Building and installing it
~~~~~~~~~~~~~~~~~~~~~~~~~~
To build/install from the GIT repository or from a distribution
tarball, refer to the section with the same name in README.
Building Valgrind requires autoconf, GNU make and a suitable C
compiler.
Building and not installing it
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To run Valgrind without having to install it, run coregrind/valgrind
with the VALGRIND_LIB environment variable set, where <dir> is the root
of the source tree (and must be an absolute path). Eg:
VALGRIND_LIB=~/grind/head4/.in_place ~/grind/head4/coregrind/valgrind
This allows you to compile and run with "make" instead of "make install",
saving you time.
Or, you can use the 'vg-in-place' script which does that for you.
I recommend compiling with "make --quiet" to further reduce the amount of
output spewed out during compilation, letting you actually see any errors,
warnings, etc.
Building a distribution tarball
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To build a distribution tarball from the valgrind sources:
make dist
In addition to compiling, linking and packaging everything up, the command
will also attempt to build the documentation.
If you only want to test whether the generated tarball is complete and runs
regression tests successfully, building documentation is not needed.
make dist BUILD_ALL_DOCS=no
If you insist on building documentation some embarrassing instructions
can be found in docs/README.
Running the regression tests
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Running the regression tests requires GNU sed, python 3.9 or later, gdb,
and a suitable C++ compiler
To build and run all the regression tests, run "make [--quiet] regtest".
To run a subset of the regression tests, execute:
perl tests/vg_regtest <name>
where <name> is a directory (all tests within will be run) or a single
.vgtest test file, or the name of a program which has a like-named .vgtest
file. Eg:
perl tests/vg_regtest memcheck
perl tests/vg_regtest memcheck/tests/badfree.vgtest
perl tests/vg_regtest memcheck/tests/badfree
Running the performance tests
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To build and run all the performance tests, run "make [--quiet] perf".
To run a subset of the performance suite, execute:
perl perf/vg_perf <name>
where <name> is a directory (all tests within will be run) or a single
.vgperf test file, or the name of a program which has a like-named .vgperf
file. Eg:
perl perf/vg_perf perf/
perl perf/vg_perf perf/bz2.vgperf
perl perf/vg_perf perf/bz2
To compare multiple versions of Valgrind, use the --vg= option multiple
times. For example, if you have two Valgrinds next to each other, one in
trunk1/ and one in trunk2/, from within either trunk1/ or trunk2/ do this to
compare them on all the performance tests:
perl perf/vg_perf --vg=../trunk1 --vg=../trunk2 perf/
Writing regression tests
~~~~~~~~~~~~~~~~~~~~~~~~
Each tool has a tests directory containing regression tests. There is also
the gdbserver_tests directory at the top level. Test directories may have
architecture, OS and and architecture-OS sub-directories for tests that are
specific to one architecture, OS or both.
Once you have written a C or C++ executable that performs the required
tests you will have to modify and create several files. The new files that
will need adding are
(a) a .vgtest file, which controls the test
(b) a .stderr.exp file, which is the golden reference for any Valgrind output
Note that even if Valgrind doesn't produce any output you will need to
create an empty .stderr.exp file.
(c) [optional] a .stdout.exp file, the golden reference for any output from the
test executable
(d) [optional] filter files (see the test directories for examples).
Quite often the output will depend on the platform the test is run on.
Getting the tests to be 'portable' can require filtering or adding multiple
.stderr.exp reference files.
If the test only runs under certain conditions like the availability of functions
in libc or C++ standard versions you will need to modify configure.ac in the
top level directory. See AC_CHECK_FUNCS and the various blocks starting with
AC_MSG_CHECKING.
In the test directory, modify Makefile.am. Add to EXTRA_DIST the .vgtest,
.stderr.exp and .stderr.out files. Add any filters to dist_noinst_SCRIPTS.
Add the test executable name to check_PROGRAMS. Try to respect the
formatting and alphabetical ordering of the Makefile.am. For simple C files that is
sufficient. If you needed to add a feature test to configure.ac then you should
use the same condition to add the executable name to check_PROGRAMS. If the
executable uses C++ you need to add exename_SOURCES. If the executable needs
special compilation or link options, use exename_CFLAGS, exename_CXXFLAGS,
exename_LDFLAGS or exename_LDADD. Finally in Makefile.am it's nice not to
have any warnings, even if they were done on purpose. See configure.ac
and various Makefile.am files for examples of using FLAG_W_*.
The vgtest file contains the instructions for running the test. Typically
it will contain (with examples in quotes)
(a) the name of the test executable: "prog: exename"
(b) arguments for the test executable: "args: hello world"
(c) arguments for the Valgrind tool: "vgopts: -q"
(d) [optional] a check for prerequisites: "prereq: ! ../../tests/os_test darwin"
(e) [optional] a filter: "stderr_filter: filter_fdleak"
See tests/vg_regtest for a full description of all possible vgtest directives.
The easiest way to generate the expected files is to run the test. Create empty
files with touch (otherwise the test won't run) then run the test from the
top directory using perl and vg_regtest script (as in the "Running the
regression tests" section. Then copy "tool/tests/newtest.stderr.out" to
"tool/tests/newtest.stderr.exp". It is better to generate the .stdout.exp
file directly from the testcase. You can do that by redirecting stdout to
the expected file, for instance (in the test directory)
./newtest arg1 arg2 > newtest.stdout.exp
This is not always possible - sometimes there are tests that depend on the use
of client requests or have imperfect emulation of opcodes.
Make sure that the test runs and passes.
The last file to change is .gitignore in the top directory. Add a new entry,
for example "/tool/tests/newtest".
Check for mistakes in Makefile.am. In the top directory run
make post-regtest-checks
You should only see
...checking makefile consistency
...checking header files and include directives
and no messages related to EXTRA_DIST.
Commit access and try branches
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To get commit access to the valgrind git repository on sourceware
you will have to ask an existing developer and fill in the following
form: https://sourceware.org/cgi-bin/pdw/ps_form.cgi
Every developer with commit access can use try branches. If you want to try a
branch before pushing you can push to a special named try branch as follows:
git push origin $BRANCH:users/$USERNAME/try-$BRANCH
Where $BRANCH is the branch name and $USERNAME is your user name.
You can see the status of the builders here:
https://builder.sourceware.org/buildbot/#/builders?tags=valgrind-try
The buildbot will also sent the patch author multiple success/failure emails.
Afterwards you can delete the branch again:
git push origin :users/$USERNAME/try-$BRANCH
Debugging Valgrind with GDB
~~~~~~~~~~~~~~~~~~~~~~~~~~~
To debug the valgrind launcher program (<prefix>/bin/valgrind) just
run it under gdb in the normal way.
Debugging the main body of the valgrind code (and/or the code for
a particular tool) requires a bit more trickery but can be achieved
without too much problem by following these steps:
(1) Set VALGRIND_LAUNCHER to point to the valgrind executable. Eg:
export VALGRIND_LAUNCHER=/usr/local/bin/valgrind
or for an uninstalled version in a source directory $DIR:
export VALGRIND_LAUNCHER=$DIR/coregrind/valgrind
export VALGRIND_LIB=$DIR/.in_place
VALGRIND_LIB is where the default.supp and vgpreload_ libraries
are found (which is under /usr/libexec/valgrind for an installed
version).
(2) Run gdb on the tool executable. Eg:
gdb /usr/local/lib/valgrind/lackey-ppc32-linux
or
gdb $DIR/.in_place/memcheck-x86-linux
(3) Do "handle SIGSEGV SIGILL nostop noprint" in GDB to prevent GDB from
stopping on a SIGSEGV or SIGILL:
(gdb) handle SIGILL SIGSEGV nostop noprint
If you are using lldb, then the equivalent command is
(lldb) pro hand -p true -s false -n false SIGILL SIGSEGV
(4) Set any breakpoints you want and proceed as normal for gdb. The
macro VG_(FUNC) is expanded to vgPlain_FUNC, so If you want to set
a breakpoint VG_(do_exec_inner), you could do like this in GDB:
(gdb) b vgPlain_do_exec_inner
Note: This is just an example, for various reasons internal
function names might be renamed or optimized out
(for example when building with --enable-lto).
(5) Run the tool with required options (the --tool option is required
for correct setup), e.g.
(gdb) run --tool=lackey pwd
Steps (1)--(3) can be put in a .gdbinit file, but any directory names must
be fully expanded (ie. not an environment variable).
A different and possibly easier way is as follows:
(1) Run Valgrind as normal, but add the flag --wait-for-gdb=yes. This
puts the tool executable into a wait loop soon after it gains
control. This delays startup for a few seconds.
(2) In a different shell, do "gdb /proc/<pid>/exe <pid>", where
<pid> you read from the output printed by (1). This attaches
GDB to the tool executable, which should be in the above mentioned
wait loop.
(3) Do "cont" to continue. After the loop finishes spinning, startup
will continue as normal. Note that comment (3) above re passing
signals applies here too.
The default build of Valgrind uses "-g -O2". This is OK most of the
time, but with sophisticated optimization it can be difficult to
see the contents of variables. A quick way to get to see function
variables is to temporarily add "__attribute__((optnone))" before
the function definition and rebuild. Alternatively modify
Makefile.all.am and remove -O2 from AM_CFLAGS_BASE. That will
require you to reconfigure and rebuild Valgrind.
Self-hosting
~~~~~~~~~~~~
This section explains:
(A) How to configure Valgrind to run under Valgrind.
Such a setup is called self hosting, or outer/inner setup.
(B) How to run Valgrind regression tests in a 'self-hosting' mode,
e.g. to verify Valgrind has no bugs such as memory leaks.
(C) How to run Valgrind performance tests in a 'self-hosting' mode,
to analyse and optimise the performance of Valgrind and its tools.
(A) How to configure Valgrind to run under Valgrind:
(1) Check out 2 trees, "Inner" and "Outer". Inner runs the app
directly. Outer runs Inner.
(2) Configure Inner with --enable-inner and build as usual.
(3) Configure Outer normally and build+install as usual.
Note: You must use a "make install"-ed valgrind.
Do *not* use vg-in-place for the Outer valgrind.
(4) Choose a very simple program (date) and try
outer/.../bin/valgrind --sim-hints=enable-outer --trace-children=yes \
--smc-check=all-non-file \
--run-libc-freeres=no --tool=cachegrind -v \
inner/.../vg-in-place --vgdb-prefix=./inner --tool=none -v prog
If you omit the --trace-children=yes, you'll only monitor Inner's launcher
program, not its stage2. Outer needs --run-libc-freeres=no, as otherwise
it will try to find and run __libc_freeres in the inner, while libc is not
used by the inner. Inner needs --vgdb-prefix=./inner to avoid inner
gdbserver colliding with outer gdbserver.
Currently, inner does *not* use the client request
VALGRIND_DISCARD_TRANSLATIONS for the JITted code or the code patched for
translation chaining. So the outer needs --smc-check=all-non-file to
detect the modified code.
Debugging the whole thing might imply to use up to 3 GDB:
* a GDB attached to the Outer valgrind, allowing
to examine the state of Outer.
* a GDB using Outer gdbserver, allowing to
examine the state of Inner.
* a GDB using Inner gdbserver, allowing to
examine the state of prog.
The whole thing is fragile, confusing and slow, but it does work well enough
for you to get some useful performance data. Inner has most of
its output (ie. those lines beginning with "==<pid>==") prefixed with a '>',
which helps a lot. However, when running regression tests in an Outer/Inner
setup, this prefix causes the reg test diff to fail. Give
--sim-hints=no-inner-prefix to the Inner to disable the production
of the prefix in the stdout/stderr output of Inner.
The allocators in coregrind/m_mallocfree.c and VEX/priv/main_util.h are
annotated with client requests so Memcheck can be used to find leaks
and use after free in an Inner Valgrind.
The Valgrind "big lock" is annotated with helgrind client requests
so Helgrind and DRD can be used to find race conditions in an Inner
Valgrind.
All this has not been tested much, so don't be surprised if you hit problems.
When using self-hosting with an outer Callgrind tool, use '--pop-on-jump'
(on the outer). Otherwise, Callgrind has much higher memory requirements.
(B) Regression tests in an outer/inner setup:
To run all the regression tests with an outer memcheck, do :
perl tests/vg_regtest --outer-valgrind=../outer/.../bin/valgrind \
--all
To run a specific regression tests with an outer memcheck, do:
perl tests/vg_regtest --outer-valgrind=../outer/.../bin/valgrind \
none/tests/args.vgtest
To run regression tests with another outer tool:
perl tests/vg_regtest --outer-valgrind=../outer/.../bin/valgrind \
--outer-tool=helgrind --all
--outer-args allows to give specific arguments to the outer tool,
replacing the default one provided by vg_regtest.
Note: --outer-valgrind must be a "make install"-ed valgrind.
Do *not* use vg-in-place.
When an outer valgrind runs an inner valgrind, a regression test
produces one additional file <testname>.outer.log which contains the
errors detected by the outer valgrind. E.g. for an outer memcheck, it
contains the leaks found in the inner, for an outer helgrind or drd,
it contains the detected race conditions.
The file tests/outer_inner.supp contains suppressions for
the irrelevant or benign errors found in the inner.
A regression test running in the inner (e.g. memcheck/tests/badrw) will
cause the inner to report an error, which is expected and checked
as usual when running the regtests in an outer/inner setup.
However, the outer will often also observe an error, e.g. a jump
using uninitialised data, or a read/write outside the bounds of a heap
block. When the outer reports such an error, it will output the
inner host stacktrace. To this stacktrace, it will append the
stacktrace of the inner guest program. For example, this is an error
reported by the outer when the inner runs the badrw regtest:
==8119== Invalid read of size 2
==8119== at 0x7F2EFD7AF: ???
==8119== by 0x7F2C82EAF: ???
==8119== by 0x7F180867F: ???
==8119== by 0x40051D: main (badrw.c:5)
==8119== by 0x7F180867F: ???
==8119== by 0x1BFF: ???
==8119== by 0x3803B7F0: _______VVVVVVVV_appended_inner_guest_stack_VVVVVVVV_______ (m_execontext.c:332)
==8119== by 0x40055C: main (badrw.c:22)
==8119== Address 0x55cd03c is 4 bytes before a block of size 16 alloc'd
==8119== at 0x2804E26D: vgPlain_arena_malloc (m_mallocfree.c:1914)
==8119== by 0x2800BAB4: vgMemCheck_new_block (mc_malloc_wrappers.c:368)
==8119== by 0x2800BC87: vgMemCheck_malloc (mc_malloc_wrappers.c:403)
==8119== by 0x28097EAE: do_client_request (scheduler.c:1861)
==8119== by 0x28097EAE: vgPlain_scheduler (scheduler.c:1425)
==8119== by 0x280A7237: thread_wrapper (syswrap-linux.c:103)
==8119== by 0x280A7237: run_a_thread_NORETURN (syswrap-linux.c:156)
==8119== by 0x3803B7F0: _______VVVVVVVV_appended_inner_guest_stack_VVVVVVVV_______ (m_execontext.c:332)
==8119== by 0x4C294C4: malloc (vg_replace_malloc.c:298)
==8119== by 0x40051D: main (badrw.c:5)
In the above, the first stacktrace starts with the inner host stacktrace,
which in this case is some JITted code. Such code sometimes contains IPs
that points in the inner guest code (0x40051D: main (badrw.c:5)).
After the separator, we have the inner guest stacktrace.
The second stacktrace gives the stacktrace where the heap block that was
overrun was allocated. We see it was allocated by the inner valgrind
in the client arena (first part of the stacktrace). The second part is
the guest stacktrace that did the allocation.
(C) Performance tests in an outer/inner setup:
To run all the performance tests with an outer cachegrind, do :
perl perf/vg_perf --outer-valgrind=../outer/.../bin/valgrind perf
To run a specific perf test (e.g. bz2) in this setup, do :
perl perf/vg_perf --outer-valgrind=../outer/.../bin/valgrind perf/bz2
To run all the performance tests with an outer callgrind, do :
perl perf/vg_perf --outer-valgrind=../outer/.../bin/valgrind \
--outer-tool=callgrind perf
Note: --outer-valgrind must be a "make install"-ed valgrind.
Do *not* use vg-in-place.
To compare the performance of multiple Valgrind versions, do :
perl perf/vg_perf --outer-valgrind=../outer/.../bin/valgrind \
--outer-tool=callgrind \
--vg=../inner_xxxx --vg=../inner_yyyy perf
(where inner_xxxx and inner_yyyy are the toplevel directories of
the versions to compare).
Cachegrind and cg_diff are particularly handy to obtain a delta
between the two versions.
When the outer tool is callgrind or cachegrind, the following
output files will be created for each test:
<outertoolname>.out.<inner_valgrind_dir>.<tt>.<perftestname>.<pid>
<outertoolname>.outer.log.<inner_valgrind_dir>.<tt>.<perftestname>.<pid>
(where tt is the two letters abbreviation for the inner tool(s) run).
For example, the command
perl perf/vg_perf \
--outer-valgrind=../outer_trunk/install/bin/valgrind \
--outer-tool=callgrind \
--vg=../inner_tchain --vg=../inner_trunk perf/many-loss-records
produces the files
callgrind.out.inner_tchain.no.many-loss-records.18465
callgrind.outer.log.inner_tchain.no.many-loss-records.18465
callgrind.out.inner_tchain.me.many-loss-records.21899
callgrind.outer.log.inner_tchain.me.many-loss-records.21899
callgrind.out.inner_trunk.no.many-loss-records.21224
callgrind.outer.log.inner_trunk.no.many-loss-records.21224
callgrind.out.inner_trunk.me.many-loss-records.22916
callgrind.outer.log.inner_trunk.me.many-loss-records.22916
Printing out problematic blocks
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If you want to print out a disassembly of a particular block that
causes a crash, do the following.
Try running with "--vex-guest-chase=no --trace-flags=10000000
--trace-notbelow=999999". This should print one line for each block
translated, and that includes the address.
Then re-run with 999999 changed to the highest bb number shown.
This will print the one line per block, and also will print a
disassembly of the block in which the fault occurred.
Formatting the code with clang-format
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
clang-format is a tool to format C/C++/... code. The root directory of the
Valgrind tree contains file .clang-format which is a configuration for this tool
and specifies a style for Valgrind. This gives you an option to use
clang-format to easily format Valgrind code which you are modifying.
The Valgrind codebase is not globally formatted with clang-format. It means
that you should not use the tool to format a complete file after making changes
in it because that would lead to creating unrelated modifications.
The right approach is to format only updated or new code. By using an
integration with a text editor, it is possible to reformat arbitrary blocks
of code with a single keystroke. Refer to the upstream documentation which
describes integration with various editors and IDEs:
https://clang.llvm.org/docs/ClangFormat.html.