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import collections import functools import os import re import struct import sys import warnings from typing import IO, Dict, Iterator, NamedTuple, Optional, Tuple # Python does not provide platform information at sufficient granularity to # identify the architecture of the running executable in some cases, so we # determine it dynamically by reading the information from the running # process. This only applies on Linux, which uses the ELF format. class _ELFFileHeader: # https://en.wikipedia.org/wiki/Executable_and_Linkable_Format#File_header class _InvalidELFFileHeader(ValueError): """ An invalid ELF file header was found. """ ELF_MAGIC_NUMBER = 0x7F454C46 ELFCLASS32 = 1 ELFCLASS64 = 2 ELFDATA2LSB = 1 ELFDATA2MSB = 2 EM_386 = 3 EM_S390 = 22 EM_ARM = 40 EM_X86_64 = 62 EF_ARM_ABIMASK = 0xFF000000 EF_ARM_ABI_VER5 = 0x05000000 EF_ARM_ABI_FLOAT_HARD = 0x00000400 def __init__(self, file: IO[bytes]) -> None: def unpack(fmt: str) -> int: try: data = file.read(struct.calcsize(fmt)) result: Tuple[int, ...] = struct.unpack(fmt, data) except struct.error: raise _ELFFileHeader._InvalidELFFileHeader() return result[0] self.e_ident_magic = unpack(">I") if self.e_ident_magic != self.ELF_MAGIC_NUMBER: raise _ELFFileHeader._InvalidELFFileHeader() self.e_ident_class = unpack("B") if self.e_ident_class not in {self.ELFCLASS32, self.ELFCLASS64}: raise _ELFFileHeader._InvalidELFFileHeader() self.e_ident_data = unpack("B") if self.e_ident_data not in {self.ELFDATA2LSB, self.ELFDATA2MSB}: raise _ELFFileHeader._InvalidELFFileHeader() self.e_ident_version = unpack("B") self.e_ident_osabi = unpack("B") self.e_ident_abiversion = unpack("B") self.e_ident_pad = file.read(7) format_h = "<H" if self.e_ident_data == self.ELFDATA2LSB else ">H" format_i = "<I" if self.e_ident_data == self.ELFDATA2LSB else ">I" format_q = "<Q" if self.e_ident_data == self.ELFDATA2LSB else ">Q" format_p = format_i if self.e_ident_class == self.ELFCLASS32 else format_q self.e_type = unpack(format_h) self.e_machine = unpack(format_h) self.e_version = unpack(format_i) self.e_entry = unpack(format_p) self.e_phoff = unpack(format_p) self.e_shoff = unpack(format_p) self.e_flags = unpack(format_i) self.e_ehsize = unpack(format_h) self.e_phentsize = unpack(format_h) self.e_phnum = unpack(format_h) self.e_shentsize = unpack(format_h) self.e_shnum = unpack(format_h) self.e_shstrndx = unpack(format_h) def _get_elf_header() -> Optional[_ELFFileHeader]: try: with open(sys.executable, "rb") as f: elf_header = _ELFFileHeader(f) except (OSError, TypeError, _ELFFileHeader._InvalidELFFileHeader): return None return elf_header def _is_linux_armhf() -> bool: # hard-float ABI can be detected from the ELF header of the running # process # https://static.docs.arm.com/ihi0044/g/aaelf32.pdf elf_header = _get_elf_header() if elf_header is None: return False result = elf_header.e_ident_class == elf_header.ELFCLASS32 result &= elf_header.e_ident_data == elf_header.ELFDATA2LSB result &= elf_header.e_machine == elf_header.EM_ARM result &= ( elf_header.e_flags & elf_header.EF_ARM_ABIMASK ) == elf_header.EF_ARM_ABI_VER5 result &= ( elf_header.e_flags & elf_header.EF_ARM_ABI_FLOAT_HARD ) == elf_header.EF_ARM_ABI_FLOAT_HARD return result def _is_linux_i686() -> bool: elf_header = _get_elf_header() if elf_header is None: return False result = elf_header.e_ident_class == elf_header.ELFCLASS32 result &= elf_header.e_ident_data == elf_header.ELFDATA2LSB result &= elf_header.e_machine == elf_header.EM_386 return result def _have_compatible_abi(arch: str) -> bool: if arch == "armv7l": return _is_linux_armhf() if arch == "i686": return _is_linux_i686() return arch in {"x86_64", "aarch64", "ppc64", "ppc64le", "s390x"} # If glibc ever changes its major version, we need to know what the last # minor version was, so we can build the complete list of all versions. # For now, guess what the highest minor version might be, assume it will # be 50 for testing. Once this actually happens, update the dictionary # with the actual value. _LAST_GLIBC_MINOR: Dict[int, int] = collections.defaultdict(lambda: 50) class _GLibCVersion(NamedTuple): major: int minor: int def _glibc_version_string_confstr() -> Optional[str]: """ Primary implementation of glibc_version_string using os.confstr. """ # os.confstr is quite a bit faster than ctypes.DLL. It's also less likely # to be broken or missing. This strategy is used in the standard library # platform module. # https://github.com/python/cpython/blob/fcf1d003bf4f0100c/Lib/platform.py#L175-L183 try: # os.confstr("CS_GNU_LIBC_VERSION") returns a string like "glibc 2.17". version_string = os.confstr("CS_GNU_LIBC_VERSION") assert version_string is not None _, version = version_string.split() except (AssertionError, AttributeError, OSError, ValueError): # os.confstr() or CS_GNU_LIBC_VERSION not available (or a bad value)... return None return version def _glibc_version_string_ctypes() -> Optional[str]: """ Fallback implementation of glibc_version_string using ctypes. """ try: import ctypes except ImportError: return None # ctypes.CDLL(None) internally calls dlopen(NULL), and as the dlopen # manpage says, "If filename is NULL, then the returned handle is for the # main program". This way we can let the linker do the work to figure out # which libc our process is actually using. # # We must also handle the special case where the executable is not a # dynamically linked executable. This can occur when using musl libc, # for example. In this situation, dlopen() will error, leading to an # OSError. Interestingly, at least in the case of musl, there is no # errno set on the OSError. The single string argument used to construct # OSError comes from libc itself and is therefore not portable to # hard code here. In any case, failure to call dlopen() means we # can proceed, so we bail on our attempt. try: process_namespace = ctypes.CDLL(None) except OSError: return None try: gnu_get_libc_version = process_namespace.gnu_get_libc_version except AttributeError: # Symbol doesn't exist -> therefore, we are not linked to # glibc. return None # Call gnu_get_libc_version, which returns a string like "2.5" gnu_get_libc_version.restype = ctypes.c_char_p version_str: str = gnu_get_libc_version() # py2 / py3 compatibility: if not isinstance(version_str, str): version_str = version_str.decode("ascii") return version_str def _glibc_version_string() -> Optional[str]: """Returns glibc version string, or None if not using glibc.""" return _glibc_version_string_confstr() or _glibc_version_string_ctypes() def _parse_glibc_version(version_str: str) -> Tuple[int, int]: """Parse glibc version. We use a regexp instead of str.split because we want to discard any random junk that might come after the minor version -- this might happen in patched/forked versions of glibc (e.g. Linaro's version of glibc uses version strings like "2.20-2014.11"). See gh-3588. """ m = re.match(r"(?P<major>[0-9]+)\.(?P<minor>[0-9]+)", version_str) if not m: warnings.warn( "Expected glibc version with 2 components major.minor," " got: %s" % version_str, RuntimeWarning, ) return -1, -1 return int(m.group("major")), int(m.group("minor")) @functools.lru_cache() def _get_glibc_version() -> Tuple[int, int]: version_str = _glibc_version_string() if version_str is None: return (-1, -1) return _parse_glibc_version(version_str) # From PEP 513, PEP 600 def _is_compatible(name: str, arch: str, version: _GLibCVersion) -> bool: sys_glibc = _get_glibc_version() if sys_glibc < version: return False # Check for presence of _manylinux module. try: import _manylinux # noqa except ImportError: return True if hasattr(_manylinux, "manylinux_compatible"): result = _manylinux.manylinux_compatible(version[0], version[1], arch) if result is not None: return bool(result) return True if version == _GLibCVersion(2, 5): if hasattr(_manylinux, "manylinux1_compatible"): return bool(_manylinux.manylinux1_compatible) if version == _GLibCVersion(2, 12): if hasattr(_manylinux, "manylinux2010_compatible"): return bool(_manylinux.manylinux2010_compatible) if version == _GLibCVersion(2, 17): if hasattr(_manylinux, "manylinux2014_compatible"): return bool(_manylinux.manylinux2014_compatible) return True _LEGACY_MANYLINUX_MAP = { # CentOS 7 w/ glibc 2.17 (PEP 599) (2, 17): "manylinux2014", # CentOS 6 w/ glibc 2.12 (PEP 571) (2, 12): "manylinux2010", # CentOS 5 w/ glibc 2.5 (PEP 513) (2, 5): "manylinux1", } def platform_tags(linux: str, arch: str) -> Iterator[str]: if not _have_compatible_abi(arch): return # Oldest glibc to be supported regardless of architecture is (2, 17). too_old_glibc2 = _GLibCVersion(2, 16) if arch in {"x86_64", "i686"}: # On x86/i686 also oldest glibc to be supported is (2, 5). too_old_glibc2 = _GLibCVersion(2, 4) current_glibc = _GLibCVersion(*_get_glibc_version()) glibc_max_list = [current_glibc] # We can assume compatibility across glibc major versions. # https://sourceware.org/bugzilla/show_bug.cgi?id=24636 # # Build a list of maximum glibc versions so that we can # output the canonical list of all glibc from current_glibc # down to too_old_glibc2, including all intermediary versions. for glibc_major in range(current_glibc.major - 1, 1, -1): glibc_minor = _LAST_GLIBC_MINOR[glibc_major] glibc_max_list.append(_GLibCVersion(glibc_major, glibc_minor)) for glibc_max in glibc_max_list: if glibc_max.major == too_old_glibc2.major: min_minor = too_old_glibc2.minor else: # For other glibc major versions oldest supported is (x, 0). min_minor = -1 for glibc_minor in range(glibc_max.minor, min_minor, -1): glibc_version = _GLibCVersion(glibc_max.major, glibc_minor) tag = "manylinux_{}_{}".format(*glibc_version) if _is_compatible(tag, arch, glibc_version): yield linux.replace("linux", tag) # Handle the legacy manylinux1, manylinux2010, manylinux2014 tags. if glibc_version in _LEGACY_MANYLINUX_MAP: legacy_tag = _LEGACY_MANYLINUX_MAP[glibc_version] if _is_compatible(legacy_tag, arch, glibc_version): yield linux.replace("linux", legacy_tag)