#!/usr/bin/python #---------------------------------------------------------------------- # This module is designed to live inside the "lldb" python package # in the "lldb.macosx" package. To use this in the embedded python # interpreter using "lldb" just import it: # # (lldb) script import lldb.macosx.heap #---------------------------------------------------------------------- import lldb import commands import optparse import os import os.path import re import shlex import string import tempfile import lldb.utils.symbolication g_libheap_dylib_dir = None g_libheap_dylib_dict = dict() def get_iterate_memory_expr(options, process, user_init_code, user_return_code): expr = ''' typedef unsigned natural_t; typedef uintptr_t vm_size_t; typedef uintptr_t vm_address_t; typedef natural_t task_t; typedef int kern_return_t; #define KERN_SUCCESS 0 typedef void (*range_callback_t)(task_t task, void *baton, unsigned type, uintptr_t ptr_addr, uintptr_t ptr_size); '''; if options.search_vm_regions: expr += ''' typedef int vm_prot_t; typedef unsigned int vm_inherit_t; typedef unsigned long long memory_object_offset_t; typedef unsigned int boolean_t; typedef int vm_behavior_t; typedef uint32_t vm32_object_id_t; typedef natural_t mach_msg_type_number_t; typedef uint64_t mach_vm_address_t; typedef uint64_t mach_vm_offset_t; typedef uint64_t mach_vm_size_t; typedef uint64_t vm_map_offset_t; typedef uint64_t vm_map_address_t; typedef uint64_t vm_map_size_t; #define VM_PROT_NONE ((vm_prot_t) 0x00) #define VM_PROT_READ ((vm_prot_t) 0x01) #define VM_PROT_WRITE ((vm_prot_t) 0x02) #define VM_PROT_EXECUTE ((vm_prot_t) 0x04) typedef struct vm_region_submap_short_info_data_64_t { vm_prot_t protection; vm_prot_t max_protection; vm_inherit_t inheritance; memory_object_offset_t offset; // offset into object/map unsigned int user_tag; // user tag on map entry unsigned int ref_count; // obj/map mappers, etc unsigned short shadow_depth; // only for obj unsigned char external_pager; // only for obj unsigned char share_mode; // see enumeration boolean_t is_submap; // submap vs obj vm_behavior_t behavior; // access behavior hint vm32_object_id_t object_id; // obj/map name, not a handle unsigned short user_wired_count; } vm_region_submap_short_info_data_64_t; #define VM_REGION_SUBMAP_SHORT_INFO_COUNT_64 ((mach_msg_type_number_t)(sizeof(vm_region_submap_short_info_data_64_t)/sizeof(int)))'''; if user_init_code: expr += user_init_code; expr += ''' task_t task = (task_t)mach_task_self(); mach_vm_address_t vm_region_base_addr; mach_vm_size_t vm_region_size; natural_t vm_region_depth; vm_region_submap_short_info_data_64_t vm_region_info; kern_return_t err; for (vm_region_base_addr = 0, vm_region_size = 1; vm_region_size != 0; vm_region_base_addr += vm_region_size) { mach_msg_type_number_t vm_region_info_size = VM_REGION_SUBMAP_SHORT_INFO_COUNT_64; err = (kern_return_t)mach_vm_region_recurse (task, &vm_region_base_addr, &vm_region_size, &vm_region_depth, &vm_region_info, &vm_region_info_size); if (err) break; // Check all read + write regions. This will cover the thread stacks // and any regions of memory like __DATA segments, that might contain // data we are looking for if (vm_region_info.protection & VM_PROT_WRITE && vm_region_info.protection & VM_PROT_READ) { baton.callback (task, &baton, 64, vm_region_base_addr, vm_region_size); } }''' else: if options.search_stack: expr += get_thread_stack_ranges_struct (process) if options.search_segments: expr += get_sections_ranges_struct (process) if user_init_code: expr += user_init_code if options.search_heap: expr += ''' #define MALLOC_PTR_IN_USE_RANGE_TYPE 1 typedef struct vm_range_t { vm_address_t address; vm_size_t size; } vm_range_t; typedef kern_return_t (*memory_reader_t)(task_t task, vm_address_t remote_address, vm_size_t size, void **local_memory); typedef void (*vm_range_recorder_t)(task_t task, void *baton, unsigned type, vm_range_t *range, unsigned size); typedef struct malloc_introspection_t { kern_return_t (*enumerator)(task_t task, void *, unsigned type_mask, vm_address_t zone_address, memory_reader_t reader, vm_range_recorder_t recorder); /* enumerates all the malloc pointers in use */ } malloc_introspection_t; typedef struct malloc_zone_t { void *reserved1[12]; struct malloc_introspection_t *introspect; } malloc_zone_t; memory_reader_t task_peek = [](task_t task, vm_address_t remote_address, vm_size_t size, void **local_memory) -> kern_return_t { *local_memory = (void*) remote_address; return KERN_SUCCESS; }; vm_address_t *zones = 0; unsigned int num_zones = 0;task_t task = 0; kern_return_t err = (kern_return_t)malloc_get_all_zones (task, task_peek, &zones, &num_zones); if (KERN_SUCCESS == err) { for (unsigned int i=0; iintrospect) zone->introspect->enumerator (task, &baton, MALLOC_PTR_IN_USE_RANGE_TYPE, (vm_address_t)zone, task_peek, [] (task_t task, void *baton, unsigned type, vm_range_t *ranges, unsigned size) -> void { range_callback_t callback = ((callback_baton_t *)baton)->callback; for (unsigned i=0; i 0) { range_callback(task, &baton, 16, stacks[i].base - STACK_RED_ZONE_SIZE, STACK_RED_ZONE_SIZE); } } #endif''' if options.search_segments: expr += ''' #ifdef NUM_SEGMENTS // Call the callback for all segments for (uint32_t i=0; i= 0x1000: frames = symbolicator.symbolicate(pc) if frames: for frame in frames: result.AppendMessage(' [%u] %s' % (frame_idx, frame)) frame_idx += 1 else: result.AppendMessage(' [%u] 0x%x' % (frame_idx, pc)) frame_idx += 1 idx = idx + 1 pc = int(stack_history_entry.frames[idx]) else: pc = 0 if idx >= options.max_frames: result.AppendMessage('warning: the max number of stack frames (%u) was reached, use the "--max-frames=" option to see more frames' % (options.max_frames)) result.AppendMessage('') def dump_stack_history_entries(options, result, addr, history): # malloc_stack_entry *get_stack_history_for_address (const void * addr) single_expr = ''' typedef int kern_return_t; #define MAX_FRAMES %u typedef struct $malloc_stack_entry { uint64_t address; uint64_t argument; uint32_t type_flags; uint32_t num_frames; uint64_t frames[512]; kern_return_t err; } $malloc_stack_entry; typedef unsigned task_t; $malloc_stack_entry stack; stack.address = 0x%x; stack.type_flags = 2; stack.num_frames = 0; stack.frames[0] = 0; uint32_t max_stack_frames = MAX_FRAMES; stack.err = (kern_return_t)__mach_stack_logging_get_frames ( (task_t)mach_task_self(), stack.address, &stack.frames[0], max_stack_frames, &stack.num_frames); if (stack.num_frames < MAX_FRAMES) stack.frames[stack.num_frames] = 0; else stack.frames[MAX_FRAMES-1] = 0; stack''' % (options.max_frames, addr); history_expr = ''' typedef int kern_return_t; typedef unsigned task_t; #define MAX_FRAMES %u #define MAX_HISTORY %u typedef struct mach_stack_logging_record_t { uint32_t type_flags; uint64_t stack_identifier; uint64_t argument; uint64_t address; } mach_stack_logging_record_t; typedef void (*enumerate_callback_t)(mach_stack_logging_record_t, void *); typedef struct malloc_stack_entry { uint64_t address; uint64_t argument; uint32_t type_flags; uint32_t num_frames; uint64_t frames[MAX_FRAMES]; kern_return_t frames_err; } malloc_stack_entry; typedef struct $malloc_stack_history { task_t task; unsigned idx; malloc_stack_entry entries[MAX_HISTORY]; } $malloc_stack_history; $malloc_stack_history info = { (task_t)mach_task_self(), 0 }; uint32_t max_stack_frames = MAX_FRAMES; enumerate_callback_t callback = [] (mach_stack_logging_record_t stack_record, void *baton) -> void { $malloc_stack_history *info = ($malloc_stack_history *)baton; if (info->idx < MAX_HISTORY) { malloc_stack_entry *stack_entry = &(info->entries[info->idx]); stack_entry->address = stack_record.address; stack_entry->type_flags = stack_record.type_flags; stack_entry->argument = stack_record.argument; stack_entry->num_frames = 0; stack_entry->frames[0] = 0; stack_entry->frames_err = (kern_return_t)__mach_stack_logging_frames_for_uniqued_stack ( info->task, stack_record.stack_identifier, stack_entry->frames, (uint32_t)MAX_FRAMES, &stack_entry->num_frames); // Terminate the frames with zero if there is room if (stack_entry->num_frames < MAX_FRAMES) stack_entry->frames[stack_entry->num_frames] = 0; } ++info->idx; }; (kern_return_t)__mach_stack_logging_enumerate_records (info.task, (uint64_t)0x%x, callback, &info); info''' % (options.max_frames, options.max_history, addr); frame = lldb.debugger.GetSelectedTarget().GetProcess().GetSelectedThread().GetSelectedFrame() if history: expr = history_expr else: expr = single_expr expr_options = lldb.SBExpressionOptions() expr_options.SetIgnoreBreakpoints(True); expr_options.SetTimeoutInMicroSeconds (5*1000*1000) # 5 second timeout expr_options.SetTryAllThreads (True) expr_sbvalue = frame.EvaluateExpression (expr, expr_options) if options.verbose: print "expression:" print expr print "expression result:" print expr_sbvalue if expr_sbvalue.error.Success(): if history: malloc_stack_history = lldb.value(expr_sbvalue) num_stacks = int(malloc_stack_history.idx) if num_stacks <= options.max_history: i_max = num_stacks else: i_max = options.max_history for i in range(i_max): stack_history_entry = malloc_stack_history.entries[i] dump_stack_history_entry(options, result, stack_history_entry, i) if num_stacks > options.max_history: result.AppendMessage('warning: the max number of stacks (%u) was reached, use the "--max-history=%u" option to see all of the stacks' % (options.max_history, num_stacks)) else: stack_history_entry = lldb.value(expr_sbvalue) dump_stack_history_entry(options, result, stack_history_entry, 0) else: result.AppendMessage('error: expression failed "%s" => %s' % (expr, expr_sbvalue.error)) def display_match_results (result, options, arg_str_description, expr, print_no_matches = True): frame = lldb.debugger.GetSelectedTarget().GetProcess().GetSelectedThread().GetSelectedFrame() if not frame: result.AppendMessage('error: invalid frame') return 0 expr_options = lldb.SBExpressionOptions() expr_options.SetIgnoreBreakpoints(True); expr_options.SetFetchDynamicValue(lldb.eNoDynamicValues); expr_options.SetTimeoutInMicroSeconds (30*1000*1000) # 30 second timeout expr_options.SetTryAllThreads (False) expr_sbvalue = frame.EvaluateExpression (expr, expr_options) if options.verbose: print "expression:" print expr print "expression result:" print expr_sbvalue if expr_sbvalue.error.Success(): match_value = lldb.value(expr_sbvalue) i = 0 match_idx = 0 while 1: print_entry = True match_entry = match_value[i]; i += 1 if i > options.max_matches: result.AppendMessage('warning: the max number of matches (%u) was reached, use the --max-matches option to get more results' % (options.max_matches)) break malloc_addr = match_entry.addr.sbvalue.unsigned if malloc_addr == 0: break malloc_size = int(match_entry.size) offset = int(match_entry.offset) if options.offset >= 0 and options.offset != offset: print_entry = False else: match_addr = malloc_addr + offset type_flags = int(match_entry.type) #result.AppendMessage (hex(malloc_addr + offset)) if type_flags == 64: search_stack_old = options.search_stack search_segments_old = options.search_segments search_heap_old = options.search_heap search_vm_regions = options.search_vm_regions options.search_stack = True options.search_segments = True options.search_heap = True options.search_vm_regions = False if malloc_info_impl (lldb.debugger, result, options, [hex(malloc_addr + offset)]): print_entry = False options.search_stack = search_stack_old options.search_segments = search_segments_old options.search_heap = search_heap_old options.search_vm_regions = search_vm_regions if print_entry: description = '%#16.16x: %s' % (match_addr, type_flags_to_description(type_flags, malloc_addr, malloc_size, offset)) if options.show_size: description += ' <%5u>' % (malloc_size) if options.show_range: description += ' [%#x - %#x)' % (malloc_addr, malloc_addr + malloc_size) derefed_dynamic_value = None dynamic_value = match_entry.addr.sbvalue.GetDynamicValue(lldb.eDynamicCanRunTarget) if dynamic_value.type.name == 'void *': if options.type == 'pointer' and malloc_size == 4096: error = lldb.SBError() process = expr_sbvalue.GetProcess() target = expr_sbvalue.GetTarget() data = bytearray(process.ReadMemory(malloc_addr, 16, error)) if data == '\xa1\xa1\xa1\xa1AUTORELEASE!': ptr_size = target.addr_size thread = process.ReadUnsignedFromMemory (malloc_addr + 16 + ptr_size, ptr_size, error) # 4 bytes 0xa1a1a1a1 # 12 bytes 'AUTORELEASE!' # ptr bytes autorelease insertion point # ptr bytes pthread_t # ptr bytes next colder page # ptr bytes next hotter page # 4 bytes this page's depth in the list # 4 bytes high-water mark description += ' AUTORELEASE! for pthread_t %#x' % (thread) # else: # description += 'malloc(%u)' % (malloc_size) # else: # description += 'malloc(%u)' % (malloc_size) else: derefed_dynamic_value = dynamic_value.deref if derefed_dynamic_value: derefed_dynamic_type = derefed_dynamic_value.type derefed_dynamic_type_size = derefed_dynamic_type.size derefed_dynamic_type_name = derefed_dynamic_type.name description += ' ' description += derefed_dynamic_type_name if offset < derefed_dynamic_type_size: member_list = list(); get_member_types_for_offset (derefed_dynamic_type, offset, member_list) if member_list: member_path = '' for member in member_list: member_name = member.name if member_name: if member_path: member_path += '.' member_path += member_name if member_path: if options.ivar_regex_blacklist: for ivar_regex in options.ivar_regex_blacklist: if ivar_regex.match(member_path): print_entry = False description += '.%s' % (member_path) else: description += '%u bytes after %s' % (offset - derefed_dynamic_type_size, derefed_dynamic_type_name) else: # strip the "*" from the end of the name since we were unable to dereference this description += dynamic_value.type.name[0:-1] if print_entry: match_idx += 1 result_output = '' if description: result_output += description if options.print_type and derefed_dynamic_value: result_output += ' %s' % (derefed_dynamic_value) if options.print_object_description and dynamic_value: desc = dynamic_value.GetObjectDescription() if desc: result_output += '\n%s' % (desc) if result_output: result.AppendMessage(result_output) if options.memory: cmd_result = lldb.SBCommandReturnObject() if options.format == None: memory_command = "memory read --force 0x%x 0x%x" % (malloc_addr, malloc_addr + malloc_size) else: memory_command = "memory read --force -f %s 0x%x 0x%x" % (options.format, malloc_addr, malloc_addr + malloc_size) if options.verbose: result.AppendMessage(memory_command) lldb.debugger.GetCommandInterpreter().HandleCommand(memory_command, cmd_result) result.AppendMessage(cmd_result.GetOutput()) if options.stack_history: dump_stack_history_entries(options, result, malloc_addr, 1) elif options.stack: dump_stack_history_entries(options, result, malloc_addr, 0) return i else: result.AppendMessage(str(expr_sbvalue.error)) return 0 def get_ptr_refs_options (): usage = "usage: %prog [options] [EXPR ...]" description='''Searches all allocations on the heap for pointer values on darwin user space programs. Any matches that were found will dump the malloc blocks that contain the pointers and might be able to print what kind of objects the pointers are contained in using dynamic type information in the program.''' parser = optparse.OptionParser(description=description, prog='ptr_refs',usage=usage) add_common_options(parser) return parser def ptr_refs(debugger, command, result, dict): command_args = shlex.split(command) parser = get_ptr_refs_options() try: (options, args) = parser.parse_args(command_args) except: return process = lldb.debugger.GetSelectedTarget().GetProcess() if not process: result.AppendMessage('error: invalid process') return frame = process.GetSelectedThread().GetSelectedFrame() if not frame: result.AppendMessage('error: invalid frame') return options.type = 'pointer' if options.format == None: options.format = "A" # 'A' is "address" format if args: # When we initialize the expression, we must define any types that # we will need when looking at every allocation. We must also define # a type named callback_baton_t and make an instance named "baton" # and initialize it how ever we want to. The address of "baton" will # be passed into our range callback. callback_baton_t must contain # a member named "callback" whose type is "range_callback_t". This # will be used by our zone callbacks to call the range callback for # each malloc range. user_init_code_format = ''' #define MAX_MATCHES %u struct $malloc_match { void *addr; uintptr_t size; uintptr_t offset; uintptr_t type; }; typedef struct callback_baton_t { range_callback_t callback; unsigned num_matches; $malloc_match matches[MAX_MATCHES]; void *ptr; } callback_baton_t; range_callback_t range_callback = [](task_t task, void *baton, unsigned type, uintptr_t ptr_addr, uintptr_t ptr_size) -> void { callback_baton_t *info = (callback_baton_t *)baton; typedef void* T; const unsigned size = sizeof(T); T *array = (T*)ptr_addr; for (unsigned idx = 0; ((idx + 1) * sizeof(T)) <= ptr_size; ++idx) { if (array[idx] == info->ptr) { if (info->num_matches < MAX_MATCHES) { info->matches[info->num_matches].addr = (void*)ptr_addr; info->matches[info->num_matches].size = ptr_size; info->matches[info->num_matches].offset = idx*sizeof(T); info->matches[info->num_matches].type = type; ++info->num_matches; } } } }; callback_baton_t baton = { range_callback, 0, {0}, (void *)%s }; ''' # We must also define a snippet of code to be run that returns # the result of the expression we run. # Here we return NULL if our pointer was not found in any malloc blocks, # and we return the address of the matches array so we can then access # the matching results user_return_code = '''if (baton.num_matches < MAX_MATCHES) baton.matches[baton.num_matches].addr = 0; // Terminate the matches array baton.matches''' # Iterate through all of our pointer expressions and display the results for ptr_expr in args: user_init_code = user_init_code_format % (options.max_matches, ptr_expr) expr = get_iterate_memory_expr(options, process, user_init_code, user_return_code) arg_str_description = 'malloc block containing pointer %s' % ptr_expr display_match_results (result, options, arg_str_description, expr) else: result.AppendMessage('error: no pointer arguments were given') def get_cstr_refs_options(): usage = "usage: %prog [options] [CSTR ...]" description='''Searches all allocations on the heap for C string values on darwin user space programs. Any matches that were found will dump the malloc blocks that contain the C strings and might be able to print what kind of objects the pointers are contained in using dynamic type information in the program.''' parser = optparse.OptionParser(description=description, prog='cstr_refs',usage=usage) add_common_options(parser) return parser def cstr_refs(debugger, command, result, dict): command_args = shlex.split(command) parser = get_cstr_refs_options(); try: (options, args) = parser.parse_args(command_args) except: return process = lldb.debugger.GetSelectedTarget().GetProcess() if not process: result.AppendMessage('error: invalid process') return frame = process.GetSelectedThread().GetSelectedFrame() if not frame: result.AppendMessage('error: invalid frame') return options.type = 'cstr' if options.format == None: options.format = "Y" # 'Y' is "bytes with ASCII" format if args: # When we initialize the expression, we must define any types that # we will need when looking at every allocation. We must also define # a type named callback_baton_t and make an instance named "baton" # and initialize it how ever we want to. The address of "baton" will # be passed into our range callback. callback_baton_t must contain # a member named "callback" whose type is "range_callback_t". This # will be used by our zone callbacks to call the range callback for # each malloc range. user_init_code_format = ''' #define MAX_MATCHES %u struct $malloc_match { void *addr; uintptr_t size; uintptr_t offset; uintptr_t type; }; typedef struct callback_baton_t { range_callback_t callback; unsigned num_matches; $malloc_match matches[MAX_MATCHES]; const char *cstr; unsigned cstr_len; } callback_baton_t; range_callback_t range_callback = [](task_t task, void *baton, unsigned type, uintptr_t ptr_addr, uintptr_t ptr_size) -> void { callback_baton_t *info = (callback_baton_t *)baton; if (info->cstr_len < ptr_size) { const char *begin = (const char *)ptr_addr; const char *end = begin + ptr_size - info->cstr_len; for (const char *s = begin; s < end; ++s) { if ((int)memcmp(s, info->cstr, info->cstr_len) == 0) { if (info->num_matches < MAX_MATCHES) { info->matches[info->num_matches].addr = (void*)ptr_addr; info->matches[info->num_matches].size = ptr_size; info->matches[info->num_matches].offset = s - begin; info->matches[info->num_matches].type = type; ++info->num_matches; } } } } }; const char *cstr = "%s"; callback_baton_t baton = { range_callback, 0, {0}, cstr, (unsigned)strlen(cstr) };''' # We must also define a snippet of code to be run that returns # the result of the expression we run. # Here we return NULL if our pointer was not found in any malloc blocks, # and we return the address of the matches array so we can then access # the matching results user_return_code = '''if (baton.num_matches < MAX_MATCHES) baton.matches[baton.num_matches].addr = 0; // Terminate the matches array baton.matches''' # Iterate through all of our pointer expressions and display the results for cstr in args: user_init_code = user_init_code_format % (options.max_matches, cstr) expr = get_iterate_memory_expr(options, process, user_init_code, user_return_code) arg_str_description = 'malloc block containing "%s"' % cstr display_match_results (result, options, arg_str_description, expr) else: result.AppendMessage('error: command takes one or more C string arguments') def get_malloc_info_options(): usage = "usage: %prog [options] [EXPR ...]" description='''Searches the heap a malloc block that contains the addresses specified as one or more address expressions. Any matches that were found will dump the malloc blocks that match or contain the specified address. The matching blocks might be able to show what kind of objects they are using dynamic type information in the program.''' parser = optparse.OptionParser(description=description, prog='malloc_info',usage=usage) add_common_options(parser) return parser def malloc_info(debugger, command, result, dict): command_args = shlex.split(command) parser = get_malloc_info_options() try: (options, args) = parser.parse_args(command_args) except: return malloc_info_impl (debugger, result, options, args) def malloc_info_impl (debugger, result, options, args): # We are specifically looking for something on the heap only options.type = 'malloc_info' process = lldb.debugger.GetSelectedTarget().GetProcess() if not process: result.AppendMessage('error: invalid process') return frame = process.GetSelectedThread().GetSelectedFrame() if not frame: result.AppendMessage('error: invalid frame') return user_init_code_format = ''' struct $malloc_match { void *addr; uintptr_t size; uintptr_t offset; uintptr_t type; }; typedef struct callback_baton_t { range_callback_t callback; unsigned num_matches; $malloc_match matches[2]; // Two items so they can be NULL terminated void *ptr; } callback_baton_t; range_callback_t range_callback = [](task_t task, void *baton, unsigned type, uintptr_t ptr_addr, uintptr_t ptr_size) -> void { callback_baton_t *info = (callback_baton_t *)baton; if (info->num_matches == 0) { uint8_t *p = (uint8_t *)info->ptr; uint8_t *lo = (uint8_t *)ptr_addr; uint8_t *hi = lo + ptr_size; if (lo <= p && p < hi) { info->matches[info->num_matches].addr = (void*)ptr_addr; info->matches[info->num_matches].size = ptr_size; info->matches[info->num_matches].offset = p - lo; info->matches[info->num_matches].type = type; info->num_matches = 1; } } }; callback_baton_t baton = { range_callback, 0, {0}, (void *)%s }; baton.matches[0].addr = 0; baton.matches[1].addr = 0;''' if args: total_matches = 0 for ptr_expr in args: user_init_code = user_init_code_format % (ptr_expr) expr = get_iterate_memory_expr(options, process, user_init_code, 'baton.matches') arg_str_description = 'malloc block that contains %s' % ptr_expr total_matches += display_match_results (result, options, arg_str_description, expr) return total_matches else: result.AppendMessage('error: command takes one or more pointer expressions') return 0 def get_thread_stack_ranges_struct (process): '''Create code that defines a structure that represents threads stack bounds for all threads. It returns a static sized array initialized with all of the tid, base, size structs for all the threads.''' stack_dicts = list() if process: i = 0; for thread in process: min_sp = thread.frame[0].sp max_sp = min_sp for frame in thread.frames: sp = frame.sp if sp < min_sp: min_sp = sp if sp > max_sp: max_sp = sp if min_sp < max_sp: stack_dicts.append ({ 'tid' : thread.GetThreadID(), 'base' : min_sp , 'size' : max_sp-min_sp, 'index' : i }) i += 1 stack_dicts_len = len(stack_dicts) if stack_dicts_len > 0: result = ''' #define NUM_STACKS %u #define STACK_RED_ZONE_SIZE %u typedef struct thread_stack_t { uint64_t tid, base, size; } thread_stack_t; thread_stack_t stacks[NUM_STACKS];''' % (stack_dicts_len, process.target.GetStackRedZoneSize()) for stack_dict in stack_dicts: result += ''' stacks[%(index)u].tid = 0x%(tid)x; stacks[%(index)u].base = 0x%(base)x; stacks[%(index)u].size = 0x%(size)x;''' % stack_dict return result else: return '' def get_sections_ranges_struct (process): '''Create code that defines a structure that represents all segments that can contain data for all images in "target". It returns a static sized array initialized with all of base, size structs for all the threads.''' target = process.target segment_dicts = list() for (module_idx, module) in enumerate(target.modules): for sect_idx in range(module.GetNumSections()): section = module.GetSectionAtIndex(sect_idx) if not section: break name = section.name if name != '__TEXT' and name != '__LINKEDIT' and name != '__PAGEZERO': base = section.GetLoadAddress(target) size = section.GetByteSize() if base != lldb.LLDB_INVALID_ADDRESS and size > 0: segment_dicts.append ({ 'base' : base, 'size' : size }) segment_dicts_len = len(segment_dicts) if segment_dicts_len > 0: result = ''' #define NUM_SEGMENTS %u typedef struct segment_range_t { uint64_t base; uint32_t size; } segment_range_t; segment_range_t segments[NUM_SEGMENTS];''' % (segment_dicts_len,) for (idx, segment_dict) in enumerate(segment_dicts): segment_dict['index'] = idx result += ''' segments[%(index)u].base = 0x%(base)x; segments[%(index)u].size = 0x%(size)x;''' % segment_dict return result else: return '' def section_ptr_refs(debugger, command, result, dict): command_args = shlex.split(command) usage = "usage: %prog [options] [EXPR ...]" description='''Searches section contents for pointer values in darwin user space programs.''' parser = optparse.OptionParser(description=description, prog='section_ptr_refs',usage=usage) add_common_options(parser) parser.add_option('--section', action='append', type='string', dest='section_names', help='section name to search', default=list()) try: (options, args) = parser.parse_args(command_args) except: return options.type = 'pointer' sections = list() section_modules = list() if not options.section_names: result.AppendMessage('error: at least one section must be specified with the --section option') return target = lldb.debugger.GetSelectedTarget() for module in target.modules: for section_name in options.section_names: section = module.section[section_name] if section: sections.append (section) section_modules.append (module) if sections: dylid_load_err = load_dylib() if dylid_load_err: result.AppendMessage(dylid_load_err) return frame = target.GetProcess().GetSelectedThread().GetSelectedFrame() for expr_str in args: for (idx, section) in enumerate(sections): expr = 'find_pointer_in_memory(0x%xllu, %ullu, (void *)%s)' % (section.addr.load_addr, section.size, expr_str) arg_str_description = 'section %s.%s containing "%s"' % (section_modules[idx].file.fullpath, section.name, expr_str) num_matches = display_match_results (result, options, arg_str_description, expr, False) if num_matches: if num_matches < options.max_matches: options.max_matches = options.max_matches - num_matches else: options.max_matches = 0 if options.max_matches == 0: return else: result.AppendMessage('error: no sections were found that match any of %s' % (', '.join(options.section_names))) def get_objc_refs_options(): usage = "usage: %prog [options] [CLASS ...]" description='''Searches all allocations on the heap for instances of objective C classes, or any classes that inherit from the specified classes in darwin user space programs. Any matches that were found will dump the malloc blocks that contain the C strings and might be able to print what kind of objects the pointers are contained in using dynamic type information in the program.''' parser = optparse.OptionParser(description=description, prog='objc_refs',usage=usage) add_common_options(parser) return parser def objc_refs(debugger, command, result, dict): command_args = shlex.split(command) parser = get_objc_refs_options() try: (options, args) = parser.parse_args(command_args) except: return process = lldb.debugger.GetSelectedTarget().GetProcess() if not process: result.AppendMessage('error: invalid process') return frame = process.GetSelectedThread().GetSelectedFrame() if not frame: result.AppendMessage('error: invalid frame') return options.type = 'isa' if options.format == None: options.format = "A" # 'A' is "address" format expr_options = lldb.SBExpressionOptions() expr_options.SetIgnoreBreakpoints(True); expr_options.SetTimeoutInMicroSeconds (3*1000*1000) # 3 second infinite timeout expr_options.SetTryAllThreads (True) num_objc_classes_value = frame.EvaluateExpression("(int)objc_getClassList((void *)0, (int)0)", expr_options) if not num_objc_classes_value.error.Success(): result.AppendMessage('error: %s' % num_objc_classes_value.error.GetCString()) return num_objc_classes = num_objc_classes_value.GetValueAsUnsigned() if num_objc_classes == 0: result.AppendMessage('error: no objective C classes in program') return if args: # When we initialize the expression, we must define any types that # we will need when looking at every allocation. We must also define # a type named callback_baton_t and make an instance named "baton" # and initialize it how ever we want to. The address of "baton" will # be passed into our range callback. callback_baton_t must contain # a member named "callback" whose type is "range_callback_t". This # will be used by our zone callbacks to call the range callback for # each malloc range. user_init_code_format = ''' #define MAX_MATCHES %u struct $malloc_match { void *addr; uintptr_t size; uintptr_t offset; uintptr_t type; }; typedef int (*compare_callback_t)(const void *a, const void *b); typedef struct callback_baton_t { range_callback_t callback; compare_callback_t compare_callback; unsigned num_matches; $malloc_match matches[MAX_MATCHES]; void *isa; Class classes[%u]; } callback_baton_t; compare_callback_t compare_callback = [](const void *a, const void *b) -> int { Class a_ptr = *(Class *)a; Class b_ptr = *(Class *)b; if (a_ptr < b_ptr) return -1; if (a_ptr > b_ptr) return +1; return 0; }; typedef Class (*class_getSuperclass_type)(void *isa); range_callback_t range_callback = [](task_t task, void *baton, unsigned type, uintptr_t ptr_addr, uintptr_t ptr_size) -> void { class_getSuperclass_type class_getSuperclass_impl = (class_getSuperclass_type)class_getSuperclass; callback_baton_t *info = (callback_baton_t *)baton; if (sizeof(Class) <= ptr_size) { Class *curr_class_ptr = (Class *)ptr_addr; Class *matching_class_ptr = (Class *)bsearch (curr_class_ptr, (const void *)info->classes, sizeof(info->classes)/sizeof(Class), sizeof(Class), info->compare_callback); if (matching_class_ptr) { bool match = false; if (info->isa) { Class isa = *curr_class_ptr; if (info->isa == isa) match = true; else { // if (info->objc.match_superclasses) { Class super = class_getSuperclass_impl(isa); while (super) { if (super == info->isa) { match = true; break; } super = class_getSuperclass_impl(super); } } } else match = true; if (match) { if (info->num_matches < MAX_MATCHES) { info->matches[info->num_matches].addr = (void*)ptr_addr; info->matches[info->num_matches].size = ptr_size; info->matches[info->num_matches].offset = 0; info->matches[info->num_matches].type = type; ++info->num_matches; } } } } }; callback_baton_t baton = { range_callback, compare_callback, 0, {0}, (void *)0x%x, {0} }; int nc = (int)objc_getClassList(baton.classes, sizeof(baton.classes)/sizeof(Class)); (void)qsort (baton.classes, sizeof(baton.classes)/sizeof(Class), sizeof(Class), compare_callback);''' # We must also define a snippet of code to be run that returns # the result of the expression we run. # Here we return NULL if our pointer was not found in any malloc blocks, # and we return the address of the matches array so we can then access # the matching results user_return_code = '''if (baton.num_matches < MAX_MATCHES) baton.matches[baton.num_matches].addr = 0; // Terminate the matches array baton.matches''' # Iterate through all of our ObjC class name arguments for class_name in args: addr_expr_str = "(void *)[%s class]" % class_name expr_options = lldb.SBExpressionOptions() expr_options.SetIgnoreBreakpoints(True); expr_options.SetTimeoutInMicroSeconds (1*1000*1000) # 1 second timeout expr_options.SetTryAllThreads (True) expr_sbvalue = frame.EvaluateExpression (addr_expr_str, expr_options) if expr_sbvalue.error.Success(): isa = expr_sbvalue.unsigned if isa: options.type = 'isa' result.AppendMessage('Searching for all instances of classes or subclasses of "%s" (isa=0x%x)' % (class_name, isa)) user_init_code = user_init_code_format % (options.max_matches, num_objc_classes, isa) expr = get_iterate_memory_expr(options, process, user_init_code, user_return_code) arg_str_description = 'objective C classes with isa 0x%x' % isa display_match_results (result, options, arg_str_description, expr) else: result.AppendMessage('error: Can\'t find isa for an ObjC class named "%s"' % (class_name)) else: result.AppendMessage('error: expression error for "%s": %s' % (addr_expr_str, expr_sbvalue.error)) else: result.AppendMessage('error: command takes one or more C string arguments'); if __name__ == '__main__': lldb.debugger = lldb.SBDebugger.Create() # Make the options so we can generate the help text for the new LLDB # command line command prior to registering it with LLDB below. This way # if clients in LLDB type "help malloc_info", they will see the exact same # output as typing "malloc_info --help". ptr_refs.__doc__ = get_ptr_refs_options().format_help() cstr_refs.__doc__ = get_cstr_refs_options().format_help() malloc_info.__doc__ = get_malloc_info_options().format_help() objc_refs.__doc__ = get_objc_refs_options().format_help() lldb.debugger.HandleCommand('command script add -f %s.ptr_refs ptr_refs' % __name__) lldb.debugger.HandleCommand('command script add -f %s.cstr_refs cstr_refs' % __name__) lldb.debugger.HandleCommand('command script add -f %s.malloc_info malloc_info' % __name__) # lldb.debugger.HandleCommand('command script add -f %s.heap heap' % package_name) # lldb.debugger.HandleCommand('command script add -f %s.section_ptr_refs section_ptr_refs' % package_name) # lldb.debugger.HandleCommand('command script add -f %s.stack_ptr_refs stack_ptr_refs' % package_name) lldb.debugger.HandleCommand('command script add -f %s.objc_refs objc_refs' % __name__) print '"malloc_info", "ptr_refs", "cstr_refs", and "objc_refs" commands have been installed, use the "--help" options on these commands for detailed help.'