648 lines
22 KiB
Python
Executable File
648 lines
22 KiB
Python
Executable File
#!/usr/bin/env python3
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#
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# Copyright (c) 2016, 2020 Intel Corporation
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#
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# SPDX-License-Identifier: Apache-2.0
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# Based on a script by:
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# Chereau, Fabien <fabien.chereau@intel.com>
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import argparse
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import os
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import sys
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import re
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from pathlib import Path
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import json
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from distutils.version import LooseVersion
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import elftools
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from elftools.elf.elffile import ELFFile
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from elftools.elf.sections import SymbolTableSection
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from elftools.dwarf.descriptions import describe_form_class
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from elftools.dwarf.descriptions import (
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describe_DWARF_expr, set_global_machine_arch)
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from elftools.dwarf.locationlists import (
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LocationExpr, LocationParser)
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if LooseVersion(elftools.__version__) < LooseVersion('0.24'):
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sys.exit("pyelftools is out of date, need version 0.24 or later")
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from colorama import init, Fore
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from anytree import RenderTree, NodeMixin, findall_by_attr
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from anytree.exporter import DictExporter
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# ELF section flags
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SHF_WRITE = 0x1
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SHF_ALLOC = 0x2
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SHF_EXEC = 0x4
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SHF_WRITE_ALLOC = SHF_WRITE | SHF_ALLOC
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SHF_ALLOC_EXEC = SHF_ALLOC | SHF_EXEC
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DT_LOCATION = re.compile(r"\(DW_OP_addr: ([0-9a-f]+)\)")
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def get_symbol_addr(sym):
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return sym['st_value']
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def get_symbol_size(sym):
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return sym['st_size']
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# Given a list of start/end addresses, test if the symbol
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# lies within any of these address ranges
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def is_symbol_in_ranges(sym, ranges):
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for bound in ranges:
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if bound['start'] <= sym['st_value'] <= bound['end']:
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return True
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return False
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# Get the bounding addresses from a DIE variable or subprogram
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def get_die_mapped_address(die, parser, dwarfinfo):
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low = None
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high = None
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if die.tag == 'DW_TAG_variable':
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if 'DW_AT_location' in die.attributes:
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loc_attr = die.attributes['DW_AT_location']
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if parser.attribute_has_location(loc_attr, die.cu['version']):
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loc = parser.parse_from_attribute(loc_attr, die.cu['version'])
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if isinstance(loc, LocationExpr):
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addr = describe_DWARF_expr(loc.loc_expr,
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dwarfinfo.structs)
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matcher = DT_LOCATION.match(addr)
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if matcher:
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low = int(matcher.group(1), 16)
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high = low + 1
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if die.tag == 'DW_TAG_subprogram':
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if 'DW_AT_low_pc' in die.attributes:
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low = die.attributes['DW_AT_low_pc'].value
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high_pc = die.attributes['DW_AT_high_pc']
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high_pc_class = describe_form_class(high_pc.form)
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if high_pc_class == 'address':
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high = high_pc.value
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elif high_pc_class == 'constant':
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high = low + high_pc.value
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return low, high
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# Find the symbol from a symbol list
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# where it matches the address in DIE variable,
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# or within the range of a DIE subprogram
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def match_symbol_address(symlist, die, parser, dwarfinfo):
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low, high = get_die_mapped_address(die, parser, dwarfinfo)
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if low is None:
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return None
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for sym in symlist:
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if low <= sym['symbol']['st_value'] < high:
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return sym
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return None
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# Fetch the symbols from the symbol table and put them
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# into ROM, RAM buckets
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def get_symbols(elf, addr_ranges):
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rom_syms = dict()
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ram_syms = dict()
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unassigned_syms = dict()
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rom_addr_ranges = addr_ranges['rom']
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ram_addr_ranges = addr_ranges['ram']
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for section in elf.iter_sections():
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if isinstance(section, SymbolTableSection):
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for sym in section.iter_symbols():
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# Ignore symbols with size == 0
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if get_symbol_size(sym) == 0:
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continue
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found_sec = False
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entry = {'name': sym.name,
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'symbol': sym,
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'mapped_files': set()}
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# If symbol is in ROM area?
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if is_symbol_in_ranges(sym, rom_addr_ranges):
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if sym.name not in rom_syms:
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rom_syms[sym.name] = list()
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rom_syms[sym.name].append(entry)
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found_sec = True
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# If symbol is in RAM area?
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if is_symbol_in_ranges(sym, ram_addr_ranges):
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if sym.name not in ram_syms:
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ram_syms[sym.name] = list()
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ram_syms[sym.name].append(entry)
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found_sec = True
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if not found_sec:
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unassigned_syms['sym_name'] = entry
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ret = {'rom': rom_syms,
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'ram': ram_syms,
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'unassigned': unassigned_syms}
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return ret
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# Parse ELF header to find out the address ranges of ROM or RAM sections
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# and their total sizes
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def get_section_ranges(elf):
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rom_addr_ranges = list()
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ram_addr_ranges = list()
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rom_size = 0
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ram_size = 0
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for section in elf.iter_sections():
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size = section['sh_size']
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sec_start = section['sh_addr']
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sec_end = sec_start + size - 1
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bound = {'start': sec_start, 'end': sec_end}
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if section['sh_type'] == 'SHT_NOBITS':
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# BSS and noinit sections
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ram_addr_ranges.append(bound)
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ram_size += size
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elif section['sh_type'] == 'SHT_PROGBITS':
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# Sections to be in flash or memory
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flags = section['sh_flags']
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if (flags & SHF_ALLOC_EXEC) == SHF_ALLOC_EXEC:
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# Text section
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rom_addr_ranges.append(bound)
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rom_size += size
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elif (flags & SHF_WRITE_ALLOC) == SHF_WRITE_ALLOC:
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# Data occupies both ROM and RAM
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# since at boot, content is copied from ROM to RAM
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rom_addr_ranges.append(bound)
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rom_size += size
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ram_addr_ranges.append(bound)
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ram_size += size
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elif (flags & SHF_ALLOC) == SHF_ALLOC:
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# Read only data
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rom_addr_ranges.append(bound)
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rom_size += size
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ret = {'rom': rom_addr_ranges,
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'rom_total_size': rom_size,
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'ram': ram_addr_ranges,
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'ram_total_size': ram_size}
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return ret
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def get_die_filename(die, lineprog):
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zephyrbase = os.path.normpath(args.zephyrbase)
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file_index = die.attributes['DW_AT_decl_file'].value
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file_entry = lineprog['file_entry'][file_index - 1]
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dir_index = file_entry['dir_index']
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if dir_index == 0:
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filename = file_entry.name
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else:
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directory = lineprog.header['include_directory'][dir_index - 1]
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filename = os.path.join(directory, file_entry.name)
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path = Path(filename.decode())
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# Prepend output path to relative path
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if not path.is_absolute():
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output = Path(args.output)
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path = output.joinpath(path)
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# Change path to relative to Zephyr base
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try:
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path = path.resolve()
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except OSError as e:
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if '<built-in>' in str(path):
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# This is expected, built-ins can't be resolved
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return path
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raise e
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try:
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new_path = path.relative_to(zephyrbase)
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path = new_path
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except ValueError:
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pass
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return path
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# Sequentially process DIEs in compiler units with direct file mappings
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# within the DIEs themselves, and do simply matching between DIE names
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# and symbol names.
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def do_simple_name_matching(elf, symbol_dict, processed):
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mapped_symbols = processed['mapped_symbols']
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mapped_addresses = processed['mapped_addr']
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unmapped_symbols = processed['unmapped_symbols']
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newly_mapped_syms = set()
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dwarfinfo = elf.get_dwarf_info()
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location_lists = dwarfinfo.location_lists()
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location_parser = LocationParser(location_lists)
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unmapped_dies = set()
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# Loop through all compile units
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for compile_unit in dwarfinfo.iter_CUs():
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lineprog = dwarfinfo.line_program_for_CU(compile_unit)
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if lineprog is None:
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continue
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# Loop through each DIE and find variables and
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# subprograms (i.e. functions)
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for die in compile_unit.iter_DIEs():
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sym_name = None
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# Process variables
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if die.tag == 'DW_TAG_variable':
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# DW_AT_declaration
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# having 'DW_AT_location' means this maps
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# to an actual address (e.g. not an extern)
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if 'DW_AT_location' in die.attributes:
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sym_name = die.get_full_path()
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# Process subprograms (i.e. functions) if they are valid
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if die.tag == 'DW_TAG_subprogram':
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# Refer to another DIE for name
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if ('DW_AT_abstract_origin' in die.attributes) or (
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'DW_AT_specification' in die.attributes):
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unmapped_dies.add(die)
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# having 'DW_AT_low_pc' means it maps to
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# an actual address
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elif 'DW_AT_low_pc' in die.attributes:
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# DW_AT_low_pc == 0 is a weak function
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# which has been overriden
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if die.attributes['DW_AT_low_pc'].value != 0:
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sym_name = die.get_full_path()
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# For mangled function names, the linkage name
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# is what appears in the symbol list
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if 'DW_AT_linkage_name' in die.attributes:
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linkage = die.attributes['DW_AT_linkage_name']
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sym_name = linkage.value.decode()
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if sym_name is not None:
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# Skip DIE with no reference back to a file
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if not 'DW_AT_decl_file' in die.attributes:
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continue
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is_die_mapped = False
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if sym_name in symbol_dict:
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mapped_symbols.add(sym_name)
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symlist = symbol_dict[sym_name]
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symbol = match_symbol_address(symlist, die,
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location_parser,
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dwarfinfo)
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if symbol is not None:
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symaddr = symbol['symbol']['st_value']
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if symaddr not in mapped_addresses:
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is_die_mapped = True
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path = get_die_filename(die, lineprog)
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symbol['mapped_files'].add(path)
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mapped_addresses.add(symaddr)
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newly_mapped_syms.add(sym_name)
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if not is_die_mapped:
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unmapped_dies.add(die)
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mapped_symbols = mapped_symbols.union(newly_mapped_syms)
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unmapped_symbols = unmapped_symbols.difference(newly_mapped_syms)
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processed['mapped_symbols'] = mapped_symbols
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processed['mapped_addr'] = mapped_addresses
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processed['unmapped_symbols'] = unmapped_symbols
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processed['unmapped_dies'] = unmapped_dies
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# There are functions and variables which are aliases to
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# other functions/variables. So this marks them as mapped
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# so they will not get counted again when a tree is being
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# built for display.
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def mark_address_aliases(symbol_dict, processed):
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mapped_symbols = processed['mapped_symbols']
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mapped_addresses = processed['mapped_addr']
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unmapped_symbols = processed['unmapped_symbols']
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already_mapped_syms = set()
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for ums in unmapped_symbols:
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for one_sym in symbol_dict[ums]:
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symbol = one_sym['symbol']
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if symbol['st_value'] in mapped_addresses:
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already_mapped_syms.add(ums)
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mapped_symbols = mapped_symbols.union(already_mapped_syms)
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unmapped_symbols = unmapped_symbols.difference(already_mapped_syms)
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processed['mapped_symbols'] = mapped_symbols
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processed['mapped_addr'] = mapped_addresses
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processed['unmapped_symbols'] = unmapped_symbols
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# This uses the address ranges of DIEs and map them to symbols
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# residing within those ranges, and works on DIEs that have not
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# been mapped in previous steps. This works on symbol names
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# that do not match the names in DIEs, e.g. "<func>" in DIE,
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# but "<func>.constprop.*" in symbol name list. This also
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# helps with mapping the mangled function names in C++,
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# since the names in DIE are actual function names in source
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# code and not mangled version of them.
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def do_address_range_matching(elf, symbol_dict, processed):
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if 'unmapped_dies' not in processed:
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return
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mapped_symbols = processed['mapped_symbols']
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mapped_addresses = processed['mapped_addr']
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unmapped_symbols = processed['unmapped_symbols']
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newly_mapped_syms = set()
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dwarfinfo = elf.get_dwarf_info()
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location_lists = dwarfinfo.location_lists()
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location_parser = LocationParser(location_lists)
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unmapped_dies = processed['unmapped_dies']
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# Group DIEs by compile units
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cu_list = dict()
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for die in unmapped_dies:
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cu = die.cu
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if cu not in cu_list:
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cu_list[cu] = {'dies': set()}
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cu_list[cu]['dies'].add(die)
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# Loop through all compile units
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for cu in cu_list:
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lineprog = dwarfinfo.line_program_for_CU(cu)
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# Map offsets from DIEs
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offset_map = dict()
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for die in cu.iter_DIEs():
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offset_map[die.offset] = die
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for die in cu_list[cu]['dies']:
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if not die.tag == 'DW_TAG_subprogram':
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continue
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path = None
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# Has direct reference to file, so use it
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if 'DW_AT_decl_file' in die.attributes:
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path = get_die_filename(die, lineprog)
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# Loop through indirect reference until a direct
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# reference to file is found
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if ('DW_AT_abstract_origin' in die.attributes) or (
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'DW_AT_specification' in die.attributes):
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die_ptr = die
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while path is None:
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if not (die_ptr.tag == 'DW_TAG_subprogram') or not (
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('DW_AT_abstract_origin' in die_ptr.attributes) or
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('DW_AT_specification' in die_ptr.attributes)):
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break
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if 'DW_AT_abstract_origin' in die_ptr.attributes:
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ofname = 'DW_AT_abstract_origin'
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elif 'DW_AT_specification' in die_ptr.attributes:
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ofname = 'DW_AT_specification'
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offset = die_ptr.attributes[ofname].value
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offset += die_ptr.cu.cu_offset
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# There is nothing to reference so no need to continue
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if offset not in offset_map:
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break
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die_ptr = offset_map[offset]
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if 'DW_AT_decl_file' in die_ptr.attributes:
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path = get_die_filename(die_ptr, lineprog)
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# Nothing to map
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if path is not None:
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low, high = get_die_mapped_address(die, location_parser,
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dwarfinfo)
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if low is None:
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continue
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for ums in unmapped_symbols:
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for one_sym in symbol_dict[ums]:
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symbol = one_sym['symbol']
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symaddr = symbol['st_value']
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if symaddr not in mapped_addresses:
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if low <= symaddr < high:
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one_sym['mapped_files'].add(path)
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mapped_addresses.add(symaddr)
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newly_mapped_syms.add(ums)
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mapped_symbols = mapped_symbols.union(newly_mapped_syms)
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unmapped_symbols = unmapped_symbols.difference(newly_mapped_syms)
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processed['mapped_symbols'] = mapped_symbols
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processed['mapped_addr'] = mapped_addresses
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processed['unmapped_symbols'] = unmapped_symbols
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# Any unmapped symbols are added under the root node if those
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# symbols reside within the desired memory address ranges
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# (e.g. ROM or RAM).
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def set_root_path_for_unmapped_symbols(symbol_dict, addr_range, processed):
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mapped_symbols = processed['mapped_symbols']
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mapped_addresses = processed['mapped_addr']
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unmapped_symbols = processed['unmapped_symbols']
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newly_mapped_syms = set()
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for ums in unmapped_symbols:
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for one_sym in symbol_dict[ums]:
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symbol = one_sym['symbol']
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symaddr = symbol['st_value']
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if is_symbol_in_ranges(symbol, addr_range):
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if symaddr not in mapped_addresses:
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path = Path(':')
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one_sym['mapped_files'].add(path)
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mapped_addresses.add(symaddr)
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newly_mapped_syms.add(ums)
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mapped_symbols = mapped_symbols.union(newly_mapped_syms)
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unmapped_symbols = unmapped_symbols.difference(newly_mapped_syms)
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processed['mapped_symbols'] = mapped_symbols
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processed['mapped_addr'] = mapped_addresses
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processed['unmapped_symbols'] = unmapped_symbols
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class TreeNode(NodeMixin):
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def __init__(self, name, identifier, size=0, parent=None, children=None):
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super(TreeNode, self).__init__()
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self.name = name
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self.size = size
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self.parent = parent
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self.identifier = identifier
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if children:
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self.children = children
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def __repr__(self):
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return self.name
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def generate_any_tree(symbol_dict):
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root = TreeNode('root', ":")
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# A set of helper function for building a simple tree with a path-like
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# hierarchy.
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def _insert_one_elem(root, path, size):
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cur = None
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node = None
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parent = root
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for part in path.parts:
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if cur is None:
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cur = part
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else:
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cur = str(Path(cur, part))
|
|
|
|
results = findall_by_attr(root, cur, name="identifier")
|
|
if results:
|
|
item = results[0]
|
|
item.size += size
|
|
parent = item
|
|
else:
|
|
if node:
|
|
parent = node
|
|
node = TreeNode(name=str(part), identifier=cur, size=size, parent=parent)
|
|
|
|
for name, sym in symbol_dict.items():
|
|
for symbol in sym:
|
|
size = get_symbol_size(symbol['symbol'])
|
|
for file in symbol['mapped_files']:
|
|
path = Path(file, name)
|
|
if path.is_absolute():
|
|
zb = Path(args.zephyrbase)
|
|
if zb.parent in path.parents:
|
|
path = path.relative_to(zb.parent)
|
|
|
|
_insert_one_elem(root, path, size)
|
|
|
|
return root
|
|
|
|
def node_sort(items):
|
|
return sorted(items, key=lambda item: item.name)
|
|
|
|
def print_any_tree(root, total_size, depth):
|
|
|
|
print('{:101s} {:7s} {:8s}'.format(
|
|
Fore.YELLOW + "Path", "Size", "%" + Fore.RESET))
|
|
print('=' * 110)
|
|
for row in RenderTree(root, childiter=node_sort, maxlevel=depth):
|
|
f = len(row.pre) + len(row.node.name)
|
|
s = str(row.node.size).rjust(100-f)
|
|
percent = 100 * float(row.node.size) / float(total_size)
|
|
|
|
cc = cr = ""
|
|
if not row.node.children:
|
|
cc = Fore.CYAN
|
|
cr = Fore.RESET
|
|
elif row.node.name.endswith(".c") or row.node.name.endswith(".h"):
|
|
cc = Fore.GREEN
|
|
cr = Fore.RESET
|
|
|
|
print(f"{row.pre}{cc}{row.node.name}{cr} {s} {Fore.BLUE}{percent:.2f}%{Fore.RESET}")
|
|
print('=' * 110)
|
|
print(f'{total_size:>101}')
|
|
|
|
|
|
|
|
def parse_args():
|
|
global args
|
|
|
|
parser = argparse.ArgumentParser()
|
|
|
|
parser.add_argument("-k", "--kernel", required=True,
|
|
help="Zephyr ELF binary")
|
|
parser.add_argument("-z", "--zephyrbase", required=True,
|
|
help="Zephyr base path")
|
|
parser.add_argument("-o", "--output", required=True,
|
|
help="Output path")
|
|
parser.add_argument("target", choices=['rom', 'ram'])
|
|
parser.add_argument("-d", "--depth", dest="depth",
|
|
type=int, default=None,
|
|
help="How deep should we go into the tree",
|
|
metavar="DEPTH")
|
|
parser.add_argument("-v", "--verbose", action="store_true",
|
|
help="Print extra debugging information")
|
|
parser.add_argument("--json", help="store results in a JSON file.")
|
|
args = parser.parse_args()
|
|
|
|
|
|
def main():
|
|
parse_args()
|
|
|
|
# Init colorama
|
|
init()
|
|
|
|
assert os.path.exists(args.kernel), "{0} does not exist.".format(args.kernel)
|
|
|
|
elf = ELFFile(open(args.kernel, "rb"))
|
|
|
|
assert elf.has_dwarf_info(), "ELF file has no DWARF information"
|
|
|
|
set_global_machine_arch(elf.get_machine_arch())
|
|
|
|
addr_ranges = get_section_ranges(elf)
|
|
|
|
symbols = get_symbols(elf, addr_ranges)
|
|
|
|
for sym in symbols['unassigned'].values():
|
|
print("WARN: Symbol '{0}' is not in RAM or ROM".format(sym['name']))
|
|
|
|
symbol_dict = None
|
|
if args.target == 'rom':
|
|
symbol_dict = symbols['rom']
|
|
symsize = addr_ranges['rom_total_size']
|
|
ranges = addr_ranges['rom']
|
|
elif args.target == 'ram':
|
|
symbol_dict = symbols['ram']
|
|
symsize = addr_ranges['ram_total_size']
|
|
ranges = addr_ranges['ram']
|
|
|
|
if symbol_dict is not None:
|
|
processed = {"mapped_symbols": set(),
|
|
"mapped_addr": set(),
|
|
"unmapped_symbols": set(symbol_dict.keys())}
|
|
|
|
do_simple_name_matching(elf, symbol_dict, processed)
|
|
mark_address_aliases(symbol_dict, processed)
|
|
do_address_range_matching(elf, symbol_dict, processed)
|
|
mark_address_aliases(symbol_dict, processed)
|
|
set_root_path_for_unmapped_symbols(symbol_dict, ranges, processed)
|
|
|
|
if args.verbose:
|
|
for sym in processed['unmapped_symbols']:
|
|
print("INFO: Unmapped symbol: {0}".format(sym))
|
|
|
|
root = generate_any_tree(symbol_dict)
|
|
print_any_tree(root, symsize, args.depth)
|
|
|
|
if args.json:
|
|
exporter = DictExporter()
|
|
data = dict()
|
|
data["symbols"] = exporter.export(root)
|
|
data["total_size"] = symsize
|
|
with open(args.json, "w") as fp:
|
|
json.dump(data, fp, indent=4)
|
|
|
|
|
|
if __name__ == "__main__":
|
|
main()
|