{ lowPrio, newScope, pkgs, lib, stdenv, stdenvNoCC, cmake, ninja , gccForLibs, preLibcCrossHeaders , libxml2, python3, fetchFromGitHub, overrideCC, wrapCCWith, wrapBintoolsWith , buildLlvmTools # tools, but from the previous stage, for cross , targetLlvmLibraries # libraries, but from the next stage, for cross , targetLlvm # This is the default binutils, but with *this* version of LLD rather # than the default LLVM version's, if LLD is the choice. We use these for # the `useLLVM` bootstrapping below. , bootBintoolsNoLibc ? if stdenv.targetPlatform.linker == "lld" then null else pkgs.bintoolsNoLibc , bootBintools ? if stdenv.targetPlatform.linker == "lld" then null else pkgs.bintools , darwin # LLVM release information; specify one of these but not both: , gitRelease ? null # i.e.: # { # version = /* i.e. "15.0.0" */; # rev = /* commit SHA */; # rev-version = /* human readable version; i.e. "unstable-2022-26-07" */; # sha256 = /* checksum for this release, can omit if specifying your own `monorepoSrc` */; # } , officialRelease ? { version = "15.0.7"; sha256 = "sha256-wjuZQyXQ/jsmvy6y1aksCcEDXGBjuhpgngF3XQJ/T4s="; } # i.e.: # { # version = /* i.e. "15.0.0" */; # candidate = /* optional; if specified, should be: "rcN" */ # sha256 = /* checksum for this release, can omit if specifying your own `monorepoSrc` */; # } # By default, we'll try to fetch a release from `github:llvm/llvm-project` # corresponding to the `gitRelease` or `officialRelease` specified. # # You can provide your own LLVM source by specifying this arg but then it's up # to you to make sure that the LLVM repo given matches the release configuration # specified. , monorepoSrc ? null }: assert let int = a: if a then 1 else 0; xor = a: b: ((builtins.bitXor (int a) (int b)) == 1); in lib.assertMsg (xor (gitRelease != null) (officialRelease != null)) ("must specify `gitRelease` or `officialRelease`" + (lib.optionalString (gitRelease != null) " — not both")); let monorepoSrc' = monorepoSrc; in let releaseInfo = if gitRelease != null then rec { original = gitRelease; release_version = original.version; version = gitRelease.rev-version; } else rec { original = officialRelease; release_version = original.version; version = if original ? candidate then "${release_version}-${original.candidate}" else release_version; }; monorepoSrc = if monorepoSrc' != null then monorepoSrc' else let sha256 = releaseInfo.original.sha256; rev = if gitRelease != null then gitRelease.rev else "llvmorg-${releaseInfo.version}"; in fetchFromGitHub { owner = "llvm"; repo = "llvm-project"; inherit rev sha256; }; inherit (releaseInfo) release_version version; llvm_meta = { license = lib.licenses.ncsa; maintainers = lib.teams.llvm.members; # See llvm/cmake/config-ix.cmake. platforms = lib.platforms.aarch64 ++ lib.platforms.arm ++ lib.platforms.m68k ++ lib.platforms.mips ++ lib.platforms.power ++ lib.platforms.riscv ++ lib.platforms.s390x ++ lib.platforms.wasi ++ lib.platforms.x86; }; tools = lib.makeExtensible (tools: let callPackage = newScope (tools // { inherit stdenv cmake ninja libxml2 python3 release_version version monorepoSrc buildLlvmTools; }); mkExtraBuildCommands0 = cc: '' rsrc="$out/resource-root" mkdir "$rsrc" ln -s "${cc.lib}/lib/clang/${release_version}/include" "$rsrc" echo "-resource-dir=$rsrc" >> $out/nix-support/cc-cflags ''; mkExtraBuildCommands = cc: mkExtraBuildCommands0 cc + '' ln -s "${targetLlvmLibraries.compiler-rt.out}/lib" "$rsrc/lib" ln -s "${targetLlvmLibraries.compiler-rt.out}/share" "$rsrc/share" ''; bintoolsNoLibc' = if bootBintoolsNoLibc == null then tools.bintoolsNoLibc else bootBintoolsNoLibc; bintools' = if bootBintools == null then tools.bintools else bootBintools; in { libllvm = callPackage ./llvm { inherit llvm_meta; }; # `llvm` historically had the binaries. When choosing an output explicitly, # we need to reintroduce `outputSpecified` to get the expected behavior e.g. of lib.get* llvm = tools.libllvm; libclang = callPackage ./clang { inherit llvm_meta; }; clang-unwrapped = tools.libclang; llvm-manpages = lowPrio (tools.libllvm.override { enableManpages = true; python3 = pkgs.python3; # don't use python-boot }); clang-manpages = lowPrio (tools.libclang.override { enableManpages = true; python3 = pkgs.python3; # don't use python-boot }); lldb-manpages = lowPrio (tools.lldb.override { enableManpages = true; python3 = pkgs.python3; # don't use python-boot }); # pick clang appropriate for package set we are targeting clang = /**/ if stdenv.targetPlatform.libc == null then tools.clangNoLibc else if stdenv.targetPlatform.useLLVM or false then tools.clangUseLLVM else if (pkgs.targetPackages.stdenv or stdenv).cc.isGNU then tools.libstdcxxClang else tools.libcxxClang; libstdcxxClang = wrapCCWith rec { cc = tools.clang-unwrapped; # libstdcxx is taken from gcc in an ad-hoc way in cc-wrapper. libcxx = null; extraPackages = [ targetLlvmLibraries.compiler-rt ]; extraBuildCommands = mkExtraBuildCommands cc; }; libcxxClang = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = targetLlvmLibraries.libcxx; extraPackages = [ libcxx.cxxabi targetLlvmLibraries.compiler-rt ]; extraBuildCommands = mkExtraBuildCommands cc; }; lld = callPackage ./lld { inherit llvm_meta; }; lldb = callPackage ../common/lldb.nix { patches = let resourceDirPatch = callPackage ({ substituteAll, libclang }: substituteAll { src = ./lldb/resource-dir.patch; clangLibDir = "${libclang.lib}/lib"; }) { }; in [ ./lldb/procfs.patch resourceDirPatch ./lldb/gnu-install-dirs.patch ] # This is a stopgap solution if/until the macOS SDK used for x86_64 is # updated. # # The older 10.12 SDK used on x86_64 as of this writing has a `mach/machine.h` # header that does not define `CPU_SUBTYPE_ARM64E` so we replace the one use # of this preprocessor symbol in `lldb` with its expansion. # # See here for some context: # https://github.com/NixOS/nixpkgs/pull/194634#issuecomment-1272129132 ++ lib.optional ( stdenv.targetPlatform.isDarwin && !stdenv.targetPlatform.isAarch64 && (lib.versionOlder darwin.apple_sdk.sdk.version "11.0") ) ./lldb/cpu_subtype_arm64e_replacement.patch; inherit llvm_meta; }; # Below, is the LLVM bootstrapping logic. It handles building a # fully LLVM toolchain from scratch. No GCC toolchain should be # pulled in. As a consequence, it is very quick to build different # targets provided by LLVM and we can also build for what GCC # doesn’t support like LLVM. Probably we should move to some other # file. bintools-unwrapped = callPackage ../common/bintools.nix { }; bintoolsNoLibc = wrapBintoolsWith { bintools = tools.bintools-unwrapped; libc = preLibcCrossHeaders; }; bintools = wrapBintoolsWith { bintools = tools.bintools-unwrapped; }; clangUseLLVM = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = targetLlvmLibraries.libcxx; bintools = bintools'; extraPackages = [ libcxx.cxxabi targetLlvmLibraries.compiler-rt ] ++ lib.optionals (!stdenv.targetPlatform.isWasm) [ targetLlvmLibraries.libunwind ]; extraBuildCommands = mkExtraBuildCommands cc; nixSupport.cc-cflags = [ "-rtlib=compiler-rt" "-Wno-unused-command-line-argument" "-B${targetLlvmLibraries.compiler-rt}/lib" ] ++ lib.optional (!stdenv.targetPlatform.isWasm) "--unwindlib=libunwind" ++ lib.optional (!stdenv.targetPlatform.isWasm && stdenv.targetPlatform.useLLVM or false) "-lunwind" ++ lib.optional stdenv.targetPlatform.isWasm "-fno-exceptions"; }; clangNoLibcxx = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = null; bintools = bintools'; extraPackages = [ targetLlvmLibraries.compiler-rt ]; extraBuildCommands = mkExtraBuildCommands cc; nixSupport.cc-cflags = [ "-rtlib=compiler-rt" "-B${targetLlvmLibraries.compiler-rt}/lib" "-nostdlib++" ]; }; clangNoLibc = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = null; bintools = bintoolsNoLibc'; extraPackages = [ targetLlvmLibraries.compiler-rt ]; extraBuildCommands = mkExtraBuildCommands cc; nixSupport.cc-cflags = [ "-rtlib=compiler-rt" "-B${targetLlvmLibraries.compiler-rt}/lib" ]; }; clangNoCompilerRt = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = null; bintools = bintoolsNoLibc'; extraPackages = [ ]; extraBuildCommands = mkExtraBuildCommands0 cc; nixSupport.cc-cflags = [ "-nostartfiles" ]; }; clangNoCompilerRtWithLibc = wrapCCWith rec { cc = tools.clang-unwrapped; libcxx = null; bintools = bintools'; extraPackages = [ ]; extraBuildCommands = mkExtraBuildCommands0 cc; }; }); libraries = lib.makeExtensible (libraries: let callPackage = newScope (libraries // buildLlvmTools // { inherit stdenv cmake ninja libxml2 python3 release_version version monorepoSrc; }); in { compiler-rt-libc = callPackage ./compiler-rt { inherit llvm_meta; stdenv = if stdenv.hostPlatform.useLLVM or false then overrideCC stdenv buildLlvmTools.clangNoCompilerRtWithLibc else stdenv; }; compiler-rt-no-libc = callPackage ./compiler-rt { inherit llvm_meta; stdenv = if stdenv.hostPlatform.useLLVM or false then overrideCC stdenv buildLlvmTools.clangNoCompilerRt else stdenv; }; # N.B. condition is safe because without useLLVM both are the same. compiler-rt = if stdenv.hostPlatform.isAndroid then libraries.compiler-rt-libc else libraries.compiler-rt-no-libc; stdenv = overrideCC stdenv buildLlvmTools.clang; libcxxStdenv = overrideCC stdenv buildLlvmTools.libcxxClang; libcxxabi = let # CMake will "require" a compiler capable of compiling C++ programs # cxx-header's build does not actually use one so it doesn't really matter # what stdenv we use here, as long as CMake is happy. cxx-headers = callPackage ./libcxx { inherit llvm_meta; # Note that if we use the regular stdenv here we'll get cycle errors # when attempting to use this compiler in the stdenv. # # The final stdenv pulls `cxx-headers` from the package set where # hostPlatform *is* the target platform which means that `stdenv` at # that point attempts to use this toolchain. # # So, we use `stdenv_` (the stdenv containing `clang` from this package # set, defined below) to sidestep this issue. # # Because we only use `cxx-headers` in `libcxxabi` (which depends on the # clang stdenv _anyways_), this is okay. stdenv = stdenv_; headersOnly = true; }; # `libcxxabi` *doesn't* need a compiler with a working C++ stdlib but it # *does* need a relatively modern C++ compiler (see: # https://releases.llvm.org/15.0.0/projects/libcxx/docs/index.html#platform-and-compiler-support). # # So, we use the clang from this LLVM package set, like libc++ # "boostrapping builds" do: # https://releases.llvm.org/15.0.0/projects/libcxx/docs/BuildingLibcxx.html#bootstrapping-build # # We cannot use `clangNoLibcxx` because that contains `compiler-rt` which, # on macOS, depends on `libcxxabi`, thus forming a cycle. stdenv_ = overrideCC stdenv buildLlvmTools.clangNoCompilerRtWithLibc; in callPackage ./libcxxabi { stdenv = stdenv_; inherit llvm_meta cxx-headers; }; # Like `libcxxabi` above, `libcxx` requires a fairly modern C++ compiler, # so: we use the clang from this LLVM package set instead of the regular # stdenv's compiler. libcxx = callPackage ./libcxx { inherit llvm_meta; stdenv = overrideCC stdenv buildLlvmTools.clangNoLibcxx; }; libunwind = callPackage ./libunwind { inherit llvm_meta; stdenv = overrideCC stdenv buildLlvmTools.clangNoLibcxx; }; openmp = callPackage ./openmp { inherit llvm_meta targetLlvm; }; }); noExtend = extensible: lib.attrsets.removeAttrs extensible [ "extend" ]; in { inherit tools libraries release_version; } // (noExtend libraries) // (noExtend tools)