# TODO(@Ericson2314): Remove `pkgs` param, which is only used for # `buildStackProject`, `justStaticExecutables` and `checkUnusedPackages` { pkgs, lib }: rec { /* This function takes a file like `hackage-packages.nix` and constructs a full package set out of that. */ makePackageSet = import ../make-package-set.nix; /* The function overrideCabal lets you alter the arguments to the mkDerivation function. Example: First, note how the aeson package is constructed in hackage-packages.nix: "aeson" = callPackage ({ mkDerivation, attoparsec, }: mkDerivation { pname = "aeson"; homepage = "https://github.com/bos/aeson"; }) The mkDerivation function of haskellPackages will take care of putting the homepage in the right place, in meta. > haskellPackages.aeson.meta.homepage "https://github.com/bos/aeson" > x = haskell.lib.compose.overrideCabal (old: { homepage = old.homepage + "#readme"; }) haskellPackages.aeson > x.meta.homepage "https://github.com/bos/aeson#readme" */ overrideCabal = f: drv: (drv.override (args: args // { mkDerivation = drv: (args.mkDerivation drv).override f; })) // { overrideScope = scope: overrideCabal f (drv.overrideScope scope); }; # : Map Name (Either Path VersionNumber) -> HaskellPackageOverrideSet # Given a set whose values are either paths or version strings, produces # a package override set (i.e. (self: super: { etc. })) that sets # the packages named in the input set to the corresponding versions packageSourceOverrides = overrides: self: super: pkgs.lib.mapAttrs (name: src: let isPath = x: builtins.substring 0 1 (toString x) == "/"; generateExprs = if isPath src then self.callCabal2nix else self.callHackage; in generateExprs name src {}) overrides; /* doCoverage modifies a haskell package to enable the generation and installation of a coverage report. See https://wiki.haskell.org/Haskell_program_coverage */ doCoverage = overrideCabal (drv: { doCoverage = true; }); /* dontCoverage modifies a haskell package to disable the generation and installation of a coverage report. */ dontCoverage = overrideCabal (drv: { doCoverage = false; }); /* doHaddock modifies a haskell package to enable the generation and installation of API documentation from code comments using the haddock tool. */ doHaddock = overrideCabal (drv: { doHaddock = true; }); /* dontHaddock modifies a haskell package to disable the generation and installation of API documentation from code comments using the haddock tool. */ dontHaddock = overrideCabal (drv: { doHaddock = false; }); /* doJailbreak enables the removal of version bounds from the cabal file. You may want to avoid this function. This is useful when a package reports that it can not be built due to version mismatches. In some cases, removing the version bounds entirely is an easy way to make a package build, but at the risk of breaking software in non-obvious ways now or in the future. Instead of jailbreaking, you can patch the cabal file. Note that jailbreaking at this time, doesn't lift bounds on conditional branches. https://github.com/peti/jailbreak-cabal/issues/7 has further details. */ doJailbreak = overrideCabal (drv: { jailbreak = true; }); /* dontJailbreak restores the use of the version bounds the check the use of dependencies in the package description. */ dontJailbreak = overrideCabal (drv: { jailbreak = false; }); /* doCheck enables dependency checking, compilation and execution of test suites listed in the package description file. */ doCheck = overrideCabal (drv: { doCheck = true; }); /* dontCheck disables dependency checking, compilation and execution of test suites listed in the package description file. */ dontCheck = overrideCabal (drv: { doCheck = false; }); /* doBenchmark enables dependency checking, compilation and execution for benchmarks listed in the package description file. */ doBenchmark = overrideCabal (drv: { doBenchmark = true; }); /* dontBenchmark disables dependency checking, compilation and execution for benchmarks listed in the package description file. */ dontBenchmark = overrideCabal (drv: { doBenchmark = false; }); /* doDistribute enables the distribution of binaries for the package via hydra. */ doDistribute = overrideCabal (drv: { # lib.platforms.all is the default value for platforms (since GHC can cross-compile) hydraPlatforms = lib.subtractLists (drv.badPlatforms or []) (drv.platforms or lib.platforms.all); }); /* dontDistribute disables the distribution of binaries for the package via hydra. */ dontDistribute = overrideCabal (drv: { hydraPlatforms = []; }); /* appendConfigureFlag adds a single argument that will be passed to the cabal configure command, after the arguments that have been defined in the initial declaration or previous overrides. Example: > haskell.lib.compose.appendConfigureFlag "--profiling-detail=all-functions" haskellPackages.servant */ appendConfigureFlag = x: appendConfigureFlags [x]; appendConfigureFlags = xs: overrideCabal (drv: { configureFlags = (drv.configureFlags or []) ++ xs; }); appendBuildFlag = x: overrideCabal (drv: { buildFlags = (drv.buildFlags or []) ++ [x]; }); appendBuildFlags = xs: overrideCabal (drv: { buildFlags = (drv.buildFlags or []) ++ xs; }); /* removeConfigureFlag drv x is a Haskell package like drv, but with all cabal configure arguments that are equal to x removed. > haskell.lib.compose.removeConfigureFlag "--verbose" haskellPackages.servant */ removeConfigureFlag = x: overrideCabal (drv: { configureFlags = lib.remove x (drv.configureFlags or []); }); addBuildTool = x: addBuildTools [x]; addBuildTools = xs: overrideCabal (drv: { buildTools = (drv.buildTools or []) ++ xs; }); addExtraLibrary = x: addExtraLibraries [x]; addExtraLibraries = xs: overrideCabal (drv: { extraLibraries = (drv.extraLibraries or []) ++ xs; }); addBuildDepend = x: addBuildDepends [x]; addBuildDepends = xs: overrideCabal (drv: { buildDepends = (drv.buildDepends or []) ++ xs; }); addTestToolDepend = x: addTestToolDepends [x]; addTestToolDepends = xs: overrideCabal (drv: { testToolDepends = (drv.testToolDepends or []) ++ xs; }); addPkgconfigDepend = x: addPkgconfigDepends [x]; addPkgconfigDepends = xs: overrideCabal (drv: { pkg-configDepends = (drv.pkg-configDepends or []) ++ xs; }); addSetupDepend = x: addSetupDepends [x]; addSetupDepends = xs: overrideCabal (drv: { setupHaskellDepends = (drv.setupHaskellDepends or []) ++ xs; }); enableCabalFlag = x: drv: appendConfigureFlag "-f${x}" (removeConfigureFlag "-f-${x}" drv); disableCabalFlag = x: drv: appendConfigureFlag "-f-${x}" (removeConfigureFlag "-f${x}" drv); markBroken = overrideCabal (drv: { broken = true; hydraPlatforms = []; }); unmarkBroken = overrideCabal (drv: { broken = false; }); markBrokenVersion = version: drv: assert drv.version == version; markBroken drv; markUnbroken = overrideCabal (drv: { broken = false; }); enableLibraryProfiling = overrideCabal (drv: { enableLibraryProfiling = true; }); disableLibraryProfiling = overrideCabal (drv: { enableLibraryProfiling = false; }); enableExecutableProfiling = overrideCabal (drv: { enableExecutableProfiling = true; }); disableExecutableProfiling = overrideCabal (drv: { enableExecutableProfiling = false; }); enableSharedExecutables = overrideCabal (drv: { enableSharedExecutables = true; }); disableSharedExecutables = overrideCabal (drv: { enableSharedExecutables = false; }); enableSharedLibraries = overrideCabal (drv: { enableSharedLibraries = true; }); disableSharedLibraries = overrideCabal (drv: { enableSharedLibraries = false; }); enableDeadCodeElimination = overrideCabal (drv: { enableDeadCodeElimination = true; }); disableDeadCodeElimination = overrideCabal (drv: { enableDeadCodeElimination = false; }); enableStaticLibraries = overrideCabal (drv: { enableStaticLibraries = true; }); disableStaticLibraries = overrideCabal (drv: { enableStaticLibraries = false; }); enableSeparateBinOutput = overrideCabal (drv: { enableSeparateBinOutput = true; }); appendPatch = x: appendPatches [x]; appendPatches = xs: overrideCabal (drv: { patches = (drv.patches or []) ++ xs; }); /* Set a specific build target instead of compiling all targets in the package. * For example, imagine we have a .cabal file with a library, and 2 executables "dev" and "server". * We can build only "server" and not wait on the compilation of "dev" by using setBuildTarget as follows: * * > setBuildTarget "server" (callCabal2nix "thePackageName" thePackageSrc {}) * */ setBuildTargets = xs: overrideCabal (drv: { buildTarget = lib.concatStringsSep " " xs; }); setBuildTarget = x: setBuildTargets [x]; doHyperlinkSource = overrideCabal (drv: { hyperlinkSource = true; }); dontHyperlinkSource = overrideCabal (drv: { hyperlinkSource = false; }); disableHardening = flags: overrideCabal (drv: { hardeningDisable = flags; }); /* Let Nix strip the binary files. * This removes debugging symbols. */ doStrip = overrideCabal (drv: { dontStrip = false; }); /* Stop Nix from stripping the binary files. * This keeps debugging symbols. */ dontStrip = overrideCabal (drv: { dontStrip = true; }); /* Useful for debugging segfaults with gdb. * This includes dontStrip. */ enableDWARFDebugging = drv: # -g: enables debugging symbols # --disable-*-stripping: tell GHC not to strip resulting binaries # dontStrip: see above appendConfigureFlag "--ghc-options=-g --disable-executable-stripping --disable-library-stripping" (dontStrip drv); /* Create a source distribution tarball like those found on hackage, instead of building the package. */ sdistTarball = pkg: lib.overrideDerivation pkg (drv: { name = "${drv.pname}-source-${drv.version}"; # Since we disable the haddock phase, we also need to override the # outputs since the separate doc output will not be produced. outputs = ["out"]; buildPhase = "./Setup sdist"; haddockPhase = ":"; checkPhase = ":"; installPhase = "install -D dist/${drv.pname}-*.tar.gz $out/${drv.pname}-${drv.version}.tar.gz"; fixupPhase = ":"; }); /* Create a documentation tarball suitable for uploading to Hackage instead of building the package. */ documentationTarball = pkg: pkgs.lib.overrideDerivation pkg (drv: { name = "${drv.name}-docs"; # Like sdistTarball, disable the "doc" output here. outputs = [ "out" ]; buildPhase = '' runHook preHaddock ./Setup haddock --for-hackage runHook postHaddock ''; haddockPhase = ":"; checkPhase = ":"; installPhase = '' runHook preInstall mkdir -p "$out" tar --format=ustar \ -czf "$out/${drv.name}-docs.tar.gz" \ -C dist/doc/html "${drv.name}-docs" runHook postInstall ''; }); /* Use the gold linker. It is a linker for ELF that is designed "to run as fast as possible on modern systems" */ linkWithGold = appendConfigureFlag "--ghc-option=-optl-fuse-ld=gold --ld-option=-fuse-ld=gold --with-ld=ld.gold"; /* link executables statically against haskell libs to reduce closure size */ justStaticExecutables = overrideCabal (drv: { enableSharedExecutables = false; enableLibraryProfiling = false; isLibrary = false; doHaddock = false; postFixup = drv.postFixup or "" + '' # Remove every directory which could have links to other store paths. rm -rf $out/lib $out/nix-support $out/share/doc ''; }); /* Build a source distribution tarball instead of using the source files directly. The effect is that the package is built as if it were published on hackage. This can be used as a test for the source distribution, assuming the build fails when packaging mistakes are in the cabal file. A faster implementation using `cabal-install` is available as `buildFromCabalSdist` in your Haskell package set. */ buildFromSdist = pkg: overrideCabal (drv: { src = "${sdistTarball pkg}/${pkg.pname}-${pkg.version}.tar.gz"; # Revising and jailbreaking the cabal file has been handled in sdistTarball revision = null; editedCabalFile = null; jailbreak = false; }) pkg; /* Build the package in a strict way to uncover potential problems. This includes buildFromSdist and failOnAllWarnings. */ buildStrictly = pkg: buildFromSdist (failOnAllWarnings pkg); /* Disable core optimizations, significantly speeds up build time */ disableOptimization = appendConfigureFlag "--disable-optimization"; /* Turn on most of the compiler warnings and fail the build if any of them occur. */ failOnAllWarnings = appendConfigureFlag "--ghc-option=-Wall --ghc-option=-Werror"; /* Add a post-build check to verify that dependencies declared in the cabal file are actually used. The first attrset argument can be used to configure the strictness of this check and a list of ignored package names that would otherwise cause false alarms. */ checkUnusedPackages = { ignoreEmptyImports ? false , ignoreMainModule ? false , ignorePackages ? [] } : drv : overrideCabal (_drv: { postBuild = with lib; let args = concatStringsSep " " ( optional ignoreEmptyImports "--ignore-empty-imports" ++ optional ignoreMainModule "--ignore-main-module" ++ map (pkg: "--ignore-package ${pkg}") ignorePackages ); in "${pkgs.haskellPackages.packunused}/bin/packunused" + optionalString (args != "") " ${args}"; }) (appendConfigureFlag "--ghc-option=-ddump-minimal-imports" drv); buildStackProject = pkgs.callPackage ../generic-stack-builder.nix { }; /* Add a dummy command to trigger a build despite an equivalent earlier build that is present in the store or cache. */ triggerRebuild = i: overrideCabal (drv: { postUnpack = ": trigger rebuild ${toString i}"; }); /* Override the sources for the package and optionaly the version. This also takes of removing editedCabalFile. */ overrideSrc = { src, version ? null }: drv: overrideCabal (_: { inherit src; version = if version == null then drv.version else version; editedCabalFile = null; }) drv; # Get all of the build inputs of a haskell package, divided by category. getBuildInputs = p: p.getBuildInputs; # Extract the haskell build inputs of a haskell package. # This is useful to build environments for developing on that # package. getHaskellBuildInputs = p: (getBuildInputs p).haskellBuildInputs; # Under normal evaluation, simply return the original package. Under # nix-shell evaluation, return a nix-shell optimized environment. shellAware = p: if lib.inNixShell then p.env else p; ghcInfo = ghc: rec { isCross = (ghc.cross or null) != null; isGhcjs = ghc.isGhcjs or false; nativeGhc = if isCross || isGhcjs then ghc.bootPkgs.ghc else ghc; }; ### mkDerivation helpers # These allow external users of a haskell package to extract # information about how it is built in the same way that the # generic haskell builder does, by reusing the same functions. # Each function here has the same interface as mkDerivation and thus # can be called for a given package simply by overriding the # mkDerivation argument it used. See getHaskellBuildInputs above for # an example of this. # Some information about which phases should be run. controlPhases = ghc: let inherit (ghcInfo ghc) isCross; in { doCheck ? !isCross && (lib.versionOlder "7.4" ghc.version) , doBenchmark ? false , ... }: { inherit doCheck doBenchmark; }; # Utility to convert a directory full of `cabal2nix`-generated files into a # package override set # # packagesFromDirectory : { directory : Directory, ... } -> HaskellPackageOverrideSet packagesFromDirectory = { directory, ... }: self: super: let haskellPaths = builtins.attrNames (builtins.readDir directory); toKeyVal = file: { name = builtins.replaceStrings [ ".nix" ] [ "" ] file; value = self.callPackage (directory + "/${file}") { }; }; in builtins.listToAttrs (map toKeyVal haskellPaths); /* INTERNAL function retained for backwards compatibility, use haskell.packages.*.generateOptparseApplicativeCompletions instead! */ __generateOptparseApplicativeCompletion = exeName: overrideCabal (drv: { postInstall = (drv.postInstall or "") + '' bashCompDir="''${!outputBin}/share/bash-completion/completions" zshCompDir="''${!outputBin}/share/zsh/vendor-completions" fishCompDir="''${!outputBin}/share/fish/vendor_completions.d" mkdir -p "$bashCompDir" "$zshCompDir" "$fishCompDir" "''${!outputBin}/bin/${exeName}" --bash-completion-script "''${!outputBin}/bin/${exeName}" >"$bashCompDir/${exeName}" "''${!outputBin}/bin/${exeName}" --zsh-completion-script "''${!outputBin}/bin/${exeName}" >"$zshCompDir/_${exeName}" "''${!outputBin}/bin/${exeName}" --fish-completion-script "''${!outputBin}/bin/${exeName}" >"$fishCompDir/${exeName}.fish" # Sanity check grep -F ${exeName} <$bashCompDir/${exeName} >/dev/null || { echo 'Could not find ${exeName} in completion script.' exit 1 } ''; }); /* Retained for backwards compatibility. Use haskell.packages.*.generateOptparseApplicativeCompletions which is cross aware instead. */ generateOptparseApplicativeCompletions = commands: pkg: lib.warnIf (lib.isInOldestRelease 2211) "haskellLib.generateOptparseApplicativeCompletions is deprecated in favor of haskellPackages.generateOptparseApplicativeCompletions. Please change ${pkg.name} to use the latter and make sure it uses its matching haskell.packages set!" (pkgs.lib.foldr __generateOptparseApplicativeCompletion pkg commands); /* Retained for backwards compatibility. Use haskell.packages.*.generateOptparseApplicativeCompletions which is cross aware instead. */ generateOptparseApplicativeCompletion = command: pkg: lib.warnIf (lib.isInOldestRelease 2211) "haskellLib.generateOptparseApplicativeCompletion is deprecated in favor of haskellPackages.generateOptparseApplicativeCompletions (plural!). Please change ${pkg.name} to use the latter and make sure it uses its matching haskell.packages set!" (__generateOptparseApplicativeCompletion command pkg); # Don't fail at configure time if there are multiple versions of the # same package in the (recursive) dependencies of the package being # built. Will delay failures, if any, to compile time. allowInconsistentDependencies = overrideCabal (drv: { allowInconsistentDependencies = true; }); }