0x6841, 0x6842, 0x6843, 0x6849,
149 0x6850, 0x6858, 0x6859, 0x6760, 0x6761, 0x6762, 0x6763, 0x6764, 0x6765,
150 0x6766, 0x6767, 0x6768, 0x6770, 0x6771, 0x6772, 0x6778, 0x6779, 0x677b,
151 0x6700, 0x6701, 0x6702, 0x6703, 0x6704, 0x6705, 0x6706, 0x6707, 0x6708,
152 0x6709, 0x6718, 0x6719, 0x671c, 0x671d, 0x671f, 0x683D, 0x9900, 0x9901,
153 0x9903, 0x9904, 0x9905, 0x9906, 0x9907, 0x9908, 0x9909, 0x990a, 0x990b,
154 0x990c, 0x990d, 0x990e, 0x990f, 0x9910, 0x9913, 0x9917, 0x9918, 0x9919,
155 0x9990, 0x9991, 0x9992, 0x9993, 0x9994, 0x9995, 0x9996, 0x9997, 0x9998,
156 0x9999, 0x999a, 0x999b, 0x999c, 0x999d, 0x99a0, 0x99a2, 0x99a4,
157 };
158
159 // Legacy Intel GPUs (Second generation) which have trouble with resolutions
160 // higher than 1920 x 1088
161 static const DWORD g_IntelLegacyGPUList[] = {
162 0x102, 0x106, 0x116, 0x126,
163 };
164
165 // Provides scoped access to the underlying buffer in an IMFMediaBuffer
166 // instance.
167 class MediaBufferScopedPointer {
168 public:
169 MediaBufferScopedPointer(IMFMediaBuffer* media_buffer)
170 : media_buffer_(media_buffer),
171 buffer_(nullptr),
172 max_length_(0),
173 current_length_(0) {
174 HRESULT hr = media_buffer_->Lock(&buffer_, &max_length_, &current_length_);
175 CHECK(SUCCEEDED(hr));
176 }
177
178 ~MediaBufferScopedPointer() {
179 HRESULT hr = media_buffer_->Unlock();
180 CHECK(SUCCEEDED(hr));
181 }
182
183 uint8_t* get() {
184 return buffer_;
185 }
186
187 DWORD current_length() const {
188 return current_length_;
189 }
190
191 private:
192 base::win::ScopedComPtr<IMFMediaBuffer> media_buffer_;
193 uint8_t* buffer_;
194 DWORD max_length_;
195 DWORD current_length_;
196
197 DISALLOW_COPY_AND_ASSIGN(MediaBufferScopedPointer);
198 };
199
200 } // namespace
201
202 namespace content {
203
204 static const media::VideoCodecProfile kSupportedProfiles[] = {
205 media::H264PROFILE_BASELINE,
206 media::H264PROFILE_MAIN,
207 media::H264PROFILE_HIGH,
208 media::VP8PROFILE_ANY,
209 media::VP9PROFILE_PROFILE0,
210 media::VP9PROFILE_PROFILE1,
211 media::VP9PROFILE_PROFILE2,
212 media::VP9PROFILE_PROFILE3
213 };
214
215 CreateDXGIDeviceManager DXVAVideoDecodeAccelerator::create_dxgi_device_manager_
216 = NULL;
217
218 #define RETURN_ON_FAILURE(result, log, ret) \
219 do { \
220 if (!(result)) { \
221 DLOG(ERROR) << log; \
222 return ret; \
223 } \
224 } while (0)
225
226 #define RETURN_ON_HR_FAILURE(result, log, ret) \
227 RETURN_ON_FAILURE(SUCCEEDED(result), \
228 log << ", HRESULT: 0x" << std::hex << result, \
229 ret);
230
231 #define RETURN_AND_NOTIFY_ON_FAILURE(result, log, error_code, ret) \
232 do { \
233 if (!(result)) { \
234 DVLOG(1) << log; \
235 StopOnError(error_code); \
236 return ret; \
237 } \
238 } while (0)
239
240 #define RETURN_AND_NOTIFY_ON_HR_FAILURE(result, log, error_code, ret) \
241 RETURN_AND_NOTIFY_ON_FAILURE(SUCCEEDED(result), \
242 log << ", HRESULT: 0x" << std::hex << result, \
243 error_code, ret);
244
245 enum {
246 // Maximum number of iterations we allow before aborting the attempt to flush
247 // the batched queries to the driver and allow torn/corrupt frames to be
248 // rendered.
249 kFlushDecoderSurfaceTimeoutMs = 1,
250 // Maximum iterations where we try to flush the d3d device.
251 kMaxIterationsForD3DFlush = 4,
252 // Maximum iterations where we try to flush the ANGLE device before reusing
253 // the texture.
254 kMaxIterationsForANGLEReuseFlush = 16,
255 // We only request 5 picture buffers from the client which are used to hold
256 // the decoded samples. These buffers are then reused when the client tells
257 // us that it is done with the buffer.
258 kNumPictureBuffers = 5,
259 // The keyed mutex should always be released before the other thread
260 // attempts to acquire it, so AcquireSync should always return immediately.
261 kAcquireSyncWaitMs = 0,
262 };
263
264 static IMFSample* CreateEmptySample() {
265 base::win::ScopedComPtr<IMFSample> sample;
266 HRESULT hr = MFCreateSample(sample.Receive());
267 RETURN_ON_HR_FAILURE(hr, "MFCreateSample failed", NULL);
268 return sample.Detach();
269 }
270
271 // Creates a Media Foundation sample with one buffer of length |buffer_length|
272 // on a |align|-byte boundary. Alignment must be a perfect power of 2 or 0.
273 static IMFSample* CreateEmptySampleWithBuffer(uint32_t buffer_length,
274 int align) {
275 CHECK_GT(buffer_length, 0U);
276
277 base::win::ScopedComPtr<IMFSample> sample;
278 sample.Attach(CreateEmptySample());
279
280 base::win::ScopedComPtr<IMFMediaBuffer> buffer;
281 HRESULT hr = E_FAIL;
282 if (align == 0) {
283 // Note that MFCreateMemoryBuffer is same as MFCreateAlignedMemoryBuffer
284 // with the align argument being 0.
285 hr = MFCreateMemoryBuffer(buffer_length, buffer.Receive());
286 } else {
287 hr = MFCreateAlignedMemoryBuffer(buffer_length,
288 align - 1,
289 buffer.Receive());
290 }
291 RETURN_ON_HR_FAILURE(hr, "Failed to create memory buffer for sample", NULL);
292
293 hr = sample->AddBuffer(buffer.get());
294 RETURN_ON_HR_FAILURE(hr, "Failed to add buffer to sample", NULL);
295
296 buffer->SetCurrentLength(0);
297 return sample.Detach();
298 }
299
300 // Creates a Media Foundation sample with one buffer containing a copy of the
301 // given Annex B stream data.
302 // If duration and sample time are not known, provide 0.
303 // |min_size| specifies the minimum size of the buffer (might be required by
304 // the decoder for input). If no alignment is required, provide 0.
305 static IMFSample* CreateInputSample(const uint8_t* stream,
306 uint32_t size,
307 uint32_t min_size,
308 int alignment) {
309 CHECK(stream);
310 CHECK_GT(size, 0U);
311 base::win::ScopedComPtr<IMFSample> sample;
312 sample.Attach(CreateEmptySampleWithBuffer(std::max(min_size, size),
313 alignment));
314 RETURN_ON_FAILURE(sample.get(), "Failed to create empty sample", NULL);
315
316 base::win::ScopedComPtr<IMFMediaBuffer> buffer;
317 HRESULT hr = sample->GetBufferByIndex(0, buffer.Receive());
318 RETURN_ON_HR_FAILURE(hr, "Failed to get buffer from sample", NULL);
319
320 DWORD max_length = 0;
321 DWORD current_length = 0;
322 uint8_t* destination = NULL;
323 hr = buffer->Lock(&destination, &max_length, &current_length);
324 RETURN_ON_HR_FAILURE(hr, "Failed to lock buffer", NULL);
325
326 CHECK_EQ(current_length, 0u);
327 CHECK_GE(max_length, size);
328 memcpy(destination, stream, size);
329
330 hr = buffer->SetCurrentLength(size);
331 RETURN_ON_HR_FAILURE(hr, "Failed to set buffer length", NULL);
332
333 hr = buffer->Unlock();
334 RETURN_ON_HR_FAILURE(hr, "Failed to unlock buffer", NULL);
335
336 return sample.Detach();
337 }
338
339 // Helper function to create a COM object instance from a DLL. The alternative
340 // is to use the CoCreateInstance API which requires the COM apartment to be
341 // initialized which is not the case on the GPU main thread. We want to avoid
342 // initializing COM as it may have sideeffects.
343 HRESULT CreateCOMObjectFromDll(HMODULE dll, const CLSID& clsid, const IID& iid,
344 void** object) {
345 if (!dll || !object)
346 return E_INVALIDARG;
347
348 using GetClassObject = HRESULT (WINAPI*)(
349 const CLSID& clsid, const IID& iid, void** object);
350
351 GetClassObject get_class_object = reinterpret_cast<GetClassObject>(
352 GetProcAddress(dll, "DllGetClassObject"));
353 RETURN_ON_FAILURE(
354 get_class_object, "Failed to get DllGetClassObject pointer", E_FAIL);
355
356 base::win::ScopedComPtr<IClassFactory> factory;
357 HRESULT hr = get_class_object(
358 clsid,
359 __uuidof(IClassFactory),
360 factory.ReceiveVoid());
361 RETURN_ON_HR_FAILURE(hr, "DllGetClassObject failed", hr);
362
363 hr = factory->CreateInstance(NULL, iid, object);
364 return hr;
365 }
366
367 // Helper function to query the ANGLE device object. The template argument T
368 // identifies the device interface being queried. IDirect3DDevice9Ex for d3d9
369 // and ID3D11Device for dx11.
370 template<class T>
371 base::win::ScopedComPtr<T> QueryDeviceObjectFromANGLE(int object_type) {
372 base::win::ScopedComPtr<T> device_object;
373
374 EGLDisplay egl_display = nullptr;
375 intptr_t egl_device = 0;
376 intptr_t device = 0;
377
378 {
379 TRACE_EVENT0("gpu", "QueryDeviceObjectFromANGLE. GetHardwareDisplay");
380 egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
381 }
382
383 RETURN_ON_FAILURE(
384 gfx::GLSurfaceEGL::HasEGLExtension("EGL_EXT_device_query"),
385 "EGL_EXT_device_query missing",
386 device_object);
387
388 PFNEGLQUERYDISPLAYATTRIBEXTPROC QueryDisplayAttribEXT = nullptr;
389
390 {
391 TRACE_EVENT0("gpu", "QueryDeviceObjectFromANGLE. eglGetProcAddress");
392
393 QueryDisplayAttribEXT =
394 reinterpret_cast<PFNEGLQUERYDISPLAYATTRIBEXTPROC>(eglGetProcAddress(
395 "eglQueryDisplayAttribEXT"));
396
397 RETURN_ON_FAILURE(
398 QueryDisplayAttribEXT,
399 "Failed to get the eglQueryDisplayAttribEXT function from ANGLE",
400 device_object);
401 }
402
403 PFNEGLQUERYDEVICEATTRIBEXTPROC QueryDeviceAttribEXT = nullptr;
404
405 {
406 TRACE_EVENT0("gpu", "QueryDeviceObjectFromANGLE. eglGetProcAddress");
407
408 QueryDeviceAttribEXT =
409 reinterpret_cast<PFNEGLQUERYDEVICEATTRIBEXTPROC>(eglGetProcAddress(
410 "eglQueryDeviceAttribEXT"));
411
412 RETURN_ON_FAILURE(
413 QueryDeviceAttribEXT,
414 "Failed to get the eglQueryDeviceAttribEXT function from ANGLE",
415 device_object);
416 }
417
418 {
419 TRACE_EVENT0("gpu", "QueryDeviceObjectFromANGLE. QueryDisplayAttribEXT");
420
421 RETURN_ON_FAILURE(
422 QueryDisplayAttribEXT(egl_display, EGL_DEVICE_EXT, &egl_device),
423 "The eglQueryDisplayAttribEXT function failed to get the EGL device",
424 device_object);
425 }
426
427 RETURN_ON_FAILURE(
428 egl_device,
429 "Failed to get the EGL device",
430 device_object);
431
432 {
433 TRACE_EVENT0("gpu", "QueryDeviceObjectFromANGLE. QueryDisplayAttribEXT");
434
435 RETURN_ON_FAILURE(
436 QueryDeviceAttribEXT(
437 reinterpret_cast<EGLDeviceEXT>(egl_device), object_type, &device),
438 "The eglQueryDeviceAttribEXT function failed to get the device",
439 device_object);
440
441 RETURN_ON_FAILURE(device, "Failed to get the ANGLE device", device_object);
442 }
443
444 device_object = reinterpret_cast<T*>(device);
445 return device_object;
446 }
447
448 H264ConfigChangeDetector::H264ConfigChangeDetector()
449 : last_sps_id_(0),
450 last_pps_id_(0),
451 config_changed_(false),
452 pending_config_changed_(false) {
453 }
454
455 H264ConfigChangeDetector::~H264ConfigChangeDetector() {
456 }
457
458 bool H264ConfigChangeDetector::DetectConfig(const uint8_t* stream,
459 unsigned int size) {
460 std::vector<uint8_t> sps;
461 std::vector<uint8_t> pps;
462 media::H264NALU nalu;
463 bool idr_seen = false;
464
465 if (!parser_.get())
466 parser_.reset(new media::H264Parser);
467
468 parser_->SetStream(stream, size);
469 config_changed_ = false;
470
471 while (true) {
472 media::H264Parser::Result result = parser_->AdvanceToNextNALU(&nalu);
473
474 if (result == media::H264Parser::kEOStream)
475 break;
476
477 if (result == media::H264Parser::kUnsupportedStream) {
478 DLOG(ERROR) << "Unsupported H.264 stream";
479 return false;
480 }
481
482 if (result != media::H264Parser::kOk) {
483 DLOG(ERROR) << "Failed to parse H.264 stream";
484 return false;
485 }
486
487 switch (nalu.nal_unit_type) {
488 case media::H264NALU::kSPS:
489 result = parser_->ParseSPS(&last_sps_id_);
490 if (result == media::H264Parser::kUnsupportedStream) {
491 DLOG(ERROR) << "Unsupported SPS";
492 return false;
493 }
494
495 if (result != media::H264Parser::kOk) {
496 DLOG(ERROR) << "Could not parse SPS";
497 return false;
498 }
499
500 sps.assign(nalu.data, nalu.data + nalu.size);
501 break;
502
503 case media::H264NALU::kPPS:
504 result = parser_->ParsePPS(&last_pps_id_);
505 if (result == media::H264Parser::kUnsupportedStream) {
506 DLOG(ERROR) << "Unsupported PPS";
507 return false;
508 }
509 if (result != media::H264Parser::kOk) {
510 DLOG(ERROR) << "Could not parse PPS";
511 return false;
512 }
513 pps.assign(nalu.data, nalu.data + nalu.size);
514 break;
515
516 case media::H264NALU::kIDRSlice:
517 idr_seen = true;
518 // If we previously detected a configuration change, and see an IDR
519 // slice next time around, we need to flag a configuration change.
520 if (pending_config_changed_) {
521 config_changed_ = true;
522 pending_config_changed_ = false;
523 }
524 break;
525
526 default:
527 break;
528 }
529 }
530
531 if (!sps.empty() && sps != last_sps_) {
532 if (!last_sps_.empty()) {
533 // Flag configuration changes after we see an IDR slice.
534 if (idr_seen) {
535 config_changed_ = true;
536 } else {
537 pending_config_changed_ = true;
538 }
539 }
540 last_sps_.swap(sps);
541 }
542
543 if (!pps.empty() && pps != last_pps_) {
544 if (!last_pps_.empty()) {
545 // Flag configuration changes after we see an IDR slice.
546 if (idr_seen) {
547 config_changed_ = true;
548 } else {
549 pending_config_changed_ = true;
550 }
551 }
552 last_pps_.swap(pps);
553 }
554 return true;
555 }
556
557 // Maintains information about a DXVA picture buffer, i.e. whether it is
558 // available for rendering, the texture information, etc.
559 struct DXVAVideoDecodeAccelerator::DXVAPictureBuffer {
560 public:
561 static linked_ptr<DXVAPictureBuffer> Create(
562 const DXVAVideoDecodeAccelerator& decoder,
563 const media::PictureBuffer& buffer,
564 EGLConfig egl_config);
565 ~DXVAPictureBuffer();
566
567 bool InitializeTexture(const DXVAVideoDecodeAccelerator& decoder,
568 bool use_rgb);
569
570 bool ReusePictureBuffer();
571 void ResetReuseFence();
572 // Copies the output sample data to the picture buffer provided by the
573 // client.
574 // The dest_surface parameter contains the decoded bits.
575 bool CopyOutputSampleDataToPictureBuffer(
576 DXVAVideoDecodeAccelerator* decoder,
577 IDirect3DSurface9* dest_surface,
578 ID3D11Texture2D* dx11_texture,
579 int input_buffer_id);
580
581 bool available() const {
582 return available_;
583 }
584
585 void set_available(bool available) {
586 available_ = available;
587 }
588
589 int id() const {
590 return picture_buffer_.id();
591 }
592
593 gfx::Size size() const {
594 return picture_buffer_.size();
595 }
596
597 bool waiting_to_reuse() const { return waiting_to_reuse_; }
598
599 gfx::GLFence* reuse_fence() { return reuse_fence_.get(); }
600
601 // Called when the source surface |src_surface| is copied to the destination
602 // |dest_surface|
603 bool CopySurfaceComplete(IDirect3DSurface9* src_surface,
604 IDirect3DSurface9* dest_surface);
605
606 private:
607 explicit DXVAPictureBuffer(const media::PictureBuffer& buffer);
608
609 bool available_;
610
611 // This is true if the decoder is currently waiting on the fence before
612 // reusing the buffer.
613 bool waiting_to_reuse_;
614 media::PictureBuffer picture_buffer_;
615 EGLSurface decoding_surface_;
616 std::unique_ptr<gfx::GLFence> reuse_fence_;
617
618 HANDLE texture_share_handle_;
619 base::win::ScopedComPtr<IDirect3DTexture9> decoding_texture_;
620 base::win::ScopedComPtr<ID3D11Texture2D> dx11_decoding_texture_;
621
622 base::win::ScopedComPtr<IDXGIKeyedMutex> egl_keyed_mutex_;
623 base::win::ScopedComPtr<IDXGIKeyedMutex> dx11_keyed_mutex_;
624
625 // This is the last value that was used to release the keyed mutex.
626 uint64_t keyed_mutex_value_;
627
628 // The following |IDirect3DSurface9| interface pointers are used to hold
629 // references on the surfaces during the course of a StretchRect operation
630 // to copy the source surface to the target. The references are released
631 // when the StretchRect operation i.e. the copy completes.
632 base::win::ScopedComPtr<IDirect3DSurface9> decoder_surface_;
633 base::win::ScopedComPtr<IDirect3DSurface9> target_surface_;
634
635 // This ID3D11Texture2D interface pointer is used to hold a reference to the
636 // decoder texture during the course of a copy operation. This reference is
637 // released when the copy completes.
638 base::win::ScopedComPtr<ID3D11Texture2D> decoder_dx11_texture_;
639
640 // Set to true if RGB is supported by the texture.
641 // Defaults to true.
642 bool use_rgb_;
643
644 DISALLOW_COPY_AND_ASSIGN(DXVAPictureBuffer);
645 };
646
647 // static
648 linked_ptr<DXVAVideoDecodeAccelerator::DXVAPictureBuffer>
649 DXVAVideoDecodeAccelerator::DXVAPictureBuffer::Create(
650 const DXVAVideoDecodeAccelerator& decoder,
651 const media::PictureBuffer& buffer,
652 EGLConfig egl_config) {
653 linked_ptr<DXVAPictureBuffer> picture_buffer(new DXVAPictureBuffer(buffer));
654
655 EGLDisplay egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
656
657 EGLint use_rgb = 1;
658 eglGetConfigAttrib(egl_display, egl_config, EGL_BIND_TO_TEXTURE_RGB,
659 &use_rgb);
660
661 if (!picture_buffer->InitializeTexture(decoder, !!use_rgb))
662 return linked_ptr<DXVAPictureBuffer>(nullptr);
663
664 EGLint attrib_list[] = {
665 EGL_WIDTH, buffer.size().width(),
666 EGL_HEIGHT, buffer.size().height(),
667 EGL_TEXTURE_FORMAT, use_rgb ? EGL_TEXTURE_RGB : EGL_TEXTURE_RGBA,
668 EGL_TEXTURE_TARGET, EGL_TEXTURE_2D,
669 EGL_NONE
670 };
671
672 picture_buffer->decoding_surface_ = eglCreatePbufferFromClientBuffer(
673 egl_display, EGL_D3D_TEXTURE_2D_SHARE_HANDLE_ANGLE,
674 picture_buffer->texture_share_handle_, egl_config, attrib_list);
675 RETURN_ON_FAILURE(picture_buffer->decoding_surface_,
676 "Failed to create surface",
677 linked_ptr<DXVAPictureBuffer>(NULL));
678 if (decoder.d3d11_device_ && decoder.use_keyed_mutex_) {
679 void* keyed_mutex = nullptr;
680 EGLBoolean ret = eglQuerySurfacePointerANGLE(
681 egl_display, picture_buffer->decoding_surface_,
682 EGL_DXGI_KEYED_MUTEX_ANGLE, &keyed_mutex);
683 RETURN_ON_FAILURE(keyed_mutex && ret == EGL_TRUE,
684 "Failed to query ANGLE keyed mutex",
685 linked_ptr<DXVAPictureBuffer>(nullptr));
686 picture_buffer->egl_keyed_mutex_ = base::win::ScopedComPtr<IDXGIKeyedMutex>(
687 static_cast<IDXGIKeyedMutex*>(keyed_mutex));
688 }
689 picture_buffer->use_rgb_ = !!use_rgb;
690 return picture_buffer;
691 }
692
693 bool DXVAVideoDecodeAccelerator::DXVAPictureBuffer::InitializeTexture(
694 const DXVAVideoDecodeAccelerator& decoder,
695 bool use_rgb) {
696 DCHECK(!texture_share_handle_);
697 if (decoder.d3d11_device_) {
698 D3D11_TEXTURE2D_DESC desc;
699 desc.Width = picture_buffer_.size().width();
700 desc.Height = picture_buffer_.size().height();
701 desc.MipLevels = 1;
702 desc.ArraySize = 1;
703 desc.Format = DXGI_FORMAT_B8G8R8A8_UNORM;
704 desc.SampleDesc.Count = 1;
705 desc.SampleDesc.Quality = 0;
706 desc.Usage = D3D11_USAGE_DEFAULT;
707 desc.BindFlags = D3D11_BIND_SHADER_RESOURCE | D3D11_BIND_RENDER_TARGET;
708 desc.CPUAccessFlags = 0;
709 desc.MiscFlags = decoder.use_keyed_mutex_
710 ? D3D11_RESOURCE_MISC_SHARED_KEYEDMUTEX
711 : D3D11_RESOURCE_MISC_SHARED;
712
713 HRESULT hr = decoder.d3d11_device_->CreateTexture2D(
714 &desc, nullptr, dx11_decoding_texture_.Receive());
715 RETURN_ON_HR_FAILURE(hr, "Failed to create texture", false);
716 if (decoder.use_keyed_mutex_) {
717 hr = dx11_keyed_mutex_.QueryFrom(dx11_decoding_texture_.get());
718 RETURN_ON_HR_FAILURE(hr, "Failed to get keyed mutex", false);
719 }
720
721 base::win::ScopedComPtr<IDXGIResource> resource;
722 hr = resource.QueryFrom(dx11_decoding_texture_.get());
723 DCHECK(SUCCEEDED(hr));
724 hr = resource->GetSharedHandle(&texture_share_handle_);
725 RETURN_ON_FAILURE(SUCCEEDED(hr) && texture_share_handle_,
726 "Failed to query shared handle", false);
727
728 } else {
729 HRESULT hr = E_FAIL;
730 hr = decoder.d3d9_device_ex_->CreateTexture(
731 picture_buffer_.size().width(), picture_buffer_.size().height(), 1,
732 D3DUSAGE_RENDERTARGET, use_rgb ? D3DFMT_X8R8G8B8 : D3DFMT_A8R8G8B8,
733 D3DPOOL_DEFAULT, decoding_texture_.Receive(), &texture_share_handle_);
734 RETURN_ON_HR_FAILURE(hr, "Failed to create texture", false);
735 RETURN_ON_FAILURE(texture_share_handle_, "Failed to query shared handle",
736 false);
737 }
738 return true;
739 }
740
741 DXVAVideoDecodeAccelerator::DXVAPictureBuffer::DXVAPictureBuffer(
742 const media::PictureBuffer& buffer)
743 : available_(true),
744 waiting_to_reuse_(false),
745 picture_buffer_(buffer),
746 decoding_surface_(NULL),
747 texture_share_handle_(nullptr),
748 keyed_mutex_value_(0),
749 use_rgb_(true) {}
750
751 DXVAVideoDecodeAccelerator::DXVAPictureBuffer::~DXVAPictureBuffer() {
752 if (decoding_surface_) {
753 EGLDisplay egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
754
755 eglReleaseTexImage(
756 egl_display,
757 decoding_surface_,
758 EGL_BACK_BUFFER);
759
760 eglDestroySurface(
761 egl_display,
762 decoding_surface_);
763 decoding_surface_ = NULL;
764 }
765 }
766
767 bool DXVAVideoDecodeAccelerator::DXVAPictureBuffer::ReusePictureBuffer() {
768 DCHECK(decoding_surface_);
769 EGLDisplay egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
770 eglReleaseTexImage(
771 egl_display,
772 decoding_surface_,
773 EGL_BACK_BUFFER);
774 decoder_surface_.Release();
775 target_surface_.Release();
776 decoder_dx11_texture_.Release();
777 waiting_to_reuse_ = false;
778 set_available(true);
779 if (egl_keyed_mutex_) {
780 HRESULT hr = egl_keyed_mutex_->ReleaseSync(++keyed_mutex_value_);
781 RETURN_ON_FAILURE(hr == S_OK, "Could not release sync mutex", false);
782 }
783 return true;
784 }
785
786 void DXVAVideoDecodeAccelerator::DXVAPictureBuffer::ResetReuseFence() {
787 if (!reuse_fence_ || !reuse_fence_->ResetSupported())
788 reuse_fence_.reset(gfx::GLFence::Create());
789 else
790 reuse_fence_->ResetState();
791 waiting_to_reuse_ = true;
792 }
793
794 bool DXVAVideoDecodeAccelerator::DXVAPictureBuffer::
795 CopyOutputSampleDataToPictureBuffer(
796 DXVAVideoDecodeAccelerator* decoder,
797 IDirect3DSurface9* dest_surface,
798 ID3D11Texture2D* dx11_texture,
799 int input_buffer_id) {
800 DCHECK(dest_surface || dx11_texture);
801 if (dx11_texture) {
802 // Grab a reference on the decoder texture. This reference will be released
803 // when we receive a notification that the copy was completed or when the
804 // DXVAPictureBuffer instance is destroyed.
805 decoder_dx11_texture_ = dx11_texture;
806 decoder->CopyTexture(dx11_texture, dx11_decoding_texture_.get(),
807 dx11_keyed_mutex_, keyed_mutex_value_, NULL, id(),
808 input_buffer_id);
809 return true;
810 }
811 D3DSURFACE_DESC surface_desc;
812 HRESULT hr = dest_surface->GetDesc(&surface_desc);
813 RETURN_ON_HR_FAILURE(hr, "Failed to get surface description", false);
814
815 D3DSURFACE_DESC texture_desc;
816 decoding_texture_->GetLevelDesc(0, &texture_desc);
817
818 if (texture_desc.Width != surface_desc.Width ||
819 texture_desc.Height != surface_desc.Height) {
820 NOTREACHED() << "Decode surface of different dimension than texture";
821 return false;
822 }
823
824 hr = decoder->d3d9_->CheckDeviceFormatConversion(
825 D3DADAPTER_DEFAULT, D3DDEVTYPE_HAL, surface_desc.Format,
826 use_rgb_ ? D3DFMT_X8R8G8B8 : D3DFMT_A8R8G8B8);
827 RETURN_ON_HR_FAILURE(hr, "Device does not support format converision", false);
828
829 // The same picture buffer can be reused for a different frame. Release the
830 // target surface and the decoder references here.
831 target_surface_.Release();
832 decoder_surface_.Release();
833
834 // Grab a reference on the decoder surface and the target surface. These
835 // references will be released when we receive a notification that the
836 // copy was completed or when the DXVAPictureBuffer instance is destroyed.
837 // We hold references here as it is easier to manage their lifetimes.
838 hr = decoding_texture_->GetSurfaceLevel(0, target_surface_.Receive());
839 RETURN_ON_HR_FAILURE(hr, "Failed to get surface from texture", false);
840
841 decoder_surface_ = dest_surface;
842
843 decoder->CopySurface(decoder_surface_.get(), target_surface_.get(), id(),
844 input_buffer_id);
845 return true;
846 }
847
848 bool DXVAVideoDecodeAccelerator::DXVAPictureBuffer::CopySurfaceComplete(
849 IDirect3DSurface9* src_surface,
850 IDirect3DSurface9* dest_surface) {
851 DCHECK(!available());
852
853 GLint current_texture = 0;
854 glGetIntegerv(GL_TEXTURE_BINDING_2D, &current_texture);
855
856 glBindTexture(GL_TEXTURE_2D, picture_buffer_.texture_ids()[0]);
857
858 glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
859
860 if (src_surface && dest_surface) {
861 DCHECK_EQ(src_surface, decoder_surface_.get());
862 DCHECK_EQ(dest_surface, target_surface_.get());
863 decoder_surface_.Release();
864 target_surface_.Release();
865 } else {
866 DCHECK(decoder_dx11_texture_.get());
867 decoder_dx11_texture_.Release();
868 }
869 if (egl_keyed_mutex_) {
870 keyed_mutex_value_++;
871 HRESULT result =
872 egl_keyed_mutex_->AcquireSync(keyed_mutex_value_, kAcquireSyncWaitMs);
873 RETURN_ON_FAILURE(result == S_OK, "Could not acquire sync mutex", false);
874 }
875
876 EGLDisplay egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
877 eglBindTexImage(
878 egl_display,
879 decoding_surface_,
880 EGL_BACK_BUFFER);
881
882 glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
883 glBindTexture(GL_TEXTURE_2D, current_texture);
884 return true;
885 }
886
887 DXVAVideoDecodeAccelerator::PendingSampleInfo::PendingSampleInfo(
888 int32_t buffer_id,
889 IMFSample* sample)
890 : input_buffer_id(buffer_id), picture_buffer_id(-1) {
891 output_sample.Attach(sample);
892 }
893
894 DXVAVideoDecodeAccelerator::PendingSampleInfo::PendingSampleInfo(
895 const PendingSampleInfo& other) = default;
896
897 DXVAVideoDecodeAccelerator::PendingSampleInfo::~PendingSampleInfo() {}
898
899 DXVAVideoDecodeAccelerator::DXVAVideoDecodeAccelerator(
900 const GetGLContextCallback& get_gl_context_cb,
901 const MakeGLContextCurrentCallback& make_context_current_cb,
902 bool enable_accelerated_vpx_decode)
903 : client_(NULL),
904 dev_manager_reset_token_(0),
905 dx11_dev_manager_reset_token_(0),
906 egl_config_(NULL),
907 state_(kUninitialized),
908 pictures_requested_(false),
909 inputs_before_decode_(0),
910 sent_drain_message_(false),
911 get_gl_context_cb_(get_gl_context_cb),
912 make_context_current_cb_(make_context_current_cb),
913 codec_(media::kUnknownVideoCodec),
914 decoder_thread_("DXVAVideoDecoderThread"),
915 pending_flush_(false),
916 use_dx11_(false),
917 use_keyed_mutex_(false),
918 dx11_video_format_converter_media_type_needs_init_(true),
919 using_angle_device_(false),
920 enable_accelerated_vpx_decode_(enable_accelerated_vpx_decode),
921 weak_this_factory_(this) {
922 weak_ptr_ = weak_this_factory_.GetWeakPtr();
923 memset(&input_stream_info_, 0, sizeof(input_stream_info_));
924 memset(&output_stream_info_, 0, sizeof(output_stream_info_));
925 }
926
927 DXVAVideoDecodeAccelerator::~DXVAVideoDecodeAccelerator() {
928 client_ = NULL;
929 }
930
931 bool DXVAVideoDecodeAccelerator::Initialize(const Config& config,
932 Client* client) {
933 if (get_gl_context_cb_.is_null() || make_context_current_cb_.is_null()) {
934 NOTREACHED() << "GL callbacks are required for this VDA";
935 return false;
936 }
937
938 if (config.is_encrypted) {
939 NOTREACHED() << "Encrypted streams are not supported for this VDA";
940 return false;
941 }
942
943 if (config.output_mode != Config::OutputMode::ALLOCATE) {
944 NOTREACHED() << "Only ALLOCATE OutputMode is supported by this VDA";
945 return false;
946 }
947
948 client_ = client;
949
950 main_thread_task_runner_ = base::MessageLoop::current()->task_runner();
951
952 bool profile_supported = false;
953 for (const auto& supported_profile : kSupportedProfiles) {
954 if (config.profile == supported_profile) {
955 profile_supported = true;
956 break;
957 }
958 }
959 if (!profile_supported) {
960 RETURN_AND_NOTIFY_ON_FAILURE(false,
961 "Unsupported h.264, vp8, or vp9 profile", PLATFORM_FAILURE, false);
962 }
963
964 // Not all versions of Windows 7 and later include Media Foundation DLLs.
965 // Instead of crashing while delay loading the DLL when calling MFStartup()
966 // below, probe whether we can successfully load the DLL now.
967 // See http://crbug.com/339678 for details.
968 HMODULE dxgi_manager_dll = ::GetModuleHandle(L"MFPlat.dll");
969 RETURN_ON_FAILURE(dxgi_manager_dll, "MFPlat.dll is required for decoding",
970 false);
971
972 // On Windows 8+ mfplat.dll provides the MFCreateDXGIDeviceManager API.
973 // On Windows 7 mshtmlmedia.dll provides it.
974
975 // TODO(ananta)
976 // The code below works, as in we can create the DX11 device manager for
977 // Windows 7. However the IMFTransform we use for texture conversion and
978 // copy does not exist on Windows 7. Look into an alternate approach
979 // and enable the code below.
980 #if defined(ENABLE_DX11_FOR_WIN7)
981 if (base::win::GetVersion() == base::win::VERSION_WIN7) {
982 dxgi_manager_dll = ::GetModuleHandle(L"mshtmlmedia.dll");
983 RETURN_ON_FAILURE(dxgi_manager_dll,
984 "mshtmlmedia.dll is required for decoding", false);
985 }
986 #endif
987 // If we don't find the MFCreateDXGIDeviceManager API we fallback to D3D9
988 // decoding.
989 if (dxgi_manager_dll && !create_dxgi_device_manager_) {
990 create_dxgi_device_manager_ = reinterpret_cast<CreateDXGIDeviceManager>(
991 ::GetProcAddress(dxgi_manager_dll, "MFCreateDXGIDeviceManager"));
992 }
993
994 RETURN_AND_NOTIFY_ON_FAILURE(
995 gfx::g_driver_egl.ext.b_EGL_ANGLE_surface_d3d_texture_2d_share_handle,
996 "EGL_ANGLE_surface_d3d_texture_2d_share_handle unavailable",
997 PLATFORM_FAILURE,
998 false);
999
1000 RETURN_AND_NOTIFY_ON_FAILURE(gfx::GLFence::IsSupported(),
1001 "GL fences are unsupported", PLATFORM_FAILURE,
1002 false);
1003
1004 State state = GetState();
1005 RETURN_AND_NOTIFY_ON_FAILURE((state == kUninitialized),
1006 "Initialize: invalid state: " << state, ILLEGAL_STATE, false);
1007
1008 media::InitializeMediaFoundation();
1009
1010 RETURN_AND_NOTIFY_ON_FAILURE(InitDecoder(config.profile),
1011 "Failed to initialize decoder", PLATFORM_FAILURE, false);
1012
1013 RETURN_AND_NOTIFY_ON_FAILURE(GetStreamsInfoAndBufferReqs(),
1014 "Failed to get input/output stream info.", PLATFORM_FAILURE, false);
1015
1016 RETURN_AND_NOTIFY_ON_FAILURE(
1017 SendMFTMessage(MFT_MESSAGE_NOTIFY_BEGIN_STREAMING, 0),
1018 "Send MFT_MESSAGE_NOTIFY_BEGIN_STREAMING notification failed",
1019 PLATFORM_FAILURE, false);
1020
1021 RETURN_AND_NOTIFY_ON_FAILURE(
1022 SendMFTMessage(MFT_MESSAGE_NOTIFY_START_OF_STREAM, 0),
1023 "Send MFT_MESSAGE_NOTIFY_START_OF_STREAM notification failed",
1024 PLATFORM_FAILURE, false);
1025
1026 config_ = config;
1027
1028 config_change_detector_.reset(new H264ConfigChangeDetector);
1029
1030 SetState(kNormal);
1031
1032 StartDecoderThread();
1033 return true;
1034 }
1035
1036 bool DXVAVideoDecodeAccelerator::CreateD3DDevManager() {
1037 TRACE_EVENT0("gpu", "DXVAVideoDecodeAccelerator_CreateD3DDevManager");
1038
1039 HRESULT hr = E_FAIL;
1040
1041 hr = Direct3DCreate9Ex(D3D_SDK_VERSION, d3d9_.Receive());
1042 RETURN_ON_HR_FAILURE(hr, "Direct3DCreate9Ex failed", false);
1043
1044 hr = d3d9_->CheckDeviceFormatConversion(
1045 D3DADAPTER_DEFAULT, D3DDEVTYPE_HAL,
1046 static_cast<D3DFORMAT>(MAKEFOURCC('N', 'V', '1', '2')),
1047 D3DFMT_X8R8G8B8);
1048 RETURN_ON_HR_FAILURE(hr,
1049 "D3D9 driver does not support H/W format conversion", false);
1050
1051 base::win::ScopedComPtr<IDirect3DDevice9> angle_device =
1052 QueryDeviceObjectFromANGLE<IDirect3DDevice9>(EGL_D3D9_DEVICE_ANGLE);
1053 if (angle_device.get())
1054 using_angle_device_ = true;
1055
1056 if (using_angle_device_) {
1057 hr = d3d9_device_ex_.QueryFrom(angle_device.get());
1058 RETURN_ON_HR_FAILURE(hr,
1059 "QueryInterface for IDirect3DDevice9Ex from angle device failed",
1060 false);
1061 } else {
1062 D3DPRESENT_PARAMETERS present_params = {0};
1063 present_params.BackBufferWidth = 1;
1064 present_params.BackBufferHeight = 1;
1065 present_params.BackBufferFormat = D3DFMT_UNKNOWN;
1066 present_params.BackBufferCount = 1;
1067 present_params.SwapEffect = D3DSWAPEFFECT_DISCARD;
1068 present_params.hDeviceWindow = NULL;
1069 present_params.Windowed = TRUE;
1070 present_params.Flags = D3DPRESENTFLAG_VIDEO;
1071 present_params.FullScreen_RefreshRateInHz = 0;
1072 present_params.PresentationInterval = 0;
1073
1074 hr = d3d9_->CreateDeviceEx(D3DADAPTER_DEFAULT,
1075 D3DDEVTYPE_HAL,
1076 NULL,
1077 D3DCREATE_FPU_PRESERVE |
1078 D3DCREATE_MIXED_VERTEXPROCESSING |
1079 D3DCREATE_MULTITHREADED,
1080 &present_params,
1081 NULL,
1082 d3d9_device_ex_.Receive());
1083 RETURN_ON_HR_FAILURE(hr, "Failed to create D3D device", false);
1084 }
1085
1086 hr = DXVA2CreateDirect3DDeviceManager9(&dev_manager_reset_token_,
1087 device_manager_.Receive());
1088 RETURN_ON_HR_FAILURE(hr, "DXVA2CreateDirect3DDeviceManager9 failed", false);
1089
1090 hr = device_manager_->ResetDevice(d3d9_device_ex_.get(),
1091 dev_manager_reset_token_);
1092 RETURN_ON_HR_FAILURE(hr, "Failed to reset device", false);
1093
1094 hr = d3d9_device_ex_->CreateQuery(D3DQUERYTYPE_EVENT, query_.Receive());
1095 RETURN_ON_HR_FAILURE(hr, "Failed to create D3D device query", false);
1096 // Ensure query_ API works (to avoid an infinite loop later in
1097 // CopyOutputSampleDataToPictureBuffer).
1098 hr = query_->Issue(D3DISSUE_END);
1099 RETURN_ON_HR_FAILURE(hr, "Failed to issue END test query", false);
1100 return true;
1101 }
1102
1103 bool DXVAVideoDecodeAccelerator::CreateDX11DevManager() {
1104 HRESULT hr = create_dxgi_device_manager_(&dx11_dev_manager_reset_token_,
1105 d3d11_device_manager_.Receive());
1106 RETURN_ON_HR_FAILURE(hr, "MFCreateDXGIDeviceManager failed", false);
1107
1108 // This array defines the set of DirectX hardware feature levels we support.
1109 // The ordering MUST be preserved. All applications are assumed to support
1110 // 9.1 unless otherwise stated by the application.
1111 D3D_FEATURE_LEVEL feature_levels[] = {
1112 D3D_FEATURE_LEVEL_11_1,
1113 D3D_FEATURE_LEVEL_11_0,
1114 D3D_FEATURE_LEVEL_10_1,
1115 D3D_FEATURE_LEVEL_10_0,
1116 D3D_FEATURE_LEVEL_9_3,
1117 D3D_FEATURE_LEVEL_9_2,
1118 D3D_FEATURE_LEVEL_9_1
1119 };
1120
1121 UINT flags = D3D11_CREATE_DEVICE_VIDEO_SUPPORT;
1122
1123 #if defined _DEBUG
1124 flags |= D3D11_CREATE_DEVICE_DEBUG;
1125 #endif
1126
1127 D3D_FEATURE_LEVEL feature_level_out = D3D_FEATURE_LEVEL_11_0;
1128 hr = D3D11CreateDevice(NULL,
1129 D3D_DRIVER_TYPE_HARDWARE,
1130 NULL,
1131 flags,
1132 feature_levels,
1133 arraysize(feature_levels),
1134 D3D11_SDK_VERSION,
1135 d3d11_device_.Receive(),
1136 &feature_level_out,
1137 d3d11_device_context_.Receive());
1138 RETURN_ON_HR_FAILURE(hr, "Failed to create DX11 device", false);
1139
1140 // Enable multithreaded mode on the device. This ensures that accesses to
1141 // context are synchronized across threads. We have multiple threads
1142 // accessing the context, the media foundation decoder threads and the
1143 // decoder thread via the video format conversion transform.
1144 hr = multi_threaded_.QueryFrom(d3d11_device_.get());
1145 RETURN_ON_HR_FAILURE(hr, "Failed to query ID3D10Multithread", false);
1146 multi_threaded_->SetMultithreadProtected(TRUE);
1147
1148 hr = d3d11_device_manager_->ResetDevice(d3d11_device_.get(),
1149 dx11_dev_manager_reset_token_);
1150 RETURN_ON_HR_FAILURE(hr, "Failed to reset device", false);
1151
1152 D3D11_QUERY_DESC query_desc;
1153 query_desc.Query = D3D11_QUERY_EVENT;
1154 query_desc.MiscFlags = 0;
1155 hr = d3d11_device_->CreateQuery(
1156 &query_desc,
1157 d3d11_query_.Receive());
1158 RETURN_ON_HR_FAILURE(hr, "Failed to create DX11 device query", false);
1159
1160 HMODULE video_processor_dll = ::GetModuleHandle(L"msvproc.dll");
1161 RETURN_ON_FAILURE(video_processor_dll, "Failed to load video processor",
1162 false);
1163
1164 hr = CreateCOMObjectFromDll(
1165 video_processor_dll,
1166 CLSID_VideoProcessorMFT,
1167 __uuidof(IMFTransform),
1168 video_format_converter_mft_.ReceiveVoid());
1169 if (FAILED(hr)) {
1170 base::debug::Alias(&hr);
1171 // TODO(ananta)
1172 // Remove this CHECK when the change to use DX11 for H/W decoding
1173 // stablizes.
1174 CHECK(false);
1175 }
1176
1177 RETURN_ON_HR_FAILURE(hr, "Failed to create video format converter", false);
1178
1179 base::win::ScopedComPtr<IMFAttributes> converter_attributes;
1180 hr = video_format_converter_mft_->GetAttributes(
1181 converter_attributes.Receive());
1182 RETURN_ON_HR_FAILURE(hr, "Failed to get converter attributes", false);
1183
1184 hr = converter_attributes->SetUINT32(MF_XVP_PLAYBACK_MODE, TRUE);
1185 RETURN_ON_HR_FAILURE(
1186 hr,
1187 "Failed to set MF_XVP_PLAYBACK_MODE attribute on converter",
1188 false);
1189
1190 hr = converter_attributes->SetUINT32(MF_LOW_LATENCY, FALSE);
1191 RETURN_ON_HR_FAILURE(
1192 hr,
1193 "Failed to set MF_LOW_LATENCY attribute on converter",
1194 false);
1195 return true;
1196 }
1197
1198 void DXVAVideoDecodeAccelerator::Decode(
1199 const media::BitstreamBuffer& bitstream_buffer) {
1200 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1201
1202 // SharedMemory will take over the ownership of handle.
1203 base::SharedMemory shm(bitstream_buffer.handle(), true);
1204
1205 State state = GetState();
1206 RETURN_AND_NOTIFY_ON_FAILURE((state == kNormal || state == kStopped ||
1207 state == kFlushing),
1208 "Invalid state: " << state, ILLEGAL_STATE,);
1209 if (bitstream_buffer.id() < 0) {
1210 RETURN_AND_NOTIFY_ON_FAILURE(
1211 false, "Invalid bitstream_buffer, id: " << bitstream_buffer.id(),
1212 INVALID_ARGUMENT, );
1213 }
1214
1215 base::win::ScopedComPtr<IMFSample> sample;
1216 RETURN_AND_NOTIFY_ON_FAILURE(shm.Map(bitstream_buffer.size()),
1217 "Failed in base::SharedMemory::Map",
1218 PLATFORM_FAILURE, );
1219
1220 sample.Attach(CreateInputSample(
1221 reinterpret_cast<const uint8_t*>(shm.memory()), bitstream_buffer.size(),
1222 std::min<uint32_t>(bitstream_buffer.size(), input_stream_info_.cbSize),
1223 input_stream_info_.cbAlignment));
1224 RETURN_AND_NOTIFY_ON_FAILURE(sample.get(), "Failed to create input sample",
1225 PLATFORM_FAILURE, );
1226
1227 RETURN_AND_NOTIFY_ON_HR_FAILURE(sample->SetSampleTime(bitstream_buffer.id()),
1228 "Failed to associate input buffer id with sample", PLATFORM_FAILURE,);
1229
1230 decoder_thread_task_runner_->PostTask(
1231 FROM_HERE,
1232 base::Bind(&DXVAVideoDecodeAccelerator::DecodeInternal,
1233 base::Unretained(this), sample));
1234 }
1235
1236 void DXVAVideoDecodeAccelerator::AssignPictureBuffers(
1237 const std::vector<media::PictureBuffer>& buffers) {
1238 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1239
1240 State state = GetState();
1241 RETURN_AND_NOTIFY_ON_FAILURE((state != kUninitialized),
1242 "Invalid state: " << state, ILLEGAL_STATE,);
1243 RETURN_AND_NOTIFY_ON_FAILURE((kNumPictureBuffers >= buffers.size()),
1244 "Failed to provide requested picture buffers. (Got " << buffers.size() <<
1245 ", requested " << kNumPictureBuffers << ")", INVALID_ARGUMENT,);
1246
1247 // Copy the picture buffers provided by the client to the available list,
1248 // and mark these buffers as available for use.
1249 for (size_t buffer_index = 0; buffer_index < buffers.size();
1250 ++buffer_index) {
1251 DCHECK_LE(1u, buffers[buffer_index].texture_ids().size());
1252 linked_ptr<DXVAPictureBuffer> picture_buffer =
1253 DXVAPictureBuffer::Create(*this, buffers[buffer_index], egl_config_);
1254 RETURN_AND_NOTIFY_ON_FAILURE(picture_buffer.get(),
1255 "Failed to allocate picture buffer", PLATFORM_FAILURE,);
1256
1257 bool inserted = output_picture_buffers_.insert(std::make_pair(
1258 buffers[buffer_index].id(), picture_buffer)).second;
1259 DCHECK(inserted);
1260 }
1261
1262 ProcessPendingSamples();
1263 if (pending_flush_) {
1264 decoder_thread_task_runner_->PostTask(
1265 FROM_HERE,
1266 base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
1267 base::Unretained(this)));
1268 }
1269 }
1270
1271 void DXVAVideoDecodeAccelerator::ReusePictureBuffer(int32_t picture_buffer_id) {
1272 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1273
1274 State state = GetState();
1275 RETURN_AND_NOTIFY_ON_FAILURE((state != kUninitialized),
1276 "Invalid state: " << state, ILLEGAL_STATE,);
1277
1278 if (output_picture_buffers_.empty() && stale_output_picture_buffers_.empty())
1279 return;
1280
1281 OutputBuffers::iterator it = output_picture_buffers_.find(picture_buffer_id);
1282 // If we didn't find the picture id in the |output_picture_buffers_| map we
1283 // try the |stale_output_picture_buffers_| map, as this may have been an
1284 // output picture buffer from before a resolution change, that at resolution
1285 // change time had yet to be displayed. The client is calling us back to tell
1286 // us that we can now recycle this picture buffer, so if we were waiting to
1287 // dispose of it we now can.
1288 if (it == output_picture_buffers_.end()) {
1289 if (!stale_output_picture_buffers_.empty()) {
1290 it = stale_output_picture_buffers_.find(picture_buffer_id);
1291 RETURN_AND_NOTIFY_ON_FAILURE(it != stale_output_picture_buffers_.end(),
1292 "Invalid picture id: " << picture_buffer_id, INVALID_ARGUMENT,);
1293 main_thread_task_runner_->PostTask(
1294 FROM_HERE,
1295 base::Bind(&DXVAVideoDecodeAccelerator::DeferredDismissStaleBuffer,
1296 weak_this_factory_.GetWeakPtr(), picture_buffer_id));
1297 }
1298 return;
1299 }
1300
1301 if (it->second->available() || it->second->waiting_to_reuse())
1302 return;
1303
1304 if (use_keyed_mutex_ || using_angle_device_) {
1305 RETURN_AND_NOTIFY_ON_FAILURE(it->second->ReusePictureBuffer(),
1306 "Failed to reuse picture buffer",
1307 PLATFORM_FAILURE, );
1308
1309 ProcessPendingSamples();
1310 if (pending_flush_) {
1311 decoder_thread_task_runner_->PostTask(
1312 FROM_HERE, base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
1313 base::Unretained(this)));
1314 }
1315 } else {
1316 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
1317 "Failed to make context current",
1318 PLATFORM_FAILURE, );
1319 it->second->ResetReuseFence();
1320
1321 WaitForOutputBuffer(picture_buffer_id, 0);
1322 }
1323 }
1324
1325 void DXVAVideoDecodeAccelerator::WaitForOutputBuffer(int32_t picture_buffer_id,
1326 int count) {
1327 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1328 OutputBuffers::iterator it = output_picture_buffers_.find(picture_buffer_id);
1329 if (it == output_picture_buffers_.end())
1330 return;
1331
1332 DXVAPictureBuffer* picture_buffer = it->second.get();
1333
1334 DCHECK(!picture_buffer->available());
1335 DCHECK(picture_buffer->waiting_to_reuse());
1336
1337 gfx::GLFence* fence = picture_buffer->reuse_fence();
1338 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
1339 "Failed to make context current",
1340 PLATFORM_FAILURE, );
1341 if (count <= kMaxIterationsForANGLEReuseFlush && !fence->HasCompleted()) {
1342 main_thread_task_runner_->PostDelayedTask(
1343 FROM_HERE, base::Bind(&DXVAVideoDecodeAccelerator::WaitForOutputBuffer,
1344 weak_this_factory_.GetWeakPtr(),
1345 picture_buffer_id, count + 1),
1346 base::TimeDelta::FromMilliseconds(kFlushDecoderSurfaceTimeoutMs));
1347 return;
1348 }
1349 RETURN_AND_NOTIFY_ON_FAILURE(picture_buffer->ReusePictureBuffer(),
1350 "Failed to reuse picture buffer",
1351 PLATFORM_FAILURE, );
1352
1353 ProcessPendingSamples();
1354 if (pending_flush_) {
1355 decoder_thread_task_runner_->PostTask(
1356 FROM_HERE,
1357 base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
1358 base::Unretained(this)));
1359 }
1360 }
1361
1362 void DXVAVideoDecodeAccelerator::Flush() {
1363 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1364
1365 DVLOG(1) << "DXVAVideoDecodeAccelerator::Flush";
1366
1367 State state = GetState();
1368 RETURN_AND_NOTIFY_ON_FAILURE((state == kNormal || state == kStopped),
1369 "Unexpected decoder state: " << state, ILLEGAL_STATE,);
1370
1371 SetState(kFlushing);
1372
1373 pending_flush_ = true;
1374
1375 decoder_thread_task_runner_->PostTask(
1376 FROM_HERE,
1377 base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
1378 base::Unretained(this)));
1379 }
1380
1381 void DXVAVideoDecodeAccelerator::Reset() {
1382 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1383
1384 DVLOG(1) << "DXVAVideoDecodeAccelerator::Reset";
1385
1386 State state = GetState();
1387 RETURN_AND_NOTIFY_ON_FAILURE((state == kNormal || state == kStopped),
1388 "Reset: invalid state: " << state, ILLEGAL_STATE,);
1389
1390 decoder_thread_.Stop();
1391
1392 SetState(kResetting);
1393
1394 // If we have pending output frames waiting for display then we drop those
1395 // frames and set the corresponding picture buffer as available.
1396 PendingOutputSamples::iterator index;
1397 for (index = pending_output_samples_.begin();
1398 index != pending_output_samples_.end();
1399 ++index) {
1400 if (index->picture_buffer_id != -1) {
1401 OutputBuffers::iterator it = output_picture_buffers_.find(
1402 index->picture_buffer_id);
1403 if (it != output_picture_buffers_.end()) {
1404 DXVAPictureBuffer* picture_buffer = it->second.get();
1405 picture_buffer->ReusePictureBuffer();
1406 }
1407 }
1408 }
1409
1410 pending_output_samples_.clear();
1411
1412 NotifyInputBuffersDropped();
1413
1414 RETURN_AND_NOTIFY_ON_FAILURE(SendMFTMessage(MFT_MESSAGE_COMMAND_FLUSH, 0),
1415 "Reset: Failed to send message.", PLATFORM_FAILURE,);
1416
1417 main_thread_task_runner_->PostTask(
1418 FROM_HERE,
1419 base::Bind(&DXVAVideoDecodeAccelerator::NotifyResetDone,
1420 weak_this_factory_.GetWeakPtr()));
1421
1422 StartDecoderThread();
1423 SetState(kNormal);
1424 }
1425
1426 void DXVAVideoDecodeAccelerator::Destroy() {
1427 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
1428 Invalidate();
1429 delete this;
1430 }
1431
1432 bool DXVAVideoDecodeAccelerator::TryToSetupDecodeOnSeparateThread(
1433 const base::WeakPtr<Client>& decode_client,
1434 const scoped_refptr<base::SingleThreadTaskRunner>& decode_task_runner) {
1435 return false;
1436 }
1437
1438 GLenum DXVAVideoDecodeAccelerator::GetSurfaceInternalFormat() const {
1439 return GL_BGRA_EXT;
1440 }
1441
1442 // static
1443 media::VideoDecodeAccelerator::SupportedProfiles
1444 DXVAVideoDecodeAccelerator::GetSupportedProfiles() {
1445 TRACE_EVENT0("gpu,startup",
1446 "DXVAVideoDecodeAccelerator::GetSupportedProfiles");
1447
1448 // TODO(henryhsu): Need to ensure the profiles are actually supported.
1449 SupportedProfiles profiles;
1450 for (const auto& supported_profile : kSupportedProfiles) {
1451 std::pair<int, int> min_resolution = GetMinResolution(supported_profile);
1452 std::pair<int, int> max_resolution = GetMaxResolution(supported_profile);
1453
1454 SupportedProfile profile;
1455 profile.profile = supported_profile;
1456 profile.min_resolution.SetSize(min_resolution.first, min_resolution.second);
1457 profile.max_resolution.SetSize(max_resolution.first, max_resolution.second);
1458 profiles.push_back(profile);
1459 }
1460 return profiles;
1461 }
1462
1463 // static
1464 void DXVAVideoDecodeAccelerator::PreSandboxInitialization() {
1465 ::LoadLibrary(L"MFPlat.dll");
1466 ::LoadLibrary(L"msmpeg2vdec.dll");
1467 ::LoadLibrary(L"mf.dll");
1468 ::LoadLibrary(L"dxva2.dll");
1469
1470 if (base::win::GetVersion() > base::win::VERSION_WIN7) {
1471 LoadLibrary(L"msvproc.dll");
1472 } else {
1473 #if defined(ENABLE_DX11_FOR_WIN7)
1474 LoadLibrary(L"mshtmlmedia.dll");
1475 #endif
1476 }
1477 }
1478
1479 // static
1480 std::pair<int, int> DXVAVideoDecodeAccelerator::GetMinResolution(
1481 media::VideoCodecProfile profile) {
1482 TRACE_EVENT0("gpu,startup",
1483 "DXVAVideoDecodeAccelerator::GetMinResolution");
1484 std::pair<int, int> min_resolution;
1485 if (profile >= media::H264PROFILE_BASELINE &&
1486 profile <= media::H264PROFILE_HIGH) {
1487 // Windows Media Foundation H.264 decoding does not support decoding videos
1488 // with any dimension smaller than 48 pixels:
1489 // http://msdn.microsoft.com/en-us/library/windows/desktop/dd797815
1490 min_resolution = std::make_pair(48, 48);
1491 } else {
1492 // TODO(ananta)
1493 // Detect this properly for VP8/VP9 profiles.
1494 min_resolution = std::make_pair(16, 16);
1495 }
1496 return min_resolution;
1497 }
1498
1499 // static
1500 std::pair<int, int> DXVAVideoDecodeAccelerator::GetMaxResolution(
1501 const media::VideoCodecProfile profile) {
1502 TRACE_EVENT0("gpu,startup",
1503 "DXVAVideoDecodeAccelerator::GetMaxResolution");
1504 std::pair<int, int> max_resolution;
1505 if (profile >= media::H264PROFILE_BASELINE &&
1506 profile <= media::H264PROFILE_HIGH) {
1507 max_resolution = GetMaxH264Resolution();
1508 } else {
1509 // TODO(ananta)
1510 // Detect this properly for VP8/VP9 profiles.
1511 max_resolution = std::make_pair(4096, 2160);
1512 }
1513 return max_resolution;
1514 }
1515
1516 std::pair<int, int> DXVAVideoDecodeAccelerator::GetMaxH264Resolution() {
1517 TRACE_EVENT0("gpu,startup",
1518 "DXVAVideoDecodeAccelerator::GetMaxH264Resolution");
1519 // The H.264 resolution detection operation is expensive. This static flag
1520 // allows us to run the detection once.
1521 static bool resolution_detected = false;
1522 // Use 1088 to account for 16x16 macroblocks.
1523 static std::pair<int, int> max_resolution = std::make_pair(1920, 1088);
1524 if (resolution_detected)
1525 return max_resolution;
1526
1527 resolution_detected = true;
1528
1529 // On Windows 7 the maximum resolution supported by media foundation is
1530 // 1920 x 1088.
1531 if (base::win::GetVersion() == base::win::VERSION_WIN7)
1532 return max_resolution;
1533
1534 // To detect if a driver supports the desired resolutions, we try and create
1535 // a DXVA decoder instance for that resolution and profile. If that succeeds
1536 // we assume that the driver supports H/W H.264 decoding for that resolution.
1537 HRESULT hr = E_FAIL;
1538 base::win::ScopedComPtr<ID3D11Device> device;
1539
1540 {
1541 TRACE_EVENT0("gpu,startup",
1542 "GetMaxH264Resolution. QueryDeviceObjectFromANGLE");
1543
1544 device = QueryDeviceObjectFromANGLE<ID3D11Device>(EGL_D3D11_DEVICE_ANGLE);
1545 if (!device.get())
1546 return max_resolution;
1547 }
1548
1549 base::win::ScopedComPtr<ID3D11VideoDevice> video_device;
1550 hr = device.QueryInterface(IID_ID3D11VideoDevice,
1551 video_device.ReceiveVoid());
1552 if (FAILED(hr))
1553 return max_resolution;
1554
1555 GUID decoder_guid = {};
1556
1557 {
1558 TRACE_EVENT0("gpu,startup",
1559 "GetMaxH264Resolution. H.264 guid search begin");
1560 // Enumerate supported video profiles and look for the H264 profile.
1561 bool found = false;
1562 UINT profile_count = video_device->GetVideoDecoderProfileCount();
1563 for (UINT profile_idx = 0; profile_idx < profile_count; profile_idx++) {
1564 GUID profile_id = {};
1565 hr = video_device->GetVideoDecoderProfile(profile_idx, &profile_id);
1566 if (SUCCEEDED(hr) &&
1567 (profile_id == DXVA2_ModeH264_E ||
1568 profile_id == DXVA2_Intel_ModeH264_E)) {
1569 decoder_guid = profile_id;
1570 found = true;
1571 break;
1572 }
1573 }
1574 if (!found)
1575 return max_resolution;
1576 }
1577
1578 // Legacy AMD drivers with UVD3 or earlier and some Intel GPU's crash while
1579 // creating surfaces larger than 1920 x 1088.
1580 if (IsLegacyGPU(device.get()))
1581 return max_resolution;
1582
1583 // We look for the following resolutions in the driver.
1584 // TODO(ananta)
1585 // Look into whether this list needs to be expanded.
1586 static std::pair<int, int> resolution_array[] = {
1587 // Use 1088 to account for 16x16 macroblocks.
1588 std::make_pair(1920, 1088),
1589 std::make_pair(2560, 1440),
1590 std::make_pair(3840, 2160),
1591 std::make_pair(4096, 2160),
1592 std::make_pair(4096, 2304),
1593 };
1594
1595 {
1596 TRACE_EVENT0("gpu,startup",
1597 "GetMaxH264Resolution. Resolution search begin");
1598
1599 for (size_t res_idx = 0; res_idx < arraysize(resolution_array);
1600 res_idx++) {
1601 D3D11_VIDEO_DECODER_DESC desc = {};
1602 desc.Guid = decoder_guid;
1603 desc.SampleWidth = resolution_array[res_idx].first;
1604 desc.SampleHeight = resolution_array[res_idx].second;
1605 desc.OutputFormat = DXGI_FORMAT_NV12;
1606 UINT config_count = 0;
1607 hr = video_device->GetVideoDecoderConfigCount(&desc, &config_count);
1608 if (FAILED(hr) || config_count == 0)
1609 return max_resolution;
1610
1611 D3D11_VIDEO_DECODER_CONFIG config = {};
1612 hr = video_device->GetVideoDecoderConfig(&desc, 0, &config);
1613 if (FAILED(hr))
1614 return max_resolution;
1615
1616 base::win::ScopedComPtr<ID3D11VideoDecoder> video_decoder;
1617 hr = video_device->CreateVideoDecoder(&desc, &config,
1618 video_decoder.Receive());
1619 if (!video_decoder.get())
1620 return max_resolution;
1621
1622 max_resolution = resolution_array[res_idx];
1623 }
1624 }
1625 return max_resolution;
1626 }
1627
1628 // static
1629 bool DXVAVideoDecodeAccelerator::IsLegacyGPU(ID3D11Device* device) {
1630 static const int kAMDGPUId1 = 0x1002;
1631 static const int kAMDGPUId2 = 0x1022;
1632 static const int kIntelGPU = 0x8086;
1633
1634 static bool legacy_gpu = true;
1635 // This flag ensures that we determine the GPU type once.
1636 static bool legacy_gpu_determined = false;
1637
1638 if (legacy_gpu_determined)
1639 return legacy_gpu;
1640
1641 legacy_gpu_determined = true;
1642
1643 base::win::ScopedComPtr<IDXGIDevice> dxgi_device;
1644 HRESULT hr = dxgi_device.QueryFrom(device);
1645 if (FAILED(hr))
1646 return legacy_gpu;
1647
1648 base::win::ScopedComPtr<IDXGIAdapter> adapter;
1649 hr = dxgi_device->GetAdapter(adapter.Receive());
1650 if (FAILED(hr))
1651 return legacy_gpu;
1652
1653 DXGI_ADAPTER_DESC adapter_desc = {};
1654 hr = adapter->GetDesc(&adapter_desc);
1655 if (FAILED(hr))
1656 return legacy_gpu;
1657
1658 // We check if the device is an Intel or an AMD device and whether it is in
1659 // the global list defined by the g_AMDUVD3GPUList and g_IntelLegacyGPUList
1660 // arrays above. If yes then the device is treated as a legacy device.
1661 if ((adapter_desc.VendorId == kAMDGPUId1) ||
1662 adapter_desc.VendorId == kAMDGPUId2) {
1663 {
1664 TRACE_EVENT0("gpu,startup",
1665 "DXVAVideoDecodeAccelerator::IsLegacyGPU. AMD check");
1666 for (size_t i = 0; i < arraysize(g_AMDUVD3GPUList); i++) {
1667 if (adapter_desc.DeviceId == g_AMDUVD3GPUList[i])
1668 return legacy_gpu;
1669 }
1670 }
1671 } else if (adapter_desc.VendorId == kIntelGPU) {
1672 {
1673 TRACE_EVENT0("gpu,startup",
1674 "DXVAVideoDecodeAccelerator::IsLegacyGPU. Intel check");
1675 for (size_t i = 0; i < arraysize(g_IntelLegacyGPUList); i++) {
1676 if (adapter_desc.DeviceId == g_IntelLegacyGPUList[i])
1677 return legacy_gpu;
1678 }
1679 }
1680 }
1681 legacy_gpu = false;
1682 return legacy_gpu;
1683 }
1684
1685 bool DXVAVideoDecodeAccelerator::InitDecoder(media::VideoCodecProfile profile) {
1686 HMODULE decoder_dll = NULL;
1687
1688 CLSID clsid = {};
1689
1690 // Profile must fall within the valid range for one of the supported codecs.
1691 if (profile >= media::H264PROFILE_MIN && profile <= media::H264PROFILE_MAX) {
1692 // We mimic the steps CoCreateInstance uses to instantiate the object. This
1693 // was previously done because it failed inside the sandbox, and now is done
1694 // as a more minimal approach to avoid other side-effects CCI might have (as
1695 // we are still in a reduced sandbox).
1696 decoder_dll = ::GetModuleHandle(L"msmpeg2vdec.dll");
1697 RETURN_ON_FAILURE(decoder_dll,
1698 "msmpeg2vdec.dll required for decoding is not loaded",
1699 false);
1700
1701 // Check version of DLL, version 6.1.7140 is blacklisted due to high crash
1702 // rates in browsers loading that DLL. If that is the version installed we
1703 // fall back to software decoding. See crbug/403440.
1704 std::unique_ptr<FileVersionInfo> version_info(
1705 FileVersionInfo::CreateFileVersionInfoForModule(decoder_dll));
1706 RETURN_ON_FAILURE(version_info,
1707 "unable to get version of msmpeg2vdec.dll",
1708 false);
1709 base::string16 file_version = version_info->file_version();
1710 RETURN_ON_FAILURE(file_version.find(L"6.1.7140") == base::string16::npos,
1711 "blacklisted version of msmpeg2vdec.dll 6.1.7140",
1712 false);
1713 codec_ = media::kCodecH264;
1714 clsid = __uuidof(CMSH264DecoderMFT);
1715 } else if (enable_accelerated_vpx_decode_ &&
1716 (profile == media::VP8PROFILE_ANY ||
1717 profile == media::VP9PROFILE_PROFILE0 ||
1718 profile == media::VP9PROFILE_PROFILE1 ||
1719 profile == media::VP9PROFILE_PROFILE2 ||
1720 profile == media::VP9PROFILE_PROFILE3)) {
1721 int program_files_key = base::DIR_PROGRAM_FILES;
1722 if (base::win::OSInfo::GetInstance()->wow64_status() ==
1723 base::win::OSInfo::WOW64_ENABLED) {
1724 program_files_key = base::DIR_PROGRAM_FILES6432;
1725 }
1726
1727 base::FilePath dll_path;
1728 RETURN_ON_FAILURE(PathService::Get(program_files_key, &dll_path),
1729 "failed to get path for Program Files", false);
1730
1731 dll_path = dll_path.Append(kVPXDecoderDLLPath);
1732 if (profile == media::VP8PROFILE_ANY) {
1733 codec_ = media::kCodecVP8;
1734 dll_path = dll_path.Append(kVP8DecoderDLLName);
1735 clsid = CLSID_WebmMfVp8Dec;
1736 } else {
1737 codec_ = media::kCodecVP9;
1738 dll_path = dll_path.Append(kVP9DecoderDLLName);
1739 clsid = CLSID_WebmMfVp9Dec;
1740 }
1741 decoder_dll = ::LoadLibraryEx(dll_path.value().data(), NULL,
1742 LOAD_WITH_ALTERED_SEARCH_PATH);
1743 RETURN_ON_FAILURE(decoder_dll, "vpx decoder dll is not loaded", false);
1744 } else {
1745 RETURN_ON_FAILURE(false, "Unsupported codec.", false);
1746 }
1747
1748 HRESULT hr = CreateCOMObjectFromDll(decoder_dll,
1749 clsid,
1750 __uuidof(IMFTransform),
1751 decoder_.ReceiveVoid());
1752 RETURN_ON_HR_FAILURE(hr, "Failed to create decoder instance", false);
1753
1754 RETURN_ON_FAILURE(CheckDecoderDxvaSupport(),
1755 "Failed to check decoder DXVA support", false);
1756
1757 ULONG_PTR device_manager_to_use = NULL;
1758 if (use_dx11_) {
1759 CHECK(create_dxgi_device_manager_);
1760 RETURN_AND_NOTIFY_ON_FAILURE(CreateDX11DevManager(),
1761 "Failed to initialize DX11 device and manager",
1762 PLATFORM_FAILURE,
1763 false);
1764 device_manager_to_use = reinterpret_cast<ULONG_PTR>(
1765 d3d11_device_manager_.get());
1766 } else {
1767 RETURN_AND_NOTIFY_ON_FAILURE(CreateD3DDevManager(),
1768 "Failed to initialize D3D device and manager",
1769 PLATFORM_FAILURE,
1770 false);
1771 device_manager_to_use = reinterpret_cast<ULONG_PTR>(device_manager_.get());
1772 }
1773
1774 hr = decoder_->ProcessMessage(
1775 MFT_MESSAGE_SET_D3D_MANAGER,
1776 device_manager_to_use);
1777 if (use_dx11_) {
1778 RETURN_ON_HR_FAILURE(hr, "Failed to pass DX11 manager to decoder", false);
1779 } else {
1780 RETURN_ON_HR_FAILURE(hr, "Failed to pass D3D manager to decoder", false);
1781 }
1782
1783 EGLDisplay egl_display = gfx::GLSurfaceEGL::GetHardwareDisplay();
1784
1785 EGLint config_attribs[] = {
1786 EGL_BUFFER_SIZE, 32,
1787 EGL_RED_SIZE, 8,
1788 EGL_GREEN_SIZE, 8,
1789 EGL_BLUE_SIZE, 8,
1790 EGL_SURFACE_TYPE, EGL_PBUFFER_BIT,
1791 EGL_ALPHA_SIZE, 0,
1792 EGL_NONE
1793 };
1794
1795 EGLint num_configs;
1796
1797 if (!eglChooseConfig(
1798 egl_display,
1799 config_attribs,
1800 &egl_config_,
1801 1,
1802 &num_configs))
1803 return false;
1804
1805 return SetDecoderMediaTypes();
1806 }
1807
1808 bool DXVAVideoDecodeAccelerator::CheckDecoderDxvaSupport() {
1809 base::win::ScopedComPtr<IMFAttributes> attributes;
1810 HRESULT hr = decoder_->GetAttributes(attributes.Receive());
1811 RETURN_ON_HR_FAILURE(hr, "Failed to get decoder attributes", false);
1812
1813 UINT32 dxva = 0;
1814 hr = attributes->GetUINT32(MF_SA_D3D_AWARE, &dxva);
1815 RETURN_ON_HR_FAILURE(hr, "Failed to check if decoder supports DXVA", false);
1816
1817 if (codec_ == media::kCodecH264) {
1818 hr = attributes->SetUINT32(CODECAPI_AVDecVideoAcceleration_H264, TRUE);
1819 RETURN_ON_HR_FAILURE(hr, "Failed to enable DXVA H/W decoding", false);
1820 }
1821
1822 hr = attributes->SetUINT32(CODECAPI_AVLowLatencyMode, TRUE);
1823 if (SUCCEEDED(hr)) {
1824 DVLOG(1) << "Successfully set Low latency mode on decoder.";
1825 } else {
1826 DVLOG(1) << "Failed to set Low latency mode on decoder. Error: " << hr;
1827 }
1828
1829 auto gl_context = get_gl_context_cb_.Run();
1830 RETURN_ON_FAILURE(gl_context, "Couldn't get GL context", false);
1831
1832 // The decoder should use DX11 iff
1833 // 1. The underlying H/W decoder supports it.
1834 // 2. We have a pointer to the MFCreateDXGIDeviceManager function needed for
1835 // this. This should always be true for Windows 8+.
1836 // 3. ANGLE is using DX11.
1837 if (create_dxgi_device_manager_ &&
1838 (gl_context->GetGLRenderer().find("Direct3D11") != std::string::npos)) {
1839 UINT32 dx11_aware = 0;
1840 attributes->GetUINT32(MF_SA_D3D11_AWARE, &dx11_aware);
1841 use_dx11_ = !!dx11_aware;
1842 }
1843
1844 use_keyed_mutex_ =
1845 use_dx11_ && gfx::GLSurfaceEGL::HasEGLExtension("EGL_ANGLE_keyed_mutex");
1846
1847 return true;
1848 }
1849
1850 bool DXVAVideoDecodeAccelerator::SetDecoderMediaTypes() {
1851 RETURN_ON_FAILURE(SetDecoderInputMediaType(),
1852 "Failed to set decoder input media type", false);
1853 return SetDecoderOutputMediaType(MFVideoFormat_NV12);
1854 }
1855
1856 bool DXVAVideoDecodeAccelerator::SetDecoderInputMediaType() {
1857 base::win::ScopedComPtr<IMFMediaType> media_type;
1858 HRESULT hr = MFCreateMediaType(media_type.Receive());
1859 RETURN_ON_HR_FAILURE(hr, "MFCreateMediaType failed", false);
1860
1861 hr = media_type->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video);
1862 RETURN_ON_HR_FAILURE(hr, "Failed to set major input type", false);
1863
1864 if (codec_ == media::kCodecH264) {
1865 hr = media_type->SetGUID(MF_MT_SUBTYPE, MFVideoFormat_H264);
1866 } else if (codec_ == media::kCodecVP8) {
1867 hr = media_type->SetGUID(MF_MT_SUBTYPE, MEDIASUBTYPE_VP80);
1868 } else if (codec_ == media::kCodecVP9) {
1869 hr = media_type->SetGUID(MF_MT_SUBTYPE, MEDIASUBTYPE_VP90);
1870 } else {
1871 NOTREACHED();
1872 RETURN_ON_FAILURE(false, "Unsupported codec on input media type.", false);
1873 }
1874 RETURN_ON_HR_FAILURE(hr, "Failed to set subtype", false);
1875
1876 // Not sure about this. msdn recommends setting this value on the input
1877 // media type.
1878 hr = media_type->SetUINT32(MF_MT_INTERLACE_MODE,
1879 MFVideoInterlace_MixedInterlaceOrProgressive);
1880 RETURN_ON_HR_FAILURE(hr, "Failed to set interlace mode", false);
1881
1882 hr = decoder_->SetInputType(0, media_type.get(), 0); // No flags
1883 RETURN_ON_HR_FAILURE(hr, "Failed to set decoder input type", false);
1884 return true;
1885 }
1886
1887 bool DXVAVideoDecodeAccelerator::SetDecoderOutputMediaType(
1888 const GUID& subtype) {
1889 return SetTransformOutputType(decoder_.get(), subtype, 0, 0);
1890 }
1891
1892 bool DXVAVideoDecodeAccelerator::SendMFTMessage(MFT_MESSAGE_TYPE msg,
1893 int32_t param) {
1894 HRESULT hr = decoder_->ProcessMessage(msg, param);
1895 return SUCCEEDED(hr);
1896 }
1897
1898 // Gets the minimum buffer sizes for input and output samples. The MFT will not
1899 // allocate buffer for input nor output, so we have to do it ourselves and make
1900 // sure they're the correct size. We only provide decoding if DXVA is enabled.
1901 bool DXVAVideoDecodeAccelerator::GetStreamsInfoAndBufferReqs() {
1902 HRESULT hr = decoder_->GetInputStreamInfo(0, &input_stream_info_);
1903 RETURN_ON_HR_FAILURE(hr, "Failed to get input stream info", false);
1904
1905 hr = decoder_->GetOutputStreamInfo(0, &output_stream_info_);
1906 RETURN_ON_HR_FAILURE(hr, "Failed to get decoder output stream info", false);
1907
1908 DVLOG(1) << "Input stream info: ";
1909 DVLOG(1) << "Max latency: " << input_stream_info_.hnsMaxLatency;
1910 if (codec_ == media::kCodecH264) {
1911 // There should be three flags, one for requiring a whole frame be in a
1912 // single sample, one for requiring there be one buffer only in a single
1913 // sample, and one that specifies a fixed sample size. (as in cbSize)
1914 CHECK_EQ(input_stream_info_.dwFlags, 0x7u);
1915 }
1916
1917 DVLOG(1) << "Min buffer size: " << input_stream_info_.cbSize;
1918 DVLOG(1) << "Max lookahead: " << input_stream_info_.cbMaxLookahead;
1919 DVLOG(1) << "Alignment: " << input_stream_info_.cbAlignment;
1920
1921 DVLOG(1) << "Output stream info: ";
1922 // The flags here should be the same and mean the same thing, except when
1923 // DXVA is enabled, there is an extra 0x100 flag meaning decoder will
1924 // allocate its own sample.
1925 DVLOG(1) << "Flags: "
1926 << std::hex << std::showbase << output_stream_info_.dwFlags;
1927 if (codec_ == media::kCodecH264) {
1928 CHECK_EQ(output_stream_info_.dwFlags, 0x107u);
1929 }
1930 DVLOG(1) << "Min buffer size: " << output_stream_info_.cbSize;
1931 DVLOG(1) << "Alignment: " << output_stream_info_.cbAlignment;
1932 return true;
1933 }
1934
1935 void DXVAVideoDecodeAccelerator::DoDecode() {
1936 DCHECK(decoder_thread_task_runner_->BelongsToCurrentThread());
1937 // This function is also called from FlushInternal in a loop which could
1938 // result in the state transitioning to kStopped due to no decoded output.
1939 State state = GetState();
1940 RETURN_AND_NOTIFY_ON_FAILURE(
1941 (state == kNormal || state == kFlushing || state == kStopped),
1942 "DoDecode: not in normal/flushing/stopped state", ILLEGAL_STATE,);
1943
1944 MFT_OUTPUT_DATA_BUFFER output_data_buffer = {0};
1945 DWORD status = 0;
1946
1947 HRESULT hr = decoder_->ProcessOutput(0, // No flags
1948 1, // # of out streams to pull from
1949 &output_data_buffer,
1950 &status);
1951 IMFCollection* events = output_data_buffer.pEvents;
1952 if (events != NULL) {
1953 DVLOG(1) << "Got events from ProcessOuput, but discarding";
1954 events->Release();
1955 }
1956 if (FAILED(hr)) {
1957 // A stream change needs further ProcessInput calls to get back decoder
1958 // output which is why we need to set the state to stopped.
1959 if (hr == MF_E_TRANSFORM_STREAM_CHANGE) {
1960 if (!SetDecoderOutputMediaType(MFVideoFormat_NV12)) {
1961 // Decoder didn't let us set NV12 output format. Not sure as to why
1962 // this can happen. Give up in disgust.
1963 NOTREACHED() << "Failed to set decoder output media type to NV12";
1964 SetState(kStopped);
1965 } else {
1966 DVLOG(1) << "Received output format change from the decoder."
1967 " Recursively invoking DoDecode";
1968 DoDecode();
1969 }
1970 return;
1971 } else if (hr == MF_E_TRANSFORM_NEED_MORE_INPUT) {
1972 // No more output from the decoder. Stop playback.
1973 SetState(kStopped);
1974 return;
1975 } else {
1976 NOTREACHED() << "Unhandled error in DoDecode()";
1977 return;
1978 }
1979 }
1980 TRACE_EVENT_ASYNC_END0("gpu", "DXVAVideoDecodeAccelerator.Decoding", this);
1981
1982 TRACE_COUNTER1("DXVA Decoding", "TotalPacketsBeforeDecode",
1983 inputs_before_decode_);
1984
1985 inputs_before_decode_ = 0;
1986
1987 RETURN_AND_NOTIFY_ON_FAILURE(ProcessOutputSample(output_data_buffer.pSample),
1988 "Failed to process output sample.", PLATFORM_FAILURE,);
1989 }
1990
1991 bool DXVAVideoDecodeAccelerator::ProcessOutputSample(IMFSample* sample) {
1992 RETURN_ON_FAILURE(sample, "Decode succeeded with NULL output sample", false);
1993
1994 LONGLONG input_buffer_id = 0;
1995 RETURN_ON_HR_FAILURE(sample->GetSampleTime(&input_buffer_id),
1996 "Failed to get input buffer id associated with sample",
1997 false);
1998
1999 {
2000 base::AutoLock lock(decoder_lock_);
2001 DCHECK(pending_output_samples_.empty());
2002 pending_output_samples_.push_back(
2003 PendingSampleInfo(input_buffer_id, sample));
2004 }
2005
2006 if (pictures_requested_) {
2007 DVLOG(1) << "Waiting for picture slots from the client.";
2008 main_thread_task_runner_->PostTask(
2009 FROM_HERE,
2010 base::Bind(&DXVAVideoDecodeAccelerator::ProcessPendingSamples,
2011 weak_this_factory_.GetWeakPtr()));
2012 return true;
2013 }
2014
2015 int width = 0;
2016 int height = 0;
2017 if (!GetVideoFrameDimensions(sample, &width, &height)) {
2018 RETURN_ON_FAILURE(false, "Failed to get D3D surface from output sample",
2019 false);
2020 }
2021
2022 // Go ahead and request picture buffers.
2023 main_thread_task_runner_->PostTask(
2024 FROM_HERE,
2025 base::Bind(&DXVAVideoDecodeAccelerator::RequestPictureBuffers,
2026 weak_this_factory_.GetWeakPtr(),
2027 width,
2028 height));
2029
2030 pictures_requested_ = true;
2031 return true;
2032 }
2033
2034 void DXVAVideoDecodeAccelerator::ProcessPendingSamples() {
2035 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2036
2037 if (!output_picture_buffers_.size())
2038 return;
2039
2040 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
2041 "Failed to make context current",
2042 PLATFORM_FAILURE, );
2043
2044 OutputBuffers::iterator index;
2045
2046 for (index = output_picture_buffers_.begin();
2047 index != output_picture_buffers_.end() &&
2048 OutputSamplesPresent();
2049 ++index) {
2050 if (index->second->available()) {
2051 PendingSampleInfo* pending_sample = NULL;
2052 {
2053 base::AutoLock lock(decoder_lock_);
2054 PendingSampleInfo& sample_info = pending_output_samples_.front();
2055 if (sample_info.picture_buffer_id != -1)
2056 continue;
2057 pending_sample = &sample_info;
2058 }
2059
2060 int width = 0;
2061 int height = 0;
2062 if (!GetVideoFrameDimensions(pending_sample->output_sample.get(),
2063 &width, &height)) {
2064 RETURN_AND_NOTIFY_ON_FAILURE(false,
2065 "Failed to get D3D surface from output sample", PLATFORM_FAILURE,);
2066 }
2067
2068 if (width != index->second->size().width() ||
2069 height != index->second->size().height()) {
2070 HandleResolutionChanged(width, height);
2071 return;
2072 }
2073
2074 base::win::ScopedComPtr<IMFMediaBuffer> output_buffer;
2075 HRESULT hr = pending_sample->output_sample->GetBufferByIndex(
2076 0, output_buffer.Receive());
2077 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2078 "Failed to get buffer from output sample", PLATFORM_FAILURE,);
2079
2080 base::win::ScopedComPtr<IDirect3DSurface9> surface;
2081 base::win::ScopedComPtr<ID3D11Texture2D> d3d11_texture;
2082
2083 if (use_dx11_) {
2084 base::win::ScopedComPtr<IMFDXGIBuffer> dxgi_buffer;
2085 hr = dxgi_buffer.QueryFrom(output_buffer.get());
2086 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2087 "Failed to get DXGIBuffer from output sample", PLATFORM_FAILURE,);
2088 hr = dxgi_buffer->GetResource(
2089 __uuidof(ID3D11Texture2D),
2090 reinterpret_cast<void**>(d3d11_texture.Receive()));
2091 } else {
2092 hr = MFGetService(output_buffer.get(), MR_BUFFER_SERVICE,
2093 IID_PPV_ARGS(surface.Receive()));
2094 }
2095 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2096 "Failed to get surface from output sample", PLATFORM_FAILURE,);
2097
2098 pending_sample->picture_buffer_id = index->second->id();
2099
2100 RETURN_AND_NOTIFY_ON_FAILURE(
2101 index->second->CopyOutputSampleDataToPictureBuffer(
2102 this,
2103 surface.get(),
2104 d3d11_texture.get(),
2105 pending_sample->input_buffer_id),
2106 "Failed to copy output sample", PLATFORM_FAILURE,);
2107
2108 index->second->set_available(false);
2109 }
2110 }
2111 }
2112
2113 void DXVAVideoDecodeAccelerator::StopOnError(
2114 media::VideoDecodeAccelerator::Error error) {
2115 if (!main_thread_task_runner_->BelongsToCurrentThread()) {
2116 main_thread_task_runner_->PostTask(
2117 FROM_HERE,
2118 base::Bind(&DXVAVideoDecodeAccelerator::StopOnError,
2119 weak_this_factory_.GetWeakPtr(),
2120 error));
2121 return;
2122 }
2123
2124 if (client_)
2125 client_->NotifyError(error);
2126 client_ = NULL;
2127
2128 if (GetState() != kUninitialized) {
2129 Invalidate();
2130 }
2131 }
2132
2133 void DXVAVideoDecodeAccelerator::Invalidate() {
2134 if (GetState() == kUninitialized)
2135 return;
2136
2137 // Best effort to make the GL context current.
2138 make_context_current_cb_.Run();
2139
2140 decoder_thread_.Stop();
2141 weak_this_factory_.InvalidateWeakPtrs();
2142 output_picture_buffers_.clear();
2143 stale_output_picture_buffers_.clear();
2144 pending_output_samples_.clear();
2145 // We want to continue processing pending input after detecting a config
2146 // change.
2147 if (GetState() != kConfigChange)
2148 pending_input_buffers_.clear();
2149 decoder_.Release();
2150 pictures_requested_ = false;
2151
2152 config_change_detector_.reset();
2153
2154 if (use_dx11_) {
2155 if (video_format_converter_mft_.get()) {
2156 video_format_converter_mft_->ProcessMessage(
2157 MFT_MESSAGE_NOTIFY_END_STREAMING, 0);
2158 video_format_converter_mft_.Release();
2159 }
2160 d3d11_device_context_.Release();
2161 d3d11_device_.Release();
2162 d3d11_device_manager_.Release();
2163 d3d11_query_.Release();
2164 dx11_video_format_converter_media_type_needs_init_ = true;
2165 multi_threaded_.Release();
2166 } else {
2167 d3d9_.Release();
2168 d3d9_device_ex_.Release();
2169 device_manager_.Release();
2170 query_.Release();
2171 }
2172
2173 SetState(kUninitialized);
2174 }
2175
2176 void DXVAVideoDecodeAccelerator::NotifyInputBufferRead(int input_buffer_id) {
2177 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2178 if (client_)
2179 client_->NotifyEndOfBitstreamBuffer(input_buffer_id);
2180 }
2181
2182 void DXVAVideoDecodeAccelerator::NotifyFlushDone() {
2183 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2184 if (client_ && pending_flush_) {
2185 pending_flush_ = false;
2186 {
2187 base::AutoLock lock(decoder_lock_);
2188 sent_drain_message_ = false;
2189 }
2190
2191 client_->NotifyFlushDone();
2192 }
2193 }
2194
2195 void DXVAVideoDecodeAccelerator::NotifyResetDone() {
2196 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2197 if (client_)
2198 client_->NotifyResetDone();
2199 }
2200
2201 void DXVAVideoDecodeAccelerator::RequestPictureBuffers(int width, int height) {
2202 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2203 // This task could execute after the decoder has been torn down.
2204 if (GetState() != kUninitialized && client_) {
2205 client_->ProvidePictureBuffers(kNumPictureBuffers, 1,
2206 gfx::Size(width, height), GL_TEXTURE_2D);
2207 }
2208 }
2209
2210 void DXVAVideoDecodeAccelerator::NotifyPictureReady(
2211 int picture_buffer_id,
2212 int input_buffer_id) {
2213 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2214 // This task could execute after the decoder has been torn down.
2215 if (GetState() != kUninitialized && client_) {
2216 // TODO(henryhsu): Use correct visible size instead of (0, 0). We can't use
2217 // coded size here so use (0, 0) intentionally to have the client choose.
2218 media::Picture picture(picture_buffer_id, input_buffer_id,
2219 gfx::Rect(0, 0), false);
2220 client_->PictureReady(picture);
2221 }
2222 }
2223
2224 void DXVAVideoDecodeAccelerator::NotifyInputBuffersDropped() {
2225 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2226 if (!client_)
2227 return;
2228
2229 for (PendingInputs::iterator it = pending_input_buffers_.begin();
2230 it != pending_input_buffers_.end(); ++it) {
2231 LONGLONG input_buffer_id = 0;
2232 RETURN_ON_HR_FAILURE((*it)->GetSampleTime(&input_buffer_id),
2233 "Failed to get buffer id associated with sample",);
2234 client_->NotifyEndOfBitstreamBuffer(input_buffer_id);
2235 }
2236 pending_input_buffers_.clear();
2237 }
2238
2239 void DXVAVideoDecodeAccelerator::DecodePendingInputBuffers() {
2240 DCHECK(decoder_thread_task_runner_->BelongsToCurrentThread());
2241 State state = GetState();
2242 RETURN_AND_NOTIFY_ON_FAILURE((state != kUninitialized),
2243 "Invalid state: " << state, ILLEGAL_STATE,);
2244
2245 if (pending_input_buffers_.empty() || OutputSamplesPresent())
2246 return;
2247
2248 PendingInputs pending_input_buffers_copy;
2249 std::swap(pending_input_buffers_, pending_input_buffers_copy);
2250
2251 for (PendingInputs::iterator it = pending_input_buffers_copy.begin();
2252 it != pending_input_buffers_copy.end(); ++it) {
2253 DecodeInternal(*it);
2254 }
2255 }
2256
2257 void DXVAVideoDecodeAccelerator::FlushInternal() {
2258 DCHECK(decoder_thread_task_runner_->BelongsToCurrentThread());
2259
2260 // We allow only one output frame to be present at any given time. If we have
2261 // an output frame, then we cannot complete the flush at this time.
2262 if (OutputSamplesPresent())
2263 return;
2264
2265 // First drain the pending input because once the drain message is sent below,
2266 // the decoder will ignore further input until it's drained.
2267 if (!pending_input_buffers_.empty()) {
2268 decoder_thread_task_runner_->PostTask(
2269 FROM_HERE,
2270 base::Bind(&DXVAVideoDecodeAccelerator::DecodePendingInputBuffers,
2271 base::Unretained(this)));
2272 decoder_thread_task_runner_->PostTask(
2273 FROM_HERE,
2274 base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
2275 base::Unretained(this)));
2276 return;
2277 }
2278
2279 {
2280 base::AutoLock lock(decoder_lock_);
2281 if (!sent_drain_message_) {
2282 RETURN_AND_NOTIFY_ON_FAILURE(SendMFTMessage(MFT_MESSAGE_COMMAND_DRAIN, 0),
2283 "Failed to send drain message",
2284 PLATFORM_FAILURE,);
2285 sent_drain_message_ = true;
2286 }
2287 }
2288
2289 // Attempt to retrieve an output frame from the decoder. If we have one,
2290 // return and proceed when the output frame is processed. If we don't have a
2291 // frame then we are done.
2292 DoDecode();
2293 if (OutputSamplesPresent())
2294 return;
2295
2296 SetState(kFlushing);
2297
2298 main_thread_task_runner_->PostTask(
2299 FROM_HERE,
2300 base::Bind(&DXVAVideoDecodeAccelerator::NotifyFlushDone,
2301 weak_this_factory_.GetWeakPtr()));
2302
2303 SetState(kNormal);
2304 }
2305
2306 void DXVAVideoDecodeAccelerator::DecodeInternal(
2307 const base::win::ScopedComPtr<IMFSample>& sample) {
2308 DCHECK(decoder_thread_task_runner_->BelongsToCurrentThread());
2309
2310 if (GetState() == kUninitialized)
2311 return;
2312
2313 if (OutputSamplesPresent() || !pending_input_buffers_.empty()) {
2314 pending_input_buffers_.push_back(sample);
2315 return;
2316 }
2317
2318 // Check if the resolution, bit rate, etc changed in the stream. If yes we
2319 // reinitialize the decoder to ensure that the stream decodes correctly.
2320 bool config_changed = false;
2321
2322 HRESULT hr = CheckConfigChanged(sample.get(), &config_changed);
2323 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to check video stream config",
2324 PLATFORM_FAILURE,);
2325
2326 if (config_changed) {
2327 pending_input_buffers_.push_back(sample);
2328 main_thread_task_runner_->PostTask(
2329 FROM_HERE,
2330 base::Bind(&DXVAVideoDecodeAccelerator::ConfigChanged,
2331 weak_this_factory_.GetWeakPtr(),
2332 config_));
2333 return;
2334 }
2335
2336 if (!inputs_before_decode_) {
2337 TRACE_EVENT_ASYNC_BEGIN0("gpu", "DXVAVideoDecodeAccelerator.Decoding",
2338 this);
2339 }
2340 inputs_before_decode_++;
2341
2342 hr = decoder_->ProcessInput(0, sample.get(), 0);
2343 // As per msdn if the decoder returns MF_E_NOTACCEPTING then it means that it
2344 // has enough data to produce one or more output samples. In this case the
2345 // recommended options are to
2346 // 1. Generate new output by calling IMFTransform::ProcessOutput until it
2347 // returns MF_E_TRANSFORM_NEED_MORE_INPUT.
2348 // 2. Flush the input data
2349 // We implement the first option, i.e to retrieve the output sample and then
2350 // process the input again. Failure in either of these steps is treated as a
2351 // decoder failure.
2352 if (hr == MF_E_NOTACCEPTING) {
2353 DoDecode();
2354 // If the DoDecode call resulted in an output frame then we should not
2355 // process any more input until that frame is copied to the target surface.
2356 if (!OutputSamplesPresent()) {
2357 State state = GetState();
2358 RETURN_AND_NOTIFY_ON_FAILURE((state == kStopped || state == kNormal ||
2359 state == kFlushing),
2360 "Failed to process output. Unexpected decoder state: " << state,
2361 PLATFORM_FAILURE,);
2362 hr = decoder_->ProcessInput(0, sample.get(), 0);
2363 }
2364 // If we continue to get the MF_E_NOTACCEPTING error we do the following:-
2365 // 1. Add the input sample to the pending queue.
2366 // 2. If we don't have any output samples we post the
2367 // DecodePendingInputBuffers task to process the pending input samples.
2368 // If we have an output sample then the above task is posted when the
2369 // output samples are sent to the client.
2370 // This is because we only support 1 pending output sample at any
2371 // given time due to the limitation with the Microsoft media foundation
2372 // decoder where it recycles the output Decoder surfaces.
2373 if (hr == MF_E_NOTACCEPTING) {
2374 pending_input_buffers_.push_back(sample);
2375 decoder_thread_task_runner_->PostTask(
2376 FROM_HERE,
2377 base::Bind(&DXVAVideoDecodeAccelerator::DecodePendingInputBuffers,
2378 base::Unretained(this)));
2379 return;
2380 }
2381 }
2382 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to process input sample",
2383 PLATFORM_FAILURE,);
2384
2385 DoDecode();
2386
2387 State state = GetState();
2388 RETURN_AND_NOTIFY_ON_FAILURE((state == kStopped || state == kNormal ||
2389 state == kFlushing),
2390 "Failed to process output. Unexpected decoder state: " << state,
2391 ILLEGAL_STATE,);
2392
2393 LONGLONG input_buffer_id = 0;
2394 RETURN_ON_HR_FAILURE(sample->GetSampleTime(&input_buffer_id),
2395 "Failed to get input buffer id associated with sample",);
2396 // The Microsoft Media foundation decoder internally buffers up to 30 frames
2397 // before returning a decoded frame. We need to inform the client that this
2398 // input buffer is processed as it may stop sending us further input.
2399 // Note: This may break clients which expect every input buffer to be
2400 // associated with a decoded output buffer.
2401 // TODO(ananta)
2402 // Do some more investigation into whether it is possible to get the MFT
2403 // decoder to emit an output packet for every input packet.
2404 // http://code.google.com/p/chromium/issues/detail?id=108121
2405 // http://code.google.com/p/chromium/issues/detail?id=150925
2406 main_thread_task_runner_->PostTask(
2407 FROM_HERE,
2408 base::Bind(&DXVAVideoDecodeAccelerator::NotifyInputBufferRead,
2409 weak_this_factory_.GetWeakPtr(),
2410 input_buffer_id));
2411 }
2412
2413 void DXVAVideoDecodeAccelerator::HandleResolutionChanged(int width,
2414 int height) {
2415 dx11_video_format_converter_media_type_needs_init_ = true;
2416
2417 main_thread_task_runner_->PostTask(
2418 FROM_HERE,
2419 base::Bind(&DXVAVideoDecodeAccelerator::DismissStaleBuffers,
2420 weak_this_factory_.GetWeakPtr(), false));
2421
2422 main_thread_task_runner_->PostTask(
2423 FROM_HERE,
2424 base::Bind(&DXVAVideoDecodeAccelerator::RequestPictureBuffers,
2425 weak_this_factory_.GetWeakPtr(),
2426 width,
2427 height));
2428 }
2429
2430 void DXVAVideoDecodeAccelerator::DismissStaleBuffers(bool force) {
2431 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
2432 "Failed to make context current",
2433 PLATFORM_FAILURE, );
2434
2435 OutputBuffers::iterator index;
2436
2437 for (index = output_picture_buffers_.begin();
2438 index != output_picture_buffers_.end();
2439 ++index) {
2440 if (force || index->second->available()) {
2441 DVLOG(1) << "Dismissing picture id: " << index->second->id();
2442 client_->DismissPictureBuffer(index->second->id());
2443 } else {
2444 // Move to |stale_output_picture_buffers_| for deferred deletion.
2445 stale_output_picture_buffers_.insert(
2446 std::make_pair(index->first, index->second));
2447 }
2448 }
2449
2450 output_picture_buffers_.clear();
2451 }
2452
2453 void DXVAVideoDecodeAccelerator::DeferredDismissStaleBuffer(
2454 int32_t picture_buffer_id) {
2455 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
2456 "Failed to make context current",
2457 PLATFORM_FAILURE, );
2458
2459 OutputBuffers::iterator it = stale_output_picture_buffers_.find(
2460 picture_buffer_id);
2461 DCHECK(it != stale_output_picture_buffers_.end());
2462 DVLOG(1) << "Dismissing picture id: " << it->second->id();
2463 client_->DismissPictureBuffer(it->second->id());
2464 stale_output_picture_buffers_.erase(it);
2465 }
2466
2467 DXVAVideoDecodeAccelerator::State
2468 DXVAVideoDecodeAccelerator::GetState() {
2469 static_assert(sizeof(State) == sizeof(long), "mismatched type sizes");
2470 State state = static_cast<State>(
2471 InterlockedAdd(reinterpret_cast<volatile long*>(&state_), 0));
2472 return state;
2473 }
2474
2475 void DXVAVideoDecodeAccelerator::SetState(State new_state) {
2476 if (!main_thread_task_runner_->BelongsToCurrentThread()) {
2477 main_thread_task_runner_->PostTask(
2478 FROM_HERE,
2479 base::Bind(&DXVAVideoDecodeAccelerator::SetState,
2480 weak_this_factory_.GetWeakPtr(),
2481 new_state));
2482 return;
2483 }
2484
2485 static_assert(sizeof(State) == sizeof(long), "mismatched type sizes");
2486 ::InterlockedExchange(reinterpret_cast<volatile long*>(&state_),
2487 new_state);
2488 DCHECK_EQ(state_, new_state);
2489 }
2490
2491 void DXVAVideoDecodeAccelerator::StartDecoderThread() {
2492 decoder_thread_.init_com_with_mta(false);
2493 decoder_thread_.Start();
2494 decoder_thread_task_runner_ = decoder_thread_.task_runner();
2495 }
2496
2497 bool DXVAVideoDecodeAccelerator::OutputSamplesPresent() {
2498 base::AutoLock lock(decoder_lock_);
2499 return !pending_output_samples_.empty();
2500 }
2501
2502 void DXVAVideoDecodeAccelerator::CopySurface(IDirect3DSurface9* src_surface,
2503 IDirect3DSurface9* dest_surface,
2504 int picture_buffer_id,
2505 int input_buffer_id) {
2506 if (!decoder_thread_task_runner_->BelongsToCurrentThread()) {
2507 decoder_thread_task_runner_->PostTask(
2508 FROM_HERE,
2509 base::Bind(&DXVAVideoDecodeAccelerator::CopySurface,
2510 base::Unretained(this),
2511 src_surface,
2512 dest_surface,
2513 picture_buffer_id,
2514 input_buffer_id));
2515 return;
2516 }
2517
2518 HRESULT hr = d3d9_device_ex_->StretchRect(src_surface, NULL, dest_surface,
2519 NULL, D3DTEXF_NONE);
2520 RETURN_ON_HR_FAILURE(hr, "Colorspace conversion via StretchRect failed",);
2521
2522 // Ideally, this should be done immediately before the draw call that uses
2523 // the texture. Flush it once here though.
2524 hr = query_->Issue(D3DISSUE_END);
2525 RETURN_ON_HR_FAILURE(hr, "Failed to issue END",);
2526
2527 // If we are sharing the ANGLE device we don't need to wait for the Flush to
2528 // complete.
2529 if (using_angle_device_) {
2530 main_thread_task_runner_->PostTask(
2531 FROM_HERE,
2532 base::Bind(&DXVAVideoDecodeAccelerator::CopySurfaceComplete,
2533 weak_this_factory_.GetWeakPtr(),
2534 src_surface,
2535 dest_surface,
2536 picture_buffer_id,
2537 input_buffer_id));
2538 return;
2539 }
2540
2541 // Flush the decoder device to ensure that the decoded frame is copied to the
2542 // target surface.
2543 decoder_thread_task_runner_->PostDelayedTask(
2544 FROM_HERE,
2545 base::Bind(&DXVAVideoDecodeAccelerator::FlushDecoder,
2546 base::Unretained(this), 0, src_surface, dest_surface,
2547 picture_buffer_id, input_buffer_id),
2548 base::TimeDelta::FromMilliseconds(kFlushDecoderSurfaceTimeoutMs));
2549 }
2550
2551 void DXVAVideoDecodeAccelerator::CopySurfaceComplete(
2552 IDirect3DSurface9* src_surface,
2553 IDirect3DSurface9* dest_surface,
2554 int picture_buffer_id,
2555 int input_buffer_id) {
2556 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2557
2558 // The output buffers may have changed in the following scenarios:-
2559 // 1. A resolution change.
2560 // 2. Decoder instance was destroyed.
2561 // Ignore copy surface notifications for such buffers.
2562 // copy surface notifications for such buffers.
2563 OutputBuffers::iterator it = output_picture_buffers_.find(picture_buffer_id);
2564 if (it == output_picture_buffers_.end())
2565 return;
2566
2567 // If the picture buffer is marked as available it probably means that there
2568 // was a Reset operation which dropped the output frame.
2569 DXVAPictureBuffer* picture_buffer = it->second.get();
2570 if (picture_buffer->available())
2571 return;
2572
2573 RETURN_AND_NOTIFY_ON_FAILURE(make_context_current_cb_.Run(),
2574 "Failed to make context current",
2575 PLATFORM_FAILURE, );
2576
2577 DCHECK(!output_picture_buffers_.empty());
2578
2579 bool result = picture_buffer->CopySurfaceComplete(src_surface, dest_surface);
2580 RETURN_AND_NOTIFY_ON_FAILURE(result, "Failed to complete copying surface",
2581 PLATFORM_FAILURE, );
2582
2583 NotifyPictureReady(picture_buffer->id(), input_buffer_id);
2584
2585 {
2586 base::AutoLock lock(decoder_lock_);
2587 if (!pending_output_samples_.empty())
2588 pending_output_samples_.pop_front();
2589 }
2590
2591 if (pending_flush_) {
2592 decoder_thread_task_runner_->PostTask(
2593 FROM_HERE,
2594 base::Bind(&DXVAVideoDecodeAccelerator::FlushInternal,
2595 base::Unretained(this)));
2596 return;
2597 }
2598 decoder_thread_task_runner_->PostTask(
2599 FROM_HERE,
2600 base::Bind(&DXVAVideoDecodeAccelerator::DecodePendingInputBuffers,
2601 base::Unretained(this)));
2602 }
2603
2604 void DXVAVideoDecodeAccelerator::CopyTexture(
2605 ID3D11Texture2D* src_texture,
2606 ID3D11Texture2D* dest_texture,
2607 base::win::ScopedComPtr<IDXGIKeyedMutex> dest_keyed_mutex,
2608 uint64_t keyed_mutex_value,
2609 IMFSample* video_frame,
2610 int picture_buffer_id,
2611 int input_buffer_id) {
2612 HRESULT hr = E_FAIL;
2613
2614 DCHECK(use_dx11_);
2615
2616 if (!decoder_thread_task_runner_->BelongsToCurrentThread()) {
2617 // The media foundation H.264 decoder outputs YUV12 textures which we
2618 // cannot copy into ANGLE as they expect ARGB textures. In D3D land
2619 // the StretchRect API in the IDirect3DDevice9Ex interface did the color
2620 // space conversion for us. Sadly in DX11 land the API does not provide
2621 // a straightforward way to do this.
2622 // We use the video processor MFT.
2623 // https://msdn.microsoft.com/en-us/library/hh162913(v=vs.85).aspx
2624 // This object implements a media foundation transform (IMFTransform)
2625 // which follows the same contract as the decoder. The color space
2626 // conversion as per msdn is done in the GPU.
2627
2628 D3D11_TEXTURE2D_DESC source_desc;
2629 src_texture->GetDesc(&source_desc);
2630
2631 // Set up the input and output types for the video processor MFT.
2632 if (!InitializeDX11VideoFormatConverterMediaType(source_desc.Width,
2633 source_desc.Height)) {
2634 RETURN_AND_NOTIFY_ON_FAILURE(
2635 false, "Failed to initialize media types for convesion.",
2636 PLATFORM_FAILURE,);
2637 }
2638
2639 // The input to the video processor is the output sample.
2640 base::win::ScopedComPtr<IMFSample> input_sample_for_conversion;
2641 {
2642 base::AutoLock lock(decoder_lock_);
2643 PendingSampleInfo& sample_info = pending_output_samples_.front();
2644 input_sample_for_conversion = sample_info.output_sample;
2645 }
2646
2647 decoder_thread_task_runner_->PostTask(
2648 FROM_HERE, base::Bind(&DXVAVideoDecodeAccelerator::CopyTexture,
2649 base::Unretained(this), src_texture, dest_texture,
2650 dest_keyed_mutex, keyed_mutex_value,
2651 input_sample_for_conversion.Detach(),
2652 picture_buffer_id, input_buffer_id));
2653 return;
2654 }
2655
2656 DCHECK(video_frame);
2657
2658 base::win::ScopedComPtr<IMFSample> input_sample;
2659 input_sample.Attach(video_frame);
2660
2661 DCHECK(video_format_converter_mft_.get());
2662
2663 if (dest_keyed_mutex) {
2664 HRESULT hr =
2665 dest_keyed_mutex->AcquireSync(keyed_mutex_value, kAcquireSyncWaitMs);
2666 RETURN_AND_NOTIFY_ON_FAILURE(
2667 hr == S_OK, "D3D11 failed to acquire keyed mutex for texture.",
2668 PLATFORM_FAILURE, );
2669 }
2670 // The video processor MFT requires output samples to be allocated by the
2671 // caller. We create a sample with a buffer backed with the ID3D11Texture2D
2672 // interface exposed by ANGLE. This works nicely as this ensures that the
2673 // video processor coverts the color space of the output frame and copies
2674 // the result into the ANGLE texture.
2675 base::win::ScopedComPtr<IMFSample> output_sample;
2676 hr = MFCreateSample(output_sample.Receive());
2677 if (FAILED(hr)) {
2678 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2679 "Failed to create output sample.", PLATFORM_FAILURE,);
2680 }
2681
2682 base::win::ScopedComPtr<IMFMediaBuffer> output_buffer;
2683 hr = MFCreateDXGISurfaceBuffer(
2684 __uuidof(ID3D11Texture2D), dest_texture, 0, FALSE,
2685 output_buffer.Receive());
2686 if (FAILED(hr)) {
2687 base::debug::Alias(&hr);
2688 // TODO(ananta)
2689 // Remove this CHECK when the change to use DX11 for H/W decoding
2690 // stablizes.
2691 CHECK(false);
2692 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2693 "Failed to create output sample.", PLATFORM_FAILURE,);
2694 }
2695
2696 output_sample->AddBuffer(output_buffer.get());
2697
2698 hr = video_format_converter_mft_->ProcessInput(0, video_frame, 0);
2699 if (FAILED(hr)) {
2700 DCHECK(false);
2701 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2702 "Failed to convert output sample format.", PLATFORM_FAILURE,);
2703 }
2704
2705 DWORD status = 0;
2706 MFT_OUTPUT_DATA_BUFFER format_converter_output = {};
2707 format_converter_output.pSample = output_sample.get();
2708 hr = video_format_converter_mft_->ProcessOutput(
2709 0, // No flags
2710 1, // # of out streams to pull from
2711 &format_converter_output,
2712 &status);
2713
2714 if (FAILED(hr)) {
2715 base::debug::Alias(&hr);
2716 // TODO(ananta)
2717 // Remove this CHECK when the change to use DX11 for H/W decoding
2718 // stablizes.
2719 CHECK(false);
2720 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2721 "Failed to convert output sample format.", PLATFORM_FAILURE,);
2722 }
2723
2724 if (dest_keyed_mutex) {
2725 HRESULT hr = dest_keyed_mutex->ReleaseSync(keyed_mutex_value + 1);
2726 RETURN_AND_NOTIFY_ON_FAILURE(hr == S_OK, "Failed to release keyed mutex.",
2727 PLATFORM_FAILURE, );
2728
2729 main_thread_task_runner_->PostTask(
2730 FROM_HERE, base::Bind(&DXVAVideoDecodeAccelerator::CopySurfaceComplete,
2731 weak_this_factory_.GetWeakPtr(), nullptr, nullptr,
2732 picture_buffer_id, input_buffer_id));
2733 } else {
2734 d3d11_device_context_->Flush();
2735 d3d11_device_context_->End(d3d11_query_.get());
2736
2737 decoder_thread_task_runner_->PostDelayedTask(
2738 FROM_HERE, base::Bind(&DXVAVideoDecodeAccelerator::FlushDecoder,
2739 base::Unretained(this), 0,
2740 reinterpret_cast<IDirect3DSurface9*>(NULL),
2741 reinterpret_cast<IDirect3DSurface9*>(NULL),
2742 picture_buffer_id, input_buffer_id),
2743 base::TimeDelta::FromMilliseconds(kFlushDecoderSurfaceTimeoutMs));
2744 }
2745 }
2746
2747 void DXVAVideoDecodeAccelerator::FlushDecoder(
2748 int iterations,
2749 IDirect3DSurface9* src_surface,
2750 IDirect3DSurface9* dest_surface,
2751 int picture_buffer_id,
2752 int input_buffer_id) {
2753 DCHECK(decoder_thread_task_runner_->BelongsToCurrentThread());
2754
2755 // The DXVA decoder has its own device which it uses for decoding. ANGLE
2756 // has its own device which we don't have access to.
2757 // The above code attempts to copy the decoded picture into a surface
2758 // which is owned by ANGLE. As there are multiple devices involved in
2759 // this, the StretchRect call above is not synchronous.
2760 // We attempt to flush the batched operations to ensure that the picture is
2761 // copied to the surface owned by ANGLE.
2762 // We need to do this in a loop and call flush multiple times.
2763 // We have seen the GetData call for flushing the command buffer fail to
2764 // return success occassionally on multi core machines, leading to an
2765 // infinite loop.
2766 // Workaround is to have an upper limit of 4 on the number of iterations to
2767 // wait for the Flush to finish.
2768
2769 HRESULT hr = E_FAIL;
2770 if (use_dx11_) {
2771 BOOL query_data = 0;
2772 hr = d3d11_device_context_->GetData(d3d11_query_.get(), &query_data,
2773 sizeof(BOOL), 0);
2774 if (FAILED(hr)) {
2775 base::debug::Alias(&hr);
2776 // TODO(ananta)
2777 // Remove this CHECK when the change to use DX11 for H/W decoding
2778 // stablizes.
2779 CHECK(false);
2780 }
2781 } else {
2782 hr = query_->GetData(NULL, 0, D3DGETDATA_FLUSH);
2783 }
2784
2785 if ((hr == S_FALSE) && (++iterations < kMaxIterationsForD3DFlush)) {
2786 decoder_thread_task_runner_->PostDelayedTask(
2787 FROM_HERE,
2788 base::Bind(&DXVAVideoDecodeAccelerator::FlushDecoder,
2789 base::Unretained(this), iterations, src_surface,
2790 dest_surface, picture_buffer_id, input_buffer_id),
2791 base::TimeDelta::FromMilliseconds(kFlushDecoderSurfaceTimeoutMs));
2792 return;
2793 }
2794
2795 main_thread_task_runner_->PostTask(
2796 FROM_HERE,
2797 base::Bind(&DXVAVideoDecodeAccelerator::CopySurfaceComplete,
2798 weak_this_factory_.GetWeakPtr(),
2799 src_surface,
2800 dest_surface,
2801 picture_buffer_id,
2802 input_buffer_id));
2803 }
2804
2805 bool DXVAVideoDecodeAccelerator::InitializeDX11VideoFormatConverterMediaType(
2806 int width, int height) {
2807 if (!dx11_video_format_converter_media_type_needs_init_)
2808 return true;
2809
2810 CHECK(video_format_converter_mft_.get());
2811
2812 HRESULT hr = video_format_converter_mft_->ProcessMessage(
2813 MFT_MESSAGE_SET_D3D_MANAGER,
2814 reinterpret_cast<ULONG_PTR>(
2815 d3d11_device_manager_.get()));
2816
2817 if (FAILED(hr)) {
2818 base::debug::Alias(&hr);
2819 // TODO(ananta)
2820 // Remove this CHECK when the change to use DX11 for H/W decoding
2821 // stablizes.
2822 CHECK(false);
2823 }
2824 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr,
2825 "Failed to initialize video format converter", PLATFORM_FAILURE, false);
2826
2827 video_format_converter_mft_->ProcessMessage(
2828 MFT_MESSAGE_NOTIFY_END_STREAMING, 0);
2829
2830 base::win::ScopedComPtr<IMFMediaType> media_type;
2831 hr = MFCreateMediaType(media_type.Receive());
2832 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "MFCreateMediaType failed",
2833 PLATFORM_FAILURE, false);
2834
2835 hr = media_type->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video);
2836 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to set major input type",
2837 PLATFORM_FAILURE, false);
2838
2839 hr = media_type->SetGUID(MF_MT_SUBTYPE, MFVideoFormat_NV12);
2840 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to set input sub type",
2841 PLATFORM_FAILURE, false);
2842
2843 hr = MFSetAttributeSize(media_type.get(), MF_MT_FRAME_SIZE, width, height);
2844 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to set media type attributes",
2845 PLATFORM_FAILURE, false);
2846
2847 hr = video_format_converter_mft_->SetInputType(0, media_type.get(), 0);
2848 if (FAILED(hr)) {
2849 base::debug::Alias(&hr);
2850 // TODO(ananta)
2851 // Remove this CHECK when the change to use DX11 for H/W decoding
2852 // stablizes.
2853 CHECK(false);
2854 }
2855 RETURN_AND_NOTIFY_ON_HR_FAILURE(hr, "Failed to set converter input type",
2856 PLATFORM_FAILURE, false);
2857
2858 // It appears that we fail to set MFVideoFormat_ARGB32 as the output media
2859 // type in certain configurations. Try to fallback to MFVideoFormat_RGB32
2860 // in such cases. If both fail, then bail.
2861 bool media_type_set =
2862 SetTransformOutputType(video_format_converter_mft_.get(),
2863 MFVideoFormat_ARGB32,
2864 width,
2865 height);
2866 if (!media_type_set) {
2867 media_type_set =
2868 SetTransformOutputType(video_format_converter_mft_.get(),
2869 MFVideoFormat_RGB32,
2870 width,
2871 height);
2872 }
2873
2874 if (!media_type_set) {
2875 // Remove this once this stabilizes in the field.
2876 CHECK(false);
2877 LOG(ERROR) << "Failed to find a matching RGB output type in the converter";
2878 return false;
2879 }
2880
2881 dx11_video_format_converter_media_type_needs_init_ = false;
2882 return true;
2883 }
2884
2885 bool DXVAVideoDecodeAccelerator::GetVideoFrameDimensions(
2886 IMFSample* sample,
2887 int* width,
2888 int* height) {
2889 base::win::ScopedComPtr<IMFMediaBuffer> output_buffer;
2890 HRESULT hr = sample->GetBufferByIndex(0, output_buffer.Receive());
2891 RETURN_ON_HR_FAILURE(hr, "Failed to get buffer from output sample", false);
2892
2893 if (use_dx11_) {
2894 base::win::ScopedComPtr<IMFDXGIBuffer> dxgi_buffer;
2895 base::win::ScopedComPtr<ID3D11Texture2D> d3d11_texture;
2896 hr = dxgi_buffer.QueryFrom(output_buffer.get());
2897 RETURN_ON_HR_FAILURE(hr, "Failed to get DXGIBuffer from output sample",
2898 false);
2899 hr = dxgi_buffer->GetResource(
2900 __uuidof(ID3D11Texture2D),
2901 reinterpret_cast<void**>(d3d11_texture.Receive()));
2902 RETURN_ON_HR_FAILURE(hr, "Failed to get D3D11Texture from output buffer",
2903 false);
2904 D3D11_TEXTURE2D_DESC d3d11_texture_desc;
2905 d3d11_texture->GetDesc(&d3d11_texture_desc);
2906 *width = d3d11_texture_desc.Width;
2907 *height = d3d11_texture_desc.Height;
2908 } else {
2909 base::win::ScopedComPtr<IDirect3DSurface9> surface;
2910 hr = MFGetService(output_buffer.get(), MR_BUFFER_SERVICE,
2911 IID_PPV_ARGS(surface.Receive()));
2912 RETURN_ON_HR_FAILURE(hr, "Failed to get D3D surface from output sample",
2913 false);
2914 D3DSURFACE_DESC surface_desc;
2915 hr = surface->GetDesc(&surface_desc);
2916 RETURN_ON_HR_FAILURE(hr, "Failed to get surface description", false);
2917 *width = surface_desc.Width;
2918 *height = surface_desc.Height;
2919 }
2920 return true;
2921 }
2922
2923 bool DXVAVideoDecodeAccelerator::SetTransformOutputType(
2924 IMFTransform* transform,
2925 const GUID& output_type,
2926 int width,
2927 int height) {
2928 HRESULT hr = E_FAIL;
2929 base::win::ScopedComPtr<IMFMediaType> media_type;
2930
2931 for (uint32_t i = 0;
2932 SUCCEEDED(transform->GetOutputAvailableType(
2933 0, i, media_type.Receive()));
2934 ++i) {
2935 GUID out_subtype = {0};
2936 hr = media_type->GetGUID(MF_MT_SUBTYPE, &out_subtype);
2937 RETURN_ON_HR_FAILURE(hr, "Failed to get output major type", false);
2938
2939 if (out_subtype == output_type) {
2940 if (width && height) {
2941 hr = MFSetAttributeSize(media_type.get(), MF_MT_FRAME_SIZE, width,
2942 height);
2943 RETURN_ON_HR_FAILURE(hr, "Failed to set media type attributes", false);
2944 }
2945 hr = transform->SetOutputType(0, media_type.get(), 0); // No flags
2946 RETURN_ON_HR_FAILURE(hr, "Failed to set output type", false);
2947 return true;
2948 }
2949 media_type.Release();
2950 }
2951 return false;
2952 }
2953
2954 HRESULT DXVAVideoDecodeAccelerator::CheckConfigChanged(
2955 IMFSample* sample, bool* config_changed) {
2956 if (codec_ != media::kCodecH264)
2957 return S_FALSE;
2958
2959 base::win::ScopedComPtr<IMFMediaBuffer> buffer;
2960 HRESULT hr = sample->GetBufferByIndex(0, buffer.Receive());
2961 RETURN_ON_HR_FAILURE(hr, "Failed to get buffer from input sample", hr);
2962
2963 MediaBufferScopedPointer scoped_media_buffer(buffer.get());
2964
2965 if (!config_change_detector_->DetectConfig(
2966 scoped_media_buffer.get(),
2967 scoped_media_buffer.current_length())) {
2968 RETURN_ON_HR_FAILURE(E_FAIL, "Failed to detect H.264 stream config",
2969 E_FAIL);
2970 }
2971 *config_changed = config_change_detector_->config_changed();
2972 return S_OK;
2973 }
2974
2975 void DXVAVideoDecodeAccelerator::ConfigChanged(
2976 const Config& config) {
2977 DCHECK(main_thread_task_runner_->BelongsToCurrentThread());
2978
2979 SetState(kConfigChange);
2980 DismissStaleBuffers(true);
2981 Invalidate();
2982 Initialize(config_, client_);
2983 decoder_thread_task_runner_->PostTask(
2984 FROM_HERE,
2985 base::Bind(&DXVAVideoDecodeAccelerator::DecodePendingInputBuffers,
2986 base::Unretained(this)));
2987 }
2988
2989 } // namespace content
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