/* * Copyright (c) 2012 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "modules/video_capture/video_capture_impl.h" #include #include #include "api/video/i420_buffer.h" #include "api/video/video_frame_buffer.h" #include "common_video/libyuv/include/webrtc_libyuv.h" #include "modules/video_capture/video_capture_config.h" #include "rtc_base/logging.h" #include "rtc_base/ref_counted_object.h" #include "rtc_base/time_utils.h" #include "rtc_base/trace_event.h" #include "third_party/libyuv/include/libyuv.h" namespace webrtc { namespace videocapturemodule { const char* VideoCaptureImpl::CurrentDeviceName() const { return _deviceUniqueId; } // static int32_t VideoCaptureImpl::RotationFromDegrees(int degrees, VideoRotation* rotation) { switch (degrees) { case 0: *rotation = kVideoRotation_0; return 0; case 90: *rotation = kVideoRotation_90; return 0; case 180: *rotation = kVideoRotation_180; return 0; case 270: *rotation = kVideoRotation_270; return 0; default: return -1; ; } } // static int32_t VideoCaptureImpl::RotationInDegrees(VideoRotation rotation, int* degrees) { switch (rotation) { case kVideoRotation_0: *degrees = 0; return 0; case kVideoRotation_90: *degrees = 90; return 0; case kVideoRotation_180: *degrees = 180; return 0; case kVideoRotation_270: *degrees = 270; return 0; } return -1; } VideoCaptureImpl::VideoCaptureImpl() : _deviceUniqueId(NULL), _requestedCapability(), _lastProcessTimeNanos(rtc::TimeNanos()), _lastFrameRateCallbackTimeNanos(rtc::TimeNanos()), _dataCallBack(NULL), _lastProcessFrameTimeNanos(rtc::TimeNanos()), _rotateFrame(kVideoRotation_0), apply_rotation_(false) { _requestedCapability.width = kDefaultWidth; _requestedCapability.height = kDefaultHeight; _requestedCapability.maxFPS = 30; _requestedCapability.videoType = VideoType::kI420; memset(_incomingFrameTimesNanos, 0, sizeof(_incomingFrameTimesNanos)); } VideoCaptureImpl::~VideoCaptureImpl() { DeRegisterCaptureDataCallback(); if (_deviceUniqueId) delete[] _deviceUniqueId; } void VideoCaptureImpl::RegisterCaptureDataCallback( rtc::VideoSinkInterface* dataCallBack) { MutexLock lock(&api_lock_); _dataCallBack = dataCallBack; } void VideoCaptureImpl::DeRegisterCaptureDataCallback() { MutexLock lock(&api_lock_); _dataCallBack = NULL; } int32_t VideoCaptureImpl::DeliverCapturedFrame(VideoFrame& captureFrame) { UpdateFrameCount(); // frame count used for local frame rate callback. if (_dataCallBack) { _dataCallBack->OnFrame(captureFrame); } return 0; } int32_t VideoCaptureImpl::IncomingFrame(uint8_t* videoFrame, size_t videoFrameLength, const VideoCaptureCapability& frameInfo, int64_t captureTime /*=0*/) { MutexLock lock(&api_lock_); const int32_t width = frameInfo.width; const int32_t height = frameInfo.height; TRACE_EVENT1("webrtc", "VC::IncomingFrame", "capture_time", captureTime); // Not encoded, convert to I420. if (frameInfo.videoType != VideoType::kMJPEG && CalcBufferSize(frameInfo.videoType, width, abs(height)) != videoFrameLength) { RTC_LOG(LS_ERROR) << "Wrong incoming frame length."; return -1; } int stride_y = width; int stride_uv = (width + 1) / 2; int target_width = width; int target_height = abs(height); // SetApplyRotation doesn't take any lock. Make a local copy here. bool apply_rotation = apply_rotation_; if (apply_rotation) { // Rotating resolution when for 90/270 degree rotations. if (_rotateFrame == kVideoRotation_90 || _rotateFrame == kVideoRotation_270) { target_width = abs(height); target_height = width; } } // Setting absolute height (in case it was negative). // In Windows, the image starts bottom left, instead of top left. // Setting a negative source height, inverts the image (within LibYuv). // TODO(nisse): Use a pool? rtc::scoped_refptr buffer = I420Buffer::Create( target_width, target_height, stride_y, stride_uv, stride_uv); libyuv::RotationMode rotation_mode = libyuv::kRotate0; if (apply_rotation) { switch (_rotateFrame) { case kVideoRotation_0: rotation_mode = libyuv::kRotate0; break; case kVideoRotation_90: rotation_mode = libyuv::kRotate90; break; case kVideoRotation_180: rotation_mode = libyuv::kRotate180; break; case kVideoRotation_270: rotation_mode = libyuv::kRotate270; break; } } const int conversionResult = libyuv::ConvertToI420( videoFrame, videoFrameLength, buffer.get()->MutableDataY(), buffer.get()->StrideY(), buffer.get()->MutableDataU(), buffer.get()->StrideU(), buffer.get()->MutableDataV(), buffer.get()->StrideV(), 0, 0, // No Cropping width, height, target_width, target_height, rotation_mode, ConvertVideoType(frameInfo.videoType)); if (conversionResult < 0) { RTC_LOG(LS_ERROR) << "Failed to convert capture frame from type " << static_cast(frameInfo.videoType) << "to I420."; return -1; } VideoFrame captureFrame = VideoFrame::Builder() .set_video_frame_buffer(buffer) .set_timestamp_rtp(0) .set_timestamp_ms(rtc::TimeMillis()) .set_rotation(!apply_rotation ? _rotateFrame : kVideoRotation_0) .build(); captureFrame.set_ntp_time_ms(captureTime); DeliverCapturedFrame(captureFrame); return 0; } int32_t VideoCaptureImpl::StartCapture( const VideoCaptureCapability& capability) { _requestedCapability = capability; return -1; } int32_t VideoCaptureImpl::StopCapture() { return -1; } bool VideoCaptureImpl::CaptureStarted() { return false; } int32_t VideoCaptureImpl::CaptureSettings( VideoCaptureCapability& /*settings*/) { return -1; } int32_t VideoCaptureImpl::SetCaptureRotation(VideoRotation rotation) { MutexLock lock(&api_lock_); _rotateFrame = rotation; return 0; } bool VideoCaptureImpl::SetApplyRotation(bool enable) { // We can't take any lock here as it'll cause deadlock with IncomingFrame. // The effect of this is the last caller wins. apply_rotation_ = enable; return true; } bool VideoCaptureImpl::GetApplyRotation() { return apply_rotation_; } void VideoCaptureImpl::UpdateFrameCount() { if (_incomingFrameTimesNanos[0] / rtc::kNumNanosecsPerMicrosec == 0) { // first no shift } else { // shift for (int i = (kFrameRateCountHistorySize - 2); i >= 0; --i) { _incomingFrameTimesNanos[i + 1] = _incomingFrameTimesNanos[i]; } } _incomingFrameTimesNanos[0] = rtc::TimeNanos(); } uint32_t VideoCaptureImpl::CalculateFrameRate(int64_t now_ns) { int32_t num = 0; int32_t nrOfFrames = 0; for (num = 1; num < (kFrameRateCountHistorySize - 1); ++num) { if (_incomingFrameTimesNanos[num] <= 0 || (now_ns - _incomingFrameTimesNanos[num]) / rtc::kNumNanosecsPerMillisec > kFrameRateHistoryWindowMs) { // don't use data older than 2sec break; } else { nrOfFrames++; } } if (num > 1) { int64_t diff = (now_ns - _incomingFrameTimesNanos[num - 1]) / rtc::kNumNanosecsPerMillisec; if (diff > 0) { return uint32_t((nrOfFrames * 1000.0f / diff) + 0.5f); } } return nrOfFrames; } } // namespace videocapturemodule } // namespace webrtc