llvm-project/lldb/source/Core/Module.cpp

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//===-- Module.cpp ----------------------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "lldb/lldb-python.h"
#include "lldb/Core/Error.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/DataBuffer.h"
#include "lldb/Core/DataBufferHeap.h"
#include "lldb/Core/Log.h"
#include "lldb/Core/ModuleList.h"
<rdar://problem/11757916> Make breakpoint setting by file and line much more efficient by only looking for inlined breakpoint locations if we are setting a breakpoint in anything but a source implementation file. Implementing this complex for a many reasons. Turns out that parsing compile units lazily had some issues with respect to how we need to do things with DWARF in .o files. So the fixes in the checkin for this makes these changes: - Add a new setting called "target.inline-breakpoint-strategy" which can be set to "never", "always", or "headers". "never" will never try and set any inlined breakpoints (fastest). "always" always looks for inlined breakpoint locations (slowest, but most accurate). "headers", which is the default setting, will only look for inlined breakpoint locations if the breakpoint is set in what are consudered to be header files, which is realy defined as "not in an implementation source file". - modify the breakpoint setting by file and line to check the current "target.inline-breakpoint-strategy" setting and act accordingly - Modify compile units to be able to get their language and other info lazily. This allows us to create compile units from the debug map and not have to fill all of the details in, and then lazily discover this information as we go on debuggging. This is needed to avoid parsing all .o files when setting breakpoints in implementation only files (no inlines). Otherwise we would need to parse the .o file, the object file (mach-o in our case) and the symbol file (DWARF in the object file) just to see what the compile unit was. - modify the "SymbolFileDWARFDebugMap" to subclass lldb_private::Module so that the virtual "GetObjectFile()" and "GetSymbolVendor()" functions can be intercepted when the .o file contenst are later lazilly needed. Prior to this fix, when we first instantiated the "SymbolFileDWARFDebugMap" class, we would also make modules, object files and symbol files for every .o file in the debug map because we needed to fix up the sections in the .o files with information that is in the executable debug map. Now we lazily do this in the DebugMapModule::GetObjectFile() Cleaned up header includes a bit as well. llvm-svn: 162860
2012-08-30 05:13:06 +08:00
#include "lldb/Core/ModuleSpec.h"
#include "lldb/Core/RegularExpression.h"
<rdar://problem/11757916> Make breakpoint setting by file and line much more efficient by only looking for inlined breakpoint locations if we are setting a breakpoint in anything but a source implementation file. Implementing this complex for a many reasons. Turns out that parsing compile units lazily had some issues with respect to how we need to do things with DWARF in .o files. So the fixes in the checkin for this makes these changes: - Add a new setting called "target.inline-breakpoint-strategy" which can be set to "never", "always", or "headers". "never" will never try and set any inlined breakpoints (fastest). "always" always looks for inlined breakpoint locations (slowest, but most accurate). "headers", which is the default setting, will only look for inlined breakpoint locations if the breakpoint is set in what are consudered to be header files, which is realy defined as "not in an implementation source file". - modify the breakpoint setting by file and line to check the current "target.inline-breakpoint-strategy" setting and act accordingly - Modify compile units to be able to get their language and other info lazily. This allows us to create compile units from the debug map and not have to fill all of the details in, and then lazily discover this information as we go on debuggging. This is needed to avoid parsing all .o files when setting breakpoints in implementation only files (no inlines). Otherwise we would need to parse the .o file, the object file (mach-o in our case) and the symbol file (DWARF in the object file) just to see what the compile unit was. - modify the "SymbolFileDWARFDebugMap" to subclass lldb_private::Module so that the virtual "GetObjectFile()" and "GetSymbolVendor()" functions can be intercepted when the .o file contenst are later lazilly needed. Prior to this fix, when we first instantiated the "SymbolFileDWARFDebugMap" class, we would also make modules, object files and symbol files for every .o file in the debug map because we needed to fix up the sections in the .o files with information that is in the executable debug map. Now we lazily do this in the DebugMapModule::GetObjectFile() Cleaned up header includes a bit as well. llvm-svn: 162860
2012-08-30 05:13:06 +08:00
#include "lldb/Core/Section.h"
#include "lldb/Core/StreamString.h"
#include "lldb/Core/Timer.h"
#include "lldb/Host/Host.h"
#include "lldb/Host/Symbols.h"
#include "lldb/Interpreter/CommandInterpreter.h"
#include "lldb/Interpreter/ScriptInterpreter.h"
#include "lldb/lldb-private-log.h"
<rdar://problem/11757916> Make breakpoint setting by file and line much more efficient by only looking for inlined breakpoint locations if we are setting a breakpoint in anything but a source implementation file. Implementing this complex for a many reasons. Turns out that parsing compile units lazily had some issues with respect to how we need to do things with DWARF in .o files. So the fixes in the checkin for this makes these changes: - Add a new setting called "target.inline-breakpoint-strategy" which can be set to "never", "always", or "headers". "never" will never try and set any inlined breakpoints (fastest). "always" always looks for inlined breakpoint locations (slowest, but most accurate). "headers", which is the default setting, will only look for inlined breakpoint locations if the breakpoint is set in what are consudered to be header files, which is realy defined as "not in an implementation source file". - modify the breakpoint setting by file and line to check the current "target.inline-breakpoint-strategy" setting and act accordingly - Modify compile units to be able to get their language and other info lazily. This allows us to create compile units from the debug map and not have to fill all of the details in, and then lazily discover this information as we go on debuggging. This is needed to avoid parsing all .o files when setting breakpoints in implementation only files (no inlines). Otherwise we would need to parse the .o file, the object file (mach-o in our case) and the symbol file (DWARF in the object file) just to see what the compile unit was. - modify the "SymbolFileDWARFDebugMap" to subclass lldb_private::Module so that the virtual "GetObjectFile()" and "GetSymbolVendor()" functions can be intercepted when the .o file contenst are later lazilly needed. Prior to this fix, when we first instantiated the "SymbolFileDWARFDebugMap" class, we would also make modules, object files and symbol files for every .o file in the debug map because we needed to fix up the sections in the .o files with information that is in the executable debug map. Now we lazily do this in the DebugMapModule::GetObjectFile() Cleaned up header includes a bit as well. llvm-svn: 162860
2012-08-30 05:13:06 +08:00
#include "lldb/Symbol/CompileUnit.h"
#include "lldb/Symbol/ObjectFile.h"
#include "lldb/Symbol/SymbolContext.h"
#include "lldb/Symbol/SymbolVendor.h"
#include "lldb/Target/CPPLanguageRuntime.h"
#include "lldb/Target/ObjCLanguageRuntime.h"
#include "lldb/Target/Process.h"
#include "lldb/Target/Target.h"
using namespace lldb;
using namespace lldb_private;
// Shared pointers to modules track module lifetimes in
// targets and in the global module, but this collection
// will track all module objects that are still alive
typedef std::vector<Module *> ModuleCollection;
static ModuleCollection &
GetModuleCollection()
{
// This module collection needs to live past any module, so we could either make it a
// shared pointer in each module or just leak is. Since it is only an empty vector by
// the time all the modules have gone away, we just leak it for now. If we decide this
// is a big problem we can introduce a Finalize method that will tear everything down in
// a predictable order.
static ModuleCollection *g_module_collection = NULL;
if (g_module_collection == NULL)
g_module_collection = new ModuleCollection();
return *g_module_collection;
}
Mutex *
Module::GetAllocationModuleCollectionMutex()
{
// NOTE: The mutex below must be leaked since the global module list in
// the ModuleList class will get torn at some point, and we can't know
// if it will tear itself down before the "g_module_collection_mutex" below
// will. So we leak a Mutex object below to safeguard against that
static Mutex *g_module_collection_mutex = NULL;
if (g_module_collection_mutex == NULL)
g_module_collection_mutex = new Mutex (Mutex::eMutexTypeRecursive); // NOTE: known leak
return g_module_collection_mutex;
}
size_t
Module::GetNumberAllocatedModules ()
{
Mutex::Locker locker (GetAllocationModuleCollectionMutex());
return GetModuleCollection().size();
}
Module *
Module::GetAllocatedModuleAtIndex (size_t idx)
{
Mutex::Locker locker (GetAllocationModuleCollectionMutex());
ModuleCollection &modules = GetModuleCollection();
if (idx < modules.size())
return modules[idx];
return NULL;
}
#if 0
// These functions help us to determine if modules are still loaded, yet don't require that
// you have a command interpreter and can easily be called from an external debugger.
namespace lldb {
void
ClearModuleInfo (void)
{
const bool mandatory = true;
ModuleList::RemoveOrphanSharedModules(mandatory);
}
void
DumpModuleInfo (void)
{
Mutex::Locker locker (Module::GetAllocationModuleCollectionMutex());
ModuleCollection &modules = GetModuleCollection();
const size_t count = modules.size();
printf ("%s: %" PRIu64 " modules:\n", __PRETTY_FUNCTION__, (uint64_t)count);
for (size_t i=0; i<count; ++i)
{
StreamString strm;
Module *module = modules[i];
const bool in_shared_module_list = ModuleList::ModuleIsInCache (module);
module->GetDescription(&strm, eDescriptionLevelFull);
printf ("%p: shared = %i, ref_count = %3u, module = %s\n",
module,
in_shared_module_list,
(uint32_t)module->use_count(),
strm.GetString().c_str());
}
}
}
#endif
Module::Module (const ModuleSpec &module_spec) :
m_mutex (Mutex::eMutexTypeRecursive),
m_mod_time (module_spec.GetFileSpec().GetModificationTime()),
m_arch (module_spec.GetArchitecture()),
m_uuid (),
m_file (module_spec.GetFileSpec()),
m_platform_file(module_spec.GetPlatformFileSpec()),
m_symfile_spec (module_spec.GetSymbolFileSpec()),
m_object_name (module_spec.GetObjectName()),
m_object_offset (module_spec.GetObjectOffset()),
m_object_mod_time (module_spec.GetObjectModificationTime()),
m_objfile_sp (),
m_symfile_ap (),
m_ast (),
m_source_mappings (),
m_did_load_objfile (false),
m_did_load_symbol_vendor (false),
m_did_parse_uuid (false),
m_did_init_ast (false),
m_is_dynamic_loader_module (false),
m_file_has_changed (false),
m_first_file_changed_log (false)
{
// Scope for locker below...
{
Mutex::Locker locker (GetAllocationModuleCollectionMutex());
GetModuleCollection().push_back(this);
}
Log *log(lldb_private::GetLogIfAnyCategoriesSet (LIBLLDB_LOG_OBJECT|LIBLLDB_LOG_MODULES));
if (log)
log->Printf ("%p Module::Module((%s) '%s%s%s%s')",
this,
m_arch.GetArchitectureName(),
m_file.GetPath().c_str(),
m_object_name.IsEmpty() ? "" : "(",
m_object_name.IsEmpty() ? "" : m_object_name.AsCString(""),
m_object_name.IsEmpty() ? "" : ")");
}
Module::Module(const FileSpec& file_spec,
const ArchSpec& arch,
const ConstString *object_name,
off_t object_offset,
const TimeValue *object_mod_time_ptr) :
m_mutex (Mutex::eMutexTypeRecursive),
m_mod_time (file_spec.GetModificationTime()),
m_arch (arch),
m_uuid (),
m_file (file_spec),
Many improvements to the Platform base class and subclasses. The base Platform class now implements the Host functionality for a lot of things that make sense by default so that subclasses can check: int PlatformSubclass::Foo () { if (IsHost()) return Platform::Foo (); // Let the platform base class do the host specific stuff // Platform subclass specific code... int result = ... return result; } Added new functions to the platform: virtual const char *Platform::GetUserName (uint32_t uid); virtual const char *Platform::GetGroupName (uint32_t gid); The user and group names are cached locally so that remote platforms can avoid sending packets multiple times to resolve this information. Added the parent process ID to the ProcessInfo class. Added a new ProcessInfoMatch class which helps us to match processes up and changed the Host layer over to using this new class. The new class allows us to search for processs: 1 - by name (equal to, starts with, ends with, contains, and regex) 2 - by pid 3 - And further check for parent pid == value, uid == value, gid == value, euid == value, egid == value, arch == value, parent == value. This is all hookup up to the "platform process list" command which required adding dumping routines to dump process information. If the Host class implements the process lookup routines, you can now lists processes on your local machine: machine1.foo.com % lldb (lldb) platform process list PID PARENT USER GROUP EFF USER EFF GROUP TRIPLE NAME ====== ====== ========== ========== ========== ========== ======================== ============================ 99538 1 username usergroup username usergroup x86_64-apple-darwin FileMerge 94943 1 username usergroup username usergroup x86_64-apple-darwin mdworker 94852 244 username usergroup username usergroup x86_64-apple-darwin Safari 94727 244 username usergroup username usergroup x86_64-apple-darwin Xcode 92742 92710 username usergroup username usergroup i386-apple-darwin debugserver This of course also works remotely with the lldb-platform: machine1.foo.com % lldb-platform --listen 1234 machine2.foo.com % lldb (lldb) platform create remote-macosx Platform: remote-macosx Connected: no (lldb) platform connect connect://localhost:1444 Platform: remote-macosx Triple: x86_64-apple-darwin OS Version: 10.6.7 (10J869) Kernel: Darwin Kernel Version 10.7.0: Sat Jan 29 15:17:16 PST 2011; root:xnu-1504.9.37~1/RELEASE_I386 Hostname: machine1.foo.com Connected: yes (lldb) platform process list PID PARENT USER GROUP EFF USER EFF GROUP TRIPLE NAME ====== ====== ========== ========== ========== ========== ======================== ============================ 99556 244 username usergroup username usergroup x86_64-apple-darwin trustevaluation 99548 65539 username usergroup username usergroup x86_64-apple-darwin lldb 99538 1 username usergroup username usergroup x86_64-apple-darwin FileMerge 94943 1 username usergroup username usergroup x86_64-apple-darwin mdworker 94852 244 username usergroup username usergroup x86_64-apple-darwin Safari The lldb-platform implements everything with the Host:: layer, so this should "just work" for linux. I will probably be adding more stuff to the Host layer for launching processes and attaching to processes so that this support should eventually just work as well. Modified the target to be able to be created with an architecture that differs from the main executable. This is needed for iOS debugging since we can have an "armv6" binary which can run on an "armv7" machine, so we want to be able to do: % lldb (lldb) platform create remote-ios (lldb) file --arch armv7 a.out Where "a.out" is an armv6 executable. The platform then can correctly decide to open all "armv7" images for all dependent shared libraries. Modified the disassembly to show the current PC value. Example output: (lldb) disassemble --frame a.out`main: 0x1eb7: pushl %ebp 0x1eb8: movl %esp, %ebp 0x1eba: pushl %ebx 0x1ebb: subl $20, %esp 0x1ebe: calll 0x1ec3 ; main + 12 at test.c:18 0x1ec3: popl %ebx -> 0x1ec4: calll 0x1f12 ; getpid 0x1ec9: movl %eax, 4(%esp) 0x1ecd: leal 199(%ebx), %eax 0x1ed3: movl %eax, (%esp) 0x1ed6: calll 0x1f18 ; printf 0x1edb: leal 213(%ebx), %eax 0x1ee1: movl %eax, (%esp) 0x1ee4: calll 0x1f1e ; puts 0x1ee9: calll 0x1f0c ; getchar 0x1eee: movl $20, (%esp) 0x1ef5: calll 0x1e6a ; sleep_loop at test.c:6 0x1efa: movl $12, %eax 0x1eff: addl $20, %esp 0x1f02: popl %ebx 0x1f03: leave 0x1f04: ret This can be handy when dealing with the new --line options that was recently added: (lldb) disassemble --line a.out`main + 13 at test.c:19 18 { -> 19 printf("Process: %i\n\n", getpid()); 20 puts("Press any key to continue..."); getchar(); -> 0x1ec4: calll 0x1f12 ; getpid 0x1ec9: movl %eax, 4(%esp) 0x1ecd: leal 199(%ebx), %eax 0x1ed3: movl %eax, (%esp) 0x1ed6: calll 0x1f18 ; printf Modified the ModuleList to have a lookup based solely on a UUID. Since the UUID is typically the MD5 checksum of a binary image, there is no need to give the path and architecture when searching for a pre-existing image in an image list. Now that we support remote debugging a bit better, our lldb_private::Module needs to be able to track what the original path for file was as the platform knows it, as well as where the file is locally. The module has the two following functions to retrieve both paths: const FileSpec &Module::GetFileSpec () const; const FileSpec &Module::GetPlatformFileSpec () const; llvm-svn: 128563
2011-03-31 02:16:51 +08:00
m_platform_file(),
m_symfile_spec (),
m_object_name (),
Moved the execution context that was in the Debugger into the CommandInterpreter where it was always being used. Make sure that Modules can track their object file offsets correctly to allow opening of sub object files (like the "__commpage" on darwin). Modified the Platforms to be able to launch processes. The first part of this move is the platform soon will become the entity that launches your program and when it does, it uses a new ProcessLaunchInfo class which encapsulates all process launching settings. This simplifies the internal APIs needed for launching. I want to slowly phase out process launching from the process classes, so for now we can still launch just as we used to, but eventually the platform is the object that should do the launching. Modified the Host::LaunchProcess in the MacOSX Host.mm to correctly be able to launch processes with all of the new eLaunchFlag settings. Modified any code that was manually launching processes to use the Host::LaunchProcess functions. Fixed an issue where lldb_private::Args had implicitly defined copy constructors that could do the wrong thing. This has now been fixed by adding an appropriate copy constructor and assignment operator. Make sure we don't add empty ModuleSP entries to a module list. Fixed the commpage module creation on MacOSX, but we still need to train the MacOSX dynamic loader to not get rid of it when it doesn't have an entry in the all image infos. Abstracted many more calls from in ProcessGDBRemote down into the GDBRemoteCommunicationClient subclass to make the classes cleaner and more efficient. Fixed the default iOS ARM register context to be correct and also added support for targets that don't support the qThreadStopInfo packet by selecting the current thread (only if needed) and then sending a stop reply packet. Debugserver can now start up with a --unix-socket (-u for short) and can then bind to port zero and send the port it bound to to a listening process on the other end. This allows the GDB remote platform to spawn new GDB server instances (debugserver) to allow platform debugging. llvm-svn: 129351
2011-04-12 13:54:46 +08:00
m_object_offset (object_offset),
m_object_mod_time (),
m_objfile_sp (),
m_symfile_ap (),
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
m_ast (),
m_source_mappings (),
m_did_load_objfile (false),
m_did_load_symbol_vendor (false),
m_did_parse_uuid (false),
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
m_did_init_ast (false),
m_is_dynamic_loader_module (false),
m_file_has_changed (false),
m_first_file_changed_log (false)
{
// Scope for locker below...
{
Mutex::Locker locker (GetAllocationModuleCollectionMutex());
GetModuleCollection().push_back(this);
}
if (object_name)
m_object_name = *object_name;
if (object_mod_time_ptr)
m_object_mod_time = *object_mod_time_ptr;
Log *log(lldb_private::GetLogIfAnyCategoriesSet (LIBLLDB_LOG_OBJECT|LIBLLDB_LOG_MODULES));
if (log)
log->Printf ("%p Module::Module((%s) '%s%s%s%s')",
this,
Abtracted all mach-o and ELF out of ArchSpec. This patch is a modified form of Stephen Wilson's idea (thanks for the input Stephen!). What I ended up doing was: - Got rid of ArchSpec::CPU (which was a generic CPU enumeration that mimics the contents of llvm::Triple::ArchType). We now rely upon the llvm::Triple to give us the machine type from llvm::Triple::ArchType. - There is a new ArchSpec::Core definition which further qualifies the CPU core we are dealing with into a single enumeration. If you need support for a new Core and want to debug it in LLDB, it must be added to this list. In the future we can allow for dynamic core registration, but for now it is hard coded. - The ArchSpec can now be initialized with a llvm::Triple or with a C string that represents the triple (it can just be an arch still like "i386"). - The ArchSpec can still initialize itself with a architecture type -- mach-o with cpu type and subtype, or ELF with e_machine + e_flags -- and this will then get translated into the internal llvm::Triple::ArchSpec + ArchSpec::Core. The mach-o cpu type and subtype can be accessed using the getter functions: uint32_t ArchSpec::GetMachOCPUType () const; uint32_t ArchSpec::GetMachOCPUSubType () const; But these functions are just converting out internal llvm::Triple::ArchSpec + ArchSpec::Core back into mach-o. Same goes for ELF. All code has been updated to deal with the changes. This should abstract us until later when the llvm::TargetSpec stuff gets finalized and we can then adopt it. llvm-svn: 126278
2011-02-23 08:35:02 +08:00
m_arch.GetArchitectureName(),
m_file.GetPath().c_str(),
m_object_name.IsEmpty() ? "" : "(",
m_object_name.IsEmpty() ? "" : m_object_name.AsCString(""),
m_object_name.IsEmpty() ? "" : ")");
}
Module::~Module()
{
// Lock our module down while we tear everything down to make sure
// we don't get any access to the module while it is being destroyed
Mutex::Locker locker (m_mutex);
// Scope for locker below...
{
Mutex::Locker locker (GetAllocationModuleCollectionMutex());
ModuleCollection &modules = GetModuleCollection();
ModuleCollection::iterator end = modules.end();
ModuleCollection::iterator pos = std::find(modules.begin(), end, this);
assert (pos != end);
modules.erase(pos);
}
Log *log(lldb_private::GetLogIfAnyCategoriesSet (LIBLLDB_LOG_OBJECT|LIBLLDB_LOG_MODULES));
if (log)
log->Printf ("%p Module::~Module((%s) '%s%s%s%s')",
this,
Abtracted all mach-o and ELF out of ArchSpec. This patch is a modified form of Stephen Wilson's idea (thanks for the input Stephen!). What I ended up doing was: - Got rid of ArchSpec::CPU (which was a generic CPU enumeration that mimics the contents of llvm::Triple::ArchType). We now rely upon the llvm::Triple to give us the machine type from llvm::Triple::ArchType. - There is a new ArchSpec::Core definition which further qualifies the CPU core we are dealing with into a single enumeration. If you need support for a new Core and want to debug it in LLDB, it must be added to this list. In the future we can allow for dynamic core registration, but for now it is hard coded. - The ArchSpec can now be initialized with a llvm::Triple or with a C string that represents the triple (it can just be an arch still like "i386"). - The ArchSpec can still initialize itself with a architecture type -- mach-o with cpu type and subtype, or ELF with e_machine + e_flags -- and this will then get translated into the internal llvm::Triple::ArchSpec + ArchSpec::Core. The mach-o cpu type and subtype can be accessed using the getter functions: uint32_t ArchSpec::GetMachOCPUType () const; uint32_t ArchSpec::GetMachOCPUSubType () const; But these functions are just converting out internal llvm::Triple::ArchSpec + ArchSpec::Core back into mach-o. Same goes for ELF. All code has been updated to deal with the changes. This should abstract us until later when the llvm::TargetSpec stuff gets finalized and we can then adopt it. llvm-svn: 126278
2011-02-23 08:35:02 +08:00
m_arch.GetArchitectureName(),
m_file.GetPath().c_str(),
m_object_name.IsEmpty() ? "" : "(",
m_object_name.IsEmpty() ? "" : m_object_name.AsCString(""),
m_object_name.IsEmpty() ? "" : ")");
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
// Release any auto pointers before we start tearing down our member
// variables since the object file and symbol files might need to make
// function calls back into this module object. The ordering is important
// here because symbol files can require the module object file. So we tear
// down the symbol file first, then the object file.
m_symfile_ap.reset();
m_objfile_sp.reset();
}
ObjectFile *
Module::GetMemoryObjectFile (const lldb::ProcessSP &process_sp, lldb::addr_t header_addr, Error &error)
{
if (m_objfile_sp)
{
error.SetErrorString ("object file already exists");
}
else
{
Mutex::Locker locker (m_mutex);
if (process_sp)
{
m_did_load_objfile = true;
std::unique_ptr<DataBufferHeap> data_ap (new DataBufferHeap (512, 0));
Error readmem_error;
const size_t bytes_read = process_sp->ReadMemory (header_addr,
data_ap->GetBytes(),
data_ap->GetByteSize(),
readmem_error);
if (bytes_read == 512)
{
DataBufferSP data_sp(data_ap.release());
m_objfile_sp = ObjectFile::FindPlugin(shared_from_this(), process_sp, header_addr, data_sp);
if (m_objfile_sp)
{
StreamString s;
s.Printf("0x%16.16" PRIx64, header_addr);
m_object_name.SetCString (s.GetData());
// Once we get the object file, update our module with the object file's
// architecture since it might differ in vendor/os if some parts were
// unknown.
m_objfile_sp->GetArchitecture (m_arch);
}
else
{
error.SetErrorString ("unable to find suitable object file plug-in");
}
}
else
{
error.SetErrorStringWithFormat ("unable to read header from memory: %s", readmem_error.AsCString());
}
}
else
{
error.SetErrorString ("invalid process");
}
}
return m_objfile_sp.get();
}
const lldb_private::UUID&
Module::GetUUID()
{
Mutex::Locker locker (m_mutex);
if (m_did_parse_uuid == false)
{
ObjectFile * obj_file = GetObjectFile ();
if (obj_file != NULL)
{
obj_file->GetUUID(&m_uuid);
m_did_parse_uuid = true;
}
}
return m_uuid;
}
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
ClangASTContext &
Module::GetClangASTContext ()
{
Mutex::Locker locker (m_mutex);
if (m_did_init_ast == false)
{
ObjectFile * objfile = GetObjectFile();
ArchSpec object_arch;
if (objfile && objfile->GetArchitecture(object_arch))
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
{
m_did_init_ast = true;
// LLVM wants this to be set to iOS or MacOSX; if we're working on
// a bare-boards type image, change the triple for llvm's benefit.
if (object_arch.GetTriple().getVendor() == llvm::Triple::Apple
&& object_arch.GetTriple().getOS() == llvm::Triple::UnknownOS)
{
if (object_arch.GetTriple().getArch() == llvm::Triple::arm ||
object_arch.GetTriple().getArch() == llvm::Triple::thumb)
{
object_arch.GetTriple().setOS(llvm::Triple::IOS);
}
else
{
object_arch.GetTriple().setOS(llvm::Triple::MacOSX);
}
}
m_ast.SetArchitecture (object_arch);
A few of the issue I have been trying to track down and fix have been due to the way LLDB lazily gets complete definitions for types within the debug info. When we run across a class/struct/union definition in the DWARF, we will only parse the full definition if we need to. This works fine for top level types that are assigned directly to variables and arguments, but when we have a variable with a class, lets say "A" for this example, that has a member: "B *m_b". Initially we don't need to hunt down a definition for this class unless we are ever asked to do something with it ("expr m_b->getDecl()" for example). With my previous approach to lazy type completion, we would be able to take a "A *a" and get a complete type for it, but we wouldn't be able to then do an "a->m_b->getDecl()" unless we always expanded all types within a class prior to handing out the type. Expanding everything is very costly and it would be great if there were a better way. A few months ago I worked with the llvm/clang folks to have the ExternalASTSource class be able to complete classes if there weren't completed yet: class ExternalASTSource { .... virtual void CompleteType (clang::TagDecl *Tag); virtual void CompleteType (clang::ObjCInterfaceDecl *Class); }; This was great, because we can now have the class that is producing the AST (SymbolFileDWARF and SymbolFileDWARFDebugMap) sign up as external AST sources and the object that creates the forward declaration types can now also complete them anywhere within the clang type system. This patch makes a few major changes: - lldb_private::Module classes now own the AST context. Previously the TypeList objects did. - The DWARF parsers now sign up as an external AST sources so they can complete types. - All of the pure clang type system wrapper code we have in LLDB (ClangASTContext, ClangASTType, and more) can now be iterating through children of any type, and if a class/union/struct type (clang::RecordType or ObjC interface) is found that is incomplete, we can ask the AST to get the definition. - The SymbolFileDWARFDebugMap class now will create and use a single AST that all child SymbolFileDWARF classes will share (much like what happens when we have a complete linked DWARF for an executable). We will need to modify some of the ClangUserExpression code to take more advantage of this completion ability in the near future. Meanwhile we should be better off now that we can be accessing any children of variables through pointers and always be able to resolve the clang type if needed. llvm-svn: 123613
2011-01-17 11:46:26 +08:00
}
}
return m_ast;
}
void
Module::ParseAllDebugSymbols()
{
Mutex::Locker locker (m_mutex);
size_t num_comp_units = GetNumCompileUnits();
if (num_comp_units == 0)
return;
SymbolContext sc;
sc.module_sp = shared_from_this();
SymbolVendor *symbols = GetSymbolVendor ();
for (size_t cu_idx = 0; cu_idx < num_comp_units; cu_idx++)
{
sc.comp_unit = symbols->GetCompileUnitAtIndex(cu_idx).get();
if (sc.comp_unit)
{
sc.function = NULL;
symbols->ParseVariablesForContext(sc);
symbols->ParseCompileUnitFunctions(sc);
for (size_t func_idx = 0; (sc.function = sc.comp_unit->GetFunctionAtIndex(func_idx).get()) != NULL; ++func_idx)
{
symbols->ParseFunctionBlocks(sc);
// Parse the variables for this function and all its blocks
symbols->ParseVariablesForContext(sc);
}
// Parse all types for this compile unit
sc.function = NULL;
symbols->ParseTypes(sc);
}
}
}
void
Module::CalculateSymbolContext(SymbolContext* sc)
{
sc->module_sp = shared_from_this();
}
ModuleSP
Module::CalculateSymbolContextModule ()
{
return shared_from_this();
}
void
Module::DumpSymbolContext(Stream *s)
{
s->Printf(", Module{%p}", this);
}
size_t
Module::GetNumCompileUnits()
{
Mutex::Locker locker (m_mutex);
Timer scoped_timer(__PRETTY_FUNCTION__, "Module::GetNumCompileUnits (module = %p)", this);
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
return symbols->GetNumCompileUnits();
return 0;
}
CompUnitSP
Module::GetCompileUnitAtIndex (size_t index)
{
Mutex::Locker locker (m_mutex);
size_t num_comp_units = GetNumCompileUnits ();
CompUnitSP cu_sp;
if (index < num_comp_units)
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
cu_sp = symbols->GetCompileUnitAtIndex(index);
}
return cu_sp;
}
bool
Module::ResolveFileAddress (lldb::addr_t vm_addr, Address& so_addr)
{
Mutex::Locker locker (m_mutex);
Timer scoped_timer(__PRETTY_FUNCTION__, "Module::ResolveFileAddress (vm_addr = 0x%" PRIx64 ")", vm_addr);
ObjectFile* ofile = GetObjectFile();
if (ofile)
return so_addr.ResolveAddressUsingFileSections(vm_addr, ofile->GetSectionList());
return false;
}
uint32_t
Module::ResolveSymbolContextForAddress (const Address& so_addr, uint32_t resolve_scope, SymbolContext& sc)
{
Mutex::Locker locker (m_mutex);
uint32_t resolved_flags = 0;
// Clear the result symbol context in case we don't find anything, but don't clear the target
sc.Clear(false);
// Get the section from the section/offset address.
SectionSP section_sp (so_addr.GetSection());
// Make sure the section matches this module before we try and match anything
if (section_sp && section_sp->GetModule().get() == this)
{
// If the section offset based address resolved itself, then this
// is the right module.
sc.module_sp = shared_from_this();
resolved_flags |= eSymbolContextModule;
// Resolve the compile unit, function, block, line table or line
// entry if requested.
if (resolve_scope & eSymbolContextCompUnit ||
resolve_scope & eSymbolContextFunction ||
resolve_scope & eSymbolContextBlock ||
resolve_scope & eSymbolContextLineEntry )
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
resolved_flags |= symbols->ResolveSymbolContext (so_addr, resolve_scope, sc);
}
// Resolve the symbol if requested, but don't re-look it up if we've already found it.
if (resolve_scope & eSymbolContextSymbol && !(resolved_flags & eSymbolContextSymbol))
{
ObjectFile* ofile = GetObjectFile();
if (ofile)
{
Symtab *symtab = ofile->GetSymtab();
if (symtab)
{
if (so_addr.IsSectionOffset())
{
sc.symbol = symtab->FindSymbolContainingFileAddress(so_addr.GetFileAddress());
if (sc.symbol)
resolved_flags |= eSymbolContextSymbol;
}
}
}
}
}
return resolved_flags;
}
uint32_t
Module::ResolveSymbolContextForFilePath
(
const char *file_path,
uint32_t line,
bool check_inlines,
uint32_t resolve_scope,
SymbolContextList& sc_list
)
{
FileSpec file_spec(file_path, false);
return ResolveSymbolContextsForFileSpec (file_spec, line, check_inlines, resolve_scope, sc_list);
}
uint32_t
Module::ResolveSymbolContextsForFileSpec (const FileSpec &file_spec, uint32_t line, bool check_inlines, uint32_t resolve_scope, SymbolContextList& sc_list)
{
Mutex::Locker locker (m_mutex);
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::ResolveSymbolContextForFilePath (%s:%u, check_inlines = %s, resolve_scope = 0x%8.8x)",
file_spec.GetPath().c_str(),
line,
check_inlines ? "yes" : "no",
resolve_scope);
const uint32_t initial_count = sc_list.GetSize();
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
symbols->ResolveSymbolContext (file_spec, line, check_inlines, resolve_scope, sc_list);
return sc_list.GetSize() - initial_count;
}
size_t
Module::FindGlobalVariables (const ConstString &name,
const ClangNamespaceDecl *namespace_decl,
bool append,
size_t max_matches,
VariableList& variables)
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
return symbols->FindGlobalVariables(name, namespace_decl, append, max_matches, variables);
return 0;
}
size_t
Module::FindGlobalVariables (const RegularExpression& regex,
bool append,
size_t max_matches,
VariableList& variables)
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
return symbols->FindGlobalVariables(regex, append, max_matches, variables);
return 0;
}
size_t
Module::FindCompileUnits (const FileSpec &path,
bool append,
SymbolContextList &sc_list)
{
if (!append)
sc_list.Clear();
const size_t start_size = sc_list.GetSize();
const size_t num_compile_units = GetNumCompileUnits();
SymbolContext sc;
sc.module_sp = shared_from_this();
const bool compare_directory = path.GetDirectory();
for (size_t i=0; i<num_compile_units; ++i)
{
sc.comp_unit = GetCompileUnitAtIndex(i).get();
if (sc.comp_unit)
{
if (FileSpec::Equal (*sc.comp_unit, path, compare_directory))
sc_list.Append(sc);
}
}
return sc_list.GetSize() - start_size;
}
size_t
Module::FindFunctions (const ConstString &name,
const ClangNamespaceDecl *namespace_decl,
uint32_t name_type_mask,
bool include_symbols,
bool include_inlines,
bool append,
SymbolContextList& sc_list)
{
if (!append)
sc_list.Clear();
const size_t old_size = sc_list.GetSize();
// Find all the functions (not symbols, but debug information functions...
SymbolVendor *symbols = GetSymbolVendor ();
if (name_type_mask & eFunctionNameTypeAuto)
{
ConstString lookup_name;
uint32_t lookup_name_type_mask = 0;
bool match_name_after_lookup = false;
Module::PrepareForFunctionNameLookup (name,
name_type_mask,
lookup_name,
lookup_name_type_mask,
match_name_after_lookup);
if (symbols)
symbols->FindFunctions(lookup_name,
namespace_decl,
lookup_name_type_mask,
include_inlines,
append,
sc_list);
// Now check our symbol table for symbols that are code symbols if requested
if (include_symbols)
{
ObjectFile *objfile = GetObjectFile();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
symtab->FindFunctionSymbols(lookup_name, lookup_name_type_mask, sc_list);
}
}
if (match_name_after_lookup)
{
SymbolContext sc;
size_t i = old_size;
while (i<sc_list.GetSize())
{
if (sc_list.GetContextAtIndex(i, sc))
{
const char *func_name = sc.GetFunctionName().GetCString();
if (func_name && strstr (func_name, name.GetCString()) == NULL)
{
// Remove the current context
sc_list.RemoveContextAtIndex(i);
// Don't increment i and continue in the loop
continue;
}
}
++i;
}
}
}
else
{
if (symbols)
symbols->FindFunctions(name, namespace_decl, name_type_mask, include_inlines, append, sc_list);
// Now check our symbol table for symbols that are code symbols if requested
if (include_symbols)
{
ObjectFile *objfile = GetObjectFile();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
symtab->FindFunctionSymbols(name, name_type_mask, sc_list);
}
}
}
return sc_list.GetSize() - old_size;
}
size_t
Module::FindFunctions (const RegularExpression& regex,
bool include_symbols,
bool include_inlines,
bool append,
SymbolContextList& sc_list)
{
if (!append)
sc_list.Clear();
const size_t start_size = sc_list.GetSize();
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
symbols->FindFunctions(regex, include_inlines, append, sc_list);
// Now check our symbol table for symbols that are code symbols if requested
if (include_symbols)
{
ObjectFile *objfile = GetObjectFile();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
{
std::vector<uint32_t> symbol_indexes;
symtab->AppendSymbolIndexesMatchingRegExAndType (regex, eSymbolTypeAny, Symtab::eDebugAny, Symtab::eVisibilityAny, symbol_indexes);
const size_t num_matches = symbol_indexes.size();
if (num_matches)
{
SymbolContext sc(this);
const size_t end_functions_added_index = sc_list.GetSize();
size_t num_functions_added_to_sc_list = end_functions_added_index - start_size;
if (num_functions_added_to_sc_list == 0)
{
// No functions were added, just symbols, so we can just append them
for (size_t i=0; i<num_matches; ++i)
{
sc.symbol = symtab->SymbolAtIndex(symbol_indexes[i]);
SymbolType sym_type = sc.symbol->GetType();
if (sc.symbol && (sym_type == eSymbolTypeCode ||
sym_type == eSymbolTypeResolver))
sc_list.Append(sc);
}
}
else
{
typedef std::map<lldb::addr_t, uint32_t> FileAddrToIndexMap;
FileAddrToIndexMap file_addr_to_index;
for (size_t i=start_size; i<end_functions_added_index; ++i)
{
const SymbolContext &sc = sc_list[i];
if (sc.block)
continue;
file_addr_to_index[sc.function->GetAddressRange().GetBaseAddress().GetFileAddress()] = i;
}
FileAddrToIndexMap::const_iterator end = file_addr_to_index.end();
// Functions were added so we need to merge symbols into any
// existing function symbol contexts
for (size_t i=start_size; i<num_matches; ++i)
{
sc.symbol = symtab->SymbolAtIndex(symbol_indexes[i]);
SymbolType sym_type = sc.symbol->GetType();
if (sc.symbol && (sym_type == eSymbolTypeCode ||
sym_type == eSymbolTypeResolver))
{
FileAddrToIndexMap::const_iterator pos = file_addr_to_index.find(sc.symbol->GetAddress().GetFileAddress());
if (pos == end)
sc_list.Append(sc);
else
sc_list[pos->second].symbol = sc.symbol;
}
}
}
}
}
}
}
return sc_list.GetSize() - start_size;
}
size_t
Module::FindTypes_Impl (const SymbolContext& sc,
const ConstString &name,
const ClangNamespaceDecl *namespace_decl,
bool append,
size_t max_matches,
TypeList& types)
{
Timer scoped_timer(__PRETTY_FUNCTION__, __PRETTY_FUNCTION__);
if (sc.module_sp.get() == NULL || sc.module_sp.get() == this)
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
return symbols->FindTypes(sc, name, namespace_decl, append, max_matches, types);
}
return 0;
}
size_t
Module::FindTypesInNamespace (const SymbolContext& sc,
const ConstString &type_name,
const ClangNamespaceDecl *namespace_decl,
size_t max_matches,
TypeList& type_list)
{
const bool append = true;
return FindTypes_Impl(sc, type_name, namespace_decl, append, max_matches, type_list);
}
lldb::TypeSP
Module::FindFirstType (const SymbolContext& sc,
const ConstString &name,
bool exact_match)
{
TypeList type_list;
const size_t num_matches = FindTypes (sc, name, exact_match, 1, type_list);
if (num_matches)
return type_list.GetTypeAtIndex(0);
return TypeSP();
}
size_t
Module::FindTypes (const SymbolContext& sc,
const ConstString &name,
bool exact_match,
size_t max_matches,
TypeList& types)
{
size_t num_matches = 0;
const char *type_name_cstr = name.GetCString();
std::string type_scope;
std::string type_basename;
const bool append = true;
TypeClass type_class = eTypeClassAny;
if (Type::GetTypeScopeAndBasename (type_name_cstr, type_scope, type_basename, type_class))
{
// Check if "name" starts with "::" which means the qualified type starts
// from the root namespace and implies and exact match. The typenames we
// get back from clang do not start with "::" so we need to strip this off
// in order to get the qualfied names to match
if (type_scope.size() >= 2 && type_scope[0] == ':' && type_scope[1] == ':')
{
type_scope.erase(0,2);
exact_match = true;
}
ConstString type_basename_const_str (type_basename.c_str());
if (FindTypes_Impl(sc, type_basename_const_str, NULL, append, max_matches, types))
{
types.RemoveMismatchedTypes (type_scope, type_basename, type_class, exact_match);
num_matches = types.GetSize();
}
}
else
{
// The type is not in a namespace/class scope, just search for it by basename
if (type_class != eTypeClassAny)
{
// The "type_name_cstr" will have been modified if we have a valid type class
// prefix (like "struct", "class", "union", "typedef" etc).
num_matches = FindTypes_Impl(sc, ConstString(type_name_cstr), NULL, append, max_matches, types);
types.RemoveMismatchedTypes (type_class);
num_matches = types.GetSize();
}
else
{
num_matches = FindTypes_Impl(sc, name, NULL, append, max_matches, types);
}
}
return num_matches;
}
SymbolVendor*
Module::GetSymbolVendor (bool can_create, lldb_private::Stream *feedback_strm)
{
Mutex::Locker locker (m_mutex);
if (m_did_load_symbol_vendor == false && can_create)
{
ObjectFile *obj_file = GetObjectFile ();
if (obj_file != NULL)
{
Timer scoped_timer(__PRETTY_FUNCTION__, __PRETTY_FUNCTION__);
m_symfile_ap.reset(SymbolVendor::FindPlugin(shared_from_this(), feedback_strm));
m_did_load_symbol_vendor = true;
}
}
return m_symfile_ap.get();
}
void
Module::SetFileSpecAndObjectName (const FileSpec &file, const ConstString &object_name)
{
// Container objects whose paths do not specify a file directly can call
// this function to correct the file and object names.
m_file = file;
m_mod_time = file.GetModificationTime();
m_object_name = object_name;
}
const ArchSpec&
Module::GetArchitecture () const
{
return m_arch;
}
std::string
Module::GetSpecificationDescription () const
{
std::string spec(GetFileSpec().GetPath());
if (m_object_name)
{
spec += '(';
spec += m_object_name.GetCString();
spec += ')';
}
return spec;
}
void
Module::GetDescription (Stream *s, lldb::DescriptionLevel level)
{
Mutex::Locker locker (m_mutex);
if (level >= eDescriptionLevelFull)
{
if (m_arch.IsValid())
s->Printf("(%s) ", m_arch.GetArchitectureName());
}
if (level == eDescriptionLevelBrief)
{
const char *filename = m_file.GetFilename().GetCString();
if (filename)
s->PutCString (filename);
}
else
{
char path[PATH_MAX];
if (m_file.GetPath(path, sizeof(path)))
s->PutCString(path);
}
const char *object_name = m_object_name.GetCString();
if (object_name)
s->Printf("(%s)", object_name);
}
void
Module::ReportError (const char *format, ...)
{
if (format && format[0])
{
StreamString strm;
strm.PutCString("error: ");
GetDescription(&strm, lldb::eDescriptionLevelBrief);
strm.PutChar (' ');
va_list args;
va_start (args, format);
strm.PrintfVarArg(format, args);
va_end (args);
const int format_len = strlen(format);
if (format_len > 0)
{
const char last_char = format[format_len-1];
if (last_char != '\n' || last_char != '\r')
strm.EOL();
}
Host::SystemLog (Host::eSystemLogError, "%s", strm.GetString().c_str());
}
}
bool
Module::FileHasChanged () const
{
if (m_file_has_changed == false)
m_file_has_changed = (m_file.GetModificationTime() != m_mod_time);
return m_file_has_changed;
}
void
Module::ReportErrorIfModifyDetected (const char *format, ...)
{
if (m_first_file_changed_log == false)
{
if (FileHasChanged ())
{
m_first_file_changed_log = true;
if (format)
{
StreamString strm;
strm.PutCString("error: the object file ");
GetDescription(&strm, lldb::eDescriptionLevelFull);
strm.PutCString (" has been modified\n");
va_list args;
va_start (args, format);
strm.PrintfVarArg(format, args);
va_end (args);
const int format_len = strlen(format);
if (format_len > 0)
{
const char last_char = format[format_len-1];
if (last_char != '\n' || last_char != '\r')
strm.EOL();
}
strm.PutCString("The debug session should be aborted as the original debug information has been overwritten.\n");
Host::SystemLog (Host::eSystemLogError, "%s", strm.GetString().c_str());
}
}
}
}
void
Module::ReportWarning (const char *format, ...)
{
if (format && format[0])
{
StreamString strm;
strm.PutCString("warning: ");
GetDescription(&strm, lldb::eDescriptionLevelFull);
strm.PutChar (' ');
va_list args;
va_start (args, format);
strm.PrintfVarArg(format, args);
va_end (args);
const int format_len = strlen(format);
if (format_len > 0)
{
const char last_char = format[format_len-1];
if (last_char != '\n' || last_char != '\r')
strm.EOL();
}
Host::SystemLog (Host::eSystemLogWarning, "%s", strm.GetString().c_str());
}
}
void
Module::LogMessage (Log *log, const char *format, ...)
{
if (log)
{
StreamString log_message;
GetDescription(&log_message, lldb::eDescriptionLevelFull);
log_message.PutCString (": ");
va_list args;
va_start (args, format);
log_message.PrintfVarArg (format, args);
va_end (args);
log->PutCString(log_message.GetString().c_str());
}
}
void
Module::LogMessageVerboseBacktrace (Log *log, const char *format, ...)
{
if (log)
{
StreamString log_message;
GetDescription(&log_message, lldb::eDescriptionLevelFull);
log_message.PutCString (": ");
va_list args;
va_start (args, format);
log_message.PrintfVarArg (format, args);
va_end (args);
if (log->GetVerbose())
Host::Backtrace (log_message, 1024);
log->PutCString(log_message.GetString().c_str());
}
}
void
Module::Dump(Stream *s)
{
Mutex::Locker locker (m_mutex);
//s->Printf("%.*p: ", (int)sizeof(void*) * 2, this);
s->Indent();
s->Printf("Module %s%s%s%s\n",
m_file.GetPath().c_str(),
m_object_name ? "(" : "",
m_object_name ? m_object_name.GetCString() : "",
m_object_name ? ")" : "");
s->IndentMore();
ObjectFile *objfile = GetObjectFile ();
if (objfile)
objfile->Dump(s);
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
symbols->Dump(s);
s->IndentLess();
}
TypeList*
Module::GetTypeList ()
{
SymbolVendor *symbols = GetSymbolVendor ();
if (symbols)
return &symbols->GetTypeList();
return NULL;
}
const ConstString &
Module::GetObjectName() const
{
return m_object_name;
}
ObjectFile *
Module::GetObjectFile()
{
Mutex::Locker locker (m_mutex);
if (m_did_load_objfile == false)
{
m_did_load_objfile = true;
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::GetObjectFile () module = %s", GetFileSpec().GetFilename().AsCString(""));
DataBufferSP data_sp;
lldb::offset_t data_offset = 0;
m_objfile_sp = ObjectFile::FindPlugin (shared_from_this(),
&m_file,
m_object_offset,
m_file.GetByteSize(),
data_sp,
data_offset);
if (m_objfile_sp)
{
// Once we get the object file, update our module with the object file's
// architecture since it might differ in vendor/os if some parts were
// unknown.
m_objfile_sp->GetArchitecture (m_arch);
}
}
return m_objfile_sp.get();
}
const Symbol *
Module::FindFirstSymbolWithNameAndType (const ConstString &name, SymbolType symbol_type)
{
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::FindFirstSymbolWithNameAndType (name = %s, type = %i)",
name.AsCString(),
symbol_type);
ObjectFile *objfile = GetObjectFile();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
return symtab->FindFirstSymbolWithNameAndType (name, symbol_type, Symtab::eDebugAny, Symtab::eVisibilityAny);
}
return NULL;
}
void
Module::SymbolIndicesToSymbolContextList (Symtab *symtab, std::vector<uint32_t> &symbol_indexes, SymbolContextList &sc_list)
{
// No need to protect this call using m_mutex all other method calls are
// already thread safe.
size_t num_indices = symbol_indexes.size();
if (num_indices > 0)
{
SymbolContext sc;
CalculateSymbolContext (&sc);
for (size_t i = 0; i < num_indices; i++)
{
sc.symbol = symtab->SymbolAtIndex (symbol_indexes[i]);
if (sc.symbol)
sc_list.Append (sc);
}
}
}
size_t
Module::FindFunctionSymbols (const ConstString &name,
uint32_t name_type_mask,
SymbolContextList& sc_list)
{
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::FindSymbolsFunctions (name = %s, mask = 0x%8.8x)",
name.AsCString(),
name_type_mask);
ObjectFile *objfile = GetObjectFile ();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
return symtab->FindFunctionSymbols (name, name_type_mask, sc_list);
}
return 0;
}
size_t
Module::FindSymbolsWithNameAndType (const ConstString &name, SymbolType symbol_type, SymbolContextList &sc_list)
{
// No need to protect this call using m_mutex all other method calls are
// already thread safe.
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::FindSymbolsWithNameAndType (name = %s, type = %i)",
name.AsCString(),
symbol_type);
const size_t initial_size = sc_list.GetSize();
ObjectFile *objfile = GetObjectFile ();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
{
std::vector<uint32_t> symbol_indexes;
symtab->FindAllSymbolsWithNameAndType (name, symbol_type, symbol_indexes);
SymbolIndicesToSymbolContextList (symtab, symbol_indexes, sc_list);
}
}
return sc_list.GetSize() - initial_size;
}
size_t
Module::FindSymbolsMatchingRegExAndType (const RegularExpression &regex, SymbolType symbol_type, SymbolContextList &sc_list)
{
// No need to protect this call using m_mutex all other method calls are
// already thread safe.
Timer scoped_timer(__PRETTY_FUNCTION__,
"Module::FindSymbolsMatchingRegExAndType (regex = %s, type = %i)",
regex.GetText(),
symbol_type);
const size_t initial_size = sc_list.GetSize();
ObjectFile *objfile = GetObjectFile ();
if (objfile)
{
Symtab *symtab = objfile->GetSymtab();
if (symtab)
{
std::vector<uint32_t> symbol_indexes;
symtab->FindAllSymbolsMatchingRexExAndType (regex, symbol_type, Symtab::eDebugAny, Symtab::eVisibilityAny, symbol_indexes);
SymbolIndicesToSymbolContextList (symtab, symbol_indexes, sc_list);
}
}
return sc_list.GetSize() - initial_size;
}
void
Module::SetSymbolFileFileSpec (const FileSpec &file)
{
m_symfile_spec = file;
m_symfile_ap.reset();
m_did_load_symbol_vendor = false;
}
bool
Module::IsExecutable ()
{
if (GetObjectFile() == NULL)
return false;
else
return GetObjectFile()->IsExecutable();
}
bool
Module::IsLoadedInTarget (Target *target)
{
ObjectFile *obj_file = GetObjectFile();
if (obj_file)
{
SectionList *sections = obj_file->GetSectionList();
if (sections != NULL)
{
size_t num_sections = sections->GetSize();
for (size_t sect_idx = 0; sect_idx < num_sections; sect_idx++)
{
SectionSP section_sp = sections->GetSectionAtIndex(sect_idx);
if (section_sp->GetLoadBaseAddress(target) != LLDB_INVALID_ADDRESS)
{
return true;
}
}
}
}
return false;
}
bool
Module::LoadScriptingResourceInTarget (Target *target, Error& error, Stream* feedback_stream)
{
if (!target)
{
error.SetErrorString("invalid destination Target");
return false;
}
LoadScriptFromSymFile shoud_load = target->TargetProperties::GetLoadScriptFromSymbolFile();
Debugger &debugger = target->GetDebugger();
const ScriptLanguage script_language = debugger.GetScriptLanguage();
if (script_language != eScriptLanguageNone)
{
PlatformSP platform_sp(target->GetPlatform());
if (!platform_sp)
{
error.SetErrorString("invalid Platform");
return false;
}
FileSpecList file_specs = platform_sp->LocateExecutableScriptingResources (target,
*this);
const uint32_t num_specs = file_specs.GetSize();
if (num_specs)
{
ScriptInterpreter *script_interpreter = debugger.GetCommandInterpreter().GetScriptInterpreter();
if (script_interpreter)
{
for (uint32_t i=0; i<num_specs; ++i)
{
FileSpec scripting_fspec (file_specs.GetFileSpecAtIndex(i));
if (scripting_fspec && scripting_fspec.Exists())
{
if (shoud_load == eLoadScriptFromSymFileFalse)
return false;
if (shoud_load == eLoadScriptFromSymFileWarn)
{
if (feedback_stream)
feedback_stream->Printf("warning: '%s' contains a debug script. To run this script in this debug session:\n\n command script import \"%s\"\n\nTo run all discovered debug scripts in this session:\n\n settings set target.load-script-from-symbol-file true\n"
,GetFileSpec().GetFileNameStrippingExtension().GetCString(),scripting_fspec.GetPath().c_str());
return false;
}
StreamString scripting_stream;
scripting_fspec.Dump(&scripting_stream);
const bool can_reload = true;
const bool init_lldb_globals = false;
bool did_load = script_interpreter->LoadScriptingModule(scripting_stream.GetData(), can_reload, init_lldb_globals, error);
if (!did_load)
return false;
}
}
}
else
{
error.SetErrorString("invalid ScriptInterpreter");
return false;
}
}
}
return true;
}
bool
Module::SetArchitecture (const ArchSpec &new_arch)
{
Abtracted all mach-o and ELF out of ArchSpec. This patch is a modified form of Stephen Wilson's idea (thanks for the input Stephen!). What I ended up doing was: - Got rid of ArchSpec::CPU (which was a generic CPU enumeration that mimics the contents of llvm::Triple::ArchType). We now rely upon the llvm::Triple to give us the machine type from llvm::Triple::ArchType. - There is a new ArchSpec::Core definition which further qualifies the CPU core we are dealing with into a single enumeration. If you need support for a new Core and want to debug it in LLDB, it must be added to this list. In the future we can allow for dynamic core registration, but for now it is hard coded. - The ArchSpec can now be initialized with a llvm::Triple or with a C string that represents the triple (it can just be an arch still like "i386"). - The ArchSpec can still initialize itself with a architecture type -- mach-o with cpu type and subtype, or ELF with e_machine + e_flags -- and this will then get translated into the internal llvm::Triple::ArchSpec + ArchSpec::Core. The mach-o cpu type and subtype can be accessed using the getter functions: uint32_t ArchSpec::GetMachOCPUType () const; uint32_t ArchSpec::GetMachOCPUSubType () const; But these functions are just converting out internal llvm::Triple::ArchSpec + ArchSpec::Core back into mach-o. Same goes for ELF. All code has been updated to deal with the changes. This should abstract us until later when the llvm::TargetSpec stuff gets finalized and we can then adopt it. llvm-svn: 126278
2011-02-23 08:35:02 +08:00
if (!m_arch.IsValid())
{
m_arch = new_arch;
return true;
Abtracted all mach-o and ELF out of ArchSpec. This patch is a modified form of Stephen Wilson's idea (thanks for the input Stephen!). What I ended up doing was: - Got rid of ArchSpec::CPU (which was a generic CPU enumeration that mimics the contents of llvm::Triple::ArchType). We now rely upon the llvm::Triple to give us the machine type from llvm::Triple::ArchType. - There is a new ArchSpec::Core definition which further qualifies the CPU core we are dealing with into a single enumeration. If you need support for a new Core and want to debug it in LLDB, it must be added to this list. In the future we can allow for dynamic core registration, but for now it is hard coded. - The ArchSpec can now be initialized with a llvm::Triple or with a C string that represents the triple (it can just be an arch still like "i386"). - The ArchSpec can still initialize itself with a architecture type -- mach-o with cpu type and subtype, or ELF with e_machine + e_flags -- and this will then get translated into the internal llvm::Triple::ArchSpec + ArchSpec::Core. The mach-o cpu type and subtype can be accessed using the getter functions: uint32_t ArchSpec::GetMachOCPUType () const; uint32_t ArchSpec::GetMachOCPUSubType () const; But these functions are just converting out internal llvm::Triple::ArchSpec + ArchSpec::Core back into mach-o. Same goes for ELF. All code has been updated to deal with the changes. This should abstract us until later when the llvm::TargetSpec stuff gets finalized and we can then adopt it. llvm-svn: 126278
2011-02-23 08:35:02 +08:00
}
return m_arch.IsExactMatch(new_arch);
}
bool
Module::SetLoadAddress (Target &target, lldb::addr_t offset, bool &changed)
{
size_t num_loaded_sections = 0;
ObjectFile *objfile = GetObjectFile();
if (objfile)
{
SectionList *section_list = objfile->GetSectionList ();
if (section_list)
{
const size_t num_sections = section_list->GetSize();
size_t sect_idx = 0;
for (sect_idx = 0; sect_idx < num_sections; ++sect_idx)
{
// Iterate through the object file sections to find the
// first section that starts of file offset zero and that
// has bytes in the file...
SectionSP section_sp (section_list->GetSectionAtIndex (sect_idx));
// Only load non-thread specific sections when given a slide
if (section_sp && !section_sp->IsThreadSpecific())
{
if (target.GetSectionLoadList().SetSectionLoadAddress (section_sp, section_sp->GetFileAddress() + offset))
++num_loaded_sections;
}
}
}
}
changed = num_loaded_sections > 0;
return num_loaded_sections > 0;
}
bool
Module::MatchesModuleSpec (const ModuleSpec &module_ref)
{
const UUID &uuid = module_ref.GetUUID();
if (uuid.IsValid())
{
// If the UUID matches, then nothing more needs to match...
if (uuid == GetUUID())
return true;
else
return false;
}
const FileSpec &file_spec = module_ref.GetFileSpec();
if (file_spec)
{
if (!FileSpec::Equal (file_spec, m_file, file_spec.GetDirectory()))
return false;
}
const FileSpec &platform_file_spec = module_ref.GetPlatformFileSpec();
if (platform_file_spec)
{
if (!FileSpec::Equal (platform_file_spec, GetPlatformFileSpec (), platform_file_spec.GetDirectory()))
return false;
}
const ArchSpec &arch = module_ref.GetArchitecture();
if (arch.IsValid())
{
if (!m_arch.IsCompatibleMatch(arch))
return false;
}
const ConstString &object_name = module_ref.GetObjectName();
if (object_name)
{
if (object_name != GetObjectName())
return false;
}
return true;
}
bool
Module::FindSourceFile (const FileSpec &orig_spec, FileSpec &new_spec) const
{
Mutex::Locker locker (m_mutex);
return m_source_mappings.FindFile (orig_spec, new_spec);
}
bool
Module::RemapSourceFile (const char *path, std::string &new_path) const
{
Mutex::Locker locker (m_mutex);
return m_source_mappings.RemapPath(path, new_path);
}
uint32_t
Module::GetVersion (uint32_t *versions, uint32_t num_versions)
{
ObjectFile *obj_file = GetObjectFile();
if (obj_file)
return obj_file->GetVersion (versions, num_versions);
if (versions && num_versions)
{
for (uint32_t i=0; i<num_versions; ++i)
versions[i] = UINT32_MAX;
}
return 0;
}
void
Module::PrepareForFunctionNameLookup (const ConstString &name,
uint32_t name_type_mask,
ConstString &lookup_name,
uint32_t &lookup_name_type_mask,
bool &match_name_after_lookup)
{
const char *name_cstr = name.GetCString();
lookup_name_type_mask = eFunctionNameTypeNone;
match_name_after_lookup = false;
const char *base_name_start = NULL;
const char *base_name_end = NULL;
if (name_type_mask & eFunctionNameTypeAuto)
{
if (CPPLanguageRuntime::IsCPPMangledName (name_cstr))
lookup_name_type_mask = eFunctionNameTypeFull;
else if (ObjCLanguageRuntime::IsPossibleObjCMethodName (name_cstr))
lookup_name_type_mask = eFunctionNameTypeFull;
else
{
if (ObjCLanguageRuntime::IsPossibleObjCSelector(name_cstr))
lookup_name_type_mask |= eFunctionNameTypeSelector;
CPPLanguageRuntime::MethodName cpp_method (name);
llvm::StringRef basename (cpp_method.GetBasename());
if (basename.empty())
{
if (CPPLanguageRuntime::StripNamespacesFromVariableName (name_cstr, base_name_start, base_name_end))
lookup_name_type_mask |= (eFunctionNameTypeMethod | eFunctionNameTypeBase);
}
else
{
base_name_start = basename.data();
base_name_end = base_name_start + basename.size();
lookup_name_type_mask |= (eFunctionNameTypeMethod | eFunctionNameTypeBase);
}
}
}
else
{
lookup_name_type_mask = name_type_mask;
if (lookup_name_type_mask & eFunctionNameTypeMethod || name_type_mask & eFunctionNameTypeBase)
{
// If they've asked for a CPP method or function name and it can't be that, we don't
// even need to search for CPP methods or names.
CPPLanguageRuntime::MethodName cpp_method (name);
if (cpp_method.IsValid())
{
llvm::StringRef basename (cpp_method.GetBasename());
base_name_start = basename.data();
base_name_end = base_name_start + basename.size();
if (!cpp_method.GetQualifiers().empty())
{
// There is a "const" or other qualifer following the end of the fucntion parens,
// this can't be a eFunctionNameTypeBase
lookup_name_type_mask &= ~(eFunctionNameTypeBase);
if (lookup_name_type_mask == eFunctionNameTypeNone)
return;
}
}
else
{
if (!CPPLanguageRuntime::StripNamespacesFromVariableName (name_cstr, base_name_start, base_name_end))
{
lookup_name_type_mask &= ~(eFunctionNameTypeMethod | eFunctionNameTypeBase);
if (lookup_name_type_mask == eFunctionNameTypeNone)
return;
}
}
}
if (lookup_name_type_mask & eFunctionNameTypeSelector)
{
if (!ObjCLanguageRuntime::IsPossibleObjCSelector(name_cstr))
{
lookup_name_type_mask &= ~(eFunctionNameTypeSelector);
if (lookup_name_type_mask == eFunctionNameTypeNone)
return;
}
}
}
if (base_name_start &&
base_name_end &&
base_name_start != name_cstr &&
base_name_start < base_name_end)
{
// The name supplied was a partial C++ path like "a::count". In this case we want to do a
// lookup on the basename "count" and then make sure any matching results contain "a::count"
// so that it would match "b::a::count" and "a::count". This is why we set "match_name_after_lookup"
// to true
lookup_name.SetCStringWithLength(base_name_start, base_name_end - base_name_start);
match_name_after_lookup = true;
}
else
{
// The name is already correct, just use the exact name as supplied, and we won't need
// to check if any matches contain "name"
lookup_name = name;
match_name_after_lookup = false;
}
}