1 by the expression parser. We now correctly
report that they are of size 0. (C++ structs
are mandated to have nonzero size, and Clang marks
them as being 1 byte in size.)
<rdar://problem/12380800>
llvm-svn: 166256
Added a new setting that allows a python OS plug-in to detect threads and provide registers for memory threads. To enable this you set the setting:
settings set target.process.python-os-plugin-path lldb/examples/python/operating_system.py
Then run your program and see the extra threads.
llvm-svn: 166244
<rdar://problem/12068650>
More fixes to how we handle paths that are used to create a target.
This modification centralizes the location where and how what the user specifies gets resolved. Prior to this fix, the TargetList::CreateTarget variants took a FileSpec object which meant everyone had the opportunity to resolve the path their own way. Now both CreateTarget variants take a "const char *use_exe_path" which allows the TargetList::CreateTarget to centralize where the resolving happens and "do the right thing".
llvm-svn: 166186
LLDB changes argv[0] when debugging a symlink. Now we have the notion of argv0 in the target settings:
target.arg0 (string) =
There is also the program argument that are separate from the first argument that have existed for a while:
target.run-args (arguments) =
When running "target create <exe>", we will place the untouched "<exe>" into target.arg0 to ensure when we run, we run with what the user typed. This has been added to the ProcessLaunchInfo and all other needed places so we always carry around the:
- resolved executable path
- argv0
- program args
Some systems may not support separating argv0 from the resolved executable path and the ProcessLaunchInfo needs to carry all of this information along so that each platform can make that decision.
llvm-svn: 166137
to handle an addition class of early-return instructions we find in arm code:
tail-call optimziation returns where we restore the register state from the
function entry and jump directly (not branch & link) to another function --
when that other function returns, it will return to our caller.
Previously this mid-function epilogue sequence was not being correctly detected.
We would not re-instate the prologue setup instructions for the rest of the function
so unwinds would break from that point until the end of the function.
<rdar://problem/12502597>
llvm-svn: 166081
to work properly; when doing bare-boards rom debugging
force the OS to be one of those when initializing llvm.
<rdar://problem/12504138>
llvm-svn: 166057
This patch fixes an issue where if lldb fails to attach to a process (ie. invalid pid) on Linux, the process monitor thread gets stuck waiting for a signal from the attach thread, which never comes due to not being signaled. It also implements StopOpThread which is used for both attach/launch cases as I'm not aware of any special handling needed for the attach case. Also, propagate 'Error' from the Detach function instead of using a bool.
llvm-svn: 166055
command line to dotest.py, replace / with _ in
the logfile names that mention that compiler so
that we don't try to put log files in weird
places.
llvm-svn: 166038
must push something on the stack for a function call or not. In
x86, the stack pointer is decremented when the caller's pc is saved
on the stack. In arm, the stack pointer and frame pointer don't
necessarily have to change for a function call, although most
functions need to use some stack space during their execution.
Use this information in the RegisterContextLLDB to detect invalid
unwind scenarios more accurately.
<rdar://problem/12348574>
llvm-svn: 166005
I added the ability for a process plug-in to implement custom commands. All the lldb_private::Process plug-in has to do is override:
virtual CommandObject *
GetPluginCommandObject();
This object returned should be a multi-word command that vends LLDB commands. There is a sample implementation in ProcessGDBRemote that is hollowed out. It is intended to be used for sending a custom packet, though the body of the command execute function has yet to be implemented!
llvm-svn: 165861
ConstString Host::GetVendorString();
ConstString Host::GetOSString();
comes from. It now all comes from the Host::GetArchitecture (eSystemDefaultArchitecture) like the Apple build was doing to minimize the number of places that need to be updated when Host::GetArchitecture () is called.
llvm-svn: 165805
Dynamic type code must be efficient and fast. Now it is.
Added ObjC v1 support for getting the complete list of ISA values.
The main flow of the AppleObjCRuntime subclasses is now they must override "virtual bool UpdateISAToDescriptorMap_Impl();". This function will update the complete list of ISA values and create ClassDescriptorSP objects for each one. Now we have the complete list of valid ISA values which we can use for verification when doing dynamic typing.
Refactored a bunch of stuff so that the AppleObjCRuntime subclasses don't have to implement as many functions as they used to.
llvm-svn: 165730
with ~, we need to realpath it. Fixes the case where
settings set target.expr-prefix ~/lldb.prefix.header
wouldn't read this prefix header file. <rdar://problem/12475676>
llvm-svn: 165704
Then make the Thread a Broadcaster, and get it to broadcast when the selected frame is changed (but only from the Command Line) and when Thread::ReturnFromFrame
changes the stack.
Made the Driver use this notification to print the new thread status rather than doing it in the command.
Fixed a few places where people were setting their broadcaster class by hand rather than using the static broadcaster class call.
<rdar://problem/12383087>
llvm-svn: 165640
over to simply update its cache and then look up
the descriptor in the cache. This is fine because
the cache now builds much faster (since descriptors
are minimal).
Metaclasses aren't in the cache, so I switched
the Describe method for class descriptors from using
GetClassDescriptor to manually creating an automatic
ClassDescriptorV2.
llvm-svn: 165579
The following are now derived lazily:
- The name of the class (cached);
- the instance size of the class (not cached);
The following have been removed entirely:
- Whether the class is realized. This is an
implementation detail.
- The contents of the objc_class object. That
object can be read as needed.
- Whether the class is valid. The fact that
we vended a class to begin with means it's
valid. We will only give up looking parts
of it up if they are not in the format we
expect.
llvm-svn: 165567
lighter-weight so that the cache can be populated
faster.
- I Added a ProcessWP to the runtime so I can
take it out of the individual descriptors, saving
space;
- I made the constructors for the descriptors
private so that only the runtime can invoke them;
and
- I removed the constructor that takes a ValueObject
since the logic for using a ValueObject is in the
runtime.
llvm-svn: 165549
whether we try to call an external program to load symbols unconditionally,
or if we check the user's preferences before calling it.
ProcessMachCore now sets CanJIT to false - we can't execute code in a core file.
DynamicLoaderDarwinKernel::OSKextLoadedKextSummary::LoadImageUsingMemoryModule changed
to load the kernel from an on-disk file if at all possible.
Don't load the kext binaries out of memory from the remote systems - their linkedit doesn't
seem to be in a good state and we'll error out down in SymbolVendorMacOSX if we try to use
the in-memory images.
Call Symbols::DownloadObjectAndSymbolFile to get the kext/kernel binary -- the external
program may be able to give us a file path on the local filesystem instead of reading
the binary / dSYM over a network drive every time. Fall back to calling
Target::GetSharedModule() like before if DownloadObjectAndSymbolFile fails.
llvm-svn: 165471
Also added a new option for "log enable" which is "--stack" which will print out a stack backtrace for each log line.
This was used to track down the leaking module issue I fixed last week.
llvm-svn: 165438
if we have a kernel binary, set the target's architecture to match.
Include the target's architecture in the ModuleSpec when we're searching for the
kext binaries on the local system -- otherwise we won't get a specific slice of
a fat file picked out for us and we won't use the returned Module correctly.
Remove the redundant attempt to find a file on the local filesystem from this method.
In ProcessGDBRemote::CheckForKernel(), if we have a kernel binary in memory, mark
the canJIT as false. There is no jitting code in kernel debug sessions.
llvm-svn: 165357
starting lldb I get
% ./lldb -x
Traceback (most recent call last):
File "<string>", line 1, in <module>
File "/private/tmp/build/Debug/LLDB.framework/Versions/A/Resources/Python/lldb/__init__.py", line 9008
raise TypeError("No array item of type %s" % str(type(key)))
^
SyntaxError: invalid syntax
Traceback (most recent call last):
File "<string>", line 1, in <module>
NameError: name 'run_one_line' is not defined
Traceback (most recent call last):
File "<string>", line 1, in <module>
NameError: name 'run_one_line' is not defined
Traceback (most recent call last):
File "<string>", line 1, in <module>
NameError: name 'run_one_line' is not defined
(lldb)
I did a clean build and still got the problem so I'm backing this out until Enrico can
look at it.
llvm-svn: 165356
Document "f <n>" selects frame n.
"t <n>" selects thread n but this was just added to TOT
so most people won't have access to an lldb that accepts it.
llvm-svn: 165332
It is now a regex command alias that more faithfully emulates gdb's
behavior, most importantly, "bt 5" will backtrace 5 frames of the
currently selected thread. "bt all" still backtraces all threads
(unlike gdb) and for users who have learned to use "bt -c 5", that
form is still accepted.
llvm-svn: 165300
often hear feedback from people that having the lldb commands on
the left hand side is non-intuitive -- they say "I want a *gdb* to
*lldb* table, not a *lldb* to *gdb* table". It doesn't seem odious
to go from the right-hand column to the left hand column but I've
heard this same feedback enough that it's also pointless to keep
the format lldb-first, gdb-second when it was an arbitrary choice
to begin with.
llvm-svn: 165294
enabled after we'd found a few bugs that were caused by shadowed
local variables; the most important issue this turned up was
a common mistake of trying to obtain a mutex lock for the scope
of a code block by doing
Mutex::Locker(m_map_mutex);
This doesn't assign the lock object to a local variable; it is
a temporary that has its dtor called immediately. Instead,
Mutex::Locker locker(m_map_mutex);
does what is intended. For some reason -Wshadow happened to
highlight these as shadowed variables.
I also fixed a few obivous and easy shadowed variable issues
across the code base but there are a couple dozen more that
should be fixed when someone has a free minute.
<rdar://problem/12437585>
llvm-svn: 165269
remove the duplicates of this code in ProcessGDBRemote and ProcessKDP.
These two Process plugins will hardcode their DynamicLoader name to be
the DynamicLoaderDarwinKernel so the correct DynamicLoader is picked,
and return the kernel load address as the ImageInfosAddress.
<rdar://problem/12417038>
llvm-svn: 165080
the Symbols::LocateExecutableObjectFile method to locate kexts and
kernels instead of copying them out of the memory of the remote
system. This is the fix for <rdar://problem/12416384>.
Fix a variable shadowing problem in
Symbols::LocateMacOSXFilesUsingDebugSymbols which caused the symbol
rich executable binaries to not be found even if they were listed
in the dSYM Info.plist.
Change Symbols::DownloadObjectAndSymbolFile to ignore dsymForUUID's
negative cache - this is typically being called by the user and we
should try even if there's a incorrect entry in the negative cache.
llvm-svn: 165061
Shared libraries on MacOSX were not properly being removed from the shared
module list when re-running a debug session due to an error in:
Module::MatchesModuleSpec()
llvm-svn: 164991
When attaching to a remote system that does not look like a typical vendor system, and no
executable binary was specified to lldb, check a couple of fixed locations where kernels
running in ASLR mode (slid in memory to a random address) store their load addr when booted
in debug mode, and relocate the symbols or load the kernel wholesale from the host computer
if we can find it.
<rdar://problem/7714201>
llvm-svn: 164888
loaded at a random offset).
To get the kernel's UUID and load address I need to send a kdp
packet so I had to implement the kernel relocation (and attempt to
find the kernel if none was provided to lldb already) in ProcessKDP
-- but this code really properly belongs in DynamicLoaderDarwinKernel.
I also had to add an optional Stream to ConnectRemote so
ProcessKDP::DoConnectRemote can print feedback about the remote kernel's
UUID, load address, and notify the user if we auto-loaded the kernel via
the UUID.
<rdar://problem/7714201>
llvm-svn: 164881
runtime, we read method signatures for both class
and instance methods out of the runtime data.
(lldb) fr var str
(NSString *) str = 0x0000000105000180 @"Hello from '/Volumes/Data/projects/lldb/test/lang/objc/foundation/a.out'"
(lldb) expr str.length
(unsigned long long) $0 = 72
(lldb) expr [NSString stringWithCString:"Hello world!" encoding:1]
(id) $1 = 0x0000000105100050
(lldb) po $1
$1 = 0x0000000105100050 Hello world!
(lldb) fr var array1
(NSArray *) array1 = 0x000000010010a6e0 @"3 objects"
(lldb) expr array1.count
(unsigned long long) $0 = 3
(lldb) expr [array1 objectAtIndex:2]
(id) $1 = 0x00000001000025d0
(lldb) po $1
$1 = 0x00000001000025d0 array1 object3
Notice that both regular and property-style notation
work. I still need to add explicit support for
properties with non-default setters/getters.
This information is only queried if an Objective-C
object does not have debug information for a complete
type available. Otherwise we query debug information
as usual.
llvm-svn: 164878
This checkin adds the capability for LLDB to load plugins from external dylibs that can provide new commands
It exports an SBCommand class from the public API layer, and a new SBCommandPluginInterface
There is a minimal load-only plugin manager built into the debugger, which can be accessed via Debugger::LoadPlugin.
Plugins are loaded from two locations at debugger startup (LLDB.framework/Resources/PlugIns and ~/Library/Application Support/LLDB/PlugIns) and more can be (re)loaded via the "plugin load" command
For an example of how to make a plugin, refer to the fooplugin.cpp file in examples/plugins/commands
Caveats:
Currently, the new API objects and features are not exposed via Python.
The new commands can only be "parsed" (i.e. not raw) and get their command line via a char** parameter (we do not expose our internal Args object)
There is no unloading feature, which can potentially lead to leaks if you overwrite the commands by reloading the same or different plugins
There is no API exposed for option parsing, which means you may need to use getopt or roll-your-own
llvm-svn: 164865
We can now do:
Specify a path to a debug symbols file:
(lldb) add-dsym <path-to-dsym>
Go and download the dSYM file for the "libunc.dylib" module in your target:
(lldb) add-dsym --shlib libunc.dylib
Go and download the dSYM given a UUID:
(lldb) add-dsym --uuid <UUID>
Go and download the dSYM file for the current frame:
(lldb) add-dsym --frame
llvm-svn: 164806
which builds a Debug+Asserts build of Clang and
links LLDB against it. The Debug configuration
builds Clang with Release+Asserts, for faster
linking and smaller memory footprint when debugging
the build LLDB.
llvm-svn: 164573
top-of-tree. Removed all local patches and llvm.zip.
The intent is that fron now on top-of-tree will
always build against LLVM/Clang top-of-tree, and
that problems building will be resolved as they
occur. Stable release branches of LLDB can be
constructed as needed and linked to specific release
branches of LLVM/Clang.
llvm-svn: 164563
Jason Molenda