diff --git a/3rdparty/README.md b/3rdparty/README.md index b747d7b77b..b0acc80f6c 100644 --- a/3rdparty/README.md +++ b/3rdparty/README.md @@ -1,289 +1,289 @@ # CMake external projects to build krita's dependencies on Linux, Windows or OSX If you need to build Krita's dependencies for the following reasons: * you develop on Windows and aren't using build-tools/windows/build.cmd or KDE's craft * you develop on OSX and aren't using the scripts in krita/packaging/osx or Homebrew * you want to build a generic, distro-agnostic version of Krita for Linux and aren't using the scripts in packaging/linux/appimage * you develop on Linux, but some dependencies aren't available for your distribution and aren't using the scripts in packaging/linux/appimage and you know what you're doing, you can use the following guide to build the dependencies that Krita needs. Using the scripts mentioned above is strongly preferred because that's what the Krita team uses to build the binaries on the binary factory (https://binary-factory.kde.org/). If you develop on Linux and your distribution has all dependencies available, YOU DO NOT NEED THIS GUIDE AND YOU SHOULD STOP READING NOW Otherwise you risk major confusion. ## Prerequisites Note: on all operating systems the entire procedure is done in a terminal window. 1. git: https://git-scm.com/downloads. Make sure git is in your path 2. CMake 3.3.2 or later: https://cmake.org/download/. Make sure cmake is in your path. * CMake 3.9 does not build Krita properly at the moment, please use 3.8 or 3.10 instead. 3. Make sure you have a compiler: * Linux: gcc, minimum version 4.8 * OSX: clang, you need to install xcode for this * Windows: mingw-w64 7.3 (by mingw-builds): https://files.kde.org/krita/build/x86_64-7.3.0-release-posix-seh-rt_v5-rev0.7z * For threading, select posix. * For exceptions, select seh (64-bit) or dwarf (32-bit). * Install mingw to something like C:\mingw; the full path must not contain any spaces. * Make sure mingw's bin folder is in your path. It might be a good idea to create a batch file which sets the path and start cmd. * MSVC is *not* supported at the moment. -4. On Windows, you will also need a release of Python 3.9: https://www.python.org. Make sure to have that version of python.exe in your path. This version of Python will be used for two things: to configure Qt and to build the Python scripting module. Make sure that this version of Python comes first in your path. Do not set PYTHONHOME or PYTHONPATH. +4. On Windows, you will also need a release of Python 3.8 (not 3.7, probably not 3.9): https://www.python.org. Make sure to have that version of python.exe in your path. This version of Python will be used for two things: to configure Qt and to build the Python scripting module. Make sure that this version of Python comes first in your path. Do not set PYTHONHOME or PYTHONPATH. * Make sure that your Python will have the correct architecture for the version you are trying to build. If building for 32-bit target, you need the 32-bit release of Python. 5. On Windows, if you want to compile Qt with ANGLE support, you will need to install Windows 10 SDK and have 2 environment variables set: * `WindowsSdkDir` (typically set to `C:\Program Files (x86)\Windows Kits\10`) * `WindowsSdkVerBinPath` (typically set to `C:\Program Files (x86)\Windows Kits\10\bin\10.0.18362.0`) where 10.0.18362.0 is the version of the Window 10 SDK. * Example: set "WindowsSdkDir=%ProgramFiles(x86)%\Windows Kits\10" set "WindowsSdkVerBinPath=%ProgramFiles(x86)%\Windows Kits\10\bin\10.0.18362.0" THIS IS ALSO NEEDED IF YOU USE THE build.cmd script. ## Setup your environment ## Prepare your directory layout 1. Make a toplevel build directory, say $HOME/dev or c:\dev. We'll refer to this directory as BUILDROOT. You can use a variable for this, on WINDOWS %BUILDROOT%, on OSX and Linux $BUILDROOT. You will have to replace a bare BUILDROOT with $BUILDROOT or %BUILDROOT% whenever you copy and paste a command, depending on your operating system. 2. Checkout krita in BUILDROOT ``` cd BUILDROOT git clone git://anongit.kde.org/krita.git ``` 3. Create the build directory ``` mkdir BUILDROOT/b ``` 4. Create the downloads directory ``` mkdir BUILDROOT/d ``` 5. Create the install directory ``` mkdir BUILDROOT/i ``` ## Prepare the externals build 1. Enter the BUILDROOT/b directory 2. Run cmake: * Linux: ``` export PATH=$BUILDROOT/i/bin:$PATH export PYTHONHOME=$BUILDROOT/i (only if you want to build your own python) cmake ../krita/3rdparty \ -DINSTALL_ROOT=$BUILDROOT/i \ -DEXTERNALS_DOWNLOAD_DIR=$BUILDROOT/d \ -DCMAKE_INSTALL_PREFIX=BUILDROOT/i ``` * OSX: ``` export PATH=$BUILDROOT/i/bin:$PATH export PYTHONHOME=$BUILDROOT/i (only if you want to build your own python) cmake ../krita/3rdparty/ \ -DCMAKE_INSTALL_PREFIX=$BUILDROOT/i \ -DEXTERNALS_DOWNLOAD_DIR=$BUILDROOT/d \ -DINSTALL_ROOT=$BUILDROOT/i ``` * Windows 32-bit / 64-bit: Note that the cmake command needs to point to your BUILDROOT like /dev/d, not c:\dev\d. ``` set PATH=%BUILDROOT%\i\bin\;%BUILDROOT%\i\lib;%PATH% cmake ..\krita\3rdparty -DEXTERNALS_DOWNLOAD_DIR=/dev/d -DINSTALL_ROOT=/dev/i -G "MinGW Makefiles" ``` - If you want to build Qt and some other dependencies with parallel jobs, add `-DSUBMAKE_JOBS=` to this cmake command where is the number of jobs to run (if your PC has 4 CPU cores, you might want to set it to 5). For other jobs, you might need to manually add a -- -j N option, where N is the number of jobs. - If you don't have Windows 10 SDK and don't want to build Qt with ANGLE, add `-DQT_ENABLE_DYNAMIC_OPENGL=OFF` to the CMake command line args. 3. Build the packages: On Windows: ``` cmake --build . --config RelWithDebInfo --target ext_patch cmake --build . --config RelWithDebInfo --target ext_png2ico ``` On OSX and Windows: ``` cmake --build . --config RelWithDebInfo --target ext_gettext cmake --build . --config RelWithDebInfo --target ext_openssl ``` On all operating systems: ``` cmake --build . --config RelWithDebInfo --target ext_qt cmake --build . --config RelWithDebInfo --target ext_zlib cmake --build . --config RelWithDebInfo --target ext_boost Note about boost: check if the headers are installed into i/include/boost, but not into i/include/boost-1.61/boost cmake --build . --config RelWithDebInfo --target ext_eigen3 cmake --build . --config RelWithDebInfo --target ext_exiv2 cmake --build . --config RelWithDebInfo --target ext_fftw3 cmake --build . --config RelWithDebInfo --target ext_ilmbase cmake --build . --config RelWithDebInfo --target ext_jpeg cmake --build . --config RelWithDebInfo --target ext_lcms2 cmake --build . --config RelWithDebInfo --target ext_ocio cmake --build . --config RelWithDebInfo --target ext_openexr ``` OSX Note: You need to first build openexr; that will fail; then you need to set the rpath for the two utilities correctly, then try to build openexr again. ``` install_name_tool -add_rpath $BUILD_ROOT/i/lib $BUILD_ROOT/b/ext_openexr/ext_openexr-prefix/src/ext_openexr-build/IlmImf/./b44ExpLogTable install_name_tool -add_rpath $BUILD_ROOT/i/lib $BUILD_ROOT/b/ext_openexr/ext_openexr-prefix/src/ext_openexr-build/IlmImf/./dwaLookups ``` On All operating systems ``` cmake --build . --config RelWithDebInfo --target ext_png cmake --build . --config RelWithDebInfo --target ext_tiff cmake --build . --config RelWithDebInfo --target ext_gsl cmake --build . --config RelWithDebInfo --target ext_vc cmake --build . --config RelWithDebInfo --target ext_libraw cmake --build . --config RelWithDebInfo --target ext_giflib cmake --build . --config RelWithDebInfo --target ext_openjpeg cmake --build . --config RelWithDebInfo --target ext_quazip ``` On Linux (if you want to build your own SIP and PyQt instead of the system one) ``` cmake --build . --config RelWithDebInfo --target ext_sip cmake --build . --config RelWithDebInfo --target ext_pyqt ``` On Windows ``` cmake --build . --config RelWithDebInfo --target ext_freetype cmake --build . --config RelWithDebInfo --target ext_poppler ``` On Linux ``` cmake --build . --config RelWithDebInfo --target ext_kcrash ``` On Windows (if you want to include DrMingw for dumping backtrace on crash) ``` cmake --build . --config RelWithDebInfo --target ext_drmingw ``` On Windows (if you want to include Python scripting) ``` cmake --build . --config RelWithDebInfo --target ext_python cmake --build . --config RelWithDebInfo --target ext_sip cmake --build . --config RelWithDebInfo --target ext_pyqt ``` Troubleshooting: if you have problems with 'install' step of ext_sip or ext_pyqt, make sure you install it in single thread only (`mingw32-make -j1 install`). Otherwise, a race condition may happen in the post-install script and metadata generation will be started before actual libraries are installed. On Windows and Linux (if you want to include gmic-qt) ``` cmake --build . --config RelWithDebInfo --target ext_gmic ``` Linux Note: poppler should be buildable on Linux as well with a home-built freetype and fontconfig, but I don't know how to make fontconfig find freetype, and on Linux, fontconfig is needed for poppler. Poppler is needed for PDF import. OSX Note: In order to build fontconfig on macOS, you need to have pkg-config installed. You probably need homebrew for that... See http://macappstore.org/pkg-config/ . archives from: files.kde.org/krita/build/dependencies: On Windows and OSX ``` cmake --build . --config RelWithDebInfo --target ext_kwindowsystem ``` ## Build Krita 1. Make a krita build directory: mkdir BUILDROOT/build 2. Enter the BUILDROOT/build 3. Configure the build: On Windows ``` cmake ..\krita -G "MinGW Makefiles" -DBoost_DEBUG=OFF -DBOOST_INCLUDEDIR=c:\dev\i\include -DBOOST_DEBUG=ON -DBOOST_ROOT=c:\dev\i -DBOOST_LIBRARYDIR=c:\dev\i\lib -DCMAKE_INSTALL_PREFIX=c:\dev\i -DCMAKE_PREFIX_PATH=c:\dev\i -DCMAKE_BUILD_TYPE=RelWithDebInfo -DBUILD_TESTING=OFF -DKDE4_BUILD_TESTS=OFF -DHAVE_MEMORY_LEAK_TRACKER=OFF -Wno-dev -DDEFINE_NO_DEPRECATED=1 ``` On Linux ``` cmake ../krita -DCMAKE_INSTALL_PREFIX=BUILDROOT/i -DDEFINE_NO_DEPRECATED=1 -DBUILD_TESTING=OFF -DKDE4_BUILD_TESTS=OFF -DCMAKE_BUILD_TYPE=RelWithDebInfo # Troubleshooting: if you built your own SIP and CMake fails to find it, please set # the following environment variable to the SIP installation directory: export PYTHONPATH=$BUILDROOT/i/sip/ # If you also have KIO installed in the system, don't forget to disable it by bassing to cmake: # cmake -DCMAKE_DISABLE_FIND_PACKAGE_KF5KIO=true . ``` On OSX ``` cmake ../krita -DCMAKE_INSTALL_PREFIX=$BUILDROOT/i -DDEFINE_NO_DEPRECATED=1 -DBUILD_TESTING=OFF -DKDE4_BUILD_TESTS=OFF -DBUNDLE_INSTALL_DIR=$BUILDROOT/i/bin -DCMAKE_BUILD_TYPE=RelWithDebInfo ``` 4. Run the build: On Linux and OSX ``` make make install ``` On Windows (replace 4 with the number of jobs to run in parallel) ``` cmake --build . --target install -- -j4 ``` 6. Run krita: On Linux ``` BUILDROOT/i/bin/krita ``` On Windows ``` BUILDROOT\i\bin\krita.exe ``` On OSX ``` BUILDROOT/i/bin/krita.app/Contents/MacOS/krita ``` ## Packaging a Windows Build If you want to create a stripped down version of Krita to distribute, after building everything just run the packaging/windows/package-complete.cmd script. That script will copy the necessary files into the specified folder and leave out developer related files. After the script runs there will be two new ZIP files that contain a small portable version of Krita and a separate portable debug version. diff --git a/3rdparty/ext_frameworks/CMakeLists.txt b/3rdparty/ext_frameworks/CMakeLists.txt index e56639ff72..2de72b7378 100644 --- a/3rdparty/ext_frameworks/CMakeLists.txt +++ b/3rdparty/ext_frameworks/CMakeLists.txt @@ -1,226 +1,243 @@ SET(EXTPREFIX_frameworks "${EXTPREFIX}" ) # # All needed frameworks: # # Config # WidgetsAddons # Completion # CoreAddons # GuiAddons # I18n # ItemModels # ItemViews # WindowSystem # kimageformats # On Linux: # KCrash ExternalProject_Add( ext_extra_cmake_modules DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/extra-cmake-modules-5.64.0.zip URL_MD5 e8fa4bba6a534feb9d9e39db036923da PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/ecm_install_to_share.diff INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" ) ExternalProject_Add( ext_kconfig DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kconfig-5.64.0.zip URL_MD5 52858f7fdcd17d0c5680acf96dcaae9a PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/kconfig.diff INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false -DKCONFIG_USE_DBUS=off UPDATE_COMMAND "" DEPENDS ext_extra_cmake_modules ) +ExternalProject_Add( + ext_karchive + DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} + URL https://download.kde.org/stable/frameworks/5.64/karchive-5.64.0.zip + URL_MD5 26c7f89bfde97bc85f887f81a2d0f648 + PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/karchive.diff + INSTALL_DIR ${EXTPREFIX_frameworks} + CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} + -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} + ${GLOBAL_PROFILE} + -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} + -DBUILD_TESTING=false + UPDATE_COMMAND "" + DEPENDS ext_extra_cmake_modules +) + + ExternalProject_Add( ext_kwidgetsaddons DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kwidgetsaddons-5.64.0.zip URL_MD5 d6578f8b5b4bf19fddb8c16918ec0117 INSTALL_DIR ${EXTPREFIX_frameworks} # PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/kwidgetsaddons.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kconfig ) ExternalProject_Add( ext_kcompletion DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kcompletion-5.64.0.zip URL_MD5 21fef280c2580da83df289707326d42a INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kwidgetsaddons ) ExternalProject_Add( ext_kcoreaddons DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kcoreaddons-5.64.0.zip URL_MD5 670a74cda110da89d1a7b0fd832fca42 INSTALL_DIR ${EXTPREFIX_frameworks} PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/desktoptojson.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kcompletion ) ExternalProject_Add( ext_kguiaddons DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kguiaddons-5.64.0.zip URL_MD5 565dcb39e812463100dddaf3f02bd2a0 INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kcoreaddons ) if(APPLE) ExternalProject_Add( ext_ki18n DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/ki18n-5.64.0.zip URL_MD5 75a86675bf2b352b53cbcaece956b486 INSTALL_DIR ${EXTPREFIX_frameworks} PATCH_COMMAND COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/ki18n-appdatalocation.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kguiaddons ext_gettext ) else() ExternalProject_Add( ext_ki18n DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/ki18n-5.64.0.zip URL_MD5 75a86675bf2b352b53cbcaece956b486 INSTALL_DIR ${EXTPREFIX_frameworks} PATCH_COMMAND COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/ki18n-appdatalocation.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kguiaddons ) endif() ExternalProject_Add( ext_kitemmodels DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kitemmodels-5.64.0.zip URL_MD5 e561031cafe7af08de3c62f01fa154b2 INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_ki18n ) ExternalProject_Add( ext_kitemviews DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kitemviews-5.64.0.zip URL_MD5 bbd20e563e3f3cbc80252ba89d27962c INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kitemmodels ) ExternalProject_Add( ext_kimageformats DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kimageformats-5.64.0.zip URL_MD5 744090cf90ddde84f51dcabd167dd607 INSTALL_DIR ${EXTPREFIX_frameworks} PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/kimageformats.diff COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/disable_exr.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kitemviews ) ExternalProject_Add( ext_kwindowsystem DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kwindowsystem-5.64.0.zip URL_MD5 4e2819edb9d029ff33791d691637065a INSTALL_DIR ${EXTPREFIX_frameworks} PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/kwindowsystem-x11.diff CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kimageformats ) ExternalProject_Add( ext_kcrash DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL https://download.kde.org/stable/frameworks/5.64/kcrash-5.64.0.zip URL_MD5 2d4d9c074c2e1d19804618d3f291a568 INSTALL_DIR ${EXTPREFIX_frameworks} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${EXTPREFIX_frameworks} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DCMAKE_SYSTEM_PREFIX_PATH=${EXTPREFIX} -DBUILD_TESTING=false UPDATE_COMMAND "" DEPENDS ext_kwindowsystem ) diff --git a/3rdparty/ext_lcms2/CMakeLists.txt b/3rdparty/ext_lcms2/CMakeLists.txt index 1863b373d5..53bbedd5a5 100644 --- a/3rdparty/ext_lcms2/CMakeLists.txt +++ b/3rdparty/ext_lcms2/CMakeLists.txt @@ -1,39 +1,39 @@ SET(PREFIX_ext_lcms2 "${EXTPREFIX}" ) if (MINGW) ExternalProject_Add( ext_lcms2 DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL http://files.kde.org/krita/build/dependencies/lcms2-2.10.tar.gz URL_MD5 c5f915d681325e0767e40187799f23b1 PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/lcms2-10.diff INSTALL_DIR ${PREFIX_ext_lcms2} - CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${PREFIX_ext_lcms2} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DBUILD_TESTS=FALSE -DBUILD_UTILS=FALSE -DBUILD_STATIC=FALSE + CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${PREFIX_ext_lcms2} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DBUILD_TESTS=FALSE -DBUILD_UTILS=FALSE -DBUILD_STATIC=FALSE -DBUILD_PLUGINS=FALSE UPDATE_COMMAND "" DEPENDS ext_patch ) elseif (ANDROID) ExternalProject_Add( ext_lcms2 DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL http://files.kde.org/krita/build/dependencies/lcms2-2.10.tar.gz URL_MD5 c5f915d681325e0767e40187799f23b1 PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/lcms2-10.diff INSTALL_DIR ${PREFIX_ext_lcms2} CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${PREFIX_ext_lcms2} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DBUILD_TESTS=FALSE -DBUILD_UTILS=FALSE -DBUILD_STATIC=FALSE -DBUILD_PLUGINS=FALSE UPDATE_COMMAND "" ) else () ExternalProject_Add( ext_lcms2 DOWNLOAD_DIR ${EXTERNALS_DOWNLOAD_DIR} URL http://files.kde.org/krita/build/dependencies/lcms2-2.10.tar.gz URL_MD5 c5f915d681325e0767e40187799f23b1 PATCH_COMMAND ${PATCH_COMMAND} -p1 -i ${CMAKE_CURRENT_SOURCE_DIR}/lcms2-10.diff INSTALL_DIR ${PREFIX_ext_lcms2} - CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${PREFIX_ext_lcms2} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DBUILD_TESTS=FALSE -DBUILD_UTILS=FALSE -DBUILD_STATIC=FALSE + CMAKE_ARGS -DCMAKE_INSTALL_PREFIX=${PREFIX_ext_lcms2} -DCMAKE_BUILD_TYPE=${GLOBAL_BUILD_TYPE} ${GLOBAL_PROFILE} -DBUILD_TESTS=FALSE -DBUILD_UTILS=FALSE -DBUILD_STATIC=FALSE -DBUILD_PLUGINS=FALSE UPDATE_COMMAND "" ) endif () diff --git a/libs/image/kis_convolution_painter.h b/libs/image/kis_convolution_painter.h index 2db38414a7..0911bec934 100644 --- a/libs/image/kis_convolution_painter.h +++ b/libs/image/kis_convolution_painter.h @@ -1,104 +1,109 @@ /* * Copyright (c) 2005 Cyrille Berger * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #ifndef KIS_CONVOLUTION_PAINTER_H_ #define KIS_CONVOLUTION_PAINTER_H_ #include "kis_types.h" #include "kis_painter.h" #include "kis_image.h" #include "kritaimage_export.h" template class KisConvolutionWorker; enum KisConvolutionBorderOp { BORDER_IGNORE = 0, // read the pixels outside of the application rect BORDER_REPEAT = 1 // Use the border for the missing pixels }; /** * @brief The KisConvolutionPainter class applies a convolution kernel to a paint device. * * * Note: https://bugs.kde.org/show_bug.cgi?id=220310 shows that there's something here * that we need to fix... */ class KRITAIMAGE_EXPORT KisConvolutionPainter : public KisPainter { public: KisConvolutionPainter(); KisConvolutionPainter(KisPaintDeviceSP device); KisConvolutionPainter(KisPaintDeviceSP device, KisSelectionSP selection); enum TestingEnginePreference { NONE, SPATIAL, FFTW }; KisConvolutionPainter(KisPaintDeviceSP device, TestingEnginePreference enginePreference); /** * Convolve all channels in src using the specified kernel; there is only one kernel for all - * channels possible. By default the border pixels are not convolved, that is, convolving - * starts with at (x + kernel.width/2, y + kernel.height/2) and stops at w - (kernel.width/2) - * and h - (kernel.height/2) + * channels possible. + * + * WARNING: The painter will read **more** pixels than you pass in \p areaSize. + * The actual processing area will be: + * QRect(x - kernel.width() / 2, + * y - kernel.height() / 2, + * w + 2 * (kernel.width() / 2), + * h + 2 * (kernel.height() / 2)) * * The border op decides what to do with pixels too close to the edge of the rect as defined above. * * The channels flag determines which set out of color channels, alpha channels. * channels we convolve. * * Note that we do not (currently) support different kernels for * different channels _or_ channel types. * * If you want to convolve a subset of the channels in a pixel, * set those channels with KisPainter::setChannelFlags(); */ void applyMatrix(const KisConvolutionKernelSP kernel, const KisPaintDeviceSP src, QPoint srcPos, QPoint dstPos, QSize areaSize, KisConvolutionBorderOp borderOp = BORDER_REPEAT); /** * The caller should ask if the painter needs an explicit transaction iff * the source and destination devices coincide. Otherwise, the transaction is * just not needed. */ bool needsTransaction(const KisConvolutionKernelSP kernel) const; static bool supportsFFTW(); protected: friend class KisConvolutionPainterTest; private: template KisConvolutionWorker* createWorker(const KisConvolutionKernelSP kernel, KisPainter *painter, KoUpdater *progress); bool useFFTImplementation(const KisConvolutionKernelSP kernel) const; private: TestingEnginePreference m_enginePreference; }; #endif //KIS_CONVOLUTION_PAINTER_H_ diff --git a/libs/image/kis_edge_detection_kernel.cpp b/libs/image/kis_edge_detection_kernel.cpp index 2596140852..15ed4fc938 100644 --- a/libs/image/kis_edge_detection_kernel.cpp +++ b/libs/image/kis_edge_detection_kernel.cpp @@ -1,428 +1,414 @@ /* * Copyright (c) 2017 Wolthera van Hövell tot Westerflier * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "kis_edge_detection_kernel.h" #include "kis_global.h" #include "kis_convolution_kernel.h" #include #include #include #include #include #include KisEdgeDetectionKernel::KisEdgeDetectionKernel() { } /* * This code is very similar to the gaussian kernel code, except unlike the gaussian code, * edge-detection kernels DO use the diagonals. * Except for the simple mode. We implement the simple mode because it is an analog to * the old sobel filter. */ Eigen::Matrix KisEdgeDetectionKernel::createHorizontalMatrix(qreal radius, FilterType type, bool reverse) { int kernelSize = kernelSizeFromRadius(radius); Eigen::Matrix matrix(kernelSize, kernelSize); KIS_ASSERT_RECOVER_NOOP(kernelSize & 0x1); const int center = kernelSize / 2; if (type==Prewit) { for (int x = 0; x < kernelSize; x++) { for (int y=0; y KisEdgeDetectionKernel::createVerticalMatrix(qreal radius, FilterType type, bool reverse) { int kernelSize = kernelSizeFromRadius(radius); Eigen::Matrix matrix(kernelSize, kernelSize); KIS_ASSERT_RECOVER_NOOP(kernelSize & 0x1); const int center = kernelSize / 2; if (type==Prewit) { for (int y = 0; y < kernelSize; y++) { for (int x=0; x matrix = createHorizontalMatrix(radius, type, reverse); if (denormalize) { return KisConvolutionKernel::fromMatrix(matrix, 0.5, 1); } else { return KisConvolutionKernel::fromMatrix(matrix, 0, matrix.sum()); } } KisConvolutionKernelSP KisEdgeDetectionKernel::createVerticalKernel(qreal radius, KisEdgeDetectionKernel::FilterType type, bool denormalize, bool reverse) { Eigen::Matrix matrix = createVerticalMatrix(radius, type, reverse); if (denormalize) { return KisConvolutionKernel::fromMatrix(matrix, 0.5, 1); } else { return KisConvolutionKernel::fromMatrix(matrix, 0, matrix.sum()); } } int KisEdgeDetectionKernel::kernelSizeFromRadius(qreal radius) { return qMax((int)(2 * ceil(sigmaFromRadius(radius)) + 1), 3); } qreal KisEdgeDetectionKernel::sigmaFromRadius(qreal radius) { return 0.3 * radius + 0.3; } void KisEdgeDetectionKernel::applyEdgeDetection(KisPaintDeviceSP device, const QRect &rect, qreal xRadius, qreal yRadius, KisEdgeDetectionKernel::FilterType type, const QBitArray &channelFlags, KoUpdater *progressUpdater, FilterOutput output, bool writeToAlpha) { QPoint srcTopLeft = rect.topLeft(); KisPainter finalPainter(device); finalPainter.setChannelFlags(channelFlags); finalPainter.setProgress(progressUpdater); if (output == pythagorean || output == radian) { KisPaintDeviceSP x_denormalised = new KisPaintDevice(device->colorSpace()); KisPaintDeviceSP y_denormalised = new KisPaintDevice(device->colorSpace()); x_denormalised->prepareClone(device); y_denormalised->prepareClone(device); KisConvolutionKernelSP kernelHorizLeftRight = KisEdgeDetectionKernel::createHorizontalKernel(xRadius, type); KisConvolutionKernelSP kernelVerticalTopBottom = KisEdgeDetectionKernel::createVerticalKernel(yRadius, type); - qreal horizontalCenter = qreal(kernelHorizLeftRight->width()) / 2.0; - qreal verticalCenter = qreal(kernelVerticalTopBottom->height()) / 2.0; - KisConvolutionPainter horizPainterLR(x_denormalised); horizPainterLR.setChannelFlags(channelFlags); horizPainterLR.setProgress(progressUpdater); horizPainterLR.applyMatrix(kernelHorizLeftRight, device, - srcTopLeft - QPoint(0, ceil(horizontalCenter)), - srcTopLeft - QPoint(0, ceil(horizontalCenter)), - rect.size() + QSize(0, 2 * ceil(horizontalCenter)), BORDER_REPEAT); + srcTopLeft, + srcTopLeft, + rect.size(), BORDER_REPEAT); KisConvolutionPainter verticalPainterTB(y_denormalised); verticalPainterTB.setChannelFlags(channelFlags); verticalPainterTB.setProgress(progressUpdater); verticalPainterTB.applyMatrix(kernelVerticalTopBottom, device, - srcTopLeft - QPoint(0, ceil(verticalCenter)), - srcTopLeft - QPoint(0, ceil(verticalCenter)), - rect.size() + QSize(0, 2 * ceil(verticalCenter)), BORDER_REPEAT); + srcTopLeft, + srcTopLeft, + rect.size(), BORDER_REPEAT); KisSequentialIterator yItterator(y_denormalised, rect); KisSequentialIterator xItterator(x_denormalised, rect); KisSequentialIterator finalIt(device, rect); const int pixelSize = device->colorSpace()->pixelSize(); const int channels = device->colorSpace()->channelCount(); const int alphaPos = device->colorSpace()->alphaPos(); KIS_SAFE_ASSERT_RECOVER_RETURN(alphaPos >= 0); QVector yNormalised(channels); QVector xNormalised(channels); QVector finalNorm(channels); while(yItterator.nextPixel() && xItterator.nextPixel() && finalIt.nextPixel()) { device->colorSpace()->normalisedChannelsValue(yItterator.rawData(), yNormalised); device->colorSpace()->normalisedChannelsValue(xItterator.rawData(), xNormalised); device->colorSpace()->normalisedChannelsValue(finalIt.rawData(), finalNorm); if (output == pythagorean) { for (int c = 0; ccolorSpace()); qreal alpha = 0; for (int c = 0; c<(channels-1); c++) { alpha = alpha+finalNorm[c]; } alpha = qMin(alpha/(channels-1), col.opacityF()); col.setOpacity(alpha); memcpy(finalIt.rawData(), col.data(), pixelSize); } else { quint8* f = finalIt.rawData(); finalNorm[alphaPos] = 1.0; device->colorSpace()->fromNormalisedChannelsValue(f, finalNorm); memcpy(finalIt.rawData(), f, pixelSize); } } } else { KisConvolutionKernelSP kernel; - qreal center = 0; bool denormalize = !writeToAlpha; if (output == xGrowth) { kernel = KisEdgeDetectionKernel::createHorizontalKernel(xRadius, type, denormalize); - center = qreal(kernel->width()) / 2.0; } else if (output == xFall) { kernel = KisEdgeDetectionKernel::createHorizontalKernel(xRadius, type, denormalize, true); - center = qreal(kernel->width()) / 2.0; } else if (output == yGrowth) { kernel = KisEdgeDetectionKernel::createVerticalKernel(yRadius, type, denormalize); - center = qreal(kernel->height()) / 2.0; } else { //yFall kernel = KisEdgeDetectionKernel::createVerticalKernel(yRadius, type, denormalize, true); - center = qreal(kernel->height()) / 2.0; } if (writeToAlpha) { KisPaintDeviceSP denormalised = new KisPaintDevice(device->colorSpace()); denormalised->prepareClone(device); KisConvolutionPainter kernelP(denormalised); kernelP.setChannelFlags(channelFlags); kernelP.setProgress(progressUpdater); kernelP.applyMatrix(kernel, device, - srcTopLeft - QPoint(0, ceil(center)), - srcTopLeft - QPoint(0, ceil(center)), - rect.size() + QSize(0, 2 * ceil(center)), BORDER_REPEAT); + srcTopLeft, srcTopLeft, + rect.size(), BORDER_REPEAT); KisSequentialIterator iterator(denormalised, rect); KisSequentialIterator finalIt(device, rect); const int pixelSize = device->colorSpace()->pixelSize(); const int channels = device->colorSpace()->colorChannelCount(); QVector normalised(channels); while (iterator.nextPixel() && finalIt.nextPixel()) { device->colorSpace()->normalisedChannelsValue(iterator.rawData(), normalised); KoColor col(finalIt.rawData(), device->colorSpace()); qreal alpha = 0; for (int c = 0; ccolorSpace()->setOpacity(finalIt.rawData(), 1.0, numConseqPixels); } } } } void KisEdgeDetectionKernel::convertToNormalMap(KisPaintDeviceSP device, const QRect &rect, qreal xRadius, qreal yRadius, KisEdgeDetectionKernel::FilterType type, int channelToConvert, QVector channelOrder, QVector channelFlip, const QBitArray &channelFlags, KoUpdater *progressUpdater) { QPoint srcTopLeft = rect.topLeft(); KisPainter finalPainter(device); finalPainter.setChannelFlags(channelFlags); finalPainter.setProgress(progressUpdater); KisPaintDeviceSP x_denormalised = new KisPaintDevice(device->colorSpace()); KisPaintDeviceSP y_denormalised = new KisPaintDevice(device->colorSpace()); x_denormalised->prepareClone(device); y_denormalised->prepareClone(device); KisConvolutionKernelSP kernelHorizLeftRight = KisEdgeDetectionKernel::createHorizontalKernel(yRadius, type, true, !channelFlip[1]); KisConvolutionKernelSP kernelVerticalTopBottom = KisEdgeDetectionKernel::createVerticalKernel(xRadius, type, true, !channelFlip[0]); - qreal horizontalCenter = qreal(kernelHorizLeftRight->width()) / 2.0; - qreal verticalCenter = qreal(kernelVerticalTopBottom->height()) / 2.0; - KisConvolutionPainter horizPainterLR(y_denormalised); horizPainterLR.setChannelFlags(channelFlags); horizPainterLR.setProgress(progressUpdater); horizPainterLR.applyMatrix(kernelHorizLeftRight, device, - srcTopLeft - QPoint(ceil(horizontalCenter), 0), - srcTopLeft - QPoint(ceil(horizontalCenter), 0), - rect.size() + QSize(2 * ceil(horizontalCenter), 0), BORDER_REPEAT); + srcTopLeft, srcTopLeft, + rect.size(), BORDER_REPEAT); KisConvolutionPainter verticalPainterTB(x_denormalised); verticalPainterTB.setChannelFlags(channelFlags); verticalPainterTB.setProgress(progressUpdater); verticalPainterTB.applyMatrix(kernelVerticalTopBottom, device, - srcTopLeft - QPoint(0, ceil(verticalCenter)), - srcTopLeft - QPoint(0, ceil(verticalCenter)), - rect.size() + QSize(0, 2 * ceil(verticalCenter)), BORDER_REPEAT); + srcTopLeft, + srcTopLeft, + rect.size(), BORDER_REPEAT); KisSequentialIterator yItterator(y_denormalised, rect); KisSequentialIterator xItterator(x_denormalised, rect); KisSequentialIterator finalIt(device, rect); const int pixelSize = device->colorSpace()->pixelSize(); const int channels = device->colorSpace()->channelCount(); const int alphaPos = device->colorSpace()->alphaPos(); KIS_SAFE_ASSERT_RECOVER_RETURN(alphaPos >= 0); QVector yNormalised(channels); QVector xNormalised(channels); QVector finalNorm(channels); while(yItterator.nextPixel() && xItterator.nextPixel() && finalIt.nextPixel()) { device->colorSpace()->normalisedChannelsValue(yItterator.rawData(), yNormalised); device->colorSpace()->normalisedChannelsValue(xItterator.rawData(), xNormalised); qreal z = 1.0; if (channelFlip[2]==true){ z=-1.0; } QVector3D normal = QVector3D((xNormalised[channelToConvert]-0.5)*2, (yNormalised[channelToConvert]-0.5)*2, z); normal.normalize(); finalNorm.fill(1.0); for (int c = 0; c<3; c++) { finalNorm[device->colorSpace()->channels().at(channelOrder[c])->displayPosition()] = (normal[channelOrder[c]]/2)+0.5; } finalNorm[alphaPos]= 1.0; quint8* pixel = finalIt.rawData(); device->colorSpace()->fromNormalisedChannelsValue(pixel, finalNorm); memcpy(finalIt.rawData(), pixel, pixelSize); } } diff --git a/libs/ui/opengl/kis_opengl_canvas2.cpp b/libs/ui/opengl/kis_opengl_canvas2.cpp index dce0f530b5..cf48d4bc55 100644 --- a/libs/ui/opengl/kis_opengl_canvas2.cpp +++ b/libs/ui/opengl/kis_opengl_canvas2.cpp @@ -1,1119 +1,1119 @@ /* This file is part of the KDE project * Copyright (C) Boudewijn Rempt , (C) 2006-2013 * Copyright (C) 2015 Michael Abrahams * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #define GL_GLEXT_PROTOTYPES #include "opengl/kis_opengl_canvas2.h" #include "opengl/kis_opengl_canvas2_p.h" #include "kis_algebra_2d.h" #include "opengl/kis_opengl_shader_loader.h" #include "opengl/kis_opengl_canvas_debugger.h" #include "canvas/kis_canvas2.h" #include "canvas/kis_coordinates_converter.h" #include "canvas/kis_display_filter.h" #include "canvas/kis_display_color_converter.h" #include "kis_config.h" #include "kis_config_notifier.h" #include "kis_debug.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "KisOpenGLModeProber.h" #include #if !defined(Q_OS_MACOS) && !defined(HAS_ONLY_OPENGL_ES) #include #endif #define NEAR_VAL -1000.0 #define FAR_VAL 1000.0 #ifndef GL_CLAMP_TO_EDGE #define GL_CLAMP_TO_EDGE 0x812F #endif #define PROGRAM_VERTEX_ATTRIBUTE 0 #define PROGRAM_TEXCOORD_ATTRIBUTE 1 static bool OPENGL_SUCCESS = false; struct KisOpenGLCanvas2::Private { public: ~Private() { delete displayShader; delete checkerShader; delete solidColorShader; delete overlayInvertedShader; Sync::deleteSync(glSyncObject); } bool canvasInitialized{false}; KisOpenGLImageTexturesSP openGLImageTextures; KisOpenGLShaderLoader shaderLoader; KisShaderProgram *displayShader{0}; KisShaderProgram *checkerShader{0}; KisShaderProgram *solidColorShader{0}; KisShaderProgram *overlayInvertedShader{0}; QScopedPointer canvasFBO; bool displayShaderCompiledWithDisplayFilterSupport{false}; GLfloat checkSizeScale; bool scrollCheckers; QSharedPointer displayFilter; KisOpenGL::FilterMode filterMode; bool proofingConfigIsUpdated=false; GLsync glSyncObject{0}; bool wrapAroundMode{false}; // Stores a quad for drawing the canvas QOpenGLVertexArrayObject quadVAO; QOpenGLBuffer quadBuffers[2]; // Stores data for drawing tool outlines QOpenGLVertexArrayObject outlineVAO; QOpenGLBuffer lineVertexBuffer; QOpenGLBuffer lineTexCoordBuffer; QVector3D vertices[6]; QVector2D texCoords[6]; #if !defined(Q_OS_MACOS) && !defined(HAS_ONLY_OPENGL_ES) QOpenGLFunctions_2_1 *glFn201; #endif qreal pixelGridDrawingThreshold; bool pixelGridEnabled; QColor gridColor; QColor cursorColor; bool lodSwitchInProgress = false; int xToColWithWrapCompensation(int x, const QRect &imageRect) { int firstImageColumn = openGLImageTextures->xToCol(imageRect.left()); int lastImageColumn = openGLImageTextures->xToCol(imageRect.right()); int colsPerImage = lastImageColumn - firstImageColumn + 1; int numWraps = floor(qreal(x) / imageRect.width()); int remainder = x - imageRect.width() * numWraps; return colsPerImage * numWraps + openGLImageTextures->xToCol(remainder); } int yToRowWithWrapCompensation(int y, const QRect &imageRect) { int firstImageRow = openGLImageTextures->yToRow(imageRect.top()); int lastImageRow = openGLImageTextures->yToRow(imageRect.bottom()); int rowsPerImage = lastImageRow - firstImageRow + 1; int numWraps = floor(qreal(y) / imageRect.height()); int remainder = y - imageRect.height() * numWraps; return rowsPerImage * numWraps + openGLImageTextures->yToRow(remainder); } }; KisOpenGLCanvas2::KisOpenGLCanvas2(KisCanvas2 *canvas, KisCoordinatesConverter *coordinatesConverter, QWidget *parent, KisImageWSP image, KisDisplayColorConverter *colorConverter) : QOpenGLWidget(parent) , KisCanvasWidgetBase(canvas, coordinatesConverter) , d(new Private()) { KisConfig cfg(false); cfg.setCanvasState("OPENGL_STARTED"); d->openGLImageTextures = KisOpenGLImageTextures::getImageTextures(image, colorConverter->openGLCanvasSurfaceProfile(), colorConverter->renderingIntent(), colorConverter->conversionFlags()); connect(d->openGLImageTextures.data(), SIGNAL(sigShowFloatingMessage(QString, int, bool)), SLOT(slotShowFloatingMessage(QString, int, bool))); setAcceptDrops(true); setAutoFillBackground(false); setFocusPolicy(Qt::StrongFocus); setAttribute(Qt::WA_NoSystemBackground, true); #ifdef Q_OS_MACOS setAttribute(Qt::WA_AcceptTouchEvents, false); #else setAttribute(Qt::WA_AcceptTouchEvents, true); #endif setAttribute(Qt::WA_InputMethodEnabled, false); setAttribute(Qt::WA_DontCreateNativeAncestors, true); #if QT_VERSION >= QT_VERSION_CHECK(5, 10, 0) // we should make sure the texture doesn't have alpha channel, // otherwise blending will not work correctly. if (KisOpenGLModeProber::instance()->useHDRMode()) { setTextureFormat(GL_RGBA16F); } else { /** * When in pure OpenGL mode, the canvas surface will have alpha * channel. Therefore, if our canvas blending algorithm produces * semi-transparent pixels (and it does), then Krita window itself * will become transparent. Which is not good. * * In Angle mode, GL_RGB8 is not available (and the transparence effect * doesn't exist at all). */ if (!KisOpenGL::hasOpenGLES()) { setTextureFormat(GL_RGB8); } } #endif setDisplayFilterImpl(colorConverter->displayFilter(), true); connect(KisConfigNotifier::instance(), SIGNAL(configChanged()), SLOT(slotConfigChanged())); connect(KisConfigNotifier::instance(), SIGNAL(pixelGridModeChanged()), SLOT(slotPixelGridModeChanged())); slotConfigChanged(); slotPixelGridModeChanged(); cfg.writeEntry("canvasState", "OPENGL_SUCCESS"); } KisOpenGLCanvas2::~KisOpenGLCanvas2() { delete d; } void KisOpenGLCanvas2::setDisplayFilter(QSharedPointer displayFilter) { setDisplayFilterImpl(displayFilter, false); } void KisOpenGLCanvas2::setDisplayFilterImpl(QSharedPointer displayFilter, bool initializing) { bool needsInternalColorManagement = !displayFilter || displayFilter->useInternalColorManagement(); bool needsFullRefresh = d->openGLImageTextures->setInternalColorManagementActive(needsInternalColorManagement); d->displayFilter = displayFilter; if (!initializing && needsFullRefresh) { canvas()->startUpdateInPatches(canvas()->image()->bounds()); } else if (!initializing) { canvas()->updateCanvas(); } } void KisOpenGLCanvas2::notifyImageColorSpaceChanged(const KoColorSpace *cs) { // FIXME: on color space change the data is refetched multiple // times by different actors! if (d->openGLImageTextures->setImageColorSpace(cs)) { canvas()->startUpdateInPatches(canvas()->image()->bounds()); } } void KisOpenGLCanvas2::setWrapAroundViewingMode(bool value) { d->wrapAroundMode = value; update(); } inline void rectToVertices(QVector3D* vertices, const QRectF &rc) { vertices[0] = QVector3D(rc.left(), rc.bottom(), 0.f); vertices[1] = QVector3D(rc.left(), rc.top(), 0.f); vertices[2] = QVector3D(rc.right(), rc.bottom(), 0.f); vertices[3] = QVector3D(rc.left(), rc.top(), 0.f); vertices[4] = QVector3D(rc.right(), rc.top(), 0.f); vertices[5] = QVector3D(rc.right(), rc.bottom(), 0.f); } inline void rectToTexCoords(QVector2D* texCoords, const QRectF &rc) { texCoords[0] = QVector2D(rc.left(), rc.bottom()); texCoords[1] = QVector2D(rc.left(), rc.top()); texCoords[2] = QVector2D(rc.right(), rc.bottom()); texCoords[3] = QVector2D(rc.left(), rc.top()); texCoords[4] = QVector2D(rc.right(), rc.top()); texCoords[5] = QVector2D(rc.right(), rc.bottom()); } void KisOpenGLCanvas2::initializeGL() { KisOpenGL::initializeContext(context()); initializeOpenGLFunctions(); #if !defined(Q_OS_MACOS) && !defined(HAS_ONLY_OPENGL_ES) if (!KisOpenGL::hasOpenGLES()) { d->glFn201 = context()->versionFunctions(); if (!d->glFn201) { warnUI << "Cannot obtain QOpenGLFunctions_2_1, glLogicOp cannot be used"; } } else { d->glFn201 = nullptr; } #endif KisConfig cfg(true); d->openGLImageTextures->setProofingConfig(canvas()->proofingConfiguration()); d->openGLImageTextures->initGL(context()->functions()); d->openGLImageTextures->generateCheckerTexture(createCheckersImage(cfg.checkSize())); initializeShaders(); // If we support OpenGL 3.2, then prepare our VAOs and VBOs for drawing if (KisOpenGL::hasOpenGL3()) { d->quadVAO.create(); d->quadVAO.bind(); glEnableVertexAttribArray(PROGRAM_VERTEX_ATTRIBUTE); glEnableVertexAttribArray(PROGRAM_TEXCOORD_ATTRIBUTE); // Create the vertex buffer object, it has 6 vertices with 3 components d->quadBuffers[0].create(); d->quadBuffers[0].setUsagePattern(QOpenGLBuffer::StaticDraw); d->quadBuffers[0].bind(); d->quadBuffers[0].allocate(d->vertices, 6 * 3 * sizeof(float)); glVertexAttribPointer(PROGRAM_VERTEX_ATTRIBUTE, 3, GL_FLOAT, GL_FALSE, 0, 0); // Create the texture buffer object, it has 6 texture coordinates with 2 components d->quadBuffers[1].create(); d->quadBuffers[1].setUsagePattern(QOpenGLBuffer::StaticDraw); d->quadBuffers[1].bind(); d->quadBuffers[1].allocate(d->texCoords, 6 * 2 * sizeof(float)); glVertexAttribPointer(PROGRAM_TEXCOORD_ATTRIBUTE, 2, GL_FLOAT, GL_FALSE, 0, 0); // Create the outline buffer, this buffer will store the outlines of // tools and will frequently change data d->outlineVAO.create(); d->outlineVAO.bind(); glEnableVertexAttribArray(PROGRAM_VERTEX_ATTRIBUTE); glEnableVertexAttribArray(PROGRAM_TEXCOORD_ATTRIBUTE); // The outline buffer has a StreamDraw usage pattern, because it changes constantly d->lineVertexBuffer.create(); d->lineVertexBuffer.setUsagePattern(QOpenGLBuffer::StreamDraw); d->lineVertexBuffer.bind(); glVertexAttribPointer(PROGRAM_VERTEX_ATTRIBUTE, 3, GL_FLOAT, GL_FALSE, 0, 0); d->lineTexCoordBuffer.create(); d->lineTexCoordBuffer.setUsagePattern(QOpenGLBuffer::StreamDraw); d->lineTexCoordBuffer.bind(); glVertexAttribPointer(PROGRAM_TEXCOORD_ATTRIBUTE, 2, GL_FLOAT, GL_FALSE, 0 ,0); } Sync::init(context()); d->canvasInitialized = true; } /** * Loads all shaders and reports compilation problems */ void KisOpenGLCanvas2::initializeShaders() { KIS_SAFE_ASSERT_RECOVER_RETURN(!d->canvasInitialized); delete d->checkerShader; delete d->solidColorShader; delete d->overlayInvertedShader; d->checkerShader = 0; d->solidColorShader = 0; d->overlayInvertedShader = 0; try { d->checkerShader = d->shaderLoader.loadCheckerShader(); d->solidColorShader = d->shaderLoader.loadSolidColorShader(); d->overlayInvertedShader = d->shaderLoader.loadOverlayInvertedShader(); } catch (const ShaderLoaderException &e) { reportFailedShaderCompilation(e.what()); } initializeDisplayShader(); } void KisOpenGLCanvas2::initializeDisplayShader() { KIS_SAFE_ASSERT_RECOVER_RETURN(!d->canvasInitialized); bool useHiQualityFiltering = d->filterMode == KisOpenGL::HighQualityFiltering; delete d->displayShader; d->displayShader = 0; try { d->displayShader = d->shaderLoader.loadDisplayShader(d->displayFilter, useHiQualityFiltering); d->displayShaderCompiledWithDisplayFilterSupport = d->displayFilter; } catch (const ShaderLoaderException &e) { reportFailedShaderCompilation(e.what()); } } /** * Displays a message box telling the user that * shader compilation failed and turns off OpenGL. */ void KisOpenGLCanvas2::reportFailedShaderCompilation(const QString &context) { KisConfig cfg(false); qDebug() << "Shader Compilation Failure: " << context; QMessageBox::critical(this, i18nc("@title:window", "Krita"), i18n("Krita could not initialize the OpenGL canvas:\n\n%1\n\n Krita will disable OpenGL and close now.", context), QMessageBox::Close); cfg.disableOpenGL(); cfg.setCanvasState("OPENGL_FAILED"); } void KisOpenGLCanvas2::resizeGL(int width, int height) { // The given size is the widget size but here we actually want to give // KisCoordinatesConverter the viewport size aligned to device pixels. if (KisOpenGL::supportsRenderToFBO()) { - d->canvasFBO.reset(new QOpenGLFramebufferObject(QSize(width, height))); + d->canvasFBO.reset(new QOpenGLFramebufferObject(QSize(width * devicePixelRatio(), height * devicePixelRatio()))); } coordinatesConverter()->setCanvasWidgetSize(widgetSizeAlignedToDevicePixel()); paintGL(); } void KisOpenGLCanvas2::paintGL() { if (!OPENGL_SUCCESS) { KisConfig cfg(false); cfg.writeEntry("canvasState", "OPENGL_PAINT_STARTED"); } KisOpenglCanvasDebugger::instance()->nofityPaintRequested(); if (d->canvasFBO) { d->canvasFBO->bind(); } renderCanvasGL(); if (d->canvasFBO) { d->canvasFBO->release(); QOpenGLFramebufferObject::blitFramebuffer(nullptr, d->canvasFBO.data(), GL_COLOR_BUFFER_BIT, GL_NEAREST); QOpenGLFramebufferObject::bindDefault(); } if (d->glSyncObject) { Sync::deleteSync(d->glSyncObject); } d->glSyncObject = Sync::getSync(); QPainter gc(this); renderDecorations(&gc); gc.end(); if (!OPENGL_SUCCESS) { KisConfig cfg(false); cfg.writeEntry("canvasState", "OPENGL_SUCCESS"); OPENGL_SUCCESS = true; } } void KisOpenGLCanvas2::paintToolOutline(const QPainterPath &path) { if (!d->overlayInvertedShader->bind()) { return; } QSizeF widgetSize = widgetSizeAlignedToDevicePixel(); // setup the mvp transformation QMatrix4x4 projectionMatrix; projectionMatrix.setToIdentity(); // FIXME: It may be better to have the projection in device pixel, but // this requires introducing a new coordinate system. projectionMatrix.ortho(0, widgetSize.width(), widgetSize.height(), 0, NEAR_VAL, FAR_VAL); // Set view/projection & texture matrices QMatrix4x4 modelMatrix(coordinatesConverter()->flakeToWidgetTransform()); modelMatrix.optimize(); modelMatrix = projectionMatrix * modelMatrix; d->overlayInvertedShader->setUniformValue(d->overlayInvertedShader->location(Uniform::ModelViewProjection), modelMatrix); d->overlayInvertedShader->setUniformValue( d->overlayInvertedShader->location(Uniform::FragmentColor), QVector4D(d->cursorColor.redF(), d->cursorColor.greenF(), d->cursorColor.blueF(), 1.0f)); // NOTE: Texture matrix transforms flake space -> widget space -> OpenGL UV texcoord space.. const QMatrix4x4 widgetToFBOTexCoordTransform = KisAlgebra2D::mapToRectInverse(QRect(QPoint(0, this->height()), QSize(this->width(), -1 * this->height()))); const QMatrix4x4 textureMatrix = widgetToFBOTexCoordTransform * QMatrix4x4(coordinatesConverter()->flakeToWidgetTransform()); d->overlayInvertedShader->setUniformValue(d->overlayInvertedShader->location(Uniform::TextureMatrix), textureMatrix); // For the legacy shader, we should use old fixed function // blending operations if available. if (!KisOpenGL::hasOpenGL3() && !KisOpenGL::hasOpenGLES()) { #ifndef HAS_ONLY_OPENGL_ES glHint(GL_LINE_SMOOTH_HINT, GL_NICEST); glEnable(GL_COLOR_LOGIC_OP); #ifndef Q_OS_MACOS if (d->glFn201) { d->glFn201->glLogicOp(GL_XOR); } #else // Q_OS_MACOS glLogicOp(GL_XOR); #endif // Q_OS_MACOS #else // HAS_ONLY_OPENGL_ES KIS_ASSERT_X(false, "KisOpenGLCanvas2::paintToolOutline", "Unexpected KisOpenGL::hasOpenGLES returned false"); #endif // HAS_ONLY_OPENGL_ES } // Paint the tool outline if (KisOpenGL::hasOpenGL3()) { d->outlineVAO.bind(); d->lineVertexBuffer.bind(); } // Convert every disjointed subpath to a polygon and draw that polygon QList subPathPolygons = path.toSubpathPolygons(); for (int polyIndex = 0; polyIndex < subPathPolygons.size(); polyIndex++) { const QPolygonF& polygon = subPathPolygons.at(polyIndex); QVector vertices; QVector texCoords; vertices.resize(polygon.count()); texCoords.resize(polygon.count()); for (int vertIndex = 0; vertIndex < polygon.count(); vertIndex++) { QPointF point = polygon.at(vertIndex); vertices[vertIndex].setX(point.x()); vertices[vertIndex].setY(point.y()); texCoords[vertIndex].setX(point.x()); texCoords[vertIndex].setY(point.y()); } if (KisOpenGL::hasOpenGL3()) { d->lineVertexBuffer.bind(); d->lineVertexBuffer.allocate(vertices.constData(), 3 * vertices.size() * sizeof(float)); d->lineTexCoordBuffer.bind(); d->lineTexCoordBuffer.allocate(texCoords.constData(), 2 * texCoords.size() * sizeof(float)); } else { d->overlayInvertedShader->enableAttributeArray(PROGRAM_VERTEX_ATTRIBUTE); d->overlayInvertedShader->setAttributeArray(PROGRAM_VERTEX_ATTRIBUTE, vertices.constData()); d->overlayInvertedShader->enableAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE); d->overlayInvertedShader->setAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE, texCoords.constData()); } const bool usingLegacyShader = !((KisOpenGL::hasOpenGL3() || KisOpenGL::hasOpenGLES()) && KisOpenGL::supportsRenderToFBO()); if (usingLegacyShader){ glDrawArrays(GL_LINE_STRIP, 0, vertices.size()); } else { glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D, d->canvasFBO->texture()); glDrawArrays(GL_LINE_STRIP, 0, vertices.size()); glBindTexture(GL_TEXTURE_2D, 0); } } if (KisOpenGL::hasOpenGL3()) { d->lineVertexBuffer.release(); d->outlineVAO.release(); } if (!KisOpenGL::hasOpenGLES()) { #ifndef HAS_ONLY_OPENGL_ES glDisable(GL_COLOR_LOGIC_OP); #else KIS_ASSERT_X(false, "KisOpenGLCanvas2::paintToolOutline", "Unexpected KisOpenGL::hasOpenGLES returned false"); #endif } else { glDisable(GL_BLEND); } d->overlayInvertedShader->release(); } bool KisOpenGLCanvas2::isBusy() const { const bool isBusyStatus = Sync::syncStatus(d->glSyncObject) == Sync::Unsignaled; KisOpenglCanvasDebugger::instance()->nofitySyncStatus(isBusyStatus); return isBusyStatus; } void KisOpenGLCanvas2::setLodResetInProgress(bool value) { d->lodSwitchInProgress = value; } void KisOpenGLCanvas2::drawCheckers() { if (!d->checkerShader) { return; } KisCoordinatesConverter *converter = coordinatesConverter(); QTransform textureTransform; QTransform modelTransform; QRectF textureRect; QRectF modelRect; QSizeF widgetSize = widgetSizeAlignedToDevicePixel(); QRectF viewportRect = !d->wrapAroundMode ? converter->imageRectInViewportPixels() : converter->widgetToViewport(QRectF(0, 0, widgetSize.width(), widgetSize.height())); if (!canvas()->renderingLimit().isEmpty()) { const QRect vrect = converter->imageToViewport(canvas()->renderingLimit()).toAlignedRect(); viewportRect &= vrect; } converter->getOpenGLCheckersInfo(viewportRect, &textureTransform, &modelTransform, &textureRect, &modelRect, d->scrollCheckers); textureTransform *= QTransform::fromScale(d->checkSizeScale / KisOpenGLImageTextures::BACKGROUND_TEXTURE_SIZE, d->checkSizeScale / KisOpenGLImageTextures::BACKGROUND_TEXTURE_SIZE); if (!d->checkerShader->bind()) { qWarning() << "Could not bind checker shader"; return; } QMatrix4x4 projectionMatrix; projectionMatrix.setToIdentity(); // FIXME: It may be better to have the projection in device pixel, but // this requires introducing a new coordinate system. projectionMatrix.ortho(0, widgetSize.width(), widgetSize.height(), 0, NEAR_VAL, FAR_VAL); // Set view/projection matrices QMatrix4x4 modelMatrix(modelTransform); modelMatrix.optimize(); modelMatrix = projectionMatrix * modelMatrix; d->checkerShader->setUniformValue(d->checkerShader->location(Uniform::ModelViewProjection), modelMatrix); QMatrix4x4 textureMatrix(textureTransform); d->checkerShader->setUniformValue(d->checkerShader->location(Uniform::TextureMatrix), textureMatrix); //Setup the geometry for rendering if (KisOpenGL::hasOpenGL3()) { rectToVertices(d->vertices, modelRect); d->quadBuffers[0].bind(); d->quadBuffers[0].write(0, d->vertices, 3 * 6 * sizeof(float)); rectToTexCoords(d->texCoords, textureRect); d->quadBuffers[1].bind(); d->quadBuffers[1].write(0, d->texCoords, 2 * 6 * sizeof(float)); } else { rectToVertices(d->vertices, modelRect); d->checkerShader->enableAttributeArray(PROGRAM_VERTEX_ATTRIBUTE); d->checkerShader->setAttributeArray(PROGRAM_VERTEX_ATTRIBUTE, d->vertices); rectToTexCoords(d->texCoords, textureRect); d->checkerShader->enableAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE); d->checkerShader->setAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE, d->texCoords); } // render checkers glActiveTexture(GL_TEXTURE0); glBindTexture(GL_TEXTURE_2D, d->openGLImageTextures->checkerTexture()); glDrawArrays(GL_TRIANGLES, 0, 6); glBindTexture(GL_TEXTURE_2D, 0); d->checkerShader->release(); glBindBuffer(GL_ARRAY_BUFFER, 0); } void KisOpenGLCanvas2::drawGrid() { if (!d->solidColorShader->bind()) { return; } QSizeF widgetSize = widgetSizeAlignedToDevicePixel(); QMatrix4x4 projectionMatrix; projectionMatrix.setToIdentity(); // FIXME: It may be better to have the projection in device pixel, but // this requires introducing a new coordinate system. projectionMatrix.ortho(0, widgetSize.width(), widgetSize.height(), 0, NEAR_VAL, FAR_VAL); // Set view/projection matrices QMatrix4x4 modelMatrix(coordinatesConverter()->imageToWidgetTransform()); modelMatrix.optimize(); modelMatrix = projectionMatrix * modelMatrix; d->solidColorShader->setUniformValue(d->solidColorShader->location(Uniform::ModelViewProjection), modelMatrix); glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); d->solidColorShader->setUniformValue( d->solidColorShader->location(Uniform::FragmentColor), QVector4D(d->gridColor.redF(), d->gridColor.greenF(), d->gridColor.blueF(), 0.5f)); if (KisOpenGL::hasOpenGL3()) { d->outlineVAO.bind(); d->lineVertexBuffer.bind(); } QRectF widgetRect(0,0, widgetSize.width(), widgetSize.height()); QRectF widgetRectInImagePixels = coordinatesConverter()->documentToImage(coordinatesConverter()->widgetToDocument(widgetRect)); QRect wr = widgetRectInImagePixels.toAlignedRect(); if (!d->wrapAroundMode) { wr &= d->openGLImageTextures->storedImageBounds(); } QPoint topLeftCorner = wr.topLeft(); QPoint bottomRightCorner = wr.bottomRight() + QPoint(1, 1); QVector grid; for (int i = topLeftCorner.x(); i <= bottomRightCorner.x(); ++i) { grid.append(QVector3D(i, topLeftCorner.y(), 0)); grid.append(QVector3D(i, bottomRightCorner.y(), 0)); } for (int i = topLeftCorner.y(); i <= bottomRightCorner.y(); ++i) { grid.append(QVector3D(topLeftCorner.x(), i, 0)); grid.append(QVector3D(bottomRightCorner.x(), i, 0)); } if (KisOpenGL::hasOpenGL3()) { d->lineVertexBuffer.allocate(grid.constData(), 3 * grid.size() * sizeof(float)); } else { d->solidColorShader->enableAttributeArray(PROGRAM_VERTEX_ATTRIBUTE); d->solidColorShader->setAttributeArray(PROGRAM_VERTEX_ATTRIBUTE, grid.constData()); } glDrawArrays(GL_LINES, 0, grid.size()); if (KisOpenGL::hasOpenGL3()) { d->lineVertexBuffer.release(); d->outlineVAO.release(); } d->solidColorShader->release(); glDisable(GL_BLEND); } void KisOpenGLCanvas2::drawImage() { if (!d->displayShader) { return; } glEnable(GL_BLEND); glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); KisCoordinatesConverter *converter = coordinatesConverter(); d->displayShader->bind(); QSizeF widgetSize = widgetSizeAlignedToDevicePixel(); QMatrix4x4 projectionMatrix; projectionMatrix.setToIdentity(); // FIXME: It may be better to have the projection in device pixel, but // this requires introducing a new coordinate system. projectionMatrix.ortho(0, widgetSize.width(), widgetSize.height(), 0, NEAR_VAL, FAR_VAL); // Set view/projection matrices QMatrix4x4 modelMatrix(converter->imageToWidgetTransform()); modelMatrix.optimize(); modelMatrix = projectionMatrix * modelMatrix; d->displayShader->setUniformValue(d->displayShader->location(Uniform::ModelViewProjection), modelMatrix); QMatrix4x4 textureMatrix; textureMatrix.setToIdentity(); d->displayShader->setUniformValue(d->displayShader->location(Uniform::TextureMatrix), textureMatrix); QRectF widgetRect(0,0, widgetSize.width(), widgetSize.height()); QRectF widgetRectInImagePixels = converter->documentToImage(converter->widgetToDocument(widgetRect)); const QRect renderingLimit = canvas()->renderingLimit(); if (!renderingLimit.isEmpty()) { widgetRectInImagePixels &= renderingLimit; } qreal scaleX, scaleY; converter->imagePhysicalScale(&scaleX, &scaleY); d->displayShader->setUniformValue(d->displayShader->location(Uniform::ViewportScale), (GLfloat) scaleX); d->displayShader->setUniformValue(d->displayShader->location(Uniform::TexelSize), (GLfloat) d->openGLImageTextures->texelSize()); QRect ir = d->openGLImageTextures->storedImageBounds(); QRect wr = widgetRectInImagePixels.toAlignedRect(); if (!d->wrapAroundMode) { // if we don't want to paint wrapping images, just limit the // processing area, and the code will handle all the rest wr &= ir; } int firstColumn = d->xToColWithWrapCompensation(wr.left(), ir); int lastColumn = d->xToColWithWrapCompensation(wr.right(), ir); int firstRow = d->yToRowWithWrapCompensation(wr.top(), ir); int lastRow = d->yToRowWithWrapCompensation(wr.bottom(), ir); int minColumn = d->openGLImageTextures->xToCol(ir.left()); int maxColumn = d->openGLImageTextures->xToCol(ir.right()); int minRow = d->openGLImageTextures->yToRow(ir.top()); int maxRow = d->openGLImageTextures->yToRow(ir.bottom()); int imageColumns = maxColumn - minColumn + 1; int imageRows = maxRow - minRow + 1; for (int col = firstColumn; col <= lastColumn; col++) { for (int row = firstRow; row <= lastRow; row++) { int effectiveCol = col; int effectiveRow = row; QPointF tileWrappingTranslation; if (effectiveCol > maxColumn || effectiveCol < minColumn) { int translationStep = floor(qreal(col) / imageColumns); int originCol = translationStep * imageColumns; effectiveCol = col - originCol; tileWrappingTranslation.rx() = translationStep * ir.width(); } if (effectiveRow > maxRow || effectiveRow < minRow) { int translationStep = floor(qreal(row) / imageRows); int originRow = translationStep * imageRows; effectiveRow = row - originRow; tileWrappingTranslation.ry() = translationStep * ir.height(); } KisTextureTile *tile = d->openGLImageTextures->getTextureTileCR(effectiveCol, effectiveRow); if (!tile) { warnUI << "OpenGL: Trying to paint texture tile but it has not been created yet."; continue; } /* * We create a float rect here to workaround Qt's * "history reasons" in calculation of right() * and bottom() coordinates of integer rects. */ QRectF textureRect; QRectF modelRect; if (renderingLimit.isEmpty()) { textureRect = tile->tileRectInTexturePixels(); modelRect = tile->tileRectInImagePixels().translated(tileWrappingTranslation.x(), tileWrappingTranslation.y()); } else { const QRect limitedTileRect = tile->tileRectInImagePixels() & renderingLimit; textureRect = tile->imageRectInTexturePixels(limitedTileRect); modelRect = limitedTileRect.translated(tileWrappingTranslation.x(), tileWrappingTranslation.y()); } //Setup the geometry for rendering if (KisOpenGL::hasOpenGL3()) { rectToVertices(d->vertices, modelRect); d->quadBuffers[0].bind(); d->quadBuffers[0].write(0, d->vertices, 3 * 6 * sizeof(float)); rectToTexCoords(d->texCoords, textureRect); d->quadBuffers[1].bind(); d->quadBuffers[1].write(0, d->texCoords, 2 * 6 * sizeof(float)); } else { rectToVertices(d->vertices, modelRect); d->displayShader->enableAttributeArray(PROGRAM_VERTEX_ATTRIBUTE); d->displayShader->setAttributeArray(PROGRAM_VERTEX_ATTRIBUTE, d->vertices); rectToTexCoords(d->texCoords, textureRect); d->displayShader->enableAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE); d->displayShader->setAttributeArray(PROGRAM_TEXCOORD_ATTRIBUTE, d->texCoords); } if (d->displayFilter) { glActiveTexture(GL_TEXTURE0 + 1); glBindTexture(GL_TEXTURE_3D, d->displayFilter->lutTexture()); d->displayShader->setUniformValue(d->displayShader->location(Uniform::Texture1), 1); } glActiveTexture(GL_TEXTURE0); const int currentLodPlane = tile->bindToActiveTexture(d->lodSwitchInProgress); if (d->displayShader->location(Uniform::FixedLodLevel) >= 0) { d->displayShader->setUniformValue(d->displayShader->location(Uniform::FixedLodLevel), (GLfloat) currentLodPlane); } if (currentLodPlane > 0) { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR_MIPMAP_NEAREST); } else if (SCALE_MORE_OR_EQUAL_TO(scaleX, scaleY, 2.0)) { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); } else { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR); switch(d->filterMode) { case KisOpenGL::NearestFilterMode: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST); glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST); break; case KisOpenGL::BilinearFilterMode: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR); break; case KisOpenGL::TrilinearFilterMode: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR_MIPMAP_LINEAR); break; case KisOpenGL::HighQualityFiltering: if (SCALE_LESS_THAN(scaleX, scaleY, 0.5)) { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR_MIPMAP_NEAREST); } else { glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR); } break; } } glDrawArrays(GL_TRIANGLES, 0, 6); } } glBindTexture(GL_TEXTURE_2D, 0); d->displayShader->release(); glBindBuffer(GL_ARRAY_BUFFER, 0); glDisable(GL_BLEND); } QSize KisOpenGLCanvas2::viewportDevicePixelSize() const { // This is how QOpenGLCanvas sets the FBO and the viewport size. If // devicePixelRatioF() is non-integral, the result is truncated. int viewportWidth = static_cast(width() * devicePixelRatioF()); int viewportHeight = static_cast(height() * devicePixelRatioF()); return QSize(viewportWidth, viewportHeight); } QSizeF KisOpenGLCanvas2::widgetSizeAlignedToDevicePixel() const { QSize viewportSize = viewportDevicePixelSize(); qreal scaledWidth = viewportSize.width() / devicePixelRatioF(); qreal scaledHeight = viewportSize.height() / devicePixelRatioF(); return QSizeF(scaledWidth, scaledHeight); } void KisOpenGLCanvas2::slotConfigChanged() { KisConfig cfg(true); d->checkSizeScale = KisOpenGLImageTextures::BACKGROUND_TEXTURE_CHECK_SIZE / static_cast(cfg.checkSize()); d->scrollCheckers = cfg.scrollCheckers(); d->openGLImageTextures->generateCheckerTexture(createCheckersImage(cfg.checkSize())); d->openGLImageTextures->updateConfig(cfg.useOpenGLTextureBuffer(), cfg.numMipmapLevels()); d->filterMode = (KisOpenGL::FilterMode) cfg.openGLFilteringMode(); d->cursorColor = cfg.getCursorMainColor(); notifyConfigChanged(); } void KisOpenGLCanvas2::slotPixelGridModeChanged() { KisConfig cfg(true); d->pixelGridDrawingThreshold = cfg.getPixelGridDrawingThreshold(); d->pixelGridEnabled = cfg.pixelGridEnabled(); d->gridColor = cfg.getPixelGridColor(); update(); } void KisOpenGLCanvas2::slotShowFloatingMessage(const QString &message, int timeout, bool priority) { canvas()->imageView()->showFloatingMessage(message, QIcon(), timeout, priority ? KisFloatingMessage::High : KisFloatingMessage::Medium); } QVariant KisOpenGLCanvas2::inputMethodQuery(Qt::InputMethodQuery query) const { return processInputMethodQuery(query); } void KisOpenGLCanvas2::inputMethodEvent(QInputMethodEvent *event) { processInputMethodEvent(event); } void KisOpenGLCanvas2::renderCanvasGL() { { // Draw the border (that is, clear the whole widget to the border color) QColor widgetBackgroundColor = borderColor(); const KoColorSpace *finalColorSpace = KoColorSpaceRegistry::instance()->colorSpace(RGBAColorModelID.id(), d->openGLImageTextures->updateInfoBuilder().destinationColorSpace()->colorDepthId().id(), d->openGLImageTextures->monitorProfile()); KoColor convertedBackgroudColor = KoColor(widgetBackgroundColor, KoColorSpaceRegistry::instance()->rgb8()); convertedBackgroudColor.convertTo(finalColorSpace); QVector channels = QVector(4); convertedBackgroudColor.colorSpace()->normalisedChannelsValue(convertedBackgroudColor.data(), channels); // Data returned by KoRgbU8ColorSpace comes in the order: blue, green, red. glClearColor(channels[2], channels[1], channels[0], 1.0); } glClear(GL_COLOR_BUFFER_BIT); if ((d->displayFilter && d->displayFilter->updateShader()) || (bool(d->displayFilter) != d->displayShaderCompiledWithDisplayFilterSupport)) { KIS_SAFE_ASSERT_RECOVER_NOOP(d->canvasInitialized); d->canvasInitialized = false; // TODO: check if actually needed? initializeDisplayShader(); d->canvasInitialized = true; } if (KisOpenGL::hasOpenGL3()) { d->quadVAO.bind(); } drawCheckers(); drawImage(); if ((coordinatesConverter()->effectiveZoom() > d->pixelGridDrawingThreshold - 0.00001) && d->pixelGridEnabled) { drawGrid(); } if (KisOpenGL::hasOpenGL3()) { d->quadVAO.release(); } } void KisOpenGLCanvas2::renderDecorations(QPainter *painter) { QRect boundingRect = coordinatesConverter()->imageRectInWidgetPixels().toAlignedRect(); drawDecorations(*painter, boundingRect); } void KisOpenGLCanvas2::setDisplayColorConverter(KisDisplayColorConverter *colorConverter) { d->openGLImageTextures->setMonitorProfile(colorConverter->openGLCanvasSurfaceProfile(), colorConverter->renderingIntent(), colorConverter->conversionFlags()); } void KisOpenGLCanvas2::channelSelectionChanged(const QBitArray &channelFlags) { d->openGLImageTextures->setChannelFlags(channelFlags); } void KisOpenGLCanvas2::finishResizingImage(qint32 w, qint32 h) { if (d->canvasInitialized) { d->openGLImageTextures->slotImageSizeChanged(w, h); } } KisUpdateInfoSP KisOpenGLCanvas2::startUpdateCanvasProjection(const QRect & rc, const QBitArray &channelFlags) { d->openGLImageTextures->setChannelFlags(channelFlags); if (canvas()->proofingConfigUpdated()) { d->openGLImageTextures->setProofingConfig(canvas()->proofingConfiguration()); canvas()->setProofingConfigUpdated(false); } return d->openGLImageTextures->updateCache(rc, d->openGLImageTextures->image()); } QRect KisOpenGLCanvas2::updateCanvasProjection(KisUpdateInfoSP info) { // See KisQPainterCanvas::updateCanvasProjection for more info bool isOpenGLUpdateInfo = dynamic_cast(info.data()); if (isOpenGLUpdateInfo) { d->openGLImageTextures->recalculateCache(info, d->lodSwitchInProgress); } return QRect(); // FIXME: Implement dirty rect for OpenGL } QVector KisOpenGLCanvas2::updateCanvasProjection(const QVector &infoObjects) { #ifdef Q_OS_MACOS /** * On OSX openGL different (shared) contexts have different execution queues. * It means that the textures uploading and their painting can be easily reordered. * To overcome the issue, we should ensure that the textures are uploaded in the * same openGL context as the painting is done. */ QOpenGLContext *oldContext = QOpenGLContext::currentContext(); QSurface *oldSurface = oldContext ? oldContext->surface() : 0; this->makeCurrent(); #endif QVector result = KisCanvasWidgetBase::updateCanvasProjection(infoObjects); #ifdef Q_OS_MACOS if (oldContext) { oldContext->makeCurrent(oldSurface); } else { this->doneCurrent(); } #endif return result; } bool KisOpenGLCanvas2::callFocusNextPrevChild(bool next) { return focusNextPrevChild(next); } KisOpenGLImageTexturesSP KisOpenGLCanvas2::openGLImageTextures() const { return d->openGLImageTextures; } diff --git a/plugins/generators/pattern/kis_wdg_pattern.cpp b/plugins/generators/pattern/kis_wdg_pattern.cpp index 88b5e3ea9e..ae1297f242 100644 --- a/plugins/generators/pattern/kis_wdg_pattern.cpp +++ b/plugins/generators/pattern/kis_wdg_pattern.cpp @@ -1,162 +1,163 @@ /* * This file is part of Krita * * Copyright (c) 2006 Cyrille Berger * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "kis_wdg_pattern.h" #include #include #include #include #include #include #include #include #include #include "ui_wdgpatternoptions.h" KisWdgPattern::KisWdgPattern(QWidget* parent) : KisConfigWidget(parent) { m_widget = new Ui_WdgPatternOptions(); m_widget->setupUi(this); m_widget->lblPattern->setVisible(false); - m_widget->lblColor->setVisible(false); - m_widget->bnColor->setVisible(false); - - m_widget->sldShearX->setSuffix(i18n(" px")); - m_widget->sldShearY->setSuffix(i18n(" px")); - m_widget->sldShearX->setRange(-5.0, 5.0, 2); - m_widget->sldShearY->setRange(-5.0, 5.0, 2); - m_widget->sldShearX->setSingleStep(0.01); - m_widget->sldShearY->setSingleStep(0.01); + + m_widget->sldShearX->setSuffix(QChar(Qt::Key_Percent)); + m_widget->sldShearY->setSuffix(QChar(Qt::Key_Percent)); + m_widget->sldShearX->setRange(-500, 500, 2); + m_widget->sldShearY->setRange(-500, 500, 2); + m_widget->sldShearX->setSingleStep(1); + m_widget->sldShearY->setSingleStep(1); m_widget->sldShearX->setValue(0.0); m_widget->sldShearY->setValue(0.0); m_widget->spbOffsetX->setSuffix(i18n(" px")); m_widget->spbOffsetY->setSuffix(i18n(" px")); m_widget->spbOffsetX->setRange(-10000, 10000); m_widget->spbOffsetY->setRange(-10000, 10000); m_widget->sldRotationX->setSuffix(QChar(Qt::Key_degree)); m_widget->sldRotationY->setSuffix(QChar(Qt::Key_degree)); m_widget->sldRotationZ->setSuffix(QChar(Qt::Key_degree)); m_widget->sldRotationX->setRange(0.0, 360.0, 2); m_widget->sldRotationY->setRange(0.0, 360.0, 2); m_widget->sldRotationZ->setRange(0.0, 360.0, 2); m_widget->sldRotationX->setValue(0.0); m_widget->sldRotationY->setValue(0.0); m_widget->sldRotationZ->setValue(0.0); m_widget->sldRotationX->setSingleStep(1.0); m_widget->sldRotationY->setSingleStep(1.0); m_widget->sldRotationZ->setSingleStep(1.0); + + m_widget->gb3dRotation->setVisible(false); + connect(m_widget->patternChooser, SIGNAL(resourceSelected(KoResourceSP)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->sldShearX, SIGNAL(valueChanged(double)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->sldShearY, SIGNAL(valueChanged(double)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->spbOffsetX, SIGNAL(valueChanged(int)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->spbOffsetY, SIGNAL(valueChanged(int)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->spbScaleWidth, SIGNAL(valueChanged(double)), this, SLOT(slotWidthChanged(double))); connect(m_widget->spbScaleHeight, SIGNAL(valueChanged(double)), this, SLOT(slotHeightChanged(double))); connect(m_widget->sldRotationX, SIGNAL(valueChanged(double)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->sldRotationY, SIGNAL(valueChanged(double)), this, SIGNAL(sigConfigurationUpdated())); connect(m_widget->sldRotationZ, SIGNAL(valueChanged(double)), this, SIGNAL(sigConfigurationUpdated())); } KisWdgPattern::~KisWdgPattern() { delete m_widget; } void KisWdgPattern::setConfiguration(const KisPropertiesConfigurationSP config) { auto source = KisGlobalResourcesInterface::instance()->source(ResourceType::Patterns); KoPatternSP pattern = source.resourceForName(config->getString("pattern", "Grid01.pat")); widget()->patternChooser->setCurrentPattern(pattern ? pattern : source.fallbackResource()); m_widget->spbOffsetX->setValue(config->getInt("transform_offset_x", 0)); m_widget->spbOffsetY->setValue(config->getInt("transform_offset_y", 0)); - m_widget->spbScaleWidth->setValue(config->getInt("transform_scale_x", 1.0)*100); - m_widget->spbScaleHeight->setValue(config->getInt("transform_scale_y", 1.0)*100); + m_widget->spbScaleWidth->setValue(config->getInt("transform_scale_x", 1.0) * 100); + m_widget->spbScaleHeight->setValue(config->getInt("transform_scale_y", 1.0) * 100); m_widget->btnLockAspectRatio->setKeepAspectRatio(config->getBool("transform_keep_scale_aspect", true)); - m_widget->sldShearX->setValue(config->getDouble("transform_shear_x", 0.0)); - m_widget->sldShearY->setValue(config->getDouble("transform_shear_y", 0.0)); + m_widget->sldShearX->setValue(config->getDouble("transform_shear_x", 0.0) * 100); + m_widget->sldShearY->setValue(config->getDouble("transform_shear_y", 0.0) * 100); widget()->sldRotationX->setValue(config->getDouble("transform_rotation_x", 0.0)); widget()->sldRotationY->setValue(config->getDouble("transform_rotation_y", 0.0)); widget()->sldRotationZ->setValue(config->getDouble("transform_rotation_z", 0.0)); } KisPropertiesConfigurationSP KisWdgPattern::configuration() const { KisGeneratorSP generator = KisGeneratorRegistry::instance()->get("pattern"); KisFilterConfigurationSP config = generator->factoryConfiguration(KisGlobalResourcesInterface::instance()); QVariant v; if (widget()->patternChooser->currentResource()) { v.setValue(widget()->patternChooser->currentResource()->name()); config->setProperty("pattern", v); } config->setProperty("transform_offset_x", m_widget->spbOffsetX->value()); config->setProperty("transform_offset_y", m_widget->spbOffsetY->value()); - config->setProperty("transform_scale_x", m_widget->spbScaleWidth->value()/100); - config->setProperty("transform_scale_y", m_widget->spbScaleHeight->value()/100); + config->setProperty("transform_scale_x", m_widget->spbScaleWidth->value() / 100); + config->setProperty("transform_scale_y", m_widget->spbScaleHeight->value() / 100); config->setProperty("transform_keep_scale_aspect", m_widget->btnLockAspectRatio->keepAspectRatio()); - config->setProperty("transform_shear_x", widget()->sldShearX->value()); - config->setProperty("transform_shear_y", widget()->sldShearY->value()); + config->setProperty("transform_shear_x", widget()->sldShearX->value() / 100); + config->setProperty("transform_shear_y", widget()->sldShearY->value() / 100); config->setProperty("transform_rotation_x", widget()->sldRotationX->value()); config->setProperty("transform_rotation_y", widget()->sldRotationY->value()); config->setProperty("transform_rotation_z", widget()->sldRotationZ->value()); return config; } void KisWdgPattern::slotWidthChanged(double w) { if (m_widget->btnLockAspectRatio->keepAspectRatio()) { m_widget->spbScaleHeight->blockSignals(true); m_widget->spbScaleHeight->setValue(w); m_widget->spbScaleHeight->blockSignals(false); } emit sigConfigurationUpdated(); } void KisWdgPattern::slotHeightChanged(double h) { if (m_widget->btnLockAspectRatio->keepAspectRatio()) { m_widget->spbScaleWidth->blockSignals(true); m_widget->spbScaleWidth->setValue(h); m_widget->spbScaleWidth->blockSignals(false); } emit sigConfigurationUpdated(); } diff --git a/plugins/generators/pattern/wdgpatternoptions.ui b/plugins/generators/pattern/wdgpatternoptions.ui index b847dee948..5e35c950dc 100644 --- a/plugins/generators/pattern/wdgpatternoptions.ui +++ b/plugins/generators/pattern/wdgpatternoptions.ui @@ -1,304 +1,283 @@ WdgPatternOptions 0 0 484 477 0 Pattern &Pattern: Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter patternChooser 0 0 - - - - &Color: - - - Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter - - - bnColor - - - - - - Transform - + 3d Rotation: X-Rotation: Y-Rotation: 0 0 0 0 - + Scale: Width: Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter % 1 500.000000000000000 100.000000000000000 Height: Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter % 1 500.000000000000000 100.000000000000000 - + Offset: X: Y: - + Shear: X: Y: 0 0 0 0 - + Rotation: - - KisColorButton - QPushButton -
kis_color_button.h
- KisPatternChooser QWidget
kis_pattern_chooser.h
1 KoAspectButton QWidget
KoAspectButton.h
1 KisDoubleParseSpinBox QDoubleSpinBox
kis_double_parse_spin_box.h
 KisDoubleSliderSpinBox QWidget
kis_slider_spin_box.h
1 KisIntParseSpinBox QSpinBox
kis_int_parse_spin_box.h
 diff --git a/plugins/tools/tool_transform2/kis_tool_transform_config_widget.cpp b/plugins/tools/tool_transform2/kis_tool_transform_config_widget.cpp index bfbc5e2546..628debde9a 100644 --- a/plugins/tools/tool_transform2/kis_tool_transform_config_widget.cpp +++ b/plugins/tools/tool_transform2/kis_tool_transform_config_widget.cpp @@ -1,1288 +1,1288 @@ /* * Copyright (c) 2013 Dmitry Kazakov * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "kis_tool_transform_config_widget.h" #include #include "rotation_icons.h" #include "kis_canvas2.h" #include #include "kis_liquify_properties.h" #include "KisMainWindow.h" #include "KisViewManager.h" #include "kis_transform_utils.h" template inline T sign(T x) { return x > 0 ? 1 : x == (T)0 ? 0 : -1; } const int KisToolTransformConfigWidget::DEFAULT_POINTS_PER_LINE = 3; KisToolTransformConfigWidget::KisToolTransformConfigWidget(TransformTransactionProperties *transaction, KisCanvas2 *canvas, bool workRecursively, QWidget *parent) : QWidget(parent), m_transaction(transaction), m_notificationsBlocked(0), m_uiSlotsBlocked(0), m_configChanged(false) { setupUi(this); chkWorkRecursively->setIcon(KisIconUtils::loadIcon("krita_tool_transform_recursive")); flipXButton->setIcon(KisIconUtils::loadIcon("transform_icons_mirror_x")); flipYButton->setIcon(KisIconUtils::loadIcon("transform_icons_mirror_y")); rotateCWButton->setIcon(KisIconUtils::loadIcon("transform_icons_rotate_cw")); rotateCCWButton->setIcon(KisIconUtils::loadIcon("transform_icons_rotate_ccw")); chkWorkRecursively->setChecked(workRecursively); connect(chkWorkRecursively, SIGNAL(toggled(bool)), this, SIGNAL(sigRestartTransform())); // Granularity can only be specified in the power of 2's QStringList granularityValues{"4","8","16","32"}; changeGranularity->addItems(granularityValues); changeGranularity->setCurrentIndex(1); granularityPreview->addItems(granularityValues); granularityPreview->setCurrentIndex(2); connect(changeGranularity,SIGNAL(currentIndexChanged(QString)), this,SLOT(slotGranularityChanged(QString))); connect(granularityPreview, SIGNAL(currentIndexChanged(QString)), this,SLOT(slotPreviewGranularityChanged(QString))); // Init Filter combo cmbFilter->setIDList(KisFilterStrategyRegistry::instance()->listKeys()); cmbFilter->setCurrent("Bicubic"); cmbFilter->setToolTip(i18nc("@info:tooltip", "

Select filtering mode:\n" "

    " "
  • Bilinear for areas with uniform color to avoid artifacts
    • " "
  • Bicubic for smoother results
    • " "
  • Lanczos3 for sharp results. May produce aerials.
    • " "

")); connect(cmbFilter, SIGNAL(activated(KoID)), this, SLOT(slotFilterChanged(KoID))); // Init Warp Type combo cmbWarpType->insertItem(KisWarpTransformWorker::AFFINE_TRANSFORM,i18n("Default (Affine)")); cmbWarpType->insertItem(KisWarpTransformWorker::RIGID_TRANSFORM,i18n("Strong (Rigid)")); cmbWarpType->insertItem(KisWarpTransformWorker::SIMILITUDE_TRANSFORM,i18n("Strongest (Similitude)")); cmbWarpType->setCurrentIndex(KisWarpTransformWorker::AFFINE_TRANSFORM); connect(cmbWarpType, SIGNAL(currentIndexChanged(int)), this, SLOT(slotWarpTypeChanged(int))); // Init Rotation Center buttons m_handleDir[0] = QPointF(1, 0); m_handleDir[1] = QPointF(1, -1); m_handleDir[2] = QPointF(0, -1); m_handleDir[3] = QPointF(-1, -1); m_handleDir[4] = QPointF(-1, 0); m_handleDir[5] = QPointF(-1, 1); m_handleDir[6] = QPointF(0, 1); m_handleDir[7] = QPointF(1, 1); m_handleDir[8] = QPointF(0, 0); // also add the center m_rotationCenterButtons = new QButtonGroup(0); // we set the ids to match m_handleDir m_rotationCenterButtons->addButton(middleRightButton, 0); m_rotationCenterButtons->addButton(topRightButton, 1); m_rotationCenterButtons->addButton(middleTopButton, 2); m_rotationCenterButtons->addButton(topLeftButton, 3); m_rotationCenterButtons->addButton(middleLeftButton, 4); m_rotationCenterButtons->addButton(bottomLeftButton, 5); m_rotationCenterButtons->addButton(middleBottomButton, 6); m_rotationCenterButtons->addButton(bottomRightButton, 7); m_rotationCenterButtons->addButton(centerButton, 8); QToolButton *nothingSelected = new QToolButton(0); nothingSelected->setCheckable(true); nothingSelected->setAutoExclusive(true); nothingSelected->hide(); // a convenient button for when no button is checked in the group m_rotationCenterButtons->addButton(nothingSelected, 9); // initialize values for free transform sliders - shearXBox->setSuffix(i18n(" px")); - shearYBox->setSuffix(i18n(" px")); - shearXBox->setRange(-5.0, 5.0, 2); - shearYBox->setRange(-5.0, 5.0, 2); - shearXBox->setSingleStep(0.01); - shearYBox->setSingleStep(0.01); + shearXBox->setSuffix(QChar(Qt::Key_Percent)); + shearYBox->setSuffix(QChar(Qt::Key_Percent)); + shearXBox->setRange(-500, 500, 2); + shearYBox->setRange(-500, 500, 2); + shearXBox->setSingleStep(1); + shearYBox->setSingleStep(1); shearXBox->setValue(0.0); shearYBox->setValue(0.0); translateXBox->setSuffix(i18n(" px")); translateYBox->setSuffix(i18n(" px")); translateXBox->setRange(-10000, 10000); translateYBox->setRange(-10000, 10000); scaleXBox->setRange(-10000, 10000); scaleYBox->setRange(-10000, 10000); scaleXBox->setValue(100.0); scaleYBox->setValue(100.0); m_scaleRatio = 1.0; aXBox->setSuffix(QChar(Qt::Key_degree)); aYBox->setSuffix(QChar(Qt::Key_degree)); aZBox->setSuffix(QChar(Qt::Key_degree)); aXBox->setRange(0.0, 360.0, 2); aYBox->setRange(0.0, 360.0, 2); aZBox->setRange(0.0, 360.0, 2); aXBox->setValue(0.0); aYBox->setValue(0.0); aZBox->setValue(0.0); aXBox->setSingleStep(1.0); aYBox->setSingleStep(1.0); aZBox->setSingleStep(1.0); connect(m_rotationCenterButtons, SIGNAL(buttonPressed(int)), this, SLOT(slotRotationCenterChanged(int))); connect(btnTransformAroundPivotPoint, SIGNAL(clicked(bool)), this, SLOT(slotTransformAroundRotationCenter(bool))); // Init Free Transform Values connect(scaleXBox, SIGNAL(valueChanged(int)), this, SLOT(slotSetScaleX(int))); connect(scaleYBox, SIGNAL(valueChanged(int)), this, SLOT(slotSetScaleY(int))); connect(shearXBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetShearX(qreal))); connect(shearYBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetShearY(qreal))); connect(translateXBox, SIGNAL(valueChanged(int)), this, SLOT(slotSetTranslateX(int))); connect(translateYBox, SIGNAL(valueChanged(int)), this, SLOT(slotSetTranslateY(int))); connect(aXBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetAX(qreal))); connect(aYBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetAY(qreal))); connect(aZBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetAZ(qreal))); connect(aspectButton, SIGNAL(keepAspectRatioChanged(bool)), this, SLOT(slotSetKeepAspectRatio(bool))); connect(flipXButton, SIGNAL(clicked(bool)), this, SLOT(slotFlipX())); connect(flipYButton, SIGNAL(clicked(bool)), this, SLOT(slotFlipY())); connect(rotateCWButton, SIGNAL(clicked(bool)), this, SLOT(slotRotateCW())); connect(rotateCCWButton, SIGNAL(clicked(bool)), this, SLOT(slotRotateCCW())); // toggle visibility of different free buttons connect(freeMoveRadioButton, SIGNAL(clicked(bool)), SLOT(slotTransformAreaVisible(bool))); connect(freeRotationRadioButton, SIGNAL(clicked(bool)), SLOT(slotTransformAreaVisible(bool))); connect(freeScaleRadioButton, SIGNAL(clicked(bool)), SLOT(slotTransformAreaVisible(bool))); connect(freeShearRadioButton, SIGNAL(clicked(bool)), SLOT(slotTransformAreaVisible(bool))); // only first group for free transform rotationGroup->hide(); moveGroup->show(); scaleGroup->hide(); shearGroup->hide(); // Init Warp Transform Values alphaBox->setSingleStep(0.1); alphaBox->setRange(0, 10, 1); connect(alphaBox, SIGNAL(valueChanged(qreal)), this, SLOT(slotSetWarpAlpha(qreal))); connect(densityBox, SIGNAL(valueChanged(int)), this, SLOT(slotSetWarpDensity(int))); connect(defaultRadioButton, SIGNAL(clicked(bool)), this, SLOT(slotWarpDefaultPointsButtonClicked(bool))); connect(customRadioButton, SIGNAL(clicked(bool)), this, SLOT(slotWarpCustomPointsButtonClicked(bool))); connect(lockUnlockPointsButton, SIGNAL(clicked()), this, SLOT(slotWarpLockPointsButtonClicked())); connect(resetPointsButton, SIGNAL(clicked()), this, SLOT(slotWarpResetPointsButtonClicked())); // Init Cage Transform Values cageTransformButtonGroup->setId(cageAddEditRadio, 0); // we need to set manually since Qt Designer generates negative by default cageTransformButtonGroup->setId(cageDeformRadio, 1); connect(cageTransformButtonGroup, SIGNAL(buttonClicked(int)), this, SLOT(slotCageOptionsChanged(int))); // Init Liquify Transform Values liquifySizeSlider->setRange(KisLiquifyProperties::minSize(), KisLiquifyProperties::maxSize(), 2); liquifySizeSlider->setExponentRatio(4); liquifySizeSlider->setValue(60.0); connect(liquifySizeSlider, SIGNAL(valueChanged(qreal)), this, SLOT(liquifySizeChanged(qreal))); liquifySizeSlider->setToolTip(i18nc("@info:tooltip", "Size of the deformation brush")); liquifyAmountSlider->setRange(0.0, 1.0, 2); liquifyAmountSlider->setValue(0.05); connect(liquifyAmountSlider, SIGNAL(valueChanged(qreal)), this, SLOT(liquifyAmountChanged(qreal))); liquifyAmountSlider->setToolTip(i18nc("@info:tooltip", "Amount of the deformation you get")); liquifyFlowSlider->setRange(0.0, 1.0, 2); liquifyFlowSlider->setValue(1.0); connect(liquifyFlowSlider, SIGNAL(valueChanged(qreal)), this, SLOT(liquifyFlowChanged(qreal))); liquifyFlowSlider->setToolTip(i18nc("@info:tooltip", "When in non-buildup mode, shows how fast the deformation limit is reached.")); buidupModeComboBox->setCurrentIndex(0); // set to build-up mode by default connect(buidupModeComboBox, SIGNAL(currentIndexChanged(int)), this, SLOT(liquifyBuildUpChanged(int))); buidupModeComboBox->setToolTip("

" + i18nc("@info:tooltip", "Switch between Build Up and Wash mode of painting. Build Up mode adds deformations one on top of the other without any limits. Wash mode gradually deforms the piece to the selected deformation level.") + "

"); liquifySpacingSlider->setRange(0.0, 3.0, 2); liquifySizeSlider->setExponentRatio(3); liquifySpacingSlider->setSingleStep(0.01); liquifySpacingSlider->setValue(0.2); connect(liquifySpacingSlider, SIGNAL(valueChanged(qreal)), this, SLOT(liquifySpacingChanged(qreal))); liquifySpacingSlider->setToolTip(i18nc("@info:tooltip", "Space between two sequential applications of the deformation")); liquifySizePressureBox->setChecked(true); connect(liquifySizePressureBox, SIGNAL(toggled(bool)), this, SLOT(liquifySizePressureChanged(bool))); liquifySizePressureBox->setToolTip(i18nc("@info:tooltip", "Scale Size value according to current stylus pressure")); liquifyAmountPressureBox->setChecked(true); connect(liquifyAmountPressureBox, SIGNAL(toggled(bool)), this, SLOT(liquifyAmountPressureChanged(bool))); liquifyAmountPressureBox->setToolTip(i18nc("@info:tooltip", "Scale Amount value according to current stylus pressure")); liquifyReverseDirectionChk->setChecked(false); connect(liquifyReverseDirectionChk, SIGNAL(toggled(bool)), this, SLOT(liquifyReverseDirectionChanged(bool))); liquifyReverseDirectionChk->setToolTip(i18nc("@info:tooltip", "Reverse direction of the current deformation tool")); KisSignalMapper *liquifyModeMapper = new KisSignalMapper(this); connect(liquifyMove, SIGNAL(toggled(bool)), liquifyModeMapper, SLOT(map())); connect(liquifyScale, SIGNAL(toggled(bool)), liquifyModeMapper, SLOT(map())); connect(liquifyRotate, SIGNAL(toggled(bool)), liquifyModeMapper, SLOT(map())); connect(liquifyOffset, SIGNAL(toggled(bool)), liquifyModeMapper, SLOT(map())); connect(liquifyUndo, SIGNAL(toggled(bool)), liquifyModeMapper, SLOT(map())); liquifyModeMapper->setMapping(liquifyMove, (int)KisLiquifyProperties::MOVE); liquifyModeMapper->setMapping(liquifyScale, (int)KisLiquifyProperties::SCALE); liquifyModeMapper->setMapping(liquifyRotate, (int)KisLiquifyProperties::ROTATE); liquifyModeMapper->setMapping(liquifyOffset, (int)KisLiquifyProperties::OFFSET); liquifyModeMapper->setMapping(liquifyUndo, (int)KisLiquifyProperties::UNDO); connect(liquifyModeMapper, SIGNAL(mapped(int)), SLOT(slotLiquifyModeChanged(int))); liquifyMove->setToolTip(i18nc("@info:tooltip", "Move: drag the image along the brush stroke")); liquifyScale->setToolTip(i18nc("@info:tooltip", "Scale: grow/shrink image under cursor")); liquifyRotate->setToolTip(i18nc("@info:tooltip", "Rotate: twirl image under cursor")); liquifyOffset->setToolTip(i18nc("@info:tooltip", "Offset: shift the image to the right of the stroke direction")); liquifyUndo->setToolTip(i18nc("@info:tooltip", "Undo: erase actions of other tools")); // Connect all edit boxes to the Editing Finished signal connect(densityBox, SIGNAL(editingFinished()), this, SLOT(notifyEditingFinished())); // Connect other widget (not having editingFinished signal) to // the same slot. From Qt 4.6 onwards the sequence of the signal // delivery is definite. connect(cmbFilter, SIGNAL(activated(KoID)), this, SLOT(notifyEditingFinished())); connect(cmbWarpType, SIGNAL(currentIndexChanged(int)), this, SLOT(notifyEditingFinished())); connect(m_rotationCenterButtons, SIGNAL(buttonPressed(int)), this, SLOT(notifyEditingFinished())); connect(aspectButton, SIGNAL(keepAspectRatioChanged(bool)), this, SLOT(notifyEditingFinished())); connect(lockUnlockPointsButton, SIGNAL(clicked()), this, SLOT(notifyEditingFinished())); connect(resetPointsButton, SIGNAL(clicked()), this, SLOT(notifyEditingFinished())); connect(defaultRadioButton, SIGNAL(clicked(bool)), this, SLOT(notifyEditingFinished())); connect(customRadioButton, SIGNAL(clicked(bool)), this, SLOT(notifyEditingFinished())); // Liquify // // liquify brush options do not affect the image directly and are not // saved to undo, so we don't emit notifyEditingFinished() for them // Connect Apply/Reset buttons connect(buttonBox, SIGNAL(clicked(QAbstractButton*)), this, SLOT(slotButtonBoxClicked(QAbstractButton*))); // Mode switch buttons connect(freeTransformButton, SIGNAL(clicked(bool)), this, SLOT(slotSetFreeTransformModeButtonClicked(bool))); connect(warpButton, SIGNAL(clicked(bool)), this, SLOT(slotSetWarpModeButtonClicked(bool))); connect(cageButton, SIGNAL(clicked(bool)), this, SLOT(slotSetCageModeButtonClicked(bool))); connect(perspectiveTransformButton, SIGNAL(clicked(bool)), this, SLOT(slotSetPerspectiveModeButtonClicked(bool))); connect(liquifyButton, SIGNAL(clicked(bool)), this, SLOT(slotSetLiquifyModeButtonClicked(bool))); tooBigLabelWidget->hide(); connect(canvas->viewManager()->mainWindow(), SIGNAL(themeChanged()), SLOT(slotUpdateIcons()), Qt::UniqueConnection); slotUpdateIcons(); } void KisToolTransformConfigWidget::slotUpdateIcons() { freeTransformButton->setIcon(KisIconUtils::loadIcon("transform_icons_main")); warpButton->setIcon(KisIconUtils::loadIcon("transform_icons_warp")); cageButton->setIcon(KisIconUtils::loadIcon("transform_icons_cage")); perspectiveTransformButton->setIcon(KisIconUtils::loadIcon("transform_icons_perspective")); liquifyButton->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_main")); liquifyMove->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_move")); liquifyScale->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_resize")); liquifyRotate->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_rotate")); liquifyOffset->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_offset")); liquifyUndo->setIcon(KisIconUtils::loadIcon("transform_icons_liquify_erase")); middleRightButton->setIcon(KisIconUtils::loadIcon("arrow-right")); topRightButton->setIcon(KisIconUtils::loadIcon("arrow-topright")); middleTopButton->setIcon(KisIconUtils::loadIcon("arrow-up")); topLeftButton->setIcon(KisIconUtils::loadIcon("arrow-topleft")); middleLeftButton->setIcon(KisIconUtils::loadIcon("arrow-left")); bottomLeftButton->setIcon(KisIconUtils::loadIcon("arrow-downleft")); middleBottomButton->setIcon(KisIconUtils::loadIcon("arrow-down")); bottomRightButton->setIcon(KisIconUtils::loadIcon("arrow-downright")); btnTransformAroundPivotPoint->setIcon(KisIconUtils::loadIcon("pivot-point")); // pressure icons liquifySizePressureBox->setIcon(KisIconUtils::loadIcon("transform_icons_penPressure")); liquifyAmountPressureBox->setIcon(KisIconUtils::loadIcon("transform_icons_penPressure")); } double KisToolTransformConfigWidget::radianToDegree(double rad) { double piX2 = 2 * M_PI; if (rad < 0 || rad >= piX2) { rad = fmod(rad, piX2); if (rad < 0) { rad += piX2; } } return (rad * 360. / piX2); } double KisToolTransformConfigWidget::degreeToRadian(double degree) { if (degree < 0. || degree >= 360.) { degree = fmod(degree, 360.); if (degree < 0) degree += 360.; } return (degree * M_PI / 180.); } void KisToolTransformConfigWidget::updateLiquifyControls() { blockUiSlots(); ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); const bool useWashMode = props->useWashMode(); liquifySizeSlider->setValue(props->size()); liquifyAmountSlider->setValue(props->amount()); liquifyFlowSlider->setValue(props->flow()); buidupModeComboBox->setCurrentIndex(useWashMode); liquifySpacingSlider->setValue(props->spacing()); liquifySizePressureBox->setChecked(props->sizeHasPressure()); liquifyAmountPressureBox->setChecked(props->amountHasPressure()); liquifyReverseDirectionChk->setChecked(props->reverseDirection()); KisLiquifyProperties::LiquifyMode mode = static_cast(props->mode()); bool canInverseDirection = mode != KisLiquifyProperties::UNDO; bool canUseWashMode = mode != KisLiquifyProperties::UNDO; liquifyReverseDirectionChk->setEnabled(canInverseDirection); liquifyFlowSlider->setEnabled(canUseWashMode && useWashMode); buidupModeComboBox->setEnabled(canUseWashMode); const qreal maxAmount = canUseWashMode ? 5.0 : 1.0; liquifyAmountSlider->setRange(0.0, maxAmount, 2); unblockUiSlots(); } void KisToolTransformConfigWidget::slotLiquifyModeChanged(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); KisLiquifyProperties::LiquifyMode mode = static_cast(value); if (mode == props->mode()) return; props->setMode(mode); props->loadMode(); updateLiquifyControls(); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifySizeChanged(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setSize(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifyAmountChanged(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setAmount(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifyFlowChanged(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setFlow(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifyBuildUpChanged(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setUseWashMode(value); // 0 == build up mode / 1 == wash mode notifyConfigChanged(); // we need to enable/disable flow slider updateLiquifyControls(); } void KisToolTransformConfigWidget::liquifySpacingChanged(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setSpacing(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifySizePressureChanged(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setSizeHasPressure(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifyAmountPressureChanged(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setAmountHasPressure(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::liquifyReverseDirectionChanged(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); KisLiquifyProperties *props = config->liquifyProperties(); props->setReverseDirection(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::updateConfig(const ToolTransformArgs &config) { blockUiSlots(); if (config.mode() == ToolTransformArgs::FREE_TRANSFORM || config.mode() == ToolTransformArgs::PERSPECTIVE_4POINT) { quickTransformGroup->setEnabled(config.mode() == ToolTransformArgs::FREE_TRANSFORM); stackedWidget->setCurrentIndex(0); bool freeTransformIsActive = config.mode() == ToolTransformArgs::FREE_TRANSFORM; if (freeTransformIsActive) { freeTransformButton->setChecked(true); } else { perspectiveTransformButton->setChecked(true); } aXBox->setEnabled(freeTransformIsActive); aYBox->setEnabled(freeTransformIsActive); aZBox->setEnabled(freeTransformIsActive); freeRotationRadioButton->setEnabled(freeTransformIsActive); scaleXBox->setValue(config.scaleX() * 100.); scaleYBox->setValue(config.scaleY() * 100.); - shearXBox->setValue(config.shearX()); - shearYBox->setValue(config.shearY()); + shearXBox->setValue(config.shearX() * 100.); + shearYBox->setValue(config.shearY() * 100.); const QPointF anchorPoint = config.originalCenter() + config.rotationCenterOffset(); const KisTransformUtils::MatricesPack m(config); const QPointF anchorPointView = m.finalTransform().map(anchorPoint); translateXBox->setValue(anchorPointView.x()); translateYBox->setValue(anchorPointView.y()); aXBox->setValue(radianToDegree(config.aX())); aYBox->setValue(radianToDegree(config.aY())); aZBox->setValue(radianToDegree(config.aZ())); aspectButton->setKeepAspectRatio(config.keepAspectRatio()); cmbFilter->setCurrent(config.filterId()); QPointF pt = m_transaction->currentConfig()->rotationCenterOffset(); pt.rx() /= m_transaction->originalHalfWidth(); pt.ry() /= m_transaction->originalHalfHeight(); for (int i = 0; i < 9; i++) { if (qFuzzyCompare(m_handleDir[i].x(), pt.x()) && qFuzzyCompare(m_handleDir[i].y(), pt.y())) { m_rotationCenterButtons->button(i)->setChecked(true); break; } } btnTransformAroundPivotPoint->setChecked(config.transformAroundRotationCenter()); } else if (config.mode() == ToolTransformArgs::WARP) { stackedWidget->setCurrentIndex(1); warpButton->setChecked(true); if (config.defaultPoints()) { densityBox->setValue(std::sqrt(config.numPoints())); } cmbWarpType->setCurrentIndex((int)config.warpType()); defaultRadioButton->setChecked(config.defaultPoints()); customRadioButton->setChecked(!config.defaultPoints()); densityBox->setEnabled(config.defaultPoints()); customWarpWidget->setEnabled(!config.defaultPoints()); updateLockPointsButtonCaption(); } else if (config.mode() == ToolTransformArgs::CAGE) { // default UI options resetUIOptions(); // we need at least 3 point before we can start actively deforming if (config.origPoints().size() >= 3) { cageTransformDirections->setText(i18n("Switch between editing and deforming cage")); cageAddEditRadio->setVisible(true); cageDeformRadio->setVisible(true); // update to correct radio button if (config.isEditingTransformPoints()) cageAddEditRadio->setChecked(true); else cageDeformRadio->setChecked(true); changeGranularity->setCurrentIndex(log2(config.pixelPrecision()) - 2); granularityPreview->setCurrentIndex(log2(config.previewPixelPrecision()) - 2); } } else if (config.mode() == ToolTransformArgs::LIQUIFY) { stackedWidget->setCurrentIndex(3); liquifyButton->setChecked(true); const KisLiquifyProperties *props = config.liquifyProperties(); switch (props->mode()) { case KisLiquifyProperties::MOVE: liquifyMove->setChecked(true); break; case KisLiquifyProperties::SCALE: liquifyScale->setChecked(true); break; case KisLiquifyProperties::ROTATE: liquifyRotate->setChecked(true); break; case KisLiquifyProperties::OFFSET: liquifyOffset->setChecked(true); break; case KisLiquifyProperties::UNDO: liquifyUndo->setChecked(true); break; case KisLiquifyProperties::N_MODES: qFatal("Unsupported mode"); } updateLiquifyControls(); } unblockUiSlots(); } void KisToolTransformConfigWidget::updateLockPointsButtonCaption() { ToolTransformArgs *config = m_transaction->currentConfig(); if (config->isEditingTransformPoints()) { lockUnlockPointsButton->setText(i18n("Lock Points")); } else { lockUnlockPointsButton->setText(i18n("Unlock Points")); } } void KisToolTransformConfigWidget::setApplyResetDisabled(bool disabled) { QAbstractButton *applyButton = buttonBox->button(QDialogButtonBox::Apply); QAbstractButton *resetButton = buttonBox->button(QDialogButtonBox::Reset); Q_ASSERT(applyButton); Q_ASSERT(resetButton); applyButton->setDisabled(disabled); resetButton->setDisabled(disabled); } void KisToolTransformConfigWidget::resetRotationCenterButtons() { int checkedId = m_rotationCenterButtons->checkedId(); if (checkedId >= 0 && checkedId <= 8) { // uncheck the current checked button m_rotationCenterButtons->button(9)->setChecked(true); } } bool KisToolTransformConfigWidget::workRecursively() const { return chkWorkRecursively->isChecked(); } void KisToolTransformConfigWidget::setTooBigLabelVisible(bool value) { tooBigLabelWidget->setVisible(value); } void KisToolTransformConfigWidget::blockNotifications() { m_notificationsBlocked++; } void KisToolTransformConfigWidget::unblockNotifications() { m_notificationsBlocked--; } void KisToolTransformConfigWidget::notifyConfigChanged() { if (!m_notificationsBlocked) { emit sigConfigChanged(); } m_configChanged = true; } void KisToolTransformConfigWidget::blockUiSlots() { m_uiSlotsBlocked++; } void KisToolTransformConfigWidget::unblockUiSlots() { m_uiSlotsBlocked--; } void KisToolTransformConfigWidget::notifyEditingFinished() { if (m_uiSlotsBlocked || m_notificationsBlocked || !m_configChanged) return; emit sigEditingFinished(); m_configChanged = false; } void KisToolTransformConfigWidget::resetUIOptions() { // reset tool states since we are done (probably can encapsulate this later) ToolTransformArgs *config = m_transaction->currentConfig(); if (config->mode() == ToolTransformArgs::CAGE) { cageAddEditRadio->setVisible(false); cageAddEditRadio->setChecked(true); cageDeformRadio->setVisible(false); cageTransformDirections->setText(i18n("Create 3 points on the canvas to begin")); // ensure we are on the right options view stackedWidget->setCurrentIndex(2); } } void KisToolTransformConfigWidget::slotButtonBoxClicked(QAbstractButton *button) { QAbstractButton *applyButton = buttonBox->button(QDialogButtonBox::Apply); QAbstractButton *resetButton = buttonBox->button(QDialogButtonBox::Reset); resetUIOptions(); if (button == applyButton) { emit sigApplyTransform(); } else if (button == resetButton) { emit sigResetTransform(); } } void KisToolTransformConfigWidget::slotSetFreeTransformModeButtonClicked(bool value) { if (!value) return; lblTransformType->setText(freeTransformButton->toolTip()); ToolTransformArgs *config = m_transaction->currentConfig(); config->setMode(ToolTransformArgs::FREE_TRANSFORM); emit sigResetTransform(); } void KisToolTransformConfigWidget::slotSetWarpModeButtonClicked(bool value) { if (!value) return; lblTransformType->setText(warpButton->toolTip()); ToolTransformArgs *config = m_transaction->currentConfig(); config->setMode(ToolTransformArgs::WARP); config->setWarpCalculation(KisWarpTransformWorker::WarpCalculation::GRID); emit sigResetTransform(); } void KisToolTransformConfigWidget::slotSetCageModeButtonClicked(bool value) { if (!value) return; lblTransformType->setText(cageButton->toolTip()); ToolTransformArgs *config = m_transaction->currentConfig(); config->setMode(ToolTransformArgs::CAGE); emit sigResetTransform(); } void KisToolTransformConfigWidget::slotSetLiquifyModeButtonClicked(bool value) { if (!value) return; lblTransformType->setText(liquifyButton->toolTip()); ToolTransformArgs *config = m_transaction->currentConfig(); config->setMode(ToolTransformArgs::LIQUIFY); emit sigResetTransform(); } void KisToolTransformConfigWidget::slotSetPerspectiveModeButtonClicked(bool value) { if (!value) return; lblTransformType->setText(perspectiveTransformButton->toolTip()); ToolTransformArgs *config = m_transaction->currentConfig(); config->setMode(ToolTransformArgs::PERSPECTIVE_4POINT); emit sigResetTransform(); } void KisToolTransformConfigWidget::slotFilterChanged(const KoID &filterId) { ToolTransformArgs *config = m_transaction->currentConfig(); config->setFilterId(filterId.id()); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotRotationCenterChanged(int index) { if (m_uiSlotsBlocked) return; if (index >= 0 && index <= 8) { ToolTransformArgs *config = m_transaction->currentConfig(); double i = m_handleDir[index].x(); double j = m_handleDir[index].y(); config->setRotationCenterOffset(QPointF(i * m_transaction->originalHalfWidth(), j * m_transaction->originalHalfHeight())); notifyConfigChanged(); updateConfig(*config); } } void KisToolTransformConfigWidget::slotTransformAroundRotationCenter(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); config->setTransformAroundRotationCenter(value); notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetScaleX(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleX(value / 100.); } if (config->keepAspectRatio()) { blockNotifications(); int calculatedValue = int( value/ m_scaleRatio ); scaleYBox->blockSignals(true); scaleYBox->setValue(calculatedValue); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleY(calculatedValue / 100.); } scaleYBox->blockSignals(false); unblockNotifications(); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetScaleY(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleY(value / 100.); } if (config->keepAspectRatio()) { blockNotifications(); int calculatedValue = int(m_scaleRatio * value); scaleXBox->blockSignals(true); scaleXBox->setValue(calculatedValue); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleX(calculatedValue / 100.); } scaleXBox->blockSignals(false); unblockNotifications(); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetShearX(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); - config->setShearX((double)value); + config->setShearX((double)value / 100.); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetShearY(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); - config->setShearY((double)value); + config->setShearY((double)value / 100.); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetTranslateX(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); const QPointF anchorPoint = config->originalCenter() + config->rotationCenterOffset(); const KisTransformUtils::MatricesPack m(*config); const QPointF anchorPointView = m.finalTransform().map(anchorPoint); const QPointF newAnchorPointView(value, anchorPointView.y()); config->setTransformedCenter(config->transformedCenter() + newAnchorPointView - anchorPointView); translateXBox->setValue(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotSetTranslateY(int value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); const QPointF anchorPoint = config->originalCenter() + config->rotationCenterOffset(); const KisTransformUtils::MatricesPack m(*config); const QPointF anchorPointView = m.finalTransform().map(anchorPoint); const QPointF newAnchorPointView(anchorPointView.x(), value); config->setTransformedCenter(config->transformedCenter() + newAnchorPointView - anchorPointView); translateYBox->setValue(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotSetAX(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setAX(degreeToRadian((double)value)); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetAY(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setAY(degreeToRadian((double)value)); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetAZ(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setAZ(degreeToRadian((double)value)); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotFlipX() { ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleX(config->scaleX() * -1); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotFlipY() { ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setScaleY(config->scaleY() * -1); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotRotateCW() { ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setAZ(normalizeAngle(config->aZ() + M_PI_2)); } notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotRotateCCW() { ToolTransformArgs *config = m_transaction->currentConfig(); { KisTransformUtils::AnchorHolder keeper(config->transformAroundRotationCenter(), config); config->setAZ(normalizeAngle(config->aZ() - M_PI_2)); } notifyConfigChanged(); notifyEditingFinished(); } // change free transform setting we want to alter (all radio buttons call this) void KisToolTransformConfigWidget::slotTransformAreaVisible(bool value) { Q_UNUSED(value); //QCheckBox sender = (QCheckBox)(*)(QObject::sender()); QString senderName = QObject::sender()->objectName(); // only show setting with what we have selected rotationGroup->hide(); shearGroup->hide(); scaleGroup->hide(); moveGroup->hide(); if ("freeMoveRadioButton" == senderName) { moveGroup->show(); } else if ("freeShearRadioButton" == senderName) { shearGroup->show(); } else if ("freeScaleRadioButton" == senderName) { scaleGroup->show(); } else { rotationGroup->show(); } } void KisToolTransformConfigWidget::slotSetKeepAspectRatio(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); config->setKeepAspectRatio(value); if (value) { blockNotifications(); int tmpXScaleBox = scaleXBox->value(); int tmpYScaleBox = scaleYBox->value(); m_scaleRatio = (tmpXScaleBox / (double) tmpYScaleBox); unblockNotifications(); } notifyConfigChanged(); } void KisToolTransformConfigWidget::slotSetWarpAlpha(qreal value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); config->setAlpha((double)value); notifyConfigChanged(); notifyEditingFinished(); } void KisToolTransformConfigWidget::slotSetWarpDensity(int value) { if (m_uiSlotsBlocked) return; setDefaultWarpPoints(value); } void KisToolTransformConfigWidget::setDefaultWarpPoints(int pointsPerLine) { ToolTransformArgs *config = m_transaction->currentConfig(); KisTransformUtils::setDefaultWarpPoints(pointsPerLine, m_transaction, config); notifyConfigChanged(); } void KisToolTransformConfigWidget::activateCustomWarpPoints(bool enabled) { ToolTransformArgs *config = m_transaction->currentConfig(); densityBox->setEnabled(!enabled); customWarpWidget->setEnabled(enabled); if (!enabled) { config->setEditingTransformPoints(false); setDefaultWarpPoints(densityBox->value()); config->setWarpCalculation(KisWarpTransformWorker::WarpCalculation::GRID); } else { config->setEditingTransformPoints(true); config->setWarpCalculation(KisWarpTransformWorker::WarpCalculation::DRAW); setDefaultWarpPoints(0); } updateLockPointsButtonCaption(); } void KisToolTransformConfigWidget::slotWarpDefaultPointsButtonClicked(bool value) { if (m_uiSlotsBlocked) return; activateCustomWarpPoints(!value); } void KisToolTransformConfigWidget::slotWarpCustomPointsButtonClicked(bool value) { if (m_uiSlotsBlocked) return; activateCustomWarpPoints(value); } void KisToolTransformConfigWidget::slotWarpResetPointsButtonClicked() { if (m_uiSlotsBlocked) return; activateCustomWarpPoints(true); } void KisToolTransformConfigWidget::slotWarpLockPointsButtonClicked() { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); config->setEditingTransformPoints(!config->isEditingTransformPoints()); if (config->isEditingTransformPoints()) { // reinit the transf points to their original value ToolTransformArgs *config = m_transaction->currentConfig(); int nbPoints = config->origPoints().size(); for (int i = 0; i < nbPoints; ++i) { config->transfPoint(i) = config->origPoint(i); } } updateLockPointsButtonCaption(); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotWarpTypeChanged(int index) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); switch (index) { case KisWarpTransformWorker::AFFINE_TRANSFORM: case KisWarpTransformWorker::SIMILITUDE_TRANSFORM: case KisWarpTransformWorker::RIGID_TRANSFORM: config->setWarpType((KisWarpTransformWorker::WarpType)index); break; default: config->setWarpType(KisWarpTransformWorker::RIGID_TRANSFORM); break; } notifyConfigChanged(); } void KisToolTransformConfigWidget::slotCageOptionsChanged(int value) { if ( value == 0) { slotEditCagePoints(true); } else { slotEditCagePoints(false); } notifyEditingFinished(); } void KisToolTransformConfigWidget::slotEditCagePoints(bool value) { if (m_uiSlotsBlocked) return; ToolTransformArgs *config = m_transaction->currentConfig(); config->refTransformedPoints() = config->origPoints(); config->setEditingTransformPoints(value); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotGranularityChanged(QString value) { if (m_uiSlotsBlocked) return; KIS_SAFE_ASSERT_RECOVER_RETURN(value.toInt() > 1); ToolTransformArgs *config = m_transaction->currentConfig(); config->setPixelPrecision(value.toInt()); notifyConfigChanged(); } void KisToolTransformConfigWidget::slotPreviewGranularityChanged(QString value) { if (m_uiSlotsBlocked) return; KIS_SAFE_ASSERT_RECOVER_RETURN(value.toInt() > 1); ToolTransformArgs *config = m_transaction->currentConfig(); config->setPreviewPixelPrecision(value.toInt()); notifyConfigChanged(); }