void CLocalBrowseWindowState::SetCurrentPath(const CStdString& path)
{
// Return current path under assumption that Local browse screen has only one source
SourcesMap mapSources = m_sourceController.GetSources();
if (CUtil::IsBlurayFolder(path))
UpdateHistory();
if (!mapSources.empty())
{
CBrowseWindowSource* firstSource = mapSources.begin()->second;
if (firstSource)
{
firstSource->SetBasePath(path);
}
else
{
CLog::Log(LOGWARNING, "CLocalBrowseWindowState::SetCurrentPath - first source is null (browse)");
}
}
else
{
CLog::Log(LOGWARNING, "CLocalBrowseWindowState::SetCurrentPath - no sources found (browse)");
}
}
void flipSources(SourcesMap & sources)
{
for (auto i = sources.begin(); i != sources.end(); ++i)
{
if (i->first.first != "image")
{
cout << "warning. nonimage source: \""
<< i->first.first << "\" : " << i->first.second
<< ". flipping operation may lead to an error."
<< endl;
}
Mat & image = i->second;
flip(image, image, 1);
}
}
CStdString CLocalBrowseWindowState::GetCurrentPath()
{
// Return current path under assumption that Local browse screen has only one source
SourcesMap mapSources = m_sourceController.GetSources();
if (!mapSources.empty())
{
CBrowseWindowSource* firstSource = mapSources.begin()->second;
if (firstSource)
{
return firstSource->GetBasePath();
}
else
{
CLog::Log(LOGWARNING, "CLocalBrowseWindowState::GetCurrentPath - first source is null (browse)");
}
}
else
{
CLog::Log(LOGWARNING, "CLocalBrowseWindowState::GetCurrentPath - no sources found (browse)");
}
return "";
}
ImageAnnotation getFlipedAnnotation(const ImageAnnotation & ann,
const SourcesMap & sources)
{
ImageAnnotation flipedAnn;
for (size_t i = 0; i < ann.bboxes.size(); ++i)
{
if (ann.labels[i] == 0)
{
continue;
}
flipedAnn.labels.push_back(ann.labels[i]);
flipedAnn.scores.push_back(ann.scores[i]);
Rect bbox = ann.bboxes[i];
Size imageSize = sources.at(DataTypeTime("image", 0)).size();
bbox.x = imageSize.width - bbox.x - bbox.width;
flipedAnn.bboxes.push_back(bbox);
}
return flipedAnn;
}
void HOF::getROIDescription(Mat & featureDescription,
const SourcesMap & sources,
const vector<Rect> & roi)
{
bool hasOpticalFlowAsSource = (0 < sources.count(SOURCE_OPTICAL_FLOW));
bool hasImagesPairAsSource = (0 < sources.count(SOURCE_FIRST_IMAGE) &&
0 < sources.count(SOURCE_SECOND_IMAGE));
CV_Assert(hasImagesPairAsSource || hasOpticalFlowAsSource);
Mat opticalFlow;
if (hasOpticalFlowAsSource)
{
opticalFlow = sources.at(SOURCE_OPTICAL_FLOW);
}
else // if (hasImagesPairAsSource)
{
Mat image1, image2;
cvtColor(sources.at(SOURCE_FIRST_IMAGE), image1, CV_BGR2GRAY);
cvtColor(sources.at(SOURCE_SECOND_IMAGE), image2, CV_BGR2GRAY);
opticalFlowComputer->calc(image1, image2, opticalFlow);
}
featureDescription.create(roi.size(), featureVectorLength, CV_32F);
for (size_t t = 0; t < roi.size(); ++t)
{
const Rect & r = roi[t];
CV_Assert(0 < r.width);
CV_Assert(0 < r.height);
Mat opticalFlowROI;
getROI(opticalFlow, opticalFlowROI, r);
resize(opticalFlowROI, opticalFlowROI,
Size(params.winSizeW, params.winSizeH));
SourcesMap imageSource;
imageSource[SOURCE_OPTICAL_FLOW] = opticalFlowROI;
computeOnNewImage(imageSource);
computeOnNewScale(1.0f);
Mat featureDescriptionRow = featureDescription.row(t);
getFeatureVector(0, 0, featureDescriptionRow);
}
}
void HOF::computeOnNewImage(const SourcesMap & sources)
{
bool hasOpticalFlowAsSource = (0 < sources.count(SOURCE_OPTICAL_FLOW));
bool hasImagesPairAsSource = (0 < sources.count(SOURCE_FIRST_IMAGE) &&
0 < sources.count(SOURCE_SECOND_IMAGE));
CV_Assert(hasOpticalFlowAsSource || hasImagesPairAsSource);
if (hasOpticalFlowAsSource)
{
sources.at(SOURCE_OPTICAL_FLOW).copyTo(flow);
}
else if (hasImagesPairAsSource)
{
Mat firstImage;
cvtColor(sources.at(SOURCE_FIRST_IMAGE), firstImage, CV_BGR2GRAY);
cvtColor(sources.at(SOURCE_SECOND_IMAGE), secondImage, CV_BGR2GRAY);
CV_Assert(firstImage.size == secondImage.size);
opticalFlowComputer->calc(firstImage, secondImage, flow);
}
}
