def test_setdata(self):
ef = DataElfSegment()
data = ByteArray("foo")
ef.set_data(data)
self.assertEqual(ef.get_file_data(), data)
ef = SectionedElfSegment(sections=[])
self.assertRaises(InvalidArgument, ef.set_data, data)
def test_getmemsz(self):
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.get_memsz)
data = ByteArray()
data.memsz = 10
seg.set_data(data)
self.assertEquals(seg.get_memsz(), 10)
seg = HeaderElfSegment()
self.assertRaises(Unprepared, seg.get_memsz)
def test_get_program_header(self):
data = ByteArray()
data.memsz = 0
seg = DataElfSegment(data=data)
self.assertRaises(Unprepared, seg.get_program_header, "<", 32)
seg.prepare(0)
self.assertRaises(InvalidArgument, seg.get_program_header, "<", 33)
self.assertRaises(InvalidArgument, seg.get_program_header, "ads", 32)
ph = seg.get_program_header("<", 32)
self.assertEquals(ph.todata(), Elf32ProgramHeader("<").todata())
def test_get_program_header(self):
data = ByteArray()
data.memsz = 0
seg = DataElfSegment(None, data = data)
self.assertRaises(Unprepared, seg.get_program_header, '<', 32)
seg.prepare(0)
self.assertRaises(InvalidArgument, seg.get_program_header, '<', 33)
self.assertRaises(InvalidArgument, seg.get_program_header, 'ads', 32)
ph = seg.get_program_header('<', 32)
self.assertEquals(ph.todata(), Elf32ProgramHeader('<').todata())
def test_prepare(self):
ef = DataElfSegment()
ef.prepare(37)
self.assertEqual(ef.prepared, True)
self.assertEqual(ef.offset, 37)
self.assertRaises(InvalidArgument, ef.prepare, 12)
ef = DataElfSegment()
self.assertRaises(InvalidArgument, ef.prepare, 37, 12)
ef = HeaderElfSegment()
self.assertRaises(InvalidArgument, ef.prepare, 12)
ef.prepare(37, 12)
self.assertEqual(ef.get_memsz(), 12)
self.assertEqual(ef.offset, 37)
def test_get_file_data(self):
ef = SectionedElfSegment(sections=[])
self.assertRaises(InvalidArgument, ef.get_file_data)
data = ByteArray("pants")
ef = DataElfSegment(data=data)
self.assertEqual(ef.get_file_data(), data)
def _get_segments(self):
elf_file = UnpreparedElfFile()
sections = [UnpreparedElfSection(elf_file, "test1", data=ByteArray("test1 data")),
UnpreparedElfSection(elf_file, "test2", data=ByteArray("test2 data"))]
empty_sec_seg = SectionedElfSegment(None)
full_sec_seg = SectionedElfSegment(elf_file, sections=sections)
head_seg = HeaderElfSegment(None)
prep_head_seg = HeaderElfSegment(None)
prep_head_seg.prepare(37, PROG_HEADER_SIZE)
data = ByteArray("pants")
full_data_seg = DataElfSegment(None, vaddr=DATA_BASE, paddr=PHYS_BASE, data=data)
nobits_data_seg = DataElfSegment(None, vaddr=DATA_BASE, paddr=PHYS_BASE, data=data, memsz=10)
return empty_sec_seg, full_sec_seg, head_seg, prep_head_seg, full_data_seg, nobits_data_seg
def test_getfilesz(self):
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.get_filesz)
data = ByteArray("1234567890")
data.memsz = 10
seg.set_data(data)
self.assertEquals(seg.get_filesz(), 10)
seg = HeaderElfSegment()
self.assertRaises(Unprepared, seg.get_filesz)
seg = SectionedElfSegment()
self.assertEqual(seg.get_filesz(), 0)
def test_get_section(self):
ef = SectionedElfSegment(sections=[])
self.assertEquals(ef.get_sections(), [])
data = ByteArray("pants")
ef = DataElfSegment(data=data)
self.assertRaises(InvalidArgument, ef.get_sections)
seg = HeaderElfSegment()
self.assertRaises(InvalidArgument, seg.get_sections)
def test_has_sections(self):
seg = DataElfSegment()
self.assertEquals(seg.has_sections(), False)
seg = SectionedElfSegment(sections=[])
self.assertEquals(seg.has_sections(), True)
seg = HeaderElfSegment()
self.assertEquals(seg.has_sections(), False)
def test_add_section(self):
ef = UnpreparedElfFile()
sect = UnpreparedElfSection()
ef.add_section(sect)
self.assertEqual(ef.sections[-1], sect)
seg = HeaderElfSegment()
self.assertRaises(InvalidArgument, seg.add_section, sect)
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.add_section, sect)
def test_add_section(self):
seg = DataElfSegment()
data = ByteArray("foo")
seg.set_data(data)
section = UnpreparedElfSection()
self.assertRaises(InvalidArgument, seg.add_section, section)
seg = SectionedElfSegment()
seg.add_section(section)
self.assertEqual(section in seg.sections, True)
def test_prepare(self):
ef = DataElfSegment()
ef.prepare(37)
self.assertEqual(ef.prepared, True)
self.assertEqual(ef.offset, 37)
self.assertRaises(InvalidArgument, ef.prepare, 12)
ef = DataElfSegment()
self.assertRaises(InvalidArgument, ef.prepare, 37, 12)
ef = HeaderElfSegment()
self.assertRaises(InvalidArgument, ef.prepare, 12)
ef.prepare(37, 12)
self.assertEqual(ef.get_memsz(), 12)
self.assertEqual(ef.offset, 37)
def test_setdata(self):
ef = DataElfSegment()
data = ByteArray("foo")
ef.set_data(data)
self.assertEqual(ef.get_file_data(), data)
ef = SectionedElfSegment(sections=[])
self.assertRaises(InvalidArgument, ef.set_data, data)
def test_getfilesz(self):
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.get_filesz)
data = ByteArray("1234567890")
data.memsz = 10
seg.set_data(data)
self.assertEquals(seg.get_filesz(), 10)
seg = HeaderElfSegment()
self.assertRaises(Unprepared, seg.get_filesz)
seg = SectionedElfSegment()
self.assertEqual(seg.get_filesz(), 0)
def test_has_sections(self):
seg = DataElfSegment()
self.assertEquals(seg.has_sections(), False)
seg = SectionedElfSegment(sections=[])
self.assertEquals(seg.has_sections(), True)
seg = HeaderElfSegment()
self.assertEquals(seg.has_sections(), False)
def test_getmemsz(self):
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.get_memsz)
data = ByteArray()
data.memsz = 10
seg.set_data(data)
self.assertEquals(seg.get_memsz(), 10)
seg = HeaderElfSegment()
self.assertRaises(Unprepared, seg.get_memsz)
def test_add_section(self):
seg = DataElfSegment()
data = ByteArray("foo")
seg.set_data(data)
section = UnpreparedElfSection()
self.assertRaises(InvalidArgument, seg.add_section, section)
seg = SectionedElfSegment()
seg.add_section(section)
self.assertEqual(section in seg.sections, True)
def test_copy_into(self):
elf_from = UnpreparedElfFile()
elf_to = UnpreparedElfFile()
seg = DataElfSegment(elf_from, ByteArray("pants"))
new_seg = seg.copy_into(elf_to)
seg = SectionedElfSegment(elf_from)
seg.sections = [UnpreparedElfSection(elf_from, "test")]
new_seg = seg.copy_into(elf_to)
seg = DataElfSegment(elf_from, ByteArray("pants"))
seg._data = ByteArray()
new_seg = seg.copy_into(elf_to)
seg = DataElfSegment(elf_from, ByteArray("pants"))
seg.prepare(34)
new_seg = seg.copy_into(elf_to)
seg = HeaderElfSegment(elf_from)
new_seg = seg.copy_into(elf_to)
def test_copy(self):
seg = DataElfSegment()
new_seg = seg.copy()
seg = SectionedElfSegment()
seg.sections = [UnpreparedElfSection("test")]
new_seg = seg.copy()
seg = DataElfSegment()
seg._data = ByteArray()
new_seg = seg.copy()
seg = DataElfSegment()
seg.prepare(34)
new_seg = seg.copy()
seg = HeaderElfSegment()
new_Seg = seg.copy()
def test_add_segment(self):
ef = UnpreparedElfFile()
seg = DataElfSegment(None, data=ByteArray("pants"))
ef.add_segment(seg)
self.assertEqual(ef.segments[-1], seg)
def _initialise_segments(self, hdr, f, prepare):
"""Initialise instance from program headers."""
# Now load all the program headers
#
# "The time has come," the developer said, "to talk of many
# things: Of section to segment mapping and scatter load, of
# cabbages and kings, and why the RVCT linker is on drugs and
# whether pigs have wings."
#
# There are two ways of determining which sections belong in a
# segment:
#
# 1) In most cases a section is in a segment if its virtual
# address range falls in the virtual address range of the
# segment. These segments tend to contain multiple
# PROGBITS sections and may end with a NOBITS section.
#
# 2) In the case of segments build with RVCT's scatter load
# support the virtual address of the included sections can
# be anywhere in memory. In this case a section is in the
# segment if its data file offset falls in the offset range
# of the segment. These segments can contain multiple
# PROGBITS and NOBITS sections in any order. The file size
# of the segment is the filesize of all of the PROGBITS
# sections. The memory size of the segment is the sum of
# the size of all of the sections, not the difference
# between the lowest and highest virtual addresses.
#
# Some other things about ELF files that you need to know:
#
# a) Segments can overlap, and sections can appear in multiple
# segments.
#
# b) Some sections do not appear in any segments. These tend
# to be the symbol table and other debugging data.
#
# c) The offsets of NOBITS sections tend to be the same as the
# offset for the next PROGBITS section, even if it is in
# the next segment. However, sometimes NOBITS sections
# appear at the beginning of a segment.
#
# d) The address offset from the start of a segment and the
# file offset from the start of the segment are not
# necessarily the same.
#
# Therefore, to map sections to segments involves two passes:
#
# 1) Find all of the sections that fall in the segment virtual
# address range.
#
# 2) Find all of the remaining sections that fall in the file
# offset range. If any are found then mark the segment as
# a scatter-load segment.
#
# The file size and memory size of a segment depends on
# whether or not it is a scatter load segment. For scatter
# load files, the section that has the latest offset from the
# beginning of the section is used, while for non-scatter-load
# segments, the section with the largest virtual address is
# used.
#
# File offsets cannot be used for both types of segments
# because broken linkers can produce sections with
# inconsistant virtual address to file offset mappings and
# this will make elfweaver produce segments with incorrect
# file sizes or memory sizes.
#
# "O Readers," said the developer, "You've had a pleasant run!
# Shall we start the code again?" But answer came there none--
# And this was scarcely odd, because no-one would read this far
# for fun.
phoff = hdr.e_phoff
self._ph_offset = phoff
self.segments = []
# Short circuit the return.
if hdr.e_phoff == 0:
return
ph_list = self._get_headers(hdr, f, ELF_PH_CLASSES, hdr.e_phoff, hdr.e_phentsize, hdr.e_phnum)
phentsize = hdr.e_phentsize
sheaders = self._get_section_headers(hdr, f)
for ph in ph_list:
# Map segments to sections, pass 1.
if ph.p_type != PT_PHDR:
sects = []
for (section, sh) in zip(self.sections, sheaders):
# See if the section's virtual address range falls within
# the virtual address range of the segment.
low = ph.p_vaddr
high = low + ph.p_memsz
addr = section.address
if low <= addr < high and addr + section.get_size() <= high:
section.set_in_segment_offset(sh.sh_offset - ph.p_offset)
sects.append(section)
if sects == []:
data = f.get_data(ph.p_offset, ph.p_filesz)
data.memsz = ph.p_memsz
es = DataElfSegment(ph=ph, data=data)
else:
es = SectionedElfSegment(ph=ph, sections=sects)
else:
es = HeaderElfSegment(ph=ph)
self.segments.append(es)
# Map segments to sections, pass 2
for ph, es in zip(ph_list, self.segments):
if ph.p_type != PT_PHDR:
for (section, sh) in zip(self.sections, sheaders):
# Scatter-load sections do not appear in
# multiple segments, so skip sections that
# are already in some segment.
if section.is_in_segment():
continue
# See if the section's file offset range
# falls within the file offset range of
# the segment. Remember that the trailing
# BSS section can have the offset of the
# next section
if ph.p_offset <= sh.sh_offset <= ph.p_offset + ph.p_filesz and (
(section.type == SHT_NOBITS and sh.sh_offset != ph.p_offset)
or (
section.type != SHT_NOBITS
and section.get_size() > 0
and sh.sh_offset + section.get_size() <= ph.p_offset + ph.p_filesz
)
):
section.set_in_segment_offset(sh.sh_offset - ph.p_offset)
es.add_section(section)
es.set_scatter_load()
prog_header_size = None
else:
prog_header_size = phentsize * hdr.e_phnum
# Now mark the segment as prepared.
if prepare:
es.prepare(ph.p_offset, prog_header_size)
def test_remove_nobits(self):
seg = DataElfSegment()
self.assertRaises(InvalidArgument, seg.remove_nobits)
def _initialise_segments(self, hdr, f, prepare):
"""Initialise instance from program headers."""
# Now load all the program headers
#
# "The time has come," the developer said, "to talk of many
# things: Of section to segment mapping and scatter load, of
# cabbages and kings, and why the RVCT linker is on drugs and
# whether pigs have wings."
#
# There are two ways of determining which sections belong in a
# segment:
#
# 1) In most cases a section is in a segment if its virtual
# address range falls in the virtual address range of the
# segment. These segments tend to contain multiple
# PROGBITS sections and may end with a NOBITS section.
#
# 2) In the case of segments build with RVCT's scatter load
# support the virtual address of the included sections can
# be anywhere in memory. In this case a section is in the
# segment if its data file offset falls in the offset range
# of the segment. These segments can contain multiple
# PROGBITS and NOBITS sections in any order. The file size
# of the segment is the filesize of all of the PROGBITS
# sections. The memory size of the segment is the sum of
# the size of all of the sections, not the difference
# between the lowest and highest virtual addresses.
#
# Some other things about ELF files that you need to know:
#
# a) Segments can overlap, and sections can appear in multiple
# segments.
#
# b) Some sections do not appear in any segments. These tend
# to be the symbol table and other debugging data.
#
# c) The offsets of NOBITS sections tend to be the same as the
# offset for the next PROGBITS section, even if it is in
# the next segment. However, sometimes NOBITS sections
# appear at the beginning of a segment.
#
# d) The address offset from the start of a segment and the
# file offset from the start of the segment are not
# necessarily the same.
#
# Therefore, to map sections to segments involves two passes:
#
# 1) Find all of the sections that fall in the segment virtual
# address range.
#
# 2) Find all of the remaining sections that fall in the file
# offset range. If any are found then mark the segment as
# a scatter-load segment.
#
# The file size and memory size of a segment depends on
# whether or not it is a scatter load segment. For scatter
# load files, the section that has the latest offset from the
# beginning of the section is used, while for non-scatter-load
# segments, the section with the largest virtual address is
# used.
#
# File offsets cannot be used for both types of segments
# because broken linkers can produce sections with
# inconsistant virtual address to file offset mappings and
# this will make elfweaver produce segments with incorrect
# file sizes or memory sizes.
#
# "O Readers," said the developer, "You've had a pleasant run!
# Shall we start the code again?" But answer came there none--
# And this was scarcely odd, because no-one would read this far
# for fun.
phoff = hdr.e_phoff
self._ph_offset = phoff
self.segments = []
# Short circuit the return.
if hdr.e_phoff == 0:
return
ph_list = self._get_headers(hdr, f, ELF_PH_CLASSES, hdr.e_phoff,
hdr.e_phentsize, hdr.e_phnum)
phentsize = hdr.e_phentsize
sheaders = self._get_section_headers(hdr, f)
for ph in ph_list:
# Map segments to sections, pass 1.
if ph.p_type != PT_PHDR:
sects = []
for (section, sh) in zip(self.sections, sheaders):
# See if the section's virtual address range falls within
# the virtual address range of the segment.
low = ph.p_vaddr
high = low + ph.p_memsz
addr = section.address
if low <= addr < high and addr + section.get_size() <= high:
section.set_in_segment_offset(sh.sh_offset -
ph.p_offset)
sects.append(section)
if sects == []:
data = f.get_data(ph.p_offset, ph.p_filesz)
data.memsz = ph.p_memsz
es = DataElfSegment(ph=ph, data=data)
else:
es = SectionedElfSegment(ph=ph, sections=sects)
else:
es = HeaderElfSegment(ph=ph)
self.segments.append(es)
# Map segments to sections, pass 2
for ph, es in zip(ph_list, self.segments):
if ph.p_type != PT_PHDR:
for (section, sh) in zip(self.sections, sheaders):
# Scatter-load sections do not appear in
# multiple segments, so skip sections that
# are already in some segment.
if section.is_in_segment():
continue
# See if the section's file offset range
# falls within the file offset range of
# the segment. Remember that the trailing
# BSS section can have the offset of the
# next section
if ph.p_offset <= sh.sh_offset <= ph.p_offset + ph.p_filesz and \
((section.type == SHT_NOBITS and sh.sh_offset != ph.p_offset) or \
(section.type != SHT_NOBITS and section.get_size() > 0 and \
sh.sh_offset + section.get_size() <= ph.p_offset + ph.p_filesz)):
section.set_in_segment_offset(sh.sh_offset -
ph.p_offset)
es.add_section(section)
es.set_scatter_load()
prog_header_size = None
else:
prog_header_size = phentsize * hdr.e_phnum
# Now mark the segment as prepared.
if prepare:
es.prepare(ph.p_offset, prog_header_size)
def test_copy(self):
seg = DataElfSegment()
new_seg = seg.copy()
seg = SectionedElfSegment()
seg.sections = [UnpreparedElfSection("test")]
new_seg = seg.copy()
seg = DataElfSegment()
seg._data = ByteArray()
new_seg = seg.copy()
seg = DataElfSegment()
seg.prepare(34)
new_seg = seg.copy()
seg = HeaderElfSegment()
new_Seg = seg.copy()
