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Move source files to src directory

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This commit is contained in:
Dušan Poizl
2025-05-30 16:45:35 +02:00
parent ce67b35bfa
commit a0422683bd
64 changed files with 90 additions and 41 deletions
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src/loadrunable.cpp
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#include "loadrunable.h"
#include "imageringlist.h"
#include <QFileInfo>
#include <QPainter>
#include <QElapsedTimer>
#include <QDebug>
#include <algorithm>
#include <fitsio2.h>
#include "rawimage.h"
#include "loadimage.h"
#include <lcms2.h>
LoadRunable::LoadRunable(const QString &file, Image *receiver, AnalyzeLevel level, int index, bool thumbnail) :
m_file(makeUNCPath(file)),
m_receiver(receiver),
m_analyzeLevel(level),
m_thumbnail(thumbnail),
m_index(index)
{
}
void LoadRunable::run()
{
try
{
if(!m_thumbnail && !m_receiver->isCurrent())
{
return;
}
QElapsedTimer timer;
ImageInfoData info;
QFileInfo finfo(m_file);
info.info.append({QObject::tr("Filename"), finfo.fileName()});
std::shared_ptr<RawImage> rawImage;
if(!loadImage(m_file, info, rawImage, m_index))
info.info.append({QObject::tr("Error"), QObject::tr("Failed to load image")});
if(rawImage && !m_thumbnail)
{
rawImage->convertToGLFormat();
timer.start();
rawImage->generateLUT();
qDebug() << "generate LUT" << timer.restart();
//rawImage->convertTosRGB();
//qDebug() << "convert" << timer.restart();
rawImage->calcStats();
const RawImage::Stats &stats = rawImage->imageStats();
qDebug() << "image stats" << timer.restart();
if(rawImage->channels() == 1)
{
info.info.append({QObject::tr("Mean"), QString::number(stats.m_mean[0])});
info.info.append({QObject::tr("Standart deviation"), QString::number(stats.m_stdDev[0])});
info.info.append({QObject::tr("Median"), QString::number(stats.m_median[0])});
info.info.append({QObject::tr("Minimum"), QString::number(stats.m_min[0])});
info.info.append({QObject::tr("Maximum"), QString::number(stats.m_max[0])});
info.info.append({QObject::tr("MAD"), QString::number(stats.m_mad[0])});
info.info.append({QObject::tr("Saturated"), QString::number(100.0 * stats.m_saturated[0] / rawImage->size()) + "%"});
}
else
{
info.info.append({QObject::tr("Mean"), QString("%1 %2 %3").arg(stats.m_mean[0]).arg(stats.m_mean[1]).arg(stats.m_mean[2])});
info.info.append({QObject::tr("Standart deviation"), QString("%1 %2 %3").arg(stats.m_stdDev[0]).arg(stats.m_stdDev[1]).arg(stats.m_stdDev[2])});
info.info.append({QObject::tr("Median"), QString("%1 %2 %3").arg(stats.m_median[0]).arg(stats.m_median[1]).arg(stats.m_median[2])});
info.info.append({QObject::tr("Minimum"), QString("%1 %2 %3").arg(stats.m_min[0]).arg(stats.m_min[1]).arg(stats.m_min[2])});
info.info.append({QObject::tr("Maximum"), QString("%1 %2 %3").arg(stats.m_max[0]).arg(stats.m_max[1]).arg(stats.m_max[2])});
info.info.append({QObject::tr("MAD"), QString("%1 %2 %3").arg(stats.m_mad[0]).arg(stats.m_mad[1]).arg(stats.m_mad[2])});
info.info.append({QObject::tr("Saturated"), QString("%1 %2 %3%").arg(100.0 * stats.m_saturated[0] / rawImage->size())
.arg(100.0 * stats.m_saturated[1] / rawImage->size())
.arg(100.0 * stats.m_saturated[2] / rawImage->size())});
}
}
if(m_thumbnail)
{
if(rawImage && rawImage->valid())
{
if(QUALITY_RESIZE)
rawImage->resize(THUMB_SIZE, THUMB_SIZE);
rawImage->convertToGLFormat();
rawImage->convertToThumbnail();
}
QMetaObject::invokeMethod(m_receiver, "thumbnailLoadFinish", Qt::QueuedConnection, Q_ARG(std::shared_ptr<RawImage>, rawImage));
}
else
{
QMetaObject::invokeMethod(m_receiver, "imageLoaded", Qt::QueuedConnection, Q_ARG(std::shared_ptr<RawImage>, rawImage), Q_ARG(ImageInfoData, info));
}
}
catch(std::exception e)
{
qDebug() << m_file << e.what();
std::shared_ptr<RawImage> rawImage;
if(m_thumbnail)
QMetaObject::invokeMethod(m_receiver, "thumbnailLoadFinish", Qt::QueuedConnection, Q_ARG(std::shared_ptr<RawImage>, rawImage));
else
QMetaObject::invokeMethod(m_receiver, "imageLoaded", Qt::QueuedConnection, Q_ARG(std::shared_ptr<RawImage>, rawImage), Q_ARG(ImageInfoData, ImageInfoData()));
}
}
ConvertRunable::ConvertRunable(const QString &in, const QString &out, const QString &format, const ConvertParams &params, QSemaphore *semaphore) :
m_infile(makeUNCPath(in)),
m_outfile(makeUNCPath(out)),
m_format(format),
m_params(params),
m_semaphore(semaphore)
{
}
void writeFITSImage(fitsfile *fw, std::shared_ptr<RawImage> rawimage, ImageInfoData &imageinfo)
{
static QStringList skipKeys = {"SIMPLE", "BITPIX", "NAXIS", "NAXIS1", "NAXIS2", "NAXIS3", "BZERO", "BSCALE", "EXTEND"};
int status = 0;
long firstpix[3] = {1,1,1};
int channels = rawimage->channels();
int naxis = channels == 1 ? 2 : 3;
long naxes[3] = {(int)rawimage->width(), (int)rawimage->height(), rawimage->channels()};
std::vector<RawImage> planes;
if(channels == 1)
planes.push_back(*rawimage);
else
planes = rawimage->split();
switch(rawimage->type())
{
case RawImage::UINT8:
fits_create_img(fw, BYTE_IMG, naxis, naxes, &status);
for(int i=0; i<channels; i++)
{
firstpix[2] = i+1;
fits_write_pix(fw, TBYTE, firstpix, rawimage->size(), planes[i].data(), &status);
}
break;
case RawImage::UINT16:
fits_create_img(fw, USHORT_IMG, naxis, naxes, &status);
for(int i=0; i<channels; i++)
{
firstpix[2] = i+1;
fits_write_pix(fw, TUSHORT, firstpix, rawimage->size(), planes[i].data(), &status);
}
break;
case RawImage::FLOAT32:
fits_create_img(fw, FLOAT_IMG, naxis, naxes, &status);
for(int i=0; i<channels; i++)
{
firstpix[2] = i+1;
fits_write_pix(fw, TFLOAT, firstpix, rawimage->size(), planes[i].data(), &status);
}
break;
default:
return;
}
for(const FITSRecord &record : imageinfo.fitsHeader)
{
if(skipKeys.contains(record.key) || record.xisf)continue;
bool isdouble;
bool isint;
bool isbool = record.value.toString() == "T" || record.value.toString() == "F";
double vald = record.value.toDouble(&isdouble);
int valb = record.value.toString() == "T";
long long vall = record.value.toLongLong(&isint);
if(isint)isint = vall == vald;
QByteArray str = record.value.toString().toLatin1();
if(isint)
fits_write_key(fw, TLONGLONG, record.key.data(), &vall, record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
else if(isdouble)
fits_write_key(fw, TDOUBLE, record.key.data(), &vald, record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
else if(isbool)
fits_write_key(fw, TLOGICAL, record.key.data(), &valb, record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
else if(record.key == "COMMENT")
fits_write_comment(fw, record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
else if(record.key == "HISTORY")
fits_write_history(fw, record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
else
fits_write_key(fw, TSTRING, record.key.data(), str.isEmpty() ? nullptr : str.data(), record.comment.isEmpty() ? nullptr : record.comment.data(), &status);
}
}
void ConvertRunable::run()
{
QSemaphoreReleaser release;
if(m_semaphore)release = QSemaphoreReleaser(m_semaphore);
ImageInfoData imageinfo;
std::shared_ptr<RawImage> rawimage;
loadImage(m_infile, imageinfo, rawimage, 0);
QFileInfo info(m_outfile);
info.dir().mkpath(".");
if(m_params.autostretch)
{
rawimage->calcStats();
MTFParam mtfParam = rawimage->calcMTFParams();
rawimage->applySTF(mtfParam);
}
if(m_params.binning > 1)
{
rawimage->resizeInt(m_params.binning, m_params.average);
}
if(m_params.resize.isValid() && !m_params.resize.isEmpty())
{
QSize imgSize(rawimage->width(), rawimage->height());
imgSize = imgSize.scaled(m_params.resize, m_params.aspect);
rawimage->resize(imgSize.width(), imgSize.height());
}
if(rawimage)
{
if(m_format == "xisf")
{
try
{
LibXISF::XISFWriter xisf;
int channelCount = rawimage->channels();
LibXISF::Image::SampleFormat sampleFormat;
switch(rawimage->type())
{
case RawImage::UINT8: sampleFormat = LibXISF::Image::UInt8; break;
case RawImage::UINT16: sampleFormat = LibXISF::Image::UInt16; break;
case RawImage::FLOAT32: sampleFormat = LibXISF::Image::Float32; break;
default: return;
}
LibXISF::Image image(rawimage->width(), rawimage->height(), channelCount, sampleFormat, channelCount == 1 ? LibXISF::Image::Gray : LibXISF::Image::RGB, LibXISF::Image::Planar);
if(channelCount == 1)
{
std::memcpy(image.imageData(), rawimage->data(), image.imageDataSize());
}
else
{
size_t off = 0;
std::vector<RawImage> planes = rawimage->split();
for(const auto &plane : planes)
{
std::memcpy(image.imageData<uint8_t>() + off, plane.data(), plane.size() * RawImage::typeSize(plane.type()));
off += plane.size() * RawImage::typeSize(plane.type());
}
}
for(auto &record : imageinfo.fitsHeader)
{
if(record.xisf)continue;
if(record.value.typeId() == QMetaType::Bool)
image.addFITSKeyword({record.key.toStdString(), record.value.toBool() ? "T" : "F", record.comment.toStdString()});
else
image.addFITSKeyword({record.key.toStdString(), record.value.toString().toStdString(), record.comment.toStdString()});
}
if(m_params.compressionType.startsWith("zstd") && LibXISF::DataBlock::CompressionCodecSupported(LibXISF::DataBlock::ZSTD))
image.setCompression(LibXISF::DataBlock::ZSTD, m_params.compressionLevel);
else if(m_params.compressionType.startsWith("lz4hc"))
image.setCompression(LibXISF::DataBlock::LZ4HC, m_params.compressionLevel);
else if(m_params.compressionType.startsWith("lz4"))
image.setCompression(LibXISF::DataBlock::LZ4, m_params.compressionLevel);
else if(m_params.compressionType.startsWith("zlib"))
image.setCompression(LibXISF::DataBlock::Zlib, m_params.compressionLevel);
if(m_params.compressionType.endsWith("+sh"))
image.setByteshuffling(true);
xisf.writeImage(image);
xisf.save(m_outfile.toLocal8Bit().data());
}
catch(LibXISF::Error &err)
{
qDebug() << "Failed to save XISF image" << err.what();
}
return;
}
if(m_format == "fits")
{
int status = 0;
fitsfile *fw;
if(QFileInfo(m_outfile).exists())QFile::remove(m_outfile);
fits_create_diskfile(&fw, m_outfile.toLocal8Bit().data(), &status);
if(!m_params.compressionType.isEmpty())
{
if(m_params.compressionType == "gzip")
fits_set_compression_type(fw, GZIP_1, &status);
else if(m_params.compressionType == "rice")
fits_set_compression_type(fw, RICE_1, &status);
}
writeFITSImage(fw, rawimage, imageinfo);
fits_close_file(fw, &status);
return;
}
// if nothing else try QImage
{
QImage::Format format = QImage::Format_Invalid;
switch(rawimage->type())
{
case RawImage::UINT8:
if(rawimage->channels() == 1)format = QImage::Format_Grayscale8;
else if(rawimage->channels() == 3)format = QImage::Format_RGBX8888;
else if(rawimage->channels() == 4)format = QImage::Format_RGBA8888;
break;
case RawImage::UINT16:
if(rawimage->channels() == 1)format = QImage::Format_Grayscale16;
else if(rawimage->channels() == 3)format = QImage::Format_RGBX64;
else if(rawimage->channels() == 4)format = QImage::Format_RGBA64;
break;
case RawImage::FLOAT16:
case RawImage::FLOAT32:
case RawImage::FLOAT64:
case RawImage::UINT32:
rawimage->convertToType(RawImage::UINT16);
if(rawimage->channels() == 1)format = QImage::Format_Grayscale16;
else if(rawimage->channels() == 3)format = QImage::Format_RGBX64;
else if(rawimage->channels() == 4)format = QImage::Format_RGBA64;
break;
}
if(format == QImage::Format_Invalid)return;
QImage qimage((const uchar*)rawimage->data(), rawimage->width(), rawimage->height(), rawimage->widthBytes(), format);
qimage.save(m_outfile);
}
}
}
ConvertRunable::ConvertParams::ConvertParams(const QVariantMap &map)
{
bool ok = false;
if(map.contains("compressionLevel"))
compressionLevel = std::clamp(map["compressionLevel"].toInt(&ok), -1, 100);
if(!ok)compressionLevel = -1;
if(map.contains("compressionType"))
compressionType = map["compressionType"].toString();
if(map.contains("binning"))
binning = map["binning"].toInt();
if(map.contains("average"))
average = map["average"].toBool();
if(map.contains("resize"))
{
QVariantMap size = map["resize"].toMap();
if(size.contains("width") && size.contains("height"))
{
int w = size["width"].toInt();
int h = size["height"].toInt();
resize = QSize(w, h);
}
if(size.contains("aspect"))
{
QString aspectStr = map["aspect"].toString();
if(aspectStr == "keep")
aspect = Qt::KeepAspectRatio;
else if(aspectStr == "expand")
aspect = Qt::KeepAspectRatioByExpanding;
else if(aspectStr == "ignore")
aspect = Qt::IgnoreAspectRatio;
}
}
if(map.contains("autostretch"))
autostretch = map["autostretch"].toBool();
}