def patch_bin(self, address, new_content):
# since the content could theoretically be split into different segments we will handle it here
ndata_pos = 0
for start, end in self.get_memory_translation_list(
address, len(new_content)):
ndata = new_content[ndata_pos:ndata_pos + (end - start)]
self.ncontent = utils.bytes_overwrite(self.ncontent, ndata, start)
ndata_pos += len(ndata)
def setup_headers(self, segments):
if self.replace_note_segment:
current_hdr = self.structs.Elf_Ehdr.parse(self.ncontent)
note_segment_header_loc = current_hdr["e_phoff"]
for segment in segments:
if segment["p_type"] == "PT_NOTE":
segment = Container(
**{
"p_type":
1,
"p_offset":
self.added_data_file_start,
"p_vaddr":
self.name_map["ADDED_DATA_START"],
"p_paddr":
self.name_map["ADDED_DATA_START"],
"p_filesz":
self.added_code_file_start -
self.added_data_file_start + len(self.added_code),
"p_memsz":
self.added_code_file_start -
self.added_data_file_start + len(self.added_code),
"p_flags":
0x7,
"p_align":
0x1000
})
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(segment),
note_segment_header_loc)
break
note_segment_header_loc += current_hdr["e_phentsize"]
else:
#if self.is_patched():
# return
# copying original program headers (potentially modified by patches)
# in the new place (at the end of the file)
load_segments_rounded = []
for segment in segments:
if segment["p_type"] == "PT_LOAD":
if self.first_load is None:
self.first_load = segment
load_segments_rounded.append((
# start of the segment, round down to multiple of 0x1000
(segment["p_vaddr"] - self.first_load["p_vaddr"]) -
((segment["p_vaddr"] - self.first_load["p_vaddr"]) %
0x1000),
# end of the segment, round up to multiple of 0x1000
int((segment["p_vaddr"] + segment["p_memsz"] -
self.first_load["p_vaddr"] + 0x1000 - 1) / 0x1000
) * 0x1000))
for segment in segments:
if segment["p_type"] == "PT_PHDR":
if self.phdr_segment is not None:
raise ValueError("Multiple PHDR segments!")
self.phdr_segment = segment
segment["p_filesz"] += self.additional_headers_size
segment["p_memsz"] += self.additional_headers_size
phdr_size = max(segment["p_filesz"], segment["p_memsz"])
load_segments_rounded = sorted(load_segments_rounded,
key=lambda x: x[0])
# combine overlapping load segments
while True:
new_load_segments_rounded = []
i = 0
while i < len(load_segments_rounded) - 1:
prev_seg = load_segments_rounded[i]
next_seg = load_segments_rounded[i + 1]
if prev_seg[1] > next_seg[
0]: # two segments overlap
new_load_segments_rounded.append(
(prev_seg[0], next_seg[1]
)) # append combine of two segments
i += 2
else:
new_load_segments_rounded.append(
prev_seg) # append segment without overlap
i += 1
if i == len(load_segments_rounded) - 1:
new_load_segments_rounded.append(
load_segments_rounded[i]
) # append last segment if without overlapping
if new_load_segments_rounded == load_segments_rounded: # if no overlap
break
load_segments_rounded = new_load_segments_rounded # combined segments, run again
for prev_seg, next_seg in zip(load_segments_rounded[:-1],
load_segments_rounded[1:]):
potential_base = (
(max(prev_seg[1], len(self.ncontent)) + 0xfff)
& ~0xfff) # round up to 0x1000
if next_seg[
0] - potential_base > phdr_size: # if there is space between segments, put phdr here
self.phdr_start = potential_base
break
else:
self.phdr_start = load_segments_rounded[-1][
1] # otherwise put it after the last load segment
# try to map self.phdr_start to the next page-aligned position so that p_offset is the same as
# phdr_start if the base address of this binary is 0
# this is to workaround a weird issue in the dynamic linker of glibc
# Note taht self.phdr_start is page-aligned at this moment.
# and now we want to make sure p_vaddr (self.phdr_start) == p_offset (len(self.ncontent))
if self.phdr_start > len(self.ncontent):
# p_vaddr > p_offset: pad the file (p_offset)
if self.phdr_start - len(self.ncontent) > 1_000_000:
raise Exception(
"Cannot align the file offset and vaddr of PHDR without increasing the "
"file size by more than 1 MB.")
self.ncontent = self.ncontent.ljust(
self.phdr_start, b"\x00")
else:
# p_vaddr <= p_offset: pad the file (p_offset) to page size, and let p_vaddr = p_offset
self.ncontent += b"\x00" * (
0x1000 - (len(self.ncontent) % 0x1000))
self.phdr_start = len(self.ncontent)
segment["p_offset"] = self.phdr_start
segment["p_vaddr"] = self.phdr_start + self.first_load[
"p_vaddr"]
segment["p_paddr"] = self.phdr_start + self.first_load[
"p_vaddr"]
self.ncontent = self.ncontent.ljust(self.phdr_start, b"\x00")
# change pointer to program headers to point at the end of the elf
current_hdr = self.structs.Elf_Ehdr.parse(self.ncontent)
old_phoff = current_hdr["e_phoff"]
current_hdr["e_phoff"] = len(self.ncontent)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Ehdr.build(current_hdr), 0)
print("putting them at %#x" % self.phdr_start)
print("current len: %#x" % len(self.ncontent))
for segment in segments:
if segment["p_type"] == "PT_PHDR":
segment = self.phdr_segment
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(segment))
self.original_header_end = len(self.ncontent)
# we overwrite the first original program header,
# we do not need it anymore since we have moved original program headers at the bottom of the file
self.ncontent = utils.bytes_overwrite(self.ncontent,
self.patched_tag, old_phoff)
# adding space for the additional headers
# I add two of them, no matter what, if the data one will be used only in case of the fallback solution
# Additionally added program headers have been already copied by the for loop above
self.ncontent = self.ncontent.ljust(
len(self.ncontent) + self.additional_headers_size, b"\x00")
def set_oep(self, new_oep):
# set original entry point
current_hdr = self.structs.Elf_Ehdr.parse(self.ncontent)
current_hdr["e_entry"] = new_oep
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Ehdr.build(current_hdr), 0)
def set_added_segment_headers(self):
if self.replace_note_segment:
return
l.debug("added_data_file_start: %#x", self.added_data_file_start)
added_segments = 0
# add a LOAD segment for the PHDR segment
phdr_segment_header = Container(
**{
"p_type": 1,
"p_offset": self.phdr_segment["p_offset"],
"p_vaddr": self.phdr_segment["p_vaddr"],
"p_paddr": self.phdr_segment["p_paddr"],
"p_filesz": self.phdr_segment["p_filesz"],
"p_memsz": self.phdr_segment["p_memsz"],
"p_flags": 0x4,
"p_align": 0x1000
})
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(phdr_segment_header),
self.original_header_end + (2 * self.structs.Elf_Phdr.sizeof()))
added_segments += 1
# add a LOAD segment for the DATA segment
data_segment_header = Container(
**{
"p_type": 1,
"p_offset": self.added_data_file_start,
"p_vaddr": self.name_map["ADDED_DATA_START"],
"p_paddr": self.name_map["ADDED_DATA_START"],
"p_filesz": len(self.added_data),
"p_memsz": len(self.added_data),
"p_flags": 0x6,
"p_align": 0x1000
})
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(data_segment_header),
self.original_header_end + self.structs.Elf_Phdr.sizeof())
added_segments += 1
# add a LOAD segment for the CODE segment
code_segment_header = Container(
**{
"p_type": 1,
"p_offset": self.added_code_file_start,
"p_vaddr": self.name_map["ADDED_CODE_START"],
"p_paddr": self.name_map["ADDED_CODE_START"],
"p_filesz": len(self.added_code),
"p_memsz": len(self.added_code),
"p_flags": 0x5,
"p_align": 0x1000
})
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(code_segment_header),
self.original_header_end)
added_segments += 1
current_hdr = self.structs.Elf_Ehdr.parse(self.ncontent)
current_hdr["e_phnum"] += added_segments
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Ehdr.build(current_hdr), 0)
def apply_patches(self, patches):
# deal with stackable patches
# add stackable patches to the one with highest priority
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches_dict = defaultdict(list)
for p in insert_code_patches:
insert_code_patches_dict[p.addr].append(p)
insert_code_patches_dict_sorted = defaultdict(list)
for k, v in insert_code_patches_dict.items():
insert_code_patches_dict_sorted[k] = sorted(
v, key=lambda x: -1 * x.priority)
insert_code_patches_stackable = [
p for p in patches
if isinstance(p, InsertCodePatch) and p.stackable
]
for sp in insert_code_patches_stackable:
assert len(sp.dependencies) == 0
if sp.addr in insert_code_patches_dict_sorted:
highest_priority_at_addr = insert_code_patches_dict_sorted[
sp.addr][0]
if highest_priority_at_addr != sp:
highest_priority_at_addr.asm_code += "\n" + sp.asm_code + "\n"
patches.remove(sp)
#deal with AddLabel patches
lpatches = [p for p in patches if (isinstance(p, AddLabelPatch))]
for p in lpatches:
self.name_map[p.name] = p.addr
# check for duplicate labels, it is not very necessary for this backend
# but it is better to behave in the same way of the reassembler backend
relevant_patches = [
p for p in patches
if isinstance(p, (AddCodePatch, AddEntryPointPatch,
InsertCodePatch))
]
all_code = ""
for p in relevant_patches:
if isinstance(p, InsertCodePatch):
code = p.code
else:
code = p.asm_code
all_code += "\n" + code + "\n"
labels = utils.string_to_labels(all_code)
duplicates = set(x for x in labels if labels.count(x) > 1)
if len(duplicates) > 1:
raise DuplicateLabelsException(
"found duplicate assembly labels: %s" % (str(duplicates)))
# for now any added code will be executed by jumping out and back ie CGRex
# apply all add code patches
self.added_code_file_start = len(self.ncontent)
self.name_map.force_insert("ADDED_CODE_START",
(len(self.ncontent) % 0x1000) +
self.added_code_segment)
# 0) RawPatch:
for patch in patches:
if isinstance(patch, RawFilePatch):
self.ncontent = utils.bytes_overwrite(self.ncontent,
patch.data,
patch.file_addr)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RawMemPatch):
self.patch_bin(patch.addr, patch.data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RemoveInstructionPatch):
if patch.ins_size is None:
size = 4
else:
size = patch.ins_size
self.patch_bin(patch.ins_addr, b"\x60\x00\x00\x00" * int(
(size + 4 - 1) / 4))
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 5.5) ReplaceFunctionPatch (preprocessing rodata)
for patch in patches:
if isinstance(patch, ReplaceFunctionPatch):
patches += self.compile_function(patch.asm_code,
entry=patch.addr,
symbols=patch.symbols,
data_only=True,
prefix="_RFP" +
str(patches.index(patch)))
# 1) Add{RO/RW/RWInit}DataPatch
self.added_data_file_start = len(self.ncontent)
curr_data_position = self.name_map["ADDED_DATA_START"]
for patch in patches:
if isinstance(
patch,
(AddRWDataPatch, AddRODataPatch, AddRWInitDataPatch)):
if hasattr(patch, "data"):
final_patch_data = patch.data
else:
final_patch_data = b"\x00" * patch.len
self.added_data += final_patch_data
if patch.name is not None:
self.name_map[patch.name] = curr_data_position
curr_data_position += len(final_patch_data)
self.ncontent = utils.bytes_overwrite(self.ncontent,
final_patch_data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
self.ncontent = utils.pad_bytes(
self.ncontent, 0x10) # some minimal alignment may be good
self.added_code_file_start = len(self.ncontent)
if self.replace_note_segment:
self.name_map.force_insert(
"ADDED_CODE_START",
int((curr_data_position + 0x10 - 1) / 0x10) * 0x10)
else:
self.name_map.force_insert("ADDED_CODE_START",
(len(self.ncontent) % 0x1000) +
self.added_code_segment)
# 2) AddCodePatch
# resolving symbols
current_symbol_pos = self.get_current_code_position()
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
code_len = len(
self.compile_c(patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags))
else:
code_len = len(
self.compile_asm(patch.asm_code, current_symbol_pos))
if patch.name is not None:
self.name_map[patch.name] = current_symbol_pos
current_symbol_pos += code_len
# now compile for real
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
new_code = self.compile_c(
patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags)
else:
new_code = self.compile_asm(
patch.asm_code, self.get_current_code_position(),
self.name_map)
self.added_code += new_code
self.ncontent = utils.bytes_overwrite(self.ncontent, new_code)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 3) AddEntryPointPatch
# basically like AddCodePatch but we detour by changing oep
# and we jump at the end of all of them
# resolving symbols
for patch in patches:
if isinstance(patch, AddEntryPointPatch):
old_oep = self.get_oep()
new_oep = self.get_current_code_position()
# ref: glibc/sysdeps/{ARCH}/start.S
instructions = patch.asm_code
instructions += "\nb {}".format(hex(int(old_oep)))
new_code = self.compile_asm(instructions,
self.get_current_code_position(),
self.name_map)
self.added_code += new_code
self.added_patches.append(patch)
self.ncontent = utils.bytes_overwrite(self.ncontent, new_code)
self.set_oep(new_oep)
l.info("Added patch: %s", str(patch))
# 4) InlinePatch
# we assume the patch never patches the added code
for patch in patches:
if isinstance(patch, InlinePatch):
new_code = self.compile_asm(patch.new_asm,
patch.instruction_addr,
self.name_map)
# Limiting the inline patch to a single block is not necessary
# assert len(new_code) <= self.project.factory.block(patch.instruction_addr, num_inst=patch.num_instr, max_size=).size
file_offset = self.project.loader.main_object.addr_to_offset(
patch.instruction_addr)
self.ncontent = utils.bytes_overwrite(self.ncontent, new_code,
file_offset)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 5) InsertCodePatch
# these patches specify an address in some basic block, In general we will move the basic block
# and fix relative offsets
# With this backend heer we can fail applying a patch, in case, resolve dependencies
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches = sorted(insert_code_patches,
key=lambda x: -1 * x.priority)
applied_patches = []
while True:
name_list = [
str(p) if (p is None or p.name is None) else p.name
for p in applied_patches
]
l.info("applied_patches is: |%s|", "-".join(name_list))
assert all(a == b
for a, b in zip(applied_patches, insert_code_patches))
for patch in insert_code_patches[len(applied_patches):]:
self.save_state(applied_patches)
try:
l.info("Trying to add patch: %s", str(patch))
if patch.name is not None:
self.name_map[
patch.name] = self.get_current_code_position()
new_code = self.insert_detour(patch)
self.added_code += new_code
self.ncontent = utils.bytes_overwrite(
self.ncontent, new_code)
applied_patches.append(patch)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
except (DetourException, MissingBlockException,
DoubleDetourException) as e:
l.warning(e)
insert_code_patches, removed = self.handle_remove_patch(
insert_code_patches, patch)
#print map(str,removed)
applied_patches = self.restore_state(
applied_patches, removed)
l.warning(
"One patch failed, rolling back InsertCodePatch patches. Failed patch: %s",
str(patch))
break
# TODO: right now rollback goes back to 0 patches, we may want to go back less
# the solution is to save touched_bytes and ncontent indexed by applied patfch
# and go back to the biggest compatible list of patches
else:
break #at this point we applied everything in current insert_code_patches
# TODO symbol name, for now no name_map for InsertCode patches
header_patches = [InsertCodePatch,InlinePatch,AddEntryPointPatch,AddCodePatch, \
AddRWDataPatch,AddRODataPatch,AddRWInitDataPatch]
# 5.5) ReplaceFunctionPatch
for patch in patches:
if isinstance(patch, ReplaceFunctionPatch):
if self.structs.elfclass == 64:
# reloc type not supported (TOC info is in executables but not in object file, but relocs in object file will need TOC info.)
raise Exception(
"ReplaceFunctionPatch: PPC64 not yet supported")
for k, v in self.name_map.items():
if k.startswith("_RFP" + str(patches.index(patch))):
patch.symbols[k[len("_RFP" +
str(patches.index(patch))):]] = v
new_code = self.compile_function(
patch.asm_code,
bits=self.structs.elfclass,
little_endian=self.structs.little_endian,
entry=patch.addr,
symbols=patch.symbols)
file_offset = self.project.loader.main_object.addr_to_offset(
patch.addr)
self.ncontent = utils.bytes_overwrite(
self.ncontent, b"\x60\x00\x00\x00" * (patch.size // 4),
file_offset)
if (patch.size >= len(new_code)):
file_offset = self.project.loader.main_object.addr_to_offset(
patch.addr)
self.ncontent = utils.bytes_overwrite(
self.ncontent, new_code, file_offset)
else:
header_patches.append(ReplaceFunctionPatch)
detour_pos = self.get_current_code_position()
offset = self.project.loader.main_object.mapped_base if self.project.loader.main_object.pic else 0
new_code = self.compile_function(
patch.asm_code,
bits=self.structs.elfclass,
little_endian=self.structs.little_endian,
entry=detour_pos + offset,
symbols=patch.symbols)
self.added_code += new_code
self.ncontent = utils.bytes_overwrite(
self.ncontent, new_code)
# compile jmp
jmp_code = self.compile_jmp(patch.addr,
detour_pos + offset)
self.patch_bin(patch.addr, jmp_code)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
if any(isinstance(p,ins) for ins in header_patches for p in self.added_patches) or \
any(isinstance(p,SegmentHeaderPatch) for p in patches):
# either implicitly (because of a patch adding code or data) or explicitly, we need to change segment headers
# 6) SegmentHeaderPatch
segment_header_patches = [
p for p in patches if isinstance(p, SegmentHeaderPatch)
]
if len(segment_header_patches) > 1:
msg = "more than one patch tries to change segment headers: %s", "|".join(
[str(p) for p in segment_header_patches])
raise IncompatiblePatchesException(msg)
if len(segment_header_patches) == 1:
segment_patch = segment_header_patches[0]
segments = segment_patch.segment_headers
l.info("Added patch: %s", str(segment_patch))
else:
segments = self.modded_segments
for patch in [
p for p in patches if isinstance(p, AddSegmentHeaderPatch)
]:
# add after the first
segments = [segments[0]] + [patch.new_segment] + segments[1:]
self.setup_headers(segments)
self.set_added_segment_headers()
l.debug("final symbol table: %s",
repr([(k, hex(v)) for k, v in self.name_map.items()]))
else:
l.info("no patches, the binary will not be touched")
def compile_function(code,
compiler_flags="",
bits=32,
little_endian=False,
entry=0x0,
symbols=None,
data_only=False,
prefix=""):
with utils.tempdir() as td:
c_fname = os.path.join(td, "code.c")
object_fname = os.path.join(td, "code.o")
object2_fname = os.path.join(td, "code.2.o")
linker_script_fname = os.path.join(td, "code.lds")
data_fname = os.path.join(td, "data")
rodata_sec_index = rodata_sym_index_old = rodata_sym_index_new = -1
# C -> Object File
with open(c_fname, 'w') as fp:
fp.write(code)
target = ("powerpcle-linux-gnu" if little_endian else
"powerpc-linux-gnu") if bits == 32 else (
"powerpc64le-linux-gnu"
if little_endian else "powerpc64-linux-gnu")
res = utils.exec_cmd("clang -target %s -o %s -c %s %s" \
% (target, object_fname, c_fname, compiler_flags), shell=True)
if res[2] != 0:
raise CLangException("CLang error: " +
str(res[0] + res[1], 'utf-8'))
# Setup Linker Script
linker_script = "SECTIONS { .text : { *(.text) "
if symbols:
for i in symbols:
if i == ".rodata":
linker_script += i + " = " + hex(symbols[i] - (
(entry - 0x10700000) & ~0xFFFF)) + ";"
else:
linker_script += i + " = " + hex(symbols[i] -
entry) + ";"
linker_script += "} .rodata : { *(.rodata*) } }"
with open(linker_script_fname, 'w') as fp:
fp.write(linker_script)
# Object File --LinkerScript--> Object File
res = utils.exec_cmd(
"ld.lld -relocatable %s -T %s -o %s" %
(object_fname, linker_script_fname, object2_fname),
shell=True)
if res[2] != 0:
raise Exception("Linking Error: " +
str(res[0] + res[1], 'utf-8'))
# Load Object File
ld = cle.Loader(object2_fname,
main_opts={"base_addr": 0x0},
perform_relocations=False)
# Figure Out .text Section Size
for section in ld.all_objects[0].sections:
if section.name == ".text":
text_section_size = section.filesize
break
# Modify Symbols in Object File to Trick Loader
with open(object2_fname, "rb+") as f:
elf = ELFFile(f)
# Find the Index of .rodata Section
for i in range(elf.num_sections()):
if elf.get_section(i).name == ".rodata":
rodata_sec_index = i
break
# Find the Index of the src and dest Symbol
symtab_section = elf.get_section_by_name(".symtab")
for i in range(symtab_section.num_symbols()):
if symtab_section.get_symbol(
i
)['st_shndx'] == rodata_sec_index and symtab_section.get_symbol(
i)['st_info']['type'] == 'STT_SECTION':
rodata_sym_index_old = i
if symtab_section.get_symbol(i).name == ".rodata":
rodata_sym_index_new = i
# Rewrite the Symbol
if rodata_sym_index_new != -1 and rodata_sec_index != -1 and rodata_sym_index_old != -1:
for i in range(elf.num_sections()):
if elf.get_section(i).header[
'sh_name'] == symtab_section.header['sh_name']:
f.seek(0)
content = f.read()
f.seek(symtab_section['sh_offset'] +
rodata_sym_index_new *
symtab_section['sh_entsize'])
rodata_sym_new = f.read(
symtab_section['sh_entsize'])
content = utils.bytes_overwrite(
content, rodata_sym_new,
symtab_section['sh_offset'] +
rodata_sym_index_old *
symtab_section['sh_entsize'])
f.seek(0)
f.write(content)
f.truncate()
break
# Replace all R_PPC_PLTREL24 to R_PPC_REL24
rela_section = elf.get_section_by_name(".rela.text")
if rela_section is not None:
for i in range(rela_section.num_relocations()):
if rela_section.get_relocation(i)['r_info_type'] == 18:
reloc = rela_section.get_relocation(i).entry
reloc['r_info'] -= 8
for j in range(elf.num_sections()):
if elf.get_section(j).header[
'sh_name'] == rela_section.header[
'sh_name']:
f.seek(0)
content = f.read()
content = utils.bytes_overwrite(
content,
elf.structs.Elf_Rela.build(reloc),
rela_section['sh_offset'] +
i * rela_section['sh_entsize'])
f.seek(0)
f.write(content)
f.truncate()
break
# Load the Modified Object File and Return compiled Data or Code
ld = cle.Loader(object2_fname,
main_opts={
"base_addr": 0x0,
"entry_point": 0x0
})
if data_only:
patches = []
for section in ld.all_objects[0].sections:
if section.name == ".rodata":
res = utils.exec_cmd(
"objcopy -B i386 -O binary -j %s %s %s" %
(section.name, object2_fname, data_fname),
shell=True)
if res[2] != 0:
raise ObjcopyException("Objcopy Error: " +
str(res[0] +
res[1], 'utf-8'))
with open(data_fname, "rb") as fp:
patches.append(
AddRODataPatch(fp.read(),
name=prefix + section.name))
break
return patches
else:
compiled = ld.memory.load(ld.all_objects[0].entry,
text_section_size)
return compiled
def apply_patches(self, patches):
# deal with stackable patches
# add stackable patches to the one with highest priority
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches_dict = defaultdict(list)
for p in insert_code_patches:
insert_code_patches_dict[p.addr].append(p)
insert_code_patches_dict_sorted = defaultdict(list)
for k, v in insert_code_patches_dict.items():
insert_code_patches_dict_sorted[k] = sorted(
v, key=lambda x: -1 * x.priority)
insert_code_patches_stackable = [
p for p in patches
if isinstance(p, InsertCodePatch) and p.stackable
]
for sp in insert_code_patches_stackable:
assert len(sp.dependencies) == 0
if sp.addr in insert_code_patches_dict_sorted:
highest_priority_at_addr = insert_code_patches_dict_sorted[
sp.addr][0]
if highest_priority_at_addr != sp:
highest_priority_at_addr.asm_code += "\n" + sp.asm_code + "\n"
patches.remove(sp)
#deal with AddLabel patches
for patch in patches:
if isinstance(patch, AddLabelPatch):
self.name_map[patch.name] = patch.addr
# check for duplicate labels, it is not very necessary for this backend
# but it is better to behave in the same way of the reassembler backend
relevant_patches = [
p for p in patches
if isinstance(p, (AddCodePatch, InsertCodePatch))
]
all_code = ""
for p in relevant_patches:
if isinstance(p, InsertCodePatch):
code = p.code
else:
code = p.asm_code
all_code += "\n" + code + "\n"
labels = utils.string_to_labels(all_code)
duplicates = set(x for x in labels if labels.count(x) > 1)
if len(duplicates) > 1:
raise DuplicateLabelsException(
"found duplicate assembly labels: %s" % (str(duplicates)))
for patch in patches:
if isinstance(patch, (ReplaceFunctionPatch, AddEntryPointPatch,
AddSegmentHeaderPatch, SegmentHeaderPatch)):
raise NotImplementedError()
# 0) RawPatch:
for patch in patches:
if isinstance(patch, RawFilePatch):
self.ncontent = utils.bytes_overwrite(self.ncontent,
patch.data,
patch.file_addr)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RawMemPatch):
self.patch_bin(patch.addr, patch.data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RemoveInstructionPatch):
if patch.ins_size is None:
size = 2
else:
size = patch.ins_size
self.patch_bin(patch.ins_addr, b"\x00\x00" * int(
(size + 2 - 1) / 2))
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 1) Add{RO/RW/RWInit}DataPatch
curr_data_position = self.name_map["ADDED_DATA_START"]
for patch in patches:
if isinstance(
patch,
(AddRWDataPatch, AddRODataPatch, AddRWInitDataPatch)):
if hasattr(patch, "data"):
final_patch_data = patch.data
else:
final_patch_data = b"\x00" * patch.len
self.added_data += final_patch_data
if patch.name is not None:
self.name_map[patch.name] = curr_data_position
curr_data_position += len(final_patch_data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
if ((len(self.added_data) + self.added_data_file_start) % 2 == 1):
self.added_data += b"\x00"
self.ncontent = self.insert_bytes(self.ncontent, self.added_data,
self.added_data_file_start)
self.added_code_file_start = self.added_data_file_start + len(
self.added_data)
self.name_map.force_insert(
"ADDED_CODE_START", self.added_code_file_start -
(self.text_section_offset - self.text_section_addr))
# __do_copy_data
# FIXME: not working properly
if len(self.added_data) > 0:
data_start = self.name_map["ADDED_DATA_START"]
data_end = curr_data_position
data_load_start = self.name_map["ADDED_CODE_START"] - len(
self.added_data)
data_start_hi8, data_start_lo8 = data_start >> 8, data_start & 0xFF
data_end_hi8, data_end_lo8 = data_end >> 8, data_end & 0xFF
data_load_start_hi8, data_load_start_lo8 = data_load_start >> 8, data_load_start & 0xFF
do_copy_data_code = '''
ldi r17, %d
ldi r26, %d
ldi r27, %d
ldi r30, %d
ldi r31, %d
rjmp +0x16
lpm r0, z+
st x+, r0
cpi r26, %d
cpc r27, r17
brne 0x2
''' % (data_end_hi8, data_start_lo8, data_start_hi8,
data_load_start_lo8, data_load_start_hi8, data_end_lo8)
# TODO: should not be hardcoded to 0x8c
# we are assuming that 0x8c is end of orginal __do_copy_data and start of __do_clear_bss
patches.insert(
0,
InsertCodePatch(0x8c,
code=do_copy_data_code,
name="__do_copy_data",
priority=1000))
# 2) AddCodePatch
# resolving symbols
current_symbol_pos = self.get_current_code_position()
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
code_len = len(
self.compile_c(patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags))
else:
code_len = len(
self.compile_asm(patch.asm_code, current_symbol_pos))
if patch.name is not None:
self.name_map[patch.name] = current_symbol_pos
current_symbol_pos += code_len
# now compile for real
self.added_code = b""
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
new_code = self.compile_c(
patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags)
else:
new_code = self.compile_asm(patch.asm_code, self.name_map)
self.added_code += new_code
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 4) InlinePatch
# we assume the patch never patches the added code
for patch in patches:
if isinstance(patch, InlinePatch):
new_code = self.compile_asm(patch.new_asm, self.name_map)
file_offset = self.project.loader.main_object.addr_to_offset(
patch.instruction_addr)
self.ncontent = utils.bytes_overwrite(self.ncontent, new_code,
file_offset)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 5) InsertCodePatch
# these patches specify an address in some basic block, In general we will move the basic block
# and fix relative offsets
# With this backend heer we can fail applying a patch, in case, resolve dependencies
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches = sorted(insert_code_patches,
key=lambda x: -1 * x.priority)
applied_patches = []
while True:
name_list = [
str(p) if (p is None or p.name is None) else p.name
for p in applied_patches
]
l.info("applied_patches is: |%s|", "-".join(name_list))
assert all(a == b
for a, b in zip(applied_patches, insert_code_patches))
for patch in insert_code_patches[len(applied_patches):]:
self.save_state(applied_patches)
try:
l.info("Trying to add patch: %s", str(patch))
if patch.name is not None:
self.name_map[
patch.name] = self.get_current_code_position()
new_code = self.insert_detour(patch)
self.added_code += new_code
applied_patches.append(patch)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
except (DetourException, MissingBlockException,
DoubleDetourException) as e:
l.warning(e)
insert_code_patches, removed = self.handle_remove_patch(
insert_code_patches, patch)
#print map(str,removed)
applied_patches = self.restore_state(
applied_patches, removed)
l.warning(
"One patch failed, rolling back InsertCodePatch patches. Failed patch: %s",
str(patch))
break
# TODO: right now rollback goes back to 0 patches, we may want to go back less
# the solution is to save touched_bytes and ncontent indexed by applied patfch
# and go back to the biggest compatible list of patches
else:
break #at this point we applied everything in current insert_code_patches
# TODO symbol name, for now no name_map for InsertCode patches
self.ncontent = self.insert_bytes(self.ncontent, self.added_code,
self.added_code_file_start)
# Modifiy sections if needed
if (len(self.added_data) + len(self.added_code) > 0):
# update ELF header
current_Ehdr = self.structs.Elf_Ehdr.parse(self.ncontent)
current_Ehdr['e_shoff'] += len(self.added_code) + len(
self.added_data)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Ehdr.build(current_Ehdr), 0)
# update section headers
current_Shdr_index = -1
for section in self.sections:
current_Shdr_index += 1
current_Shdr = section.header
if section.name == ".text":
pass
elif section.name == ".data":
current_Shdr['sh_size'] += len(self.added_code) + len(
self.added_data)
current_Shdr['sh_addr'] = self.text_section_size
else:
current_Shdr['sh_offset'] += len(self.added_code) + len(
self.added_data)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Shdr.build(current_Shdr),
current_Ehdr['e_shoff'] +
current_Ehdr['e_shentsize'] * current_Shdr_index)
def apply_patches(self, patches):
# deal with stackable patches
# add stackable patches to the one with highest priority
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches_dict = defaultdict(list)
for p in insert_code_patches:
insert_code_patches_dict[p.addr].append(p)
insert_code_patches_dict_sorted = defaultdict(list)
for k, v in insert_code_patches_dict.items():
insert_code_patches_dict_sorted[k] = sorted(
v, key=lambda x: -1 * x.priority)
insert_code_patches_stackable = [
p for p in patches
if isinstance(p, InsertCodePatch) and p.stackable
]
for sp in insert_code_patches_stackable:
assert len(sp.dependencies) == 0
if sp.addr in insert_code_patches_dict_sorted:
highest_priority_at_addr = insert_code_patches_dict_sorted[
sp.addr][0]
if highest_priority_at_addr != sp:
highest_priority_at_addr.asm_code += "\n" + sp.asm_code + "\n"
patches.remove(sp)
#deal with AddLabel patches
for patch in patches:
if isinstance(patch, AddLabelPatch):
self.name_map[patch.name] = patch.addr
# check for duplicate labels, it is not very necessary for this backend
# but it is better to behave in the same way of the reassembler backend
relevant_patches = [
p for p in patches
if (isinstance(p, (AddCodePatch, InsertCodePatch)))
]
all_code = ""
for p in relevant_patches:
if isinstance(p, InsertCodePatch):
code = p.code
else:
code = p.asm_code
all_code += "\n" + code + "\n"
labels = utils.string_to_labels(all_code)
duplicates = set(x for x in labels if labels.count(x) > 1)
if len(duplicates) > 1:
raise DuplicateLabelsException(
"found duplicate assembly labels: %s" % (str(duplicates)))
for patch in patches:
if isinstance(patch, (AddEntryPointPatch, AddSegmentHeaderPatch,
SegmentHeaderPatch)):
raise NotImplementedError()
# 0) RawPatch:
for patch in patches:
if isinstance(patch, RawFilePatch):
self.ncontent = utils.bytes_overwrite(self.ncontent,
patch.data,
patch.file_addr)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RawMemPatch):
self.patch_bin(patch.addr, patch.data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
for patch in patches:
if isinstance(patch, RemoveInstructionPatch):
if patch.ins_size is None:
ins = self.read_mem_from_file(patch.ins_addr, 4)
size = self.disassemble(ins,
0,
is_thumb=self.check_if_thumb(
patch.ins_addr))[0].size
else:
size = patch.ins_size
self.patch_bin(
patch.ins_addr, b"\x00\xbf" * int(
(size + 2 - 1) / 2) if self.check_if_thumb(
patch.ins_addr) else b"\x00\xF0\x20\xE3" * int(
(size + 4 - 1) / 4))
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 1) Add{RO/RW/RWInit}DataPatch
curr_data_position = self.name_map["ADDED_DATA_START"]
for patch in patches:
if isinstance(
patch,
(AddRWDataPatch, AddRODataPatch, AddRWInitDataPatch)):
if hasattr(patch, "data"):
final_patch_data = patch.data
else:
final_patch_data = b"\x00" * patch.len
self.added_data += final_patch_data
if patch.name is not None:
self.name_map[patch.name] = curr_data_position
curr_data_position += len(final_patch_data)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
if ((len(self.added_data) + self.added_data_file_start) % 2 == 1):
self.added_data += b"\x00"
self.ncontent = self.insert_bytes(self.ncontent, self.added_data,
self.added_data_file_start)
self.added_code_file_start = self.added_data_file_start + len(
self.added_data)
self.name_map.force_insert(
"ADDED_CODE_START",
self.name_map['ADDED_DATA_START'] + len(self.added_data))
# 2) AddCodePatch
# resolving symbols
current_symbol_pos = self.get_current_code_position()
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
code_len = len(
self.compile_c(patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags,
is_thumb=patch.is_thumb))
else:
code_len = len(
self.compile_asm(patch.asm_code,
current_symbol_pos,
is_thumb=patch.is_thumb))
if patch.name is not None:
self.name_map[patch.name] = current_symbol_pos
current_symbol_pos += code_len
# now compile for real
for patch in patches:
if isinstance(patch, AddCodePatch):
if patch.is_c:
new_code = self.compile_c(
patch.asm_code,
optimization=patch.optimization,
compiler_flags=patch.compiler_flags,
is_thumb=patch.is_thumb)
else:
new_code = self.compile_asm(
patch.asm_code,
self.get_current_code_position(),
self.name_map,
is_thumb=patch.is_thumb)
self.added_code += new_code
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 4) InlinePatch
# we assume the patch never patches the added code
for patch in patches:
if isinstance(patch, InlinePatch):
new_code = self.compile_asm(patch.new_asm,
patch.instruction_addr,
self.name_map,
is_thumb=self.check_if_thumb(
patch.instruction_addr))
# Limiting the inline patch to a single block is not necessary
# assert len(new_code) <= self.project.factory.block(patch.instruction_addr, num_inst=patch.num_instr, max_size=).size
file_offset = self.project.loader.main_object.addr_to_offset(
patch.instruction_addr)
self.ncontent = utils.bytes_overwrite(self.ncontent, new_code,
file_offset)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
# 5) InsertCodePatch
# these patches specify an address in some basic block, In general we will move the basic block
# and fix relative offsets
# With this backend heer we can fail applying a patch, in case, resolve dependencies
insert_code_patches = [
p for p in patches if isinstance(p, InsertCodePatch)
]
insert_code_patches = sorted(insert_code_patches,
key=lambda x: -1 * x.priority)
applied_patches = []
while True:
name_list = [
str(p) if (p is None or p.name is None) else p.name
for p in applied_patches
]
l.info("applied_patches is: |%s|", "-".join(name_list))
assert all(a == b
for a, b in zip(applied_patches, insert_code_patches))
for patch in insert_code_patches[len(applied_patches):]:
self.save_state(applied_patches)
try:
l.info("Trying to add patch: %s", str(patch))
if patch.name is not None:
self.name_map[
patch.name] = self.get_current_code_position()
new_code = self.insert_detour(patch)
self.added_code += new_code
applied_patches.append(patch)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
except (DetourException, MissingBlockException,
DoubleDetourException) as e:
l.warning(e)
insert_code_patches, removed = self.handle_remove_patch(
insert_code_patches, patch)
#print map(str,removed)
applied_patches = self.restore_state(
applied_patches, removed)
l.warning(
"One patch failed, rolling back InsertCodePatch patches. Failed patch: %s",
str(patch))
break
# TODO: right now rollback goes back to 0 patches, we may want to go back less
# the solution is to save touched_bytes and ncontent indexed by applied patfch
# and go back to the biggest compatible list of patches
else:
break #at this point we applied everything in current insert_code_patches
# TODO symbol name, for now no name_map for InsertCode patches
# 5.5) ReplaceFunctionPatch
for patch in patches:
if isinstance(patch, ReplaceFunctionPatch):
l.warning(
"ReplaceFunctionPatch: ARM/Thumb interworking is not yet supported."
)
is_thumb = self.check_if_thumb(patch.addr)
patch.addr = patch.addr - (patch.addr % 2)
new_code = self.compile_function(
patch.asm_code,
compiler_flags="-fPIE"
if self.project.loader.main_object.pic else "",
is_thumb=is_thumb,
entry=patch.addr,
symbols=patch.symbols)
file_offset = self.project.loader.main_object.addr_to_offset(
patch.addr)
self.ncontent = utils.bytes_overwrite(
self.ncontent,
(b"\x00\xBF" * (patch.size // 2)) if is_thumb else
(b"\x00\xF0\x20\xE3" * (patch.size // 4)), file_offset)
if (patch.size >= len(new_code)):
file_offset = self.project.loader.main_object.addr_to_offset(
patch.addr)
self.ncontent = utils.bytes_overwrite(
self.ncontent, new_code, file_offset)
else:
detour_pos = self.get_current_code_position()
offset = self.project.loader.main_object.mapped_base if self.project.loader.main_object.pic else 0
new_code = self.compile_function(
patch.asm_code,
compiler_flags="-fPIE"
if self.project.loader.main_object.pic else "",
is_thumb=is_thumb,
entry=detour_pos + offset,
symbols=patch.symbols)
self.added_code += new_code
# compile jmp
jmp_code = self.compile_jmp(patch.addr,
detour_pos + offset,
is_thumb=is_thumb)
self.patch_bin(patch.addr, jmp_code)
self.added_patches.append(patch)
l.info("Added patch: %s", str(patch))
self.ncontent = self.insert_bytes(self.ncontent, self.added_code,
self.added_code_file_start)
# Modifiy sections and 3rd LOAD segment if needed
if (len(self.added_data) + len(self.added_code) > 0):
# update ELF header
current_Ehdr = self.structs.Elf_Ehdr.parse(self.ncontent)
current_Ehdr['e_shoff'] += len(self.added_code) + len(
self.added_data)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Ehdr.build(current_Ehdr), 0)
# update section headers
current_Shdr_index = -1
for section in self.sections:
current_Shdr_index += 1
current_Shdr = section.header
if current_Shdr['sh_offset'] >= self.added_data_file_start:
current_Shdr['sh_offset'] += len(self.added_code) + len(
self.added_data)
elif section.name == ".data":
current_Shdr['sh_size'] += len(self.added_code) + len(
self.added_data)
else:
pass
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Shdr.build(current_Shdr),
current_Ehdr['e_shoff'] +
current_Ehdr['e_shentsize'] * current_Shdr_index)
# update 2nd & 3rd segment header
current_Phdr = self.modded_segments[1]
current_Phdr['p_filesz'] += len(self.added_code) + len(
self.added_data)
current_Phdr['p_memsz'] += len(self.added_code) + len(
self.added_data)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(current_Phdr),
current_Ehdr['e_phoff'] + current_Ehdr['e_phentsize'] * 1)
current_Phdr = self.modded_segments[2]
current_Phdr['p_offset'] += len(self.added_code) + len(
self.added_data)
current_Phdr['p_vaddr'] += len(self.added_code) + len(
self.added_data)
current_Phdr['p_paddr'] += len(self.added_code) + len(
self.added_data)
self.ncontent = utils.bytes_overwrite(
self.ncontent, self.structs.Elf_Phdr.build(current_Phdr),
current_Ehdr['e_phoff'] + current_Ehdr['e_phentsize'] * 2)
