lldb/bindings/interface/SBModule.i - llvm-project - Git at Google

 //===-- SWIG Interface for SBModule -----------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 namespace lldb {

 #ifdef SWIGPYTHON
 %pythoncode%{
 # ==================================
 # Helper function for SBModule class
 # ==================================
 def in_range(symbol, section):
     """Test whether a symbol is within the range of a section."""
     symSA = symbol.GetStartAddress().GetFileAddress()
     symEA = symbol.GetEndAddress().GetFileAddress()
     secSA = section.GetFileAddress()
     secEA = secSA + section.GetByteSize()

     if symEA != LLDB_INVALID_ADDRESS:
         if secSA <= symSA and symEA <= secEA:
             return True
         else:
             return False
     else:
         if secSA <= symSA and symSA < secEA:
             return True
         else:
             return False
 %}
 #endif

 %feature("docstring",
 "Represents an executable image and its associated object and symbol files.

 The module is designed to be able to select a single slice of an
 executable image as it would appear on disk and during program
 execution.

 You can retrieve SBModule from :py:class:`SBSymbolContext` , which in turn is available
 from SBFrame.

 SBModule supports symbol iteration, for example, ::

     for symbol in module:
         name = symbol.GetName()
         saddr = symbol.GetStartAddress()
         eaddr = symbol.GetEndAddress()

 and rich comparison methods which allow the API program to use, ::

     if thisModule == thatModule:
         print('This module is the same as that module')

 to test module equality.  A module also contains object file sections, namely
 :py:class:`SBSection` .  SBModule supports section iteration through section_iter(), for
 example, ::

     print('Number of sections: %d' % module.GetNumSections())
     for sec in module.section_iter():
         print(sec)

 And to iterate the symbols within a SBSection, use symbol_in_section_iter(), ::

     # Iterates the text section and prints each symbols within each sub-section.
     for subsec in text_sec:
         print(INDENT + repr(subsec))
         for sym in exe_module.symbol_in_section_iter(subsec):
             print(INDENT2 + repr(sym))
             print(INDENT2 + 'symbol type: %s' % symbol_type_to_str(sym.GetType()))

 produces this following output: ::

     [0x0000000100001780-0x0000000100001d5c) a.out.__TEXT.__text
         id = {0x00000004}, name = 'mask_access(MaskAction, unsigned int)', range = [0x00000001000017c0-0x0000000100001870)
         symbol type: code
         id = {0x00000008}, name = 'thread_func(void*)', range = [0x0000000100001870-0x00000001000019b0)
         symbol type: code
         id = {0x0000000c}, name = 'main', range = [0x00000001000019b0-0x0000000100001d5c)
         symbol type: code
         id = {0x00000023}, name = 'start', address = 0x0000000100001780
         symbol type: code
     [0x0000000100001d5c-0x0000000100001da4) a.out.__TEXT.__stubs
         id = {0x00000024}, name = '__stack_chk_fail', range = [0x0000000100001d5c-0x0000000100001d62)
         symbol type: trampoline
         id = {0x00000028}, name = 'exit', range = [0x0000000100001d62-0x0000000100001d68)
         symbol type: trampoline
         id = {0x00000029}, name = 'fflush', range = [0x0000000100001d68-0x0000000100001d6e)
         symbol type: trampoline
         id = {0x0000002a}, name = 'fgets', range = [0x0000000100001d6e-0x0000000100001d74)
         symbol type: trampoline
         id = {0x0000002b}, name = 'printf', range = [0x0000000100001d74-0x0000000100001d7a)
         symbol type: trampoline
         id = {0x0000002c}, name = 'pthread_create', range = [0x0000000100001d7a-0x0000000100001d80)
         symbol type: trampoline
         id = {0x0000002d}, name = 'pthread_join', range = [0x0000000100001d80-0x0000000100001d86)
         symbol type: trampoline
         id = {0x0000002e}, name = 'pthread_mutex_lock', range = [0x0000000100001d86-0x0000000100001d8c)
         symbol type: trampoline
         id = {0x0000002f}, name = 'pthread_mutex_unlock', range = [0x0000000100001d8c-0x0000000100001d92)
         symbol type: trampoline
         id = {0x00000030}, name = 'rand', range = [0x0000000100001d92-0x0000000100001d98)
         symbol type: trampoline
         id = {0x00000031}, name = 'strtoul', range = [0x0000000100001d98-0x0000000100001d9e)
         symbol type: trampoline
         id = {0x00000032}, name = 'usleep', range = [0x0000000100001d9e-0x0000000100001da4)
         symbol type: trampoline
     [0x0000000100001da4-0x0000000100001e2c) a.out.__TEXT.__stub_helper
     [0x0000000100001e2c-0x0000000100001f10) a.out.__TEXT.__cstring
     [0x0000000100001f10-0x0000000100001f68) a.out.__TEXT.__unwind_info
     [0x0000000100001f68-0x0000000100001ff8) a.out.__TEXT.__eh_frame
 "
 ) SBModule;
 class SBModule
 {
 public:

     SBModule ();

     SBModule (const lldb::SBModule &rhs);

     SBModule (const lldb::SBModuleSpec &module_spec);

     SBModule (lldb::SBProcess &process,
               lldb::addr_t header_addr);

     ~SBModule ();

     bool
     IsValid () const;

     explicit operator bool() const;

     void
     Clear();

     %feature("docstring", "
     Get const accessor for the module file specification.

     This function returns the file for the module on the host system
     that is running LLDB. This can differ from the path on the
     platform since we might be doing remote debugging.

     @return
         A const reference to the file specification object.") GetFileSpec;
     lldb::SBFileSpec
     GetFileSpec () const;

     %feature("docstring", "
     Get accessor for the module platform file specification.

     Platform file refers to the path of the module as it is known on
     the remote system on which it is being debugged. For local
     debugging this is always the same as Module::GetFileSpec(). But
     remote debugging might mention a file '/usr/lib/liba.dylib'
     which might be locally downloaded and cached. In this case the
     platform file could be something like:
     '/tmp/lldb/platform-cache/remote.host.computer/usr/lib/liba.dylib'
     The file could also be cached in a local developer kit directory.

     @return
         A const reference to the file specification object.") GetPlatformFileSpec;
     lldb::SBFileSpec
     GetPlatformFileSpec () const;

     bool
     SetPlatformFileSpec (const lldb::SBFileSpec &platform_file);

     lldb::SBFileSpec
     GetRemoteInstallFileSpec ();

     bool
     SetRemoteInstallFileSpec (lldb::SBFileSpec &file);

     %feature("docstring", "Returns the UUID of the module as a Python string."
     ) GetUUIDString;
     const char *
     GetUUIDString () const;

     bool operator==(const lldb::SBModule &rhs) const;

     bool operator!=(const lldb::SBModule &rhs) const;

     lldb::SBSection
     FindSection (const char *sect_name);

     lldb::SBAddress
     ResolveFileAddress (lldb::addr_t vm_addr);

     lldb::SBSymbolContext
     ResolveSymbolContextForAddress (const lldb::SBAddress& addr,
                                     uint32_t resolve_scope);

     bool
     GetDescription (lldb::SBStream &description);

     uint32_t
     GetNumCompileUnits();

     lldb::SBCompileUnit
     GetCompileUnitAtIndex (uint32_t);

     %feature("docstring", "
     Find compile units related to this module and passed source
     file.

     @param[in] sb_file_spec
         A :py:class:`SBFileSpec` object that contains source file
         specification.

     @return
         A :py:class:`SBSymbolContextList` that gets filled in with all of
         the symbol contexts for all the matches.") FindCompileUnits;
     lldb::SBSymbolContextList
     FindCompileUnits (const lldb::SBFileSpec &sb_file_spec);

     size_t
     GetNumSymbols ();

     lldb::SBSymbol
     GetSymbolAtIndex (size_t idx);

     lldb::SBSymbol
     FindSymbol (const char *name,
                 lldb::SymbolType type = eSymbolTypeAny);

     lldb::SBSymbolContextList
     FindSymbols (const char *name,
                  lldb::SymbolType type = eSymbolTypeAny);


     size_t
     GetNumSections ();

     lldb::SBSection
     GetSectionAtIndex (size_t idx);


     %feature("docstring", "
     Find functions by name.

     @param[in] name
         The name of the function we are looking for.

     @param[in] name_type_mask
         A logical OR of one or more FunctionNameType enum bits that
         indicate what kind of names should be used when doing the
         lookup. Bits include fully qualified names, base names,
         C++ methods, or ObjC selectors.
         See FunctionNameType for more details.

     @return
         A symbol context list that gets filled in with all of the
         matches.") FindFunctions;
     lldb::SBSymbolContextList
     FindFunctions (const char *name,
                    uint32_t name_type_mask = lldb::eFunctionNameTypeAny);

     lldb::SBType
     FindFirstType (const char* name);

     lldb::SBTypeList
     FindTypes (const char* type);

     lldb::SBType
     GetTypeByID (lldb::user_id_t uid);

     lldb::SBType
     GetBasicType(lldb::BasicType type);

     %feature("docstring", "
     Get all types matching type_mask from debug info in this
     module.

     @param[in] type_mask
         A bitfield that consists of one or more bits logically OR'ed
         together from the lldb::TypeClass enumeration. This allows
         you to request only structure types, or only class, struct
         and union types. Passing in lldb::eTypeClassAny will return
         all types found in the debug information for this module.

     @return
         A list of types in this module that match type_mask") GetTypes;
     lldb::SBTypeList
     GetTypes (uint32_t type_mask = lldb::eTypeClassAny);

     %feature("docstring", "
     Find global and static variables by name.

     @param[in] target
         A valid SBTarget instance representing the debuggee.

     @param[in] name
         The name of the global or static variable we are looking
         for.

     @param[in] max_matches
         Allow the number of matches to be limited to max_matches.

     @return
         A list of matched variables in an SBValueList.") FindGlobalVariables;
     lldb::SBValueList
     FindGlobalVariables (lldb::SBTarget &target,
                          const char *name,
                          uint32_t max_matches);

     %feature("docstring", "
     Find the first global (or static) variable by name.

     @param[in] target
         A valid SBTarget instance representing the debuggee.

     @param[in] name
         The name of the global or static variable we are looking
         for.

     @return
         An SBValue that gets filled in with the found variable (if any).") FindFirstGlobalVariable;
     lldb::SBValue
     FindFirstGlobalVariable (lldb::SBTarget &target, const char *name);

     lldb::ByteOrder
     GetByteOrder ();

     uint32_t
     GetAddressByteSize();

     const char *
     GetTriple ();

     uint32_t
     GetVersion (uint32_t *versions,
                 uint32_t num_versions);

     lldb::SBFileSpec
     GetSymbolFileSpec() const;

     lldb::SBAddress
     GetObjectFileHeaderAddress() const;

     lldb::SBAddress
     GetObjectFileEntryPointAddress() const;

     %feature("docstring", "
     Returns the number of modules in the module cache. This is an
     implementation detail exposed for testing and should not be relied upon.

     @return
         The number of modules in the module cache.") GetNumberAllocatedModules;
     static uint32_t
     GetNumberAllocatedModules();

     %feature("docstring", "
     Removes all modules which are no longer needed by any part of LLDB from
     the module cache.

     This is an implementation detail exposed for testing and should not be
     relied upon. Use SBDebugger::MemoryPressureDetected instead to reduce
     LLDB's memory consumption during execution.
     ") GarbageCollectAllocatedModules;
     static void
     GarbageCollectAllocatedModules();

     STRING_EXTENSION(SBModule)

 #ifdef SWIGPYTHON
     %pythoncode %{
         def __len__(self):
             '''Return the number of symbols in a lldb.SBModule object.'''
             return self.GetNumSymbols()

         def __iter__(self):
             '''Iterate over all symbols in a lldb.SBModule object.'''
             return lldb_iter(self, 'GetNumSymbols', 'GetSymbolAtIndex')

         def section_iter(self):
             '''Iterate over all sections in a lldb.SBModule object.'''
             return lldb_iter(self, 'GetNumSections', 'GetSectionAtIndex')

         def compile_unit_iter(self):
             '''Iterate over all compile units in a lldb.SBModule object.'''
             return lldb_iter(self, 'GetNumCompileUnits', 'GetCompileUnitAtIndex')

         def symbol_in_section_iter(self, section):
             '''Given a module and its contained section, returns an iterator on the
             symbols within the section.'''
             for sym in self:
                 if in_range(sym, section):
                     yield sym

         class symbols_access(object):
             re_compile_type = type(re.compile('.'))
             '''A helper object that will lazily hand out lldb.SBSymbol objects for a module when supplied an index, name, or regular expression.'''
             def __init__(self, sbmodule):
                 self.sbmodule = sbmodule

             def __len__(self):
                 if self.sbmodule:
                     return int(self.sbmodule.GetNumSymbols())
                 return 0

             def __getitem__(self, key):
                 count = len(self)
                 if type(key) is int:
                     if key < count:
                         return self.sbmodule.GetSymbolAtIndex(key)
                 elif type(key) is str:
                     matches = []
                     sc_list = self.sbmodule.FindSymbols(key)
                     for sc in sc_list:
                         symbol = sc.symbol
                         if symbol:
                             matches.append(symbol)
                     return matches
                 elif isinstance(key, self.re_compile_type):
                     matches = []
                     for idx in range(count):
                         symbol = self.sbmodule.GetSymbolAtIndex(idx)
                         added = False
                         name = symbol.name
                         if name:
                             re_match = key.search(name)
                             if re_match:
                                 matches.append(symbol)
                                 added = True
                         if not added:
                             mangled = symbol.mangled
                             if mangled:
                                 re_match = key.search(mangled)
                                 if re_match:
                                     matches.append(symbol)
                     return matches
                 else:
                     print("error: unsupported item type: %s" % type(key))
                 return None

         def get_symbols_access_object(self):
             '''An accessor function that returns a symbols_access() object which allows lazy symbol access from a lldb.SBModule object.'''
             return self.symbols_access (self)

         def get_compile_units_access_object (self):
             '''An accessor function that returns a compile_units_access() object which allows lazy compile unit access from a lldb.SBModule object.'''
             return self.compile_units_access (self)

         def get_symbols_array(self):
             '''An accessor function that returns a list() that contains all symbols in a lldb.SBModule object.'''
             symbols = []
             for idx in range(self.num_symbols):
                 symbols.append(self.GetSymbolAtIndex(idx))
             return symbols

         class sections_access(object):
             re_compile_type = type(re.compile('.'))
             '''A helper object that will lazily hand out lldb.SBSection objects for a module when supplied an index, name, or regular expression.'''
             def __init__(self, sbmodule):
                 self.sbmodule = sbmodule

             def __len__(self):
                 if self.sbmodule:
                     return int(self.sbmodule.GetNumSections())
                 return 0

             def __getitem__(self, key):
                 count = len(self)
                 if type(key) is int:
                     if key < count:
                         return self.sbmodule.GetSectionAtIndex(key)
                 elif type(key) is str:
                     for idx in range(count):
                         section = self.sbmodule.GetSectionAtIndex(idx)
                         if section.name == key:
                             return section
                 elif isinstance(key, self.re_compile_type):
                     matches = []
                     for idx in range(count):
                         section = self.sbmodule.GetSectionAtIndex(idx)
                         name = section.name
                         if name:
                             re_match = key.search(name)
                             if re_match:
                                 matches.append(section)
                     return matches
                 else:
                     print("error: unsupported item type: %s" % type(key))
                 return None

         class compile_units_access(object):
             re_compile_type = type(re.compile('.'))
             '''A helper object that will lazily hand out lldb.SBCompileUnit objects for a module when supplied an index, full or partial path, or regular expression.'''
             def __init__(self, sbmodule):
                 self.sbmodule = sbmodule

             def __len__(self):
                 if self.sbmodule:
                     return int(self.sbmodule.GetNumCompileUnits())
                 return 0

             def __getitem__(self, key):
                 count = len(self)
                 if type(key) is int:
                     if key < count:
                         return self.sbmodule.GetCompileUnitAtIndex(key)
                 elif type(key) is str:
                     is_full_path = key[0] == '/'
                     for idx in range(count):
                         comp_unit = self.sbmodule.GetCompileUnitAtIndex(idx)
                         if is_full_path:
                             if comp_unit.file.fullpath == key:
                                 return comp_unit
                         else:
                             if comp_unit.file.basename == key:
                                 return comp_unit
                 elif isinstance(key, self.re_compile_type):
                     matches = []
                     for idx in range(count):
                         comp_unit = self.sbmodule.GetCompileUnitAtIndex(idx)
                         fullpath = comp_unit.file.fullpath
                         if fullpath:
                             re_match = key.search(fullpath)
                             if re_match:
                                 matches.append(comp_unit)
                     return matches
                 else:
                     print("error: unsupported item type: %s" % type(key))
                 return None

         def get_sections_access_object(self):
             '''An accessor function that returns a sections_access() object which allows lazy section array access.'''
             return self.sections_access (self)

         def get_sections_array(self):
             '''An accessor function that returns an array object that contains all sections in this module object.'''
             if not hasattr(self, 'sections_array'):
                 self.sections_array = []
                 for idx in range(self.num_sections):
                     self.sections_array.append(self.GetSectionAtIndex(idx))
             return self.sections_array

         def get_compile_units_array(self):
             '''An accessor function that returns an array object that contains all compile_units in this module object.'''
             if not hasattr(self, 'compile_units_array'):
                 self.compile_units_array = []
                 for idx in range(self.GetNumCompileUnits()):
                     self.compile_units_array.append(self.GetCompileUnitAtIndex(idx))
             return self.compile_units_array

         symbols = property(get_symbols_array, None, doc='''A read only property that returns a list() of lldb.SBSymbol objects contained in this module.''')
         symbol = property(get_symbols_access_object, None, doc='''A read only property that can be used to access symbols by index ("symbol = module.symbol[0]"), name ("symbols = module.symbol['main']"), or using a regular expression ("symbols = module.symbol[re.compile(...)]"). The return value is a single lldb.SBSymbol object for array access, and a list() of lldb.SBSymbol objects for name and regular expression access''')
         sections = property(get_sections_array, None, doc='''A read only property that returns a list() of lldb.SBSection objects contained in this module.''')
         compile_units = property(get_compile_units_array, None, doc='''A read only property that returns a list() of lldb.SBCompileUnit objects contained in this module.''')
         section = property(get_sections_access_object, None, doc='''A read only property that can be used to access symbols by index ("section = module.section[0]"), name ("sections = module.section[\'main\']"), or using a regular expression ("sections = module.section[re.compile(...)]"). The return value is a single lldb.SBSection object for array access, and a list() of lldb.SBSection objects for name and regular expression access''')
         section = property(get_sections_access_object, None, doc='''A read only property that can be used to access compile units by index ("compile_unit = module.compile_unit[0]"), name ("compile_unit = module.compile_unit[\'main.cpp\']"), or using a regular expression ("compile_unit = module.compile_unit[re.compile(...)]"). The return value is a single lldb.SBCompileUnit object for array access or by full or partial path, and a list() of lldb.SBCompileUnit objects regular expressions.''')

         def get_uuid(self):
             return uuid.UUID (self.GetUUIDString())

         uuid = property(get_uuid, None, doc='''A read only property that returns a standard python uuid.UUID object that represents the UUID of this module.''')
         file = property(GetFileSpec, None, doc='''A read only property that returns an lldb object that represents the file (lldb.SBFileSpec) for this object file for this module as it is represented where it is being debugged.''')
         platform_file = property(GetPlatformFileSpec, None, doc='''A read only property that returns an lldb object that represents the file (lldb.SBFileSpec) for this object file for this module as it is represented on the current host system.''')
         byte_order = property(GetByteOrder, None, doc='''A read only property that returns an lldb enumeration value (lldb.eByteOrderLittle, lldb.eByteOrderBig, lldb.eByteOrderInvalid) that represents the byte order for this module.''')
         addr_size = property(GetAddressByteSize, None, doc='''A read only property that returns the size in bytes of an address for this module.''')
         triple = property(GetTriple, None, doc='''A read only property that returns the target triple (arch-vendor-os) for this module.''')
         num_symbols = property(GetNumSymbols, None, doc='''A read only property that returns number of symbols in the module symbol table as an integer.''')
         num_sections = property(GetNumSections, None, doc='''A read only property that returns number of sections in the module as an integer.''')

     %}
 #endif

 };

 } // namespace lldb
	//===-- SWIG Interface for SBModule ------------------------------ C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	namespace lldb {

	#ifdef SWIGPYTHON
	%pythoncode%{
	# ==================================
	# Helper function for SBModule class
	# ==================================
	def in_range(symbol, section):
	"""Test whether a symbol is within the range of a section."""
	symSA = symbol.GetStartAddress().GetFileAddress()
	symEA = symbol.GetEndAddress().GetFileAddress()
	secSA = section.GetFileAddress()
	secEA = secSA + section.GetByteSize()

	if symEA != LLDB_INVALID_ADDRESS:
	if secSA <= symSA and symEA <= secEA:
	return True
	else:
	return False
	else:
	if secSA <= symSA and symSA < secEA:
	return True
	else:
	return False
	%}
	#endif

	%feature("docstring",
	"Represents an executable image and its associated object and symbol files.

	The module is designed to be able to select a single slice of an
	executable image as it would appear on disk and during program
	execution.

	You can retrieve SBModule from :py:class:`SBSymbolContext` , which in turn is available
	from SBFrame.

	SBModule supports symbol iteration, for example, ::

	for symbol in module:
	name = symbol.GetName()
	saddr = symbol.GetStartAddress()
	eaddr = symbol.GetEndAddress()

	and rich comparison methods which allow the API program to use, ::

	if thisModule == thatModule:
	print('This module is the same as that module')

	to test module equality. A module also contains object file sections, namely
	:py:class:`SBSection` . SBModule supports section iteration through section_iter(), for
	example, ::

	print('Number of sections: %d' % module.GetNumSections())
	for sec in module.section_iter():
	print(sec)

	And to iterate the symbols within a SBSection, use symbol_in_section_iter(), ::

	# Iterates the text section and prints each symbols within each sub-section.
	for subsec in text_sec:
	print(INDENT + repr(subsec))
	for sym in exe_module.symbol_in_section_iter(subsec):
	print(INDENT2 + repr(sym))
	print(INDENT2 + 'symbol type: %s' % symbol_type_to_str(sym.GetType()))

	produces this following output: ::

	[0x0000000100001780-0x0000000100001d5c) a.out.__TEXT.__text
	id = {0x00000004}, name = 'mask_access(MaskAction, unsigned int)', range = [0x00000001000017c0-0x0000000100001870)
	symbol type: code
	id = {0x00000008}, name = 'thread_func(void*)', range = [0x0000000100001870-0x00000001000019b0)
	symbol type: code
	id = {0x0000000c}, name = 'main', range = [0x00000001000019b0-0x0000000100001d5c)
	symbol type: code
	id = {0x00000023}, name = 'start', address = 0x0000000100001780
	symbol type: code
	[0x0000000100001d5c-0x0000000100001da4) a.out.__TEXT.__stubs
	id = {0x00000024}, name = '__stack_chk_fail', range = [0x0000000100001d5c-0x0000000100001d62)
	symbol type: trampoline
	id = {0x00000028}, name = 'exit', range = [0x0000000100001d62-0x0000000100001d68)
	symbol type: trampoline
	id = {0x00000029}, name = 'fflush', range = [0x0000000100001d68-0x0000000100001d6e)
	symbol type: trampoline
	id = {0x0000002a}, name = 'fgets', range = [0x0000000100001d6e-0x0000000100001d74)
	symbol type: trampoline
	id = {0x0000002b}, name = 'printf', range = [0x0000000100001d74-0x0000000100001d7a)
	symbol type: trampoline
	id = {0x0000002c}, name = 'pthread_create', range = [0x0000000100001d7a-0x0000000100001d80)
	symbol type: trampoline
	id = {0x0000002d}, name = 'pthread_join', range = [0x0000000100001d80-0x0000000100001d86)
	symbol type: trampoline
	id = {0x0000002e}, name = 'pthread_mutex_lock', range = [0x0000000100001d86-0x0000000100001d8c)
	symbol type: trampoline
	id = {0x0000002f}, name = 'pthread_mutex_unlock', range = [0x0000000100001d8c-0x0000000100001d92)
	symbol type: trampoline
	id = {0x00000030}, name = 'rand', range = [0x0000000100001d92-0x0000000100001d98)
	symbol type: trampoline
	id = {0x00000031}, name = 'strtoul', range = [0x0000000100001d98-0x0000000100001d9e)
	symbol type: trampoline
	id = {0x00000032}, name = 'usleep', range = [0x0000000100001d9e-0x0000000100001da4)
	symbol type: trampoline
	[0x0000000100001da4-0x0000000100001e2c) a.out.__TEXT.__stub_helper
	[0x0000000100001e2c-0x0000000100001f10) a.out.__TEXT.__cstring
	[0x0000000100001f10-0x0000000100001f68) a.out.__TEXT.__unwind_info
	[0x0000000100001f68-0x0000000100001ff8) a.out.__TEXT.__eh_frame
	"
	) SBModule;
	class SBModule
	{
	public:

	SBModule ();

	SBModule (const lldb::SBModule &rhs);

	SBModule (const lldb::SBModuleSpec &module_spec);

	SBModule (lldb::SBProcess &process,
	lldb::addr_t header_addr);

	~SBModule ();

	bool
	IsValid () const;

	explicit operator bool() const;

	void
	Clear();

	%feature("docstring", "
	Get const accessor for the module file specification.

	This function returns the file for the module on the host system
	that is running LLDB. This can differ from the path on the
	platform since we might be doing remote debugging.

	@return
	A const reference to the file specification object.") GetFileSpec;
	lldb::SBFileSpec
	GetFileSpec () const;

	%feature("docstring", "
	Get accessor for the module platform file specification.

	Platform file refers to the path of the module as it is known on
	the remote system on which it is being debugged. For local
	debugging this is always the same as Module::GetFileSpec(). But
	remote debugging might mention a file '/usr/lib/liba.dylib'
	which might be locally downloaded and cached. In this case the
	platform file could be something like:
	'/tmp/lldb/platform-cache/remote.host.computer/usr/lib/liba.dylib'
	The file could also be cached in a local developer kit directory.

	@return
	A const reference to the file specification object.") GetPlatformFileSpec;
	lldb::SBFileSpec
	GetPlatformFileSpec () const;

	bool
	SetPlatformFileSpec (const lldb::SBFileSpec &platform_file);

	lldb::SBFileSpec
	GetRemoteInstallFileSpec ();

	bool
	SetRemoteInstallFileSpec (lldb::SBFileSpec &file);

	%feature("docstring", "Returns the UUID of the module as a Python string."
	) GetUUIDString;
	const char *
	GetUUIDString () const;

	bool operator==(const lldb::SBModule &rhs) const;

	bool operator!=(const lldb::SBModule &rhs) const;

	lldb::SBSection
	FindSection (const char *sect_name);

	lldb::SBAddress
	ResolveFileAddress (lldb::addr_t vm_addr);

	lldb::SBSymbolContext
	ResolveSymbolContextForAddress (const lldb::SBAddress& addr,
	uint32_t resolve_scope);

	bool
	GetDescription (lldb::SBStream &description);

	uint32_t
	GetNumCompileUnits();

	lldb::SBCompileUnit
	GetCompileUnitAtIndex (uint32_t);

	%feature("docstring", "
	Find compile units related to this module and passed source
	file.

	@param[in] sb_file_spec
	A :py:class:`SBFileSpec` object that contains source file
	specification.

	@return
	A :py:class:`SBSymbolContextList` that gets filled in with all of
	the symbol contexts for all the matches.") FindCompileUnits;
	lldb::SBSymbolContextList
	FindCompileUnits (const lldb::SBFileSpec &sb_file_spec);

	size_t
	GetNumSymbols ();

	lldb::SBSymbol
	GetSymbolAtIndex (size_t idx);

	lldb::SBSymbol
	FindSymbol (const char *name,
	lldb::SymbolType type = eSymbolTypeAny);

	lldb::SBSymbolContextList
	FindSymbols (const char *name,
	lldb::SymbolType type = eSymbolTypeAny);


	size_t
	GetNumSections ();

	lldb::SBSection
	GetSectionAtIndex (size_t idx);


	%feature("docstring", "
	Find functions by name.

	@param[in] name
	The name of the function we are looking for.

	@param[in] name_type_mask
	A logical OR of one or more FunctionNameType enum bits that
	indicate what kind of names should be used when doing the
	lookup. Bits include fully qualified names, base names,
	C++ methods, or ObjC selectors.
	See FunctionNameType for more details.

	@return
	A symbol context list that gets filled in with all of the
	matches.") FindFunctions;
	lldb::SBSymbolContextList
	FindFunctions (const char *name,
	uint32_t name_type_mask = lldb::eFunctionNameTypeAny);

	lldb::SBType
	FindFirstType (const char* name);

	lldb::SBTypeList
	FindTypes (const char* type);

	lldb::SBType
	GetTypeByID (lldb::user_id_t uid);

	lldb::SBType
	GetBasicType(lldb::BasicType type);

	%feature("docstring", "
	Get all types matching type_mask from debug info in this
	module.

	@param[in] type_mask
	A bitfield that consists of one or more bits logically OR'ed
	together from the lldb::TypeClass enumeration. This allows
	you to request only structure types, or only class, struct
	and union types. Passing in lldb::eTypeClassAny will return
	all types found in the debug information for this module.

	@return
	A list of types in this module that match type_mask") GetTypes;
	lldb::SBTypeList
	GetTypes (uint32_t type_mask = lldb::eTypeClassAny);

	%feature("docstring", "
	Find global and static variables by name.

	@param[in] target
	A valid SBTarget instance representing the debuggee.

	@param[in] name
	The name of the global or static variable we are looking
	for.

	@param[in] max_matches
	Allow the number of matches to be limited to max_matches.

	@return
	A list of matched variables in an SBValueList.") FindGlobalVariables;
	lldb::SBValueList
	FindGlobalVariables (lldb::SBTarget &target,
	const char *name,
	uint32_t max_matches);

	%feature("docstring", "
	Find the first global (or static) variable by name.

	@param[in] target
	A valid SBTarget instance representing the debuggee.

	@param[in] name
	The name of the global or static variable we are looking
	for.

	@return
	An SBValue that gets filled in with the found variable (if any).") FindFirstGlobalVariable;
	lldb::SBValue
	FindFirstGlobalVariable (lldb::SBTarget &target, const char *name);

	lldb::ByteOrder
	GetByteOrder ();

	uint32_t
	GetAddressByteSize();

	const char *
	GetTriple ();

	uint32_t
	GetVersion (uint32_t *versions,
	uint32_t num_versions);

	lldb::SBFileSpec
	GetSymbolFileSpec() const;

	lldb::SBAddress
	GetObjectFileHeaderAddress() const;

	lldb::SBAddress
	GetObjectFileEntryPointAddress() const;

	%feature("docstring", "
	Returns the number of modules in the module cache. This is an
	implementation detail exposed for testing and should not be relied upon.

	@return
	The number of modules in the module cache.") GetNumberAllocatedModules;
	static uint32_t
	GetNumberAllocatedModules();

	%feature("docstring", "
	Removes all modules which are no longer needed by any part of LLDB from
	the module cache.

	This is an implementation detail exposed for testing and should not be
	relied upon. Use SBDebugger::MemoryPressureDetected instead to reduce
	LLDB's memory consumption during execution.
	") GarbageCollectAllocatedModules;
	static void
	GarbageCollectAllocatedModules();

	STRING_EXTENSION(SBModule)

	#ifdef SWIGPYTHON
	%pythoncode %{
	def __len__(self):
	'''Return the number of symbols in a lldb.SBModule object.'''
	return self.GetNumSymbols()

	def __iter__(self):
	'''Iterate over all symbols in a lldb.SBModule object.'''
	return lldb_iter(self, 'GetNumSymbols', 'GetSymbolAtIndex')

	def section_iter(self):
	'''Iterate over all sections in a lldb.SBModule object.'''
	return lldb_iter(self, 'GetNumSections', 'GetSectionAtIndex')

	def compile_unit_iter(self):
	'''Iterate over all compile units in a lldb.SBModule object.'''
	return lldb_iter(self, 'GetNumCompileUnits', 'GetCompileUnitAtIndex')

	def symbol_in_section_iter(self, section):
	'''Given a module and its contained section, returns an iterator on the
	symbols within the section.'''
	for sym in self:
	if in_range(sym, section):
	yield sym

	class symbols_access(object):
	re_compile_type = type(re.compile('.'))
	'''A helper object that will lazily hand out lldb.SBSymbol objects for a module when supplied an index, name, or regular expression.'''
	def __init__(self, sbmodule):
	self.sbmodule = sbmodule

	def __len__(self):
	if self.sbmodule:
	return int(self.sbmodule.GetNumSymbols())
	return 0

	def __getitem__(self, key):
	count = len(self)
	if type(key) is int:
	if key < count:
	return self.sbmodule.GetSymbolAtIndex(key)
	elif type(key) is str:
	matches = []
	sc_list = self.sbmodule.FindSymbols(key)
	for sc in sc_list:
	symbol = sc.symbol
	if symbol:
	matches.append(symbol)
	return matches
	elif isinstance(key, self.re_compile_type):
	matches = []
	for idx in range(count):
	symbol = self.sbmodule.GetSymbolAtIndex(idx)
	added = False
	name = symbol.name
	if name:
	re_match = key.search(name)
	if re_match:
	matches.append(symbol)
	added = True
	if not added:
	mangled = symbol.mangled
	if mangled:
	re_match = key.search(mangled)
	if re_match:
	matches.append(symbol)
	return matches
	else:
	print("error: unsupported item type: %s" % type(key))
	return None

	def get_symbols_access_object(self):
	'''An accessor function that returns a symbols_access() object which allows lazy symbol access from a lldb.SBModule object.'''
	return self.symbols_access (self)

	def get_compile_units_access_object (self):
	'''An accessor function that returns a compile_units_access() object which allows lazy compile unit access from a lldb.SBModule object.'''
	return self.compile_units_access (self)

	def get_symbols_array(self):
	'''An accessor function that returns a list() that contains all symbols in a lldb.SBModule object.'''
	symbols = []
	for idx in range(self.num_symbols):
	symbols.append(self.GetSymbolAtIndex(idx))
	return symbols

	class sections_access(object):
	re_compile_type = type(re.compile('.'))
	'''A helper object that will lazily hand out lldb.SBSection objects for a module when supplied an index, name, or regular expression.'''
	def __init__(self, sbmodule):
	self.sbmodule = sbmodule

	def __len__(self):
	if self.sbmodule:
	return int(self.sbmodule.GetNumSections())
	return 0

	def __getitem__(self, key):
	count = len(self)
	if type(key) is int:
	if key < count:
	return self.sbmodule.GetSectionAtIndex(key)
	elif type(key) is str:
	for idx in range(count):
	section = self.sbmodule.GetSectionAtIndex(idx)
	if section.name == key:
	return section
	elif isinstance(key, self.re_compile_type):
	matches = []
	for idx in range(count):
	section = self.sbmodule.GetSectionAtIndex(idx)
	name = section.name
	if name:
	re_match = key.search(name)
	if re_match:
	matches.append(section)
	return matches
	else:
	print("error: unsupported item type: %s" % type(key))
	return None

	class compile_units_access(object):
	re_compile_type = type(re.compile('.'))
	'''A helper object that will lazily hand out lldb.SBCompileUnit objects for a module when supplied an index, full or partial path, or regular expression.'''
	def __init__(self, sbmodule):
	self.sbmodule = sbmodule

	def __len__(self):
	if self.sbmodule:
	return int(self.sbmodule.GetNumCompileUnits())
	return 0

	def __getitem__(self, key):
	count = len(self)
	if type(key) is int:
	if key < count:
	return self.sbmodule.GetCompileUnitAtIndex(key)
	elif type(key) is str:
	is_full_path = key[0] == '/'
	for idx in range(count):
	comp_unit = self.sbmodule.GetCompileUnitAtIndex(idx)
	if is_full_path:
	if comp_unit.file.fullpath == key:
	return comp_unit
	else:
	if comp_unit.file.basename == key:
	return comp_unit
	elif isinstance(key, self.re_compile_type):
	matches = []
	for idx in range(count):
	comp_unit = self.sbmodule.GetCompileUnitAtIndex(idx)
	fullpath = comp_unit.file.fullpath
	if fullpath:
	re_match = key.search(fullpath)
	if re_match:
	matches.append(comp_unit)
	return matches
	else:
	print("error: unsupported item type: %s" % type(key))
	return None

	def get_sections_access_object(self):
	'''An accessor function that returns a sections_access() object which allows lazy section array access.'''
	return self.sections_access (self)

	def get_sections_array(self):
	'''An accessor function that returns an array object that contains all sections in this module object.'''
	if not hasattr(self, 'sections_array'):
	self.sections_array = []
	for idx in range(self.num_sections):
	self.sections_array.append(self.GetSectionAtIndex(idx))
	return self.sections_array

	def get_compile_units_array(self):
	'''An accessor function that returns an array object that contains all compile_units in this module object.'''
	if not hasattr(self, 'compile_units_array'):
	self.compile_units_array = []
	for idx in range(self.GetNumCompileUnits()):
	self.compile_units_array.append(self.GetCompileUnitAtIndex(idx))
	return self.compile_units_array

	symbols = property(get_symbols_array, None, doc='''A read only property that returns a list() of lldb.SBSymbol objects contained in this module.''')
	symbol = property(get_symbols_access_object, None, doc='''A read only property that can be used to access symbols by index ("symbol = module.symbol[0]"), name ("symbols = module.symbol['main']"), or using a regular expression ("symbols = module.symbol[re.compile(...)]"). The return value is a single lldb.SBSymbol object for array access, and a list() of lldb.SBSymbol objects for name and regular expression access''')
	sections = property(get_sections_array, None, doc='''A read only property that returns a list() of lldb.SBSection objects contained in this module.''')
	compile_units = property(get_compile_units_array, None, doc='''A read only property that returns a list() of lldb.SBCompileUnit objects contained in this module.''')
	section = property(get_sections_access_object, None, doc='''A read only property that can be used to access symbols by index ("section = module.section[0]"), name ("sections = module.section[\'main\']"), or using a regular expression ("sections = module.section[re.compile(...)]"). The return value is a single lldb.SBSection object for array access, and a list() of lldb.SBSection objects for name and regular expression access''')
	section = property(get_sections_access_object, None, doc='''A read only property that can be used to access compile units by index ("compile_unit = module.compile_unit[0]"), name ("compile_unit = module.compile_unit[\'main.cpp\']"), or using a regular expression ("compile_unit = module.compile_unit[re.compile(...)]"). The return value is a single lldb.SBCompileUnit object for array access or by full or partial path, and a list() of lldb.SBCompileUnit objects regular expressions.''')

	def get_uuid(self):
	return uuid.UUID (self.GetUUIDString())

	uuid = property(get_uuid, None, doc='''A read only property that returns a standard python uuid.UUID object that represents the UUID of this module.''')
	file = property(GetFileSpec, None, doc='''A read only property that returns an lldb object that represents the file (lldb.SBFileSpec) for this object file for this module as it is represented where it is being debugged.''')
	platform_file = property(GetPlatformFileSpec, None, doc='''A read only property that returns an lldb object that represents the file (lldb.SBFileSpec) for this object file for this module as it is represented on the current host system.''')
	byte_order = property(GetByteOrder, None, doc='''A read only property that returns an lldb enumeration value (lldb.eByteOrderLittle, lldb.eByteOrderBig, lldb.eByteOrderInvalid) that represents the byte order for this module.''')
	addr_size = property(GetAddressByteSize, None, doc='''A read only property that returns the size in bytes of an address for this module.''')
	triple = property(GetTriple, None, doc='''A read only property that returns the target triple (arch-vendor-os) for this module.''')
	num_symbols = property(GetNumSymbols, None, doc='''A read only property that returns number of symbols in the module symbol table as an integer.''')
	num_sections = property(GetNumSections, None, doc='''A read only property that returns number of sections in the module as an integer.''')

	%}
	#endif

	};

	} // namespace lldb