#!/usr/bin/env python3 # Copyright 2013-2014 The Meson development team # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # http://www.apache.org/licenses/LICENSE-2.0 # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import sys, struct SHT_STRTAB = 3 DT_NEEDED = 1 DT_RPATH = 15 DT_STRTAB = 5 DT_SONAME = 14 class DataSizes(): def __init__(self, ptrsize, is_le): if is_le: p = '<' else: p = '>' self.Half = p+'h' self.HalfSize = 2 self.Word = p+'I' self.WordSize = 4 self.Sword = p+'i' self.SwordSize = 4 if ptrsize == 64: self.Addr = p+'Q' self.AddrSize = 8 self.Off = p+'Q' self.OffSize = 8 self.XWord = p+'Q' self.XWordSize = 8 self.Sxword = p+'q' self.SxwordSize = 8 else: self.Addr = p+'I' self.AddrSize = 4 self.Off = p+'I' self.OffSize = 4 class DynamicEntry(DataSizes): def __init__(self, ifile, ptrsize, is_le): super().__init__(ptrsize, is_le) self.ptrsize = ptrsize if ptrsize == 64: self.d_tag = struct.unpack(self.Sxword, ifile.read(self.SxwordSize))[0]; self.val = struct.unpack(self.XWord, ifile.read(self.XWordSize))[0]; else: self.d_tag = struct.unpack(self.Sword, ifile.read(self.SwordSize))[0] self.val = struct.unpack(self.Word, ifile.read(self.WordSize))[0] def write(self, ofile): if self.ptrsize == 64: ofile.write(struct.pack(self.Sxword, self.d_tag)) ofile.write(struct.pack(self.XWord, self.val)) else: ofile.write(struct.pack(self.Sword, self.d_tag)) ofile.write(struct.pack(self.Word, self.val)) class SectionHeader(DataSizes): def __init__(self, ifile, ptrsize, is_le): super().__init__(ptrsize, is_le) if ptrsize == 64: is_64 = True else: is_64 = False #Elf64_Word self.sh_name = struct.unpack(self.Word, ifile.read(self.WordSize))[0]; #Elf64_Word self.sh_type = struct.unpack(self.Word, ifile.read(self.WordSize))[0] #Elf64_Xword if is_64: self.sh_flags = struct.unpack(self.XWord, ifile.read(self.XWordSize))[0] else: self.sh_flags = struct.unpack(self.Word, ifile.read(self.WordSize))[0] #Elf64_Addr self.sh_addr = struct.unpack(self.Addr, ifile.read(self.AddrSize))[0]; #Elf64_Off self.sh_offset = struct.unpack(self.Off, ifile.read(self.OffSize))[0] #Elf64_Xword if is_64: self.sh_size = struct.unpack(self.XWord, ifile.read(self.XWordSize))[0] else: self.sh_size = struct.unpack(self.Word, ifile.read(self.WordSize))[0] #Elf64_Word self.sh_link = struct.unpack(self.Word, ifile.read(self.WordSize))[0]; #Elf64_Word self.sh_info = struct.unpack(self.Word, ifile.read(self.WordSize))[0]; #Elf64_Xword if is_64: self.sh_addralign = struct.unpack(self.XWord, ifile.read(self.XWordSize))[0] else: self.sh_addralign = struct.unpack(self.Word, ifile.read(self.WordSize))[0] #Elf64_Xword if is_64: self.sh_entsize = struct.unpack(self.XWord, ifile.read(self.XWordSize))[0] else: self.sh_entsize = struct.unpack(self.Word, ifile.read(self.WordSize))[0] class Elf(DataSizes): def __init__(self, bfile): self.bfile = bfile self.bf = open(bfile, 'r+b') (self.ptrsize, self.is_le) = self.detect_elf_type() super().__init__(self.ptrsize, self.is_le) self.parse_header() self.parse_sections() self.parse_dynamic() def detect_elf_type(self): data = self.bf.read(6) if data[1:4] != b'ELF': # This script gets called to non-elf targets too # so just ignore them. print('File "%s" is not an ELF file.' % self.bfile) sys.exit(0) if data[4] == 1: ptrsize = 32 elif data[4] == 2: ptrsize = 64 else: print('File "%s" has unknown ELF class.' % self.bfile) sys.exit(1) if data[5] == 1: is_le = True elif data[5] == 2: is_le = False else: print('File "%s" has unknown ELF endianness.' % self.bfile) sys.exit(1) return (ptrsize, is_le) def parse_header(self): self.bf.seek(0) self.e_ident = struct.unpack('16s', self.bf.read(16))[0] self.e_type = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_machine = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_version = struct.unpack(self.Word, self.bf.read(self.WordSize))[0] self.e_entry = struct.unpack(self.Addr, self.bf.read(self.AddrSize))[0] self.e_phoff = struct.unpack(self.Off, self.bf.read(self.OffSize))[0] self.e_shoff = struct.unpack(self.Off, self.bf.read(self.OffSize))[0] self.e_flags = struct.unpack(self.Word, self.bf.read(self.WordSize))[0] self.e_ehsize = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_phentsize = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_phnum = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_shentsize = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_shnum = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] self.e_shstrndx = struct.unpack(self.Half, self.bf.read(self.HalfSize))[0] def parse_sections(self): self.bf.seek(self.e_shoff) self.sections = [] for i in range(self.e_shnum): self.sections.append(SectionHeader(self.bf, self.ptrsize, self.is_le)) def read_str(self): arr = [] x = self.bf.read(1) while x != b'\0': arr.append(x) x = self.bf.read(1) if x == b'': raise RuntimeError('Tried to read past the end of the file') return b''.join(arr) def find_section(self, target_name): section_names = self.sections[self.e_shstrndx] for i in self.sections: self.bf.seek(section_names.sh_offset + i.sh_name) name = self.read_str() if name == target_name: return i def parse_dynamic(self): sec = self.find_section(b'.dynamic') self.dynamic = [] self.bf.seek(sec.sh_offset) while True: e = DynamicEntry(self.bf, self.ptrsize, self.is_le) self.dynamic.append(e) if e.d_tag == 0: break def print_section_names(self): section_names = self.sections[self.e_shstrndx] for i in self.sections: self.bf.seek(section_names.sh_offset + i.sh_name) name = self.read_str() print(name.decode()) def print_soname(self): soname = None strtab = None for i in self.dynamic: if i.d_tag == DT_SONAME: soname = i if i.d_tag == DT_STRTAB: strtab = i self.bf.seek(strtab.val + soname.val) print(self.read_str()) def get_rpath_offset(self): sec = self.find_section(b'.dynstr') for i in self.dynamic: if i.d_tag == DT_RPATH: return sec.sh_offset + i.val return None def print_rpath(self): offset = self.get_rpath_offset() if offset is None: print("This file does not have an rpath.") else: self.bf.seek(offset) print(self.read_str()) def print_deps(self): sec = self.find_section(b'.dynstr') deps = [] for i in self.dynamic: if i.d_tag == DT_NEEDED: deps.append(i) for i in deps: offset = sec.sh_offset + i.val self.bf.seek(offset) name = self.read_str() print(name) def fix_deps(self, prefix): sec = self.find_section(b'.dynstr') deps = [] for i in self.dynamic: if i.d_tag == DT_NEEDED: deps.append(i) for i in deps: offset = sec.sh_offset + i.val self.bf.seek(offset) name = self.read_str() if name.startswith(prefix): basename = name.split(b'/')[-1] padding = b'\0'*(len(name) - len(basename)) newname = basename + padding assert(len(newname) == len(name)) self.bf.seek(offset) self.bf.write(newname) def fix_rpath(self, new_rpath): rp_off = self.get_rpath_offset() if rp_off is None: print('File does not have rpath. It should be a fully static executable.') return self.bf.seek(rp_off) old_rpath = self.read_str() if len(old_rpath) < len(new_rpath): print("New rpath must not be longer than the old one.") self.bf.seek(rp_off) self.bf.write(new_rpath) self.bf.write(b'\0'*(len(old_rpath) - len(new_rpath) + 1)) if len(new_rpath) == 0: self.remove_rpath_entry() def remove_rpath_entry(self): sec = self.find_section(b'.dynamic') for (i, entry) in enumerate(self.dynamic): if entry.d_tag == DT_RPATH: rpentry = self.dynamic[i] rpentry.d_tag = 0 self.dynamic = self.dynamic[:i] + self.dynamic[i+1:] + [rpentry] break; self.bf.seek(sec.sh_offset) for entry in self.dynamic: entry.write(self.bf) return None def run(args): if len(args) < 1 or len(args) > 2: print('This application resets target rpath.') print('Don\'t run this unless you know what you are doing.') print('%s: ' % sys.argv[0]) exit(1) e = Elf(args[0]) if len(args) == 1: e.print_rpath() else: new_rpath = args[1] e.fix_rpath(new_rpath.encode('utf8')) return 0 if __name__ == '__main__': run(sys.argv[1:])