#!/usr/bin/env python3 import argparse import os import pprint import subprocess import sys import json from fnmatch import fnmatch from collections import defaultdict from contextlib import contextmanager from dataclasses import dataclass from itertools import chain from pathlib import Path, PurePath from typing import DefaultDict, Generator, Iterator, Optional from elftools.common.exceptions import ELFError # type: ignore from elftools.elf.dynamic import DynamicSection # type: ignore from elftools.elf.sections import NoteSection # type: ignore from elftools.elf.elffile import ELFFile # type: ignore from elftools.elf.enums import ENUM_E_TYPE, ENUM_EI_OSABI # type: ignore @contextmanager def open_elf(path: Path) -> Iterator[ELFFile]: with path.open('rb') as stream: yield ELFFile(stream) def is_static_executable(elf: ELFFile) -> bool: # Statically linked executables have an ELF type of EXEC but no INTERP. return (elf.header["e_type"] == 'ET_EXEC' and not elf.get_section_by_name(".interp")) def is_dynamic_executable(elf: ELFFile) -> bool: # We do not require an ELF type of EXEC. This also catches # position-independent executables, as they typically have an INTERP # section but their ELF type is DYN. return bool(elf.get_section_by_name(".interp")) def get_dependencies(elf: ELFFile) -> list[list[Path]]: dependencies = [] # This convoluted code is here on purpose. For some reason, using # elf.get_section_by_name(".dynamic") does not always return an # instance of DynamicSection, but that is required to call iter_tags for section in elf.iter_sections(): if isinstance(section, DynamicSection): for tag in section.iter_tags('DT_NEEDED'): dependencies.append([Path(tag.needed)]) break # There is only one dynamic section return dependencies def get_dlopen_dependencies(elf: ELFFile) -> list[list[Path]]: """ Extracts dependencies from the `.note.dlopen` section. This is a FreeDesktop standard to annotate binaries with libraries that it may `dlopen`. See https://systemd.io/ELF_DLOPEN_METADATA/ """ dependencies = [] for section in elf.iter_sections(): if not isinstance(section, NoteSection) or section.name != ".note.dlopen": continue for note in section.iter_notes(): if note["n_type"] != 0x407C0C0A or note["n_name"] != "FDO": continue note_desc = note["n_desc"] text = note_desc.decode("utf-8").rstrip("\0") j = json.loads(text) for d in j: dependencies.append([Path(soname) for soname in d["soname"]]) return dependencies def get_rpath(elf: ELFFile) -> list[str]: # This convoluted code is here on purpose. For some reason, using # elf.get_section_by_name(".dynamic") does not always return an # instance of DynamicSection, but that is required to call iter_tags for section in elf.iter_sections(): if isinstance(section, DynamicSection): for tag in section.iter_tags('DT_RUNPATH'): return tag.runpath.split(':') for tag in section.iter_tags('DT_RPATH'): return tag.rpath.split(':') break # There is only one dynamic section return [] def get_arch(elf: ELFFile) -> str: return elf.get_machine_arch() def get_osabi(elf: ELFFile) -> str: return elf.header["e_ident"]["EI_OSABI"] def osabi_are_compatible(wanted: str, got: str) -> bool: """ Tests whether two OS ABIs are compatible, taking into account the generally accepted compatibility of SVR4 ABI with other ABIs. """ if not wanted or not got: # One of the types couldn't be detected, so as a fallback we'll # assume they're compatible. return True # Generally speaking, the base ABI (0x00), which is represented by # readelf(1) as "UNIX - System V", indicates broad compatibility # with other ABIs. # # TODO: This isn't always true. For example, some OSes embed ABI # compatibility into SHT_NOTE sections like .note.tag and # .note.ABI-tag. It would be prudent to add these to the detection # logic to produce better ABI information. if wanted == 'ELFOSABI_SYSV': return True # Similarly here, we should be able to link against a superset of # features, so even if the target has another ABI, this should be # fine. if got == 'ELFOSABI_SYSV': return True # Otherwise, we simply return whether the ABIs are identical. return wanted == got def glob(path: Path, pattern: str, recursive: bool) -> Iterator[Path]: if path.is_dir(): return path.rglob(pattern) if recursive else path.glob(pattern) else: # path.glob won't return anything if the path is not a directory. # We extend that behavior by matching the file name against the pattern. # This allows to pass single files instead of dirs to auto_patchelf, # for greater control on the files to consider. return [path] if path.match(pattern) else [] cached_paths: set[Path] = set() soname_cache: DefaultDict[tuple[str, str], list[tuple[Path, str]]] = defaultdict(list) def populate_cache(initial: list[Path], recursive: bool =False) -> None: lib_dirs = list(initial) while lib_dirs: lib_dir = lib_dirs.pop(0) if lib_dir in cached_paths: continue cached_paths.add(lib_dir) for path in glob(lib_dir, "*.so*", recursive): if not path.is_file(): continue # As an optimisation, resolve the symlinks here, as the target is unique # XXX: (layus, 2022-07-25) is this really an optimisation in all cases ? # It could make the rpath bigger or break the fragile precedence of $out. resolved = path.resolve() # Do not use resolved paths when names do not match if resolved.name != path.name: resolved = path try: with open_elf(path) as elf: osabi = get_osabi(elf) arch = get_arch(elf) rpath = [Path(p) for p in get_rpath(elf) if p and '$ORIGIN' not in p] lib_dirs += rpath soname_cache[(path.name, arch)].append((resolved.parent, osabi)) except ELFError: # Not an ELF file in the right format pass def find_dependency(soname: str, soarch: str, soabi: str) -> Optional[Path]: for lib, libabi in soname_cache[(soname, soarch)]: if osabi_are_compatible(soabi, libabi): return lib return None @dataclass class Dependency: file: Path # The file that contains the dependency name: Path # The name of the dependency found: bool = False # Whether it was found somewhere def auto_patchelf_file(path: Path, runtime_deps: list[Path], append_rpaths: list[Path] = [], extra_args: list[str] = []) -> list[Dependency]: try: with open_elf(path) as elf: if is_static_executable(elf): # No point patching these print(f"skipping {path} because it is statically linked") return [] if elf.num_segments() == 0: # no segment (e.g. object file) print(f"skipping {path} because it contains no segment") return [] file_arch = get_arch(elf) if interpreter_arch != file_arch: # Our target architecture is different than this file's # architecture, so skip it. print(f"skipping {path} because its architecture ({file_arch})" f" differs from target ({interpreter_arch})") return [] file_osabi = get_osabi(elf) if not osabi_are_compatible(interpreter_osabi, file_osabi): print(f"skipping {path} because its OS ABI ({file_osabi}) is" f" not compatible with target ({interpreter_osabi})") return [] file_is_dynamic_executable = is_dynamic_executable(elf) file_dependencies = get_dependencies(elf) + get_dlopen_dependencies(elf) except ELFError: return [] rpath = [] if file_is_dynamic_executable: print("setting interpreter of", path) subprocess.run( ["patchelf", "--set-interpreter", interpreter_path.as_posix(), path.as_posix()] + extra_args, check=True) rpath += runtime_deps print("searching for dependencies of", path) dependencies = [] # Be sure to get the output of all missing dependencies instead of # failing at the first one, because it's more useful when working # on a new package where you don't yet know the dependencies. for dep in file_dependencies: was_found = False for candidate in dep: # This loop determines which candidate for a given # dependency can be found, and how. There may be multiple # candidates for a dep because of '.note.dlopen' # dependencies. # # 1. If a candidate is an absolute path, it is already a # valid dependency if that path exists, and nothing needs # to be done. It should be an error if that path does not exist. # 2. If a candidate is found in our library dependencies, that # dependency should be added to rpath. # 3. If a candidate is found in libc, it will be correctly # resolved by the dynamic linker automatically. # # These conditions are checked in this order, because #2 # and #3 may both be true. In that case, we still want to # add the dependency to rpath, as the original binary # presumably had it and this should be preserved. if candidate.is_absolute() and candidate.is_file(): was_found = True break elif found_dependency := find_dependency(candidate.name, file_arch, file_osabi): rpath.append(found_dependency) dependencies.append(Dependency(path, candidate, found=True)) print(f" {candidate} -> found: {found_dependency}") was_found = True break elif (libc_lib / candidate).is_file(): was_found = True break if not was_found: dep_name = dep[0] if len(dep) == 1 else f"any({', '.join(map(str, dep))})" dependencies.append(Dependency(path, dep_name, found=False)) print(f" {dep_name} -> not found!") rpath.extend(append_rpaths) # Dedup the rpath rpath_str = ":".join(dict.fromkeys(map(Path.as_posix, rpath))) if rpath: print("setting RPATH to:", rpath_str) subprocess.run( ["patchelf", "--set-rpath", rpath_str, path.as_posix()] + extra_args, check=True) return dependencies def auto_patchelf( paths_to_patch: list[Path], lib_dirs: list[Path], runtime_deps: list[Path], recursive: bool = True, ignore_missing: list[str] = [], append_rpaths: list[Path] = [], extra_args: list[str] = []) -> None: if not paths_to_patch: sys.exit("No paths to patch, stopping.") # Add all shared objects of the current output path to the cache, # before lib_dirs, so that they are chosen first in find_dependency. populate_cache(paths_to_patch, recursive) populate_cache(lib_dirs) dependencies = [] for path in chain.from_iterable(glob(p, '*', recursive) for p in paths_to_patch): if not path.is_symlink() and path.is_file(): dependencies += auto_patchelf_file(path, runtime_deps, append_rpaths, extra_args) missing = [dep for dep in dependencies if not dep.found] # Print a summary of the missing dependencies at the end print(f"auto-patchelf: {len(missing)} dependencies could not be satisfied") failure = False for dep in missing: for pattern in ignore_missing: if fnmatch(dep.name.name, pattern): print(f"warn: auto-patchelf ignoring missing {dep.name} wanted by {dep.file}") break else: print(f"error: auto-patchelf could not satisfy dependency {dep.name} wanted by {dep.file}") failure = True if failure: sys.exit('auto-patchelf failed to find all the required dependencies.\n' 'Add the missing dependencies to --libs or use ' '`--ignore-missing="foo.so.1 bar.so etc.so"`.') def main() -> None: parser = argparse.ArgumentParser( prog="auto-patchelf", description='auto-patchelf tries as hard as possible to patch the' ' provided binary files by looking for compatible' 'libraries in the provided paths.') parser.add_argument( "--ignore-missing", nargs="*", type=str, help="Do not fail when some dependencies are not found.") parser.add_argument( "--no-recurse", dest="recursive", action="store_false", help="Disable the recursive traversal of paths to patch.") parser.add_argument( "--paths", nargs="*", type=Path, help="Paths whose content needs to be patched." " Single files and directories are accepted." " Directories are traversed recursively by default.") parser.add_argument( "--libs", nargs="*", type=Path, help="Paths where libraries are searched for." " Single files and directories are accepted." " Directories are not searched recursively.") parser.add_argument( "--runtime-dependencies", nargs="*", type=Path, help="Paths to prepend to the runtime path of executable binaries." " Subject to deduplication, which may imply some reordering.") parser.add_argument( "--append-rpaths", nargs="*", type=Path, help="Paths to append to all runtime paths unconditionally", ) parser.add_argument( "--extra-args", # Undocumented Python argparse feature: consume all remaining arguments # as values for this one. This means this argument should always be passed # last. nargs="...", type=str, help="Extra arguments to pass to patchelf. This argument should always come last." ) print("automatically fixing dependencies for ELF files") args = parser.parse_args() pprint.pprint(vars(args)) auto_patchelf( args.paths, args.libs, args.runtime_dependencies, args.recursive, args.ignore_missing, append_rpaths=args.append_rpaths, extra_args=args.extra_args) interpreter_path: Path = None # type: ignore interpreter_osabi: str = None # type: ignore interpreter_arch: str = None # type: ignore libc_lib: Path = None # type: ignore if __name__ == "__main__": nix_support = Path(os.environ['NIX_BINTOOLS']) / 'nix-support' interpreter_path = Path((nix_support / 'dynamic-linker').read_text().strip()) libc_lib = Path((nix_support / 'orig-libc').read_text().strip()) / 'lib' with open_elf(interpreter_path) as interpreter: interpreter_osabi = get_osabi(interpreter) interpreter_arch = get_arch(interpreter) if interpreter_arch and interpreter_osabi and interpreter_path and libc_lib: main() else: sys.exit("Failed to parse dynamic linker (ld) properties.")