Lldb uses a pty to read/write to the standard input and output of the
debugged process. For host processes this would be automatically set up
by Target::FinalizeFileActions. The Qemu platform is in a unique
position of not really being a host platform, but not being remote
either. It reports IsHost() = false, but it is sufficiently host-like
that we can use the usual pty mechanism.
This patch adds the necessary glue code to enable pty redirection. It
includes a small refactor of Target::FinalizeFileActions and
ProcessLaunchInfo::SetUpPtyRedirection to reduce the amount of
boilerplate that would need to be copied.
I will note that qemu is not able to separate output from the emulated
program from the output of the emulator itself, so the two will arrive
intertwined. Normally this should not be a problem since qemu should not
produce any output during regular operation, but some output can slip
through in case of errors. This situation should be pretty obvious (to a
human), and it is the best we can do anyway.
For testing purposes, and inspired by lldb-server tests, I have extended
the mock emulator with the ability "program" the behavior of the
"emulated" program via command-line arguments.
Differential Revision: https://reviews.llvm.org/D114796
Recognize FreeBSD vmcores (kernel core dumps) through OS ABI = 0xFF
+ ELF version = 0, and do not process them via the elf-core plugin.
While these files use ELF as a container format, they contain raw memory
dump rather than proper VM segments and therefore are not usable
to the elf-core plugin.
Differential Revision: https://reviews.llvm.org/D114967
This patch fixes:
lldb/source/Plugins/Platform/Windows/PlatformWindows.cpp:386:13:
error: comparison between NULL and non-pointer ('lldb::addr_t' (aka
'unsigned long') and NULL) [-Werror,-Wnull-arithmetic]
This implements `DoLoadImage` and `UnloadImage` in the Windows platform
plugin modelled after the POSIX platform plugin. This was previously
unimplemented and resulted in a difficult to decipher error without any
logging.
This implementation is intended to support enables the use of LLDB's
Swift REPL on Windows.
Paths which are added to the library search path are persistent and
applied to all subsequent loads. This can be adjusted in the future by
storing all the cookies and restoring the path prior to returning from
the helper. However, the dynamic path count makes this a bit more
challenging.
Reviewed By: @JDevlieghere
Differential Revision: https://reviews.llvm.org/D77287
minidebuginfo-set-and-hit-breakpoint.test is failing on Arm/Linux most
probably due to an ill formed binary after removal of certain sections
from executable. I am marking it as XFAIL for further investigation.
Some pythons are configured to set platlib somewhere outside of their
sys.prefix. It's important that we at least use some reasonable
default for LLDB_PYTHON_RELATIVE_PATH even in that case, because
even if the user overrides it on the cmake invocation, cmake will
still be called without the override in order to build tablegen.
Reviewed By: JDevlieghere, clayborg
Differential Revision: https://reviews.llvm.org/D114973
When debugging a Simulator process on macOS (e.g. the iPhone simulator),
the process will have both a dyld, and a dyld_sim present. The dyld_sim
is an iOS Simulator binary. The dyld is a macOS binary. Both are
MH_DYLINKER filetypes. lldb needs to identify & set a breakpoint in
dyld, so it has to distinguish between these two.
Previously lldb was checking if the inferior target was x86 (indicating
macOS) and the OS of the MH_DYLINKER binary was iOS/watchOS/etc -- if
so, then this is dyld_sim and we should ignore it. Now with arm64
macOS systems, this check was invalid, and we would set our breakpoint
for new binaries being loaded in dyld_sim, causing binary loading to
be missed by lldb.
This patch uses the Target's ArchSpec triple environment, to see if
this process is a simulator process. If this is a Simulator process,
then we only recognize a MH_DYLINKER binary with OS type macOS as
being dyld.
This patch also removes some code that handled pre-2016 era debugservers
which didn't give us the OS type for each binary. This was only being
used on macOS, where we don't need to handle the presence of very old
debugservers.
Differential Revision: https://reviews.llvm.org/D115001
rdar://85907839
Only lldb-arm-ubuntu is failing after https://reviews.llvm.org/D114288 and there isn't enough input context to see why this is failing. It works on x86_64 linux just fine.
These tests work fine with VS2017, but become more flaky with VS2019 and the buildbot is about to get upgraded.
Differential Revision: https://reviews.llvm.org/D114907
Split TestCxxChar8_t into two parts: one that check reading variables
without a process and another part with. This allows us to skip the
former on Apple Silicon, where lack of support for chained fix-ups
causes the test to fail.
Differential revision: https://reviews.llvm.org/D114819
Symbol table parsing has evolved over the years and many plug-ins contained duplicate code in the ObjectFile::GetSymtab() that used to be pure virtual. With this change, the "Symbtab *ObjectFile::GetSymtab()" is no longer virtual and will end up calling a new "void ObjectFile::ParseSymtab(Symtab &symtab)" pure virtual function to actually do the parsing. This helps centralize the code for parsing the symbol table and allows the ObjectFile base class to do all of the common work, like taking the necessary locks and creating the symbol table object itself. Plug-ins now just need to parse when they are asked to parse as the ParseSymtab function will only get called once.
This is a retry of the original patch https://reviews.llvm.org/D113965 which was reverted. There was a deadlock in the Manual DWARF indexing code during symbol preloading where the module was asked on the main thread to preload its symbols, and this would in turn cause the DWARF manual indexing to use a thread pool to index all of the compile units, and if there were relocations on the debug information sections, these threads could ask the ObjectFile to load section contents, which could cause a call to ObjectFileELF::RelocateSection() which would ask for the symbol table from the module and it would deadlock. We can't lock the module in ObjectFile::GetSymtab(), so the solution I am using is to use a llvm::once_flag to create the symbol table object once and then lock the Symtab object. Since all APIs on the symbol table use this lock, this will prevent anyone from using the symbol table before it is parsed and finalized and will avoid the deadlock I mentioned. ObjectFileELF::GetSymtab() was never locking the module lock before and would put off creating the symbol table until somewhere inside ObjectFileELF::GetSymtab(). Now we create it one time inside of the ObjectFile::GetSymtab() and immediately lock it which should be safe enough. This avoids the deadlocks and still provides safety.
Differential Revision: https://reviews.llvm.org/D114288
727bd89b60 broke the UBSan decorator. The decorator compiles a custom
source code snippet that exposes UB and verifies the presence of a UBSan
symbol in the generated binary. The aforementioned commit broke both by
compiling a snippet without UB and discarding the result.
Make sure to add the PrivateFrameworks directory to the frameworks path
when using an internal SDK. This is necessary for the "on-device" test
suite.
rdar://84519268
Differential revision: https://reviews.llvm.org/D114742
This adds a new platform class, whose job is to enable running
(debugging) executables under qemu.
(For general information about qemu, I recommend reading the RFC thread
on lldb-dev
<https://lists.llvm.org/pipermail/lldb-dev/2021-October/017106.html>.)
This initial patch implements the necessary boilerplate as well as the
minimal amount of functionality needed to actually be able to do
something useful (which, in this case means debugging a fully statically
linked executable).
The knobs necessary to emulate dynamically linked programs, as well as
to control other aspects of qemu operation (the emulated cpu, for
instance) will be added in subsequent patches. Same goes for the ability
to automatically bind to the executables of the emulated architecture.
Currently only two settings are available:
- architecture: the architecture that we should emulate
- emulator-path: the path to the emulator
Even though this patch is relatively small, it doesn't lack subtleties
that are worth calling out explicitly:
- named sockets: qemu supports tcp and unix socket connections, both of
them in the "forward connect" mode (qemu listening, lldb connecting).
Forward TCP connections are impossible to realise in a race-free way.
This is the reason why I chose unix sockets as they have larger, more
structured names, which can guarantee that there are no collisions
between concurrent connection attempts.
- the above means that this code will not work on windows. I don't think
that's an issue since user mode qemu does not support windows anyway.
- Right now, I am leaving the code enabled for windows, but maybe it
would be better to disable it (otoh, disabling it means windows
developers can't check they don't break it)
- qemu-user also does not support macOS, so one could contemplate
disabling it there too. However, macOS does support named sockets, so
one can even run the (mock) qemu tests there, and I think it'd be a
shame to lose that.
Differential Revision: https://reviews.llvm.org/D114509
The LLDBSWIGPython functions had (at least) two problems:
- There wasn't a single source of truth (a header file) for the
prototypes of these functions. This meant that subtle differences
in copies of function declarations could go by undetected. And
not-so-subtle differences would result in strange runtime failures.
- All of the declarations had to have an extern "C" interface, because
the function definitions were being placed inside and extert "C" block
generated by swig.
This patch fixes both problems by moving the function definitions to the
%header block of the swig files. This block is not surrounded by extern
"C", and seems more appropriate anyway, as swig docs say it is meant for
"user-defined support code" (whereas the previous %wrapper code was for
automatically-generated wrappers).
It also puts the declarations into the SWIGPythonBridge header file
(which seems to have been created for this purpose), and ensures it is
included by all code wishing to define or use these functions. This
means that any differences in the declaration become a compiler error
instead of a runtime failure.
Differential Revision: https://reviews.llvm.org/D114369
This reverts commit fac3f20de5.
I found this has broken how we detect the last memory region in
GetMemoryRegions/"memory region" command.
When you're debugging an AArch64 system with pointer authentication,
the ABI plugin will remove the top bit from the end address of the last
user mapped area.
(lldb)
[0x0000fffffffdf000-0x0001000000000000) rw- [stack]
ABI plugin removes anything above the 48th bit (48 bit virtual addresses
by default on AArch64, leaving an address of 0.
(lldb)
[0x0000000000000000-0x0000000000400000) ---
You get back a mapping for 0 and get into an infinite loop.
Certain commands like 'memory write', 'register read' etc all use
the OptionGroupFormat options but the help usage text for those
options is not customized to those commands.
One such example is:
(lldb) help memory read
-s <byte-size> ( --size <byte-size> )
The size in bytes to use when displaying with the selected format.
(lldb) help memory write
-s <byte-size> ( --size <byte-size> )
The size in bytes to use when displaying with the selected format.
This patch allows such commands to overwrite the help text for the options
in the OptionGroupFormat group as needed and fixes help text of memory write.
llvm.org/pr49018.
Reviewed By: DavidSpickett
Differential Revision: https://reviews.llvm.org/D114448
Currently the 'memory write' command allows specifying the values when
writing the file contents to memory but the values are actually ignored. This
patch fixes that by erroring out when values are specified in such cases.
Reviewed By: DavidSpickett
Differential Revision: https://reviews.llvm.org/D114544
On Linux some C++ and C include files reside in target specific directories, like /usr/include/x86_64-linux-gnu.
Patch adds them to libclang, so LLDB jitter has more chances to compile expression.
OS Laboratory. Huawei Russian Research Institute. Saint-Petersburg
Reviewed By: teemperor
Differential Revision: https://reviews.llvm.org/D110827
Although I cannot find any mention of this in the specification, both
gdb and lldb agree on sending an initial + packet after establishing the
connection.
OTOH, gdbserver and lldb-server behavior is subtly different. While
lldb-server *expects* the initial ack, and drops the connection if it is
not received, gdbserver will just ignore a spurious ack at _any_ point
in the connection.
This patch changes lldb's behavior to match that of gdb. An ACK packet
is ignored at any point in the connection (except when expecting an ACK
packet, of course). This is inline with the "be strict in what you
generate, and lenient in what you accept" philosophy, and also enables
us to remove some special cases from the server code. I've extended the
same handling to NAK (-) packets, mainly because I don't see a reason to
treat them differently here.
(The background here is that we had a stub which was sending spurious
+ packets. This bug has since been fixed, but I think this change makes
sense nonetheless.)
Differential Revision: https://reviews.llvm.org/D114520
This code, added in rL197579 (Dec 2013) is supposed to work around what
was presumably a qemu bug, where it would send unsolicited stop-reply
packets after the initial connection.
At present, qemu does not exhibit such behavior. Also, the 10ms delay
introduced by this code is sufficient to mask bugs in other stubs, but
it is not sufficient to *reliably* mask those bugs. This resulted in
flakyness in one of our stubs, which was (incorrectly) sending a +
packet at the start of the connection, resulting in a small-but-annoying
number of dropped connections.
Differential Revision: https://reviews.llvm.org/D114529
Right now if the LLDB is compiled under the windows with static vcruntime library, the -o and -k commands will not work.
The problem is that the LLDB create FILE* in lldb.exe and pass it to liblldb.dll which is an object from CRT.
Since the CRT is statically linked each of these module has its own copy of the CRT with it's own global state and the LLDB should not share CRT objects between them.
In this change I moved the logic of creating FILE* out of commands stream from Driver class to SBDebugger.
To do this I added new method: SBError SBDebugger::SetInputStream(SBStream &stream)
Command to build the LLDB:
cmake -G Ninja -DLLVM_ENABLE_PROJECTS="clang;lldb;libcxx" -DLLVM_USE_CRT_RELEASE="MT" -DLLVM_USE_CRT_MINSIZEREL="MT" -DLLVM_USE_CRT_RELWITHDEBINFO="MT" -DP
YTHON_HOME:FILEPATH=C:/Python38 -DCMAKE_C_COMPILER:STRING=cl.exe -DCMAKE_CXX_COMPILER:STRING=cl.exe ../llvm
Command which will fail:
lldb.exe -o help
See discord discussion for more details: https://discord.com/channels/636084430946959380/636732809708306432/854629125398724628
This revision is for the further discussion.
Reviewed By: teemperor
Differential Revision: https://reviews.llvm.org/D104413
I don't see a reason why not to. If we allows lookup functions by full names,
I can change the test case in D113930 to use `lldb-test symbols --find=function --name=full::name --function-flags=full ...`,
though the duplicate method decl prolem is still there for `lldb-test symbols --dump-ast`.
That's a seprate bug, we can fix it later.
Differential Revision: https://reviews.llvm.org/D114467
This diff is adding the capping_size determination for the list and forward list, to limit the number of children to be displayed. Also it modifies and unifies tests for libcxx and libstdcpp list data formatter.
Reviewed By: wallace
Differential Revision: https://reviews.llvm.org/D114433
This diff is avoiding the size limitation introduced by the capping size for the libcxx and libcpp bitset data formatters.
Reviewed By: wallace
Differential Revision: https://reviews.llvm.org/D114461
Aaron Ballman