#------------------------------------------------------------------------------- # elftools: elf/segments.py # # ELF segments # # Eli Bendersky (eliben@gmail.com) # This code is in the public domain #------------------------------------------------------------------------------- from ..construct import CString from ..common.utils import struct_parse from .constants import SH_FLAGS from .notes import iter_notes class Segment(object): def __init__(self, header, stream): self.header = header self.stream = stream def data(self): """ The segment data from the file. """ self.stream.seek(self['p_offset']) return self.stream.read(self['p_filesz']) def __getitem__(self, name): """ Implement dict-like access to header entries """ return self.header[name] def section_in_segment(self, section): """ Is the given section contained in this segment? Note: this tries to reproduce the intricate rules of the ELF_SECTION_IN_SEGMENT_STRICT macro of the header elf/include/internal.h in the source of binutils. """ # Only the 'strict' checks from ELF_SECTION_IN_SEGMENT_1 are included segtype = self['p_type'] sectype = section['sh_type'] secflags = section['sh_flags'] # Only PT_LOAD, PT_GNU_RELR0 and PT_TLS segments can contain SHF_TLS # sections if ( secflags & SH_FLAGS.SHF_TLS and segtype in ('PT_TLS', 'PT_GNU_RELR0', 'PT_LOAD')): return False # PT_TLS segment contains only SHF_TLS sections, PT_PHDR no sections # at all elif ( (secflags & SH_FLAGS.SHF_TLS) != 0 and segtype not in ('PT_TLS', 'PT_PHDR')): return False # In ELF_SECTION_IN_SEGMENT_STRICT the flag check_vma is on, so if # this is an alloc section, check whether its VMA is in bounds. if secflags & SH_FLAGS.SHF_ALLOC: secaddr = section['sh_addr'] vaddr = self['p_vaddr'] # This checks that the section is wholly contained in the segment. # The third condition is the 'strict' one - an empty section will # not match at the very end of the segment (unless the segment is # also zero size, which is handled by the second condition). if not (secaddr >= vaddr and secaddr - vaddr + section['sh_size'] <= self['p_memsz'] and secaddr - vaddr <= self['p_memsz'] - 1): return False # If we've come this far and it's a NOBITS section, it's in the segment if sectype == 'SHT_NOBITS': return True secoffset = section['sh_offset'] poffset = self['p_offset'] # Same logic as with secaddr vs. vaddr checks above, just on offsets in # the file return (secoffset >= poffset and secoffset - poffset + section['sh_size'] <= self['p_filesz'] and secoffset - poffset <= self['p_filesz'] - 1) class InterpSegment(Segment): """ INTERP segment. Knows how to obtain the path to the interpreter used for this ELF file. """ def __init__(self, header, stream): super(InterpSegment, self).__init__(header, stream) def get_interp_name(self): """ Obtain the interpreter path used for this ELF file. """ path_offset = self['p_offset'] return struct_parse( CString('', encoding='utf-8'), self.stream, stream_pos=path_offset) class NoteSegment(Segment): """ NOTE segment. Knows how to parse notes. """ def __init__(self, header, stream, elffile): super(NoteSegment, self).__init__(header, stream) self.elffile = elffile def iter_notes(self): """ Yield all the notes in the segment. Each result is a dictionary- like object with "n_name", "n_type", and "n_desc" fields, amongst others. """ return iter_notes(self.elffile, self['p_offset'], self['p_filesz'])