{ lib , stdenv , fetchurl , fetchFromGitHub , fetchpatch , fetchzip , cmake , lz4 , bzip2 , m4 , hdf5 , gsl , unzip , makeWrapper , meson , git , ninja , eigen , pkg-config , wrapGAppsHook , flex , bison , doxygen , opencl-headers , ncurses , msgpack , fftw , zeromq , ocl-icd , gtk3 , gdk-pixbuf , argp-standalone , memorymappingHook , withGui ? true , withBitshuffle ? true }: let libccp4 = stdenv.mkDerivation rec { pname = "libccp4"; version = "8.0.0"; src = fetchurl { url = "https://ftp.ccp4.ac.uk/opensource/${pname}-${version}.tar.gz"; hash = "sha256-y4E66GYSoIZjKd6rfO6W6sVz2BvlskA0HUD5rVMi/y0="; }; nativeBuildInputs = [ meson ninja ]; buildInputs = [ hdf5 gsl ]; configureFlags = [ "FFLAGS=-fallow-argument-mismatch" ]; # libccp4 tries to read syminfo.lib by looking at an environment variable, which hinders reproducibility. # We hard-code this by providing a little patch and then passing the absolute path to syminfo.lib as a # preprocessor flag. env.NIX_CFLAGS_COMPILE = "-DNIX_PROVIDED_SYMOP_FILE=\"${placeholder "out"}/share/ccp4/syminfo.lib\""; patches = [ ./libccp4-use-hardcoded-syminfo-lib.patch ]; postPatch = let mesonPatch = fetchzip { url = "https://wrapdb.mesonbuild.com/v2/libccp4c_8.0.0-1/get_patch#somefile.zip"; hash = "sha256-ohskfKh+972Pl56KtwAeWwHtAaAFNpCzz5vZBAI/vdU="; }; in '' cp ${mesonPatch}/meson.build . ''; }; # This is the statically-linked, pre-built binary of mosflm. Compiling it ourselves turns out to be very difficult # since the build process is very hard-coded for a specific machine, architecture, and libraries. mosflm = let version = "7.4.0"; src = if stdenv.isDarwin then fetchurl { url = "https://www.mrc-lmb.cam.ac.uk/mosflm/mosflm/ver${builtins.replaceStrings [ "." ] [ "" ] version}/pre-built/mosflm-osx-64-noX11.zip"; sha256 = "1da5wimv3kl8bccp49j69vh8gi28cn7axg59lrmb38s68c618h7j"; } else fetchurl { url = "https://www.mrc-lmb.cam.ac.uk/mosflm/mosflm/ver${builtins.replaceStrings [ "." ] [ "" ] version}/pre-built/mosflm-linux-64-noX11.zip"; sha256 = "1rqh3nprxfmnyihllw31nb8i3wfhybmsic6y7z6wn4rafyv3w4fk"; }; mosflmBinary = if stdenv.isDarwin then "bin/mosflm" else "mosflm-linux-64-noX11"; in stdenv.mkDerivation rec { pname = "mosflm"; inherit version src; dontBuild = true; nativeBuildInputs = [ unzip makeWrapper ]; sourceRoot = "."; # mosflm statically links against its own libccp4, which as the syminfo.lib environment variable problem. # Here, we circumvent it by creating a little wrapper script that calls mosflm after setting the SYMINFO variable. installPhase = '' mkdir -p $out/bin cp ${mosflmBinary} $out/bin/mosflm-raw makeWrapper $out/bin/mosflm-raw $out/bin/mosflm --set SYMINFO ${libccp4}/share/syminfo.lib --add-flags -n ''; }; xgandalf = stdenv.mkDerivation rec { pname = "xgandalf"; version = "c6c5003ff1086e8c0fb5313660b4f02f3a3aab7b"; src = fetchurl { url = "https://gitlab.desy.de/thomas.white/${pname}/-/archive/${version}/${pname}-${version}.tar.gz"; hash = "sha256-/uZlBwAINSoYqgLQFTMz8rS1Rpadu79JkO6Bu/+Nx9E="; }; nativeBuildInputs = [ meson pkg-config ninja ]; buildInputs = [ eigen ]; }; pinkIndexer = stdenv.mkDerivation rec { pname = "pinkindexer"; version = "5d4e016941eb2a9e50a10df96ded7ff1e2464503"; src = fetchurl { url = "https://gitlab.desy.de/thomas.white/${pname}/-/archive/${version}/${pname}-${version}.tar.gz"; hash = "sha256-VnJOJJ247dNoBlos4Fu3GQBlAnTk9el+yZDRiicJtu0="; }; nativeBuildInputs = [ meson pkg-config ninja ]; buildInputs = [ eigen ]; }; fdip = stdenv.mkDerivation rec { pname = "fdip"; version = "5628fedddd79323b4b26df9b85e9543d83286d4c"; src = fetchurl { url = "https://gitlab.desy.de/thomas.white/fdip/-/archive/${version}/fdip-${version}.tar.gz"; hash = "sha256-EaihnW7p//ecgMn+KKlfmBeXrnAqs+HdhN+ovuSrtiQ="; }; nativeBuildInputs = [ meson ninja pkg-config ]; buildInputs = [ eigen ]; }; hdf5-external-filter-plugins = stdenv.mkDerivation rec { pname = "HDF5-External-Filter-Plugins"; version = "0.1.0"; src = fetchFromGitHub { owner = "nexusformat"; repo = pname; rev = "49e3b65eca772bca77af13ba047d8b577673afba"; hash = "sha256-bEzfWdZuHmb0PDzCqy8Dey4tLtq+4coO0sT0GzqrTYI="; }; patches = [ (fetchpatch { url = "https://github.com/spanezz/HDF5-External-Filter-Plugins/commit/6b337fe36da97a3ef72354393687ce3386c0709d.patch"; hash = "sha256-wnBEdL/MjEyRHPwaVtuhzY+DW1AFeaUQUmIXh+JaRHo="; }) ]; nativeBuildInputs = [ cmake ]; buildInputs = [ hdf5 lz4 bzip2 ]; cmakeFlags = [ "-DENABLE_BITSHUFFLE_PLUGIN=yes" "-DENABLE_LZ4_PLUGIN=yes" "-DENABLE_BZIP2_PLUGIN=yes" ]; }; in stdenv.mkDerivation rec { pname = "crystfel"; version = "0.10.2"; src = fetchurl { url = "https://www.desy.de/~twhite/${pname}/${pname}-${version}.tar.gz"; sha256 = "sha256-nCO9ndDKS54bVN9IhFBiCVNzqk7BsCljXFrOmlx+sP4="; }; nativeBuildInputs = [ meson pkg-config ninja flex bison doxygen opencl-headers makeWrapper ] ++ lib.optionals withGui [ wrapGAppsHook ]; buildInputs = [ hdf5 gsl ncurses msgpack fftw fdip zeromq ocl-icd libccp4 mosflm pinkIndexer xgandalf ] ++ lib.optionals withGui [ gtk3 gdk-pixbuf ] ++ lib.optionals stdenv.isDarwin [ argp-standalone ] ++ lib.optionals (stdenv.isDarwin && !stdenv.isAarch64) [ memorymappingHook ] ++ lib.optionals withBitshuffle [ hdf5-external-filter-plugins ]; patches = [ ./link-to-argp-standalone-if-needed.patch ./disable-fmemopen-on-aarch64-darwin.patch (fetchpatch { url = "https://gitlab.desy.de/thomas.white/crystfel/-/commit/3c54d59e1c13aaae716845fed2585770c3ca9d14.diff"; hash = "sha256-oaJNBQQn0c+z4p1pnW4osRJA2KdKiz4hWu7uzoKY7wc="; }) ]; # CrystFEL calls mosflm by searching PATH for it. We could've create a wrapper script that sets the PATH, but # we'd have to do that for every CrystFEL executable (indexamajig, crystfel, partialator). Better to just # hard-code mosflm's path once. postPatch = '' sed -i -e 's#execlp("mosflm"#execl("${mosflm}/bin/mosflm"#' libcrystfel/src/indexers/mosflm.c; ''; postInstall = lib.optionalString withBitshuffle '' for file in $out/bin/*; do wrapProgram $file --set HDF5_PLUGIN_PATH ${hdf5-external-filter-plugins}/lib/plugins done ''; meta = with lib; { description = "Data processing for serial crystallography"; longDescription = '' CrystFEL is a suite of programs for processing (and simulating) Bragg diffraction data from "serial crystallography" experiments, often (but not always) performed using an X-ray Free-Electron Laser. Compared to rotation data, some of the particular characteristics of such data which call for a specialised software suite are: - The sliced, rather than integrated, measurement of intensity data. Many, if not all reflections are partially integrated. - Many patterns (thousands) are required - high throughput is needed. - The crystal orientations in each pattern are random and uncorrelated. - Merging into lower symmetry point groups may require the resolution of indexing ambiguities.''; homepage = "https://www.desy.de/~twhite/crystfel/"; changelog = "https://www.desy.de/~twhite/crystfel/changes.html"; downloadPage = "https://www.desy.de/~twhite/crystfel/download.html"; license = licenses.gpl3Plus; maintainers = with maintainers; [ pmiddend ]; platforms = platforms.unix; }; }