The path to the runtime libraries used by the compiler under test
is normally identical to the path where just built libraries are
created. However, this is not necessarily the case when doing standalone
builds. This is because the external compiler used by tests may choose
to get its runtime libraries from somewhere else.
When doing standalone builds there are two types of testing we could be
doing:
* Test the just built runtime libraries.
* Test the runtime libraries shipped with the compile under test.
Both types of testing are valid but it confusingly turns out compiler-rt
actually did a mixture of these types of testing.
* The `test/builtins/Unit/` test suite always tested the just built runtime
libraries.
* All other testsuites implicitly use whatever runtime library the
compiler decides to link.
There is no way for us to infer which type of testing the developer
wants so this patch introduces a new
`COMPILER_RT_TEST_STANDALONE_BUILD_LIBS` CMake
option which explicitly declares which runtime libraries should be
tested. If it is `ON` then the just built libraries should be tested,
otherwise the libraries in the external compiler should be tested.
When testing starts the lit test suite queries the compiler used for
testing to see where it will get its runtime libraries from. If these
paths are identical no action is taken (the common case). If the paths
are not identical then we check the value of
`COMPILER_RT_TEST_STANDALONE_BUILD_LIBS` (progated into the config as
`test_standalone_build_libs`) and check if the test suite supports testing in the
requested configuration.
* If we want to test just built libs and the test suite supports it
(currently only `test/builtins/Unit`) then testing proceeds without any changes.
* If we want to test the just built libs and the test suite doesn't
support it we emit a fatal error to prevent the developer from
testing the wrong runtime libraries.
* If we are testing the compiler's built libs then we adjust
`config.compiler_rt_libdir` to point at the compiler's runtime
directory. This makes the `test/builtins/Unit` tests use the
compiler's builtin library. No other changes are required because
all other testsuites implicitly use the compiler's built libs.
To make the above work the
`test_suite_supports_overriding_runtime_lib_path` test suite config
option has been introduced so we can identify what each test suite
supports.
Note all of these checks **have to be performed** when lit runs.
We cannot run the checks at CMake generation time because
multi-configuration build systems prevent us from knowing what the
paths will be.
We could perhaps support `COMPILER_RT_TEST_STANDALONE_BUILD_LIBS` being
`ON` for most test suites (when the runtime library paths differs) in
the future by specifiying a custom compiler resource directory path.
Doing so is out of scope for this patch.
rdar://77182297
Differential Revision: https://reviews.llvm.org/D101681
This reapplies 1e1d75b190, which was reverted in ce1a4d5323 due to build
failures.
The unconditional dependencies on clang and llvm-jitlink in
compiler-rt/test/orc/CMakeLists.txt have been removed -- they don't appear to
be necessary, and I suspect they're the cause of the build failures seen
earlier.
Some builders failed with a missing clang dependency. E.g.
CMake Error at /Users/buildslave/jenkins/workspace/clang-stage1-RA/clang-build \
/lib/cmake/llvm/AddLLVM.cmake:1786 (add_dependencies):
The dependency target "clang" of target "check-compiler-rt" does not exist.
Reverting while I investigate.
This reverts commit 1e1d75b190.
The runtimes build uses variables set by add_lit_testsuite to collect
testsuites from all the runtimes.
Differential Revision: https://reviews.llvm.org/D97913
__start_/__stop_ references retain C identifier name sections such as
__llvm_prf_*. Putting these into a section group disables this logic.
The ELF section group semantics ensures that group members are retained
or discarded as a unit. When a function symbol is discarded, this allows
allows linker to discard counters, data and values associated with that
function symbol as well.
Note that `noduplicates` COMDAT is lowered to zero-flag section group in
ELF. We only set this for functions that aren't already in a COMDAT and
for those that don't have available_externally linkage since we already
use regular COMDAT groups for those.
Differential Revision: https://reviews.llvm.org/D96757
__start_/__stop_ references retain C identifier name sections such as
__llvm_prf_*. Putting these into a section group disables this logic.
The ELF section group semantics ensures that group members are retained
or discarded as a unit. When a function symbol is discarded, this allows
allows linker to discard counters, data and values associated with that
function symbol as well.
Note that `noduplicates` COMDAT is lowered to zero-flag section group in
ELF. We only set this for functions that aren't already in a COMDAT and
for those that don't have available_externally linkage since we already
use regular COMDAT groups for those.
Differential Revision: https://reviews.llvm.org/D96757
C identifier name input sections such as __llvm_prf_* are GC roots so
they cannot be discarded. In LLD, the SHF_LINK_ORDER flag overrides the
C identifier name semantics.
The !associated metadata may be attached to a global object declaration
with a single argument that references another global object, and it
gets lowered to SHF_LINK_ORDER flag. When a function symbol is discarded
by the linker, setting up !associated metadata allows linker to discard
counters, data and values associated with that function symbol.
Note that !associated metadata is only supported by ELF, it does not have
any effect on non-ELF targets.
Differential Revision: https://reviews.llvm.org/D76802
See RFC for background:
http://lists.llvm.org/pipermail/llvm-dev/2020-June/142744.html
Follow on companion to the clang/llvm instrumentation support in D85948
and committed earlier.
This patch adds the compiler-rt runtime support for the memory
profiling.
Note that much of this support was cloned from asan (and then greatly
simplified and renamed). For example the interactions with the
sanitizer_common allocators, error handling, interception, etc.
The bulk of the memory profiling specific code can be found in the
MemInfoBlock, MemInfoBlockCache, and related classes defined and used
in memprof_allocator.cpp.
For now, the memory profile is dumped to text (stderr by default, but
honors the sanitizer_common log_path flag). It is dumped in either a
default verbose format, or an optional terse format.
This patch also adds a set of tests for the core functionality.
Differential Revision: https://reviews.llvm.org/D87120
Clang relies on existence of certain symbols that are normally
provided by crtbegin.o/crtend.o. However, LLVM does not currently
provide implementation of these files, instead relying on either
libgcc or implementations provided as part of the system.
This change provides an initial implementation of crtbegin.o/crtend.o
that can be used on system that don't provide crtbegin.o/crtend.o as
part of their C library.
Differential Revision: https://reviews.llvm.org/D28791
llvm-svn: 359591
Clang relies on existence of certain symbols that are normally
provided by crtbegin.o/crtend.o. However, LLVM does not currently
provide implementation of these files, instead relying on either
libgcc or implementations provided as part of the system.
This change provides an initial implementation of crtbegin.o/crtend.o
that can be used on system that don't provide crtbegin.o/crtend.o as
part of their C library.
Differential Revision: https://reviews.llvm.org/D28791
llvm-svn: 359576
Summary:
The current install-clang-headers target installs clang's resource
directory headers. This is different from the install-llvm-headers
target, which installs LLVM's API headers. We want to introduce the
corresponding target to clang, and the natural name for that new target
would be install-clang-headers. Rename the existing target to
install-clang-resource-headers to free up the install-clang-headers name
for the new target, following the discussion on cfe-dev [1].
I didn't find any bots on zorg referencing install-clang-headers. I'll
send out another PSA to cfe-dev to accompany this rename.
[1] http://lists.llvm.org/pipermail/cfe-dev/2019-February/061365.html
Reviewers: beanz, phosek, tstellar, rnk, dim, serge-sans-paille
Subscribers: mgorny, javed.absar, jdoerfert, #sanitizers, openmp-commits, lldb-commits, cfe-commits, llvm-commits
Tags: #clang, #sanitizers, #lldb, #openmp, #llvm
Differential Revision: https://reviews.llvm.org/D58791
llvm-svn: 355340
LLVM started exporting targets for utilites with https://reviews.llvm.org/rL350959, which broke compiler-rt standalone builds because it was used to define FileCheck manually.
Changed this, so FileCheck gets imported now.
llvm-svn: 350973
Summary:
Enable tests on Windows and make check-fuzzer pass on it. Make
check-fuzzer pass on Windows by fixing libFuzzer, fixing tests, and by
disabling tests on Windows. Most of these are disabled temporarily as
support for the tests and the features they test will be added
incrementally. Other tests will not be enabled since they require
things that are not on Windows (eg: afl_driver tests). Every test
that was explicitly disabled on Windows has a comment explaining why
(unless obvious like merge-posix.test).
The lit.cfg file was modified to support running tests on windows.
fuzzer-dirs.test was fixed by making the Windows implementation print
the same error message as the posix version.
merge-control-file.test was fixed by making the test binary end with
the ".exe" extension (on all platforms).
Patch By: metzman
Reviewers: morehouse
Reviewed By: morehouse
Subscribers: srhines, mgorny
Differential Revision: https://reviews.llvm.org/D51549
llvm-svn: 341385
Summary:
Port libFuzzer to windows-msvc.
This patch allows libFuzzer targets to be built and run on Windows, using -fsanitize=fuzzer and/or fsanitize=fuzzer-no-link. It allows these forms of coverage instrumentation to work on Windows as well.
It does not fix all issues, such as those with -fsanitize-coverage=stack-depth, which is not usable on Windows as of this patch.
It also does not fix any libFuzzer integration tests. Nearly all of them fail to compile, fixing them will come in a later patch, so libFuzzer tests are disabled on Windows until them.
Patch By: metzman
Reviewers: morehouse, rnk
Reviewed By: morehouse, rnk
Subscribers: #sanitizers, delcypher, morehouse, kcc, eraman
Differential Revision: https://reviews.llvm.org/D51022
llvm-svn: 341082
Summary:
Port libFuzzer to windows-msvc.
This patch allows libFuzzer targets to be built and run on Windows, using -fsanitize=fuzzer and/or fsanitize=fuzzer-no-link. It allows these forms of coverage instrumentation to work on Windows as well.
It does not fix all issues, such as those with -fsanitize-coverage=stack-depth, which is not usable on Windows as of this patch.
It also does not fix any libFuzzer integration tests. Nearly all of them fail to compile, fixing them will come in a later patch, so libFuzzer tests are disabled on Windows until them.
Reviewers: morehouse, rnk
Reviewed By: morehouse, rnk
Subscribers: #sanitizers, delcypher, morehouse, kcc, eraman
Differential Revision: https://reviews.llvm.org/D51022
llvm-svn: 340949
Summary:
Port libFuzzer to windows-msvc.
This patch allows libFuzzer targets to be built and run on Windows, using -fsanitize=fuzzer and/or fsanitize=fuzzer-no-link. It allows these forms of coverage instrumentation to work on Windows as well.
It does not fix all issues, such as those with -fsanitize-coverage=stack-depth, which is not usable on Windows as of this patch.
It also does not fix any libFuzzer integration tests. Nearly all of them fail to compile, fixing them will come in a later patch, so libFuzzer tests are disabled on Windows until them.
Patch By: metzman
Reviewers: morehouse, rnk
Reviewed By: morehouse, rnk
Subscribers: morehouse, kcc, eraman
Differential Revision: https://reviews.llvm.org/D51022
llvm-svn: 340860
Summary:
- Enabling libfuzzer on OpenBSD
- OpenBSD can t support asan, msan ... the tests can t be run.
Patch by David CARLIER
Reviewers: eugenis, phosek, vitalybuka
Reviewed By: vitalybuka
Subscribers: srhines, mgorny, krytarowski, llvm-commits, #sanitizers
Differential Revision: https://reviews.llvm.org/D44877
llvm-svn: 329631
Summary:
ShadowCallStack does not yet have a runtime provided by compiler-rt, but
this change includes simple tests that make use of a very minimal
runtime in test/shadowcallstack/minimal_runtime.h
Reviewers: pcc, kcc, delcypher, eugenis, filcab
Reviewed By: pcc
Subscribers: kubamracek, mgorny, delcypher, llvm-commits, #sanitizers, kcc
Differential Revision: https://reviews.llvm.org/D44803
llvm-svn: 329210
Multi-config CMake generators need lit to be able to resolve paths of
artifacts from previous build steps at lit time, rather than expect them
to be fully resolved at CMake time as they may contain the build mode.
Differential Revision: https://reviews.llvm.org/D38471
llvm-svn: 318037
Make it possible to control building profile runtime separately from
other options. Before r313549, the profile runtime building was
controlled along with sanitizers. However, since that commit it is built
unconditionally which results in multiple builds for people building
different runtimes separately.
Differential Revision: https://reviews.llvm.org/D38441
llvm-svn: 314646
This should fix an issue which arises when running check-compiler-rt on
the coverage bot:
http://green.lab.llvm.org/green/job/clang-stage2-coverage-R_build/1590/
The bot doesn't build the sanitizers, but the check-compiler-rt target
always expects the profile runtime to exist.
llvm-svn: 313549
Breaks buildbot with
CMake Error at projects/compiler-rt/test/CMakeLists.txt:76 (add_dependencies):
The dependency target "check-ubsan-minimal" of target "check-ubsan" does
not exist.
llvm-svn: 312295
Summary: This way we don't need to add check-ubsan-minimal steps to all the bots.
Reviewers: vitalybuka
Subscribers: mgorny, llvm-commits
Differential Revision: https://reviews.llvm.org/D37350
llvm-svn: 312291
Resulting library binaries will be named libclang_rt.fuzzer*, and will
be placed in Clang toolchain, allowing redistribution.
Differential Revision: https://reviews.llvm.org/D36908
llvm-svn: 311407
Summary: Cleaner than computing the intersection for each possible sanitizer
Reviewers: compnerd, beanz
Subscribers: llvm-commits, mgorny
Differential Revision: https://reviews.llvm.org/D34693
llvm-svn: 306453
Summary: This allows check-all to be used when only a subset of the sanitizers are built.
Reviewers: beanz, compnerd, rnk, pcc
Subscribers: llvm-commits, mgorny
Differential Revision: https://reviews.llvm.org/D34644
llvm-svn: 306450
Summary: This allows check-all to be used when only a subset of the sanitizers are built.
Reviewers: beanz, compnerd
Subscribers: llvm-commits, mgorny
Differential Revision: https://reviews.llvm.org/D34644
llvm-svn: 306415
Cover the sanitizer tests with COMPILER_RT_BUILD_SANITIZERS
conditional, and add COMPILER_RT_BUILD_XRAY conditional to the xray
tests. This makes it possible to do a pure-builtins build with tests
enabled.
Differential Revision: https://reviews.llvm.org/D32489
llvm-svn: 301387
This predicate compares the host's marketing OS version to one passed as
argument. Currently, only darwin targets are supported. This is done by parsing
the SystemVersion.plist file.
Also added in this patch is some lit testing infrastructure for builtins, which
previously had none. This part of the patch was written by Alex Lorenz (with
some minor modifications).
This patch is part of a feature I proposed here:
http://lists.llvm.org/pipermail/cfe-dev/2016-July/049851.html
Differential revision: https://reviews.llvm.org/D30136
llvm-svn: 297382