diff --git a/kstars/CMakeLists.txt b/kstars/CMakeLists.txt index e42bc2281..8137f1bef 100644 --- a/kstars/CMakeLists.txt +++ b/kstars/CMakeLists.txt @@ -1,1193 +1,1194 @@ add_subdirectory( data ) add_subdirectory( icons ) add_subdirectory( htmesh ) if (${KF5_VERSION} VERSION_EQUAL 5.18.0 OR ${KF5_VERSION} VERSION_GREATER 5.18.0) SET(HAVE_KF5WIT 1) # if(NOT BUILD_KSTARS_LITE) # add_subdirectory( tools/whatsinteresting/qml) # endif(NOT BUILD_KSTARS_LITE) else() SET(HAVE_KF5WIT 0) endif() if (ANDROID AND CMAKE_TOOLCHAIN_FILE) include(${CMAKE_TOOLCHAIN_FILE}) endif () if (NOT ANDROID) find_package(ZLIB REQUIRED) find_package(Threads REQUIRED) endif () if(MSVC) add_definitions(-D_USE_MATH_DEFINES=1) add_definitions(-DNOMINMAX) endif() include_directories( ${kstars_SOURCE_DIR}/kstars ${kstars_SOURCE_DIR}/kstars/skyobjects ${kstars_SOURCE_DIR}/kstars/skycomponents ${kstars_SOURCE_DIR}/kstars/auxiliary ${kstars_SOURCE_DIR}/kstars/time ${kstars_SOURCE_DIR}/kstars/tools ) if (INDI_FOUND) if(BUILD_KSTARS_LITE) set (fits_klite_SRCS fitsviewer/fitsdata.cpp ) set (fits2_klite_SRCS fitsviewer/bayer.c fitsviewer/fpack.c fitsviewer/fpackutil.c ) include_directories(${CFITSIO_INCLUDE_DIR}) include_directories(${NOVA_INCLUDE_DIR}) set (indi_klite_SRCS indi/clientmanagerlite.cpp indi/inditelescopelite.cpp kstarslite/skyitems/skynodes/crosshairnode.cpp kstarslite/skyitems/telescopesymbolsitem.cpp ) endif () set(indiui_SRCS indi/streamform.ui indi/drivermanager.ui indi/opsindi.ui indi/indihostconf.ui indi/customdrivers.ui #indi/telescopewizard.ui ) set(indi_SRCS indi/drivermanager.cpp indi/servermanager.cpp indi/clientmanager.cpp indi/blobmanager.cpp indi/guimanager.cpp indi/driverinfo.cpp indi/deviceinfo.cpp indi/indidevice.cpp indi/indigroup.cpp indi/indiproperty.cpp indi/indielement.cpp indi/indistd.cpp indi/indilistener.cpp indi/inditelescope.cpp indi/indiccd.cpp indi/wsmedia.cpp indi/indifocuser.cpp indi/indifilter.cpp indi/indidome.cpp indi/indiweather.cpp indi/indicap.cpp indi/indilightbox.cpp indi/indidbus.cpp indi/opsindi.cpp #indi/telescopewizardprocess.cpp indi/streamwg.cpp indi/videowg.cpp indi/indiwebmanager.cpp indi/customdrivers.cpp ) if (CFITSIO_FOUND) set(ekosui_SRCS ekos/opsekos.ui ekos/manager.ui ekos/profileeditor.ui ekos/profilewizard.ui # Scheduler ekos/scheduler/scheduler.ui ekos/scheduler/mosaic.ui # Capture ekos/capture/capture.ui ekos/capture/calibrationoptions.ui ekos/capture/dslrinfo.ui ekos/capture/rotatorsettings.ui ekos/capture/customproperties.ui # Align ekos/align/align.ui ekos/align/opsastrometry.ui ekos/align/opsalign.ui ekos/align/opsastrometrycfg.ui ekos/align/opsastrometryindexfiles.ui ekos/align/mountmodel.ui + ekos/align/opsastap.ui # Focus ekos/focus/focus.ui # Mount ekos/mount/mount.ui # Guide ekos/guide/guide.ui ekos/guide/opscalibration.ui ekos/guide/opsguide.ui ekos/guide/manualdither.ui ekos/observatory/observatory.ui #TODO remove from GIT #ekos/guide/guider.ui #ekos/guide/rcalibration.ui # Auxiliary ekos/auxiliary/filtersettings.ui ekos/auxiliary/opslogs.ui ekos/auxiliary/serialportassistant.ui # Ekos Live ekos/ekoslive/ekoslivedialog.ui ) set(ekos_SRCS ekos/ekos.cpp ekos/manager.cpp ekos/profileeditor.cpp ekos/profilewizard.cpp ekos/qMDNS.cpp ekos/opsekos.cpp # Auxiliary ekos/auxiliary/dome.cpp ekos/auxiliary/weather.cpp ekos/auxiliary/dustcap.cpp ekos/auxiliary/darklibrary.cpp ekos/auxiliary/filtermanager.cpp ekos/auxiliary/filterdelegate.cpp ekos/auxiliary/opslogs.cpp ekos/auxiliary/serialportassistant.cpp # Capture ekos/capture/capture.cpp ekos/capture/sequencejob.cpp ekos/capture/dslrinfodialog.cpp ekos/capture/rotatorsettings.cpp ekos/capture/customproperties.cpp # Scheduler ekos/scheduler/schedulerjob.cpp ekos/scheduler/scheduler.cpp ekos/scheduler/mosaic.cpp # Focus ekos/focus/focus.cpp # Mount ekos/mount/mount.cpp # Align ekos/align/align.cpp ekos/align/alignview.cpp ekos/align/astrometryparser.cpp ekos/align/opsastrometry.cpp ekos/align/opsalign.cpp ekos/align/opsastrometrycfg.cpp ekos/align/opsastrometryindexfiles.cpp ekos/align/offlineastrometryparser.cpp ekos/align/onlineastrometryparser.cpp ekos/align/remoteastrometryparser.cpp # Guide ekos/guide/guide.cpp ekos/guide/guideinterface.cpp ekos/guide/opscalibration.cpp ekos/guide/opsguide.cpp # Internal Guide ekos/guide/internalguide/gmath.cpp ekos/guide/internalguide/internalguider.cpp #ekos/guide/internalguide/guider.cpp ekos/guide/internalguide/matr.cpp #ekos/guide/internalguide/rcalibration.cpp ekos/guide/internalguide/vect.cpp ekos/guide/internalguide/imageautoguiding.cpp # External Guide ekos/guide/externalguide/phd2.cpp ekos/guide/externalguide/linguider.cpp #Observatory ekos/observatory/observatory.cpp ekos/observatory/observatorymodel.cpp ekos/observatory/observatorydomemodel.cpp ekos/observatory/observatoryweathermodel.cpp # Ekos Live ekos/ekoslive/ekosliveclient.cpp ekos/ekoslive/message.cpp ekos/ekoslive/media.cpp ekos/ekoslive/cloud.cpp ) endif(CFITSIO_FOUND) include_directories(${INDI_INCLUDE_DIR}) endif (INDI_FOUND) if (CFITSIO_FOUND) set (sep_SRCS fitsviewer/sep/analyse.c fitsviewer/sep/aperture.c fitsviewer/sep/background.c fitsviewer/sep/convolve.c fitsviewer/sep/deblend.c fitsviewer/sep/extract.c fitsviewer/sep/lutz.c fitsviewer/sep/util.c ) set (fits_SRCS fitsviewer/fitslabel.cpp fitsviewer/fitsviewer.cpp fitsviewer/fitstab.cpp fitsviewer/fitsdebayer.cpp fitsviewer/opsfits.cpp ) if (Qt5DataVisualization_FOUND) set(fits_SRCS ${fits_SRCS} fitsviewer/starprofileviewer.cpp) endif() set (fits2_SRCS fitsviewer/bayer.c fitsviewer/fpack.c fitsviewer/fpackutil.c fitsviewer/fitshistogram.cpp fitsviewer/fitsview.cpp fitsviewer/fitsdata.cpp ) set (fitsui_SRCS fitsviewer/fitsheaderdialog.ui fitsviewer/statform.ui fitsviewer/fitsdebayer.ui indi/streamform.ui indi/recordingoptions.ui fitsviewer/fitshistogramui.ui fitsviewer/opsfits.ui ) include_directories(${CFITSIO_INCLUDE_DIR}) endif(CFITSIO_FOUND) IF (CFITSIO_FOUND) IF (("${CMAKE_CXX_COMPILER_ID}" STREQUAL "AppleClang" OR "${CMAKE_CXX_COMPILER_ID}" STREQUAL "Clang")) IF (SANITIZERS) SET_SOURCE_FILES_PROPERTIES(fitsviewer/bayer.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align -fno-sanitize=address,undefined -fomit-frame-pointer") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fitsdata.cpp PROPERTIES COMPILE_FLAGS "-fno-sanitize=address,undefined -fomit-frame-pointer") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fitshistogram.cpp PROPERTIES COMPILE_FLAGS "-fno-sanitize=address,undefined -fomit-frame-pointer") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fitsview.cpp PROPERTIES COMPILE_FLAGS "-fno-sanitize=address,undefined -fomit-frame-pointer") ELSE () SET_SOURCE_FILES_PROPERTIES(fitsviewer/bayer.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align") ENDIF () SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/analyse.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/aperture.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align -Wno-pointer-arith") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/background.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/deblend.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align -Wno-incompatible-pointer-types-discards-qualifiers") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/extract.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/lutz.c PROPERTIES COMPILE_FLAGS "-Wno-cast-align") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/util.c PROPERTIES COMPILE_FLAGS "-Wno-incompatible-pointer-types-discards-qualifiers") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fpack.c PROPERTIES COMPILE_FLAGS "-Wno-error") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fpackutil.c PROPERTIES COMPILE_FLAGS "-Wno-error") ELSEIF (NOT WIN32) SET_SOURCE_FILES_PROPERTIES(fitsviewer/fpack.c PROPERTIES COMPILE_FLAGS "-Wno-error") SET_SOURCE_FILES_PROPERTIES(fitsviewer/fpackutil.c PROPERTIES COMPILE_FLAGS "-Wno-error") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/aperture.c PROPERTIES COMPILE_FLAGS "-Wno-pointer-arith") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/deblend.c PROPERTIES COMPILE_FLAGS "-Wno-discarded-qualifiers") SET_SOURCE_FILES_PROPERTIES(fitsviewer/sep/util.c PROPERTIES COMPILE_FLAGS "-Wno-discarded-qualifiers") ENDIF () ENDIF () if(WCSLIB_FOUND) include_directories( ${WCSLIB_INCLUDE_DIR} ) endif(WCSLIB_FOUND) set(xplanet_SRCS xplanet/opsxplanet.cpp ) set(xplanetui_SRCS xplanet/opsxplanet.ui ) ########### next target ############### set(libkstarstools_SRCS tools/altvstime.cpp tools/avtplotwidget.cpp tools/calendarwidget.cpp tools/conjunctions.cpp tools/eclipsetool.cpp tools/eclipsehandler.cpp tools/eclipsetool/lunareclipsehandler.cpp # tools/jmoontool.cpp tools/approachsolver.cpp tools/ksconjunct.cpp tools/eqplotwidget.cpp tools/astrocalc.cpp tools/modcalcangdist.cpp tools/modcalcapcoord.cpp tools/modcalcaltaz.cpp tools/modcalcdaylength.cpp tools/modcalceclipticcoords.cpp tools/modcalcvizequinox.cpp tools/modcalcgalcoord.cpp tools/modcalcgeodcoord.cpp tools/modcalcjd.cpp tools/modcalcplanets.cpp tools/modcalcsidtime.cpp tools/modcalcvlsr.cpp tools/observinglist.cpp tools/obslistpopupmenu.cpp tools/sessionsortfilterproxymodel.cpp tools/obslistwizard.cpp tools/planetviewer.cpp tools/pvplotwidget.cpp tools/scriptargwidgets.cpp tools/scriptbuilder.cpp tools/scriptfunction.cpp tools/skycalendar.cpp tools/wutdialog.cpp tools/flagmanager.cpp tools/horizonmanager.cpp tools/nameresolver.cpp tools/polarishourangle.cpp #FIXME Port to KF5 #tools/moonphasetool.cpp tools/starhopper.cpp tools/eyepiecefield.cpp tools/exporteyepieceview.cpp tools/starhopperdialog.cpp tools/adddeepskyobject.cpp ) if(${KF5_VERSION} VERSION_EQUAL 5.18.0 OR ${KF5_VERSION} VERSION_GREATER 5.18.0) set(libkstarstools_SRCS ${libkstarstools_SRCS} tools/whatsinteresting/skyobjlistmodel.cpp tools/whatsinteresting/wiview.cpp tools/whatsinteresting/modelmanager.cpp tools/whatsinteresting/skyobjitem.cpp tools/whatsinteresting/wilpsettings.cpp tools/whatsinteresting/wiequipsettings.cpp tools/whatsinteresting/obsconditions.cpp tools/whatsinteresting/skyobjdescription.cpp ) endif() ki18n_wrap_ui(libkstarstools_ui_SRCS tools/altvstime.ui tools/argchangeviewoption.ui tools/argexportimage.ui tools/argloadcolorscheme.ui tools/arglooktoward.ui tools/argfindobject.ui tools/argprintimage.ui tools/argsetaltaz.ui tools/argsetcolor.ui tools/argsetgeolocation.ui tools/argsetlocaltime.ui tools/argsetradec.ui tools/argsettrack.ui tools/argtimescale.ui tools/argwaitfor.ui tools/argwaitforkey.ui tools/argzoom.ui tools/conjunctions.ui tools/eclipsetool.ui tools/modcalcangdist.ui tools/modcalcapcoord.ui tools/modcalcaltaz.ui tools/modcalcdaylength.ui tools/modcalceclipticcoords.ui tools/modcalcvizequinox.ui tools/modcalcgalcoord.ui tools/modcalcgeod.ui tools/modcalcjd.ui tools/modcalcplanets.ui tools/modcalcsidtime.ui tools/modcalcvlsr.ui tools/observinglist.ui tools/obslistwizard.ui tools/optionstreeview.ui tools/planetviewer.ui tools/scriptbuilder.ui tools/scriptnamedialog.ui tools/skycalendar.ui tools/wutdialog.ui tools/flagmanager.ui tools/starhopperdialog.ui tools/horizonmanager.ui tools/adddeepskyobject.ui tools/polarishourangle.ui ) if (${KF5_VERSION} VERSION_EQUAL 5.18.0 OR ${KF5_VERSION} VERSION_GREATER 5.18.0) ki18n_wrap_ui(libkstarstools_ui_SRCS tools/whatsinteresting/wilpsettings.ui tools/whatsinteresting/wiequipsettings.ui ) endif() set(libkstarswidgets_SRCS widgets/clicklabel.cpp widgets/dmsbox.cpp widgets/draglistbox.cpp widgets/fovwidget.cpp widgets/logedit.cpp widgets/magnitudespinbox.cpp widgets/mapcanvas.cpp widgets/thumbimage.cpp widgets/timespinbox.cpp widgets/timestepbox.cpp widgets/timeunitbox.cpp widgets/infoboxwidget.cpp # widgets/genericcalendarwidget.cpp # widgets/moonphasecalendarwidget.cpp widgets/kshelplabel.cpp widgets/unitspinboxwidget.cpp ) ki18n_wrap_ui(libkstarswidgets_ui_SRCS # widgets/genericcalendarwidget.ui widgets/unitspinboxwidget.ui ) set(kstars_KCFG_SRCS Options.kcfgc) set(kstars_options_SRCS options/opsadvanced.cpp options/opscatalog.cpp options/opscolors.cpp options/opsguides.cpp options/opssolarsystem.cpp options/opssatellites.cpp options/opssupernovae.cpp ) set(kstars_optionsui_SRCS options/opsadvanced.ui options/opscatalog.ui options/opscolors.ui options/opsguides.ui options/opssolarsystem.ui options/opssatellites.ui options/opssupernovae.ui ) set(kstars_dialogs_SRCS dialogs/addcatdialog.cpp dialogs/addlinkdialog.cpp dialogs/detaildialog.cpp dialogs/finddialog.cpp dialogs/focusdialog.cpp dialogs/fovdialog.cpp dialogs/locationdialog.cpp dialogs/timedialog.cpp dialogs/exportimagedialog.cpp ) set(kstars_dialogsui_SRCS dialogs/addcatdialog.ui dialogs/addlinkdialog.ui dialogs/details_database.ui dialogs/details_data.ui dialogs/details_data_comet.ui dialogs/details_links.ui dialogs/details_log.ui dialogs/details_position.ui dialogs/finddialog.ui dialogs/focusdialog.ui dialogs/fovdialog.ui dialogs/locationdialog.ui dialogs/wizwelcome.ui dialogs/wizlocation.ui dialogs/wizdownload.ui dialogs/wizdata.ui dialogs/newfov.ui dialogs/exportimagedialog.ui ) set(hips_SRCS hips/healpix.cpp hips/hipsrenderer.cpp hips/scanrender.cpp hips/pixcache.cpp hips/urlfiledownload.cpp hips/opships.cpp ) set(hips_manager_SRCS hips/hipsmanager.cpp ) set(oal_SRCS oal/log.cpp oal/observer.cpp oal/site.cpp oal/session.cpp oal/scope.cpp oal/eyepiece.cpp oal/filter.cpp oal/observation.cpp oal/lens.cpp oal/equipmentwriter.cpp oal/observeradd.cpp oal/execute.cpp ) set(printing_SRCS printing/detailstable.cpp printing/finderchart.cpp printing/foveditordialog.cpp printing/fovsnapshot.cpp printing/kstarsdocument.cpp printing/legend.cpp printing/loggingform.cpp printing/printingwizard.cpp printing/pwizchartconfig.cpp printing/pwizchartcontents.cpp printing/pwizfovbrowse.cpp printing/pwizfovconfig.cpp printing/pwizfovmanual.cpp printing/pwizfovsh.cpp printing/pwizfovtypeselection.cpp printing/pwizobjectselection.cpp printing/pwizprint.cpp printing/shfovexporter.cpp printing/simplefovexporter.cpp ) set(printingui_SRCS printing/foveditordialog.ui printing/pwizchartconfig.ui printing/pwizchartcontents.ui printing/pwizfovbrowse.ui printing/pwizfovconfig.ui printing/pwizfovmanual.ui printing/pwizfovsh.ui printing/pwizfovtypeselection.ui printing/pwizobjectselection.ui printing/pwizprint.ui printing/pwizwelcome.ui ) set( kstars_KCFG_SRCS Options.kcfgc ) set(libkstarscomponents_SRCS skycomponents/skylabeler.cpp skycomponents/highpmstarlist.cpp skycomponents/skymapcomposite.cpp skycomponents/skymesh.cpp skycomponents/linelistindex.cpp skycomponents/linelistlabel.cpp skycomponents/noprecessindex.cpp skycomponents/listcomponent.cpp skycomponents/pointlistcomponent.cpp skycomponents/solarsystemsinglecomponent.cpp skycomponents/solarsystemlistcomponent.cpp skycomponents/earthshadowcomponent.cpp skycomponents/asteroidscomponent.cpp skycomponents/cometscomponent.cpp skycomponents/planetmoonscomponent.cpp skycomponents/solarsystemcomposite.cpp skycomponents/satellitescomponent.cpp skycomponents/starcomponent.cpp skycomponents/deepstarcomponent.cpp skycomponents/deepskycomponent.cpp skycomponents/catalogcomponent.cpp skycomponents/syncedcatalogcomponent.cpp skycomponents/constellationartcomponent.cpp skycomponents/constellationboundarylines.cpp skycomponents/constellationlines.cpp skycomponents/constellationnamescomponent.cpp skycomponents/supernovaecomponent.cpp skycomponents/coordinategrid.cpp skycomponents/equatorialcoordinategrid.cpp skycomponents/horizontalcoordinategrid.cpp skycomponents/localmeridiancomponent.cpp skycomponents/ecliptic.cpp skycomponents/equator.cpp skycomponents/artificialhorizoncomponent.cpp skycomponents/hipscomponent.cpp skycomponents/horizoncomponent.cpp skycomponents/milkyway.cpp skycomponents/skycomponent.cpp skycomponents/skycomposite.cpp skycomponents/starblock.cpp skycomponents/starblocklist.cpp skycomponents/starblockfactory.cpp skycomponents/culturelist.cpp skycomponents/flagcomponent.cpp skycomponents/targetlistcomponent.cpp ) #LIST(APPEND libkstarscomponents_SRCS # #skycomponents/notifyupdatesui.cpp # ) IF (BUILD_KSTARS_LITE) set(libkstarstools_ui_klite_SRCS tools/nameresolver.cpp ) ENDIF () set(kstars_skyobjects_SRCS skyobjects/constellationsart.cpp skyobjects/deepskyobject.cpp # skyobjects/jupitermoons.cpp skyobjects/planetmoons.cpp skyobjects/ksasteroid.cpp skyobjects/kscomet.cpp skyobjects/ksmoon.cpp skyobjects/ksearthshadow.cpp skyobjects/ksplanetbase.cpp skyobjects/ksplanet.cpp #skyobjects/kspluto.cpp skyobjects/kssun.cpp skyobjects/skyline.cpp skyobjects/skyobject.cpp skyobjects/skypoint.cpp skyobjects/starobject.cpp skyobjects/trailobject.cpp skyobjects/satellite.cpp skyobjects/satellitegroup.cpp skyobjects/supernova.cpp ) set(kstars_projection_SRCS projections/projector.cpp projections/lambertprojector.cpp projections/gnomonicprojector.cpp projections/stereographicprojector.cpp projections/orthographicprojector.cpp projections/azimuthalequidistantprojector.cpp projections/equirectangularprojector.cpp ) set(kstars_extra_SRCS auxiliary/colorscheme.cpp auxiliary/dms.cpp auxiliary/cachingdms.cpp auxiliary/geolocation.cpp auxiliary/ksfilereader.cpp auxiliary/ksuserdb.cpp auxiliary/binfilehelper.cpp auxiliary/ksutils.cpp auxiliary/ksdssimage.cpp auxiliary/ksdssdownloader.cpp auxiliary/nonlineardoublespinbox.cpp auxiliary/profileinfo.cpp auxiliary/filedownloader.cpp auxiliary/kspaths.cpp auxiliary/QRoundProgressBar.cpp auxiliary/skyobjectlistmodel.cpp auxiliary/ksnotification.cpp auxiliary/ksmessagebox.cpp auxiliary/QProgressIndicator.cpp auxiliary/ctkrangeslider.cpp time/simclock.cpp time/kstarsdatetime.cpp time/timezonerule.cpp ksnumbers.cpp kstarsdata.cpp texturemanager.cpp #to minimize number of indef KSTARS_LITE skypainter.cpp ) SET(kstars_extra_kstars_SRCS auxiliary/thememanager.cpp auxiliary/schememanager.cpp auxiliary/imageviewer.cpp auxiliary/xplanetimageviewer.cpp auxiliary/fov.cpp auxiliary/thumbnailpicker.cpp auxiliary/thumbnaileditor.cpp auxiliary/imageexporter.cpp auxiliary/kswizard.cpp auxiliary/qcustomplot.cpp kstarsdbus.cpp kspopupmenu.cpp ksalmanac.cpp kstarsactions.cpp kstarsinit.cpp kstars.cpp kstarssplash.cpp skymap.cpp skymapdrawabstract.cpp skymapqdraw.cpp skymapevents.cpp skyqpainter.cpp ) # Temporary solution to allow use of qml files from source dir DELETE SET(KSTARSLITE_CPP_OPTIONS -DSOURCE_DIR=\"${kstars_SOURCE_DIR}\" -DQML_IMPORT="${CMAKE_CURRENT_SOURCE_DIR}") set(klite_SRCS kstarslite.cpp kstarsliteinit.cpp skymaplite.cpp skymapliteevents.cpp #Wrappers kstarslite/skypointlite.cpp kstarslite/skyobjectlite.cpp #ImageProvider kstarslite/imageprovider.cpp #Dialogs kstarslite/dialogs/detaildialoglite.cpp kstarslite/dialogs/finddialoglite.cpp kstarslite/dialogs/locationdialoglite.cpp #RootNode kstarslite/skyitems/rootnode.cpp kstarslite/skyitems/skyopacitynode.cpp kstarslite/skyitems/typedeflite.h #SkyItems kstarslite/skyitems/skyitem.cpp kstarslite/skyitems/planetsitem.cpp kstarslite/skyitems/asteroidsitem.cpp kstarslite/skyitems/cometsitem.cpp kstarslite/skyitems/horizonitem.cpp kstarslite/skyitems/labelsitem.cpp kstarslite/skyitems/constellationnamesitem.cpp kstarslite/skyitems/staritem.cpp kstarslite/skyitems/deepstaritem.cpp kstarslite/skyitems/deepskyitem.cpp kstarslite/skyitems/constellationartitem.cpp kstarslite/skyitems/satellitesitem.cpp kstarslite/skyitems/supernovaeitem.cpp kstarslite/skyitems/fovitem.cpp kstarslite/skyitems/syncedcatalogitem.cpp #Line kstarslite/skyitems/lines/linesitem.cpp kstarslite/skyitems/lines/equatoritem.cpp kstarslite/skyitems/lines/eclipticitem.cpp kstarslite/skyitems/lines/milkywayitem.cpp #SkyNodes kstarslite/skyitems/skynodes/planetnode.cpp kstarslite/skyitems/skynodes/skynode.cpp kstarslite/skyitems/skynodes/pointsourcenode.cpp kstarslite/skyitems/skynodes/planetmoonsnode.cpp kstarslite/skyitems/skynodes/horizonnode.cpp kstarslite/skyitems/skynodes/labelnode.cpp kstarslite/skyitems/skynodes/guidelabelnode.cpp kstarslite/skyitems/skynodes/deepskynode.cpp kstarslite/skyitems/skynodes/dsosymbolnode.cpp kstarslite/skyitems/skynodes/skypolygonnode.cpp kstarslite/skyitems/skynodes/constellationartnode.cpp kstarslite/skyitems/skynodes/satellitenode.cpp kstarslite/skyitems/skynodes/supernovanode.cpp kstarslite/skyitems/skynodes/trixelnode.cpp kstarslite/skyitems/skynodes/fovsymbolnode.cpp #Nodes kstarslite/skyitems/skynodes/nodes/pointnode.cpp kstarslite/skyitems/skynodes/nodes/polynode.cpp kstarslite/skyitems/skynodes/nodes/linenode.cpp kstarslite/skyitems/skynodes/nodes/ellipsenode.cpp kstarslite/skyitems/skynodes/nodes/rectnode.cpp #Other kstarslite/deviceorientation.cpp ) set(kstarslite_libtess_SRC #libtess libtess/gluos.h libtess/priorityq-sort.h libtess/sweep.c libtess/tessmono.c libtess/dict-list.h libtess/glu.h libtess/tessellate.c libtess/dict.c libtess/geom.c libtess/memalloc.c libtess/mesh.c libtess/normal.c libtess/priorityq.c libtess/priorityq-heap.c libtess/render.c libtess/tess.c ) IF (BUILD_KSTARS_LITE) ADD_CUSTOM_TARGET(convert_translations ${CMAKE_SOURCE_DIR}/tools/convert_translations.sh ${CMAKE_BINARY_DIR} WORKING_DIRECTORY ${CMAKE_BINARY_DIR}) ADD_DEPENDENCIES(convert_translations fetch-translations) IF (ANDROID) ADD_CUSTOM_TARGET(convert_translations_to_android ${CMAKE_SOURCE_DIR}/tools/convert_translations.sh ${CMAKE_BINARY_DIR}/packaging/android/export/share/kstars WORKING_DIRECTORY ${CMAKE_BINARY_DIR}) ADD_DEPENDENCIES(convert_translations_to_android fetch-translations) ENDIF () ENDIF () IF ("${CMAKE_CXX_COMPILER_ID}" STREQUAL "AppleClang" OR "${CMAKE_CXX_COMPILER_ID}" STREQUAL "Clang") SET_SOURCE_FILES_PROPERTIES(${kstarslite_libtess_SRC} PROPERTIES COMPILE_FLAGS "-Wno-error") ENDIF () #Qml files will be probably moved to user's data dir, but for use #with QtCreator it is more convenient to have them here set(kstarsliteqml_SRCS kstarslite/qml/main.qml kstarslite/qml/constants/Constants.qml kstarslite/qml/modules/SkyMapLiteWrapper.qml kstarslite/qml/modules/BottomMenu.qml kstarslite/qml/modules/KSPage.qml kstarslite/qml/modules/KSListView.qml kstarslite/qml/modules/KSLabel.qml kstarslite/qml/modules/KSText.qml kstarslite/qml/modules/KSTabButton.qml kstarslite/qml/modules/KSTab.qml kstarslite/qml/modules/KSTabBarArrow.qml kstarslite/qml/modules/KSTextField.qml kstarslite/qml/modules/KSButton.qml kstarslite/qml/modules/TopMenu.qml kstarslite/qml/modules/helpers/TopMenuButton.qml kstarslite/qml/modules/helpers/BottomMenuButton.qml kstarslite/qml/modules/Splash.qml kstarslite/qml/modules/helpers/TimeSpinBox.qml kstarslite/qml/modules/TimePage.qml #Popups kstarslite/qml/modules/popups/ProjectionsPopup.qml kstarslite/qml/modules/popups/FOVPopup.qml kstarslite/qml/modules/popups/ColorSchemePopup.qml #Menus kstarslite/qml/modules/menus/ContextMenu.qml #Helpers kstarslite/qml/modules/helpers/PassiveNotification.qml kstarslite/qml/modules/helpers/KSMenuItem.qml kstarslite/qml/modules/helpers/TelescopeControl.qml #Dialogs kstarslite/qml/dialogs/FindDialog.qml kstarslite/qml/dialogs/LocationDialog.qml kstarslite/qml/dialogs/DetailsDialog.qml kstarslite/qml/dialogs/AboutDialog.qml kstarslite/qml/dialogs/helpers/DetailsItem.qml kstarslite/qml/dialogs/helpers/DetailsAddLink.qml kstarslite/qml/dialogs/helpers/LocationEdit.qml kstarslite/qml/dialogs/helpers/LocationLoading.qml kstarslite/qml/dialogs/menus/DetailsLinkMenu.qml kstarslite/qml/dialogs/menus/LocationsGeoMenu.qml #INDI kstarslite/qml/indi/INDIControlPanel.qml kstarslite/qml/indi/DevicePanel.qml kstarslite/qml/indi/ImagePreview.qml kstarslite/qml/indi/modules/MotionControl.qml kstarslite/qml/indi/modules/Led.qml kstarslite/qml/indi/modules/KSLed.qml kstarslite/qml/indi/modules/Property.qml kstarslite/qml/indi/modules/KSComboBox.qml kstarslite/qml/indi/modules/KSButtonSwitch.qml kstarslite/qml/indi/modules/KSCheckBox.qml kstarslite/qml/indi/modules/KSINDIText.qml kstarslite/qml/indi/modules/KSINDITextField.qml kstarslite/qml/indi/modules/KSButtonsSwitchRow.qml #Tutorial kstarslite/qml/modules/tutorial/TutorialPopup.qml kstarslite/qml/modules/tutorial/TutorialExitPopup.qml kstarslite/qml/modules/tutorial/TutorialStep1.qml kstarslite/qml/modules/tutorial/TutorialStep2.qml kstarslite/qml/modules/tutorial/TutorialStep3.qml kstarslite/qml/modules/tutorial/TutorialStep4.qml kstarslite/qml/modules/tutorial/TutorialStep5.qml kstarslite/qml/modules/tutorial/TutorialPane.qml ) add_subdirectory(kstarslite/qml) ADD_CUSTOM_TARGET(kstarsliteqml SOURCES ${kstarsliteqml_SRCS}) if(ANDROID) add_subdirectory(kstarslite/res) endif(ANDROID) set(kstars_SRCS ${indi_SRCS} ${fits_SRCS} ${ekos_SRCS} ${libkstarswidgets_SRCS} ${libkstarscomponents_SRCS} ${libkstarstools_SRCS} ${kstars_extra_SRCS} ${kstars_extra_kstars_SRCS} ${kstars_projection_SRCS} ${xplanet_SRCS} ${kstars_options_SRCS} ${kstars_skyobjects_SRCS} ${kstars_dialogs_SRCS} ${hips_SRCS} ${oal_SRCS} ${printing_SRCS} #KStars Lite ${kstarslite_SRCS} # Generated files ${libkstarstools_ui_SRCS} ${libkstarswidgets_ui_SRCS} ) set(kstarslite_SRCS ${indi_klite_SRCS} ${libkstarscomponents_SRCS} ${kstars_extra_SRCS} ${kstars_projection_SRCS} ${kstars_skyobjects_SRCS} # KStars Lite sources ${klite_SRCS} # Generated files ${libkstarstools_ui_klite_SRCS} ) # Generate all the necessary QLoggingCategory files ecm_qt_declare_logging_category(kstars_SRCS HEADER kstars_debug.h IDENTIFIER KSTARS CATEGORY_NAME org.kde.kstars) ecm_qt_declare_logging_category(kstars_SRCS HEADER indi_debug.h IDENTIFIER KSTARS_INDI CATEGORY_NAME org.kde.kstars.indi) ecm_qt_declare_logging_category(kstars_SRCS HEADER fits_debug.h IDENTIFIER KSTARS_FITS CATEGORY_NAME org.kde.kstars.fits) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_debug.h IDENTIFIER KSTARS_EKOS CATEGORY_NAME org.kde.kstars.ekos) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_capture_debug.h IDENTIFIER KSTARS_EKOS_CAPTURE CATEGORY_NAME org.kde.kstars.ekos.capture) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_focus_debug.h IDENTIFIER KSTARS_EKOS_FOCUS CATEGORY_NAME org.kde.kstars.ekos.focus) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_align_debug.h IDENTIFIER KSTARS_EKOS_ALIGN CATEGORY_NAME org.kde.kstars.ekos.align) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_guide_debug.h IDENTIFIER KSTARS_EKOS_GUIDE CATEGORY_NAME org.kde.kstars.ekos.guide) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_mount_debug.h IDENTIFIER KSTARS_EKOS_MOUNT CATEGORY_NAME org.kde.kstars.ekos.mount) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_scheduler_debug.h IDENTIFIER KSTARS_EKOS_SCHEDULER CATEGORY_NAME org.kde.kstars.ekos.scheduler) ecm_qt_declare_logging_category(kstars_SRCS HEADER ekos_observatory_debug.h IDENTIFIER KSTARS_EKOS_OBSERVATORY CATEGORY_NAME org.kde.kstars.ekos.observatory) kconfig_add_kcfg_files(kstars_SRCS ${kstars_KCFG_SRCS}) ecm_qt_declare_logging_category(kstarslite_SRCS HEADER kstars_debug.h IDENTIFIER KSTARS CATEGORY_NAME org.kde.kstars) ecm_qt_declare_logging_category(kstarslite_SRCS HEADER fits_debug.h IDENTIFIER KSTARS_FITS CATEGORY_NAME org.kde.kstars.fits) kconfig_add_kcfg_files(kstarslite_SRCS ${kstars_KCFG_SRCS}) IF (UNITY_BUILD) ENABLE_UNITY_BUILD(kstars kstars_SRCS 10 cpp) ENABLE_UNITY_BUILD(kstarslite kstarslite_SRCS 10 cpp) ENDIF () set(kstars_SRCS ${kstars_SRCS} ${fits2_SRCS} ${sep_SRCS} ${hips_manager_SRCS}) set(kstarslite_SRCS ${kstarslite_SRCS} ${fits_klite_SRCS} ${sep_SRCS} ${fits2_klite_SRCS} ${kstarslite_libtess_SRC}) IF (NOT ANDROID) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.xml kstars.h KStars) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.SimClock.xml simclock.h SimClock) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.FOV.xml fov.h FOV) IF (INDI_FOUND) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.INDI.xml indi/indidbus.h INDIDBus) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.xml ekos/manager.h Ekos::Manager) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Capture.xml ekos/capture/capture.h Ekos::Capture) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Focus.xml ekos/focus/focus.h Ekos::Focus) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Guide.xml ekos/guide/guide.h Ekos::Guide) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Align.xml ekos/align/align.h Ekos::Align) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Mount.xml ekos/mount/mount.h Ekos::Mount) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Dome.xml ekos/auxiliary/dome.h Ekos::Dome) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Weather.xml ekos/auxiliary/weather.h Ekos::Weather) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.DustCap.xml ekos/auxiliary/dustcap.h Ekos::DustCap) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Scheduler.xml ekos/scheduler/scheduler.h Ekos::Scheduler) qt5_add_dbus_adaptor(kstars_SRCS org.kde.kstars.Ekos.Observatory.xml ekos/observatory/observatory.h Ekos::Observatory) ENDIF () ki18n_wrap_ui(kstars_SRCS ${indiui_SRCS} ${ui_SRCS} ${fitsui_SRCS} ${ekosui_SRCS} ${xplanetui_SRCS} ${kstars_optionsui_SRCS} ${kstars_dialogsui_SRCS} ${printingui_SRCS} auxiliary/thumbnailpicker.ui auxiliary/thumbnaileditor.ui oal/observeradd.ui oal/equipmentwriter.ui oal/execute.ui hips/opships.ui hips/opshipsdisplay.ui hips/opshipscache.ui #skycomponents/notifyupdatesui.ui ) add_library(KStarsLib STATIC ${kstars_SRCS}) include(GenerateExportHeader) generate_export_header(KStarsLib) target_link_libraries(KStarsLib LibKSDataHandlers htmesh KF5::Crash KF5::I18n KF5::NewStuff KF5::KIOFileWidgets KF5::WidgetsAddons KF5::Plotting KF5::Notifications Qt5::Gui Qt5::PrintSupport Qt5::Sql Qt5::Svg Qt5::Qml Qt5::Quick Qt5::Network #Qt5::Positioning Qt5::Concurrent Qt5::WebSockets ${ZLIB_LIBRARIES} ) if (Qt5Keychain_FOUND) include_directories(KStarsLib PUBLIC ${QTKEYCHAIN_INCLUDE_DIRS}) target_link_libraries(KStarsLib ${QTKEYCHAIN_LIBRARIES}) endif(Qt5Keychain_FOUND) if (Qt5DataVisualization_FOUND) target_link_libraries(KStarsLib Qt5::DataVisualization) endif(Qt5DataVisualization_FOUND) if (KF5NotifyConfig_FOUND) target_link_libraries(KStarsLib KF5::NotifyConfig) endif(KF5NotifyConfig_FOUND) if(NOT WIN32) target_link_libraries(KStarsLib m) endif(NOT WIN32) ENDIF () if (BUILD_KSTARS_LITE) add_library(KStarsLiteLib STATIC ${kstarslite_SRCS}) target_link_libraries(KStarsLiteLib LibKSDataHandlers htmesh KF5::I18n KF5::Plotting KF5::ConfigGui Qt5::Gui Qt5::Sql Qt5::Qml Qt5::Quick Qt5::QuickControls2 Qt5::Positioning Qt5::PositioningQuick Qt5::Concurrent ${ZLIB_LIBRARIES} ) if (ANDROID) target_link_libraries(KStarsLiteLib Qt5::AndroidExtras) endif () endif () if (CFITSIO_FOUND) if (NOT ANDROID) target_include_directories(KStarsLib PUBLIC ${CFITSIO_INCLUDE_DIR}) target_link_libraries(KStarsLib ${CFITSIO_LIBRARIES}) endif() if (BUILD_KSTARS_LITE) target_include_directories(KStarsLiteLib PUBLIC ${CFITSIO_INCLUDE_DIR}) target_link_libraries(KStarsLiteLib ${CFITSIO_LIBRARIES}) endif() endif(CFITSIO_FOUND) if(INDI_FOUND) if (NOT ANDROID) find_package(Nova REQUIRED) include_directories(${NOVA_INCLUDE_DIR}) endif () ## Support Multiple Platforms. All Require INDI ## WIN32 Desktop: Requires INDI Qt5 Client + GSL ## WIN32 Lite: Requires INDI Qt5 Client ## Linux + MacOS Desktop: Requires INDI Client + GSL ## Linux + MacOS Lite: Requires INDI Qt5 Client ## Android: Requires INDI Qt5 Client built for Android if (NOT ANDROID) find_package(GSL REQUIRED) include_directories(${GSL_INCLUDE_DIRS}) target_link_libraries(KStarsLib ${GSL_LIBRARIES} ${CMAKE_THREAD_LIBS_INIT} KF5::Notifications) endif () if(WIN32 OR ANDROID) if(ANDROID) target_link_libraries(KStarsLiteLib ${INDI_CLIENT_ANDROID_LIBRARIES} ${CFITSIO_LIBRARIES} ${LIBRAW_LIBRARIES}) target_compile_options(KStarsLiteLib PRIVATE ${KSTARSLITE_CPP_OPTIONS} -DUSE_QT5_INDI -DKSTARS_LITE) else(ANDROID) target_link_libraries(KStarsLib ${INDI_CLIENT_LIBRARIES} ${NOVA_LIBRARIES}) endif(ANDROID) else(WIN32 OR ANDROID) if (BUILD_KSTARS_LITE) target_link_libraries(KStarsLiteLib ${INDI_CLIENT_QT_LIBRARIES} ${NOVA_LIBRARIES} z) target_compile_options(KStarsLiteLib PRIVATE ${KSTARSLITE_CPP_OPTIONS} -DUSE_QT5_INDI -DKSTARS_LITE) endif(BUILD_KSTARS_LITE) target_link_libraries(KStarsLib ${INDI_CLIENT_LIBRARIES} ${NOVA_LIBRARIES} z) endif(WIN32 OR ANDROID) endif(INDI_FOUND) if(WCSLIB_FOUND) target_link_libraries(KStarsLib ${WCSLIB_LIBRARIES}) if (BUILD_KSTARS_LITE) target_link_libraries(KStarsLiteLib ${WCSLIB_LIBRARIES}) endif() endif (WCSLIB_FOUND) if(LibRaw_FOUND) if (NOT ANDROID) target_link_libraries(KStarsLib ${LibRaw_LIBRARIES}) endif() if (BUILD_KSTARS_LITE) target_link_libraries(KStarsLiteLib ${LibRaw_LIBRARIES}) endif() endif (LibRaw_FOUND) #FIXME Enable OpenGL Later #if( OPENGL_FOUND ) # target_link_libraries(KStarsLib # ${OPENGL_LIBRARIES} # ${QT_QTOPENGL_LIBRARY} # ) #endif( OPENGL_FOUND ) set (KSTARS_APP_SRCS main.cpp ) # add icon to application sources ecm_add_app_icon(KSTARS_APP_SRCS ICONS ${CMAKE_CURRENT_SOURCE_DIR}/icons/16-apps-kstars.png ${CMAKE_CURRENT_SOURCE_DIR}/icons/32-apps-kstars.png ${CMAKE_CURRENT_SOURCE_DIR}/icons/48-apps-kstars.png ${CMAKE_CURRENT_SOURCE_DIR}/icons/64-apps-kstars.png ${CMAKE_CURRENT_SOURCE_DIR}/icons/128-apps-kstars.png ) qt5_add_resources(KSTARS_APP_SRCS data/kstars.qrc) if (ANDROID) add_library(kstars SHARED ${KSTARS_APP_SRCS}) target_compile_options(kstars PRIVATE ${KSTARSLITE_CPP_OPTIONS} -DUSE_QT5_INDI -DKSTARS_LITE) add_dependencies(KStarsLiteLib cfitsio indi raw) target_link_libraries(kstars KStarsLiteLib) else () if (BUILD_KSTARS_LITE) add_executable(kstars_lite ${KSTARS_APP_SRCS}) target_compile_options(kstars_lite PRIVATE ${KSTARSLITE_CPP_OPTIONS} -DUSE_QT5_INDI -DKSTARS_LITE) target_link_libraries(kstars_lite KStarsLiteLib) endif() add_executable(kstars ${KSTARS_APP_SRCS}) target_link_libraries(kstars KStarsLib) endif () install(TARGETS kstars ${KDE_INSTALL_TARGETS_DEFAULT_ARGS}) ########### install files ############### install(PROGRAMS org.kde.kstars.desktop DESTINATION ${KDE_INSTALL_APPDIR}) install(FILES kstars.kcfg DESTINATION ${KDE_INSTALL_KCFGDIR}) install(FILES kstars.notifyrc DESTINATION ${KNOTIFYRC_INSTALL_DIR}) if(INDI_FOUND) #install(FILES ekos/mount/mountbox.qml DESTINATION ${KDE_INSTALL_DATADIR}/kstars/ekos/mount/qml) #install(DIRECTORY ekos/mount/ DESTINATION ${KDE_INSTALL_DATADIR}/kstars/ekos/mount/qml # FILES_MATCHING PATTERN "*.png") endif() if (NOT ANDROID AND BUILD_KSTARS_LITE) install(TARGETS kstars_lite ${KDE_INSTALL_TARGETS_DEFAULT_ARGS}) endif() diff --git a/kstars/auxiliary/ksutils.cpp b/kstars/auxiliary/ksutils.cpp index 9c7a5ff7a..2dfff809d 100644 --- a/kstars/auxiliary/ksutils.cpp +++ b/kstars/auxiliary/ksutils.cpp @@ -1,1643 +1,1655 @@ /*************************************************************************** ksutils.cpp - K Desktop Planetarium ------------------- begin : Mon Jan 7 10:48:09 EST 2002 copyright : (C) 2002 by Mark Hollomon email : mhh@mindspring.com ***************************************************************************/ /*************************************************************************** * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * ***************************************************************************/ #include "ksutils.h" #include "config-kstars.h" #include "ksnotification.h" #include "kstars_debug.h" #include "deepskyobject.h" #ifndef KSTARS_LITE #include "kswizard.h" #endif #include "Options.h" #include "starobject.h" #include "auxiliary/kspaths.h" #ifndef KSTARS_LITE #include #endif #ifdef HAVE_LIBRAW #include #endif #include #include #include namespace KSUtils { bool isHardwareLimited() { #ifdef __arm__ return true; #else return false; #endif } bool openDataFile(QFile &file, const QString &s) { QString FileName = KSPaths::locate(QStandardPaths::GenericDataLocation, s); if (!FileName.isNull()) { file.setFileName(FileName); return file.open(QIODevice::ReadOnly); } return false; } QString getDSSURL(const SkyPoint *const p) { double height, width; double dss_default_size = Options::defaultDSSImageSize(); double dss_padding = Options::dSSPadding(); Q_ASSERT(p); Q_ASSERT(dss_default_size > 0.0 && dss_padding >= 0.0); const DeepSkyObject *dso = dynamic_cast(p); // Decide what to do about the height and width if (dso) { // For deep-sky objects, use their height and width information double a, b, pa; a = dso->a(); b = dso->a() * dso->e(); // Use a * e instead of b, since e() returns 1 whenever one of the dimensions is zero. This is important for circular objects pa = dso->pa() * dms::DegToRad; // We now want to convert a, b, and pa into an image // height and width -- i.e. a dRA and dDec. // DSS uses dDec for height and dRA for width. (i.e. "top" is north in the DSS images, AFAICT) // From some trigonometry, assuming we have a rectangular object (worst case), we need: width = a * sin(pa) + b * cos(pa); height = a * cos(pa) + b * sin(pa); // 'a' and 'b' are in arcminutes, so height and width are in arcminutes // Pad the RA and Dec, so that we show more of the sky than just the object. height += dss_padding; width += dss_padding; } else { // For a generic sky object, we don't know what to do. So // we just assume the default size. height = width = dss_default_size; } // There's no point in tiny DSS images that are smaller than dss_default_size if (height < dss_default_size) height = dss_default_size; if (width < dss_default_size) width = dss_default_size; return getDSSURL(p->ra0(), p->dec0(), width, height); } QString getDSSURL(const dms &ra, const dms &dec, float width, float height, const QString &type) { const QString URLprefix("http://archive.stsci.edu/cgi-bin/dss_search?"); QString URLsuffix = QString("&e=J2000&f=%1&c=none&fov=NONE").arg(type); const double dss_default_size = Options::defaultDSSImageSize(); char decsgn = (dec.Degrees() < 0.0) ? '-' : '+'; int dd = abs(dec.degree()); int dm = abs(dec.arcmin()); int ds = abs(dec.arcsec()); // Infinite and NaN sizes are replaced by the default size and tiny DSS images are resized to default size if (!qIsFinite(height) || height <= 0.0) height = dss_default_size; if (!qIsFinite(width) || width <= 0.0) width = dss_default_size; // DSS accepts images that are no larger than 75 arcminutes if (height > 75.0) height = 75.0; if (width > 75.0) width = 75.0; QString RAString, DecString, SizeString; DecString = DecString.sprintf("&d=%c%02d+%02d+%02d", decsgn, dd, dm, ds); RAString = RAString.sprintf("r=%02d+%02d+%02d", ra.hour(), ra.minute(), ra.second()); SizeString = SizeString.sprintf("&h=%02.1f&w=%02.1f", height, width); return (URLprefix + RAString + DecString + SizeString + URLsuffix); } QString toDirectionString(dms angle) { // TODO: Instead of doing it this way, it would be nicer to // compute the string to arbitrary precision. Although that will // not be easy to localize. (Consider, for instance, Indian // languages that have special names for the intercardinal points) // -- asimha static const char *directions[] = { I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "N"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "NNE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "NE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "ENE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "E"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "ESE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "SE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "SSE"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "S"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "SSW"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "SW"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "WSW"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "W"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "WNW"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "NW"), I18N_NOOP2("Abbreviated cardinal / intercardinal etc. direction", "NNW"), I18N_NOOP2("Unknown cardinal / intercardinal direction", "???") }; int index = (int)((angle.reduce().Degrees() + 11.25) / 22.5); // A number between 0 and 16 (inclusive) is expected if (index < 0 || index > 16) index = 16; // Something went wrong. else index = (index == 16 ? 0 : index); return i18nc("Abbreviated cardinal / intercardinal etc. direction", directions[index]); } QList *castStarObjListToSkyObjList(QList *starObjList) { QList *skyObjList = new QList(); foreach (StarObject *so, *starObjList) { skyObjList->append(so); } return skyObjList; } QString constGenetiveFromAbbrev(const QString &code) { if (code == "And") return QString("Andromedae"); if (code == "Ant") return QString("Antliae"); if (code == "Aps") return QString("Apodis"); if (code == "Aqr") return QString("Aquarii"); if (code == "Aql") return QString("Aquilae"); if (code == "Ara") return QString("Arae"); if (code == "Ari") return QString("Arietis"); if (code == "Aur") return QString("Aurigae"); if (code == "Boo") return QString("Bootis"); if (code == "Cae") return QString("Caeli"); if (code == "Cam") return QString("Camelopardalis"); if (code == "Cnc") return QString("Cancri"); if (code == "CVn") return QString("Canum Venaticorum"); if (code == "CMa") return QString("Canis Majoris"); if (code == "CMi") return QString("Canis Minoris"); if (code == "Cap") return QString("Capricorni"); if (code == "Car") return QString("Carinae"); if (code == "Cas") return QString("Cassiopeiae"); if (code == "Cen") return QString("Centauri"); if (code == "Cep") return QString("Cephei"); if (code == "Cet") return QString("Ceti"); if (code == "Cha") return QString("Chamaeleontis"); if (code == "Cir") return QString("Circini"); if (code == "Col") return QString("Columbae"); if (code == "Com") return QString("Comae Berenices"); if (code == "CrA") return QString("Coronae Austrinae"); if (code == "CrB") return QString("Coronae Borealis"); if (code == "Crv") return QString("Corvi"); if (code == "Crt") return QString("Crateris"); if (code == "Cru") return QString("Crucis"); if (code == "Cyg") return QString("Cygni"); if (code == "Del") return QString("Delphini"); if (code == "Dor") return QString("Doradus"); if (code == "Dra") return QString("Draconis"); if (code == "Equ") return QString("Equulei"); if (code == "Eri") return QString("Eridani"); if (code == "For") return QString("Fornacis"); if (code == "Gem") return QString("Geminorum"); if (code == "Gru") return QString("Gruis"); if (code == "Her") return QString("Herculis"); if (code == "Hor") return QString("Horologii"); if (code == "Hya") return QString("Hydrae"); if (code == "Hyi") return QString("Hydri"); if (code == "Ind") return QString("Indi"); if (code == "Lac") return QString("Lacertae"); if (code == "Leo") return QString("Leonis"); if (code == "LMi") return QString("Leonis Minoris"); if (code == "Lep") return QString("Leporis"); if (code == "Lib") return QString("Librae"); if (code == "Lup") return QString("Lupi"); if (code == "Lyn") return QString("Lyncis"); if (code == "Lyr") return QString("Lyrae"); if (code == "Men") return QString("Mensae"); if (code == "Mic") return QString("Microscopii"); if (code == "Mon") return QString("Monocerotis"); if (code == "Mus") return QString("Muscae"); if (code == "Nor") return QString("Normae"); if (code == "Oct") return QString("Octantis"); if (code == "Oph") return QString("Ophiuchi"); if (code == "Ori") return QString("Orionis"); if (code == "Pav") return QString("Pavonis"); if (code == "Peg") return QString("Pegasi"); if (code == "Per") return QString("Persei"); if (code == "Phe") return QString("Phoenicis"); if (code == "Pic") return QString("Pictoris"); if (code == "Psc") return QString("Piscium"); if (code == "PsA") return QString("Piscis Austrini"); if (code == "Pup") return QString("Puppis"); if (code == "Pyx") return QString("Pyxidis"); if (code == "Ret") return QString("Reticuli"); if (code == "Sge") return QString("Sagittae"); if (code == "Sgr") return QString("Sagittarii"); if (code == "Sco") return QString("Scorpii"); if (code == "Scl") return QString("Sculptoris"); if (code == "Sct") return QString("Scuti"); if (code == "Ser") return QString("Serpentis"); if (code == "Sex") return QString("Sextantis"); if (code == "Tau") return QString("Tauri"); if (code == "Tel") return QString("Telescopii"); if (code == "Tri") return QString("Trianguli"); if (code == "TrA") return QString("Trianguli Australis"); if (code == "Tuc") return QString("Tucanae"); if (code == "UMa") return QString("Ursae Majoris"); if (code == "UMi") return QString("Ursae Minoris"); if (code == "Vel") return QString("Velorum"); if (code == "Vir") return QString("Virginis"); if (code == "Vol") return QString("Volantis"); if (code == "Vul") return QString("Vulpeculae"); return code; } QString constNameFromAbbrev(const QString &code) { if (code == "And") return QString("Andromeda"); if (code == "Ant") return QString("Antlia"); if (code == "Aps") return QString("Apus"); if (code == "Aqr") return QString("Aquarius"); if (code == "Aql") return QString("Aquila"); if (code == "Ara") return QString("Ara"); if (code == "Ari") return QString("Aries"); if (code == "Aur") return QString("Auriga"); if (code == "Boo") return QString("Bootes"); if (code == "Cae") return QString("Caelum"); if (code == "Cam") return QString("Camelopardalis"); if (code == "Cnc") return QString("Cancer"); if (code == "CVn") return QString("Canes Venatici"); if (code == "CMa") return QString("Canis Major"); if (code == "CMi") return QString("Canis Minor"); if (code == "Cap") return QString("Capricornus"); if (code == "Car") return QString("Carina"); if (code == "Cas") return QString("Cassiopeia"); if (code == "Cen") return QString("Centaurus"); if (code == "Cep") return QString("Cepheus"); if (code == "Cet") return QString("Cetus"); if (code == "Cha") return QString("Chamaeleon"); if (code == "Cir") return QString("Circinus"); if (code == "Col") return QString("Columba"); if (code == "Com") return QString("Coma Berenices"); if (code == "CrA") return QString("Corona Australis"); if (code == "CrB") return QString("Corona Borealis"); if (code == "Crv") return QString("Corvus"); if (code == "Crt") return QString("Crater"); if (code == "Cru") return QString("Crux"); if (code == "Cyg") return QString("Cygnus"); if (code == "Del") return QString("Delphinus"); if (code == "Dor") return QString("Doradus"); if (code == "Dra") return QString("Draco"); if (code == "Equ") return QString("Equuleus"); if (code == "Eri") return QString("Eridanus"); if (code == "For") return QString("Fornax"); if (code == "Gem") return QString("Gemini"); if (code == "Gru") return QString("Grus"); if (code == "Her") return QString("Hercules"); if (code == "Hor") return QString("Horologium"); if (code == "Hya") return QString("Hydra"); if (code == "Hyi") return QString("Hydrus"); if (code == "Ind") return QString("Indus"); if (code == "Lac") return QString("Lacerta"); if (code == "Leo") return QString("Leo"); if (code == "LMi") return QString("Leo Minor"); if (code == "Lep") return QString("Lepus"); if (code == "Lib") return QString("Libra"); if (code == "Lup") return QString("Lupus"); if (code == "Lyn") return QString("Lynx"); if (code == "Lyr") return QString("Lyra"); if (code == "Men") return QString("Mensa"); if (code == "Mic") return QString("Microscopium"); if (code == "Mon") return QString("Monoceros"); if (code == "Mus") return QString("Musca"); if (code == "Nor") return QString("Norma"); if (code == "Oct") return QString("Octans"); if (code == "Oph") return QString("Ophiuchus"); if (code == "Ori") return QString("Orion"); if (code == "Pav") return QString("Pavo"); if (code == "Peg") return QString("Pegasus"); if (code == "Per") return QString("Perseus"); if (code == "Phe") return QString("Phoenix"); if (code == "Pic") return QString("Pictor"); if (code == "Psc") return QString("Pisces"); if (code == "PsA") return QString("Piscis Austrinus"); if (code == "Pup") return QString("Puppis"); if (code == "Pyx") return QString("Pyxis"); if (code == "Ret") return QString("Reticulum"); if (code == "Sge") return QString("Sagitta"); if (code == "Sgr") return QString("Sagittarius"); if (code == "Sco") return QString("Scorpius"); if (code == "Scl") return QString("Sculptor"); if (code == "Sct") return QString("Scutum"); if (code == "Ser") return QString("Serpens"); if (code == "Sex") return QString("Sextans"); if (code == "Tau") return QString("Taurus"); if (code == "Tel") return QString("Telescopium"); if (code == "Tri") return QString("Triangulum"); if (code == "TrA") return QString("Triangulum Australe"); if (code == "Tuc") return QString("Tucana"); if (code == "UMa") return QString("Ursa Major"); if (code == "UMi") return QString("Ursa Minor"); if (code == "Vel") return QString("Vela"); if (code == "Vir") return QString("Virgo"); if (code == "Vol") return QString("Volans"); if (code == "Vul") return QString("Vulpecula"); return code; } QString constNameToAbbrev(const QString &fullName_) { QString fullName = fullName_.toLower(); if (fullName == "andromeda") return QString("And"); if (fullName == "antlia") return QString("Ant"); if (fullName == "apus") return QString("Aps"); if (fullName == "aquarius") return QString("Aqr"); if (fullName == "aquila") return QString("Aql"); if (fullName == "ara") return QString("Ara"); if (fullName == "aries") return QString("Ari"); if (fullName == "auriga") return QString("Aur"); if (fullName == "bootes") return QString("Boo"); if (fullName == "caelum") return QString("Cae"); if (fullName == "camelopardalis") return QString("Cam"); if (fullName == "cancer") return QString("Cnc"); if (fullName == "canes venatici") return QString("CVn"); if (fullName == "canis major") return QString("CMa"); if (fullName == "canis minor") return QString("CMi"); if (fullName == "capricornus") return QString("Cap"); if (fullName == "carina") return QString("Car"); if (fullName == "cassiopeia") return QString("Cas"); if (fullName == "centaurus") return QString("Cen"); if (fullName == "cepheus") return QString("Cep"); if (fullName == "cetus") return QString("Cet"); if (fullName == "chamaeleon") return QString("Cha"); if (fullName == "circinus") return QString("Cir"); if (fullName == "columba") return QString("Col"); if (fullName == "coma berenices") return QString("Com"); if (fullName == "corona australis") return QString("CrA"); if (fullName == "corona borealis") return QString("CrB"); if (fullName == "corvus") return QString("Crv"); if (fullName == "crater") return QString("Crt"); if (fullName == "crux") return QString("Cru"); if (fullName == "cygnus") return QString("Cyg"); if (fullName == "delphinus") return QString("Del"); if (fullName == "doradus") return QString("Dor"); if (fullName == "draco") return QString("Dra"); if (fullName == "equuleus") return QString("Equ"); if (fullName == "eridanus") return QString("Eri"); if (fullName == "fornax") return QString("For"); if (fullName == "gemini") return QString("Gem"); if (fullName == "grus") return QString("Gru"); if (fullName == "hercules") return QString("Her"); if (fullName == "horologium") return QString("Hor"); if (fullName == "hydra") return QString("Hya"); if (fullName == "hydrus") return QString("Hyi"); if (fullName == "indus") return QString("Ind"); if (fullName == "lacerta") return QString("Lac"); if (fullName == "leo") return QString("Leo"); if (fullName == "leo minor") return QString("LMi"); if (fullName == "lepus") return QString("Lep"); if (fullName == "libra") return QString("Lib"); if (fullName == "lupus") return QString("Lup"); if (fullName == "lynx") return QString("Lyn"); if (fullName == "lyra") return QString("Lyr"); if (fullName == "mensa") return QString("Men"); if (fullName == "microscopium") return QString("Mic"); if (fullName == "monoceros") return QString("Mon"); if (fullName == "musca") return QString("Mus"); if (fullName == "norma") return QString("Nor"); if (fullName == "octans") return QString("Oct"); if (fullName == "ophiuchus") return QString("Oph"); if (fullName == "orion") return QString("Ori"); if (fullName == "pavo") return QString("Pav"); if (fullName == "pegasus") return QString("Peg"); if (fullName == "perseus") return QString("Per"); if (fullName == "phoenix") return QString("Phe"); if (fullName == "pictor") return QString("Pic"); if (fullName == "pisces") return QString("Psc"); if (fullName == "piscis austrinus") return QString("PsA"); if (fullName == "puppis") return QString("Pup"); if (fullName == "pyxis") return QString("Pyx"); if (fullName == "reticulum") return QString("Ret"); if (fullName == "sagitta") return QString("Sge"); if (fullName == "sagittarius") return QString("Sgr"); if (fullName == "scorpius") return QString("Sco"); if (fullName == "sculptor") return QString("Scl"); if (fullName == "scutum") return QString("Sct"); if (fullName == "serpens") return QString("Ser"); if (fullName == "sextans") return QString("Sex"); if (fullName == "taurus") return QString("Tau"); if (fullName == "telescopium") return QString("Tel"); if (fullName == "triangulum") return QString("Tri"); if (fullName == "triangulum australe") return QString("TrA"); if (fullName == "tucana") return QString("Tuc"); if (fullName == "ursa major") return QString("UMa"); if (fullName == "ursa minor") return QString("UMi"); if (fullName == "vela") return QString("Vel"); if (fullName == "virgo") return QString("Vir"); if (fullName == "volans") return QString("Vol"); if (fullName == "vulpecula") return QString("Vul"); return fullName_; } QString constGenetiveToAbbrev(const QString &genetive_) { QString genetive = genetive_.toLower(); if (genetive == "andromedae") return QString("And"); if (genetive == "antliae") return QString("Ant"); if (genetive == "apodis") return QString("Aps"); if (genetive == "aquarii") return QString("Aqr"); if (genetive == "aquilae") return QString("Aql"); if (genetive == "arae") return QString("Ara"); if (genetive == "arietis") return QString("Ari"); if (genetive == "aurigae") return QString("Aur"); if (genetive == "bootis") return QString("Boo"); if (genetive == "caeli") return QString("Cae"); if (genetive == "camelopardalis") return QString("Cam"); if (genetive == "cancri") return QString("Cnc"); if (genetive == "canum venaticorum") return QString("CVn"); if (genetive == "canis majoris") return QString("CMa"); if (genetive == "canis minoris") return QString("CMi"); if (genetive == "capricorni") return QString("Cap"); if (genetive == "carinae") return QString("Car"); if (genetive == "cassiopeiae") return QString("Cas"); if (genetive == "centauri") return QString("Cen"); if (genetive == "cephei") return QString("Cep"); if (genetive == "ceti") return QString("Cet"); if (genetive == "chamaeleontis") return QString("Cha"); if (genetive == "circini") return QString("Cir"); if (genetive == "columbae") return QString("Col"); if (genetive == "comae berenices") return QString("Com"); if (genetive == "coronae austrinae") return QString("CrA"); if (genetive == "coronae borealis") return QString("CrB"); if (genetive == "corvi") return QString("Crv"); if (genetive == "crateris") return QString("Crt"); if (genetive == "crucis") return QString("Cru"); if (genetive == "cygni") return QString("Cyg"); if (genetive == "delphini") return QString("Del"); if (genetive == "doradus") return QString("Dor"); if (genetive == "draconis") return QString("Dra"); if (genetive == "equulei") return QString("Equ"); if (genetive == "eridani") return QString("Eri"); if (genetive == "fornacis") return QString("For"); if (genetive == "geminorum") return QString("Gem"); if (genetive == "gruis") return QString("Gru"); if (genetive == "herculis") return QString("Her"); if (genetive == "horologii") return QString("Hor"); if (genetive == "hydrae") return QString("Hya"); if (genetive == "hydri") return QString("Hyi"); if (genetive == "indi") return QString("Ind"); if (genetive == "lacertae") return QString("Lac"); if (genetive == "leonis") return QString("Leo"); if (genetive == "leonis minoris") return QString("LMi"); if (genetive == "leporis") return QString("Lep"); if (genetive == "librae") return QString("Lib"); if (genetive == "lupi") return QString("Lup"); if (genetive == "lyncis") return QString("Lyn"); if (genetive == "lyrae") return QString("Lyr"); if (genetive == "mensae") return QString("Men"); if (genetive == "microscopii") return QString("Mic"); if (genetive == "monocerotis") return QString("Mon"); if (genetive == "muscae") return QString("Mus"); if (genetive == "normae") return QString("Nor"); if (genetive == "octantis") return QString("Oct"); if (genetive == "ophiuchi") return QString("Oph"); if (genetive == "orionis") return QString("Ori"); if (genetive == "pavonis") return QString("Pav"); if (genetive == "pegasi") return QString("Peg"); if (genetive == "persei") return QString("Per"); if (genetive == "phoenicis") return QString("Phe"); if (genetive == "pictoris") return QString("Pic"); if (genetive == "piscium") return QString("Psc"); if (genetive == "piscis austrini") return QString("PsA"); if (genetive == "puppis") return QString("Pup"); if (genetive == "pyxidis") return QString("Pyx"); if (genetive == "reticuli") return QString("Ret"); if (genetive == "sagittae") return QString("Sge"); if (genetive == "sagittarii") return QString("Sgr"); if (genetive == "scorpii") return QString("Sco"); if (genetive == "sculptoris") return QString("Scl"); if (genetive == "scuti") return QString("Sct"); if (genetive == "serpentis") return QString("Ser"); if (genetive == "sextantis") return QString("Sex"); if (genetive == "tauri") return QString("Tau"); if (genetive == "telescopii") return QString("Tel"); if (genetive == "trianguli") return QString("Tri"); if (genetive == "trianguli australis") return QString("TrA"); if (genetive == "tucanae") return QString("Tuc"); if (genetive == "ursae majoris") return QString("UMa"); if (genetive == "ursae minoris") return QString("UMi"); if (genetive == "velorum") return QString("Vel"); if (genetive == "virginis") return QString("Vir"); if (genetive == "volantis") return QString("Vol"); if (genetive == "vulpeculae") return QString("Vul"); return genetive_; } QString Logging::_filename; void Logging::UseFile() { if (_filename.isEmpty()) { QDir dir; QString path = KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + "logs/" + QDateTime::currentDateTime().toString("yyyy-MM-dd"); dir.mkpath(path); QString name = "log_" + QDateTime::currentDateTime().toString("HH-mm-ss") + ".txt"; _filename = path + QStringLiteral("/") + name; // Clear file contents QFile file(_filename); file.open(QFile::WriteOnly); file.close(); } qSetMessagePattern("[%{time yyyy-MM-dd h:mm:ss.zzz t} %{if-debug}DEBG%{endif}%{if-info}INFO%{endif}%{if-warning}WARN%{endif}%{if-critical}CRIT%{endif}%{if-fatal}FATL%{endif}] %{if-category}[%{category}]%{endif} - %{message}"); qInstallMessageHandler(File); } void Logging::File(QtMsgType type, const QMessageLogContext &context, const QString &msg) { QFile file(_filename); if (file.open(QFile::Append | QIODevice::Text)) { QTextStream stream(&file); Write(stream, type, context, msg); } } void Logging::UseStdout() { qSetMessagePattern("[%{time yyyy-MM-dd h:mm:ss.zzz t} %{if-debug}DEBG%{endif}%{if-info}INFO%{endif}%{if-warning}WARN%{endif}%{if-critical}CRIT%{endif}%{if-fatal}FATL%{endif}] %{if-category}[%{category}]%{endif} - %{message}"); qInstallMessageHandler(Stdout); } void Logging::Stdout(QtMsgType type, const QMessageLogContext &context, const QString &msg) { QTextStream stream(stdout, QIODevice::WriteOnly); Write(stream, type, context, msg); } void Logging::UseStderr() { qInstallMessageHandler(Stderr); } void Logging::Stderr(QtMsgType type, const QMessageLogContext &context, const QString &msg) { QTextStream stream(stderr, QIODevice::WriteOnly); Write(stream, type, context, msg); } void Logging::Write(QTextStream &stream, QtMsgType type, const QMessageLogContext &context, const QString &msg) { stream << QDateTime::currentDateTime().toString("[yyyy-MM-ddThh:mm:ss.zzz t "); switch (type) { case QtInfoMsg: stream << "INFO ]"; break; case QtDebugMsg: stream << "DEBG ]"; break; case QtWarningMsg: stream << "WARN ]"; break; case QtCriticalMsg: stream << "CRIT ]"; break; case QtFatalMsg: stream << "FATL ]"; break; default: stream << "UNKN ]"; } stream << "[" << qSetFieldWidth(30) << context.category << qSetFieldWidth(0) << "] - "; stream << msg << endl; //stream << qFormatLogMessage(type, context, msg) << endl; } void Logging::UseDefault() { qInstallMessageHandler(nullptr); } void Logging::Disable() { qInstallMessageHandler(Disabled); } void Logging::Disabled(QtMsgType, const QMessageLogContext &, const QString &) { } void Logging::SyncFilterRules() { // QString rules = QString("org.kde.kstars.ekos.debug=%1\n" // "org.kde.kstars.indi.debug=%2\n" // "org.kde.kstars.fits.debug=%3\n" // "org.kde.kstars.ekos.capture.debug=%4\n" // "org.kde.kstars.ekos.focus.debug=%5\n" // "org.kde.kstars.ekos.guide.debug=%6\n" // "org.kde.kstars.ekos.align.debug=%7\n" // "org.kde.kstars.ekos.mount.debug=%8\n" // "org.kde.kstars.ekos.scheduler.debug=%9\n").arg( // Options::verboseLogging() ? "true" : "false", // Options::iNDILogging() ? "true" : "false", // Options::fITSLogging() ? "true" : "false", // Options::captureLogging() ? "true" : "false", // Options::focusLogging() ? "true" : "false", // Options::guideLogging() ? "true" : "false", // Options::alignmentLogging() ? "true" : "false", // Options::mountLogging() ? "true" : "false", // Options::schedulerLogging() ? "true" : "false") // .append(QString("org.kde.kstars.ekos.observatory.debug=%2\n" // "org.kde.kstars.debug=%1").arg( // Options::verboseLogging() ? "true" : "false", // Options::observatoryLogging() ? "true" : "false")); QStringList rules; rules << "org.kde.kstars.ekos.debug" << (Options::verboseLogging() ? "true" : "false"); rules << "org.kde.kstars.indi.debug" << (Options::iNDILogging() ? "true" : "false"); rules << "org.kde.kstars.fits.debug" << (Options::fITSLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.capture.debug" << (Options::captureLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.focus.debug" << (Options::focusLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.guide.debug" << (Options::guideLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.align.debug" << (Options::alignmentLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.mount.debug" << (Options::mountLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.scheduler.debug" << (Options::schedulerLogging() ? "true" : "false"); rules << "org.kde.kstars.ekos.observatory.debug" << (Options::observatoryLogging() ? "true" : "false"); rules << "org.kde.kstars.debug" << (Options::verboseLogging() ? "true" : "false"); QString formattedRules; for (int i = 0; i < rules.size(); i += 2) formattedRules.append(QString("%1=%2\n").arg(rules[i], rules[i + 1])); QLoggingCategory::setFilterRules(formattedRules); } /** This method provides a centralized location for the default paths to important external files used in the Options on different operating systems. Note that on OS X, if the user builds the app without indi, astrometry, and xplanet internally then the options below will be used. If the user drags the app from a dmg and has to install the KStars data directory, then most of these paths will be overwritten since it is preferred to use the internal versions. **/ QString getDefaultPath(QString option) { QString snap = QProcessEnvironment::systemEnvironment().value("SNAP"); QString flat = QProcessEnvironment::systemEnvironment().value("FLATPAK_DEST"); if (option == "fitsDir") { return QDir::homePath(); } else if (option == "indiServer") { #if defined(Q_OS_OSX) return "/usr/local/bin/indiserver"; #endif if (flat.isEmpty() == false) return flat + "/bin/indiserver"; else return snap + "/usr/bin/indiserver"; } else if (option == "indiDriversDir") { #if defined(Q_OS_OSX) return "/usr/local/share/indi"; #elif defined(Q_OS_LINUX) if (flat.isEmpty() == false) return flat + "/share/indi"; else return snap + "/usr/share/indi"; #else return QStandardPaths::locate(QStandardPaths::GenericDataLocation, "indi", QStandardPaths::LocateDirectory); #endif } else if (option == "AstrometrySolverBinary") { #if defined(Q_OS_OSX) return "/usr/local/bin/solve-field"; #endif if (flat.isEmpty() == false) return flat + "/bin/solve-field"; else return snap + "/usr/bin/solve-field"; } else if (option == "AstrometryWCSInfo") { #if defined(Q_OS_OSX) return "/usr/local/bin/wcsinfo"; #endif if (flat.isEmpty() == false) return flat + "/bin/wcsinfo"; else return snap + "/usr/bin/wcsinfo"; } else if (option == "AstrometryConfFile") { #if defined(Q_OS_OSX) return "/usr/local/etc/astrometry.cfg"; #endif if (flat.isEmpty() == false) return flat + "/etc/astrometry.cfg"; else return snap + "/etc/astrometry.cfg"; } else if (option == "AstrometryIndexFileLocation") { #if defined(Q_OS_OSX) return QStandardPaths::writableLocation(QStandardPaths::GenericDataLocation) + "/Astrometry/"; #endif if (flat.isEmpty() == false) return flat + "/usr/share/astrometry/"; else return snap + "/usr/share/astrometry/"; } else if (option == "XplanetPath") { #if defined(Q_OS_OSX) return "/usr/local/bin/xplanet"; #endif if (flat.isEmpty() == false) return flat + "/bin/xplanet"; else return snap + "/usr/bin/xplanet"; } + else if (option == "ASTAP") + { +#if defined(Q_OS_OSX) + return "/usr/local/bin/aspat"; +#elif defined(Q_OS_WIN) + return "C:\Program Files\astap\astap.exe"; +#endif + if (flat.isEmpty() == false) + return flat + "/bin/astap"; + else + return snap + "/usr/local/bin/astap"; + } return QString(); } #if defined(Q_OS_OSX) //Note that this will copy and will not overwrite, so that the user's changes in the files are preserved. void copyResourcesFolderFromAppBundle(QString folder) { QString folderLocation = QStandardPaths::locate(QStandardPaths::GenericDataLocation, folder, QStandardPaths::LocateDirectory); QDir folderSourceDir; if(folder == "kstars") folderSourceDir = QDir(QCoreApplication::applicationDirPath() + "/../Resources/data").absolutePath(); else folderSourceDir = QDir(QCoreApplication::applicationDirPath() + "/../Resources/" + folder).absolutePath(); if (folderSourceDir.exists()) { folderLocation = QStandardPaths::writableLocation(QStandardPaths::GenericDataLocation) + '/' + folder; QDir writableDir; writableDir.mkdir(folderLocation); copyRecursively(folderSourceDir.absolutePath(), folderLocation); } } bool copyDataFolderFromAppBundleIfNeeded() //The method returns true if the data directory is good to go. { //This will copy the locale folder, the notifications folder, and the sounds folder and any missing files in them to Application Support if needed. copyResourcesFolderFromAppBundle("locale"); copyResourcesFolderFromAppBundle("knotifications5"); copyResourcesFolderFromAppBundle("sounds"); //This will check for the data directory and if its not present, it will run the wizard. QString dataLocation = QStandardPaths::locate(QStandardPaths::GenericDataLocation, "kstars", QStandardPaths::LocateDirectory); if (dataLocation.isEmpty()) //If there is no kstars user data directory { QPointer wizard = new KSWizard(new QFrame()); wizard->exec(); //This will pause the startup until the user installs the data directory from the Wizard. dataLocation = QStandardPaths::locate(QStandardPaths::GenericDataLocation, "kstars", QStandardPaths::LocateDirectory); if (dataLocation.isEmpty()) return false; //This sets some important OS X options. Options::setIndiServerIsInternal(true); Options::setIndiServer("*Internal INDI Server*"); Options::setIndiDriversAreInternal(true); Options::setIndiDriversDir("*Internal INDI Drivers*"); Options::setAstrometrySolverIsInternal(true); Options::setAstrometrySolverBinary("*Internal Solver*"); Options::setAstrometryConfFileIsInternal(true); Options::setAstrometryConfFile("*Internal astrometry.cfg*"); Options::setAstrometryWCSIsInternal(true); Options::setAstrometryWCSInfo("*Internal wcsinfo*"); Options::setAstrometryUseNoFITS2FITS(false); Options::setXplanetIsInternal(true); Options::setXplanetPath("*Internal XPlanet*"); Options::setRunStartupWizard(false); //don't run on startup because we are doing it now. return true; //This means the data directory is good to go now that we created it from the default. } //This will copy any of the critical KStars files from the app bundle to application support if they are missing. copyResourcesFolderFromAppBundle("kstars"); return true; //This means the data directory was good to go from the start and the wizard did not run. } //Can this and the linux method be merged somehow? See KSUtils::createLocalAstrometryConf bool configureAstrometry() { QStringList astrometryDataDirs = getAstrometryDataDirs(); if (astrometryDataDirs.count() == 0) return false; QString defaultAstrometryDataDir = getDefaultPath("AstrometryIndexFileLocation"); if(astrometryDataDirs.contains("IndexFileLocationNotYetSet")) replaceIndexFileNotYetSet(); if (QDir(defaultAstrometryDataDir).exists() == false) { if (KMessageBox::warningYesNo( nullptr, i18n("The selected Astrometry Index File Location:\n %1 \n does not exist. Do you want to make the directory?", defaultAstrometryDataDir), i18n("Make Astrometry Index File Directory?")) == KMessageBox::Yes) { if(QDir(defaultAstrometryDataDir).mkdir(defaultAstrometryDataDir)) { KSNotification::info(i18n("The Default Astrometry Index File Location was created.")); } else { KSNotification::sorry(i18n("The Default Astrometry Index File Directory does not exist and was not able to be created.")); } } else { return false; } } return true; } bool replaceIndexFileNotYetSet() { QString confPath = KSUtils::getAstrometryConfFilePath(); QFile confFile(confPath); QString contents; if (confFile.open(QIODevice::ReadOnly) == false) { KSNotification::error( i18n("Astrometry Configuration File Read Error.")); return false; } else { QByteArray fileContent = confFile.readAll(); confFile.close(); QString contents = QString::fromLatin1(fileContent); contents.replace("IndexFileLocationNotYetSet", getDefaultPath("AstrometryIndexFileLocation")); if (confFile.open(QIODevice::WriteOnly) == false) { KSNotification::error( i18n("Internal Astrometry Configuration File Write Error.")); return false; } else { QTextStream out(&confFile); out << contents; confFile.close(); } } return true; } bool copyRecursively(QString sourceFolder, QString destFolder) { QDir sourceDir(sourceFolder); if (!sourceDir.exists()) return false; QDir destDir(destFolder); if (!destDir.exists()) destDir.mkdir(destFolder); QStringList files = sourceDir.entryList(QDir::Files); for (int i = 0; i < files.count(); i++) { QString srcName = sourceFolder + QDir::separator() + files[i]; QString destName = destFolder + QDir::separator() + files[i]; QFile::copy(srcName, destName); //Note this does not overwrite files } files.clear(); files = sourceDir.entryList(QDir::AllDirs | QDir::NoDotAndDotDot); for (int i = 0; i < files.count(); i++) { QString srcName = sourceFolder + QDir::separator() + files[i]; QString destName = destFolder + QDir::separator() + files[i]; copyRecursively(srcName, destName); } return true; } #endif //Note maybe the Mac and Linux versions of creating the local astrometry conf file and index file folder can be merged. //I moved both of them here and this method references each one separately. //One is createLocalAstrometryConf and the other is configureAstrometry bool configureLocalAstrometryConfIfNecessary() { #if defined(Q_OS_LINUX) QString confPath = KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + QLatin1String("astrometry") + QLatin1String("/astrometry.cfg"); if (QFileInfo(confPath).exists() == false) { if(createLocalAstrometryConf() == false) return false; } #elif defined(Q_OS_OSX) if(configureAstrometry() == false) { KMessageBox::information( nullptr, i18n( "Failed to properly configure astrometry config file. Please click the options button in the lower right of the Astrometry Tab in Ekos to correct your settings. Then try starting Ekos again."), i18n("Astrometry Config File Error"), "astrometry_configuration_failure_warning"); return false; } #endif return true; } //Can this and the mac method be merged somehow? See KSUtils::configureAstrometry. bool createLocalAstrometryConf() { bool rc = false; QString confPath = KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + QLatin1String("astrometry") + QLatin1String("/astrometry.cfg"); QString systemConfPath = "/etc/astrometry.cfg"; // Check if directory already exists, if it doesn't create one QDir writableDir(KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + QLatin1String("astrometry")); if (writableDir.exists() == false) { rc = writableDir.mkdir(KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + QLatin1String("astrometry")); if (rc == false) { qCCritical(KSTARS) << "Failed to create local astrometry directory"; return false; } } // Now copy system astrometry.cfg to local directory rc = QFile(systemConfPath).copy(confPath); if (rc == false) { qCCritical(KSTARS) << "Failed to copy" << systemConfPath << "to" << confPath; return false; } QFile localConf(confPath); // Open file and add our own path to it if (localConf.open(QFile::ReadWrite)) { QString all = localConf.readAll(); QStringList lines = all.split("\n"); for (int i = 0; i < lines.count(); i++) { if (lines[i].startsWith("add_path")) { lines.insert(i + 1, QString("add_path %1astrometry").arg(KSPaths::writableLocation(QStandardPaths::GenericDataLocation))); break; } } // Clear contents localConf.resize(0); // Now write back all the lines including our own inserted above QTextStream out(&localConf); for(const QString &line : lines) out << line << endl; localConf.close(); return true; } qCCritical(KSTARS) << "Failed to open local astrometry config" << confPath; return false; } QString getAstrometryConfFilePath() { #if defined(Q_OS_LINUX) if (Options::astrometryConfFileIsInternal()) return KSPaths::writableLocation(QStandardPaths::GenericDataLocation) + QLatin1String("astrometry") + QLatin1String("/astrometry.cfg"); #elif defined(Q_OS_OSX) if (Options::astrometryConfFileIsInternal()) return QCoreApplication::applicationDirPath() + "/astrometry/bin/astrometry.cfg"; #endif return Options::astrometryConfFile(); } QStringList getAstrometryDataDirs() { QStringList dataDirs; QString confPath = KSUtils::getAstrometryConfFilePath(); QFile confFile(confPath); if (confFile.open(QIODevice::ReadOnly) == false) { bool confFileExists = false; if(Options::astrometryConfFileIsInternal()) { if(KSUtils::configureLocalAstrometryConfIfNecessary()) { if (confFile.open(QIODevice::ReadOnly)) confFileExists = true; } } if(!confFileExists) { KSNotification::error(i18n("Astrometry configuration file corrupted or missing: %1\nPlease set the " "configuration file full path in INDI options.", confPath)); return dataDirs; } } QTextStream in(&confFile); QString line; while (!in.atEnd()) { line = in.readLine(); if (line.isEmpty() || line.startsWith('#')) continue; line = line.trimmed(); if (line.startsWith(QLatin1String("add_path"))) { dataDirs << line.mid(9).trimmed(); } } // if(dataDirs.size()==0) // KSNotification::error(i18n("Unable to find data dir in astrometry configuration file.")); return dataDirs; } bool addAstrometryDataDir(QString dataDir) { //This will need to be fixed! //if(Options::astrometryIndexFileLocation() != dataDir) // Options::setAstrometryIndexFileLocation(dataDir); QString confPath = KSUtils::getAstrometryConfFilePath(); QStringList astrometryDataDirs = getAstrometryDataDirs(); QFile confFile(confPath); QString contents; if (confFile.open(QIODevice::ReadOnly) == false) { KSNotification::error( i18n("Astrometry Configuration File Read Error.")); return false; } else { QTextStream in(&confFile); QString line; bool foundSpot = false; while (!in.atEnd()) { line = in.readLine(); if (line.trimmed().startsWith(QLatin1String("add_path"))) { if (!foundSpot) { foundSpot = true; for(QString astrometryDataDir : astrometryDataDirs) contents += "add_path " + astrometryDataDir + '\n'; contents += "add_path " + dataDir + '\n'; } else { //Do not keep adding the other add_paths because they just got added in the seciton above. } } else { contents += line + '\n'; } } if(!foundSpot) { for(QString astrometryDataDir : astrometryDataDirs) contents += "add_path " + astrometryDataDir + '\n'; contents += "add_path " + dataDir + '\n'; } confFile.close(); if (confFile.open(QIODevice::WriteOnly) == false) { KSNotification::error( i18n("Internal Astrometry Configuration File Write Error.")); return false; } else { QTextStream out(&confFile); out << contents; confFile.close(); } } return true; } bool removeAstrometryDataDir(QString dataDir) { QString confPath = KSUtils::getAstrometryConfFilePath(); QStringList astrometryDataDirs = getAstrometryDataDirs(); QFile confFile(confPath); QString contents; if (confFile.open(QIODevice::ReadOnly) == false) { KSNotification::error( i18n("Astrometry Configuration File Read Error.")); return false; } else { QTextStream in(&confFile); QString line; while (!in.atEnd()) { line = in.readLine(); if (line.mid(9).trimmed() != dataDir) { contents += line + '\n'; } } confFile.close(); if (confFile.open(QIODevice::WriteOnly) == false) { KSNotification::error( i18n("Internal Astrometry Configuration File Write Error.")); return false; } else { QTextStream out(&confFile); out << contents; confFile.close(); } } return true; } QByteArray getJPLQueryString(const QByteArray &kind, const QByteArray &dataFields, const QVector &filters) { QByteArray query("obj_group=all&obj_kind=" + kind + "&obj_numbered=all&OBJ_field=0&ORB_field=0"); // Apply filters: for (int i = 0; i < filters.length(); i++) { QByteArray f = QByteArray::number(i + 1); query += "&c" + f + "_group=OBJ&c1_item=" + filters[i].item + "&c" + f + "_op=" + filters[i].op + "&c" + f + "_value=" + filters[i].value; } // Apply query data fields... query += "&c_fields=" + dataFields; query += "&table_format=CSV&max_rows=10&format_option=full&query=Generate%20Table&." "cgifields=format_option&.cgifields=field_list&.cgifields=obj_kind&.cgifie" "lds=obj_group&.cgifields=obj_numbered&.cgifields=combine_mode&.cgifields=" "ast_orbit_class&.cgifields=table_format&.cgifields=ORB_field_set&.cgifiel" "ds=OBJ_field_set&.cgifields=preset_field_set&.cgifields=com_orbit_class"; return query; } bool RAWToJPEG(const QString &rawImage, const QString &output, QString &errorMessage) { #ifndef HAVE_LIBRAW errorMessage = i18n("Unable to find dcraw and cjpeg. Please install the required tools to convert CR2/NEF to JPEG."); return false; #else int ret = 0; // Creation of image processing object LibRaw RawProcessor; // Let us open the file if ((ret = RawProcessor.open_file(rawImage.toLatin1().data())) != LIBRAW_SUCCESS) { errorMessage = i18n("Cannot open %1: %2", rawImage, libraw_strerror(ret)); RawProcessor.recycle(); return false; } // Let us unpack the thumbnail if ((ret = RawProcessor.unpack_thumb()) != LIBRAW_SUCCESS) { errorMessage = i18n("Cannot unpack_thumb %1: %2", rawImage, libraw_strerror(ret)); RawProcessor.recycle(); return false; } else // We have successfully unpacked the thumbnail, now let us write it to a file { //snprintf(thumbfn,sizeof(thumbfn),"%s.%s",av[i],T.tformat == LIBRAW_THUMBNAIL_JPEG ? "thumb.jpg" : "thumb.ppm"); if (LIBRAW_SUCCESS != (ret = RawProcessor.dcraw_thumb_writer(output.toLatin1().data()))) { errorMessage = i18n("Cannot write %s %1: %2", output, libraw_strerror(ret)); RawProcessor.recycle(); return false; } } return true; #endif } } diff --git a/kstars/data/icons/astap.ico b/kstars/data/icons/astap.ico new file mode 100644 index 000000000..45f28a9e5 Binary files /dev/null and b/kstars/data/icons/astap.ico differ diff --git a/kstars/data/kstars.qrc b/kstars/data/kstars.qrc index 26edb671c..69f6d8c92 100644 --- a/kstars/data/kstars.qrc +++ b/kstars/data/kstars.qrc @@ -1,76 +1,77 @@ icons/ekos_align.png icons/ekos_ccd.png icons/ekos_focus.png icons/ekos_guide.png icons/ekos_mount.png icons/ekos_scheduler.png icons/ekos_setup.png icons/fov.png icons/histogram.png icons/glstarbase.png icons/center_telescope.svg icons/center_telescope_red.svg icons/AlignFailure.svg icons/AlignSuccess.svg icons/AlignWarning.svg icons/astrometry.svg icons/stellarmate.svg icons/center_telescope_magenta.svg icons/dome-park.svg icons/dome-unpark.svg icons/star_profile.svg icons/astrometry-optional.svg icons/astrometry-recommended.svg icons/astrometry-required.svg indidrivers.xml qml/whatisinteresting/CategoryTitle.qml qml/whatisinteresting/DetailsItem.qml qml/whatisinteresting/downloadIcon.png qml/whatisinteresting/favoriteIcon.png qml/whatisinteresting/helpIcon.png qml/whatisinteresting/iconcredits.dat qml/whatisinteresting/inspectIcon.png qml/whatisinteresting/leftArrow.png qml/whatisinteresting/next.png qml/whatisinteresting/previous.png qml/whatisinteresting/reloadIcon.png qml/whatisinteresting/ScrollBar.qml qml/whatisinteresting/settingsIcon.png qml/whatisinteresting/visibleIcon.png qml/whatisinteresting/wiview.qml qml/mount/go-east.png qml/mount/go-north.png qml/mount/go-northeast.png qml/mount/go-northwest.png qml/mount/go-south.png qml/mount/go-southeast.png qml/mount/go-southwest.png qml/mount/go-west.png qml/mount/mountbox.qml qml/mount/stop.png icons/kstars_satellites_invisible.svg icons/kstars_satellites_visible.svg icons/cloud-online.svg icons/ekos_observatory.png icons/cfa.svg icons/pi.svg icons/atikbase.svg + icons/astap.ico kstars.knsrc kstarsui.rc fitsviewerui.rc noimage.png reticle12.png reticle24.png sm_animation.gif diff --git a/kstars/ekos/align/align.cpp b/kstars/ekos/align/align.cpp index 7c9ada0f7..b51573a48 100644 --- a/kstars/ekos/align/align.cpp +++ b/kstars/ekos/align/align.cpp @@ -1,6129 +1,6156 @@ /* Ekos Alignment Module Copyright (C) 2013 Jasem Mutlaq This application is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. */ #include "align.h" #include "alignadaptor.h" #include "alignview.h" #include "flagcomponent.h" #include "fov.h" #include "kstars.h" #include "kstarsdata.h" #include "ksuserdb.h" #include "offlineastrometryparser.h" #include "onlineastrometryparser.h" +#include "astapastrometryparser.h" #include "opsalign.h" +#include "opsastap.h" #include "opsastrometry.h" #include "opsastrometrycfg.h" #include "opsastrometryindexfiles.h" #include "Options.h" #include "remoteastrometryparser.h" #include "skymap.h" #include "skymapcomposite.h" #include "starobject.h" #include "auxiliary/QProgressIndicator.h" #include "auxiliary/ksmessagebox.h" #include "dialogs/finddialog.h" #include "ekos/manager.h" #include "ekos/auxiliary/darklibrary.h" #include "fitsviewer/fitsdata.h" #include "fitsviewer/fitstab.h" #include "indi/clientmanager.h" #include "indi/driverinfo.h" #include "indi/indifilter.h" #include "profileinfo.h" #include "ksnotification.h" #include #include #include #include #include #define PAH_CUTOFF_FOV 10 // Minimum FOV width in arcminutes for PAH to work #define MAXIMUM_SOLVER_ITERATIONS 10 #define AL_FORMAT_VERSION 1.0 namespace Ekos { // 30 arcminutes RA movement const double Align::RAMotion = 0.5; // Sidereal rate, degrees/s const double Align::SIDRATE = 0.004178; const QMap Align::PAHStages = { {PAH_IDLE, I18N_NOOP("Idle")}, {PAH_FIRST_CAPTURE, I18N_NOOP("First Capture"}), {PAH_FIND_CP, I18N_NOOP("Finding CP"}), {PAH_FIRST_ROTATE, I18N_NOOP("First Rotation"}), {PAH_SECOND_CAPTURE, I18N_NOOP("Second Capture"}), {PAH_SECOND_ROTATE, I18N_NOOP("Second Rotation"}), {PAH_THIRD_CAPTURE, I18N_NOOP("Third Capture"}), {PAH_STAR_SELECT, I18N_NOOP("Select Star"}), {PAH_PRE_REFRESH, I18N_NOOP("Select Refresh"}), {PAH_REFRESH, I18N_NOOP("Refreshing"}), {PAH_ERROR, I18N_NOOP("Error")}, }; Align::Align(ProfileInfo *activeProfile) : m_ActiveProfile(activeProfile) { setupUi(this); qRegisterMetaType("Ekos::AlignState"); qDBusRegisterMetaType(); new AlignAdaptor(this); QDBusConnection::sessionBus().registerObject("/KStars/Ekos/Align", this); dirPath = QDir::homePath(); //loadSlewMode = false; solverFOV.reset(new FOV()); solverFOV->setName(i18n("Solver FOV")); solverFOV->setLockCelestialPole(true); solverFOV->setColor(KStars::Instance()->data()->colorScheme()->colorNamed("SolverFOVColor").name()); sensorFOV.reset(new FOV()); sensorFOV->setLockCelestialPole(true); QAction *a = KStars::Instance()->actionCollection()->action("show_sensor_fov"); if (a) a->setEnabled(true); showFITSViewerB->setIcon( QIcon::fromTheme("kstars_fitsviewer")); showFITSViewerB->setAttribute(Qt::WA_LayoutUsesWidgetRect); connect(showFITSViewerB, &QPushButton::clicked, this, &Ekos::Align::showFITSViewer); toggleFullScreenB->setIcon( QIcon::fromTheme("view-fullscreen")); toggleFullScreenB->setShortcut(Qt::Key_F4); toggleFullScreenB->setAttribute(Qt::WA_LayoutUsesWidgetRect); connect(toggleFullScreenB, &QPushButton::clicked, this, &Ekos::Align::toggleAlignWidgetFullScreen); alignView = new AlignView(alignWidget, FITS_ALIGN); alignView->setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Expanding); alignView->setBaseSize(alignWidget->size()); alignView->createFloatingToolBar(); QVBoxLayout *vlayout = new QVBoxLayout(); vlayout->addWidget(alignView); alignWidget->setLayout(vlayout); connect(solveB, &QPushButton::clicked, this, &Ekos::Align::captureAndSolve); connect(stopB, &QPushButton::clicked, this, &Ekos::Align::abort); connect(measureAltB, &QPushButton::clicked, this, &Ekos::Align::measureAltError); connect(measureAzB, &QPushButton::clicked, this, &Ekos::Align::measureAzError); // Effective FOV Edit connect(FOVOut, &QLineEdit::editingFinished, this, &Align::syncFOV); connect(CCDCaptureCombo, static_cast(&QComboBox::activated), this, &Ekos::Align::setDefaultCCD); connect(CCDCaptureCombo, static_cast(&QComboBox::activated), this, &Ekos::Align::checkCCD); connect(correctAltB, &QPushButton::clicked, this, &Ekos::Align::correctAltError); connect(correctAzB, &QPushButton::clicked, this, &Ekos::Align::correctAzError); connect(loadSlewB, &QPushButton::clicked, [&]() { loadAndSlew(); }); FilterDevicesCombo->addItem("--"); connect(FilterDevicesCombo, static_cast(&QComboBox::activated), [ = ](const QString & text) { syncSettings(); Options::setDefaultAlignFW(text); }); connect(FilterDevicesCombo, static_cast(&QComboBox::activated), this, &Ekos::Align::checkFilter); connect(FilterPosCombo, static_cast(&QComboBox::activated), [ = ](int index) { syncSettings(); Options::setLockAlignFilterIndex(index); } ); connect(PAHSlewRateCombo, static_cast(&QComboBox::activated), [&](int index) { Options::setPAHMountSpeedIndex(index); }); gotoModeButtonGroup->setId(syncR, GOTO_SYNC); gotoModeButtonGroup->setId(slewR, GOTO_SLEW); gotoModeButtonGroup->setId(nothingR, GOTO_NOTHING); connect(gotoModeButtonGroup, static_cast(&QButtonGroup::buttonClicked), this, [ = ](int id) { this->currentGotoMode = static_cast(id); }); m_CaptureTimer.setSingleShot(true); m_CaptureTimer.setInterval(10000); connect(&m_CaptureTimer, &QTimer::timeout, [&]() { if (m_CaptureTimeoutCounter++ > 3) { appendLogText(i18n("Capture timed out.")); abort(); } else { ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); if (targetChip->isCapturing()) { targetChip->abortExposure(); m_CaptureTimer.start( m_CaptureTimer.interval() * 2); } else captureAndSolve(); } }); m_AlignTimer.setSingleShot(true); m_AlignTimer.setInterval(Options::astrometryTimeout() * 1000); connect(&m_AlignTimer, &QTimer::timeout, this, &Ekos::Align::checkAlignmentTimeout); currentGotoMode = static_cast(Options::solverGotoOption()); gotoModeButtonGroup->button(currentGotoMode)->setChecked(true); editOptionsB->setIcon(QIcon::fromTheme("document-edit")); editOptionsB->setAttribute(Qt::WA_LayoutUsesWidgetRect); KConfigDialog *dialog = new KConfigDialog(this, "alignsettings", Options::self()); #ifdef Q_OS_OSX dialog->setWindowFlags(Qt::Tool | Qt::WindowStaysOnTopHint); #endif opsAlign = new OpsAlign(this); connect(opsAlign, &OpsAlign::settingsUpdated, this, &Ekos::Align::refreshAlignOptions); KPageWidgetItem *page = dialog->addPage(opsAlign, i18n("Astrometry.net")); page->setIcon(QIcon(":/icons/astrometry.svg")); opsAstrometry = new OpsAstrometry(this); page = dialog->addPage(opsAstrometry, i18n("Solver Options")); page->setIcon(QIcon::fromTheme("configure")); #ifndef Q_OS_WIN opsAstrometryCfg = new OpsAstrometryCfg(this); page = dialog->addPage(opsAstrometryCfg, i18n("Astrometry.cfg")); page->setIcon(QIcon::fromTheme("document-edit")); opsAstrometryIndexFiles = new OpsAstrometryIndexFiles(this); page = dialog->addPage(opsAstrometryIndexFiles, i18n("Index Files")); page->setIcon(QIcon::fromTheme("map-flat")); #endif + opsASTAP = new OpsASTAP(this); + page = dialog->addPage(opsASTAP, i18n("ASTAP")); + page->setIcon(QIcon(":/icons/astap.ico")); + connect(editOptionsB, &QPushButton::clicked, dialog, &QDialog::show); appendLogText(i18n("Idle.")); pi.reset(new QProgressIndicator(this)); stopLayout->addWidget(pi.get()); exposureIN->setValue(Options::alignExposure()); connect(exposureIN, static_cast(&QDoubleSpinBox::valueChanged), [&]() { syncSettings(); }); altStage = ALT_INIT; azStage = AZ_INIT; rememberSolverWCS = Options::astrometrySolverWCS(); rememberAutoWCS = Options::autoWCS(); +#if 0 // Online/Offline/Remote solver check solverTypeGroup->setId(onlineSolverR, SOLVER_ONLINE); solverTypeGroup->setId(offlineSolverR, SOLVER_OFFLINE); solverTypeGroup->setId(remoteSolverR, SOLVER_REMOTE); #ifdef Q_OS_WIN offlineSolverR->setEnabled(false); offlineSolverR->setToolTip( i18n("Offline solver is not supported under Windows. Please use either the Online or Remote solvers.")); #endif +#endif + + solverTypeGroup->setId(astapSolverR, SOLVER_ASTAP); + solverTypeGroup->setId(astrometrySolverR, SOLVER_ASTROMETRYNET); solverTypeGroup->button(Options::solverType())->setChecked(true); connect(solverTypeGroup, static_cast(&QButtonGroup::buttonClicked), this, &Align::setSolverType); + astrometryTypeCombo->addItem(i18n("Online")); +#ifndef Q_OS_WIN + astrometryTypeCombo->addItem(i18n("Offline")); +#endif + astrometryTypeCombo->addItem(i18n("Remote")); + switch (solverTypeGroup->checkedId()) { - case SOLVER_ONLINE: - onlineParser.reset(new Ekos::OnlineAstrometryParser()); - parser = onlineParser.get(); + case SOLVER_ASTAP: + astapParser.reset(new Ekos::ASTAPAstrometryParser()); + parser = astapParser.get(); break; - case SOLVER_OFFLINE: - offlineParser.reset(new OfflineAstrometryParser()); - parser = offlineParser.get(); - break; + case SOLVER_ASTROMETRYNET: + { + switch (astrometryTypeCombo->currentIndex()) + { + case SOLVER_ONLINE: + onlineParser.reset(new Ekos::OnlineAstrometryParser()); + parser = onlineParser.get(); + break; - case SOLVER_REMOTE: - remoteParser.reset(new RemoteAstrometryParser()); - parser = remoteParser.get(); - break; + case SOLVER_OFFLINE: + offlineParser.reset(new OfflineAstrometryParser()); + parser = offlineParser.get(); + break; + + case SOLVER_REMOTE: + remoteParser.reset(new RemoteAstrometryParser()); + parser = remoteParser.get(); + break; + } + } + break; } parser->setAlign(this); if (parser->init() == false) setEnabled(false); else { connect(parser, &Ekos::AstrometryParser::solverFinished, this, &Ekos::Align::solverFinished, Qt::UniqueConnection); connect(parser, &Ekos::AstrometryParser::solverFailed, this, &Ekos::Align::solverFailed, Qt::UniqueConnection); } //solverOptions->setText(Options::solverOptions()); // Which telescope info to use for FOV calculations //kcfg_solverOTA->setChecked(Options::solverOTA()); //guideScopeCCDs = Options::guideScopeCCDs(); FOVScopeCombo->setCurrentIndex(Options::solverScopeType()); connect(FOVScopeCombo, static_cast(&QComboBox::currentIndexChanged), this, &Ekos::Align::updateTelescopeType); //connect(FOVScopeCombo, SIGNAL(currentIndexChanged(int)), this, SIGNAL(newFOVTelescopeType(int))); accuracySpin->setValue(Options::solverAccuracyThreshold()); alignDarkFrameCheck->setChecked(Options::alignDarkFrame()); delaySpin->setValue(Options::settlingTime()); connect(delaySpin, &QSpinBox::editingFinished, this, &Ekos::Align::saveSettleTime); connect(binningCombo, static_cast(&QComboBox::currentIndexChanged), this, &Ekos::Align::setBinningIndex); // PAH Connections connect(this, &Align::PAHEnabled, [&](bool enabled) { PAHStartB->setEnabled(enabled); directionLabel->setEnabled(enabled); PAHDirectionCombo->setEnabled(enabled); PAHRotationSpin->setEnabled(enabled); PAHSlewRateCombo->setEnabled(enabled); PAHManual->setEnabled(enabled); }); connect(PAHStartB, &QPushButton::clicked, this, &Ekos::Align::startPAHProcess); // PAH StopB is just a shortcut for the regular stop connect(PAHStopB, &QPushButton::clicked, this, &Align::stopPAHProcess); connect(PAHCorrectionsNextB, &QPushButton::clicked, this, &Ekos::Align::setPAHCorrectionSelectionComplete); connect(PAHRefreshB, &QPushButton::clicked, this, &Ekos::Align::startPAHRefreshProcess); connect(PAHDoneB, &QPushButton::clicked, this, &Ekos::Align::setPAHRefreshComplete); // done buttons for manual slewing during polar alignment: connect(PAHfirstDone, &QPushButton::clicked, this, &Ekos::Align::setPAHSlewDone); connect(PAHsecondDone, &QPushButton::clicked, this, &Ekos::Align::setPAHSlewDone); if (solverOptions->text().contains("no-fits2fits")) appendLogText(i18n( "Warning: If using astrometry.net v0.68 or above, remove the --no-fits2fits from the astrometry options.")); hemisphere = KStarsData::Instance()->geo()->lat()->Degrees() > 0 ? NORTH_HEMISPHERE : SOUTH_HEMISPHERE; double accuracyRadius = accuracySpin->value(); alignPlot->setBackground(QBrush(Qt::black)); alignPlot->setSelectionTolerance(10); alignPlot->xAxis->setBasePen(QPen(Qt::white, 1)); alignPlot->yAxis->setBasePen(QPen(Qt::white, 1)); alignPlot->xAxis->setTickPen(QPen(Qt::white, 1)); alignPlot->yAxis->setTickPen(QPen(Qt::white, 1)); alignPlot->xAxis->setSubTickPen(QPen(Qt::white, 1)); alignPlot->yAxis->setSubTickPen(QPen(Qt::white, 1)); alignPlot->xAxis->setTickLabelColor(Qt::white); alignPlot->yAxis->setTickLabelColor(Qt::white); alignPlot->xAxis->setLabelColor(Qt::white); alignPlot->yAxis->setLabelColor(Qt::white); alignPlot->xAxis->setLabelFont(QFont(font().family(), 10)); alignPlot->yAxis->setLabelFont(QFont(font().family(), 10)); alignPlot->xAxis->setLabelPadding(2); alignPlot->yAxis->setLabelPadding(2); alignPlot->xAxis->grid()->setPen(QPen(QColor(140, 140, 140), 1, Qt::DotLine)); alignPlot->yAxis->grid()->setPen(QPen(QColor(140, 140, 140), 1, Qt::DotLine)); alignPlot->xAxis->grid()->setSubGridPen(QPen(QColor(80, 80, 80), 1, Qt::DotLine)); alignPlot->yAxis->grid()->setSubGridPen(QPen(QColor(80, 80, 80), 1, Qt::DotLine)); alignPlot->xAxis->grid()->setZeroLinePen(QPen(Qt::yellow)); alignPlot->yAxis->grid()->setZeroLinePen(QPen(Qt::yellow)); alignPlot->xAxis->setLabel(i18n("dRA (arcsec)")); alignPlot->yAxis->setLabel(i18n("dDE (arcsec)")); alignPlot->xAxis->setRange(-accuracyRadius * 3, accuracyRadius * 3); alignPlot->yAxis->setRange(-accuracyRadius * 3, accuracyRadius * 3); alignPlot->setInteractions(QCP::iRangeZoom); alignPlot->setInteraction(QCP::iRangeDrag, true); alignPlot->addGraph(); alignPlot->graph(0)->setLineStyle(QCPGraph::lsNone); alignPlot->graph(0)->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDisc, Qt::white, 15)); buildTarget(); connect(alignPlot, &QCustomPlot::mouseMove, this, &Ekos::Align::handlePointTooltip); connect(rightLayout, &QSplitter::splitterMoved, this, &Ekos::Align::handleVerticalPlotSizeChange); connect(alignSplitter, &QSplitter::splitterMoved, this, &Ekos::Align::handleHorizontalPlotSizeChange); connect(accuracySpin, static_cast(&QSpinBox::valueChanged), this, &Ekos::Align::buildTarget); alignPlot->resize(190, 190); alignPlot->replot(); solutionTable->setColumnWidth(0, 70); solutionTable->setColumnWidth(1, 75); solutionTable->setColumnWidth(2, 80); solutionTable->setColumnWidth(3, 30); solutionTable->setColumnWidth(4, 100); solutionTable->setColumnWidth(5, 100); clearAllSolutionsB->setIcon( QIcon::fromTheme("application-exit")); clearAllSolutionsB->setAttribute(Qt::WA_LayoutUsesWidgetRect); removeSolutionB->setIcon(QIcon::fromTheme("list-remove")); removeSolutionB->setAttribute(Qt::WA_LayoutUsesWidgetRect); exportSolutionsCSV->setIcon( QIcon::fromTheme("document-save-as")); exportSolutionsCSV->setAttribute(Qt::WA_LayoutUsesWidgetRect); autoScaleGraphB->setIcon(QIcon::fromTheme("zoom-fit-best")); autoScaleGraphB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.setupUi(&mountModelDialog); mountModelDialog.setWindowTitle("Mount Model Tool"); mountModelDialog.setWindowFlags(Qt::Tool | Qt::WindowStaysOnTopHint); mountModel.alignTable->setColumnWidth(0, 70); mountModel.alignTable->setColumnWidth(1, 75); mountModel.alignTable->setColumnWidth(2, 130); mountModel.alignTable->setColumnWidth(3, 30); mountModel.wizardAlignB->setIcon( QIcon::fromTheme("tools-wizard")); mountModel.wizardAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.clearAllAlignB->setIcon( QIcon::fromTheme("application-exit")); mountModel.clearAllAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.removeAlignB->setIcon(QIcon::fromTheme("list-remove")); mountModel.removeAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.addAlignB->setIcon(QIcon::fromTheme("list-add")); mountModel.addAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.findAlignB->setIcon(QIcon::fromTheme("edit-find")); mountModel.findAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.alignTable->verticalHeader()->setDragDropOverwriteMode(false); mountModel.alignTable->verticalHeader()->setSectionsMovable(true); mountModel.alignTable->verticalHeader()->setDragEnabled(true); mountModel.alignTable->verticalHeader()->setDragDropMode(QAbstractItemView::InternalMove); connect(mountModel.alignTable->verticalHeader(), SIGNAL(sectionMoved(int, int, int)), this, SLOT(moveAlignPoint(int, int, int))); mountModel.loadAlignB->setIcon( QIcon::fromTheme("document-open")); mountModel.loadAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.saveAsAlignB->setIcon( QIcon::fromTheme("document-save-as")); mountModel.saveAsAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.saveAlignB->setIcon( QIcon::fromTheme("document-save")); mountModel.saveAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.previewB->setIcon(QIcon::fromTheme("kstars_grid")); mountModel.previewB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.previewB->setCheckable(true); mountModel.sortAlignB->setIcon(QIcon::fromTheme("svn-update")); mountModel.sortAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.stopAlignB->setIcon( QIcon::fromTheme("media-playback-stop")); mountModel.stopAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); mountModel.startAlignB->setIcon( QIcon::fromTheme("media-playback-start")); mountModel.startAlignB->setAttribute(Qt::WA_LayoutUsesWidgetRect); connect(clearAllSolutionsB, &QPushButton::clicked, this, &Ekos::Align::slotClearAllSolutionPoints); connect(removeSolutionB, &QPushButton::clicked, this, &Ekos::Align::slotRemoveSolutionPoint); connect(exportSolutionsCSV, &QPushButton::clicked, this, &Ekos::Align::exportSolutionPoints); connect(autoScaleGraphB, &QPushButton::clicked, this, &Ekos::Align::slotAutoScaleGraph); connect(mountModelB, &QPushButton::clicked, this, &Ekos::Align::slotMountModel); connect(solutionTable, &QTableWidget::cellClicked, this, &Ekos::Align::selectSolutionTableRow); connect(mountModel.wizardAlignB, &QPushButton::clicked, this, &Ekos::Align::slotWizardAlignmentPoints); connect(mountModel.alignTypeBox, static_cast(&QComboBox::currentIndexChanged), this, &Ekos::Align::alignTypeChanged); connect(mountModel.starListBox, static_cast(&QComboBox::currentIndexChanged), this, &Ekos::Align::slotStarSelected); connect(mountModel.greekStarListBox, static_cast(&QComboBox::currentIndexChanged), this, &Ekos::Align::slotStarSelected); connect(mountModel.loadAlignB, &QPushButton::clicked, this, &Ekos::Align::slotLoadAlignmentPoints); connect(mountModel.saveAsAlignB, &QPushButton::clicked, this, &Ekos::Align::slotSaveAsAlignmentPoints); connect(mountModel.saveAlignB, &QPushButton::clicked, this, &Ekos::Align::slotSaveAlignmentPoints); connect(mountModel.clearAllAlignB, &QPushButton::clicked, this, &Ekos::Align::slotClearAllAlignPoints); connect(mountModel.removeAlignB, &QPushButton::clicked, this, &Ekos::Align::slotRemoveAlignPoint); connect(mountModel.addAlignB, &QPushButton::clicked, this, &Ekos::Align::slotAddAlignPoint); connect(mountModel.findAlignB, &QPushButton::clicked, this, &Ekos::Align::slotFindAlignObject); connect(mountModel.sortAlignB, &QPushButton::clicked, this, &Ekos::Align::slotSortAlignmentPoints); connect(mountModel.previewB, &QPushButton::clicked, this, &Ekos::Align::togglePreviewAlignPoints); connect(mountModel.stopAlignB, &QPushButton::clicked, this, &Ekos::Align::resetAlignmentProcedure); connect(mountModel.startAlignB, &QPushButton::clicked, this, &Ekos::Align::startStopAlignmentProcedure); //Note: This is to prevent a button from being called the default button //and then executing when the user hits the enter key such as when on a Text Box QList qButtons = findChildren(); for (auto &button : qButtons) button->setAutoDefault(false); } Align::~Align() { if (alignWidget->parent() == nullptr) toggleAlignWidgetFullScreen(); // Remove temporary FITS files left before by the solver QDir dir(QDir::tempPath()); dir.setNameFilters(QStringList() << "fits*" << "tmp.*"); dir.setFilter(QDir::Files); for (auto &dirFile : dir.entryList()) dir.remove(dirFile); } void Align::selectSolutionTableRow(int row, int column) { Q_UNUSED(column); solutionTable->selectRow(row); for (int i = 0; i < alignPlot->itemCount(); i++) { QCPAbstractItem *abstractItem = alignPlot->item(i); if (abstractItem) { QCPItemText *item = qobject_cast(abstractItem); if (item) { if (i == row) { item->setColor(Qt::black); item->setBrush(Qt::yellow); } else { item->setColor(Qt::red); item->setBrush(Qt::white); } } } } alignPlot->replot(); } void Align::handleHorizontalPlotSizeChange() { alignPlot->xAxis->setScaleRatio(alignPlot->yAxis, 1.0); alignPlot->replot(); } void Align::handleVerticalPlotSizeChange() { alignPlot->yAxis->setScaleRatio(alignPlot->xAxis, 1.0); alignPlot->replot(); } void Align::resizeEvent(QResizeEvent *event) { if (event->oldSize().width() != -1) { if (event->oldSize().width() != size().width()) handleHorizontalPlotSizeChange(); else if (event->oldSize().height() != size().height()) handleVerticalPlotSizeChange(); } else { QTimer::singleShot(10, this, &Ekos::Align::handleHorizontalPlotSizeChange); } } void Align::handlePointTooltip(QMouseEvent *event) { QCPAbstractItem *item = alignPlot->itemAt(event->localPos()); if (item) { QCPItemText *label = qobject_cast(item); if (label) { QString labelText = label->text(); int point = labelText.toInt() - 1; if (point < 0) return; QToolTip::showText(event->globalPos(), tr("" "" "" "" "" "" "" "" "" "" "" "" "" "" "" "" "
Object %L1: %L2
RA:%L3
DE:%L4
dRA:%L5
dDE:%L6
") .arg(point + 1) .arg(solutionTable->item(point, 2)->text(), solutionTable->item(point, 0)->text(), solutionTable->item(point, 1)->text(), solutionTable->item(point, 4)->text(), solutionTable->item(point, 5)->text()), alignPlot, alignPlot->rect()); } } } void Align::buildTarget() { double accuracyRadius = accuracySpin->value(); if (centralTarget) { concentricRings->data()->clear(); redTarget->data()->clear(); yellowTarget->data()->clear(); centralTarget->data()->clear(); } else { concentricRings = new QCPCurve(alignPlot->xAxis, alignPlot->yAxis); redTarget = new QCPCurve(alignPlot->xAxis, alignPlot->yAxis); yellowTarget = new QCPCurve(alignPlot->xAxis, alignPlot->yAxis); centralTarget = new QCPCurve(alignPlot->xAxis, alignPlot->yAxis); } const int pointCount = 200; QVector circleRings( pointCount * (5)); //Have to multiply by the number of rings, Rings at : 25%, 50%, 75%, 125%, 175% QVector circleCentral(pointCount); QVector circleYellow(pointCount); QVector circleRed(pointCount); int circleRingPt = 0; for (int i = 0; i < pointCount; i++) { double theta = i / static_cast(pointCount) * 2 * M_PI; for (double ring = 1; ring < 8; ring++) { if (ring != 4 && ring != 6) { if (i % (9 - static_cast(ring)) == 0) //This causes fewer points to draw on the inner circles. { circleRings[circleRingPt] = QCPCurveData(circleRingPt, accuracyRadius * ring * 0.25 * qCos(theta), accuracyRadius * ring * 0.25 * qSin(theta)); circleRingPt++; } } } circleCentral[i] = QCPCurveData(i, accuracyRadius * qCos(theta), accuracyRadius * qSin(theta)); circleYellow[i] = QCPCurveData(i, accuracyRadius * 1.5 * qCos(theta), accuracyRadius * 1.5 * qSin(theta)); circleRed[i] = QCPCurveData(i, accuracyRadius * 2 * qCos(theta), accuracyRadius * 2 * qSin(theta)); } concentricRings->setLineStyle(QCPCurve::lsNone); concentricRings->setScatterSkip(0); concentricRings->setScatterStyle(QCPScatterStyle(QCPScatterStyle::ssDisc, QColor(255, 255, 255, 150), 1)); concentricRings->data()->set(circleRings, true); redTarget->data()->set(circleRed, true); yellowTarget->data()->set(circleYellow, true); centralTarget->data()->set(circleCentral, true); concentricRings->setPen(QPen(Qt::white)); redTarget->setPen(QPen(Qt::red)); yellowTarget->setPen(QPen(Qt::yellow)); centralTarget->setPen(QPen(Qt::green)); concentricRings->setBrush(Qt::NoBrush); redTarget->setBrush(QBrush(QColor(255, 0, 0, 50))); yellowTarget->setBrush( QBrush(QColor(0, 255, 0, 50))); //Note this is actually yellow. It is green on top of red with equal opacity. centralTarget->setBrush(QBrush(QColor(0, 255, 0, 50))); if (alignPlot->size().width() > 0) alignPlot->replot(); } void Align::slotAutoScaleGraph() { double accuracyRadius = accuracySpin->value(); alignPlot->xAxis->setRange(-accuracyRadius * 3, accuracyRadius * 3); alignPlot->yAxis->setRange(-accuracyRadius * 3, accuracyRadius * 3); alignPlot->xAxis->setScaleRatio(alignPlot->yAxis, 1.0); alignPlot->replot(); } void Align::slotWizardAlignmentPoints() { int points = mountModel.alignPtNum->value(); if (points < 2) //The minimum is 2 because the wizard calculations require the calculation of an angle between points. return; //It should not be less than 2 because the minimum in the spin box is 2. int minAlt = mountModel.minAltBox->value(); KStarsData *data = KStarsData::Instance(); GeoLocation *geo = data->geo(); double lat = geo->lat()->Degrees(); if (mountModel.alignTypeBox->currentIndex() == OBJECT_FIXED_DEC) { double decAngle = mountModel.alignDec->value(); //Dec that never rises. if (lat > 0) { if (decAngle < lat - 90 + minAlt) //Min altitude possible at minAlt deg above horizon { KSNotification::sorry(i18n("DEC is below the altitude limit")); return; } } else { if (decAngle > lat + 90 - minAlt) //Max altitude possible at minAlt deg above horizon { KSNotification::sorry(i18n("DEC is below the altitude limit")); return; } } } //If there are less than 6 points, keep them all in the same DEC, //any more, set the num per row to be the sqrt of the points to evenly distribute in RA and DEC int numRAperDEC = 5; if (points > 5) numRAperDEC = qSqrt(points); //These calculations rely on modulus and int division counting beginning at 0, but the #s start at 1. int decPoints = (points - 1) / numRAperDEC + 1; int lastSetRAPoints = (points - 1) % numRAperDEC + 1; double decIncrement = -1; double initDEC = -1; SkyPoint spTest; if (mountModel.alignTypeBox->currentIndex() == OBJECT_FIXED_DEC) { decPoints = 1; initDEC = mountModel.alignDec->value(); decIncrement = 0; } else if (decPoints == 1) { decIncrement = 0; spTest.setAlt( minAlt); //The goal here is to get the point exactly West at the minAlt so that we can use that DEC spTest.setAz(270); spTest.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); initDEC = spTest.dec().Degrees(); } else { spTest.setAlt( minAlt + 10); //We don't want to be right at the minAlt because there would be only 1 point on the dec circle above the alt. spTest.setAz(180); spTest.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); initDEC = spTest.dec().Degrees(); if (lat > 0) decIncrement = (80 - initDEC) / (decPoints); //Don't quite want to reach NCP else decIncrement = (initDEC - 80) / (decPoints); //Don't quite want to reach SCP } for (int d = 0; d < decPoints; d++) { double initRA = -1; double raPoints = -1; double raIncrement = -1; double dec; if (lat > 0) dec = initDEC + d * decIncrement; else dec = initDEC - d * decIncrement; if (mountModel.alignTypeBox->currentIndex() == OBJECT_FIXED_DEC) { raPoints = points; } else if (d == decPoints - 1) { raPoints = lastSetRAPoints; } else { raPoints = numRAperDEC; } //This computes both the initRA and the raIncrement. calculateAngleForRALine(raIncrement, initRA, dec, lat, raPoints, minAlt); if (raIncrement == -1 || decIncrement == -1) { KSNotification::sorry(i18n("Point calculation error.")); return; } for (int i = 0; i < raPoints; i++) { double ra = initRA + i * raIncrement; const SkyObject *original = getWizardAlignObject(ra, dec); QString ra_report, dec_report, name; if (original) { SkyObject *o = original->clone(); o->updateCoords(data->updateNum(), true, data->geo()->lat(), data->lst(), false); getFormattedCoords(o->ra0().Hours(), o->dec0().Degrees(), ra_report, dec_report); name = o->longname(); } else { getFormattedCoords(dms(ra).Hours(), dec, ra_report, dec_report); name = i18n("Sky Point"); } int currentRow = mountModel.alignTable->rowCount(); mountModel.alignTable->insertRow(currentRow); QTableWidgetItem *RAReport = new QTableWidgetItem(); RAReport->setText(ra_report); RAReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 0, RAReport); QTableWidgetItem *DECReport = new QTableWidgetItem(); DECReport->setText(dec_report); DECReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 1, DECReport); QTableWidgetItem *ObjNameReport = new QTableWidgetItem(); ObjNameReport->setText(name); ObjNameReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 2, ObjNameReport); QTableWidgetItem *disabledBox = new QTableWidgetItem(); disabledBox->setFlags(Qt::ItemIsSelectable); mountModel.alignTable->setItem(currentRow, 3, disabledBox); } } if (previewShowing) updatePreviewAlignPoints(); } void Align::calculateAngleForRALine(double &raIncrement, double &initRA, double initDEC, double lat, double raPoints, double minAlt) { SkyPoint spEast; SkyPoint spWest; //Circumpolar dec if (fabs(initDEC) > (90 - fabs(lat) + minAlt)) { if (raPoints > 1) raIncrement = 360 / (raPoints - 1); else raIncrement = 0; initRA = 0; } else { dms AZEast, AZWest; calculateAZPointsForDEC(dms(initDEC), dms(minAlt), AZEast, AZWest); spEast.setAlt(minAlt); spEast.setAz(AZEast.Degrees()); spEast.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); spWest.setAlt(minAlt); spWest.setAz(AZWest.Degrees()); spWest.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); dms angleSep = spEast.ra().deltaAngle(spWest.ra()); //dms angleSep; // if (spEast.ra().Degrees() > spWest.ra().Degrees()) // angleSep = spEast.ra() - spWest.ra(); // else // angleSep = spEast.ra() + dms(360) - spWest.ra(); initRA = spWest.ra().Degrees(); if (raPoints > 1) raIncrement = fabs(angleSep.Degrees() / (raPoints - 1)); else raIncrement = 0; } } void Align::calculateAZPointsForDEC(dms dec, dms alt, dms &AZEast, dms &AZWest) { KStarsData *data = KStarsData::Instance(); GeoLocation *geo = data->geo(); double AZRad; double sindec, cosdec, sinlat, coslat; double sinAlt, cosAlt; geo->lat()->SinCos(sinlat, coslat); dec.SinCos(sindec, cosdec); alt.SinCos(sinAlt, cosAlt); double arg = (sindec - sinlat * sinAlt) / (coslat * cosAlt); AZRad = acos(arg); AZEast.setRadians(AZRad); AZWest.setRadians(2.0 * dms::PI - AZRad); } const SkyObject *Align::getWizardAlignObject(double ra, double dec) { double maxSearch = 5.0; switch (mountModel.alignTypeBox->currentIndex()) { case OBJECT_ANY_OBJECT: return KStarsData::Instance()->skyComposite()->objectNearest(new SkyPoint(dms(ra), dms(dec)), maxSearch); case OBJECT_FIXED_DEC: case OBJECT_FIXED_GRID: return nullptr; case OBJECT_ANY_STAR: return KStarsData::Instance()->skyComposite()->starNearest(new SkyPoint(dms(ra), dms(dec)), maxSearch); } // if (mountModel.alignTypeBox->currentText() == "Any Object") // return KStarsData::Instance()->skyComposite()->objectNearest(new SkyPoint(dms(ra), dms(dec)), maxSearch); // else if (mountModel.alignTypeBox->currentText() == "Fixed DEC" || // mountModel.alignTypeBox->currentText() == "Fixed Grid") // return nullptr; // else if (mountModel.alignTypeBox->currentText() == "Any Stars") // return KStarsData::Instance()->skyComposite()->starNearest(new SkyPoint(dms(ra), dms(dec)), maxSearch); //If they want named stars, then try to search for and return the closest Align Star to the requested location dms bestDiff = dms(360); double index = -1; for (int i = 0; i < alignStars.size(); i++) { const StarObject *star = alignStars.value(i); if (star) { if (star->hasName()) { SkyPoint thisPt(ra / 15.0, dec); dms thisDiff = thisPt.angularDistanceTo(star); if (thisDiff.Degrees() < bestDiff.Degrees()) { index = i; bestDiff = thisDiff; } } } } if (index == -1) return KStarsData::Instance()->skyComposite()->starNearest(new SkyPoint(dms(ra), dms(dec)), maxSearch); return alignStars.value(index); } void Align::alignTypeChanged(int alignType) { if (alignType == OBJECT_FIXED_DEC) mountModel.alignDec->setEnabled(true); else mountModel.alignDec->setEnabled(false); } void Align::slotStarSelected(const QString selectedStar) { for (int i = 0; i < alignStars.size(); i++) { const StarObject *star = alignStars.value(i); if (star) { if (star->name() == selectedStar || star->gname().simplified() == selectedStar) { int currentRow = mountModel.alignTable->rowCount(); mountModel.alignTable->insertRow(currentRow); QString ra_report, dec_report; getFormattedCoords(star->ra0().Hours(), star->dec0().Degrees(), ra_report, dec_report); QTableWidgetItem *RAReport = new QTableWidgetItem(); RAReport->setText(ra_report); RAReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 0, RAReport); QTableWidgetItem *DECReport = new QTableWidgetItem(); DECReport->setText(dec_report); DECReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 1, DECReport); QTableWidgetItem *ObjNameReport = new QTableWidgetItem(); ObjNameReport->setText(star->longname()); ObjNameReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 2, ObjNameReport); QTableWidgetItem *disabledBox = new QTableWidgetItem(); disabledBox->setFlags(Qt::ItemIsSelectable); mountModel.alignTable->setItem(currentRow, 3, disabledBox); mountModel.starListBox->setCurrentIndex(0); mountModel.greekStarListBox->setCurrentIndex(0); return; } } } if (previewShowing) updatePreviewAlignPoints(); } void Align::generateAlignStarList() { alignStars.clear(); mountModel.starListBox->clear(); mountModel.greekStarListBox->clear(); KStarsData *data = KStarsData::Instance(); QVector> listStars; listStars.append(data->skyComposite()->objectLists(SkyObject::STAR)); for (int i = 0; i < listStars.size(); i++) { QPair pair = listStars.value(i); const StarObject *star = dynamic_cast(pair.second); if (star) { StarObject *alignStar = star->clone(); alignStar->updateCoords(data->updateNum(), true, data->geo()->lat(), data->lst(), false); alignStars.append(alignStar); } } QStringList boxNames; QStringList greekBoxNames; for (int i = 0; i < alignStars.size(); i++) { const StarObject *star = alignStars.value(i); if (star) { if (!isVisible(star)) { alignStars.remove(i); i--; } else { if (star->hasLatinName()) boxNames << star->name(); else { if (!star->gname().isEmpty()) greekBoxNames << star->gname().simplified(); } } } } boxNames.sort(Qt::CaseInsensitive); boxNames.removeDuplicates(); greekBoxNames.removeDuplicates(); qSort(greekBoxNames.begin(), greekBoxNames.end(), [](const QString & a, const QString & b) { QStringList aParts = a.split(' '); QStringList bParts = b.split(' '); if (aParts.length() < 2 || bParts.length() < 2) return a < b; //This should not happen, they should all have 2 words in the string. if (aParts[1] == bParts[1]) { return aParts[0] < bParts[0]; //This compares the greek letter when the constellation is the same } else return aParts[1] < bParts[1]; //This compares the constellation names }); mountModel.starListBox->addItem("Select one:"); mountModel.greekStarListBox->addItem("Select one:"); for (int i = 0; i < boxNames.size(); i++) mountModel.starListBox->addItem(boxNames.at(i)); for (int i = 0; i < greekBoxNames.size(); i++) mountModel.greekStarListBox->addItem(greekBoxNames.at(i)); } bool Align::isVisible(const SkyObject *so) { return (getAltitude(so) > 30); } double Align::getAltitude(const SkyObject *so) { KStarsData *data = KStarsData::Instance(); SkyPoint sp = so->recomputeCoords(data->ut(), data->geo()); //check altitude of object at this time. sp.EquatorialToHorizontal(data->lst(), data->geo()->lat()); return sp.alt().Degrees(); } void Align::togglePreviewAlignPoints() { previewShowing = !previewShowing; mountModel.previewB->setChecked(previewShowing); updatePreviewAlignPoints(); } void Align::updatePreviewAlignPoints() { FlagComponent *flags = KStarsData::Instance()->skyComposite()->flags(); for (int i = 0; i < flags->size(); i++) { if (flags->label(i).startsWith(QLatin1String("Align"))) { flags->remove(i); i--; } } if (previewShowing) { for (int i = 0; i < mountModel.alignTable->rowCount(); i++) { QTableWidgetItem *raCell = mountModel.alignTable->item(i, 0); QTableWidgetItem *deCell = mountModel.alignTable->item(i, 1); QTableWidgetItem *objNameCell = mountModel.alignTable->item(i, 2); if (raCell && deCell && objNameCell) { QString raString = raCell->text(); QString deString = deCell->text(); dms raDMS = dms::fromString(raString, false); dms decDMS = dms::fromString(deString, true); QString objString = objNameCell->text(); SkyPoint flagPoint(raDMS, decDMS); flags->add(flagPoint, "J2000", "Default", "Align " + QString::number(i + 1) + ' ' + objString, "white"); } } } KStars::Instance()->map()->forceUpdate(true); } void Align::slotLoadAlignmentPoints() { QUrl fileURL = QFileDialog::getOpenFileUrl(&mountModelDialog, i18n("Open Ekos Alignment List"), alignURLPath, "Ekos AlignmentList (*.eal)"); if (fileURL.isEmpty()) return; if (fileURL.isValid() == false) { QString message = i18n("Invalid URL: %1", fileURL.toLocalFile()); KSNotification::sorry(message, i18n("Invalid URL")); return; } alignURLPath = QUrl(fileURL.url(QUrl::RemoveFilename)); loadAlignmentPoints(fileURL.toLocalFile()); if (previewShowing) updatePreviewAlignPoints(); } bool Align::loadAlignmentPoints(const QString &fileURL) { QFile sFile; sFile.setFileName(fileURL); if (!sFile.open(QIODevice::ReadOnly)) { QString message = i18n("Unable to open file %1", fileURL); KSNotification::sorry(message, i18n("Could Not Open File")); return false; } mountModel.alignTable->setRowCount(0); LilXML *xmlParser = newLilXML(); char errmsg[MAXRBUF]; XMLEle *root = nullptr; char c; while (sFile.getChar(&c)) { root = readXMLEle(xmlParser, c, errmsg); if (root) { double sqVersion = atof(findXMLAttValu(root, "version")); if (sqVersion < AL_FORMAT_VERSION) { appendLogText(i18n("Deprecated sequence file format version %1. Please construct a new sequence file.", sqVersion)); return false; } XMLEle *ep = nullptr; XMLEle *subEP = nullptr; int currentRow = 0; for (ep = nextXMLEle(root, 1); ep != nullptr; ep = nextXMLEle(root, 0)) { if (!strcmp(tagXMLEle(ep), "AlignmentPoint")) { mountModel.alignTable->insertRow(currentRow); subEP = findXMLEle(ep, "RA"); if (subEP) { QTableWidgetItem *RAReport = new QTableWidgetItem(); RAReport->setText(pcdataXMLEle(subEP)); RAReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 0, RAReport); } else return false; subEP = findXMLEle(ep, "DE"); if (subEP) { QTableWidgetItem *DEReport = new QTableWidgetItem(); DEReport->setText(pcdataXMLEle(subEP)); DEReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 1, DEReport); } else return false; subEP = findXMLEle(ep, "NAME"); if (subEP) { QTableWidgetItem *ObjReport = new QTableWidgetItem(); ObjReport->setText(pcdataXMLEle(subEP)); ObjReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 2, ObjReport); } else return false; } currentRow++; } return true; } } return false; } void Align::slotSaveAsAlignmentPoints() { alignURL.clear(); slotSaveAlignmentPoints(); } void Align::slotSaveAlignmentPoints() { QUrl backupCurrent = alignURL; if (alignURL.toLocalFile().startsWith(QLatin1String("/tmp/")) || alignURL.toLocalFile().contains("/Temp")) alignURL.clear(); if (alignURL.isEmpty()) { alignURL = QFileDialog::getSaveFileUrl(&mountModelDialog, i18n("Save Ekos Alignment List"), alignURLPath, "Ekos Alignment List (*.eal)"); // if user presses cancel if (alignURL.isEmpty()) { alignURL = backupCurrent; return; } alignURLPath = QUrl(alignURL.url(QUrl::RemoveFilename)); if (alignURL.toLocalFile().endsWith(QLatin1String(".eal")) == false) alignURL.setPath(alignURL.toLocalFile() + ".eal"); if (QFile::exists(alignURL.toLocalFile())) { int r = KMessageBox::warningContinueCancel(nullptr, i18n("A file named \"%1\" already exists. " "Overwrite it?", alignURL.fileName()), i18n("Overwrite File?"), KStandardGuiItem::overwrite()); if (r == KMessageBox::Cancel) return; } } if (alignURL.isValid()) { if ((saveAlignmentPoints(alignURL.toLocalFile())) == false) { KSNotification::error(i18n("Failed to save alignment list"), i18n("Save")); return; } } else { QString message = i18n("Invalid URL: %1", alignURL.url()); KSNotification::sorry(message, i18n("Invalid URL")); } } bool Align::saveAlignmentPoints(const QString &path) { QFile file; file.setFileName(path); if (!file.open(QIODevice::WriteOnly)) { QString message = i18n("Unable to write to file %1", path); KSNotification::sorry(message, i18n("Could Not Open File")); return false; } QTextStream outstream(&file); outstream << "" << endl; outstream << "" << endl; for (int i = 0; i < mountModel.alignTable->rowCount(); i++) { QTableWidgetItem *raCell = mountModel.alignTable->item(i, 0); QTableWidgetItem *deCell = mountModel.alignTable->item(i, 1); QTableWidgetItem *objNameCell = mountModel.alignTable->item(i, 2); if (!raCell || !deCell || !objNameCell) return false; QString raString = raCell->text(); QString deString = deCell->text(); QString objString = objNameCell->text(); outstream << "" << endl; outstream << "" << raString << "" << endl; outstream << "" << deString << "" << endl; outstream << "" << objString << "" << endl; outstream << "" << endl; } outstream << "" << endl; appendLogText(i18n("Alignment List saved to %1", path)); file.close(); return true; } void Align::slotSortAlignmentPoints() { int firstAlignmentPt = findClosestAlignmentPointToTelescope(); if (firstAlignmentPt != -1) { swapAlignPoints(firstAlignmentPt, 0); } for (int i = 0; i < mountModel.alignTable->rowCount() - 1; i++) { int nextAlignmentPoint = findNextAlignmentPointAfter(i); if (nextAlignmentPoint != -1) { swapAlignPoints(nextAlignmentPoint, i + 1); } } if (previewShowing) updatePreviewAlignPoints(); } int Align::findClosestAlignmentPointToTelescope() { dms bestDiff = dms(360); double index = -1; for (int i = 0; i < mountModel.alignTable->rowCount(); i++) { QTableWidgetItem *raCell = mountModel.alignTable->item(i, 0); QTableWidgetItem *deCell = mountModel.alignTable->item(i, 1); if (raCell && deCell) { dms raDMS = dms::fromString(raCell->text(), false); dms deDMS = dms::fromString(deCell->text(), true); dms thisDiff = telescopeCoord.angularDistanceTo(new SkyPoint(raDMS, deDMS)); if (thisDiff.Degrees() < bestDiff.Degrees()) { index = i; bestDiff = thisDiff; } } } return index; } int Align::findNextAlignmentPointAfter(int currentSpot) { QTableWidgetItem *currentRACell = mountModel.alignTable->item(currentSpot, 0); QTableWidgetItem *currentDECell = mountModel.alignTable->item(currentSpot, 1); if (currentRACell && currentDECell) { dms thisRADMS = dms::fromString(currentRACell->text(), false); dms thisDEDMS = dms::fromString(currentDECell->text(), true); SkyPoint thisPt(thisRADMS, thisDEDMS); dms bestDiff = dms(360); double index = -1; for (int i = currentSpot + 1; i < mountModel.alignTable->rowCount(); i++) { QTableWidgetItem *raCell = mountModel.alignTable->item(i, 0); QTableWidgetItem *deCell = mountModel.alignTable->item(i, 1); if (raCell && deCell) { dms raDMS = dms::fromString(raCell->text(), false); dms deDMS = dms::fromString(deCell->text(), true); SkyPoint point(raDMS, deDMS); dms thisDiff = thisPt.angularDistanceTo(&point); if (thisDiff.Degrees() < bestDiff.Degrees()) { index = i; bestDiff = thisDiff; } } } return index; } else return -1; } void Align::exportSolutionPoints() { if (solutionTable->rowCount() == 0) return; QUrl exportFile = QFileDialog::getSaveFileUrl(KStars::Instance(), i18n("Export Solution Points"), alignURLPath, "CSV File (*.csv)"); if (exportFile.isEmpty()) // if user presses cancel return; if (exportFile.toLocalFile().endsWith(QLatin1String(".csv")) == false) exportFile.setPath(exportFile.toLocalFile() + ".csv"); QString path = exportFile.toLocalFile(); if (QFile::exists(path)) { int r = KMessageBox::warningContinueCancel(nullptr, i18n("A file named \"%1\" already exists. " "Overwrite it?", exportFile.fileName()), i18n("Overwrite File?"), KStandardGuiItem::overwrite()); if (r == KMessageBox::Cancel) return; } if (!exportFile.isValid()) { QString message = i18n("Invalid URL: %1", exportFile.url()); KSNotification::sorry(message, i18n("Invalid URL")); return; } QFile file; file.setFileName(path); if (!file.open(QIODevice::WriteOnly)) { QString message = i18n("Unable to write to file %1", path); KSNotification::sorry(message, i18n("Could Not Open File")); return; } QTextStream outstream(&file); QString epoch = QString::number(KStarsDateTime::currentDateTime().epoch()); outstream << "RA (J" << epoch << "),DE (J" << epoch << "),RA (degrees),DE (degrees),Name,RA Error (arcsec),DE Error (arcsec)" << endl; for (int i = 0; i < solutionTable->rowCount(); i++) { QTableWidgetItem *raCell = solutionTable->item(i, 0); QTableWidgetItem *deCell = solutionTable->item(i, 1); QTableWidgetItem *objNameCell = solutionTable->item(i, 2); QTableWidgetItem *raErrorCell = solutionTable->item(i, 4); QTableWidgetItem *deErrorCell = solutionTable->item(i, 5); if (!raCell || !deCell || !objNameCell || !raErrorCell || !deErrorCell) { KSNotification::sorry(i18n("Error in table structure.")); return; } dms raDMS = dms::fromString(raCell->text(), false); dms deDMS = dms::fromString(deCell->text(), true); outstream << raDMS.toHMSString() << ',' << deDMS.toDMSString() << ',' << raDMS.Degrees() << ',' << deDMS.Degrees() << ',' << objNameCell->text() << ',' << raErrorCell->text().remove('\"') << ',' << deErrorCell->text().remove('\"') << endl; } appendLogText(i18n("Solution Points Saved as: %1", path)); file.close(); } void Align::slotClearAllSolutionPoints() { if (solutionTable->rowCount() == 0) return; // if (Options::autonomousMode() || KMessageBox::questionYesNo( // KStars::Instance(), i18n("Are you sure you want to clear all of the solution points?"), // i18n("Clear Solution Points"), KStandardGuiItem::yes(), KStandardGuiItem::no()) == KMessageBox::Yes) // { // solutionTable->setRowCount(0); // alignPlot->graph(0)->data()->clear(); // alignPlot->clearItems(); // buildTarget(); // slotAutoScaleGraph(); // } connect(KSMessageBox::Instance(), &KSMessageBox::accepted, this, [this]() { //QObject::disconnect(KSMessageBox::Instance(), &KSMessageBox::accepted, this, nullptr); KSMessageBox::Instance()->disconnect(this); solutionTable->setRowCount(0); alignPlot->graph(0)->data()->clear(); alignPlot->clearItems(); buildTarget(); slotAutoScaleGraph(); }); KSMessageBox::Instance()->questionYesNo(i18n("Are you sure you want to clear all of the solution points?"), i18n("Clear Solution Points"), 60); } void Align::slotClearAllAlignPoints() { if (mountModel.alignTable->rowCount() == 0) return; if (KMessageBox::questionYesNo(&mountModelDialog, i18n("Are you sure you want to clear all the alignment points?"), i18n("Clear Align Points")) == KMessageBox::Yes) mountModel.alignTable->setRowCount(0); if (previewShowing) updatePreviewAlignPoints(); } void Align::slotRemoveSolutionPoint() { QCPAbstractItem *abstractItem = alignPlot->item(solutionTable->currentRow()); if (abstractItem) { QCPItemText *item = qobject_cast(abstractItem); if (item) { double point = item->position->key(); alignPlot->graph(0)->data()->remove(point); } } alignPlot->removeItem(solutionTable->currentRow()); for (int i = 0; i < alignPlot->itemCount(); i++) { QCPAbstractItem *abstractItem = alignPlot->item(i); if (abstractItem) { QCPItemText *item = qobject_cast(abstractItem); if (item) item->setText(QString::number(i + 1)); } } solutionTable->removeRow(solutionTable->currentRow()); alignPlot->replot(); } void Align::slotRemoveAlignPoint() { mountModel.alignTable->removeRow(mountModel.alignTable->currentRow()); if (previewShowing) updatePreviewAlignPoints(); } void Align::moveAlignPoint(int logicalIndex, int oldVisualIndex, int newVisualIndex) { Q_UNUSED(logicalIndex); for (int i = 0; i < mountModel.alignTable->columnCount(); i++) { QTableWidgetItem *oldItem = mountModel.alignTable->takeItem(oldVisualIndex, i); QTableWidgetItem *newItem = mountModel.alignTable->takeItem(newVisualIndex, i); mountModel.alignTable->setItem(newVisualIndex, i, oldItem); mountModel.alignTable->setItem(oldVisualIndex, i, newItem); } mountModel.alignTable->verticalHeader()->blockSignals(true); mountModel.alignTable->verticalHeader()->moveSection(newVisualIndex, oldVisualIndex); mountModel.alignTable->verticalHeader()->blockSignals(false); if (previewShowing) updatePreviewAlignPoints(); } void Align::swapAlignPoints(int firstPt, int secondPt) { for (int i = 0; i < mountModel.alignTable->columnCount(); i++) { QTableWidgetItem *firstPtItem = mountModel.alignTable->takeItem(firstPt, i); QTableWidgetItem *secondPtItem = mountModel.alignTable->takeItem(secondPt, i); mountModel.alignTable->setItem(firstPt, i, secondPtItem); mountModel.alignTable->setItem(secondPt, i, firstPtItem); } } void Align::slotMountModel() { generateAlignStarList(); SkyPoint spWest; spWest.setAlt(30); spWest.setAz(270); spWest.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); mountModel.alignDec->setValue(static_cast(spWest.dec().Degrees())); mountModelDialog.show(); } void Align::slotAddAlignPoint() { int currentRow = mountModel.alignTable->rowCount(); mountModel.alignTable->insertRow(currentRow); QTableWidgetItem *disabledBox = new QTableWidgetItem(); disabledBox->setFlags(Qt::ItemIsSelectable); mountModel.alignTable->setItem(currentRow, 3, disabledBox); } void Align::slotFindAlignObject() { KStarsData *data = KStarsData::Instance(); if (FindDialog::Instance()->exec() == QDialog::Accepted) { SkyObject *object = FindDialog::Instance()->targetObject(); if (object != nullptr) { SkyObject *o = object->clone(); o->updateCoords(data->updateNum(), true, data->geo()->lat(), data->lst(), false); int currentRow = mountModel.alignTable->rowCount(); mountModel.alignTable->insertRow(currentRow); QString ra_report, dec_report; getFormattedCoords(o->ra0().Hours(), o->dec0().Degrees(), ra_report, dec_report); QTableWidgetItem *RAReport = new QTableWidgetItem(); RAReport->setText(ra_report); RAReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 0, RAReport); QTableWidgetItem *DECReport = new QTableWidgetItem(); DECReport->setText(dec_report); DECReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 1, DECReport); QTableWidgetItem *ObjNameReport = new QTableWidgetItem(); ObjNameReport->setText(o->longname()); ObjNameReport->setTextAlignment(Qt::AlignHCenter); mountModel.alignTable->setItem(currentRow, 2, ObjNameReport); QTableWidgetItem *disabledBox = new QTableWidgetItem(); disabledBox->setFlags(Qt::ItemIsSelectable); mountModel.alignTable->setItem(currentRow, 3, disabledBox); } } if (previewShowing) updatePreviewAlignPoints(); } void Align::resetAlignmentProcedure() { mountModel.alignTable->setCellWidget(currentAlignmentPoint, 3, new QWidget()); QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setFlags(Qt::ItemIsSelectable); statusReport->setIcon(QIcon(":/icons/AlignWarning.svg")); mountModel.alignTable->setItem(currentAlignmentPoint, 3, statusReport); appendLogText(i18n("The Mount Model Tool is Reset.")); mountModel.startAlignB->setIcon( QIcon::fromTheme("media-playback-start")); mountModelRunning = false; currentAlignmentPoint = 0; abort(); } bool Align::alignmentPointsAreBad() { for (int i = 0; i < mountModel.alignTable->rowCount(); i++) { QTableWidgetItem *raCell = mountModel.alignTable->item(i, 0); if (!raCell) return true; QString raString = raCell->text(); if (dms().setFromString(raString, false) == false) return true; QTableWidgetItem *decCell = mountModel.alignTable->item(i, 1); if (!decCell) return true; QString decString = decCell->text(); if (dms().setFromString(decString, true) == false) return true; } return false; } void Align::startStopAlignmentProcedure() { if (!mountModelRunning) { if (mountModel.alignTable->rowCount() > 0) { if (alignmentPointsAreBad()) { KSNotification::error(i18n("Please Check the Alignment Points.")); return; } if (currentGotoMode == GOTO_NOTHING) { int r = KMessageBox::warningContinueCancel( nullptr, i18n("In the Align Module, \"Nothing\" is Selected for the Solver Action. This means that the " "mount model tool will not sync/align your mount but will only report the pointing model " "errors. Do you wish to continue?"), i18n("Pointing Model Report Only?"), KStandardGuiItem::cont(), KStandardGuiItem::cancel(), "nothing_selected_warning"); if (r == KMessageBox::Cancel) return; } if (currentAlignmentPoint == 0) { for (int row = 0; row < mountModel.alignTable->rowCount(); row++) { QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setIcon(QIcon()); mountModel.alignTable->setItem(row, 3, statusReport); } } mountModel.startAlignB->setIcon( QIcon::fromTheme("media-playback-pause")); mountModelRunning = true; appendLogText(i18n("The Mount Model Tool is Starting.")); startAlignmentPoint(); } } else { mountModel.startAlignB->setIcon( QIcon::fromTheme("media-playback-start")); mountModel.alignTable->setCellWidget(currentAlignmentPoint, 3, new QWidget()); appendLogText(i18n("The Mount Model Tool is Paused.")); abort(); mountModelRunning = false; QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setFlags(Qt::ItemIsSelectable); statusReport->setIcon(QIcon(":/icons/AlignWarning.svg")); mountModel.alignTable->setItem(currentAlignmentPoint, 3, statusReport); } } void Align::startAlignmentPoint() { if (mountModelRunning && currentAlignmentPoint >= 0 && currentAlignmentPoint < mountModel.alignTable->rowCount()) { QTableWidgetItem *raCell = mountModel.alignTable->item(currentAlignmentPoint, 0); QString raString = raCell->text(); dms raDMS = dms::fromString(raString, false); double ra = raDMS.Hours(); QTableWidgetItem *decCell = mountModel.alignTable->item(currentAlignmentPoint, 1); QString decString = decCell->text(); dms decDMS = dms::fromString(decString, true); double dec = decDMS.Degrees(); QProgressIndicator *alignIndicator = new QProgressIndicator(this); mountModel.alignTable->setCellWidget(currentAlignmentPoint, 3, alignIndicator); alignIndicator->startAnimation(); targetCoord.setRA0(ra); targetCoord.setDec0(dec); targetCoord.updateCoordsNow(KStarsData::Instance()->updateNum()); Slew(); } } void Align::finishAlignmentPoint(bool solverSucceeded) { if (mountModelRunning && currentAlignmentPoint >= 0 && currentAlignmentPoint < mountModel.alignTable->rowCount()) { mountModel.alignTable->setCellWidget(currentAlignmentPoint, 3, new QWidget()); QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setFlags(Qt::ItemIsSelectable); if (solverSucceeded) statusReport->setIcon(QIcon(":/icons/AlignSuccess.svg")); else statusReport->setIcon(QIcon(":/icons/AlignFailure.svg")); mountModel.alignTable->setItem(currentAlignmentPoint, 3, statusReport); currentAlignmentPoint++; if (currentAlignmentPoint < mountModel.alignTable->rowCount()) { startAlignmentPoint(); } else { mountModelRunning = false; mountModel.startAlignB->setIcon( QIcon::fromTheme("media-playback-start")); appendLogText(i18n("The Mount Model Tool is Finished.")); currentAlignmentPoint = 0; } } } bool Align::isParserOK() { bool rc = parser->init(); if (rc) { connect(parser, &AstrometryParser::solverFinished, this, &Ekos::Align::solverFinished, Qt::UniqueConnection); connect(parser, &AstrometryParser::solverFailed, this, &Ekos::Align::solverFailed, Qt::UniqueConnection); } return rc; } void Align::checkAlignmentTimeout() { if (loadSlewState != IPS_IDLE || ++solverIterations == MAXIMUM_SOLVER_ITERATIONS) abort(); else if (loadSlewState == IPS_IDLE) { appendLogText(i18n("Solver timed out.")); parser->stopSolver(); captureAndSolve(); } // TODO must also account for loadAndSlew. Retain file name } void Align::setSolverType(int type) { if (sender() == nullptr && type >= 0 && type <= 2) solverTypeGroup->button(type)->setChecked(true); syncSettings(); Options::setSolverType(type); switch (type) { case SOLVER_ONLINE: loadSlewB->setEnabled(true); if (onlineParser.get() != nullptr) { parser = onlineParser.get(); return; } onlineParser.reset(new Ekos::OnlineAstrometryParser()); parser = onlineParser.get(); break; case SOLVER_OFFLINE: loadSlewB->setEnabled(true); if (offlineParser.get() != nullptr) { parser = offlineParser.get(); return; } offlineParser.reset(new Ekos::OfflineAstrometryParser()); parser = offlineParser.get(); break; case SOLVER_REMOTE: loadSlewB->setEnabled(true); if (remoteParser.get() != nullptr && remoteParserDevice != nullptr) { parser = remoteParser.get(); (dynamic_cast(parser))->setAstrometryDevice(remoteParserDevice); return; } remoteParser.reset(new Ekos::RemoteAstrometryParser()); parser = remoteParser.get(); (dynamic_cast(parser))->setAstrometryDevice(remoteParserDevice); if (currentCCD) (dynamic_cast(parser))->setCCD(currentCCD->getDeviceName()); break; } parser->setAlign(this); if (parser->init()) { connect(parser, &AstrometryParser::solverFinished, this, &Ekos::Align::solverFinished, Qt::UniqueConnection); connect(parser, &AstrometryParser::solverFailed, this, &Ekos::Align::solverFailed, Qt::UniqueConnection); } else parser->disconnect(); } bool Align::setCamera(const QString &device) { for (int i = 0; i < CCDCaptureCombo->count(); i++) if (device == CCDCaptureCombo->itemText(i)) { CCDCaptureCombo->setCurrentIndex(i); checkCCD(i); return true; } return false; } QString Align::camera() { if (currentCCD) return currentCCD->getDeviceName(); return QString(); } void Align::setDefaultCCD(QString ccd) { syncSettings(); Options::setDefaultAlignCCD(ccd); } void Align::checkCCD(int ccdNum) { if (ccdNum == -1 || ccdNum >= CCDs.count()) { ccdNum = CCDCaptureCombo->currentIndex(); if (ccdNum == -1) return; } currentCCD = CCDs.at(ccdNum); ISD::CCDChip *targetChip = currentCCD->getChip(ISD::CCDChip::PRIMARY_CCD); if (targetChip && targetChip->isCapturing()) return; if (solverTypeGroup->checkedId() == SOLVER_REMOTE && remoteParser.get() != nullptr) (dynamic_cast(remoteParser.get()))->setCCD(currentCCD->getDeviceName()); syncCCDInfo(); /* FOVScopeCombo->blockSignals(true); ISD::CCD::TelescopeType type = currentCCD->getTelescopeType(); FOVScopeCombo->setCurrentIndex(type == ISD::CCD::TELESCOPE_UNKNOWN ? 0 : type); FOVScopeCombo->blockSignals(false); */ syncTelescopeInfo(); } void Align::addCCD(ISD::GDInterface *newCCD) { if (CCDs.contains(static_cast(newCCD))) { syncCCDInfo(); return; } CCDs.append(static_cast(newCCD)); CCDCaptureCombo->addItem(newCCD->getDeviceName()); checkCCD(); syncSettings(); } void Align::setTelescope(ISD::GDInterface *newTelescope) { currentTelescope = static_cast(newTelescope); currentTelescope->disconnect(this); connect(currentTelescope, &ISD::GDInterface::numberUpdated, this, &Ekos::Align::processNumber, Qt::UniqueConnection); connect(currentTelescope, &ISD::GDInterface::Disconnected, this, [this]() { m_isRateSynced = false; }); if (m_isRateSynced == false) { PAHSlewRateCombo->blockSignals(true); PAHSlewRateCombo->clear(); PAHSlewRateCombo->addItems(currentTelescope->slewRates()); if (Options::pAHMountSpeedIndex() >= 0) PAHSlewRateCombo->setCurrentIndex(Options::pAHMountSpeedIndex()); else PAHSlewRateCombo->setCurrentIndex(currentTelescope->getSlewRate()); PAHSlewRateCombo->blockSignals(false); m_isRateSynced = !currentTelescope->slewRates().empty(); } syncTelescopeInfo(); } void Align::setDome(ISD::GDInterface *newDome) { currentDome = static_cast(newDome); connect(currentDome, &ISD::GDInterface::switchUpdated, this, &Ekos::Align::processSwitch, Qt::UniqueConnection); } void Align::removeDevice(ISD::GDInterface *device) { device->disconnect(this); if (currentTelescope && !strcmp(currentTelescope->getDeviceName(), device->getDeviceName())) { currentTelescope = nullptr; m_isRateSynced = false; } else if (currentDome && !strcmp(currentDome->getDeviceName(), device->getDeviceName())) { currentDome = nullptr; } else if (currentRotator && !strcmp(currentRotator->getDeviceName(), device->getDeviceName())) { currentRotator = nullptr; } if (CCDs.contains(static_cast(device))) { CCDs.removeAll(static_cast(device)); CCDCaptureCombo->removeItem(CCDCaptureCombo->findText(device->getDeviceName())); CCDCaptureCombo->removeItem(CCDCaptureCombo->findText(device->getDeviceName() + QString(" Guider"))); if (CCDs.empty()) currentCCD = nullptr; checkCCD(); } if (Filters.contains(static_cast(device))) { Filters.removeAll(static_cast(device)); filterManager->removeDevice(device); FilterDevicesCombo->removeItem(FilterDevicesCombo->findText(device->getDeviceName())); if (Filters.empty()) currentFilter = nullptr; checkFilter(); } } bool Align::syncTelescopeInfo() { if (currentTelescope == nullptr || currentTelescope->isConnected() == false) return false; canSync = currentTelescope->canSync(); if (canSync == false && syncR->isEnabled()) { slewR->setChecked(true); appendLogText(i18n("Mount does not support syncing.")); } syncR->setEnabled(canSync); INumberVectorProperty *nvp = currentTelescope->getBaseDevice()->getNumber("TELESCOPE_INFO"); if (nvp) { INumber *np = IUFindNumber(nvp, "TELESCOPE_APERTURE"); if (np && np->value > 0) primaryAperture = np->value; np = IUFindNumber(nvp, "GUIDER_APERTURE"); if (np && np->value > 0) guideAperture = np->value; aperture = primaryAperture; //if (currentCCD && currentCCD->getTelescopeType() == ISD::CCD::TELESCOPE_GUIDE) if (FOVScopeCombo->currentIndex() == ISD::CCD::TELESCOPE_GUIDE) aperture = guideAperture; np = IUFindNumber(nvp, "TELESCOPE_FOCAL_LENGTH"); if (np && np->value > 0) primaryFL = np->value; np = IUFindNumber(nvp, "GUIDER_FOCAL_LENGTH"); if (np && np->value > 0) guideFL = np->value; focal_length = primaryFL; //if (currentCCD && currentCCD->getTelescopeType() == ISD::CCD::TELESCOPE_GUIDE) if (FOVScopeCombo->currentIndex() == ISD::CCD::TELESCOPE_GUIDE) focal_length = guideFL; } if (focal_length == -1 || aperture == -1) return false; if (ccd_hor_pixel != -1 && ccd_ver_pixel != -1 && focal_length != -1 && aperture != -1) { FOVScopeCombo->setItemData( ISD::CCD::TELESCOPE_PRIMARY, i18nc("F-Number, Focal Length, Aperture", "F%1 Focal Length: %2 mm Aperture: %3 mm2", QString::number(primaryFL / primaryAperture, 'f', 1), QString::number(primaryFL, 'f', 2), QString::number(primaryAperture, 'f', 2)), Qt::ToolTipRole); FOVScopeCombo->setItemData( ISD::CCD::TELESCOPE_GUIDE, i18nc("F-Number, Focal Length, Aperture", "F%1 Focal Length: %2 mm Aperture: %3 mm2", QString::number(guideFL / guideAperture, 'f', 1), QString::number(guideFL, 'f', 2), QString::number(guideAperture, 'f', 2)), Qt::ToolTipRole); calculateFOV(); generateArgs(); return true; } return false; } void Align::setTelescopeInfo(double primaryFocalLength, double primaryAperture, double guideFocalLength, double guideAperture) { if (primaryFocalLength > 0) primaryFL = primaryFocalLength; if (guideFocalLength > 0) guideFL = guideFocalLength; if (primaryAperture > 0) this->primaryAperture = primaryAperture; if (guideAperture > 0) this->guideAperture = guideAperture; focal_length = primaryFL; if (currentCCD && currentCCD->getTelescopeType() == ISD::CCD::TELESCOPE_GUIDE) focal_length = guideFL; aperture = primaryAperture; if (currentCCD && currentCCD->getTelescopeType() == ISD::CCD::TELESCOPE_GUIDE) aperture = guideAperture; syncTelescopeInfo(); } void Align::syncCCDInfo() { INumberVectorProperty *nvp = nullptr; if (currentCCD == nullptr) return; if (useGuideHead) nvp = currentCCD->getBaseDevice()->getNumber("GUIDER_INFO"); else nvp = currentCCD->getBaseDevice()->getNumber("CCD_INFO"); if (nvp) { INumber *np = IUFindNumber(nvp, "CCD_PIXEL_SIZE_X"); if (np && np->value > 0) ccd_hor_pixel = ccd_ver_pixel = np->value; np = IUFindNumber(nvp, "CCD_PIXEL_SIZE_Y"); if (np && np->value > 0) ccd_ver_pixel = np->value; np = IUFindNumber(nvp, "CCD_PIXEL_SIZE_Y"); if (np && np->value > 0) ccd_ver_pixel = np->value; } ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); ISwitchVectorProperty *svp = currentCCD->getBaseDevice()->getSwitch("WCS_CONTROL"); if (svp) setWCSEnabled(Options::astrometrySolverWCS()); targetChip->setImageView(alignView, FITS_ALIGN); targetChip->getFrameMinMax(nullptr, nullptr, nullptr, nullptr, nullptr, &ccd_width, nullptr, &ccd_height); //targetChip->getFrame(&x,&y,&ccd_width,&ccd_height); binningCombo->setEnabled(targetChip->canBin()); if (targetChip->canBin()) { binningCombo->blockSignals(true); int binx = 1, biny = 1; targetChip->getMaxBin(&binx, &biny); binningCombo->clear(); for (int i = 0; i < binx; i++) binningCombo->addItem(QString("%1x%2").arg(i + 1).arg(i + 1)); // By default, set to maximum binning since the solver behaves better this way // solverBinningIndex is set by default to 4, but as soon as the user changes the binning, it changes // to whatever value the user selected. if (Options::solverBinningIndex() == 4 && binningCombo->count() <= 4) { binningCombo->setCurrentIndex(binningCombo->count() - 1); Options::setSolverBinningIndex(binningCombo->count() - 1); } else binningCombo->setCurrentIndex(Options::solverBinningIndex()); binningCombo->blockSignals(false); } if (ccd_hor_pixel == -1 || ccd_ver_pixel == -1) return; if (ccd_hor_pixel != -1 && ccd_ver_pixel != -1 && focal_length != -1 && aperture != -1) { calculateFOV(); generateArgs(); } } void Align::getFOVScale(double &fov_w, double &fov_h, double &fov_scale) { fov_w = fov_x; fov_h = fov_y; fov_scale = fov_pixscale; } QList Align::fov() { QList result; result << fov_x << fov_y << fov_pixscale; return result; } QList Align::cameraInfo() { QList result; result << ccd_width << ccd_height << ccd_hor_pixel << ccd_ver_pixel; return result; } QList Align::telescopeInfo() { QList result; result << focal_length << aperture; return result; } void Align::getCalculatedFOVScale(double &fov_w, double &fov_h, double &fov_scale) { // FOV in arcsecs fov_w = 206264.8062470963552 * ccd_width * ccd_hor_pixel / 1000.0 / focal_length; fov_h = 206264.8062470963552 * ccd_height * ccd_ver_pixel / 1000.0 / focal_length; // Pix Scale fov_scale = (fov_w * (Options::solverBinningIndex() + 1)) / ccd_width; // FOV in arcmins fov_w /= 60.0; fov_h /= 60.0; } void Align::calculateFOV() { // Calculate FOV // FOV in arcsecs fov_x = 206264.8062470963552 * ccd_width * ccd_hor_pixel / 1000.0 / focal_length; fov_y = 206264.8062470963552 * ccd_height * ccd_ver_pixel / 1000.0 / focal_length; // Pix Scale fov_pixscale = (fov_x * (Options::solverBinningIndex() + 1)) / ccd_width; // FOV in arcmins fov_x /= 60.0; fov_y /= 60.0; QString calculatedFOV = (QString("%1' x %2'").arg(fov_x, 0, 'g', 3).arg(fov_y, 0, 'g', 3)); // JM 2018-04-20 Above calculations are for RAW FOV. Starting from 2.9.5, we are using EFFECTIVE FOV // Which is the real FOV as measured from the plate solution. The effective FOVs are stored in the database and are unique // per profile/pixel_size/focal_length combinations. It defaults to 0' x 0' and gets updated after the first successful solver is complete. getEffectiveFOV(); if (fov_x == 0) { //FOVOut->setReadOnly(false); FOVOut->setToolTip(i18n("

Effective field of view size in arcminutes.

Please capture and solve once to measure the effective FOV or enter the values manually.

Calculated FOV: %1

", calculatedFOV)); } else { FOVOut->setToolTip(i18n("

Effective field of view size in arcminutes.

")); //FOVOut->setReadOnly(true); } solverFOV->setSize(fov_x, fov_y); sensorFOV->setSize(fov_x, fov_y); if (currentCCD) sensorFOV->setName(currentCCD->getDeviceName()); FOVOut->setText(QString("%1' x %2'").arg(fov_x, 0, 'g', 3).arg(fov_y, 0, 'g', 3)); if (((fov_x + fov_y) / 2.0) > PAH_CUTOFF_FOV) { if (isPAHReady == false) { PAHWidgets->setEnabled(true); isPAHReady = true; emit PAHEnabled(true); PAHWidgets->setToolTip(QString()); FOVDisabledLabel->hide(); } } else if (PAHWidgets->isEnabled()) { PAHWidgets->setEnabled(false); isPAHReady = false; emit PAHEnabled(false); PAHWidgets->setToolTip(i18n( "

Polar Alignment Helper tool requires the following:

1. German Equatorial Mount

2. FOV >" " 0.5 degrees

For small FOVs, use the Legacy Polar Alignment Tool.

")); FOVDisabledLabel->show(); } if (opsAstrometry->kcfg_AstrometryUseImageScale->isChecked()) { int unitType = opsAstrometry->kcfg_AstrometryImageScaleUnits->currentIndex(); // Degrees if (unitType == 0) { double fov_low = qMin(fov_x / 60, fov_y / 60); double fov_high = qMax(fov_x / 60, fov_y / 60); opsAstrometry->kcfg_AstrometryImageScaleLow->setValue(fov_low); opsAstrometry->kcfg_AstrometryImageScaleHigh->setValue(fov_high); Options::setAstrometryImageScaleLow(fov_low); Options::setAstrometryImageScaleHigh(fov_high); } // Arcmins else if (unitType == 1) { double fov_low = qMin(fov_x, fov_y); double fov_high = qMax(fov_x, fov_y); opsAstrometry->kcfg_AstrometryImageScaleLow->setValue(fov_low); opsAstrometry->kcfg_AstrometryImageScaleHigh->setValue(fov_high); Options::setAstrometryImageScaleLow(fov_low); Options::setAstrometryImageScaleHigh(fov_high); } // Arcsec per pixel else { opsAstrometry->kcfg_AstrometryImageScaleLow->setValue(fov_pixscale * 0.9); opsAstrometry->kcfg_AstrometryImageScaleHigh->setValue(fov_pixscale * 1.1); // 10% boundary Options::setAstrometryImageScaleLow(fov_pixscale * 0.9); Options::setAstrometryImageScaleHigh(fov_pixscale * 1.1); } } } QStringList Align::generateOptions(const QVariantMap &optionsMap) { // -O overwrite // -3 Expected RA // -4 Expected DEC // -5 Radius (deg) // -L lower scale of image in arcminutes // -H upper scale of image in arcminutes // -u aw set scale to be in arcminutes // -W solution.wcs name of solution file // apog1.jpg name of target file to analyze //solve-field -O -3 06:40:51 -4 +09:49:53 -5 1 -L 40 -H 100 -u aw -W solution.wcs apod1.jpg QStringList solver_args; // Start with always-used arguments solver_args << "-O" << "--no-plots"; // Now go over boolean options // noverify if (optionsMap.contains("noverify")) solver_args << "--no-verify"; // noresort if (optionsMap.contains("resort")) solver_args << "--resort"; // fits2fits if (optionsMap.contains("nofits2fits")) solver_args << "--no-fits2fits"; // downsample if (optionsMap.contains("downsample")) solver_args << "--downsample" << QString::number(optionsMap.value("downsample", 2).toInt()); // image scale low if (optionsMap.contains("scaleL")) solver_args << "-L" << QString::number(optionsMap.value("scaleL").toDouble()); // image scale high if (optionsMap.contains("scaleH")) solver_args << "-H" << QString::number(optionsMap.value("scaleH").toDouble()); // image scale units if (optionsMap.contains("scaleUnits")) solver_args << "-u" << optionsMap.value("scaleUnits").toString(); // RA if (optionsMap.contains("ra")) solver_args << "-3" << QString::number(optionsMap.value("ra").toDouble()); // DE if (optionsMap.contains("de")) solver_args << "-4" << QString::number(optionsMap.value("de").toDouble()); // Radius if (optionsMap.contains("radius")) solver_args << "-5" << QString::number(optionsMap.value("radius").toDouble()); // Custom if (optionsMap.contains("custom")) solver_args << optionsMap.value("custom").toString(); return solver_args; } //This will generate the high and low scale of the imager field size based on the stated units. void Align::generateFOVBounds(double fov_h, double fov_v, QString &fov_low, QString &fov_high) { double fov_lower, fov_upper; // let's stretch the boundaries by 5% fov_lower = ((fov_h < fov_v) ? (fov_h * 0.95) : (fov_v * 0.95)); fov_upper = ((fov_h > fov_v) ? (fov_h * 1.05) : (fov_v * 1.05)); //No need to do anything if they are aw, since that is the default fov_low = QString::number(fov_lower); fov_high = QString::number(fov_upper); } void Align::generateArgs() { // -O overwrite // -3 Expected RA // -4 Expected DEC // -5 Radius (deg) // -L lower scale of image in arcminutes // -H upper scale of image in arcminutes // -u aw set scale to be in arcminutes // -W solution.wcs name of solution file // apog1.jpg name of target file to analyze //solve-field -O -3 06:40:51 -4 +09:49:53 -5 1 -L 40 -H 100 -u aw -W solution.wcs apod1.jpg QVariantMap optionsMap; if (Options::astrometryUseNoVerify()) optionsMap["noverify"] = true; if (Options::astrometryUseResort()) optionsMap["resort"] = true; if (Options::astrometryUseNoFITS2FITS()) optionsMap["nofits2fits"] = true; if (Options::astrometryUseDownsample()) { if (Options::astrometryAutoDownsample() && ccd_width && ccd_height) { uint8_t bin = qMax(Options::solverBinningIndex() + 1, 1u); uint16_t w = ccd_width / bin; optionsMap["downsample"] = getSolverDownsample(w); } else optionsMap["downsample"] = Options::astrometryDownsample(); } if (Options::astrometryUseImageScale() && fov_x > 0 && fov_y > 0) { QString units = ImageScales[Options::astrometryImageScaleUnits()]; if (Options::astrometryAutoUpdateImageScale()) { QString fov_low, fov_high; double fov_w = fov_x; double fov_h = fov_y; if (units == "dw") { fov_w /= 60; fov_h /= 60; } else if (units == "app") { fov_w = fov_pixscale; fov_h = fov_pixscale; } generateFOVBounds(fov_w, fov_h, fov_low, fov_high); optionsMap["scaleL"] = fov_low; optionsMap["scaleH"] = fov_high; optionsMap["scaleUnits"] = units; } else { optionsMap["scaleL"] = Options::astrometryImageScaleLow(); optionsMap["scaleH"] = Options::astrometryImageScaleHigh(); optionsMap["scaleUnits"] = units; } } if (Options::astrometryUsePosition() && currentTelescope != nullptr) { double ra = 0, dec = 0; currentTelescope->getEqCoords(&ra, &dec); optionsMap["ra"] = ra * 15.0; optionsMap["de"] = dec; optionsMap["radius"] = Options::astrometryRadius(); } if (Options::astrometryCustomOptions().isEmpty() == false) optionsMap["custom"] = Options::astrometryCustomOptions(); QStringList solverArgs = generateOptions(optionsMap); QString options = solverArgs.join(" "); solverOptions->setText(options); solverOptions->setToolTip(options); } bool Align::captureAndSolve() { m_AlignTimer.stop(); m_CaptureTimer.stop(); #ifdef Q_OS_OSX if(solverTypeGroup->checkedId() == SOLVER_OFFLINE) { if(Options::useDefaultPython()) { if( !opsAlign->astropyInstalled() || !opsAlign->pythonInstalled() ) { KSNotification::error(i18n("Astrometry.net uses python3 and the astropy package for plate solving images offline. These were not detected on your system. Please go into the Align Options and either click the setup button to install them or uncheck the default button and enter the path to python3 on your system and manually install astropy.")); return false; } } } #endif if (currentCCD == nullptr) return false; if (currentCCD->isConnected() == false) { appendLogText(i18n("Error: lost connection to CCD.")); KSNotification::event(QLatin1String("AlignFailed"), i18n("Astrometry alignment failed"), KSNotification::EVENT_ALERT); return false; } if (currentCCD->isBLOBEnabled() == false) { currentCCD->setBLOBEnabled(true); } // If CCD Telescope Type does not match desired scope type, change it // but remember current value so that it can be reset once capture is complete or is aborted. if (currentCCD->getTelescopeType() != FOVScopeCombo->currentIndex()) { rememberTelescopeType = currentCCD->getTelescopeType(); currentCCD->setTelescopeType(static_cast(FOVScopeCombo->currentIndex())); } if (parser->init() == false) return false; if (focal_length == -1 || aperture == -1) { KSNotification::error(i18n("Telescope aperture and focal length are missing. Please check your driver settings and try again.")); return false; } if (ccd_hor_pixel == -1 || ccd_ver_pixel == -1) { KSNotification::error(i18n("CCD pixel size is missing. Please check your driver settings and try again.")); return false; } if (currentFilter != nullptr) { if (currentFilter->isConnected() == false) { appendLogText(i18n("Error: lost connection to filter wheel.")); return false; } int targetPosition = FilterPosCombo->currentIndex() + 1; if (targetPosition > 0 && targetPosition != currentFilterPosition) { filterPositionPending = true; filterManager->setFilterPosition(targetPosition); state = ALIGN_PROGRESS; return true; } } if (currentCCD->getDriverInfo()->getClientManager()->getBLOBMode(currentCCD->getDeviceName(), "CCD1") == B_NEVER) { if (KMessageBox::questionYesNo( nullptr, i18n("Image transfer is disabled for this camera. Would you like to enable it?")) == KMessageBox::Yes) { currentCCD->getDriverInfo()->getClientManager()->setBLOBMode(B_ONLY, currentCCD->getDeviceName(), "CCD1"); currentCCD->getDriverInfo()->getClientManager()->setBLOBMode(B_ONLY, currentCCD->getDeviceName(), "CCD2"); } else { return false; } } double seqExpose = exposureIN->value(); ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); if (focusState >= FOCUS_PROGRESS) { appendLogText(i18n("Cannot capture while focus module is busy. Retrying in 10 seconds...")); m_CaptureTimer.start(); return false; } if (targetChip->isCapturing()) { appendLogText(i18n("Cannot capture while CCD exposure is in progress. Retrying in 10 seconds...")); m_CaptureTimer.start(); return false; } alignView->setBaseSize(alignWidget->size()); connect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Align::newFITS); connect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Align::checkCCDExposureProgress); // In case of remote solver, check if we need to update active CCD if (solverTypeGroup->checkedId() == SOLVER_REMOTE && remoteParser.get() != nullptr) { // Update ACTIVE_CCD of the remote astrometry driver so it listens to BLOB emitted by the CCD ITextVectorProperty *activeDevices = remoteParserDevice->getBaseDevice()->getText("ACTIVE_DEVICES"); if (activeDevices) { IText *activeCCD = IUFindText(activeDevices, "ACTIVE_CCD"); if (QString(activeCCD->text) != CCDCaptureCombo->currentText()) { IUSaveText(activeCCD, CCDCaptureCombo->currentText().toLatin1().data()); remoteParserDevice->getDriverInfo()->getClientManager()->sendNewText(activeDevices); } } // Enable remote parse dynamic_cast(remoteParser.get())->setEnabled(true); QString options = solverOptions->text().simplified(); QStringList solverArgs = options.split(' '); dynamic_cast(remoteParser.get())->sendArgs(solverArgs); // If mount model was reset, we do not update targetCoord // since the RA/DE is now different immediately after the reset // so we still try to lock for the coordinates before the reset. if (solverIterations == 0 && mountModelReset == false) { double ra, dec; currentTelescope->getEqCoords(&ra, &dec); targetCoord.setRA(ra); targetCoord.setDec(dec); } mountModelReset = false; solverTimer.start(); } //else //{ if (currentCCD->getUploadMode() == ISD::CCD::UPLOAD_LOCAL) { rememberUploadMode = ISD::CCD::UPLOAD_LOCAL; currentCCD->setUploadMode(ISD::CCD::UPLOAD_CLIENT); } rememberCCDExposureLooping = currentCCD->isLooping(); if (rememberCCDExposureLooping) currentCCD->setExposureLoopingEnabled(false); // Remove temporary FITS files left before by the solver QDir dir(QDir::tempPath()); dir.setNameFilters(QStringList() << "fits*" << "tmp.*"); dir.setFilter(QDir::Files); for (auto &dirFile : dir.entryList()) dir.remove(dirFile); //} currentCCD->setTransformFormat(ISD::CCD::FORMAT_FITS); targetChip->resetFrame(); targetChip->setBatchMode(false); targetChip->setCaptureMode(FITS_ALIGN); targetChip->setFrameType(FRAME_LIGHT); int bin = Options::solverBinningIndex() + 1; targetChip->setBinning(bin, bin); // In case we're in refresh phase of the polar alignment helper then we use capture value from there if (pahStage == PAH_REFRESH) targetChip->capture(PAHExposure->value()); else targetChip->capture(seqExpose); Options::setAlignExposure(seqExpose); solveB->setEnabled(false); stopB->setEnabled(true); pi->startAnimation(); differentialSlewingActivated = false; state = ALIGN_PROGRESS; emit newStatus(state); // If we're just refreshing, then we're done if (pahStage == PAH_REFRESH) return true; appendLogText(i18n("Capturing image...")); //This block of code will create the row in the solution table and populate RA, DE, and object name. //It also starts the progress indicator. double ra, dec; currentTelescope->getEqCoords(&ra, &dec); if (loadSlewState == IPS_IDLE) { int currentRow = solutionTable->rowCount(); solutionTable->insertRow(currentRow); for (int i = 4; i < 6; i++) { QTableWidgetItem *disabledBox = new QTableWidgetItem(); disabledBox->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, i, disabledBox); } QTableWidgetItem *RAReport = new QTableWidgetItem(); RAReport->setText(ScopeRAOut->text()); RAReport->setTextAlignment(Qt::AlignHCenter); RAReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 0, RAReport); QTableWidgetItem *DECReport = new QTableWidgetItem(); DECReport->setText(ScopeDecOut->text()); DECReport->setTextAlignment(Qt::AlignHCenter); DECReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 1, DECReport); double maxrad = 1.0; SkyObject *so = KStarsData::Instance()->skyComposite()->objectNearest(new SkyPoint(dms(ra * 15), dms(dec)), maxrad); QString name; if (so) { name = so->longname(); } else { name = "None"; } QTableWidgetItem *ObjNameReport = new QTableWidgetItem(); ObjNameReport->setText(name); ObjNameReport->setTextAlignment(Qt::AlignHCenter); ObjNameReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 2, ObjNameReport); #ifdef Q_OS_OSX repaint(); //This is a band-aid for a bug in QT 5.10.0 #endif QProgressIndicator *alignIndicator = new QProgressIndicator(this); solutionTable->setCellWidget(currentRow, 3, alignIndicator); alignIndicator->startAnimation(); #ifdef Q_OS_OSX repaint(); //This is a band-aid for a bug in QT 5.10.0 #endif } return true; } void Align::newFITS(IBLOB *bp) { // Ignore guide head if there is any. if (!strcmp(bp->name, "CCD2")) return; disconnect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Align::newFITS); disconnect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Align::checkCCDExposureProgress); blobType = *(static_cast(bp->aux1)); blobFileName = QString(static_cast(bp->aux2)); // If it's Refresh, we're done if (pahStage == PAH_REFRESH) { setCaptureComplete(); return; } appendLogText(i18n("Image received.")); if (solverTypeGroup->checkedId() != SOLVER_REMOTE) { if (blobType == ISD::CCD::BLOB_FITS) { ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); if (alignDarkFrameCheck->isChecked()) { int x, y, w, h, binx = 1, biny = 1; targetChip->getFrame(&x, &y, &w, &h); targetChip->getBinning(&binx, &biny); uint16_t offsetX = x / binx; uint16_t offsetY = y / biny; FITSData *darkData = DarkLibrary::Instance()->getDarkFrame(targetChip, exposureIN->value()); connect(DarkLibrary::Instance(), &DarkLibrary::darkFrameCompleted, this, [&](bool completed) { DarkLibrary::Instance()->disconnect(this); alignDarkFrameCheck->setChecked(completed); if (completed) setCaptureComplete(); else abort(); }); connect(DarkLibrary::Instance(), &DarkLibrary::newLog, this, &Ekos::Align::appendLogText); if (darkData) DarkLibrary::Instance()->subtract(darkData, alignView, FITS_NONE, offsetX, offsetY); else { DarkLibrary::Instance()->captureAndSubtract(targetChip, alignView, exposureIN->value(), offsetX, offsetY); } return; } } setCaptureComplete(); } } void Align::setCaptureComplete() { DarkLibrary::Instance()->disconnect(this); if (pahStage == PAH_REFRESH) { newFrame(alignView); captureAndSolve(); return; } emit newImage(alignView); if (solverTypeGroup->checkedId() == SOLVER_ONLINE && Options::astrometryUseJPEG()) { ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); if (targetChip) { QString jpegFile = blobFileName + ".jpg"; bool rc = alignView->getDisplayImage().save(jpegFile, "JPG"); if (rc) blobFileName = jpegFile; } } if (getSolverFOV()) getSolverFOV()->setImage(alignView->getDisplayImage()); startSolving(blobFileName); } void Align::setSolverAction(int mode) { gotoModeButtonGroup->button(mode)->setChecked(true); currentGotoMode = static_cast(mode); } void Align::startSolving(const QString &filename, bool isGenerated) { QStringList solverArgs; QString options = solverOptions->text().simplified(); if (isGenerated) { solverArgs = options.split(' '); // Replace RA and DE with LST & 90/-90 pole if (pahStage == PAH_FIRST_CAPTURE) { for (int i = 0; i < solverArgs.count(); i++) { // RA if (solverArgs[i] == "-3") solverArgs[i + 1] = QString::number(KStarsData::Instance()->lst()->Degrees()); // DE. +90 for Northern hemisphere. -90 for southern hemisphere else if (solverArgs[i] == "-4") solverArgs[i + 1] = QString::number(hemisphere == NORTH_HEMISPHERE ? 90 : -90); } } } else if (filename.endsWith(QLatin1String("fits")) || filename.endsWith(QLatin1String("fit"))) { solverArgs = getSolverOptionsFromFITS(filename); appendLogText(i18n("Using solver options: %1", solverArgs.join(' '))); } else { KGuiItem blindItem(i18n("Blind solver"), QString(), i18n("Blind solver takes a very long time to solve but can reliably solve any image any " "where in the sky given enough time.")); KGuiItem existingItem(i18n("Use existing settings"), QString(), i18n("Mount must be pointing close to the target location and current field of view must " "match the image's field of view.")); int rc = KMessageBox::questionYesNoCancel(nullptr, i18n("No metadata is available in this image. Do you want to use the " "blind solver or the existing solver settings?"), i18n("Astrometry solver"), blindItem, existingItem, KStandardGuiItem::cancel(), "blind_solver_or_existing_solver_option"); if (rc == KMessageBox::Yes) { QVariantMap optionsMap; if (Options::astrometryUseNoVerify()) optionsMap["noverify"] = true; if (Options::astrometryUseResort()) optionsMap["resort"] = true; if (Options::astrometryUseNoFITS2FITS()) optionsMap["nofits2fits"] = true; if (Options::astrometryUseDownsample()) optionsMap["downsample"] = Options::astrometryDownsample(); solverArgs = generateOptions(optionsMap); } else if (rc == KMessageBox::No) solverArgs = options.split(' '); else { abort(); return; } } if (solverIterations == 0 && mountModelReset == false) { double ra, dec; currentTelescope->getEqCoords(&ra, &dec); targetCoord.setRA(ra); targetCoord.setDec(dec); } mountModelReset = false; //Options::setSolverOptions(solverOptions->text()); //Options::setGuideScopeCCDs(guideScopeCCDs); Options::setSolverAccuracyThreshold(accuracySpin->value()); Options::setAlignDarkFrame(alignDarkFrameCheck->isChecked()); Options::setSolverGotoOption(currentGotoMode); //m_isSolverComplete = false; //m_isSolverSuccessful = false; if (fov_x > 0) parser->verifyIndexFiles(fov_x, fov_y); solverTimer.start(); m_AlignTimer.start(); if (currentGotoMode == GOTO_SLEW) appendLogText(i18n("Solver iteration #%1", solverIterations + 1)); state = ALIGN_PROGRESS; emit newStatus(state); parser->startSovler(filename, solverArgs, isGenerated); } void Align::solverFinished(double orientation, double ra, double dec, double pixscale) { pi->stopAnimation(); stopB->setEnabled(false); solveB->setEnabled(true); sOrientation = orientation; sRA = ra; sDEC = dec; // Reset Telescope Type to remembered value if (rememberTelescopeType != ISD::CCD::TELESCOPE_UNKNOWN) { currentCCD->setTelescopeType(rememberTelescopeType); rememberTelescopeType = ISD::CCD::TELESCOPE_UNKNOWN; } m_AlignTimer.stop(); if (solverTypeGroup->checkedId() == SOLVER_REMOTE && remoteParser.get() != nullptr) { // Disable remote parse dynamic_cast(remoteParser.get())->setEnabled(false); } int binx, biny; ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); targetChip->getBinning(&binx, &biny); if (Options::alignmentLogging()) appendLogText(i18n("Solver RA (%1) DEC (%2) Orientation (%3) Pixel Scale (%4)", QString::number(ra, 'g', 5), QString::number(dec, 'g', 5), QString::number(orientation, 'g', 5), QString::number(pixscale, 'g', 5))); #if 0 if (pixscale > 0 && loadSlewState == IPS_IDLE) { double solver_focal_length = (206.264 * ccd_hor_pixel) / pixscale * binx; if (fabs(focal_length - solver_focal_length) > 1) appendLogText(i18n("Current focal length is %1 mm while computed focal length from the solver is %2 mm. " "Please update the mount focal length to obtain accurate results.", QString::number(focal_length, 'g', 5), QString::number(solver_focal_length, 'g', 5))); } #endif if (fov_x == 0 && pixscale > 0) { double newFOVW = ccd_width * pixscale / binx / 60.0; double newFOVH = ccd_height * pixscale / biny / 60.0; saveNewEffectiveFOV(newFOVW, newFOVH); } alignCoord.setRA0(ra / 15.0); alignCoord.setDec0(dec); RotOut->setText(QString::number(orientation, 'g', 5)); // Convert to JNow alignCoord.apparentCoord(static_cast(J2000), KStars::Instance()->data()->ut().djd()); // Get horizontal coords alignCoord.EquatorialToHorizontal(KStarsData::Instance()->lst(), KStarsData::Instance()->geo()->lat()); // double raDiff = (alignCoord.ra().Degrees() - targetCoord.ra().Degrees()) * 3600; // double deDiff = (alignCoord.dec().Degrees() - targetCoord.dec().Degrees()) * 3600; double raDiff = (alignCoord.ra().deltaAngle(targetCoord.ra())).Degrees() * 3600; double deDiff = (alignCoord.dec().deltaAngle(targetCoord.dec())).Degrees() * 3600; dms RADiff(fabs(raDiff) / 3600.0), DEDiff(deDiff / 3600.0); dRAOut->setText(QString("%1%2").arg((raDiff > 0 ? "+" : "-"), RADiff.toHMSString())); dDEOut->setText(DEDiff.toDMSString(true)); pixScaleOut->setText(QString::number(pixscale, 'f', 2)); //emit newSolutionDeviation(raDiff, deDiff); targetDiff = sqrt(raDiff * raDiff + deDiff * deDiff); // Because astrometry reads image upside-down (bottom to top), the orientation is rotated 180 degrees when compared to PA // PA = Orientation + 180 double solverPA = orientation + 180; // Limit PA to -180 to +180 if (solverPA > 180) solverPA -= 360; if (solverPA < -180) solverPA += 360; solverFOV->setCenter(alignCoord); solverFOV->setPA(solverPA); solverFOV->setImageDisplay(Options::astrometrySolverOverlay()); sensorFOV->setPA(solverPA); QString ra_dms, dec_dms; getFormattedCoords(alignCoord.ra().Hours(), alignCoord.dec().Degrees(), ra_dms, dec_dms); SolverRAOut->setText(ra_dms); SolverDecOut->setText(dec_dms); //This block of code will write the result into the solution table and plot it on the graph. int currentRow = solutionTable->rowCount() - 1; if (loadSlewState == IPS_IDLE) { QTableWidgetItem *dRAReport = new QTableWidgetItem(); if (dRAReport) { dRAReport->setText(QString::number(raDiff, 'f', 3) + "\""); dRAReport->setTextAlignment(Qt::AlignHCenter); dRAReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 4, dRAReport); } QTableWidgetItem *dDECReport = new QTableWidgetItem(); if (dDECReport) { dDECReport->setText(QString::number(deDiff, 'f', 3) + "\""); dDECReport->setTextAlignment(Qt::AlignHCenter); dDECReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 5, dDECReport); } double raPlot = raDiff; double decPlot = deDiff; alignPlot->graph(0)->addData(raPlot, decPlot); QCPItemText *textLabel = new QCPItemText(alignPlot); textLabel->setPositionAlignment(Qt::AlignVCenter | Qt::AlignHCenter); textLabel->position->setType(QCPItemPosition::ptPlotCoords); textLabel->position->setCoords(raPlot, decPlot); textLabel->setColor(Qt::red); textLabel->setPadding(QMargins(0, 0, 0, 0)); textLabel->setBrush(Qt::white); //textLabel->setBrush(Qt::NoBrush); textLabel->setPen(Qt::NoPen); textLabel->setText(' ' + QString::number(solutionTable->rowCount()) + ' '); textLabel->setFont(QFont(font().family(), 8)); if (!alignPlot->xAxis->range().contains(raDiff)) { alignPlot->graph(0)->rescaleKeyAxis(true); alignPlot->yAxis->setScaleRatio(alignPlot->xAxis, 1.0); } if (!alignPlot->yAxis->range().contains(deDiff)) { alignPlot->graph(0)->rescaleValueAxis(true); alignPlot->xAxis->setScaleRatio(alignPlot->yAxis, 1.0); } alignPlot->replot(); } if (Options::astrometrySolverWCS()) { INumberVectorProperty *ccdRotation = currentCCD->getBaseDevice()->getNumber("CCD_ROTATION"); if (ccdRotation) { INumber *rotation = IUFindNumber(ccdRotation, "CCD_ROTATION_VALUE"); if (rotation) { ClientManager *clientManager = currentCCD->getDriverInfo()->getClientManager(); rotation->value = orientation; clientManager->sendNewNumber(ccdRotation); if (m_wcsSynced == false) { appendLogText( i18n("WCS information updated. Images captured from this point forward shall have valid WCS.")); // Just send telescope info in case the CCD driver did not pick up before. INumberVectorProperty *telescopeInfo = currentTelescope->getBaseDevice()->getNumber("TELESCOPE_INFO"); if (telescopeInfo) clientManager->sendNewNumber(telescopeInfo); m_wcsSynced = true; } } } } m_CaptureErrorCounter = 0; m_SlewErrorCounter = 0; m_CaptureTimeoutCounter = 0; appendLogText(i18n("Solution coordinates: RA (%1) DEC (%2) Telescope Coordinates: RA (%3) DEC (%4)", alignCoord.ra().toHMSString(), alignCoord.dec().toDMSString(), telescopeCoord.ra().toHMSString(), telescopeCoord.dec().toDMSString())); if (loadSlewState == IPS_IDLE && currentGotoMode == GOTO_SLEW) { dms diffDeg(targetDiff / 3600.0); appendLogText(i18n("Target is within %1 degrees of solution coordinates.", diffDeg.toDMSString())); } if (rememberUploadMode != currentCCD->getUploadMode()) currentCCD->setUploadMode(rememberUploadMode); if (rememberCCDExposureLooping) currentCCD->setExposureLoopingEnabled(true); //if (syncR->isChecked() || nothingR->isChecked() || targetDiff <= accuracySpin->value()) // CONTINUE HERE //This block of code along with some sections in the switch below will set the status report in the solution table for this item. std::unique_ptr statusReport(new QTableWidgetItem()); if (loadSlewState == IPS_IDLE) { solutionTable->setCellWidget(currentRow, 3, new QWidget()); statusReport->setFlags(Qt::ItemIsSelectable); } // Update Rotator offsets if (currentRotator != nullptr) { // When Load&Slew image is solved, we check if we need to rotate the rotator to match the position angle of the image if (loadSlewState == IPS_BUSY && Options::astrometryUseRotator()) { loadSlewTargetPA = solverPA; qCDebug(KSTARS_EKOS_ALIGN) << "loaSlewTargetPA:" << loadSlewTargetPA; } else { INumberVectorProperty *absAngle = currentRotator->getBaseDevice()->getNumber("ABS_ROTATOR_ANGLE"); if (absAngle) { // PA = RawAngle * Multiplier + Offset currentRotatorPA = solverPA; double rawAngle = absAngle->np[0].value; double offset = solverPA - (rawAngle * Options::pAMultiplier()); qCDebug(KSTARS_EKOS_ALIGN) << "Raw Rotator Angle:" << rawAngle << "Rotator PA:" << currentRotatorPA << "Rotator Offset:" << offset; Options::setPAOffset(offset); } if (absAngle && std::isnan(loadSlewTargetPA) == false && fabs(currentRotatorPA - loadSlewTargetPA) * 60 > Options::astrometryRotatorThreshold()) { double rawAngle = (loadSlewTargetPA - Options::pAOffset()) / Options::pAMultiplier(); if (rawAngle < 0) rawAngle += 360; else if (rawAngle > 360) rawAngle -= 360; absAngle->np[0].value = rawAngle; ClientManager *clientManager = currentRotator->getDriverInfo()->getClientManager(); clientManager->sendNewNumber(absAngle); appendLogText(i18n("Setting position angle to %1 degrees E of N...", loadSlewTargetPA)); return; } } } emit newSolverResults(orientation, ra, dec, pixscale); QJsonObject solution = { {"ra", SolverRAOut->text()}, {"de", SolverDecOut->text()}, {"dRA", dRAOut->text()}, {"dDE", dDEOut->text()}, {"pix", pixscale}, {"rot", orientation}, {"fov", FOVOut->text()}, }; emit newSolution(solution.toVariantMap()); switch (currentGotoMode) { case GOTO_SYNC: executeGOTO(); if (loadSlewState == IPS_IDLE) { statusReport->setIcon(QIcon(":/icons/AlignSuccess.svg")); solutionTable->setItem(currentRow, 3, statusReport.release()); } return; case GOTO_SLEW: if (loadSlewState == IPS_BUSY || targetDiff > static_cast(accuracySpin->value())) { if (loadSlewState == IPS_IDLE && ++solverIterations == MAXIMUM_SOLVER_ITERATIONS) { appendLogText(i18n("Maximum number of iterations reached. Solver failed.")); if (loadSlewState == IPS_IDLE) { statusReport->setIcon(QIcon(":/icons/AlignFailure.svg")); solutionTable->setItem(currentRow, 3, statusReport.release()); } solverFailed(); if (mountModelRunning) finishAlignmentPoint(false); return; } targetAccuracyNotMet = true; if (loadSlewState == IPS_IDLE) { statusReport->setIcon(QIcon(":/icons/AlignWarning.svg")); solutionTable->setItem(currentRow, 3, statusReport.release()); } executeGOTO(); return; } if (loadSlewState == IPS_IDLE) { statusReport->setIcon(QIcon(":/icons/AlignSuccess.svg")); solutionTable->setItem(currentRow, 3, statusReport.release()); } appendLogText(i18n("Target is within acceptable range. Astrometric solver is successful.")); if (mountModelRunning) { finishAlignmentPoint(true); if (mountModelRunning) return; } break; case GOTO_NOTHING: if (loadSlewState == IPS_IDLE) { statusReport->setIcon(QIcon(":/icons/AlignSuccess.svg")); solutionTable->setItem(currentRow, 3, statusReport.release()); } if (mountModelRunning) { finishAlignmentPoint(true); if (mountModelRunning) return; } break; } KSNotification::event(QLatin1String("AlignSuccessful"), i18n("Astrometry alignment completed successfully")); state = ALIGN_COMPLETE; emit newStatus(state); solverIterations = 0; if (pahStage != PAH_IDLE) processPAHStage(orientation, ra, dec, pixscale); else if (azStage > AZ_INIT || altStage > ALT_INIT) executePolarAlign(); else { solveB->setEnabled(true); loadSlewB->setEnabled(true); } } void Align::solverFailed() { KSNotification::event(QLatin1String("AlignFailed"), i18n("Astrometry alignment failed with errors"), KSNotification::EVENT_ALERT); pi->stopAnimation(); stopB->setEnabled(false); solveB->setEnabled(true); m_AlignTimer.stop(); azStage = AZ_INIT; altStage = ALT_INIT; //loadSlewMode = false; loadSlewState = IPS_IDLE; solverIterations = 0; m_CaptureErrorCounter = 0; m_CaptureTimeoutCounter = 0; m_SlewErrorCounter = 0; //emit solverComplete(false); state = ALIGN_FAILED; emit newStatus(state); int currentRow = solutionTable->rowCount() - 1; solutionTable->setCellWidget(currentRow, 3, new QWidget()); QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setIcon(QIcon(":/icons/AlignFailure.svg")); statusReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 3, statusReport); } void Align::abort() { parser->stopSolver(); pi->stopAnimation(); stopB->setEnabled(false); solveB->setEnabled(true); loadSlewB->setEnabled(true); // Reset Telescope Type to remembered value if (rememberTelescopeType != ISD::CCD::TELESCOPE_UNKNOWN) { currentCCD->setTelescopeType(rememberTelescopeType); rememberTelescopeType = ISD::CCD::TELESCOPE_UNKNOWN; } azStage = AZ_INIT; altStage = ALT_INIT; //loadSlewMode = false; loadSlewState = IPS_IDLE; solverIterations = 0; m_CaptureErrorCounter = 0; m_CaptureTimeoutCounter = 0; m_SlewErrorCounter = 0; m_AlignTimer.stop(); //currentCCD->disconnect(this); disconnect(currentCCD, &ISD::CCD::BLOBUpdated, this, &Ekos::Align::newFITS); disconnect(currentCCD, &ISD::CCD::newExposureValue, this, &Ekos::Align::checkCCDExposureProgress); if (rememberUploadMode != currentCCD->getUploadMode()) currentCCD->setUploadMode(rememberUploadMode); if (rememberCCDExposureLooping) currentCCD->setExposureLoopingEnabled(true); ISD::CCDChip *targetChip = currentCCD->getChip(useGuideHead ? ISD::CCDChip::GUIDE_CCD : ISD::CCDChip::PRIMARY_CCD); // If capture is still in progress, let's stop that. if (pahStage == PAH_REFRESH) { if (targetChip->isCapturing()) targetChip->abortExposure(); appendLogText(i18n("Refresh is complete.")); } else { if (targetChip->isCapturing()) { targetChip->abortExposure(); appendLogText(i18n("Capture aborted.")); } else { int elapsed = static_cast(round(solverTimer.elapsed() / 1000.0)); appendLogText(i18np("Solver aborted after %1 second.", "Solver aborted after %1 seconds", elapsed)); } } state = ALIGN_ABORTED; emit newStatus(state); int currentRow = solutionTable->rowCount() - 1; solutionTable->setCellWidget(currentRow, 3, new QWidget()); QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setIcon(QIcon(":/icons/AlignFailure.svg")); statusReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 3, statusReport); } QList Align::getSolutionResult() { QList result; result << sOrientation << sRA << sDEC; return result; } void Align::appendLogText(const QString &text) { m_LogText.insert(0, i18nc("log entry; %1 is the date, %2 is the text", "%1 %2", KStarsData::Instance()->lt().toString("yyyy-MM-ddThh:mm:ss"), text)); qCInfo(KSTARS_EKOS_ALIGN) << text; emit newLog(text); } void Align::clearLog() { m_LogText.clear(); emit newLog(QString()); } void Align::processSwitch(ISwitchVectorProperty *svp) { if (!strcmp(svp->name, "DOME_MOTION")) { // If dome is not ready and state is now if (domeReady == false && svp->s == IPS_OK) { domeReady = true; // trigger process number for mount so that it proceeds with normal workflow since // it was stopped by dome not being ready INumberVectorProperty *nvp = nullptr; if (currentTelescope->isJ2000()) nvp = currentTelescope->getBaseDevice()->getNumber("EQUATORIAL_COORD"); else nvp = currentTelescope->getBaseDevice()->getNumber("EQUATORIAL_EOD_COORD"); if (nvp) processNumber(nvp); } } } void Align::processNumber(INumberVectorProperty *nvp) { if (!strcmp(nvp->name, "EQUATORIAL_EOD_COORD") || !strcmp(nvp->name, "EQUATORIAL_COORD")) { QString ra_dms, dec_dms; if (!strcmp(nvp->name, "EQUATORIAL_COORD")) { telescopeCoord.setRA0(nvp->np[0].value); telescopeCoord.setDec0(nvp->np[1].value); // Get JNow as well telescopeCoord.apparentCoord(static_cast(J2000), KStars::Instance()->data()->ut().djd()); } else { telescopeCoord.setRA(nvp->np[0].value); telescopeCoord.setDec(nvp->np[1].value); } getFormattedCoords(telescopeCoord.ra().Hours(), telescopeCoord.dec().Degrees(), ra_dms, dec_dms); telescopeCoord.EquatorialToHorizontal(KStarsData::Instance()->lst(), KStarsData::Instance()->geo()->lat()); ScopeRAOut->setText(ra_dms); ScopeDecOut->setText(dec_dms); // qCDebug(KSTARS_EKOS_ALIGN) << "## RA" << ra_dms << "DE" << dec_dms // << "state:" << pstateStr(nvp->s) << "slewStarted?" << m_wasSlewStarted; switch (nvp->s) { // Idle --> Mount not tracking or slewing case IPS_IDLE: m_wasSlewStarted = false; //qCDebug(KSTARS_EKOS_ALIGN) << "## IPS_IDLE --> setting slewStarted to FALSE"; break; // Ok --> Mount Tracking. If m_wasSlewStarted is true // then it just finished slewing case IPS_OK: { // Update the boxes as the mount just finished slewing if (m_wasSlewStarted && Options::astrometryAutoUpdatePosition()) { //qCDebug(KSTARS_EKOS_ALIGN) << "## IPS_OK --> Auto Update Position..."; opsAstrometry->estRA->setText(ra_dms); opsAstrometry->estDec->setText(dec_dms); Options::setAstrometryPositionRA(nvp->np[0].value * 15); Options::setAstrometryPositionDE(nvp->np[1].value); generateArgs(); } // If dome is syncing, wait until it stops if (currentDome && currentDome->isMoving()) { domeReady = false; return; } // If we are looking for celestial pole if (m_wasSlewStarted && pahStage == PAH_FIND_CP) { //qCDebug(KSTARS_EKOS_ALIGN) << "## PAH_FIND_CP--> setting slewStarted to FALSE"; m_wasSlewStarted = false; appendLogText(i18n("Mount completed slewing near celestial pole. Capture again to verify.")); setSolverAction(GOTO_NOTHING); pahStage = PAH_FIRST_CAPTURE; emit newPAHStage(pahStage); return; } // if (m_wasSlewStarted && pahStage == PAH_FIRST_ROTATE) // { // m_wasSlewStarted = false; // appendLogText(i18n("Mount first rotation is complete.")); // pahStage = PAH_SECOND_CAPTURE; // emit newPAHStage(pahStage); // PAHWidgets->setCurrentWidget(PAHSecondCapturePage); // emit newPAHMessage(secondCaptureText->text()); // if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) // appendLogText(i18n("Settling...")); // QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); // return; // } // else if (m_wasSlewStarted && pahStage == PAH_SECOND_ROTATE) // { // m_wasSlewStarted = false; // appendLogText(i18n("Mount second rotation is complete.")); // pahStage = PAH_THIRD_CAPTURE; // emit newPAHStage(pahStage); // PAHWidgets->setCurrentWidget(PAHThirdCapturePage); // emit newPAHMessage(thirdCaptureText->text()); // if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) // appendLogText(i18n("Settling...")); // QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); // return; // } switch (state) { case ALIGN_PROGRESS: break; case ALIGN_SYNCING: { m_wasSlewStarted = false; //qCDebug(KSTARS_EKOS_ALIGN) << "## ALIGN_SYNCING --> setting slewStarted to FALSE"; if (currentGotoMode == GOTO_SLEW) { Slew(); return; } else { appendLogText(i18n("Mount is synced to solution coordinates. Astrometric solver is successful.")); KSNotification::event(QLatin1String("AlignSuccessful"), i18n("Astrometry alignment completed successfully")); state = ALIGN_COMPLETE; emit newStatus(state); solverIterations = 0; if (mountModelRunning) finishAlignmentPoint(true); } } break; case ALIGN_SLEWING: // If mount has not started slewing yet, then skip //qCDebug(KSTARS_EKOS_ALIGN) << "## Mount has not started slewing yet..."; if (m_wasSlewStarted == false) break; //qCDebug(KSTARS_EKOS_ALIGN) << "## ALIGN_SLEWING --> setting slewStarted to FALSE"; m_wasSlewStarted = false; if (loadSlewState == IPS_BUSY) { loadSlewState = IPS_IDLE; qCDebug(KSTARS_EKOS_ALIGN) << "loadSlewState is IDLE."; state = ALIGN_PROGRESS; emit newStatus(state); if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); return; } else if (differentialSlewingActivated) { appendLogText(i18n("Differential slewing complete. Astrometric solver is successful.")); KSNotification::event(QLatin1String("AlignSuccessful"), i18n("Astrometry alignment completed successfully")); state = ALIGN_COMPLETE; emit newStatus(state); solverIterations = 0; if (mountModelRunning) finishAlignmentPoint(true); } else if (currentGotoMode == GOTO_SLEW || mountModelRunning) { if (targetAccuracyNotMet) appendLogText(i18n("Slew complete. Target accuracy is not met, running solver again...")); else appendLogText(i18n("Slew complete. Solving Alignment Point. . .")); targetAccuracyNotMet = false; state = ALIGN_PROGRESS; emit newStatus(state); if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); return; } break; default: { //qCDebug(KSTARS_EKOS_ALIGN) << "## Align State " << state << "--> setting slewStarted to FALSE"; m_wasSlewStarted = false; } break; } } break; // Busy --> Mount Slewing or Moving (NSWE buttons) case IPS_BUSY: { //qCDebug(KSTARS_EKOS_ALIGN) << "## IPS_BUSY --> setting slewStarted to TRUE"; m_wasSlewStarted = true; } break; // Alert --> Mount has problem moving or communicating. case IPS_ALERT: { //qCDebug(KSTARS_EKOS_ALIGN) << "## IPS_ALERT --> setting slewStarted to FALSE"; m_wasSlewStarted = false; if (state == ALIGN_SYNCING || state == ALIGN_SLEWING) { if (state == ALIGN_SYNCING) appendLogText(i18n("Syncing failed.")); else appendLogText(i18n("Slewing failed.")); if (++m_SlewErrorCounter == 3) { abort(); return; } else { if (currentGotoMode == GOTO_SLEW) Slew(); else Sync(); } } return; } } if (pahStage == PAH_FIRST_ROTATE) { // only wait for telescope to slew to new position if manual slewing is switched off if(!PAHManual->isChecked()) { double deltaAngle = fabs(telescopeCoord.ra().deltaAngle(targetPAH.ra()).Degrees()); qCDebug(KSTARS_EKOS_ALIGN) << "First mount rotation remaining degrees:" << deltaAngle; if (deltaAngle <= PAH_ROTATION_THRESHOLD) { currentTelescope->StopWE(); appendLogText(i18n("Mount first rotation is complete.")); pahStage = PAH_SECOND_CAPTURE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHSecondCapturePage); emit newPAHMessage(secondCaptureText->text()); if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); } // If for some reason we didn't stop, let's stop if we get too far else if (deltaAngle > PAHRotationSpin->value() * 1.25) { currentTelescope->Abort(); appendLogText(i18n("Mount aborted. Please restart the process and reduce the speed.")); stopPAHProcess(); } return; } // endif not manual slew } else if (pahStage == PAH_SECOND_ROTATE) { // only wait for telescope to slew to new position if manual slewing is switched off if(!PAHManual->isChecked()) { double deltaAngle = fabs(telescopeCoord.ra().deltaAngle(targetPAH.ra()).Degrees()); qCDebug(KSTARS_EKOS_ALIGN) << "Second mount rotation remaining degrees:" << deltaAngle; if (deltaAngle <= PAH_ROTATION_THRESHOLD) { currentTelescope->StopWE(); appendLogText(i18n("Mount second rotation is complete.")); pahStage = PAH_THIRD_CAPTURE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHThirdCapturePage); emit newPAHMessage(thirdCaptureText->text()); if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); } // If for some reason we didn't stop, let's stop if we get too far else if (deltaAngle > PAHRotationSpin->value() * 1.25) { currentTelescope->Abort(); appendLogText(i18n("Mount aborted. Please restart the process and reduce the speed.")); stopPAHProcess(); } return; } // endif not manual slew } switch (azStage) { case AZ_SYNCING: if (currentTelescope->isSlewing()) azStage = AZ_SLEWING; break; case AZ_SLEWING: if (currentTelescope->isSlewing() == false) { azStage = AZ_SECOND_TARGET; measureAzError(); } break; case AZ_CORRECTING: if (currentTelescope->isSlewing() == false) { appendLogText(i18n( "Slew complete. Please adjust azimuth knob until the target is in the center of the view.")); azStage = AZ_INIT; } break; default: break; } switch (altStage) { case ALT_SYNCING: if (currentTelescope->isSlewing()) altStage = ALT_SLEWING; break; case ALT_SLEWING: if (currentTelescope->isSlewing() == false) { altStage = ALT_SECOND_TARGET; measureAltError(); } break; case ALT_CORRECTING: if (currentTelescope->isSlewing() == false) { appendLogText(i18n( "Slew complete. Please adjust altitude knob until the target is in the center of the view.")); altStage = ALT_INIT; } break; default: break; } } else if (!strcmp(nvp->name, "ABS_ROTATOR_ANGLE")) { // PA = RawAngle * Multiplier + Offset currentRotatorPA = (nvp->np[0].value * Options::pAMultiplier()) + Options::pAOffset(); if (currentRotatorPA > 180) currentRotatorPA -= 360; if (currentRotatorPA < -180) currentRotatorPA += 360; if (std::isnan(loadSlewTargetPA) == false && fabs(currentRotatorPA - loadSlewTargetPA) * 60 <= Options::astrometryRotatorThreshold()) { appendLogText(i18n("Rotator reached target position angle.")); targetAccuracyNotMet = true; loadSlewTargetPA = std::numeric_limits::quiet_NaN(); QTimer::singleShot(Options::settlingTime(), this, &Ekos::Align::executeGOTO); } } // N.B. Ekos::Manager already manages TELESCOPE_INFO, why here again? //if (!strcmp(coord->name, "TELESCOPE_INFO")) //syncTelescopeInfo(); } void Align::executeGOTO() { if (loadSlewState == IPS_BUSY) { //if (loadSlewIterations == loadSlewIterationsSpin->value()) //loadSlewCoord = alignCoord; //targetCoord = loadSlewCoord; targetCoord = alignCoord; SlewToTarget(); } else if (currentGotoMode == GOTO_SYNC) Sync(); else if (currentGotoMode == GOTO_SLEW) SlewToTarget(); } void Align::Sync() { state = ALIGN_SYNCING; if (currentTelescope->Sync(&alignCoord)) { emit newStatus(state); appendLogText( i18n("Syncing to RA (%1) DEC (%2)", alignCoord.ra().toHMSString(), alignCoord.dec().toDMSString())); } else { state = ALIGN_IDLE; emit newStatus(state); appendLogText(i18n("Syncing failed.")); } } void Align::Slew() { state = ALIGN_SLEWING; emit newStatus(state); //qCDebug(KSTARS_EKOS_ALIGN) << "## Before SLEW command: wasSlewStarted -->" << m_wasSlewStarted; //m_wasSlewStarted = currentTelescope->Slew(&targetCoord); //qCDebug(KSTARS_EKOS_ALIGN) << "## After SLEW command: wasSlewStarted -->" << m_wasSlewStarted; // JM 2019-08-23: Do not assume that slew was started immediately. Wait until IPS_BUSY state is triggered // from Goto currentTelescope->Slew(&targetCoord); appendLogText(i18n("Slewing to target coordinates: RA (%1) DEC (%2).", targetCoord.ra().toHMSString(), targetCoord.dec().toDMSString())); } void Align::SlewToTarget() { if (canSync && loadSlewState == IPS_IDLE) { // 2018-01-24 JM: This is ugly. Maybe use DBus? Signal/Slots? Ekos Manager usage like this should be avoided if (KStars::Instance()->ekosManager() && !KStars::Instance()->ekosManager()->getCurrentJobName().isEmpty()) { KSNotification::event(QLatin1String("EkosSchedulerTelescopeSynced"), i18n("Ekos job (%1) - Telescope synced", KStars::Instance()->ekosManager()->getCurrentJobName())); } // Do we perform a regular sync or use differential slewing? if (Options::astrometryDifferentialSlewing()) { dms raDiff = alignCoord.ra().deltaAngle(targetCoord.ra()); dms deDiff = alignCoord.dec().deltaAngle(targetCoord.dec()); targetCoord.setRA(targetCoord.ra() - raDiff); targetCoord.setDec(targetCoord.dec() - deDiff); differentialSlewingActivated = true; qCDebug(KSTARS_EKOS_ALIGN) << "Using differential slewing..."; Slew(); } else Sync(); return; } Slew(); } void Align::executePolarAlign() { appendLogText(i18n("Processing solution for polar alignment...")); switch (azStage) { case AZ_FIRST_TARGET: case AZ_FINISHED: measureAzError(); break; default: break; } switch (altStage) { case ALT_FIRST_TARGET: case ALT_FINISHED: measureAltError(); break; default: break; } } void Align::measureAzError() { static double initRA = 0, initDEC = 0, finalRA = 0, finalDEC = 0, initAz = 0; if (pahStage != PAH_IDLE && (KMessageBox::warningContinueCancel(KStars::Instance(), i18n("Polar Alignment Helper is still active. Do you want to continue " "using legacy polar alignment tool?")) != KMessageBox::Continue)) return; pahStage = PAH_IDLE; emit newPAHStage(pahStage); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Measuring Azimuth Error..."; switch (azStage) { case AZ_INIT: // Display message box confirming user point scope near meridian and south // N.B. This action cannot be automated. if (KMessageBox::warningContinueCancel( nullptr, hemisphere == NORTH_HEMISPHERE ? i18n("Point the telescope at the southern meridian. Press Continue when ready.") : i18n("Point the telescope at the northern meridian. Press Continue when ready."), i18n("Polar Alignment Measurement"), KStandardGuiItem::cont(), KStandardGuiItem::cancel(), "ekos_measure_az_error") != KMessageBox::Continue) return; appendLogText(i18n("Solving first frame near the meridian.")); azStage = AZ_FIRST_TARGET; captureAndSolve(); break; case AZ_FIRST_TARGET: // start solving there, find RA/DEC initRA = alignCoord.ra().Degrees(); initDEC = alignCoord.dec().Degrees(); initAz = alignCoord.az().Degrees(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar initRA " << alignCoord.ra().toHMSString() << " initDEC " << alignCoord.dec().toDMSString() << " initlAz " << alignCoord.az().toDMSString() << " initAlt " << alignCoord.alt().toDMSString(); // Now move 30 arcminutes in RA if (canSync) { azStage = AZ_SYNCING; currentTelescope->Sync(initRA / 15.0, initDEC); currentTelescope->Slew((initRA - RAMotion) / 15.0, initDEC); } // If telescope doesn't sync, we slew relative to its current coordinates else { azStage = AZ_SLEWING; currentTelescope->Slew(telescopeCoord.ra().Hours() - RAMotion / 15.0, telescopeCoord.dec().Degrees()); } appendLogText(i18n("Slewing 30 arcminutes in RA...")); break; case AZ_SECOND_TARGET: // We reached second target now // Let now solver for RA/DEC appendLogText(i18n("Solving second frame near the meridian.")); azStage = AZ_FINISHED; captureAndSolve(); break; case AZ_FINISHED: // Measure deviation in DEC // Call function to report error // set stage to AZ_FIRST_TARGET again appendLogText(i18n("Calculating azimuth alignment error...")); finalRA = alignCoord.ra().Degrees(); finalDEC = alignCoord.dec().Degrees(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar finalRA " << alignCoord.ra().toHMSString() << " finalDEC " << alignCoord.dec().toDMSString() << " finalAz " << alignCoord.az().toDMSString() << " finalAlt " << alignCoord.alt().toDMSString(); // Slew back to original position if (canSync) currentTelescope->Slew(initRA / 15.0, initDEC); else { currentTelescope->Slew(telescopeCoord.ra().Hours() + RAMotion / 15.0, telescopeCoord.dec().Degrees()); } appendLogText(i18n("Slewing back to original position...")); calculatePolarError(initRA, initDEC, finalRA, finalDEC, initAz); azStage = AZ_INIT; break; default: break; } } void Align::measureAltError() { static double initRA = 0, initDEC = 0, finalRA = 0, finalDEC = 0, initAz = 0; if (pahStage != PAH_IDLE && (KMessageBox::warningContinueCancel(KStars::Instance(), i18n("Polar Alignment Helper is still active. Do you want to continue " "using legacy polar alignment tool?")) != KMessageBox::Continue)) return; pahStage = PAH_IDLE; emit newPAHStage(pahStage); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Measuring Altitude Error..."; switch (altStage) { case ALT_INIT: // Display message box confirming user point scope near meridian and south // N.B. This action cannot be automated. if (KMessageBox::warningContinueCancel(nullptr, i18n("Point the telescope to the eastern or western horizon with a " "minimum altitude of 20 degrees. Press continue when ready."), i18n("Polar Alignment Measurement"), KStandardGuiItem::cont(), KStandardGuiItem::cancel(), "ekos_measure_alt_error") != KMessageBox::Continue) return; appendLogText(i18n("Solving first frame.")); altStage = ALT_FIRST_TARGET; if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); break; case ALT_FIRST_TARGET: // start solving there, find RA/DEC initRA = alignCoord.ra().Degrees(); initDEC = alignCoord.dec().Degrees(); initAz = alignCoord.az().Degrees(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar initRA " << alignCoord.ra().toHMSString() << " initDEC " << alignCoord.dec().toDMSString() << " initlAz " << alignCoord.az().toDMSString() << " initAlt " << alignCoord.alt().toDMSString(); // Now move 30 arcminutes in RA if (canSync) { altStage = ALT_SYNCING; currentTelescope->Sync(initRA / 15.0, initDEC); currentTelescope->Slew((initRA - RAMotion) / 15.0, initDEC); } // If telescope doesn't sync, we slew relative to its current coordinates else { altStage = ALT_SLEWING; currentTelescope->Slew(telescopeCoord.ra().Hours() - RAMotion / 15.0, telescopeCoord.dec().Degrees()); } appendLogText(i18n("Slewing 30 arcminutes in RA...")); break; case ALT_SECOND_TARGET: // We reached second target now // Let now solver for RA/DEC appendLogText(i18n("Solving second frame.")); altStage = ALT_FINISHED; if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); break; case ALT_FINISHED: // Measure deviation in DEC // Call function to report error appendLogText(i18n("Calculating altitude alignment error...")); finalRA = alignCoord.ra().Degrees(); finalDEC = alignCoord.dec().Degrees(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar finalRA " << alignCoord.ra().toHMSString() << " finalDEC " << alignCoord.dec().toDMSString() << " finalAz " << alignCoord.az().toDMSString() << " finalAlt " << alignCoord.alt().toDMSString(); // Slew back to original position if (canSync) currentTelescope->Slew(initRA / 15.0, initDEC); // If telescope doesn't sync, we slew relative to its current coordinates else { currentTelescope->Slew(telescopeCoord.ra().Hours() + RAMotion / 15.0, telescopeCoord.dec().Degrees()); } appendLogText(i18n("Slewing back to original position...")); calculatePolarError(initRA, initDEC, finalRA, finalDEC, initAz); altStage = ALT_INIT; break; default: break; } } void Align::calculatePolarError(double initRA, double initDEC, double finalRA, double finalDEC, double initAz) { double raMotion = finalRA - initRA; decDeviation = finalDEC - initDEC; // East/West of meridian int horizon = (initAz > 0 && initAz <= 180) ? 0 : 1; // How much time passed siderrally form initRA to finalRA? //double RATime = fabs(raMotion / SIDRATE) / 60.0; // 2016-03-30: Diff in RA is sufficient for time difference // raMotion in degrees. RATime in minutes. double RATime = fabs(raMotion) * 60.0; // Equation by Frank Berret (Measuring Polar Axis Alignment Error, page 4) // In degrees double deviation = (3.81 * (decDeviation * 3600)) / (RATime * cos(initDEC * dms::DegToRad)) / 60.0; dms devDMS(fabs(deviation)); KLocalizedString deviationDirection; switch (hemisphere) { // Northern hemisphere case NORTH_HEMISPHERE: if (azStage == AZ_FINISHED) { if (decDeviation > 0) deviationDirection = ki18n("%1 too far east"); else deviationDirection = ki18n("%1 too far west"); } else if (altStage == ALT_FINISHED) { switch (horizon) { // East case 0: if (decDeviation > 0) deviationDirection = ki18n("%1 too far high"); else deviationDirection = ki18n("%1 too far low"); break; // West case 1: if (decDeviation > 0) deviationDirection = ki18n("%1 too far low"); else deviationDirection = ki18n("%1 too far high"); break; default: break; } } break; // Southern hemisphere case SOUTH_HEMISPHERE: if (azStage == AZ_FINISHED) { if (decDeviation > 0) deviationDirection = ki18n("%1 too far west"); else deviationDirection = ki18n("%1 too far east"); } else if (altStage == ALT_FINISHED) { switch (horizon) { // East case 0: if (decDeviation > 0) deviationDirection = ki18n("%1 too far low"); else deviationDirection = ki18n("%1 too far high"); break; // West case 1: if (decDeviation > 0) deviationDirection = ki18n("%1 too far high"); else deviationDirection = ki18n("%1 too far low"); break; default: break; } } break; } qCDebug(KSTARS_EKOS_ALIGN) << "Polar Hemisphere is " << ((hemisphere == NORTH_HEMISPHERE) ? "North" : "South") << " --- initAz " << initAz; qCDebug(KSTARS_EKOS_ALIGN) << "Polar initRA " << initRA << " initDEC " << initDEC << " finalRA " << finalRA << " finalDEC " << finalDEC; qCDebug(KSTARS_EKOS_ALIGN) << "Polar decDeviation " << decDeviation * 3600 << " arcsec " << " RATime " << RATime << " minutes"; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Raw Deviation " << deviation << " degrees."; if (azStage == AZ_FINISHED) { azError->setText(deviationDirection.subs(QString("%1").arg(devDMS.toDMSString())).toString()); //azError->setText(deviationDirection.subs(QString("%1")azDMS.toDMSString()); azDeviation = deviation * (decDeviation > 0 ? 1 : -1); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Azimuth Deviation " << azDeviation << " degrees."; correctAzB->setEnabled(true); } if (altStage == ALT_FINISHED) { //altError->setText(deviationDirection.subs(QString("%1").arg(fabs(deviation), 0, 'g', 3)).toString()); altError->setText(deviationDirection.subs(QString("%1").arg(devDMS.toDMSString())).toString()); altDeviation = deviation * (decDeviation > 0 ? 1 : -1); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Altitude Deviation " << altDeviation << " degrees."; correctAltB->setEnabled(true); } } void Align::correctAltError() { double newRA, newDEC; SkyPoint currentCoord(telescopeCoord); dms targetLat; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Correcting Altitude Error..."; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Current Mount RA " << currentCoord.ra().toHMSString() << " DEC " << currentCoord.dec().toDMSString() << "Az " << currentCoord.az().toDMSString() << " Alt " << currentCoord.alt().toDMSString(); // An error in polar alignment altitude reflects a deviation in the latitude of the mount from actual latitude of the site // Calculating the latitude accounting for the altitude deviation. This is the latitude at which the altitude deviation should be zero. targetLat.setD(KStars::Instance()->data()->geo()->lat()->Degrees() + altDeviation); // Calculate the Az/Alt of the mount if it were located at the corrected latitude currentCoord.EquatorialToHorizontal(KStars::Instance()->data()->lst(), &targetLat); // Convert corrected Az/Alt to RA/DEC given the local sideral time and current (not corrected) latitude currentCoord.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); // New RA/DEC should reflect the position in the sky at which the polar alignment altitude error is minimal. newRA = currentCoord.ra().Hours(); newDEC = currentCoord.dec().Degrees(); altStage = ALT_CORRECTING; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Target Latitude = Latitude " << KStars::Instance()->data()->geo()->lat()->Degrees() << " + Altitude Deviation " << altDeviation << " = " << targetLat.Degrees(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Slewing to calibration position..."; currentTelescope->Slew(newRA, newDEC); appendLogText(i18n("Slewing to calibration position, please wait until telescope completes slewing.")); } void Align::correctAzError() { double newRA, newDEC, currentAlt, currentAz; SkyPoint currentCoord(telescopeCoord); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Correcting Azimuth Error..."; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Current Mount RA " << currentCoord.ra().toHMSString() << " DEC " << currentCoord.dec().toDMSString() << "Az " << currentCoord.az().toDMSString() << " Alt " << currentCoord.alt().toDMSString(); qCDebug(KSTARS_EKOS_ALIGN) << "Polar Target Azimuth = Current Azimuth " << currentCoord.az().Degrees() << " + Azimuth Deviation " << azDeviation << " = " << currentCoord.az().Degrees() + azDeviation; // Get current horizontal coordinates of the mount currentCoord.EquatorialToHorizontal(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); // Keep Altitude as it is and change Azimuth to account for the azimuth deviation // The new sky position should be where the polar alignment azimuth error is minimal currentAlt = currentCoord.alt().Degrees(); currentAz = currentCoord.az().Degrees() + azDeviation; // Update current Alt and Azimuth to new values currentCoord.setAlt(currentAlt); currentCoord.setAz(currentAz); // Convert Alt/Az back to equatorial coordinates currentCoord.HorizontalToEquatorial(KStars::Instance()->data()->lst(), KStars::Instance()->data()->geo()->lat()); // Get new RA and DEC newRA = currentCoord.ra().Hours(); newDEC = currentCoord.dec().Degrees(); azStage = AZ_CORRECTING; qCDebug(KSTARS_EKOS_ALIGN) << "Polar Slewing to calibration position..."; currentTelescope->Slew(newRA, newDEC); appendLogText(i18n("Slewing to calibration position, please wait until telescope completes slewing.")); } void Align::getFormattedCoords(double ra, double dec, QString &ra_str, QString &dec_str) { dms ra_s, dec_s; ra_s.setH(ra); dec_s.setD(dec); ra_str = QString("%1:%2:%3") .arg(ra_s.hour(), 2, 10, QChar('0')) .arg(ra_s.minute(), 2, 10, QChar('0')) .arg(ra_s.second(), 2, 10, QChar('0')); if (dec_s.Degrees() < 0) dec_str = QString("-%1:%2:%3") .arg(abs(dec_s.degree()), 2, 10, QChar('0')) .arg(abs(dec_s.arcmin()), 2, 10, QChar('0')) .arg(dec_s.arcsec(), 2, 10, QChar('0')); else dec_str = QString("%1:%2:%3") .arg(dec_s.degree(), 2, 10, QChar('0')) .arg(dec_s.arcmin(), 2, 10, QChar('0')) .arg(dec_s.arcsec(), 2, 10, QChar('0')); } bool Align::loadAndSlew(QString fileURL) { /*if (solverTypeGroup->checkedId() == SOLVER_REMOTE) { appendLogText(i18n("Load and Slew is not supported in remote solver mode.")); loadSlewB->setEnabled(false); return; }*/ #ifdef Q_OS_OSX if(solverTypeGroup->checkedId() == SOLVER_OFFLINE) { if(Options::useDefaultPython()) { if( !opsAlign->astropyInstalled() || !opsAlign->pythonInstalled() ) { KSNotification::error(i18n("Astrometry.net uses python3 and the astropy package for plate solving images offline. These were not detected on your system. Please go into the Align Options and either click the setup button to install them or uncheck the default button and enter the path to python3 on your system and manually install astropy.")); return false; } } } #endif if (fileURL.isEmpty()) fileURL = QFileDialog::getOpenFileName(KStars::Instance(), i18n("Load Image"), dirPath, "Images (*.fits *.fit *.jpg *.jpeg)"); if (fileURL.isEmpty()) return false; QFileInfo fileInfo(fileURL); dirPath = fileInfo.absolutePath(); differentialSlewingActivated = false; loadSlewState = IPS_BUSY; stopPAHProcess(); slewR->setChecked(true); currentGotoMode = GOTO_SLEW; solveB->setEnabled(false); stopB->setEnabled(true); pi->startAnimation(); startSolving(fileURL, false); return true; } void Align::setExposure(double value) { exposureIN->setValue(value); } void Align::setBinningIndex(int binIndex) { syncSettings(); Options::setSolverBinningIndex(binIndex); // If sender is not our combo box, then we need to update the combobox itself if (dynamic_cast(sender()) != binningCombo) { binningCombo->blockSignals(true); binningCombo->setCurrentIndex(binIndex); binningCombo->blockSignals(false); } // Need to calculate FOV and args for APP if (Options::astrometryImageScaleUnits() == OpsAstrometry::SCALE_ARCSECPERPIX) { calculateFOV(); generateArgs(); } } void Align::setSolverArguments(const QString &value) { solverOptions->setText(value); } QString Align::solverArguments() { return solverOptions->text(); } void Align::setFOVTelescopeType(int index) { FOVScopeCombo->setCurrentIndex(index); } FOV *Align::getSolverFOV() { if (sOrientation == -1) return nullptr; else return solverFOV.get(); } void Align::addFilter(ISD::GDInterface *newFilter) { for (auto filter : Filters) { if (!strcmp(filter->getDeviceName(), newFilter->getDeviceName())) return; } FilterCaptureLabel->setEnabled(true); FilterDevicesCombo->setEnabled(true); FilterPosLabel->setEnabled(true); FilterPosCombo->setEnabled(true); FilterDevicesCombo->addItem(newFilter->getDeviceName()); Filters.append(static_cast(newFilter)); checkFilter(1); FilterDevicesCombo->setCurrentIndex(1); } bool Align::setFilterWheel(const QString &device) { bool deviceFound = false; for (int i = 1; i < FilterDevicesCombo->count(); i++) if (device == FilterDevicesCombo->itemText(i)) { checkFilter(i); deviceFound = true; break; } if (deviceFound == false) return false; return true; } QString Align::filterWheel() { if (FilterDevicesCombo->currentIndex() >= 1) return FilterDevicesCombo->currentText(); return QString(); } bool Align::setFilter(const QString &filter) { if (FilterDevicesCombo->currentIndex() >= 1) { FilterPosCombo->setCurrentText(filter); return true; } return false; } QString Align::filter() { return FilterPosCombo->currentText(); } void Align::checkFilter(int filterNum) { if (filterNum == -1) { filterNum = FilterDevicesCombo->currentIndex(); if (filterNum == -1) return; } // "--" is no filter if (filterNum == 0) { currentFilter = nullptr; currentFilterPosition = -1; FilterPosCombo->clear(); return; } if (filterNum <= Filters.count()) currentFilter = Filters.at(filterNum - 1); FilterPosCombo->clear(); FilterPosCombo->addItems(filterManager->getFilterLabels()); currentFilterPosition = filterManager->getFilterPosition(); FilterPosCombo->setCurrentIndex(Options::lockAlignFilterIndex()); syncSettings(); } void Align::setWCSEnabled(bool enable) { if (currentCCD == nullptr) return; ISwitchVectorProperty *wcsControl = currentCCD->getBaseDevice()->getSwitch("WCS_CONTROL"); ISwitch *wcs_enable = IUFindSwitch(wcsControl, "WCS_ENABLE"); ISwitch *wcs_disable = IUFindSwitch(wcsControl, "WCS_DISABLE"); if (!wcs_enable || !wcs_disable) return; if ((wcs_enable->s == ISS_ON && enable) || (wcs_disable->s == ISS_ON && !enable)) return; IUResetSwitch(wcsControl); if (enable) { appendLogText(i18n("World Coordinate System (WCS) is enabled. CCD rotation must be set either manually in the " "CCD driver or by solving an image before proceeding to capture any further images, " "otherwise the WCS information may be invalid.")); wcs_enable->s = ISS_ON; } else { wcs_disable->s = ISS_ON; m_wcsSynced = false; appendLogText(i18n("World Coordinate System (WCS) is disabled.")); } ClientManager *clientManager = currentCCD->getDriverInfo()->getClientManager(); clientManager->sendNewSwitch(wcsControl); } void Align::checkCCDExposureProgress(ISD::CCDChip *targetChip, double remaining, IPState state) { INDI_UNUSED(targetChip); INDI_UNUSED(remaining); if (state == IPS_ALERT) { if (++m_CaptureErrorCounter == 3 && pahStage != PAH_REFRESH) { appendLogText(i18n("Capture error. Aborting...")); abort(); return; } appendLogText(i18n("Restarting capture attempt #%1", m_CaptureErrorCounter)); int currentRow = solutionTable->rowCount() - 1; solutionTable->setCellWidget(currentRow, 3, new QWidget()); QTableWidgetItem *statusReport = new QTableWidgetItem(); statusReport->setIcon(QIcon(":/icons/AlignFailure.svg")); statusReport->setFlags(Qt::ItemIsSelectable); solutionTable->setItem(currentRow, 3, statusReport); captureAndSolve(); } } void Align::setFocusStatus(Ekos::FocusState state) { focusState = state; } QStringList Align::getSolverOptionsFromFITS(const QString &filename) { int status = 0, fits_ccd_width, fits_ccd_height, fits_binx = 1, fits_biny = 1; char comment[128], error_status[512]; fitsfile *fptr = nullptr; double ra = 0, dec = 0, fits_fov_x, fits_fov_y, fov_lower, fov_upper, fits_ccd_hor_pixel = -1, fits_ccd_ver_pixel = -1, fits_focal_length = -1; QString fov_low, fov_high; QStringList solver_args; QVariantMap optionsMap; if (Options::astrometryUseNoVerify()) optionsMap["noverify"] = true; if (Options::astrometryUseResort()) optionsMap["resort"] = true; if (Options::astrometryUseNoFITS2FITS()) optionsMap["nofits2fits"] = true; if (Options::astrometryUseDownsample()) optionsMap["downsample"] = Options::astrometryDownsample(); if (Options::astrometryCustomOptions().isEmpty() == false) optionsMap["custom"] = Options::astrometryCustomOptions(); solver_args = generateOptions(optionsMap); status = 0; #if 0 if (fits_open_image(&fptr, filename.toLatin1(), READONLY, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); qCritical(KSTARS_EKOS_ALIGN) << "Could not open file " << filename << " Error: " << QString::fromUtf8(error_status); return solver_args; } #endif // Use open diskfile as it does not use extended file names which has problems opening // files with [ ] or ( ) in their names. if (fits_open_diskfile(&fptr, filename.toLatin1(), READONLY, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); qCCritical(KSTARS_EKOS_ALIGN) << QString::fromUtf8(error_status); return solver_args; } status = 0; if (fits_movabs_hdu(fptr, 1, IMAGE_HDU, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); qCCritical(KSTARS_EKOS_ALIGN) << QString::fromUtf8(error_status); return solver_args; } status = 0; if (fits_read_key(fptr, TINT, "NAXIS1", &fits_ccd_width, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); appendLogText(i18n("FITS header: cannot find NAXIS1.")); return solver_args; } status = 0; if (fits_read_key(fptr, TINT, "NAXIS2", &fits_ccd_height, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); appendLogText(i18n("FITS header: cannot find NAXIS2.")); return solver_args; } // If we need to auto downsample, let us figure out the scale and regenerate options if (Options::astrometryAutoDownsample()) { optionsMap["downsample"] = getSolverDownsample(fits_ccd_width); solver_args = generateOptions(optionsMap); } bool coord_ok = true; status = 0; char objectra_str[32]; if (fits_read_key(fptr, TSTRING, "OBJCTRA", objectra_str, comment, &status)) { if (fits_read_key(fptr, TDOUBLE, "RA", &ra, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); coord_ok = false; appendLogText(i18n("FITS header: cannot find OBJCTRA (%1).", QString(error_status))); } else // Degrees to hours ra /= 15; } else { dms raDMS = dms::fromString(objectra_str, false); ra = raDMS.Hours(); } status = 0; char objectde_str[32]; if (coord_ok && fits_read_key(fptr, TSTRING, "OBJCTDEC", objectde_str, comment, &status)) { if (fits_read_key(fptr, TDOUBLE, "DEC", &dec, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); coord_ok = false; appendLogText(i18n("FITS header: cannot find OBJCTDEC (%1).", QString(error_status))); } } else { dms deDMS = dms::fromString(objectde_str, true); dec = deDMS.Degrees(); } /*if (coord_ok == false) { ra = telescopeCoord.ra0().Hours(); dec = telescopeCoord.dec0().Degrees(); }*/ if (coord_ok && Options::astrometryUsePosition()) solver_args << "-3" << QString::number(ra * 15.0) << "-4" << QString::number(dec) << "-5" << "15"; status = 0; double pixelScale = 0; // If we have pixel scale in arcsecs per pixel then lets use that directly // instead of calculating it from FOCAL length and other information if (fits_read_key(fptr, TDOUBLE, "SCALE", &pixelScale, comment, &status) == 0) { fov_low = QString::number(0.9 * pixelScale); fov_high = QString::number(1.1 * pixelScale); if (Options::astrometryUseImageScale()) solver_args << "-L" << fov_low << "-H" << fov_high << "-u" << "app"; return solver_args; } if (fits_read_key(fptr, TDOUBLE, "FOCALLEN", &fits_focal_length, comment, &status)) { int integer_focal_length = -1; if (fits_read_key(fptr, TINT, "FOCALLEN", &integer_focal_length, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); appendLogText(i18n("FITS header: cannot find FOCALLEN (%1).", QString(error_status))); return solver_args; } else fits_focal_length = integer_focal_length; } status = 0; if (fits_read_key(fptr, TDOUBLE, "PIXSIZE1", &fits_ccd_hor_pixel, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); appendLogText(i18n("FITS header: cannot find PIXSIZE1 (%1).", QString(error_status))); return solver_args; } status = 0; if (fits_read_key(fptr, TDOUBLE, "PIXSIZE2", &fits_ccd_ver_pixel, comment, &status)) { fits_report_error(stderr, status); fits_get_errstatus(status, error_status); appendLogText(i18n("FITS header: cannot find PIXSIZE2 (%1).", QString(error_status))); return solver_args; } status = 0; fits_read_key(fptr, TINT, "XBINNING", &fits_binx, comment, &status); status = 0; fits_read_key(fptr, TINT, "YBINNING", &fits_biny, comment, &status); // Calculate FOV fits_fov_x = 206264.8062470963552 * fits_ccd_width * fits_ccd_hor_pixel / 1000.0 / fits_focal_length * fits_binx; fits_fov_y = 206264.8062470963552 * fits_ccd_height * fits_ccd_ver_pixel / 1000.0 / fits_focal_length * fits_biny; fits_fov_x /= 60.0; fits_fov_y /= 60.0; // let's stretch the boundaries by 10% fov_lower = qMin(fits_fov_x, fits_fov_y); fov_upper = qMax(fits_fov_x, fits_fov_y); fov_lower *= 0.90; fov_upper *= 1.10; fov_low = QString::number(fov_lower); fov_high = QString::number(fov_upper); if (Options::astrometryUseImageScale()) solver_args << "-L" << fov_low << "-H" << fov_high << "-u" << "aw"; return solver_args; } uint8_t Align::getSolverDownsample(uint16_t binnedW) { uint8_t downsample = Options::astrometryDownsample(); if (!Options::astrometryAutoDownsample()) return downsample; while (downsample < 8) { if (binnedW / downsample <= 1024) break; downsample += 2; } return downsample; } void Align::saveSettleTime() { Options::setSettlingTime(delaySpin->value()); } void Align::setCaptureStatus(CaptureState newState) { switch (newState) { case CAPTURE_ALIGNING: if (currentTelescope && currentTelescope->hasAlignmentModel() && Options::resetMountModelAfterMeridian()) { mountModelReset = currentTelescope->clearAlignmentModel(); qCDebug(KSTARS_EKOS_ALIGN) << "Post meridian flip mount model reset" << (mountModelReset ? "successful." : "failed."); } QTimer::singleShot(Options::settlingTime(), this, &Ekos::Align::captureAndSolve); break; default: break; } } void Align::showFITSViewer() { FITSData *data = alignView->getImageData(); if (data) { QUrl url = QUrl::fromLocalFile(data->filename()); if (fv.isNull()) { if (Options::singleWindowCapturedFITS()) fv = KStars::Instance()->genericFITSViewer(); else { fv = new FITSViewer(Options::independentWindowFITS() ? nullptr : KStars::Instance()); KStars::Instance()->addFITSViewer(fv); } fv->addFITS(url); FITSView *currentView = fv->getCurrentView(); if (currentView) currentView->getImageData()->setAutoRemoveTemporaryFITS(false); } else fv->updateFITS(url, 0); fv->show(); } } void Align::toggleAlignWidgetFullScreen() { if (alignWidget->parent() == nullptr) { alignWidget->setParent(this); rightLayout->insertWidget(0, alignWidget); //rightLayout->setStretch(0, 2); // rightLayout->setStretch(1, 1); alignWidget->showNormal(); } else { alignWidget->setParent(nullptr); alignWidget->setWindowTitle(i18n("Align Frame")); alignWidget->setWindowFlags(Qt::Window | Qt::WindowTitleHint | Qt::CustomizeWindowHint); alignWidget->showMaximized(); alignWidget->show(); } } void Align::startPAHProcess() { qCInfo(KSTARS_EKOS_ALIGN) << "Starting Polar Alignment Assistant process..."; pahStage = PAH_FIRST_CAPTURE; emit newPAHStage(pahStage); nothingR->setChecked(true); currentGotoMode = GOTO_NOTHING; loadSlewB->setEnabled(false); rememberSolverWCS = Options::astrometrySolverWCS(); rememberAutoWCS = Options::autoWCS(); Options::setAutoWCS(false); Options::setAstrometrySolverWCS(true); if (Options::limitedResourcesMode()) appendLogText(i18n("Warning: Equatorial Grid Lines will not be drawn due to limited resources mode.")); if (currentTelescope->hasAlignmentModel()) { appendLogText(i18n("Clearing mount Alignment Model...")); mountModelReset = currentTelescope->clearAlignmentModel(); } // Unpark currentTelescope->UnPark(); // Set tracking ON if not already if (currentTelescope->canControlTrack() && currentTelescope->isTracking() == false) currentTelescope->setTrackEnabled(true); PAHStartB->setEnabled(false); PAHStopB->setEnabled(true); PAHWidgets->setCurrentWidget(PAHFirstCapturePage); emit newPAHMessage(firstCaptureText->text()); captureAndSolve(); } void Align::stopPAHProcess() { if (pahStage == PAH_IDLE) return; qCInfo(KSTARS_EKOS_ALIGN) << "Stopping Polar Alignment Assistant process..."; // Only display dialog if user explicitly restarts if ((static_cast(sender()) == PAHStopB) && KMessageBox::questionYesNo(KStars::Instance(), i18n("Are you sure you want to stop the polar alignment process?"), i18n("Polar Alignment Assistant"), KStandardGuiItem::yes(), KStandardGuiItem::no(), "restart_PAA_process_dialog") == KMessageBox::No) return; stopB->click(); if (currentTelescope && currentTelescope->isInMotion()) currentTelescope->Abort(); pahStage = PAH_IDLE; emit newPAHStage(pahStage); PAHStartB->setEnabled(true); PAHStopB->setEnabled(false); PAHRefreshB->setEnabled(true); PAHWidgets->setCurrentWidget(PAHIntroPage); emit newPAHMessage(introText->text()); qDeleteAll(pahImageInfos); pahImageInfos.clear(); correctionVector = QLineF(); correctionOffset = QPointF(); alignView->setCorrectionParams(correctionVector); alignView->setCorrectionOffset(correctionOffset); alignView->setRACircle(QVector3D()); alignView->setRefreshEnabled(false); emit newFrame(alignView); disconnect(alignView, &AlignView::trackingStarSelected, this, &Ekos::Align::setPAHCorrectionOffset); disconnect(alignView, &AlignView::newCorrectionVector, this, &Ekos::Align::newCorrectionVector); if (Options::pAHAutoPark()) { currentTelescope->Park(); appendLogText(i18n("Parking the mount...")); } state = ALIGN_IDLE; emit newStatus(state); } void Align::rotatePAH() { double raDiff = PAHRotationSpin->value(); bool westMeridian = PAHDirectionCombo->currentIndex() == 0; // West if (westMeridian) raDiff *= -1; // East else raDiff *= 1; // JM 2018-05-03: Hemispheres shouldn't affect rotation direction in RA #if 0 // North if (hemisphere == NORTH_HEMISPHERE) { // West if (westMeridian) raDiff *= -1; // East else raDiff *= 1; } // South else { // West if (westMeridian) raDiff *= 1; // East else raDiff *= -1; } #endif // if Manual slewing is selected, don't move the mount if (PAHManual->isChecked()) { appendLogText(i18n("Please rotate your mount about %1deg in RA", raDiff )); return; } // raDiff is in degrees dms newTelescopeRA = (telescopeCoord.ra() + dms(raDiff)).reduce(); targetPAH.setRA(newTelescopeRA); targetPAH.setDec(telescopeCoord.dec()); //currentTelescope->Slew(&targetPAH); // Set Selected Speed currentTelescope->setSlewRate(PAHSlewRateCombo->currentIndex()); // Go to direction currentTelescope->MoveWE(westMeridian ? ISD::Telescope::MOTION_WEST : ISD::Telescope::MOTION_EAST, ISD::Telescope::MOTION_START); appendLogText(i18n("Please wait until mount completes rotating to RA (%1) DE (%2)", targetPAH.ra().toHMSString(), targetPAH.dec().toDMSString())); } void Align::calculatePAHError() { QVector3D RACircle; bool rc = findRACircle(RACircle); if (rc == false) { appendLogText(i18n("Failed to find a solution. Try again.")); stopPAHProcess(); return; } if (alignView->isEQGridShown() == false) alignView->toggleEQGrid(); alignView->setRACircle(RACircle); FITSData *imageData = alignView->getImageData(); QPointF RACenterPoint(RACircle.x(), RACircle.y()); SkyPoint RACenter; rc = imageData->pixelToWCS(RACenterPoint, RACenter); if (rc == false) { appendLogText(i18n("Failed to find RA Axis center: %1.", imageData->getLastError())); return; } SkyPoint CP(0, (hemisphere == NORTH_HEMISPHERE) ? 90 : -90); RACenter.setRA(RACenter.ra0()); RACenter.setDec(RACenter.dec0()); double PA = 0; dms polarError = RACenter.angularDistanceTo(&CP, &PA); if (Options::alignmentLogging()) { qCDebug(KSTARS_EKOS_ALIGN) << "RA Axis Circle X: " << RACircle.x() << " Y: " << RACircle.y() << " Radius: " << RACircle.z(); qCDebug(KSTARS_EKOS_ALIGN) << "RA Axis Location RA: " << RACenter.ra0().toHMSString() << "DE: " << RACenter.dec0().toDMSString(); qCDebug(KSTARS_EKOS_ALIGN) << "RA Axis Offset: " << polarError.toDMSString() << "PA:" << PA; qCDebug(KSTARS_EKOS_ALIGN) << "CP Axis Location X:" << celestialPolePoint.x() << "Y:" << celestialPolePoint.y(); } RACenter.EquatorialToHorizontal(KStarsData::Instance()->lst(), KStarsData::Instance()->geo()->lat()); QString azDirection = RACenter.az().Degrees() < 30 ? "Right" : "Left"; QString atDirection = RACenter.alt().Degrees() < KStarsData::Instance()->geo()->lat()->Degrees() ? "Bottom" : "Top"; // FIXME should this be reversed for southern hemisphere? appendLogText(i18n("Mount axis is to the %1 %2 of the celestial pole", atDirection, azDirection)); PAHErrorLabel->setText(polarError.toDMSString()); // JM 2019-08-17: Flip for southern hemisphere. // Possible fix for: https://indilib.org/forum/ekos/5558-ekos-polar-alignment-vector-backwards.html correctionVector.setP1((hemisphere == NORTH_HEMISPHERE) ? celestialPolePoint : RACenterPoint); correctionVector.setP2((hemisphere == NORTH_HEMISPHERE) ? RACenterPoint : celestialPolePoint); /* bool RAAxisInside = imageData->contains(RACenterPoint); bool CPPointInside= imageData->contains(celestialPolePoint); if (RAAxisInside == false && CPPointInside == false) appendLogText(i18n("Warning: Mount axis and celestial pole are outside the field of view. Correction vector may be inaccurate.")); */ connect(alignView, &AlignView::trackingStarSelected, this, &Ekos::Align::setPAHCorrectionOffset); emit polarResultUpdated(correctionVector, polarError.toDMSString()); connect(alignView, &AlignView::newCorrectionVector, this, &Ekos::Align::newCorrectionVector, Qt::UniqueConnection); emit newCorrectionVector(correctionVector); alignView->setCorrectionParams(correctionVector); emit newFrame(alignView); } void Align::setPAHCorrectionOffsetPercentage(double dx, double dy) { double x = dx * alignView->zoomedWidth() * (alignView->getCurrentZoom() / 100); double y = dy * alignView->zoomedHeight() * (alignView->getCurrentZoom() / 100); setPAHCorrectionOffset(static_cast(round(x)), static_cast(round(y))); } void Align::setPAHCorrectionOffset(int x, int y) { correctionOffset.setX(x); correctionOffset.setY(y); alignView->setCorrectionOffset(correctionOffset); emit newFrame(alignView); } void Align::setPAHCorrectionSelectionComplete() { pahStage = PAH_PRE_REFRESH; emit newPAHStage(pahStage); // If user stops here, we restore the settings, if not we // disable again in the refresh process // and restore when refresh is complete Options::setAstrometrySolverWCS(rememberSolverWCS); Options::setAutoWCS(rememberAutoWCS); PAHWidgets->setCurrentWidget(PAHRefreshPage); emit newPAHMessage(refreshText->text()); } void Align::setPAHSlewDone() { emit newPAHMessage("Manual slew done."); switch(pahStage) { case PAH_FIRST_ROTATE : pahStage = PAH_SECOND_CAPTURE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHSecondCapturePage); appendLogText(i18n("First manual rotation done.")); break; case PAH_SECOND_ROTATE : pahStage = PAH_THIRD_CAPTURE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHThirdCapturePage); appendLogText(i18n("Second manual rotation done.")); break; default : return; // no other stage should be able to trigger this event } if (delaySpin->value() >= DELAY_THRESHOLD_NOTIFY) appendLogText(i18n("Settling...")); QTimer::singleShot(delaySpin->value(), this, &Ekos::Align::captureAndSolve); } void Align::startPAHRefreshProcess() { qCInfo(KSTARS_EKOS_ALIGN) << "Starting Polar Alignment Assistant refreshing..."; pahStage = PAH_REFRESH; emit newPAHStage(pahStage); PAHRefreshB->setEnabled(false); // Hide EQ Grids if shown if (alignView->isEQGridShown()) alignView->toggleEQGrid(); alignView->setRefreshEnabled(true); Options::setAstrometrySolverWCS(false); Options::setAutoWCS(false); // We for refresh, just capture really captureAndSolve(); } void Align::setPAHRefreshComplete() { abort(); Options::setAstrometrySolverWCS(rememberSolverWCS); Options::setAutoWCS(rememberAutoWCS); stopPAHProcess(); } void Align::processPAHStage(double orientation, double ra, double dec, double pixscale) { // Create temporary file to hold all WCS data // QTemporaryFile tmpFile(QDir::tempPath() + "/fitswcsXXXXXX"); // tmpFile.setAutoRemove(false); // tmpFile.open(); // QString newWCSFile = tmpFile.fileName(); // tmpFile.close(); QString newWCSFile = QDir::tempPath() + QString("/fitswcs%1").arg(QUuid::createUuid().toString().remove(QRegularExpression("[-{}]"))); //alignView->setLoadWCSEnabled(true); if (pahStage == PAH_FIND_CP) { setSolverAction(GOTO_NOTHING); appendLogText( i18n("Mount is synced to celestial pole. You can now continue Polar Alignment Assistant procedure.")); pahStage = PAH_FIRST_CAPTURE; emit newPAHStage(pahStage); return; } if (pahStage == PAH_FIRST_CAPTURE) { // Set First PAH Center PAHImageInfo *solution = new PAHImageInfo(); solution->skyCenter.setRA0(alignCoord.ra0()); solution->skyCenter.setDec0(alignCoord.dec0()); solution->orientation = orientation; solution->pixelScale = pixscale; pahImageInfos.append(solution); // Only invoke this if limited resource mode is false since we want to use CPU heavy WCS if (Options::limitedResourcesMode() == false) { appendLogText(i18n("Please wait while WCS data is processed...")); connect(alignView, &AlignView::wcsToggled, this, &Ekos::Align::setWCSToggled, Qt::UniqueConnection); alignView->createWCSFile(newWCSFile, orientation, ra, dec, pixscale); return; } pahStage = PAH_FIRST_ROTATE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHFirstRotatePage); emit newPAHMessage(firstRotateText->text()); rotatePAH(); } else if (pahStage == PAH_SECOND_CAPTURE) { // Set 2nd PAH Center PAHImageInfo *solution = new PAHImageInfo(); solution->skyCenter.setRA0(alignCoord.ra0()); solution->skyCenter.setDec0(alignCoord.dec0()); solution->orientation = orientation; solution->pixelScale = pixscale; pahImageInfos.append(solution); // Only invoke this if limited resource mode is false since we want to use CPU heavy WCS if (Options::limitedResourcesMode() == false) { appendLogText(i18n("Please wait while WCS data is processed...")); connect(alignView, &AlignView::wcsToggled, this, &Ekos::Align::setWCSToggled, Qt::UniqueConnection); alignView->createWCSFile(newWCSFile, orientation, ra, dec, pixscale); return; } pahStage = PAH_SECOND_ROTATE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHSecondRotatePage); emit newPAHMessage(secondRotateText->text()); rotatePAH(); } else if (pahStage == PAH_THIRD_CAPTURE) { // Set Third PAH Center PAHImageInfo *solution = new PAHImageInfo(); solution->skyCenter.setRA0(alignCoord.ra0()); solution->skyCenter.setDec0(alignCoord.dec0()); solution->orientation = orientation; solution->pixelScale = pixscale; pahImageInfos.append(solution); appendLogText(i18n("Please wait while WCS data is processed...")); connect(alignView, &AlignView::wcsToggled, this, &Ekos::Align::setWCSToggled, Qt::UniqueConnection); alignView->createWCSFile(newWCSFile, orientation, ra, dec, pixscale); return; } } void Align::setWCSToggled(bool result) { appendLogText(i18n("WCS data processing is complete.")); //alignView->disconnect(this); disconnect(alignView, &AlignView::wcsToggled, this, &Ekos::Align::setWCSToggled); if (pahStage == PAH_FIRST_CAPTURE) { // We need WCS to be synced first if (result == false && m_wcsSynced == true) { appendLogText(i18n("WCS info is now valid. Capturing next frame...")); pahImageInfos.clear(); captureAndSolve(); return; } // Not critical error /* if (result == false) { appendLogText( i18n("Warning: failed to load WCS data in file: %1", alignView->getImageData()->getLastError())); pahStage = PAH_FIRST_ROTATE; PAHWidgets->setCurrentWidget(PAHFirstRotatePage); return; }*/ // Find Celestial pole location SkyPoint CP(0, (hemisphere == NORTH_HEMISPHERE) ? 90 : -90); FITSData *imageData = alignView->getImageData(); QPointF pixelPoint, imagePoint; bool rc = imageData->wcsToPixel(CP, pixelPoint, imagePoint); pahImageInfos[0]->celestialPole = pixelPoint; // TODO check if pixelPoint is located TOO far from the current position as well // i.e. if X > Width * 2..etc if (rc == false) { appendLogText(i18n("Failed to process World Coordinate System: %1. Try again.", imageData->getLastError())); return; } // If celestial pole out of range, ask the user if they want to move to it if (pixelPoint.x() < (-1 * imageData->width()) || pixelPoint.x() > (imageData->width() * 2) || pixelPoint.y() < (-1 * imageData->height()) || pixelPoint.y() > (imageData->height() * 2)) { if (currentTelescope->canSync() && KMessageBox::questionYesNo( nullptr, i18n("Celestial pole is located outside of the field of view. Would you like to sync and slew " "the telescope to the celestial pole? WARNING: Slewing near poles may cause your mount to " "end up in unsafe position. Proceed with caution.")) == KMessageBox::Yes) { pahStage = PAH_FIND_CP; emit newPAHStage(pahStage); targetCoord.setRA(KStarsData::Instance()->lst()->Hours()); targetCoord.setDec(CP.dec().Degrees() > 0 ? 89.5 : -89.5); qDeleteAll(pahImageInfos); pahImageInfos.clear(); setSolverAction(GOTO_SLEW); Sync(); return; } else appendLogText(i18n("Warning: Celestial pole is located outside the field of view. Move the mount closer to the celestial pole.")); } pahStage = PAH_FIRST_ROTATE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHFirstRotatePage); emit newPAHMessage(firstRotateText->text()); rotatePAH(); } else if (pahStage == PAH_SECOND_CAPTURE) { // Find Celestial pole location SkyPoint CP(0, (hemisphere == NORTH_HEMISPHERE) ? 90 : -90); FITSData *imageData = alignView->getImageData(); QPointF pixelPoint, imagePoint; imageData->wcsToPixel(CP, pixelPoint, imagePoint); pahImageInfos[1]->celestialPole = pixelPoint; pahStage = PAH_SECOND_ROTATE; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHSecondRotatePage); emit newPAHMessage(secondRotateText->text()); rotatePAH(); } else if (pahStage == PAH_THIRD_CAPTURE) { FITSData *imageData = alignView->getImageData(); // Critical error if (result == false) { appendLogText(i18n("Failed to process World Coordinate System: %1. Try again.", imageData->getLastError())); return; } // Find Celestial pole location SkyPoint CP(0, (hemisphere == NORTH_HEMISPHERE) ? 90 : -90); QPointF imagePoint; imageData->wcsToPixel(CP, celestialPolePoint, imagePoint); pahImageInfos[2]->celestialPole = celestialPolePoint; // Now find pixel locations for all recorded center coordinates in the 3rd frame reference imageData->wcsToPixel(pahImageInfos[0]->skyCenter, pahImageInfos[0]->pixelCenter, imagePoint); imageData->wcsToPixel(pahImageInfos[1]->skyCenter, pahImageInfos[1]->pixelCenter, imagePoint); imageData->wcsToPixel(pahImageInfos[2]->skyCenter, pahImageInfos[2]->pixelCenter, imagePoint); qCDebug(KSTARS_EKOS_ALIGN) << "P1 RA: " << pahImageInfos[0]->skyCenter.ra0().toHMSString() << "DE: " << pahImageInfos[0]->skyCenter.dec0().toDMSString(); qCDebug(KSTARS_EKOS_ALIGN) << "P2 RA: " << pahImageInfos[1]->skyCenter.ra0().toHMSString() << "DE: " << pahImageInfos[1]->skyCenter.dec0().toDMSString(); qCDebug(KSTARS_EKOS_ALIGN) << "P3 RA: " << pahImageInfos[2]->skyCenter.ra0().toHMSString() << "DE: " << pahImageInfos[2]->skyCenter.dec0().toDMSString(); qCDebug(KSTARS_EKOS_ALIGN) << "P1 X: " << pahImageInfos[0]->pixelCenter.x() << "Y: " << pahImageInfos[0]->pixelCenter.y(); qCDebug(KSTARS_EKOS_ALIGN) << "P2 X: " << pahImageInfos[1]->pixelCenter.x() << "Y: " << pahImageInfos[1]->pixelCenter.y(); qCDebug(KSTARS_EKOS_ALIGN) << "P3 X: " << pahImageInfos[2]->pixelCenter.x() << "Y: " << pahImageInfos[2]->pixelCenter.y(); qCDebug(KSTARS_EKOS_ALIGN) << "P1 CP X: " << pahImageInfos[0]->celestialPole.x() << "CP Y: " << pahImageInfos[0]->celestialPole.y(); qCDebug(KSTARS_EKOS_ALIGN) << "P2 CP X: " << pahImageInfos[1]->celestialPole.x() << "CP Y: " << pahImageInfos[1]->celestialPole.y(); qCDebug(KSTARS_EKOS_ALIGN) << "P3 CP X: " << pahImageInfos[2]->celestialPole.x() << "CP Y: " << pahImageInfos[2]->celestialPole.y(); // We have 3 points which uniquely defines a circle with its center representing the RA Axis // We have celestial pole location. So correction vector is just the vector between these two points calculatePAHError(); pahStage = PAH_STAR_SELECT; emit newPAHStage(pahStage); PAHWidgets->setCurrentWidget(PAHCorrectionPage); emit newPAHMessage(correctionText->text()); } } void Align::updateTelescopeType(int index) { if (currentCCD == nullptr) return; syncSettings(); /* bool rc = currentCCD->setTelescopeType(static_cast(index)); // If false, try to set it to existing known telescope if (rc == false) { focal_length = (index == ISD::CCD::TELESCOPE_PRIMARY) ? primaryFL : guideFL; aperture = (index == ISD::CCD::TELESCOPE_PRIMARY) ? primaryAperture : guideAperture; syncTelescopeInfo(); }*/ focal_length = (index == ISD::CCD::TELESCOPE_PRIMARY) ? primaryFL : guideFL; aperture = (index == ISD::CCD::TELESCOPE_PRIMARY) ? primaryAperture : guideAperture; Options::setSolverScopeType(index); syncTelescopeInfo(); } // Function adapted from https://rosettacode.org/wiki/Circles_of_given_radius_through_two_points Align::CircleSolution Align::findCircleSolutions(const QPointF &p1, const QPointF p2, double angle, QPair &circleSolutions) { QPointF solutionOne(1, 1), solutionTwo(1, 1); double radius = distance(p1, p2) / (dms::DegToRad * angle); if (p1 == p2) { if (angle == 0) { circleSolutions = qMakePair(p1, p2); appendLogText(i18n("Only one solution is found.")); return ONE_CIRCLE_SOLUTION; } else { circleSolutions = qMakePair(solutionOne, solutionTwo); appendLogText(i18n("Infinite number of solutions found.")); return INFINITE_CIRCLE_SOLUTION; } } QPointF center(p1.x() / 2 + p2.x() / 2, p1.y() / 2 + p2.y() / 2); double halfDistance = distance(center, p1); if (halfDistance > radius) { circleSolutions = qMakePair(solutionOne, solutionTwo); appendLogText(i18n("No solution is found. Points are too far away")); return NO_CIRCLE_SOLUTION; } if (halfDistance - radius == 0) { circleSolutions = qMakePair(center, solutionTwo); appendLogText(i18n("Only one solution is found.")); return ONE_CIRCLE_SOLUTION; } double root = std::hypotf(radius, halfDistance) / distance(p1, p2); solutionOne.setX(center.x() + root * (p1.y() - p2.y())); solutionOne.setY(center.y() + root * (p2.x() - p1.x())); solutionTwo.setX(center.x() - root * (p1.y() - p2.y())); solutionTwo.setY(center.y() - root * (p2.x() - p1.x())); circleSolutions = qMakePair(solutionOne, solutionTwo); return TWO_CIRCLE_SOLUTION; } double Align::distance(const QPointF &p1, const QPointF &p2) { return std::hypotf(p2.x() - p1.x(), p2.y() - p1.y()); } bool Align::findRACircle(QVector3D &RACircle) { bool rc = false; QPointF p1 = pahImageInfos[0]->pixelCenter; QPointF p2 = pahImageInfos[1]->pixelCenter; QPointF p3 = pahImageInfos[2]->pixelCenter; if (!isPerpendicular(p1, p2, p3)) rc = calcCircle(p1, p2, p3, RACircle); else if (!isPerpendicular(p1, p3, p2)) rc = calcCircle(p1, p3, p2, RACircle); else if (!isPerpendicular(p2, p1, p3)) rc = calcCircle(p2, p1, p3, RACircle); else if (!isPerpendicular(p2, p3, p1)) rc = calcCircle(p2, p3, p1, RACircle); else if (!isPerpendicular(p3, p2, p1)) rc = calcCircle(p3, p2, p1, RACircle); else if (!isPerpendicular(p3, p1, p2)) rc = calcCircle(p3, p1, p2, RACircle); else { //TRACE("\nThe three pts are perpendicular to axis\n"); return false; } return rc; } bool Align::isPerpendicular(const QPointF &p1, const QPointF &p2, const QPointF &p3) // Check the given point are perpendicular to x or y axis { double yDelta_a = p2.y() - p1.y(); double xDelta_a = p2.x() - p1.x(); double yDelta_b = p3.y() - p2.y(); double xDelta_b = p3.x() - p2.x(); // checking whether the line of the two pts are vertical if (fabs(xDelta_a) <= 0.000000001 && fabs(yDelta_b) <= 0.000000001) { //TRACE("The points are perpendicular and parallel to x-y axis\n"); return false; } if (fabs(yDelta_a) <= 0.0000001) { //TRACE(" A line of two point are perpendicular to x-axis 1\n"); return true; } else if (fabs(yDelta_b) <= 0.0000001) { //TRACE(" A line of two point are perpendicular to x-axis 2\n"); return true; } else if (fabs(xDelta_a) <= 0.000000001) { //TRACE(" A line of two point are perpendicular to y-axis 1\n"); return true; } else if (fabs(xDelta_b) <= 0.000000001) { //TRACE(" A line of two point are perpendicular to y-axis 2\n"); return true; } else return false; } bool Align::calcCircle(const QPointF &p1, const QPointF &p2, const QPointF &p3, QVector3D &RACircle) { double yDelta_a = p2.y() - p1.y(); double xDelta_a = p2.x() - p1.x(); double yDelta_b = p3.y() - p2.y(); double xDelta_b = p3.x() - p2.x(); if (fabs(xDelta_a) <= 0.000000001 && fabs(yDelta_b) <= 0.000000001) { RACircle.setX(0.5 * (p2.x() + p3.x())); RACircle.setY(0.5 * (p1.y() + p2.y())); QPointF center(RACircle.x(), RACircle.y()); RACircle.setZ(distance(center, p1)); return true; } // IsPerpendicular() assure that xDelta(s) are not zero double aSlope = yDelta_a / xDelta_a; // double bSlope = yDelta_b / xDelta_b; if (fabs(aSlope - bSlope) <= 0.000000001) { // checking whether the given points are colinear. //TRACE("The three ps are colinear\n"); return false; } // calc center RACircle.setX((aSlope * bSlope * (p1.y() - p3.y()) + bSlope * (p1.x() + p2.x()) - aSlope * (p2.x() + p3.x())) / (2 * (bSlope - aSlope))); RACircle.setY(-1 * (RACircle.x() - (p1.x() + p2.x()) / 2) / aSlope + (p1.y() + p2.y()) / 2); QPointF center(RACircle.x(), RACircle.y()); RACircle.setZ(distance(center, p1)); return true; } void Align::setMountStatus(ISD::Telescope::Status newState) { switch (newState) { case ISD::Telescope::MOUNT_PARKING: case ISD::Telescope::MOUNT_SLEWING: case ISD::Telescope::MOUNT_MOVING: solveB->setEnabled(false); loadSlewB->setEnabled(false); PAHStartB->setEnabled(false); break; default: if (state != ALIGN_PROGRESS) { solveB->setEnabled(true); if (pahStage == PAH_IDLE) { PAHStartB->setEnabled(true); loadSlewB->setEnabled(true); } } break; } } void Align::setAstrometryDevice(ISD::GDInterface *newAstrometry) { remoteParserDevice = newAstrometry; - remoteSolverR->setEnabled(true); if (remoteParser.get() != nullptr) { remoteParser->setAstrometryDevice(remoteParserDevice); connect(remoteParser.get(), &AstrometryParser::solverFinished, this, &Ekos::Align::solverFinished, Qt::UniqueConnection); connect(remoteParser.get(), &AstrometryParser::solverFailed, this, &Ekos::Align::solverFailed, Qt::UniqueConnection); } } void Align::setRotator(ISD::GDInterface *newRotator) { currentRotator = newRotator; connect(currentRotator, &ISD::GDInterface::numberUpdated, this, &Ekos::Align::processNumber, Qt::UniqueConnection); } void Align::refreshAlignOptions() { if (getSolverFOV()) getSolverFOV()->setImageDisplay(Options::astrometrySolverWCS()); m_AlignTimer.setInterval(Options::astrometryTimeout() * 1000); } void Align::setFilterManager(const QSharedPointer &manager) { filterManager = manager; connect(filterManager.data(), &FilterManager::ready, [this]() { if (filterPositionPending) { focusState = FOCUS_IDLE; filterPositionPending = false; captureAndSolve(); } } ); connect(filterManager.data(), &FilterManager::failed, [this]() { appendLogText(i18n("Filter operation failed.")); abort(); } ); connect(filterManager.data(), &FilterManager::newStatus, [this](Ekos::FilterState filterState) { if (filterPositionPending) { switch (filterState) { case FILTER_OFFSET: appendLogText(i18n("Changing focus offset by %1 steps...", filterManager->getTargetFilterOffset())); break; case FILTER_CHANGE: appendLogText(i18n("Changing filter to %1...", FilterPosCombo->itemText(filterManager->getTargetFilterPosition() - 1))); break; case FILTER_AUTOFOCUS: appendLogText(i18n("Auto focus on filter change...")); break; default: break; } } }); connect(filterManager.data(), &FilterManager::labelsChanged, this, [this]() { checkFilter(); }); connect(filterManager.data(), &FilterManager::positionChanged, this, [this]() { checkFilter(); }); } QVariantMap Align::getEffectiveFOV() { KStarsData::Instance()->userdb()->GetAllEffectiveFOVs(effectiveFOVs); fov_x = fov_y = 0; for (auto &map : effectiveFOVs) { if (map["Profile"].toString() == m_ActiveProfile->name) { if (map["Width"].toInt() == ccd_width && map["Height"].toInt() == ccd_height && map["PixelW"].toDouble() == ccd_hor_pixel && map["PixelH"].toDouble() == ccd_ver_pixel && map["FocalLength"].toDouble() == focal_length) { fov_x = map["FovW"].toDouble(); fov_y = map["FovH"].toDouble(); return map; } } } return QVariantMap(); } void Align::saveNewEffectiveFOV(double newFOVW, double newFOVH) { if (newFOVW < 0 || newFOVH < 0 || (newFOVW == fov_x && newFOVH == fov_y)) return; QVariantMap effectiveMap = getEffectiveFOV(); // If ID exists, delete it first. if (effectiveMap.isEmpty() == false) KStarsData::Instance()->userdb()->DeleteEffectiveFOV(effectiveMap["id"].toString()); // If FOV is 0x0, then we just remove existing effective FOV if (newFOVW == 0.0 && newFOVH == 0.0) { calculateFOV(); return; } effectiveMap["Profile"] = m_ActiveProfile->name; effectiveMap["Width"] = ccd_width; effectiveMap["Height"] = ccd_height; effectiveMap["PixelW"] = ccd_hor_pixel; effectiveMap["PixelH"] = ccd_ver_pixel; effectiveMap["FocalLength"] = focal_length; effectiveMap["FovW"] = newFOVW; effectiveMap["FovH"] = newFOVH; KStarsData::Instance()->userdb()->AddEffectiveFOV(effectiveMap); calculateFOV(); } QStringList Align::getActiveSolvers() const { QStringList solvers; solvers << "Online"; #ifndef Q_OS_WIN solvers << "Offline"; #endif if (remoteParserDevice != nullptr) solvers << "Remote"; return solvers; } int Align::getActiveSolverIndex() const { return solverTypeGroup->checkedId(); } QString Align::getPAHMessage() const { switch (pahStage) { case PAH_IDLE: case PAH_FIND_CP: - default: return introText->text(); case PAH_FIRST_CAPTURE: return firstCaptureText->text(); case PAH_FIRST_ROTATE: return firstRotateText->text(); case PAH_SECOND_CAPTURE: return secondCaptureText->text(); case PAH_SECOND_ROTATE: return secondRotateText->text(); case PAH_THIRD_CAPTURE: return thirdCaptureText->text(); case PAH_STAR_SELECT: return correctionText->text(); case PAH_PRE_REFRESH: case PAH_REFRESH: return refreshText->text(); case PAH_ERROR: return PAHErrorDescriptionLabel->text(); } } void Align::zoomAlignView() { alignView->ZoomDefault(); emit newFrame(alignView); } QJsonObject Align::getSettings() const { QJsonObject settings; settings.insert("camera", CCDCaptureCombo->currentText()); settings.insert("fw", FilterDevicesCombo->currentText()); settings.insert("filter", FilterPosCombo->currentText()); settings.insert("exp", exposureIN->value()); settings.insert("bin", binningCombo->currentIndex() + 1); settings.insert("solverAction", gotoModeButtonGroup->checkedId()); settings.insert("solverType", solverTypeGroup->checkedId()); settings.insert("scopeType", FOVScopeCombo->currentIndex()); return settings; } void Align::setSettings(const QJsonObject &settings) { CCDCaptureCombo->setCurrentText(settings["camera"].toString()); FilterDevicesCombo->setCurrentText(settings["fw"].toString()); FilterPosCombo->setCurrentText(settings["filter"].toString()); Options::setLockAlignFilterIndex(FilterPosCombo->currentIndex()); exposureIN->setValue(settings["exp"].toDouble(1)); binningCombo->setCurrentIndex(settings["bin"].toInt() - 1); gotoModeButtonGroup->button(settings["solverAction"].toInt(1))->click(); solverTypeGroup->button(settings["solverType"].toInt(1))->click(); FOVScopeCombo->setCurrentIndex(settings["scopeType"].toInt(0)); } void Align::syncSettings() { emit settingsUpdated(getSettings()); } QJsonObject Align::getPAHSettings() const { QJsonObject settings = getSettings(); settings.insert("mountDirection", PAHDirectionCombo->currentIndex()); settings.insert("mountSpeed", PAHSlewRateCombo->currentIndex()); settings.insert("mountRotation", PAHRotationSpin->value()); settings.insert("refresh", PAHExposure->value()); settings.insert("manualslew", PAHManual->isChecked()); return settings; } void Align::setPAHSettings(const QJsonObject &settings) { setSettings(settings); PAHDirectionCombo->setCurrentIndex(settings["mountDirection"].toInt(0)); PAHRotationSpin->setValue(settings["mountRotation"].toInt(30)); PAHExposure->setValue(settings["refresh"].toDouble(1)); if (settings.contains("mountSpeed")) PAHSlewRateCombo->setCurrentIndex(settings["mountSpeed"].toInt(0)); PAHManual->setChecked(settings["manualslew"].toBool(false)); } void Align::syncFOV() { QString newFOV = FOVOut->text(); QRegularExpression re("(\\d+\\.*\\d*)\\D*x\\D*(\\d+\\.*\\d*)"); QRegularExpressionMatch match = re.match(newFOV); if (match.hasMatch()) { double newFOVW = match.captured(1).toDouble(); double newFOVH = match.captured(2).toDouble(); //if (newFOVW > 0 && newFOVH > 0) saveNewEffectiveFOV(newFOVW, newFOVH); FOVOut->setStyleSheet(QString()); } else { KSNotification::error(i18n("Invalid FOV.")); FOVOut->setStyleSheet("background-color:red"); } } } diff --git a/kstars/ekos/align/align.h b/kstars/ekos/align/align.h index 539c6eac1..6a670a49e 100644 --- a/kstars/ekos/align/align.h +++ b/kstars/ekos/align/align.h @@ -1,923 +1,935 @@ /* Ekos Polar Alignment Tool Copyright (C) 2013 Jasem Mutlaq This application is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. */ #pragma once #include "ui_align.h" #include "ui_mountmodel.h" #include "ekos/ekos.h" #include "indi/indiccd.h" #include "indi/indistd.h" #include "indi/inditelescope.h" #include "indi/indidome.h" #include "ekos/auxiliary/filtermanager.h" #include #include #if QT_VERSION >= QT_VERSION_CHECK(5, 8, 0) #include #else #include #endif #include class QProgressIndicator; class AlignView; class FOV; class StarObject; class ProfileInfo; namespace Ekos { class AstrometryParser; class OnlineAstrometryParser; class OfflineAstrometryParser; class RemoteAstrometryParser; +class ASTAPAstrometryParser; class OpsAstrometry; class OpsAlign; +class OpsASTAP; class OpsAstrometryCfg; class OpsAstrometryIndexFiles; /** *@class Align *@short Align class handles plate-solving and polar alignment measurement and correction using astrometry.net * The align class can capture images from the CCD and use either online or offline astrometry.net engine to solve the plate constants and find the center RA/DEC coordinates. The user selects the action * to perform when the solver completes successfully. * Align module provide Polar Align Helper tool which enables easy-to-follow polar alignment procedure given wide FOVs (> 1.5 degrees) * For small FOVs, the Legacy polar alignment measurement should be used. * LEGACY: Measurement of polar alignment errors is performed by capturing two images on selected points in the sky and measuring the declination drift to calculate * the error in the mount's azimuth and altitude displacement from optimal. Correction is carried by asking the user to re-center a star by adjusting the telescope's azimuth and/or altitude knobs. *@author Jasem Mutlaq *@version 1.4 */ class Align : public QWidget, public Ui::Align { Q_OBJECT Q_CLASSINFO("D-Bus Interface", "org.kde.kstars.Ekos.Align") Q_PROPERTY(Ekos::AlignState status READ status NOTIFY newStatus) Q_PROPERTY(QStringList logText READ logText NOTIFY newLog) Q_PROPERTY(QString camera READ camera WRITE setCamera) Q_PROPERTY(QString filterWheel READ filterWheel WRITE setFilterWheel) Q_PROPERTY(QString filter READ filter WRITE setFilter) Q_PROPERTY(double exposure READ exposure WRITE setExposure) Q_PROPERTY(QList fov READ fov) Q_PROPERTY(QList cameraInfo READ cameraInfo) Q_PROPERTY(QList telescopeInfo READ telescopeInfo) Q_PROPERTY(QString solverArguments READ solverArguments WRITE setSolverArguments) public: explicit Align(ProfileInfo *activeProfile); virtual ~Align() override; typedef enum { AZ_INIT, AZ_FIRST_TARGET, AZ_SYNCING, AZ_SLEWING, AZ_SECOND_TARGET, AZ_CORRECTING, AZ_FINISHED } AZStage; typedef enum { ALT_INIT, ALT_FIRST_TARGET, ALT_SYNCING, ALT_SLEWING, ALT_SECOND_TARGET, ALT_CORRECTING, ALT_FINISHED } ALTStage; typedef enum { GOTO_SYNC, GOTO_SLEW, GOTO_NOTHING } GotoMode; - typedef enum { SOLVER_ONLINE, SOLVER_OFFLINE, SOLVER_REMOTE } SolverType; + typedef enum { SOLVER_ONLINE, SOLVER_OFFLINE, SOLVER_REMOTE } AstrometrySolverType; + typedef enum { SOLVER_ASTAP, SOLVER_ASTROMETRYNET } SolverType; typedef enum { PAH_IDLE, PAH_FIRST_CAPTURE, PAH_FIND_CP, PAH_FIRST_ROTATE, PAH_SECOND_CAPTURE, PAH_SECOND_ROTATE, PAH_THIRD_CAPTURE, PAH_STAR_SELECT, PAH_PRE_REFRESH, PAH_REFRESH, PAH_ERROR } PAHStage; typedef enum { NORTH_HEMISPHERE, SOUTH_HEMISPHERE } HemisphereType; // Image Scales const QStringList ImageScales = { "dw", "aw", "app" }; enum CircleSolution { NO_CIRCLE_SOLUTION, ONE_CIRCLE_SOLUTION, TWO_CIRCLE_SOLUTION, INFINITE_CIRCLE_SOLUTION }; enum ModelObjectType { OBJECT_ANY_STAR, OBJECT_NAMED_STAR, OBJECT_ANY_OBJECT, OBJECT_FIXED_DEC, OBJECT_FIXED_GRID }; /** @defgroup AlignDBusInterface Ekos DBus Interface - Align Module * Ekos::Align interface provides advanced scripting capabilities to solve images using online or offline astrometry.net */ /*@{*/ /** DBUS interface function. * Select CCD * @param device CCD device name * @return Returns true if device if found and selected, false otherwise. */ Q_SCRIPTABLE bool setCamera(const QString &device); Q_SCRIPTABLE QString camera(); /** DBUS interface function. * select the filter device from the available filter drivers. The filter device can be the same as the CCD driver if the filter functionality was embedded within the driver. * @param device The filter device name * @return Returns true if filter device is found and set, false otherwise. */ Q_SCRIPTABLE bool setFilterWheel(const QString &device); Q_SCRIPTABLE QString filterWheel(); /** DBUS interface function. * select the filter from the available filters. * @param filter The filter name * @return Returns true if filter is found and set, false otherwise. */ Q_SCRIPTABLE bool setFilter(const QString &filter); Q_SCRIPTABLE QString filter(); /** DBUS interface function. * Start the plate-solving process given the passed image file. * @param filename Name of image file to solve. FITS and JPG/JPG/TIFF formats are accepted. * @param isGenerated Set to true if filename is generated from a CCD capture operation. If the file is loaded from any storage or network media, pass false. * @return Returns true if device if found and selected, false otherwise. */ Q_SCRIPTABLE Q_NOREPLY void startSolving(const QString &filename, bool isGenerated = true); /** DBUS interface function. * Select Solver Action after successfully solving an image. * @param mode 0 for Sync, 1 for Slew To Target, 2 for Nothing (just display solution results) */ Q_SCRIPTABLE Q_NOREPLY void setSolverAction(int mode); /** DBUS interface function. * Returns the solver's solution results * @return Returns array of doubles. First item is RA in degrees. Second item is DEC in degrees. */ Q_SCRIPTABLE QList getSolutionResult(); /** DBUS interface function. * Returns the solver's current status * @return Returns solver status (Ekos::AlignState) */ Q_SCRIPTABLE Ekos::AlignState status() { return state; } /** DBUS interface function. * @return Returns State of load slew procedure. Idle if not started. Busy if in progress. Ok if complete. Alert if procedure failed. */ Q_SCRIPTABLE int getLoadAndSlewStatus() { return loadSlewState; } /** DBUS interface function. * Sets the exposure of the selected CCD device. * @param value Exposure value in seconds */ Q_SCRIPTABLE Q_NOREPLY void setExposure(double value); Q_SCRIPTABLE double exposure() { return exposureIN->value(); } /** DBUS interface function. * Sets the arguments that gets passed to the astrometry.net offline solver. * @param value space-separated arguments. */ Q_SCRIPTABLE Q_NOREPLY void setSolverArguments(const QString &value); /** DBUS interface function. * Get existing solver options. * @return String containing all arguments. */ Q_SCRIPTABLE QString solverArguments(); /** DBUS interface function. * Sets the telescope type (PRIMARY or GUIDE) that should be used for FOV calculations. This value is loaded form driver settings by default. * @param index 0 for PRIMARY telescope, 1 for GUIDE telescope */ Q_SCRIPTABLE Q_NOREPLY void setFOVTelescopeType(int index); int FOVTelescopeType() { return FOVScopeCombo->currentIndex(); } /** DBUS interface function. * Get currently active camera info in this order: * width, height, pixel_size_x, pixel_size_y */ Q_SCRIPTABLE QList cameraInfo(); /** DBUS interface function. * Get current active telescope info in this order: * focal length, aperture */ Q_SCRIPTABLE QList telescopeInfo(); /** @}*/ /** * @brief Add CCD to the list of available CCD. * @param newCCD pointer to CCD device. */ void addCCD(ISD::GDInterface *newCCD); /** * @brief addFilter Add filter to the list of available filters. * @param newFilter pointer to filter device. */ void addFilter(ISD::GDInterface *newFilter); /** * @brief Set the current telescope * @param newTelescope pointer to telescope device. */ void setTelescope(ISD::GDInterface *newTelescope); /** * @brief Set the current dome * @param newDome pointer to telescope device. */ void setDome(ISD::GDInterface *newDome); void setRotator(ISD::GDInterface *newRotator); void removeDevice(ISD::GDInterface *device); /* @brief Set telescope and guide scope info. All measurements is in millimeters. * @param primaryFocalLength Primary Telescope Focal Length. Set to 0 to skip setting this value. * @param primaryAperture Primary Telescope Aperture. Set to 0 to skip setting this value. * @param guideFocalLength Guide Telescope Focal Length. Set to 0 to skip setting this value. * @param guideAperture Guide Telescope Aperture. Set to 0 to skip setting this value. */ void setTelescopeInfo(double primaryFocalLength, double primaryAperture, double guideFocalLength, double guideAperture); /** * @brief setAstrometryDevice * @param newAstrometry */ void setAstrometryDevice(ISD::GDInterface *newAstrometry); /** * @brief CCD information is updated, sync them. */ void syncCCDInfo(); /** * @brief Generate arguments we pass to the online and offline solvers. Keep user own arguments in place. */ void generateArgs(); /** * @brief Does our parser exist in the system? */ bool isParserOK(); // Log QStringList logText() { return m_LogText; } QString getLogText() { return m_LogText.join("\n"); } void clearLog(); /** * @brief Return FOV object used to represent the solved image orientation on the sky map. */ FOV *getSolverFOV(); /** * @brief Return FOV object used to represent the current CCD/Telescope combination. */ FOV *getSensorFOV() { return sensorFOV.get(); } /** * @brief getFOVScale Returns calculated FOV values * @param fov_w FOV width in arcmins * @param fov_h FOV height in arcmins * @param fov_scale FOV scale in arcsec per pixel */ void getFOVScale(double &fov_w, double &fov_h, double &fov_scale); QList fov(); /** * @brief getCalculatedFOVScale Get calculated FOV scales from the current CCD+Telescope combination. * @param fov_w return calculated fov width in arcminutes * @param fov_h return calculated fov height in arcminutes * @param fov_scale return calculated fov pixcale in arcsecs per pixel. * @note This is NOT the same as effective FOV which is the measured FOV from astrometry. It is the * theoretical FOV from calculated values. */ void getCalculatedFOVScale(double &fov_w, double &fov_h, double &fov_scale); void setFilterManager(const QSharedPointer &manager); // Ekos Live Client helper functions QStringList getActiveSolvers() const; int getActiveSolverIndex() const; void setCaptureSettings(const QJsonObject &settings); /** * @brief generateOptions Generate astrometry.net option given the supplied map * @param optionsMap List of key=value pairs for all astrometry.net options * @return String List of valid astrometry.net options */ static QStringList generateOptions(const QVariantMap &optionsMap); static void generateFOVBounds(double fov_h, double fov_v, QString &fov_low, QString &fov_high); public slots: /** * @brief Process updated device properties * @param nvp pointer to updated property. */ void processNumber(INumberVectorProperty *nvp); /** * @brief Process updated device properties * @param svp pointer to updated property. */ void processSwitch(ISwitchVectorProperty *svp); /** * @brief Check CCD and make sure information is updated and FOV is re-calculated. * @param CCDNum By default, we check the already selected CCD in the dropdown menu. If CCDNum is specified, the check is made against this specific CCD in the dropdown menu. CCDNum is the index of the CCD in the dropdown menu. */ void checkCCD(int CCDNum = -1); /** * @brief Check Filter and make sure information is updated accordingly. * @param filterNum By default, we check the already selected filter in the dropdown menu. If filterNum is specified, the check is made against this specific filter in the dropdown menu. * filterNum is the index of the filter in the dropdown menu. */ void checkFilter(int filterNum = -1); /** * @brief checkCCDExposureProgress Track the progress of CCD exposure * @param targetChip Target chip under exposure * @param remaining how many seconds remaining * @param state status of exposure */ void checkCCDExposureProgress(ISD::CCDChip *targetChip, double remaining, IPState state); /** * @brief Process new FITS received from CCD. * @param bp pointer to blob property */ void newFITS(IBLOB *bp); /** \addtogroup AlignDBusInterface * @{ */ /** DBUS interface function. * Aborts the solving operation. */ Q_SCRIPTABLE Q_NOREPLY void abort(); /** DBUS interface function. * Select the solver type - * @param type Set solver type. 0 online, 1 offline, 2 remote + * @param type Set solver type. 0 ASTAP, 1 astrometry.net */ Q_SCRIPTABLE Q_NOREPLY void setSolverType(int type); + /** DBUS interface function. + * Select the astrometry solver type + * @param type Set solver type. 0 online, 1 offline, 2 remote + */ + Q_SCRIPTABLE Q_NOREPLY void setAstrometrySolverType(int type); + /** DBUS interface function. * Capture and solve an image using the astrometry.net engine * @return Returns true if the procedure started successful, false otherwise. */ Q_SCRIPTABLE bool captureAndSolve(); /** DBUS interface function. * Loads an image (FITS or JPG/TIFF) and solve its coordinates, then it slews to the solved coordinates and an image is captured and solved to ensure * the telescope is pointing to the same coordinates of the image. * @param fileURL URL to the image to solve */ Q_SCRIPTABLE bool loadAndSlew(QString fileURL = QString()); /** DBUS interface function. * Sets the binning of the selected CCD device. * @param binIndex Index of binning value. Default values range from 0 (binning 1x1) to 3 (binning 4x4) */ Q_SCRIPTABLE Q_NOREPLY void setBinningIndex(int binIndex); /** @}*/ /** * @brief Solver finished successfully, process the data and execute the required actions depending on the mode. * @param orientation Orientation of image in degrees (East of North) * @param ra Center RA in solved image, degrees. * @param dec Center DEC in solved image, degrees. * @param pixscale Image scale is arcsec/pixel */ void solverFinished(double orientation, double ra, double dec, double pixscale); /** * @brief Process solver failure. */ void solverFailed(); /** * @brief We received new telescope info, process them and update FOV. */ bool syncTelescopeInfo(); void setFocusStatus(Ekos::FocusState state); // Log void appendLogText(const QString &); // Capture void setCaptureComplete(); // Update Capture Module status void setCaptureStatus(Ekos::CaptureState newState); // Update Mount module status void setMountStatus(ISD::Telescope::Status newState); // PAH Ekos Live QString getPAHStage() const { return PAHStages[pahStage]; } bool isPAHEnabled() const { return isPAHReady; } QString getPAHMessage() const; void startPAHProcess(); void stopPAHProcess(); void setPAHCorrectionOffsetPercentage(double dx, double dy); void setPAHMountDirection(int index) { PAHDirectionCombo->setCurrentIndex(index); } void setPAHMountRotation(int value) { PAHRotationSpin->setValue(value); } void setPAHRefreshDuration(double value) { PAHExposure->setValue(value); } void startPAHRefreshProcess(); void setPAHRefreshComplete(); void setPAHSlewDone(); void setPAHCorrectionSelectionComplete(); void zoomAlignView(); // Align Settings QJsonObject getSettings() const; void setSettings(const QJsonObject &settings); // PAH Settings. PAH should be in separate class QJsonObject getPAHSettings() const; void setPAHSettings(const QJsonObject &settings); private slots: /* Polar Alignment */ void measureAltError(); void measureAzError(); void correctAzError(); void correctAltError(); void setDefaultCCD(QString ccd); void saveSettleTime(); // Solver timeout void checkAlignmentTimeout(); void updateTelescopeType(int index); // External View void showFITSViewer(); void toggleAlignWidgetFullScreen(); // Polar Alignment Helper slots void rotatePAH(); void setPAHCorrectionOffset(int x, int y); void setWCSToggled(bool result); //Solutions Display slots void buildTarget(); void handlePointTooltip(QMouseEvent *event); void handleVerticalPlotSizeChange(); void handleHorizontalPlotSizeChange(); void selectSolutionTableRow(int row, int column); void slotClearAllSolutionPoints(); void slotRemoveSolutionPoint(); void slotMountModel(); //Mount Model Slots void slotWizardAlignmentPoints(); void slotStarSelected(const QString selectedStar); void slotLoadAlignmentPoints(); void slotSaveAsAlignmentPoints(); void slotSaveAlignmentPoints(); void slotClearAllAlignPoints(); void slotRemoveAlignPoint(); void slotAddAlignPoint(); void slotFindAlignObject(); void resetAlignmentProcedure(); void startStopAlignmentProcedure(); void startAlignmentPoint(); void finishAlignmentPoint(bool solverSucceeded); void moveAlignPoint(int logicalIndex, int oldVisualIndex, int newVisualIndex); void exportSolutionPoints(); void alignTypeChanged(int alignType); void togglePreviewAlignPoints(); void slotSortAlignmentPoints(); void slotAutoScaleGraph(); // Settings void syncSettings(); protected slots: /** * @brief After a solver process is completed successfully, sync, slew to target, or do nothing as set by the user. */ void executeGOTO(); /** * @brief refreshAlignOptions is called when settings are updated in OpsAlign. */ void refreshAlignOptions(); signals: void newLog(const QString &text); void newStatus(Ekos::AlignState state); void newSolution(const QVariantMap &solution); // This is sent when we load an image in the view void newImage(FITSView *view); // This is sent when the pixmap is updated within the view void newFrame(FITSView *view); void polarResultUpdated(QLineF correctionVector, QString polarError); void newCorrectionVector(QLineF correctionVector); void newSolverResults(double orientation, double ra, double dec, double pixscale); // Polar Assistant Tool void newPAHStage(PAHStage stage); void newPAHMessage(const QString &message); void newFOVTelescopeType(int index); void PAHEnabled(bool); // Settings void settingsUpdated(const QJsonObject &settings); private: /** * @brief Calculate Field of View of CCD+Telescope combination that we need to pass to astrometry.net solver. */ void calculateFOV(); /** * @brief After a solver process is completed successfully, measure Azimuth or Altitude error as requested by the user. */ void executePolarAlign(); /** * @brief Sync the telescope to the solved alignment coordinate. */ void Sync(); /** * @brief Slew the telescope to the solved alignment coordinate. */ void Slew(); /** * @brief Sync the telescope to the solved alignment coordinate, and then slew to the target coordinate. */ void SlewToTarget(); /** * @brief Calculate polar alignment error magnitude and direction. * The calculation is performed by first capturing and solving a frame, then slewing 30 arcminutes and solving another frame to find the exact coordinates, then computing the error. * @param initRA RA of first frame. * @param initDEC DEC of first frame * @param finalRA RA of second frame * @param finalDEC DEC of second frame * @param initAz Azimuth of first frame */ void calculatePolarError(double initRA, double initDEC, double finalRA, double finalDEC, double initAz); /** * @brief Get formatted RA & DEC coordinates compatible with astrometry.net format. * @param ra Right ascension * @param dec Declination * @param ra_str will contain the formatted RA string * @param dec_str will contain the formatted DEC string */ void getFormattedCoords(double ra, double dec, QString &ra_str, QString &dec_str); /** * @brief getSolverOptionsFromFITS Generates a set of solver options given the supplied FITS image. The function reads FITS keyword headers and build the argument list accordingly. In case of a missing header keyword, it falls back to * the Alignment module existing values. * @param filename FITS path * @return List of Solver options */ QStringList getSolverOptionsFromFITS(const QString &filename); uint8_t getSolverDownsample(uint16_t binnedW); /** * @brief setWCSEnabled enables/disables World Coordinate System settings in the CCD driver. * @param enable true to enable WCS, false to disable. */ void setWCSEnabled(bool enable); /** * @brief calculatePAHError Calculate polar alignment error in the Polar Alignment Helper (PAH) method */ void calculatePAHError(); /** * @brief processPAHStage After solver is complete, handle PAH Stage processing */ void processPAHStage(double orientation, double ra, double dec, double pixscale); CircleSolution findCircleSolutions(const QPointF &p1, const QPointF p2, double angle, QPair &circleSolutions); double distance(const QPointF &p1, const QPointF &p2); bool findRACircle(QVector3D &RACircle); bool isPerpendicular(const QPointF &p1, const QPointF &p2, const QPointF &p3); bool calcCircle(const QPointF &p1, const QPointF &p2, const QPointF &p3, QVector3D &RACircle); void resizeEvent(QResizeEvent *event) override; bool alignmentPointsAreBad(); bool loadAlignmentPoints(const QString &fileURL); bool saveAlignmentPoints(const QString &path); void generateAlignStarList(); bool isVisible(const SkyObject *so); double getAltitude(const SkyObject *so); const SkyObject *getWizardAlignObject(double ra, double de); void calculateAngleForRALine(double &raIncrement, double &initRA, double initDEC, double lat, double raPoints, double minAlt); void calculateAZPointsForDEC(dms dec, dms alt, dms &AZEast, dms &AZWest); void updatePreviewAlignPoints(); int findNextAlignmentPointAfter(int currentSpot); int findClosestAlignmentPointToTelescope(); void swapAlignPoints(int firstPt, int secondPt); // Effective FOV /** * @brief getEffectiveFOV Search database for effective FOV that matches the current profile and settings * @return Variant Map containing effect FOV data or empty variant map if none found */ QVariantMap getEffectiveFOV(); void saveNewEffectiveFOV(double newFOVW, double newFOVH); QList effectiveFOVs; void syncFOV(); /// Which chip should we invoke in the current CCD? bool useGuideHead { false }; /// Can the mount sync its coordinates to those set by Ekos? bool canSync { false }; // LoadSlew mode is when we load an image and solve it, no capture is done. //bool loadSlewMode; /// If load and slew is solved successfully, coordinates obtained, slewed to target, and then captured, solved, and re-slewed to target again. IPState loadSlewState { IPS_IDLE }; // Target Position Angle of solver Load&Slew image to be used for rotator if necessary double loadSlewTargetPA { std::numeric_limits::quiet_NaN() }; double currentRotatorPA { -1 }; /// Solver iterations count uint8_t solverIterations { 0 }; // FOV double ccd_hor_pixel { -1 }; double ccd_ver_pixel { -1 }; double focal_length { -1 }; double aperture { -1 }; double fov_x { 0 }; double fov_y { 0 }; double fov_pixscale { 0 }; int ccd_width { 0 }; int ccd_height { 0 }; // Keep track of solver results double sOrientation { INVALID_VALUE }; double sRA { INVALID_VALUE }; double sDEC { INVALID_VALUE }; /// Solver alignment coordinates SkyPoint alignCoord; /// Target coordinates we need to slew to SkyPoint targetCoord; /// Actual current telescope coordinates SkyPoint telescopeCoord; /// Coord from Load & Slew SkyPoint loadSlewCoord; /// Difference between solution and target coordinate double targetDiff { 1e6 }; /// Progress icon if the solver is running std::unique_ptr pi; /// Keep track of how long the solver is running QTime solverTimer; // Polar Alignment AZStage azStage; ALTStage altStage; double azDeviation { 0 }; double altDeviation { 0 }; double decDeviation { 0 }; static const double RAMotion; static const double SIDRATE; /// Have we slewed? bool m_wasSlewStarted { false }; // Online and Offline parsers AstrometryParser* parser { nullptr }; std::unique_ptr onlineParser; std::unique_ptr offlineParser; std::unique_ptr remoteParser; ISD::GDInterface *remoteParserDevice { nullptr }; + std::unique_ptr astapParser; + // Pointers to our devices ISD::Telescope *currentTelescope { nullptr }; ISD::Dome *currentDome { nullptr }; ISD::CCD *currentCCD { nullptr }; ISD::GDInterface *currentRotator { nullptr }; QList CCDs; /// Optional device filter ISD::GDInterface *currentFilter { nullptr }; /// They're generic GDInterface because they could be either ISD::CCD or ISD::Filter QList Filters; int currentFilterPosition { -1 }; /// True if we need to change filter position and wait for result before continuing capture bool filterPositionPending { false }; /// Keep track of solver FOV to be plotted in the skymap after each successful solve operation std::unique_ptr solverFOV; std::unique_ptr sensorFOV; /// WCS bool m_wcsSynced { false }; /// Log QStringList m_LogText; /// Issue counters uint8_t m_CaptureTimeoutCounter { 0 }; uint8_t m_CaptureErrorCounter { 0 }; uint8_t m_SlewErrorCounter { 0 }; QTimer m_CaptureTimer; // State AlignState state { ALIGN_IDLE }; FocusState focusState { FOCUS_IDLE }; // Track which upload mode the CCD is set to. If set to UPLOAD_LOCAL, then we need to switch it to UPLOAD_CLIENT in order to do focusing, and then switch it back to UPLOAD_LOCAL ISD::CCD::UploadMode rememberUploadMode { ISD::CCD::UPLOAD_CLIENT }; GotoMode currentGotoMode; QString dirPath; // Timer QTimer m_AlignTimer; // BLOB Type ISD::CCD::BlobType blobType; QString blobFileName; // Align Frame AlignView *alignView { nullptr }; // FITS Viewer in case user want to display in it instead of internal view QPointer fv; // Polar Alignment Helper PAHStage pahStage { PAH_IDLE }; SkyPoint targetPAH; bool isPAHReady { false }; // keep track of autoWSC bool rememberAutoWCS { false }; bool rememberSolverWCS { false }; // Sky centers typedef struct { SkyPoint skyCenter; QPointF celestialPole; QPointF pixelCenter; double pixelScale { 0 }; double orientation { 0 }; } PAHImageInfo; QVector pahImageInfos; // User desired offset when selecting a bright star in the image QPointF celestialPolePoint, correctionOffset; // Correction vector line between mount RA Axis and celestial pole QLineF correctionVector; // CCDs using Guide Scope for parameters //QStringList guideScopeCCDs; // Which hemisphere are we located on? HemisphereType hemisphere; // Differential Slewing bool differentialSlewingActivated { false }; // Astrometry Options OpsAstrometry *opsAstrometry { nullptr }; OpsAlign *opsAlign { nullptr }; OpsAstrometryCfg *opsAstrometryCfg { nullptr }; OpsAstrometryIndexFiles *opsAstrometryIndexFiles { nullptr }; + OpsASTAP *opsASTAP { nullptr }; QCPCurve *centralTarget { nullptr }; QCPCurve *yellowTarget { nullptr }; QCPCurve *redTarget { nullptr }; QCPCurve *concentricRings { nullptr }; QDialog mountModelDialog; Ui_mountModel mountModel; int currentAlignmentPoint { 0 }; bool mountModelRunning { false }; bool mountModelReset { false }; bool targetAccuracyNotMet { false }; bool previewShowing { false }; QUrl alignURL; QUrl alignURLPath; QVector alignStars; ISD::CCD::TelescopeType rememberTelescopeType = { ISD::CCD::TELESCOPE_UNKNOWN }; double primaryFL = -1, primaryAperture = -1, guideFL = -1, guideAperture = -1; bool m_isRateSynced = false; bool domeReady = true; // CCD Exposure Looping bool rememberCCDExposureLooping = { false }; // Filter Manager QSharedPointer filterManager; // Active Profile ProfileInfo *m_ActiveProfile { nullptr }; // PAH Stage Map static const QMap PAHStages; // Threshold to notify settle time is 3 seconds static constexpr uint16_t DELAY_THRESHOLD_NOTIFY { 3000 }; // Threshold to stop PAH rotation in degrees static constexpr uint8_t PAH_ROTATION_THRESHOLD { 5 }; }; } diff --git a/kstars/ekos/align/align.ui b/kstars/ekos/align/align.ui index b05c5bb1e..8bd3e2636 100644 --- a/kstars/ekos/align/align.ui +++ b/kstars/ekos/align/align.ui @@ -1,1865 +1,1838 @@ Align 0 0 - 636 - 502 + 694 + 541 3 3 3 3 3 0 3 Solver Control Qt::AlignLeading|Qt::AlignLeft|Qt::AlignVCenter 3 3 3 3 3 true Capture && Solve true true Load a FITS image and solve. Slew mount to image central coordinates. Load && Slew... false Stop Select which action to perform after the captured image is solved Select what action to take once a solution is found. Solver Action 3 3 3 3 3 Synchronize the telescope to the solution coordinates S&ync true gotoModeButtonGroup Synchronize the telescope to the solution coordinates and then slew to the target coordinates S&lew to Target gotoModeButtonGroup Just solve &Nothing gotoModeButtonGroup Telescope Coordinates (JNow) Accuracy threshold in arcseconds between solution and target coordinates. Plate solver shall be repeatedly executed until the solution coordinates are below the accuracy threshold 1 1200 10 30 DE: true After telescope completes slewing, wait until it settles for this many milliseconds before capturing the next image. Settle true After telescope completes slewing, wait until it settles for this many milliseconds before capturing the next image. 15000 100 RA: Accuracy threshold in arcseconds between solution and target coordinates. Plate solver shall be repeatedly executed until the solution coordinates are below the accuracy threshold Accuracy Solution Coordinates (JNow) 3 3 3 3 3 Image scale in arcsecs/pixel true Image scale in arcsecs/pixel Pix: Effective field of view size in arcminutes. false Image rotation angle, East of North true true RA: Difference between telescope coordinates and solution coordinates in Declination dDE Difference between telescope coordinates and solution coordinates in Right Ascension dRA: true Effective field of view size in arcminutes. FOV: Image rotation angle, East of North Rot: Difference between telescope coordinates and solution coordinates in Declination font-weight: bold; true DE: Difference between telescope coordinates and solution coordinates in Right Ascension font-weight: bold; true Select which telescope to use when performing Field of View calculations. Primary Scope Guide Scope Solver Options 3 3 3 3 3 1 1 CCD: 22 22 22 22 Toggle full screen Exposure duration in seconds 0.100000000000000 60.000000000000000 0.500000000000000 3.000000000000000 Exp: Subtract dark frame. If no suitable dark frame is available, a dark frame shall be captured. Dark Camera binning Bin: 22 22 22 22 Show in FITS Viewer FW: Filter: 3 Options: Additional options to be the solver false 22 22 22 22 Edit solver options 3 Solver: - + Use online astrometry.net solver to solve the image. You must have an Internet connection and a valid API key. - Onl&ine + ASTAP true solverTypeGroup - + Use offline astrometry.net solver. You must install all the necessary index files for your field of view. - Offline + Astrometry.net solverTypeGroup - - - false - - - <p>Use astrometry solver on remote machine running INDI server. You must select <b>Astrometry</b> driver from Auxiliary drivers in your Ekos devices profile for this option to be enabled.</p> - - - Re&mote - - - solverTypeGroup - - - - - - - Qt::Horizontal - - - - 40 - 20 - - - + Qt::Vertical QSizePolicy::MinimumExpanding 20 1 0 0 Qt::Vertical 0 0 320 240 0 Solution Results 5 0 0 0 0 0 0 The results from Astrometric Solutions from the Capture and Solve Tool, the Load and Slew Tool, and the Mount Model Tool will be displayed below. true 0 0 Qt::Horizontal 0 0 6 75 RA AlignCenter DEC AlignCenter Obj Name AlignCenter ~~ AlignCenter dRA AlignCenter dDE AlignCenter 0 32 32 32 32 Clear all of the solutions from the solutions table. Be careful because you cannot get them back. 32 32 32 33 Remove the selected row from the solutions table. This can be useful for getting rid of results that did not actually solve from the table and/or results that you do not need any more. It can clean up clutter on both the graph and table. 32 32 32 33 Export all of the solutions in the Solution Results table to CSV file of your choosing for further analysis in a spreadsheet. 32 32 32 33 Auto scale and center the Solution Results graph. Qt::Horizontal 40 20 Launch the mount model tool. This tool enables you to create pre-programmed list of points to go to and solve. It can aid in building a pointing model for better accuracy. Mount Model 0 0 100 100 190 190 Polar Alignment 0 0 0 0 true 0 150 Polar Alignment Assistant 3 3 3 3 3 true <p>Polar Alignment Helper tool requires the following:</p><p>1. German Equatorial Mount</p><p>2. Wide FOV &gt; 1 degrees</p><p>For small FOVs, use the Legacy Polar Alignment Tool.</p> QFrame::NoFrame 0 true 3 3 3 3 3 true <html><head/><body><p>This tool provides a simple method to polar align a German equatorial mount. <span style=" font-weight:600;">Park</span> your mount to home position where it <span style=" font-weight:600;">points</span> toward the celestial pole with the counter weight down. Select mount direction and speed and then click <span style=" font-weight:600;">Start</span> to begin the process.</p></body></html> true <html><head/><body><p><span style=" font-weight:600; color:#ff5500;">Disabled: FOV must be 10 arcmins or wider. 60+ arcminutes is recommended.</span></p></body></html> Qt::RichText 3 false Direction: false Mount direction West East false Rotation magnitude in degrees 15 60 15 30 Speed: false Toggle for manual slewing with non-GOTO mounts Manual slew Qt::Horizontal 40 20 3 3 3 3 3 <p>The assistant requires three images to find a solution. Ekos is now capturing the first image...</p> true 3 3 3 3 3 <p>Executing the <span style=" font-style:italic;">first</span> mount rotation...</p> true Qt::Horizontal 40 20 Done 3 3 3 3 3 <p>Capturing the second image...</p> true <p>Executing the <i>second </i>mount rotation...</p> true Qt::Horizontal 40 20 Done <p>Capturing the <i>third</i> and final image...</p> true 3 3 3 3 3 Error Occurred true 3 Angle between expected perfectly aligned mount center and the actual center Polar Error: 0 Qt::Horizontal 40 20 3 0 0 <p>Correction vector is plotted above. <b>Select</b> a bright star to reposition the correction vector. Proceed next when done.</p> true Next 3 3 3 3 3 <p>Adjust mount's Altitude and Azimuth knobs until the selected star is centered within the crosshair. Click <b>Refresh</b> to begin continuous capture. You are <b>Done</b> when star is centered.</p> true 3 Refresh Exposure duration in seconds during refresh phase 4 0.000100000000000 30.000000000000000 1.000000000000000 Qt::Horizontal 40 20 Done 3 Qt::Horizontal 40 20 false Start Start false Stop Stop Legacy Polar Alignment Tool Qt::AlignLeading|Qt::AlignLeft|Qt::AlignTop 3 3 3 3 3 3 Az Error: true true Measure Az Error false Correct Az Error Qt::Vertical 3 Alt Error: true true Measure Alt Error false Correct Alt Error QCustomPlot QWidget
auxiliary/qcustomplot.h
1 solveB loadSlewB stopB syncR slewR nothingR ScopeRAOut ScopeDecOut accuracySpin delaySpin SolverRAOut SolverDecOut dRAOut dDEOut pixScaleOut RotOut FOVOut FOVScopeCombo tabWidget CCDCaptureCombo showFITSViewerB exposureIN alignDarkFrameCheck toggleFullScreenB binningCombo FilterDevicesCombo FilterPosCombo solverOptions editOptionsB - onlineSolverR - offlineSolverR - remoteSolverR + astapSolverR + astrometrySolverR solutionTable clearAllSolutionsB removeSolutionB exportSolutionsCSV autoScaleGraphB mountModelB correctAltB altError azError correctAzB measureAzB measureAltB PAHCorrectionsNextB PAHRefreshB PAHExposure PAHDoneB PAHManual toggled(bool) PAHfirstDone setEnabled(bool) 699 392 388 316 PAHManual toggled(bool) PAHsecondDone setEnabled(bool) 699 392 385 316 diff --git a/kstars/ekos/align/astapastrometryparser.cpp b/kstars/ekos/align/astapastrometryparser.cpp new file mode 100644 index 000000000..98a1bcc84 --- /dev/null +++ b/kstars/ekos/align/astapastrometryparser.cpp @@ -0,0 +1,54 @@ +/* Astrometry.net Parser - Remote + Copyright (C) 2016 Jasem Mutlaq + + This application is free software; you can redistribute it and/or + modify it under the terms of the GNU General Public + License as published by the Free Software Foundation; either + version 2 of the License, or (at your option) any later version. +*/ + +#include "astapastrometryparser.h" + +#include "align.h" +#include "ekos_align_debug.h" +#include "Options.h" +#include "indi/clientmanager.h" +#include "indi/driverinfo.h" +#include "indi/guimanager.h" +#include "indi/indidevice.h" + +#include + +#include + +namespace Ekos +{ +ASTAPAstrometryParser::ASTAPAstrometryParser() : AstrometryParser() +{ +} + +bool ASTAPAstrometryParser::init() +{ + return QFile::exists(Options::aSTAPExecutable()); +} + +void ASTAPAstrometryParser::verifyIndexFiles(double, double) +{ +} + +bool ASTAPAstrometryParser::startSovler(const QString &filename, const QStringList &args, bool generated) +{ + INDI_UNUSED(generated); + + align->appendLogText(i18n("Starting ASTAP solver...")); + solverTimer.start(); + + return true; +} + +bool ASTAPAstrometryParser::stopSolver() +{ + solverRunning = false; + return true; +} +} diff --git a/kstars/ekos/align/astapastrometryparser.h b/kstars/ekos/align/astapastrometryparser.h new file mode 100644 index 000000000..f002c9cd9 --- /dev/null +++ b/kstars/ekos/align/astapastrometryparser.h @@ -0,0 +1,53 @@ +/* ASTAP Parser + Copyright (C) 2019 Jasem Mutlaq + + This application is free software; you can redistribute it and/or + modify it under the terms of the GNU General Public + License as published by the Free Software Foundation; either + version 2 of the License, or (at your option) any later version. +*/ + +#pragma once + +#include "astrometryparser.h" +#include "indi/indiccd.h" + +namespace Ekos +{ +class Align; + +/** + * @class ASTAPAstrometryParser + * ASTAPAstrometryParser invokes the local ASTAP solver. + * + * @author Jasem Mutlaq + */ +class ASTAPAstrometryParser : public AstrometryParser +{ + Q_OBJECT + + public: + ASTAPAstrometryParser(); + virtual ~ASTAPAstrometryParser() override = default; + + virtual void setAlign(Align *_align) override + { + align = _align; + } + virtual bool init() override; + virtual void verifyIndexFiles(double fov_x, double fov_y) override; + virtual bool startSovler(const QString &filename, const QStringList &args, bool generated = true) override; + virtual bool stopSolver() override; + + public slots: + void checkStatus(ISwitchVectorProperty *svp); + void checkResults(INumberVectorProperty *nvp); + + private: + bool solverRunning { false }; + bool captureRunning { false }; + Align *align { nullptr }; + QTime solverTimer; + QString targetCCD; +}; +} diff --git a/kstars/ekos/align/opsastap.cpp b/kstars/ekos/align/opsastap.cpp new file mode 100644 index 000000000..16a5f60cc --- /dev/null +++ b/kstars/ekos/align/opsastap.cpp @@ -0,0 +1,51 @@ +/* ASTAP Options Editor + Copyright (C) 2019 Jasem Mutlaq + + This application is free software; you can redistribute it and/or + modify it under the terms of the GNU General Public + License as published by the Free Software Foundation; either + version 2 of the License, or (at your option) any later version. +*/ + +#include "opsastap.h" + +#include "align.h" +#include "fov.h" +#include "kstars.h" +#include "ksnotification.h" +#include "Options.h" + +#include +#include + +namespace Ekos +{ +OpsASTAP::OpsASTAP(Align *parent) : QWidget(KStars::Instance()) +{ + setupUi(this); + + alignModule = parent; + + //Get a pointer to the KConfigDialog + m_ConfigDialog = KConfigDialog::exists("alignsettings"); + + connect(m_ConfigDialog->button(QDialogButtonBox::Apply), SIGNAL(clicked()), SLOT(slotApply())); + connect(m_ConfigDialog->button(QDialogButtonBox::Ok), SIGNAL(clicked()), SLOT(slotApply())); + connect(selectASTAPExecB, &QPushButton::clicked, this, &OpsASTAP::slotSelectExecutable); +} + +void OpsASTAP::slotApply() +{ + emit settingsUpdated(); +} + +void OpsASTAP::slotSelectExecutable() +{ + QUrl executable = QFileDialog::getOpenFileUrl(this, i18n("Select ASTAP executable"), QUrl(), "(astap astap.exe)"); + if (executable.isEmpty()) + return; + + kcfg_ASTAPExecutable->setText(executable.toLocalFile()); +} + +} diff --git a/kstars/ekos/align/opsastap.h b/kstars/ekos/align/opsastap.h new file mode 100644 index 000000000..612640018 --- /dev/null +++ b/kstars/ekos/align/opsastap.h @@ -0,0 +1,43 @@ +/* ASTAP Options Editor + Copyright (C) 2019 Jasem Mutlaq + + This application is free software; you can redistribute it and/or + modify it under the terms of the GNU General Public + License as published by the Free Software Foundation; either + version 2 of the License, or (at your option) any later version. +*/ + +#pragma once + +#include "ui_opsastap.h" + +#include + +class KConfigDialog; + +namespace Ekos +{ +class Align; + +class OpsASTAP : public QWidget, public Ui::OpsASTAP +{ + Q_OBJECT + + public: + explicit OpsASTAP(Align *parent); + virtual ~OpsASTAP() override = default; + + private slots: + void slotApply(); + void slotSelectExecutable(); + + signals: + void settingsUpdated(); + + private: + KConfigDialog *m_ConfigDialog { nullptr }; + Align *alignModule { nullptr }; + + +}; +} diff --git a/kstars/ekos/align/opsastap.ui b/kstars/ekos/align/opsastap.ui new file mode 100644 index 000000000..8544f9048 --- /dev/null +++ b/kstars/ekos/align/opsastap.ui @@ -0,0 +1,220 @@ + + + OpsASTAP + + + + 0 + 0 + 373 + 195 + + + + + 3 + + + 3 + + + 3 + + + 3 + + + 3 + + + + + + + Options + + + + + + <html><head/><body><p>Down sample prior to solving. Also called binning. A value &quot;0&quot; will result in auto selection downsampling.</p></body></html> + + + Tolerance + + + false + + + + + + + <html><head/><body><p>Down sample prior to solving. Also called binning. A value &quot;0&quot; will result in auto selection downsampling.</p></body></html> + + + Down Sample + + + false + + + + + + + <html><head/><body><p>Down sample prior to solving. Also called binning. A value &quot;0&quot; will result in auto selection downsampling.</p></body></html> + + + 0 + + + 4 + + + 0 + + + + + + + 3 + + + 0.003000000000000 + + + 0.007000000000000 + + + 0.001000000000000 + + + 0.005000000000000 + + + + + + + + 200 + 0 + + + + + + + + + + + 1 + + + 60 + + + 30 + + + + + + + Executable + + + + + + + <html><head/><body><p>Down sample prior to solving. Also called binning. A value &quot;0&quot; will result in auto selection downsampling.</p></body></html> + + + Update FITS + + + false + + + + + + + <html><head/><body><p>Down sample prior to solving. Also called binning. A value &quot;0&quot; will result in auto selection downsampling.</p></body></html> + + + Search Radius + + + false + + + + + + + + 32 + 32 + + + + + 32 + 32 + + + + + + + + + + + 24 + 24 + + + + + + + + + + + Qt::Horizontal + + + + 40 + 20 + + + + + + + + + + Qt::Vertical + + + + 20 + 40 + + + + + + + + + diff --git a/kstars/kstars.kcfg b/kstars/kstars.kcfg index 813d2546e..58ed29e6a 100644 --- a/kstars/kstars.kcfg +++ b/kstars/kstars.kcfg @@ -1,2447 +1,2485 @@ ksutils.h The screen coordinates of the Time InfoBox. QPoint(0,0) The screen coordinates of the Focus InfoBox. QPoint(600,0) The screen coordinates of the Geographic Location InfoBox. QPoint(0,600) If true, the Time InfoBox will show only its top line of data. true If true, the Focus InfoBox will show only its top line of data. true If true, the Geographic Location InfoBox will show only its top line of data. true Toggles display of all three InfoBoxes. true Toggles display of the Time InfoBox. true Toggles display of the Focus InfoBox. true Toggles display of the Geographic Location InfoBox. true Is the Time InfoBox anchored to a window edge? 0 = not anchored; 1 = anchored to right edge; 2 = anchored to bottom edge; 3 = anchored to bottom and right edges. 0 0 3 Is the Focus InfoBox anchored to a window edge? 0 = not anchored; 1 = anchored to right edge; 2 = anchored to bottom edge; 3 = anchored to bottom and right edges. 1 0 3 Is the Geographic Location InfoBox anchored to a window edge? 0 = not anchored; 1 = anchored to right edge; 2 = anchored to bottom edge; 3 = anchored to bottom and right edges. 2 0 3 Toggle display of the status bar. true Toggle display of the Horizontal coordinates of the mouse cursor in the status bar. true Toggle display of the Equatorial coordinates of the mouse cursor at the current epoch in the status bar. true Toggle display of the Equatorial coordinates of the mouse cursor at the standard epoch in the status bar. false true 1024 768 true Black Body List of the filenames of custom object catalogs. List of integers toggling display of each custom object catalog (any nonzero value indicates the objects in that catalog will be displayed). List of names for which custom catalogs are to be displayed. Names of objects entered into the find dialog are resolved using online services and stored in the database. This option also toggles the display of such resolved objects on the sky map. true 800 600 true true false Toggle display of crosshairs centered at telescope's pointed position in the KStars sky map. true Toggle display of INDI messages in the KStars statusbar. true false Show INDI messages as desktop notifications instead of dialogs. false true false false The default location of saved FITS files KSUtils::getDefaultPath("fitsDir") INDI server will attempt to bind with ports starting from this port 7624 INDI server will attempt to bind with ports ending with this port 9000 List of the aliases for filter wheel slots. PATH to indiserver binary KSUtils::getDefaultPath("indiServer") false PATH to indi drivers directory KSUtils::getDefaultPath("indiDriversDir") false 320 240 false false false false false false false false false false false The City name of the current geographic location. Greenwich The Province name of the current geographic location. This is the name of the state for locations in the U. S. The Country name of the current geographic location. United Kingdom The longitude of the current geographic location, in decimal degrees. 0.0 The latitude of the current geographic location, in decimal degrees. 51.468 -10.0 0.0 Two-letter code that determines the dates on which daylight savings time begins and ends (you can view the rules by pressing the "Explain DST Rules" button in the Geographic Location window). -- If true, focus changes will cause the sky to visibly spin to the new position. Otherwise, the display will "snap" instantly to the new position. true If true, clicking on the skymap will select the closest object and highlights it. false Type of cursor when exploring the sky map. 1 The names of the currently selected field-of-view indicators. The list of defined FOV indicator names is listed in the "Settings|FOV Symbols" menu. Telrad If true, trails attached to solar system bodies will fade into the background sky color. true The right ascension of the initial focus position of the sky map, in decimal hours. This value is volatile; it is reset whenever the program shuts down. 180.0 The declination of the initial focus position of the sky map, in decimal degrees. This value is volatile; it is reset whenever the program shuts down. 45.0 The name of the object that should be centered and tracked on startup. If no object should be centered, set to "nothing". This value is volatile; it is reset whenever the program shuts down. nothing True if the skymap should track on its initial position on startup. This value is volatile; it is reset whenever the program shuts down. false Toggle whether KStars should hide some objects while the display is moving, for smoother motion. true Toggle whether constellation boundaries are hidden while the display is in motion. true Toggle whether constellation lines are hidden while the display is in motion. false Choose sky culture. 11 Toggle whether constellation names are hidden while the display is in motion. false Toggle whether the coordinate grids are hidden while the display is in motion. true Toggle whether the Milky Way contour is hidden while the display is in motion. true Toggle whether IC objects are hidden while the display is in motion. true Toggle whether Messier objects are hidden while the display is in motion. true Toggle whether NGC objects are hidden while the display is in motion. true Toggle whether extra objects are hidden while the display is in motion. true Toggle whether solar system objects are hidden while the display is in motion. false Toggle whether faint stars are hidden while the display is in motion. true Toggle whether name labels are hidden while the display is in motion. true Toggle whether asteroids are drawn in the sky map. true Toggle whether asteroid name labels are drawn in the sky map. false true Toggle whether comets are drawn in the sky map. true Toggle whether comet comas are drawn in the sky map. true Toggle whether comet name labels are drawn in the sky map. false Toggle whether supernovae are drawn in the sky map. false Toggle whether supernova name labels are drawn in the sky map. false Set magnitude limit for supernovae to be shown on the skymap. 16 Toggle supernova alerts. true Set magnitude limit for supernovae to be alerted. 13 Toggle whether constellation boundaries are drawn in the sky map. false Toggle whether constellation boundary containing the central focus point is highlighted in the sky map. false Toggle whether constellation lines are drawn in the sky map. false Toggle whether constellation art drawn in the sky map. false Toggle whether constellation name labels are drawn in the sky map. false Toggle whether deep-sky objects are drawn in the sky map. true Toggle whether the ecliptic line is drawn in the sky map. false Toggle whether the equator line is drawn in the sky map. false Coordinate grids will automatically change according to active coordinate system. true Toggle whether the equatorial coordinate grid is drawn in the sky map. false Toggle whether the horizontal coordinate grid is drawn in the sky map. false Toggle whether the local meridian line is drawn in the sky map. false Toggle whether the region below the horizon is opaque. true Toggle whether the horizon line is drawn in the sky map. true Toggle whether flags are drawn in the sky map. true Toggle whether IC objects are drawn in the sky map. false Toggle whether NGC objects are drawn in the sky map. true Toggle whether Messier objects are drawn in the sky map. true Toggle whether Messier objects are rendered as images in the sky map. true Toggle whether extra objects are drawn in the sky map. true Toggle whether the Milky Way contour is drawn in the sky map. true Toggle whether the Milky Way contour is filled. When this option is false, the Milky Way is shown as an outline. true Meta-option to control whether all major planets (and the Sun and Moon) are drawn in the sky map. true Toggle whether major planets (and the Sun and Moon) are rendered as images in the sky map. true Toggle whether major planets (and the Sun and Moon) are labeled in the sky map. true Toggle whether the Sun is drawn in the sky map. true Toggle whether the Moon is drawn in the sky map. true Toggle whether Mercury is drawn in the sky map. true Toggle whether Venus is drawn in the sky map. true Toggle whether Mars is drawn in the sky map. true Toggle whether Jupiter is drawn in the sky map. true Toggle whether Saturn is drawn in the sky map. true Toggle whether Uranus is drawn in the sky map. true Toggle whether Neptune is drawn in the sky map. true Toggle whether Pluto is drawn in the sky map. true Toggle whether stars are drawn in the sky map. true Toggle whether star magnitude (brightness) labels are shown in the sky map. false Toggle whether star name labels are shown in the sky map. true Toggle whether deep-sky object magnitude (brightness) labels are shown in the sky map. false Toggle whether deep-sky object name labels are shown in the sky map. false The timescale above which slewing mode is forced on at all times. 60 The background fill mode for the on-screen information boxes: 0="no BG"; 1="semi-transparent BG"; 2="opaque BG" 1 Algorithm for the mapping projection. 0 Use official IAU abbreviations for constellation names. false Use Latin constellation names. false Use localized constellation names (if localized names are not available, default to Latin names). true Display the sky with horizontal coordinates (when false, equatorial coordinates will be used). true Toggle whether a centered object automatically gets a name label attached. true Toggle whether a centered solar system object automatically gets a trail attached, as long as it remains centered. true Toggle whether the object under the mouse cursor gets a transient name label. true Toggle whether object positions are corrected for the effects of atmospheric refraction (only applies when horizontal coordinates are used). true Toggle whether corrections due to bending of light around the sun are taken into account false Toggle whether the sky is rendered using antialiasing. Lines and shapes are smoother with antialiasing, but rendering the screen will take more time. true The zoom level, measured in pixels per radian. 250. 250. 5000000. When zooming in or out, change zoom speed factor by this multiplier. 0.2 0.01 1.0 The faint magnitude limit for drawing asteroids. 15.0 The maximum magnitude (visibility) to filter the asteroid data download from JPL. 12.000 Controls the relative number of asteroid name labels drawn in the map. 4.0 The faint magnitude limit for drawing deep-sky objects, when fully zoomed in. 16.0 The faint magnitude limit for drawing deep-sky objects, when fully zoomed out. 5.0 When enabled, objects whose magnitudes are unknown, or not available to KStars, are drawn irrespective of the faint limits set. true Sets the density of stars in the field of view 5 The faint magnitude limit for drawing stars, when the map is in motion (only applicable if faint stars are set to be hidden while the map is in motion). 5.0 The relative density for drawing star name and magnitude labels. 2.0 The relative density for drawing deep-sky object name and magnitude labels. 5.0 If true, long names (common names) for deep-sky objects are shown in the labels. false The maximum solar distance for drawing comets. 3.0 Use experimental OpenGL backend (deprecated). false The state of the clock (running or not) true Objects in the observing list will be highlighted with a symbol in the map. true Objects in the observing list will be highlighted with a colored name label in the map. false The observing list will prefer DSS imagery while downloading imagery. true The observing list will prefer SDSS imagery while downloading imagery. false Check this if you use a large Dobsonian telescope. Sorting by percentage current altitude is an easy way of determining what objects are well-placed for observation. However, when using a large Dobsonian telescope, objects close to the zenith are hard to observe. Since tracking there corresponds to a rotation in azimuth, it is both counterintuitive and requires the observer to frequently move the ladder. The region around the zenith where this is particularly frustrating is called the Dobsonian hole. This checkbox makes the observing list consider objects present in the hole as unfit for observation. false This specifies the angular radius of the Dobsonian hole, i.e. the region where a large Dobsonian telescope cannot be pointed easily. 15.00 40.00 The name of the color scheme moonless-night.colors The method for rendering stars: 0="realistic colors"; 1="solid red"; 2="solid black"; 3="solid white"; 4="solid real colors" 0 4 The color saturation level of stars (only applicable when using "realistic colors" mode). 6 10 The color for the angular-distance measurement ruler. #FFF The background color of the on-screen information boxes. #000 The text color for the on-screen information boxes, when activated by a mouse click. #F00 The normal text color of the on-screen information boxes. #FFF The color for the constellation boundary lines. #222 The color for the constellation boundary lines. #222 The color for the constellation figure lines. #555 The color for the constellation names. #AA7 The color for the cardinal compass point labels. #002 The color for the ecliptic line. #663 The color for the equator line. #FFF The color for the equatorial coordinate grid lines. #456 The color for the horizontal coordinate grid lines. #5A3 The color for objects which have extra URL links available. #A00 The color for the horizon line and opaque ground. #5A3 The color for the local meridian line. #0059b3 The color for Messier object symbols. #0F0 The color for NGC object symbols. #066 The color for IC object symbols. #439 The color for the Milky Way contour. #123 The color for star name labels. #7AA The color for deep-sky object name labels. #7AA The color for solar system object labels. #439 The color for solar system object trails. #963 The color for the sky background. #002 The color for the artificial horizon region. #C82828 The color for telescope target symbols. #8B8 Color of visible satellites. #00FF00 Color of invisible satellites. #FF0000 Color of satellites labels. #640000 Color of supernova #FFA500 The color for user-added object labels. #439 The color for RA Guide Error bar in Ekos guide module. #00FF00 The color for DEC Guide Error bar in Ekos guide module. #00A5FF The color for solver FOV box in Ekos alignment module. #FFFF00 false Xplanet binary path KSUtils::getDefaultPath("XplanetPath") Option to use a FIFO file instead of saving to the hard disk true How long to wait for XPlanet before giving up in milliseconds 1000 How long to pause between frames in the XPlanet Animation 100 Width of xplanet window 640 Height of xplanet window 480 If true, display a label in the upper right corner. false Show local time. true Show GMT instead of local time. false Specify the text of the first line of the label. By default, it says something like "Looking at Earth". Any instances of %t will be replaced by the target name, and any instances of %o will be replaced by the origin name. Specify the point size. 12 Set the color for the label. #F00 Specify the format for the date/time label. This format string is passed to strftime(3). The default is "%c %Z", which shows the date, time, and time zone in the locale’s appropriate date and time representation. %c %Z false true false false Draw a glare around the sun with a radius of the specified value larger than the Sun. The default value is 28. 28 Place the observer above a random latitude and longitude false Place the observer above the specified longitude and latitude true Render the target body as seen from above the specified latitude (in degrees). The default value is 0. 0 Place the observer above the specified longitude (in degrees). Longitude is positive going east, negative going west (for the earth and moon), so for example Los Angeles is at -118 or 242. The default value is 0. 0 The default is no projection. Multiple bodies will not be shown if this option is specified, although shadows will still be drawn. 0 Use a file as the background image, with the planet to be superimposed upon it. This option is only meaningful with the -projection option. A color may also be supplied. false Use a file as the background image. false The path of the background image. Use a color as the background. true The color of the background. #000 A star of the specified magnitude will have a pixel brightness of 1. The default value is 10. Stars will be drawn more brightly if this number is larger. 10 If checked, use an arc file to be plotted against the background stars. false Specify an arc file to be plotted against the background stars. If checked, use a config file. false Use the specified configuration file. If checked, use kstars's FOV. false If checked, use the specified marker file. false Specify a file containing user-defined marker data to display against the background stars. If checked, write coordinates of the bounding box for each marker in a file. false Write coordinates of the bounding box for each marker to this file. If checked, use star map file to draw the background stars. false Star map file path This option is only used when creating JPEG images. The quality can range from 0 to 100. The default value is 80. 80 Toggle whether satellite tracks are drawn in the sky map. false Toggle whether satellite tracks are drawn in the sky map. false If selected, satellites will be draw like stars, otherwise, draw satellites as small colored square. false Toggle whether satellite labels are drawn in the sky map. false List of selected satellites. Checking this option causes recomputation of current equatorial coordinates from catalog coordinates (i.e. application of precession, nutation and aberration corrections) for every redraw of the map. This makes processing slower when there are many stars to handle, but is more likely to be bug free. There are known bugs in the rendering of stars when this recomputation is avoided. false The default size for DSS images downloaded from the Internet. 15.0 To include parts of the star field, we add some extra padding around DSS images of deep-sky objects. This option configures the total (both sides) padding added to either dimension of the field. 10.0 Checking this option causes KStars to generate verbose debug information for diagnostic purposes. This may cause slowdown of KStars. false Checking this option causes KStars to generate regular debug information. true Checking this option causes KStars to stop generating ANY debug information. false Checking this option causes KStars log debug messages to the default output used by the platform (e.g. Standard Error). true Checking this option causes KStars log debug messages to a log file as specified. false Log FITS Data activity. false Log INDI devices activity. false Log Ekos Capture Module activity. false Log Ekos Focus Module activity. false Log Ekos Guide Module activity. false Log Ekos Alignment Module activity. false Log Ekos Mount Module activity. false Log Ekos Observatory Module activity. false true Display all captured FITS images in a single tab instead of multiple tabs per image. true Display all captured FITS images in a single FITS Viewer window. By default each camera create its own FITS Viewer instance false Display all opened FITS images in a single FITS Viewer window. true Bring the FITSViewer window to the foreground when receiving a new image. true false !KSUtils::isHardwareLimited() false !KSUtils::isHardwareLimited() !KSUtils::isHardwareLimited() KSUtils::isHardwareLimited() 4 false false 40.0 0 600 600 true false true true true false Simulators false true false true 1 Minimum telescope altitude limit. If the telescope is below this limit, it will be commanded to stop. 0 Maximum telescope altitude limit. If the telescope is above this limit, it will be commanded to stop. 90.0 false If the target hour angle exceeds this value, Ekos will command a meridian flip and if successful it will resume guiding and capture operations. false true false false false 3:00 AM false 1 0 If guide deviation exceeds this limit, the exposure will be automatically aborted and only resumed when the deviation is within this limit. 2 If HFR deviation exceeds this limit, the autofocus routine will be automatically started. 0.5 false false false Sets the time interval before forced autofocus attempts during a capture sequence. 60 false If set, Ekos will capture a few flat images to determine the optimal exposure time to achieve the desired ADU value. 0 Maximum difference between measured and target ADU values to deem the value as acceptable. 1000 0 0 0 0 0.1 0 false false 2.5 true false 1 30 true !KSUtils::isHardwareLimited() !KSUtils::isHardwareLimited() true 0 KSUtils::getDefaultPath("fitsDir") 60 false false false Step size of the absolute focuser. The step size TICKS should be adjusted so that when the focuser moves TICKS steps, the difference in HFR is more than 0.1 pixels. Lower the value when you are close to optimal focus. 100 Wait for this many seconds after moving the focuser before capturing the next image during AutoFocus. 0 Wait for this many seconds after resuming guide. 0 The tolerance specifies the percentage difference between the current focusing position and the minimum obtained during the focusing run. Adjustment of this value is necessary to prevent the focusing algorithm from oscillating back and forth. 1 Set the maximum travel distance of an absolute focuser. 10000 Specifies gain value of CCD when performing focusing if supported by camera. 0 Set box size to select a focus star. 64 Set horizontal binning of CCD camera while in focus mode. 1 Set vertical binning of CCD camera while in focus mode. 1 true false During full field focusing, stars which are inside this percentage of the frame are filtered out of HFR calculation (default 0%). Detection algorithms may also have an inherent filter. 0.0 During full field focusing, stars which are outside this percentage of the frame are filtered out of HFR calculation (default 100%). Detection algorithms may also have an inherent filter. 100.0 false true false 0 150 0 0 1 Specifies exposure value of CCD in seconds when performing plate solving. 1 Set binning index of CCD camera while in alignment mode. Default values 0-3 corresponding to 1x1 to 4x4 binning. 4 is max binning. 4 Use rotator when performing load and slew. false Threshold between measured and FITS position angles in arcminutes to consider the load and slew operation successful. 30 - + Solver type (0 ASTAP, 1 astrometry.net). + 1 + + + 0 0 1 true false false 30 0 false 1500 false true true true true 1 true 2 true true true 30 false Path to astrometry.net solver location. KSUtils::getDefaultPath("AstrometrySolverBinary") false Path to astrometry.net wcsinfo location. KSUtils::getDefaultPath("AstrometryWCSInfo") false Path to astrometry.net file location. KSUtils::getDefaultPath("AstrometryConfFile") true true Folder in which the desired python executable or link to be used for astrometry.net resides. /usr/local/opt/python/libexec/bin Key to access astrometry.net online web services. You must register with astrometry.net to obtain a key. iczikaqstszeptgs http://nova.astrometry.net true 180 -1 true 1.0 0 0 localhost 4400 localhost 5656 0 1000 2 false 1 false false 3 60 10 true false false false 2 1 0 1 45 10 500 false false false 2 true true true true true true 133.33 133.33 0 0 0 0 5000 5000 100 100 0.5 2 true true false false Log Ekos Scheduler Module activity. false Sort scheduler jobs by priority and altitude. true true false false false false true false 2 true 5 30 3 0 0 0 0 0 0 0 0 1 0 false 7624 8624 300 1000 None false false false Toggle whether the HIPS sources are drawn in the sky map. false true true false false true 600 true true true 30 true true true + + + + KSUtils::getDefaultPath("ASTAP") + + + + false + + + + 0 + + + + true + + + + 30 + + + + false + + + + 0.005 + + + + true + + diff --git a/kstars/org.kde.kstars.Ekos.Align.xml b/kstars/org.kde.kstars.Ekos.Align.xml index 20239b4de..ac2e5e9f4 100644 --- a/kstars/org.kde.kstars.Ekos.Align.xml +++ b/kstars/org.kde.kstars.Ekos.Align.xml @@ -1,78 +1,82 @@ + + + +