The production buildbot master apparently has not yet been restarted
since https://github.com/llvm/llvm-zorg/pull/393 landed.
This reverts commit 96d1baedefc3581b53bc4389bb171760bec6f191.
Remove the FLANG_INCLUDE_RUNTIME option which was replaced by
LLVM_ENABLE_RUNTIMES=flang-rt.
The FLANG_INCLUDE_RUNTIME option was added in #122336 which disables the
non-runtimes build instructions for the Flang runtime so they do not
conflict with the LLVM_ENABLE_RUNTIMES=flang-rt option added in #110217.
In order to not maintain multiple build instructions for the same thing,
this PR completely removes the old build instructions (effectively
forcing FLANG_INCLUDE_RUNTIME=OFF).
As per discussion in
https://discourse.llvm.org/t/buildbot-changes-with-llvm-enable-runtimes-flang-rt/83571/2
we now implicitly add LLVM_ENABLE_RUNTIMES=flang-rt whenever Flang is
compiled in a bootstrapping (non-standalone) build. Because it is
possible to build Flang-RT separately, this behavior can be disabled
using `-DFLANG_ENABLE_FLANG_RT=OFF`. Also see the discussion an
implicitly adding runtimes/projects in #123964.
When building Flang with Clang, we need to do the same quadmath.h
wrapping as we do for flang-rt. I extracted the CMake code
into FlangCommon.cmake, and cleaned up the arguments passing
to execute_process (note that `-###` was treated as `-` in the original
code, because `#` starts a comment). I believe the Clang command
does not require the input source file, so I removed it as well.
Summary:
Currently we use `TestBigEndian` in CMake to determine endianness. This
doesn't work on all platforms and is deprecated since CMake 3.20.
Instead of using CMake, we can just use the GNU/Clang preprocessor
definitions.
The only difficulty is MSVC, mostly because they don't support the same
macros. But, as far as I'm aware, MSVC / Windows targets are always
little endian, and if not we can just override it for that specific
target in the future.
Summary:
This patch adds initial support for compiling `flang-rt` directly for
the GPU. The method used here matches what's already done for `libc` and
`libc++` for the GPU and builds off of those projects.
Mainly this requires setting up some flags and setting the sources that
currently work. This will deposit the resulting library in the
appropriate directory. These files are then intended to be linked via
`-Xoffload-linker` support in the offloading driver.
```
lib/clang/21/lib/nvptx64-nvidia-cuda/libflang_rt.runtime.a
lib/clang/21/lib/amdgcn-amd-amdhsa/libflang_rt.runtime.a
```
This is obviously missing a lot of functions, mainly the `io` support.
Most of what we cannot support is due to using POSIX things that just
don't make sense on the GPU. Stuff like `pthreads` or `sema`.
Getting unit tests to run on this will also be a challenge. We could run
tests the same way we do with `libc`, but the problem there is that the
`libc` test suite is freestanding while `gtest` currently doesn't
compile on the GPU bcause it uses a lot of weird stuff. If the unit
tests were simply `int main` then it would work.
I don't understand the actual runtime code very well, I'd appreciate
some guidance on how to actually support Fortran IO from this interface.
As I understand it, Fortran IO requires a stack-like operation, which
conflicts with the SIMT model GPUs use. Worst case scenario we could
burn some LDS to keep a stack, or serialize it somehow since we can
always just iterate over all the active lanes.
Building this right now looks like this, which depends on the arguments
added in https://github.com/llvm/llvm-project/pull/131695.
```
-DRUNTIMES_nvptx64-nvidia-cuda_LLVM_ENABLE_RUNTIMES=compiler-rt;libc;libcxx;libcxxabi;flang-rt \
-DRUNTIMES_amdgcn-amd-amdhsa_LLVM_ENABLE_RUNTIMES=compiler-rt;libc;libcxx;libcxxabi;flang-rt \
-DRUNTIMES_nvptx64-nvidia-cuda_FLANG_RT_LIBC_PROVIDER=llvm \
-DRUNTIMES_nvptx64-nvidia-cuda_FLANG_RT_LIBCXX_PROVIDER=llvm \
-DRUNTIMES_amdgcn-amd-amdhsa_FLANG_RT_LIBC_PROVIDER=llvm \
-DRUNTIMES_amdgcn-amd-amdhsa_FLANG_RT_LIBCXX_PROVIDER=llvm
```
I thought I guessed a fix in #130836, but I was wrong.
We actually had the same code in
`flang/cmake/modules/FlangCommon.cmake`.
The check does not pass in flang-rt bootstrap build, because
`-nostdinc++` is added for all `runtimes` checks.
I decided to make the check with the C header, though, I am still
unsure whether it is reliable with a clang that has not been
installed (it is taken from the build structure during flang-rt
configure step).
I verified that this PR enables REAL(16) math entries on aarch64.
This is a re-apply of 083c683969b2436afdc45becadc955841f5f4d31 with a
fix for the flang runtime build.
This works the same way as LLVM_PARALLEL_COMPILE_JOBS except that it is
specific to the flang source rather than for the whole project.
Configuring with -DFLANG_PARALLEL_COMPILE_JOBS=1 would mean that there
would only ever be one flang source being compiled at a time.
Some of the flang sources require large amounts of memory to compile, so
this option can be used to avoid OOM erros when compiling those files
while still allowing the rest of the project to compile using the
maximum number of jobs.
Update flang/CMakeLists.txt
---------
Co-authored-by: Nikita Popov <github@npopov.com>
Co-authored-by: Michael Kruse <github@meinersbur.de>
Extract Flang's runtime library to use the LLVM_ENABLE_RUNTIME
mechanism. It will only become active when
`LLVM_ENABLE_RUNTIMES=flang-rt` is used, which also changes the
`FLANG_INCLUDE_RUNTIME` to `OFF` so the old runtime build rules do not
conflict. This also means that unless `LLVM_ENABLE_RUNTIMES=flang-rt` is
passed, nothing changes with the current build process.
Motivation:
* Consistency with LLVM's other runtime libraries (compiler-rt, libc,
libcxx, openmp offload, ...)
* Allows compiling the runtime for multiple targets at once using the
LLVM_RUNTIME_TARGETS configuration options
* Installs the runtime into the compiler's per-target resource directory
so it can be automatically found even when cross-compiling
Also see RFC discussion at
https://discourse.llvm.org/t/rfc-use-llvm-enable-runtimes-for-flangs-runtime/80826
1. Add a new `MLIR_DEPS` argument group to `flang_add_library()`, and
move MLIR-specific dependencies to that group. These dependencies are
added as usual in regular builds, and are skipped in standalone builds,
since MLIR targets are not visible there (and were already built and
installed).
2. Fix the value of `MLIR_MAIN_SRC_DIR` to refer to the current source
directory rather than the directory written into MLIR CMake files. The
latter refers to the directory used to build the MLIR package, and is no
longer valid.
3. Fix non-dylib friendly linking of `LLVMTargetParser` in `Optimizer`
unittests.
With these changes, I can successfully run Flang's regression tests.
Following the conclusion of the
[RFC](https://discourse.llvm.org/t/rfc-names-for-flang-rt-libraries/84321),
rename Flang's runtime libraries as follows:
* libFortranRuntime.(a|so) to libflang_rt.runtime.(a|so)
* libFortranFloat128Math.a to libflang_rt.quadmath.a
* libCufRuntime_cuda_${CUDAToolkit_VERSION_MAJOR}.(a|so) to
libflang_rt.cuda_${CUDAToolkit_VERSION_MAJOR}.(a|so)
This follows the same naming scheme as Compiler-RT libraries
(`libclang_rt.${component}.(a|so)`). It provides some consistency
between Flang's runtime libraries for current and potential future
library components.
Do not call `mlir_target_link_libraries()` when there are no `MLIR_LIBS`
specified. This fixes a failure when `flang/runtime` is being built
standalone, as it does not use MLIR and therefore the function
is not defined:
https://lab.llvm.org/buildbot/#/builders/152/builds/932
Fixes 6a2cc122296b04a4f09768a714a74ffc82b7be87
Introduce a new `MLIR_LIBS` argument to `add_flang_library`, that uses
`mlir_target_link_libraries` to link the MLIR dylib alterantively to the
component libraries. Use it, along with a few inline
`mlir_target_link_libraries` in tools, to support linking Flang to MLIR
dylib rather than the static libraries.
With these changes, the vast majority of Flang can be linked
dynamically. The only parts still using static libraries are these
requiring MLIR test libraries, that are not included in the dylib.
When the `add_flang_library` was first added, it was apparently copied
over from `add_clang_library`, including its logic to determine the
library type. It includes a workaround: If `BUILD_SHARED_LIBS` is
enabled, it should build all libraries as shared, including those that
are explicitly marked as `STATIC`[^1], because `add_clang_library`
always passes at least one of `STATIC`/`SHARED` to `llvm_add_library`,
and `llvm_add_library` could not distinguish the two cases.
Then, the two implementations diverged. For its runtime libraries, Flang
requires some libraries to always be static libraries, so if a library
is explicitly marked as `STATIC`, `BUILD_SHARED_LIBS` is ignored[^2].
I noticed the two implementations of the same functionality, modified
only the `add_clang_library`, and copied over the result to
`add_flang_library`[^3], without noticing that they are slightly
different. As a result, Flang runtime libraries would be built as shared
libraries with `-DBUILD_SHARED_LIBS=ON`, which may break some build
configurations[^4].
This PR fixes the problem and at the same time simplifies the library
type algorithm by just passing SHARED/STATIC verbatim to
`llvm_add_library`. This is effectively what [^2] should have done
instead adding more code to undo the workaround of [^1]. Ideally, one
would use
```
llvm_add_library(${name} ${ARG_STATIC} ${ARG_SHARED} [...])
```
but `ARG_STATIC`/`ARG_SHARED` as set by `cmake_parse_arguments` contain
`TRUE`/`FALSE` instead of the keywords themselves. I could imagine a
utility function akin to `pythonize_bool` that does this.
This simplification adds two more changes:
1. Object libraries are not explicitly requested anymore.
`llvm_add_library` itself should determine whether an object library is
necessary. As the comment notes, using an object library is not without
problems and seem of no use here since it works fine without object
library when in `XCODE`/`MSVC_IDE` mode.
2. The property `CLANG_STATIC_LIBS` was removed. It was
`FLANG_STATIC_LIBS` before to copy&paste error of #93519 [^3] which not
used anywhere. In clang, `CLANG_STATIC_LIBS` is used for `clang-shlib`
to include all component libraries in a single large library. There is
no equivalent `flang-shlib`.
[^1]: dbc2a12c7311ff4cc2cd7887d128b506bd35b579
[^2]: 3d2e05d542e646891745c5278a09950d3c4fb4a5
[^3]: #93519
[^4]:
https://github.com/llvm/llvm-project/pull/93519#issuecomment-2192359002
As discussed in #89743, when using the Visual Studio solution
generators, object library projects are displayed as a collection of
non-editable *.obj files. To look for the corresponding source files,
one has to browse (or search) to the library's obj.libname project. This
patch tries to avoid this as much as possible.
For Clang, there is already an exception for XCode. We handle MSVC_IDE
the same way.
For MLIR, this is more complicated. There are explicit references to the
obj.libname target that only work when there is an object library. This
patch cleans up the reasons for why an object library is needed:
1. The obj.libname is modified in the calling CMakeLists.txt. Note that
with use-only references, `add_library(<name> ALIAS <target>)` could
have been used.
2. An `libMLIR.so` (mlir-shlib) is also created. This works by adding
linking the object libraries' object files into the libMLIR.so (in
addition to the library's own .so/.a). XCode is handled using the
`-force_load` linker option instead. Windows is not supported. This
mechanism is different from LLVM's llvm-shlib that is created by linking
static libraries with `-Wl,--whole-archive` (and `-Wl,-all_load` on
MacOS).
3. The library might be added to an aggregate library. In-tree, the
seems to be only `libMLIR-C.so` and the standalone example. In XCode, it
uses the object library and `-force_load` mechanism as above. Again,
this is different from `libLLVM-C.so`.
4. Build an object library whenever it was before this patch, except
when generating a Visual Studio solution. This condition could be
removed, but I am trying to avoid build breakages of whatever
configurations others use.
This seems to never have worked with XCode because of the explicit
references to obj.libname (reason 1.). I don't have access to XCode, but
I tried to preserve the current working. IMHO there should be a common
mechanism to build aggregate libraries for all LLVM projects instead of
the 4 that we have now.
As far as I can see, this means for LLVM there are the following changes
on whether object libraries are created:
1. An object library is created even in XCode if FORCE_OBJECT_LIBRARY is
set. I do not know how XCode handles it, but I also know CMake will
abort otherwise.
2. An object library is created even for explicitly SHARED libraries for
building `libMLIR.so`. Again, mlir-shlib does not work otherwise.
`libMLIR.so` itself is created using SHARED so this patch is marking it
as EXCLUDE_FROM_LIBMLIR.
3. For the second condition, it is now sensitive to whether the
mlir-shlib is built at all (LLVM_BUILD_LLVM_DYLIB). However, an object
library is still built using the fourth condition unless using the MSVC
solution generator. That is, except with MSVC_IDE, when an object
library was built before, it will also be an object library now.
This works the same way as LLVM_PARALLEL_COMPILE_JOBS except that it is
specific to the flang source rather than for the whole project.
Configuring with -DFLANG_PARALLEL_COMPILE_JOBS=1 would mean that there
would only ever be one flang source being compiled at a time.
Some of the flang sources require large amounts of memory to compile, so
this option can be used to avoid OOM erros when compiling those files
while still allowing the rest of the project to compile using the
maximum number of jobs.
---------
Co-authored-by: Nikita Popov <github@npopov.com>
Update the folder titles for targets in the monorepository that have not
seen taken care of for some time. These are the folders that targets are
organized in Visual Studio and XCode (`set_property(TARGET <target>
PROPERTY FOLDER "<title>")`) when using the respective CMake's IDE
generator.
* Ensure that every target is in a folder
* Use a folder hierarchy with each LLVM subproject as a top-level folder
* Use consistent folder names between subprojects
* When using target-creating functions from AddLLVM.cmake, automatically
deduce the folder. This reduces the number of
`set_property`/`set_target_property`, but are still necessary when
`add_custom_target`, `add_executable`, `add_library`, etc. are used. A
LLVM_SUBPROJECT_TITLE definition is used for that in each subproject's
root CMakeLists.txt.
This is to experiment with distributing F18 runtime CUDA library
in the form of a pure PTX library. The change is under
FLANG_EXPERIMENTAL_CUDA_RUNTIME CMake control.
This reverts commit 6403287eff71a3d6f6c862346d6ed3f0f000eb70.
This is failing on all but 1 of Linaro's flang builders.
CMake Error at /home/tcwg-buildbot/worker/clang-aarch64-full-2stage/llvm/flang-rt/unittests/CMakeLists.txt:37 (message):
Target llvm_gtest not found.
See discourse thread https://discourse.llvm.org/t/rfc-support-cmake-option-to-control-link-type-built-for-flang-runtime-libraries/71602/18 for full details.
Flang-rt is the new library target for the flang runtime libraries. It builds the Flang-rt library (which contains the sources of FortranRuntime and FortranDecimal) and the Fortran_main library. See documentation in this patch for detailed description (flang-rt/docs/GettingStarted.md).
This patch aims to:
- integrate Flang's runtime into existing llvm infrasturcture so that Flang's runtime can be built similarly to other runtimes via the runtimes target or via the llvm target as an enabled runtime
- decouple the FortranDecimal library sources that were used by both compiler and runtime so that different build configurations can be applied for compiler vs runtime
- add support for running flang-rt testsuites, which were created by migrating relevant tests from `flang/test` and `flang/unittest` to `flang-rt/test` and `flang-rt/unittest`, using a new `check-flang-rt` target.
- provide documentation on how to build and use the new FlangRT runtime
Reviewed By: DanielCChen
Differential Revision: https://reviews.llvm.org/D154869
Without this change the problem is that flangOmpReport and
flangPrintFunctionNames libraries are not built under 'all',
but they are imported targets via LLVMExports.cmake so that
any out-of-tree build that configures upon LLVM+Flang package
will get this CMake error:
```
The imported target "flangPrintFunctionNames" references the file
".../lib/flangPrintFunctionNames.so"
but this file does not exist.
```
flang-aarch64-out-of-tree buildbot (https://lab.llvm.org/buildbot/#/builders/175)
does not catch this issue, because it does not enable Flang on the first stage.
This change gets rid of FLANG_BUILD_EXAMPLES in favor of LLVM_BUILD_EXAMPLES
and uses available LLVM CMake macros to add example executables/libraries.
Differential Revision: https://reviews.llvm.org/D145992
D139623 replaces CMAKE_CFG_INTDIR
with '.' for multi-config builds. However, this change has
not been reflected in mlir, flang, polly, lld, and clang.
The patch updates the path to LLVMConfig.cmake for those
projects.
Reviewed By: sebastian-ne
Differential Revision: https://reviews.llvm.org/D141538
Patch D138274 removed some Flang cmake configuration information that we
need for our internal builds. This change restores them.
Differential Revision: https://reviews.llvm.org/D139355
Add a version to non-LLVM cmake package so that users needing an exact
version match can use the version parameter to find_package. Also adjust
the find_package(LLVM) to use an exact version match as well.
Reviewed By: arsenm, stellaraccident, mceier
Differential Revision: https://reviews.llvm.org/D138274
Add a version to non-LLVM cmake package so that users needing an exact
version match can use the version parameter to find_package. Also adjust
the find_package(LLVM) to use an exact version match as well.
Reviewed By: arsenm, stellaraccident
Differential Revision: https://reviews.llvm.org/D138274
A simple sed doing these substitutions:
- `${LLVM_BINARY_DIR}/lib${LLVM_LIBDIR_SUFFIX}\>` -> `${LLVM_LIBRARY_DIR}`
- `${LLVM_BINARY_DIR}/bin\>` -> `${LLVM_TOOLS_BINARY_DIR}`
where `\>` means "word boundary".
The only manual modifications were reverting changes in
- `runtimes/CMakeLists.txt`
because these were "entry points" where we wanted to tread carefully not not introduce a "loop" which would end with an undefined variable being expanded to nothing.
There are some `${LLVM_BINARY_DIR}/lib` without the `${LLVM_LIBDIR_SUFFIX}`, but these refer to the lib subdirectory of the source (`llvm/lib`). That `lib` is automatically appended to make the local `CMAKE_CURRENT_BINARY_DIR` value by `add_subdirectory`; since the directory name in the source tree is fixed without any suffix, the corresponding `CMAKE_CURRENT_BINARY_DIR` will also be. We therefore do not replace it but leave it as-is.
This picks up where D133828 left off, getting the occurrences with*out* `CMAKE_CFG_INTDIR`. But this is difficult to do correctly and so not done in the (retroactively) previous diff.
This hopefully increases readability overall, and also decreases the usages of `LLVM_LIBDIR_SUFFIX`, preparing us for D130586.
Reviewed By: sebastian-ne
Differential Revision: https://reviews.llvm.org/D132316
A simple sed doing these substitutions:
- `${LLVM_BINARY_DIR}/(\$\{CMAKE_CFG_INTDIR}/)?lib(${LLVM_LIBDIR_SUFFIX})?\>` -> `${LLVM_LIBRARY_DIR}`
- `${LLVM_BINARY_DIR}/(\$\{CMAKE_CFG_INTDIR}/)?bin\>` -> `${LLVM_TOOLS_BINARY_DIR}`
where `\>` means "word boundary".
The only manual modifications were reverting changes in
- `compiler-rt/cmake/Modules/CompilerRTUtils.cmake
- `runtimes/CMakeLists.txt`
because these were "entry points" where we wanted to tread carefully not not introduce a "loop" which would end with an undefined variable being expanded to nothing.
This hopefully increases readability overall, and also decreases the usages of `LLVM_LIBDIR_SUFFIX`, preparing us for D130586.
Reviewed By: sebastian-ne
Differential Revision: https://reviews.llvm.org/D132316
We held off on this before as `LLVM_LIBDIR_SUFFIX` conflicted with it.
Now we return this.
`LLVM_LIBDIR_SUFFIX` is kept as a deprecated way to set
`CMAKE_INSTALL_LIBDIR`. The other `*_LIBDIR_SUFFIX` are just removed
entirely.
I imagine this is too potentially-breaking to make LLVM 15. That's fine.
I have a more minimal version of this in the disto (NixOS) patches for
LLVM 15 (like previous versions). This more expansive version I will
test harder after the release is cut.
Reviewed By: sebastian-ne, ldionne, #libc, #libc_abi
Differential Revision: https://reviews.llvm.org/D130586
Make sure that FortranDecimal, FortranRuntime and Fortran_main are
installed/packaged even when LLVM_INSTALL_TOOLCHAIN_ONLY is enabled.
They are used by flang to link executables, so they should be provided
even with minimal installs.
Differential Revision: https://reviews.llvm.org/D131670
Fixes a regression from D117973, that used CMAKE_BINARY_DIR instead of
LLVM_BINARY_DIR in some places.
Differential Revision: https://reviews.llvm.org/D130555
Firstly, we we make an additional GNUInstallDirs-style variable. With
NixOS, for example, this is crucial as we want those to go in
`${dev}/lib/cmake` not `${out}/lib/cmake` as that would a cmake subdir
of the "regular" libdir, which is installed even when no one needs to do
any development.
Secondly, we make *Config.cmake robust to absolute package install
paths. We for NixOS will in fact be passing them absolute paths to make
the `${dev}` vs `${out}` distinction mentioned above, and the
GNUInstallDirs-style variables are suposed to support absolute paths in
general so it's good practice besides the NixOS use-case.
Thirdly, we make `${project}_INSTALL_PACKAGE_DIR` CACHE PATHs like other
install dirs are.
Reviewed By: sebastian-ne
Differential Revision: https://reviews.llvm.org/D117973
First of all, `LLVM_TOOLS_INSTALL_DIR` put there breaks our NixOS
builds, because `LLVM_TOOLS_INSTALL_DIR` defined the same as
`CMAKE_INSTALL_BINDIR` becomes an *absolute* path, and then when
downstream projects try to install there too this breaks because our
builds always install to fresh directories for isolation's sake.
Second of all, note that `LLVM_TOOLS_INSTALL_DIR` stands out against the
other specially crafted `LLVM_CONFIG_*` variables substituted in
`llvm/cmake/modules/LLVMConfig.cmake.in`.
@beanz added it in d0e1c2a550ef348aae036d0fe78cab6f038c420c to fix a
dangling reference in `AddLLVM`, but I am suspicious of how this
variable doesn't follow the pattern.
Those other ones are carefully made to be build-time vs install-time
variables depending on which `LLVMConfig.cmake` is being generated, are
carefully made relative as appropriate, etc. etc. For my NixOS use-case
they are also fine because they are never used as downstream install
variables, only for reading not writing.
To avoid the problems I face, and restore symmetry, I deleted the
exported and arranged to have many `${project}_TOOLS_INSTALL_DIR`s.
`AddLLVM` now instead expects each project to define its own, and they
do so based on `CMAKE_INSTALL_BINDIR`. `LLVMConfig` still exports
`LLVM_TOOLS_BINARY_DIR` which is the location for the tools defined in
the usual way, matching the other remaining exported variables.
For the `AddLLVM` changes, I tried to copy the existing pattern of
internal vs non-internal or for LLVM vs for downstream function/macro
names, but it would good to confirm I did that correctly.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D117977
First of all, `LLVM_TOOLS_INSTALL_DIR` put there breaks our NixOS
builds, because `LLVM_TOOLS_INSTALL_DIR` defined the same as
`CMAKE_INSTALL_BINDIR` becomes an *absolute* path, and then when
downstream projects try to install there too this breaks because our
builds always install to fresh directories for isolation's sake.
Second of all, note that `LLVM_TOOLS_INSTALL_DIR` stands out against the
other specially crafted `LLVM_CONFIG_*` variables substituted in
`llvm/cmake/modules/LLVMConfig.cmake.in`.
@beanz added it in d0e1c2a550ef348aae036d0fe78cab6f038c420c to fix a
dangling reference in `AddLLVM`, but I am suspicious of how this
variable doesn't follow the pattern.
Those other ones are carefully made to be build-time vs install-time
variables depending on which `LLVMConfig.cmake` is being generated, are
carefully made relative as appropriate, etc. etc. For my NixOS use-case
they are also fine because they are never used as downstream install
variables, only for reading not writing.
To avoid the problems I face, and restore symmetry, I deleted the
exported and arranged to have many `${project}_TOOLS_INSTALL_DIR`s.
`AddLLVM` now instead expects each project to define its own, and they
do so based on `CMAKE_INSTALL_BINDIR`. `LLVMConfig` still exports
`LLVM_TOOLS_BINARY_DIR` which is the location for the tools defined in
the usual way, matching the other remaining exported variables.
For the `AddLLVM` changes, I tried to copy the existing pattern of
internal vs non-internal or for LLVM vs for downstream function/macro
names, but it would good to confirm I did that correctly.
Reviewed By: nikic
Differential Revision: https://reviews.llvm.org/D117977
At the moment the Fortran_main library is not installed, so it cannot be
found by the driver when run from an install directory. This patch fixes
the issue by replacing llvm_add_library with add_flang_library, which
already contains all the proper incantations for installing a library.
It also enhances add_flang_library to support a STATIC arg which forces
the library to be static even when BUILD_SHARED_LIBS is on.
Differential Revision: https://reviews.llvm.org/D124759
Co-authored-by: Dan Palermo <Dan.Palermo@amd.com>
See the docs in the new function for details.
I think I found every instance of this copy pasted code. Polly could
also use it, but currently does something different, so I will save the
behavior change for a future revision.
We get the shared, non-installed CMake modules following the pattern
established in D116472.
It might be good to have LLD and Flang also use this, but that would be
a functional change and so I leave it as future work.
Reviewed By: beanz, lebedev.ri
Differential Revision: https://reviews.llvm.org/D116521
Extracted from D99484. My new plan is to start from the outside and work
inward.
Reviewed By: stephenneuendorffer
Differential Revision: https://reviews.llvm.org/D115569
Revert "[flang][NFC] Add debug dump method to evaluate::Expr and semantics::Symbol"
This reverts commit b0e35fde21ecb47799603e1acfc9ffa7b83dea13.
Revert "[flang] Add a wrapper for Fortran main program"
This reverts commit 2c1ce0755e09909c41db93845c4c3f42457cb9c8.
Revert "[flang][NFC] Fix header comments in some runtime headers"
This reverts commit a63f57674d511eb287edbabad9674c6298cf8b84.
