tools/binman/elf.py - platform/external/u-boot - Gitiles

 # SPDX-License-Identifier: GPL-2.0+
 # Copyright (c) 2016 Google, Inc
 # Written by Simon Glass <sjg@chromium.org>
 #
 # Handle various things related to ELF images
 #

 from collections import namedtuple, OrderedDict
 import io
 import os
 import re
 import shutil
 import struct
 import tempfile

 from patman import command
 from patman import tools
 from patman import tout

 ELF_TOOLS = True
 try:
     from elftools.elf.elffile import ELFFile
     from elftools.elf.elffile import ELFError
     from elftools.elf.sections import SymbolTableSection
 except:  # pragma: no cover
     ELF_TOOLS = False

 # BSYM in little endian, keep in sync with include/binman_sym.h
 BINMAN_SYM_MAGIC_VALUE = 0x4d595342

 # Information about an EFL symbol:
 # section (str): Name of the section containing this symbol
 # address (int): Address of the symbol (its value)
 # size (int): Size of the symbol in bytes
 # weak (bool): True if the symbol is weak
 # offset (int or None): Offset of the symbol's data in the ELF file, or None if
 #   not known
 Symbol = namedtuple('Symbol', ['section', 'address', 'size', 'weak', 'offset'])

 # Information about an ELF file:
 #    data: Extracted program contents of ELF file (this would be loaded by an
 #           ELF loader when reading this file
 #    load: Load address of code
 #    entry: Entry address of code
 #    memsize: Number of bytes in memory occupied by loading this ELF file
 ElfInfo = namedtuple('ElfInfo', ['data', 'load', 'entry', 'memsize'])


 def GetSymbols(fname, patterns):
     """Get the symbols from an ELF file

     Args:
         fname: Filename of the ELF file to read
         patterns: List of regex patterns to search for, each a string

     Returns:
         None, if the file does not exist, or Dict:
           key: Name of symbol
           value: Hex value of symbol
     """
     stdout = tools.run('objdump', '-t', fname)
     lines = stdout.splitlines()
     if patterns:
         re_syms = re.compile('|'.join(patterns))
     else:
         re_syms = None
     syms = {}
     syms_started = False
     for line in lines:
         if not line or not syms_started:
             if 'SYMBOL TABLE' in line:
                 syms_started = True
             line = None  # Otherwise code coverage complains about 'continue'
             continue
         if re_syms and not re_syms.search(line):
             continue

         space_pos = line.find(' ')
         value, rest = line[:space_pos], line[space_pos + 1:]
         flags = rest[:7]
         parts = rest[7:].split()
         section, size =  parts[:2]
         if len(parts) > 2:
             name = parts[2] if parts[2] != '.hidden' else parts[3]
             syms[name] = Symbol(section, int(value, 16), int(size, 16),
                                 flags[1] == 'w', None)

     # Sort dict by address
     return OrderedDict(sorted(syms.items(), key=lambda x: x[1].address))

 def _GetFileOffset(elf, addr):
     """Get the file offset for an address

     Args:
         elf (ELFFile): ELF file to check
         addr (int): Address to search for

     Returns
         int: Offset of that address in the ELF file, or None if not valid
     """
     for seg in elf.iter_segments():
         seg_end = seg['p_vaddr'] + seg['p_filesz']
         if seg.header['p_type'] == 'PT_LOAD':
             if addr >= seg['p_vaddr'] and addr < seg_end:
                 return addr - seg['p_vaddr'] + seg['p_offset']

 def GetFileOffset(fname, addr):
     """Get the file offset for an address

     Args:
         fname (str): Filename of ELF file to check
         addr (int): Address to search for

     Returns
         int: Offset of that address in the ELF file, or None if not valid
     """
     if not ELF_TOOLS:
         raise ValueError("Python: No module named 'elftools'")
     with open(fname, 'rb') as fd:
         elf = ELFFile(fd)
         return _GetFileOffset(elf, addr)

 def GetSymbolFromAddress(fname, addr):
     """Get the symbol at a particular address

     Args:
         fname (str): Filename of ELF file to check
         addr (int): Address to search for

     Returns:
         str: Symbol name, or None if no symbol at that address
     """
     if not ELF_TOOLS:
         raise ValueError("Python: No module named 'elftools'")
     with open(fname, 'rb') as fd:
         elf = ELFFile(fd)
         syms = GetSymbols(fname, None)
     for name, sym in syms.items():
         if sym.address == addr:
             return name

 def GetSymbolFileOffset(fname, patterns):
     """Get the symbols from an ELF file

     Args:
         fname: Filename of the ELF file to read
         patterns: List of regex patterns to search for, each a string

     Returns:
         None, if the file does not exist, or Dict:
           key: Name of symbol
           value: Hex value of symbol
     """
     if not ELF_TOOLS:
         raise ValueError("Python: No module named 'elftools'")

     syms = {}
     with open(fname, 'rb') as fd:
         elf = ELFFile(fd)

         re_syms = re.compile('|'.join(patterns))
         for section in elf.iter_sections():
             if isinstance(section, SymbolTableSection):
                 for symbol in section.iter_symbols():
                     if not re_syms or re_syms.search(symbol.name):
                         addr = symbol.entry['st_value']
                         syms[symbol.name] = Symbol(
                             section.name, addr, symbol.entry['st_size'],
                             symbol.entry['st_info']['bind'] == 'STB_WEAK',
                             _GetFileOffset(elf, addr))

     # Sort dict by address
     return OrderedDict(sorted(syms.items(), key=lambda x: x[1].address))

 def GetSymbolAddress(fname, sym_name):
     """Get a value of a symbol from an ELF file

     Args:
         fname: Filename of the ELF file to read
         patterns: List of regex patterns to search for, each a string

     Returns:
         Symbol value (as an integer) or None if not found
     """
     syms = GetSymbols(fname, [sym_name])
     sym = syms.get(sym_name)
     if not sym:
         return None
     return sym.address

 def GetPackString(sym, msg):
     """Get the struct.pack/unpack string to use with a given symbol

     Args:
         sym (Symbol): Symbol to check. Only the size member is checked
         @msg (str): String which indicates the entry being processed, used for
             errors

     Returns:
         str: struct string to use, .e.g. '<I'

     Raises:
         ValueError: Symbol has an unexpected size
     """
     if sym.size == 4:
         return '<I'
     elif sym.size == 8:
         return '<Q'
     else:
         raise ValueError('%s has size %d: only 4 and 8 are supported' %
                          (msg, sym.size))

 def LookupAndWriteSymbols(elf_fname, entry, section, is_elf=False):
     """Replace all symbols in an entry with their correct values

     The entry contents is updated so that values for referenced symbols will be
     visible at run time. This is done by finding out the symbols offsets in the
     entry (using the ELF file) and replacing them with values from binman's data
     structures.

     Args:
         elf_fname: Filename of ELF image containing the symbol information for
             entry
         entry: Entry to process
         section: Section which can be used to lookup symbol values
     """
     fname = tools.get_input_filename(elf_fname)
     syms = GetSymbols(fname, ['image', 'binman'])
     if is_elf:
         if not ELF_TOOLS:
             msg = ("Section '%s': entry '%s'" %
                    (section.GetPath(), entry.GetPath()))
             raise ValueError(f'{msg}: Cannot write symbols to an ELF file without Python elftools')
         new_syms = {}
         with open(fname, 'rb') as fd:
             elf = ELFFile(fd)
             for name, sym in syms.items():
                 offset = _GetFileOffset(elf, sym.address)
                 new_syms[name] = Symbol(sym.section, sym.address, sym.size,
                                         sym.weak, offset)
             syms = new_syms

     if not syms:
         tout.debug('LookupAndWriteSymbols: no syms')
         return
     base = syms.get('__image_copy_start')
     if not base and not is_elf:
         tout.debug('LookupAndWriteSymbols: no base')
         return
     base_addr = 0 if is_elf else base.address
     for name, sym in syms.items():
         if name.startswith('_binman'):
             msg = ("Section '%s': Symbol '%s'\n   in entry '%s'" %
                    (section.GetPath(), name, entry.GetPath()))
             if is_elf:
                 # For ELF files, use the file offset
                 offset = sym.offset
             else:
                 # For blobs use the offset of the symbol, calculated by
                 # subtracting the base address which by definition is at the
                 # start
                 offset = sym.address - base.address
                 if offset < 0 or offset + sym.size > entry.contents_size:
                     raise ValueError('%s has offset %x (size %x) but the contents '
                                      'size is %x' % (entry.GetPath(), offset,
                                                      sym.size,
                                                      entry.contents_size))
             pack_string = GetPackString(sym, msg)
             if name == '_binman_sym_magic':
                 value = BINMAN_SYM_MAGIC_VALUE
             else:
                 # Look up the symbol in our entry tables.
                 value = section.GetImage().LookupImageSymbol(name, sym.weak,
                                                              msg, base_addr)
             if value is None:
                 value = -1
                 pack_string = pack_string.lower()
             value_bytes = struct.pack(pack_string, value)
             tout.debug('%s:\n   insert %s, offset %x, value %x, length %d' %
                        (msg, name, offset, value, len(value_bytes)))
             entry.data = (entry.data[:offset] + value_bytes +
                         entry.data[offset + sym.size:])

 def GetSymbolValue(sym, data, msg):
     """Get the value of a symbol

     This can only be used on symbols with an integer value.

     Args:
         sym (Symbol): Symbol to check
         data (butes): Data for the ELF file - the symbol data appears at offset
             sym.offset
         @msg (str): String which indicates the entry being processed, used for
             errors

     Returns:
         int: Value of the symbol

     Raises:
         ValueError: Symbol has an unexpected size
     """
     pack_string = GetPackString(sym, msg)
     value = struct.unpack(pack_string, data[sym.offset:sym.offset + sym.size])
     return value[0]

 def MakeElf(elf_fname, text, data):
     """Make an elf file with the given data in a single section

     The output file has a several section including '.text' and '.data',
     containing the info provided in arguments.

     Args:
         elf_fname: Output filename
         text: Text (code) to put in the file's .text section
         data: Data to put in the file's .data section
     """
     outdir = tempfile.mkdtemp(prefix='binman.elf.')
     s_file = os.path.join(outdir, 'elf.S')

     # Spilt the text into two parts so that we can make the entry point two
     # bytes after the start of the text section
     text_bytes1 = ['\t.byte\t%#x' % byte for byte in text[:2]]
     text_bytes2 = ['\t.byte\t%#x' % byte for byte in text[2:]]
     data_bytes = ['\t.byte\t%#x' % byte for byte in data]
     with open(s_file, 'w') as fd:
         print('''/* Auto-generated C program to produce an ELF file for testing */

 .section .text
 .code32
 .globl _start
 .type _start, @function
 %s
 _start:
 %s
 .ident "comment"

 .comm fred,8,4

 .section .empty
 .globl _empty
 _empty:
 .byte 1

 .globl ernie
 .data
 .type ernie, @object
 .size ernie, 4
 ernie:
 %s
 ''' % ('\n'.join(text_bytes1), '\n'.join(text_bytes2), '\n'.join(data_bytes)),
         file=fd)
     lds_file = os.path.join(outdir, 'elf.lds')

     # Use a linker script to set the alignment and text address.
     with open(lds_file, 'w') as fd:
         print('''/* Auto-generated linker script to produce an ELF file for testing */

 PHDRS
 {
     text PT_LOAD ;
     data PT_LOAD ;
     empty PT_LOAD FLAGS ( 6 ) ;
     note PT_NOTE ;
 }

 SECTIONS
 {
     . = 0xfef20000;
     ENTRY(_start)
     .text . : SUBALIGN(0)
     {
         *(.text)
     } :text
     .data : {
         *(.data)
     } :data
     _bss_start = .;
     .empty : {
         *(.empty)
     } :empty
     /DISCARD/ : {
         *(.note.gnu.property)
     }
     .note : {
         *(.comment)
     } :note
     .bss _bss_start  (OVERLAY) : {
         *(.bss)
     }
 }
 ''', file=fd)
     # -static: Avoid requiring any shared libraries
     # -nostdlib: Don't link with C library
     # -Wl,--build-id=none: Don't generate a build ID, so that we just get the
     #   text section at the start
     # -m32: Build for 32-bit x86
     # -T...: Specifies the link script, which sets the start address
     cc, args = tools.get_target_compile_tool('cc')
     args += ['-static', '-nostdlib', '-Wl,--build-id=none', '-m32', '-T',
             lds_file, '-o', elf_fname, s_file]
     stdout = command.output(cc, *args)
     shutil.rmtree(outdir)

 def DecodeElf(data, location):
     """Decode an ELF file and return information about it

     Args:
         data: Data from ELF file
         location: Start address of data to return

     Returns:
         ElfInfo object containing information about the decoded ELF file
     """
     file_size = len(data)
     with io.BytesIO(data) as fd:
         elf = ELFFile(fd)
         data_start = 0xffffffff;
         data_end = 0;
         mem_end = 0;
         virt_to_phys = 0;

         for i in range(elf.num_segments()):
             segment = elf.get_segment(i)
             if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
                 skipped = 1  # To make code-coverage see this line
                 continue
             start = segment['p_paddr']
             mend = start + segment['p_memsz']
             rend = start + segment['p_filesz']
             data_start = min(data_start, start)
             data_end = max(data_end, rend)
             mem_end = max(mem_end, mend)
             if not virt_to_phys:
                 virt_to_phys = segment['p_paddr'] - segment['p_vaddr']

         output = bytearray(data_end - data_start)
         for i in range(elf.num_segments()):
             segment = elf.get_segment(i)
             if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
                 skipped = 1  # To make code-coverage see this line
                 continue
             start = segment['p_paddr']
             offset = 0
             if start < location:
                 offset = location - start
                 start = location
             # A legal ELF file can have a program header with non-zero length
             # but zero-length file size and a non-zero offset which, added
             # together, are greater than input->size (i.e. the total file size).
             #  So we need to not even test in the case that p_filesz is zero.
             # Note: All of this code is commented out since we don't have a test
             # case for it.
             size = segment['p_filesz']
             #if not size:
                 #continue
             #end = segment['p_offset'] + segment['p_filesz']
             #if end > file_size:
                 #raise ValueError('Underflow copying out the segment. File has %#x bytes left, segment end is %#x\n',
                                  #file_size, end)
             output[start - data_start:start - data_start + size] = (
                 segment.data()[offset:])
     return ElfInfo(output, data_start, elf.header['e_entry'] + virt_to_phys,
                    mem_end - data_start)

 def UpdateFile(infile, outfile, start_sym, end_sym, insert):
     tout.notice("Creating file '%s' with data length %#x (%d) between symbols '%s' and '%s'" %
                 (outfile, len(insert), len(insert), start_sym, end_sym))
     syms = GetSymbolFileOffset(infile, [start_sym, end_sym])
     if len(syms) != 2:
         raise ValueError("Expected two symbols '%s' and '%s': got %d: %s" %
                          (start_sym, end_sym, len(syms),
                           ','.join(syms.keys())))

     size = syms[end_sym].offset - syms[start_sym].offset
     if len(insert) > size:
         raise ValueError("Not enough space in '%s' for data length %#x (%d); size is %#x (%d)" %
                          (infile, len(insert), len(insert), size, size))

     data = tools.read_file(infile)
     newdata = data[:syms[start_sym].offset]
     newdata += insert + tools.get_bytes(0, size - len(insert))
     newdata += data[syms[end_sym].offset:]
     tools.write_file(outfile, newdata)
     tout.info('Written to offset %#x' % syms[start_sym].offset)

 def read_loadable_segments(data):
     """Read segments from an ELF file

     Args:
         data (bytes): Contents of file

     Returns:
         tuple:
             list of segments, each:
                 int: Segment number (0 = first)
                 int: Start address of segment in memory
                 bytes: Contents of segment
             int: entry address for image

     Raises:
         ValueError: elftools is not available
     """
     if not ELF_TOOLS:
         raise ValueError("Python: No module named 'elftools'")
     with io.BytesIO(data) as inf:
         try:
             elf = ELFFile(inf)
         except ELFError as err:
             raise ValueError(err)
         entry = elf.header['e_entry']
         segments = []
         for i in range(elf.num_segments()):
             segment = elf.get_segment(i)
             if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
                 skipped = 1  # To make code-coverage see this line
                 continue
             start = segment['p_offset']
             rend = start + segment['p_filesz']
             segments.append((i, segment['p_paddr'], data[start:rend]))
     return segments, entry
	# SPDX-License-Identifier: GPL-2.0+
	# Copyright (c) 2016 Google, Inc
	# Written by Simon Glass <sjg@chromium.org>
	#
	# Handle various things related to ELF images
	#

	from collections import namedtuple, OrderedDict
	import io
	import os
	import re
	import shutil
	import struct
	import tempfile

	from patman import command
	from patman import tools
	from patman import tout

	ELF_TOOLS = True
	try:
	from elftools.elf.elffile import ELFFile
	from elftools.elf.elffile import ELFError
	from elftools.elf.sections import SymbolTableSection
	except: # pragma: no cover
	ELF_TOOLS = False

	# BSYM in little endian, keep in sync with include/binman_sym.h
	BINMAN_SYM_MAGIC_VALUE = 0x4d595342

	# Information about an EFL symbol:
	# section (str): Name of the section containing this symbol
	# address (int): Address of the symbol (its value)
	# size (int): Size of the symbol in bytes
	# weak (bool): True if the symbol is weak
	# offset (int or None): Offset of the symbol's data in the ELF file, or None if
	# not known
	Symbol = namedtuple('Symbol', ['section', 'address', 'size', 'weak', 'offset'])

	# Information about an ELF file:
	# data: Extracted program contents of ELF file (this would be loaded by an
	# ELF loader when reading this file
	# load: Load address of code
	# entry: Entry address of code
	# memsize: Number of bytes in memory occupied by loading this ELF file
	ElfInfo = namedtuple('ElfInfo', ['data', 'load', 'entry', 'memsize'])


	def GetSymbols(fname, patterns):
	"""Get the symbols from an ELF file

	Args:
	fname: Filename of the ELF file to read
	patterns: List of regex patterns to search for, each a string

	Returns:
	None, if the file does not exist, or Dict:
	key: Name of symbol
	value: Hex value of symbol
	"""
	stdout = tools.run('objdump', '-t', fname)
	lines = stdout.splitlines()
	if patterns:
	re_syms = re.compile('\|'.join(patterns))
	else:
	re_syms = None
	syms = {}
	syms_started = False
	for line in lines:
	if not line or not syms_started:
	if 'SYMBOL TABLE' in line:
	syms_started = True
	line = None # Otherwise code coverage complains about 'continue'
	continue
	if re_syms and not re_syms.search(line):
	continue

	space_pos = line.find(' ')
	value, rest = line[:space_pos], line[space_pos + 1:]
	flags = rest[:7]
	parts = rest[7:].split()
	section, size = parts[:2]
	if len(parts) > 2:
	name = parts[2] if parts[2] != '.hidden' else parts[3]
	syms[name] = Symbol(section, int(value, 16), int(size, 16),
	flags[1] == 'w', None)

	# Sort dict by address
	return OrderedDict(sorted(syms.items(), key=lambda x: x[1].address))

	def _GetFileOffset(elf, addr):
	"""Get the file offset for an address

	Args:
	elf (ELFFile): ELF file to check
	addr (int): Address to search for

	Returns
	int: Offset of that address in the ELF file, or None if not valid
	"""
	for seg in elf.iter_segments():
	seg_end = seg['p_vaddr'] + seg['p_filesz']
	if seg.header['p_type'] == 'PT_LOAD':
	if addr >= seg['p_vaddr'] and addr < seg_end:
	return addr - seg['p_vaddr'] + seg['p_offset']

	def GetFileOffset(fname, addr):
	"""Get the file offset for an address

	Args:
	fname (str): Filename of ELF file to check
	addr (int): Address to search for

	Returns
	int: Offset of that address in the ELF file, or None if not valid
	"""
	if not ELF_TOOLS:
	raise ValueError("Python: No module named 'elftools'")
	with open(fname, 'rb') as fd:
	elf = ELFFile(fd)
	return _GetFileOffset(elf, addr)

	def GetSymbolFromAddress(fname, addr):
	"""Get the symbol at a particular address

	Args:
	fname (str): Filename of ELF file to check
	addr (int): Address to search for

	Returns:
	str: Symbol name, or None if no symbol at that address
	"""
	if not ELF_TOOLS:
	raise ValueError("Python: No module named 'elftools'")
	with open(fname, 'rb') as fd:
	elf = ELFFile(fd)
	syms = GetSymbols(fname, None)
	for name, sym in syms.items():
	if sym.address == addr:
	return name

	def GetSymbolFileOffset(fname, patterns):
	"""Get the symbols from an ELF file

	Args:
	fname: Filename of the ELF file to read
	patterns: List of regex patterns to search for, each a string

	Returns:
	None, if the file does not exist, or Dict:
	key: Name of symbol
	value: Hex value of symbol
	"""
	if not ELF_TOOLS:
	raise ValueError("Python: No module named 'elftools'")

	syms = {}
	with open(fname, 'rb') as fd:
	elf = ELFFile(fd)

	re_syms = re.compile('\|'.join(patterns))
	for section in elf.iter_sections():
	if isinstance(section, SymbolTableSection):
	for symbol in section.iter_symbols():
	if not re_syms or re_syms.search(symbol.name):
	addr = symbol.entry['st_value']
	syms[symbol.name] = Symbol(
	section.name, addr, symbol.entry['st_size'],
	symbol.entry['st_info']['bind'] == 'STB_WEAK',
	_GetFileOffset(elf, addr))

	# Sort dict by address
	return OrderedDict(sorted(syms.items(), key=lambda x: x[1].address))

	def GetSymbolAddress(fname, sym_name):
	"""Get a value of a symbol from an ELF file

	Args:
	fname: Filename of the ELF file to read
	patterns: List of regex patterns to search for, each a string

	Returns:
	Symbol value (as an integer) or None if not found
	"""
	syms = GetSymbols(fname, [sym_name])
	sym = syms.get(sym_name)
	if not sym:
	return None
	return sym.address

	def GetPackString(sym, msg):
	"""Get the struct.pack/unpack string to use with a given symbol

	Args:
	sym (Symbol): Symbol to check. Only the size member is checked
	@msg (str): String which indicates the entry being processed, used for
	errors

	Returns:
	str: struct string to use, .e.g. '<I'

	Raises:
	ValueError: Symbol has an unexpected size
	"""
	if sym.size == 4:
	return '<I'
	elif sym.size == 8:
	return '<Q'
	else:
	raise ValueError('%s has size %d: only 4 and 8 are supported' %
	(msg, sym.size))

	def LookupAndWriteSymbols(elf_fname, entry, section, is_elf=False):
	"""Replace all symbols in an entry with their correct values

	The entry contents is updated so that values for referenced symbols will be
	visible at run time. This is done by finding out the symbols offsets in the
	entry (using the ELF file) and replacing them with values from binman's data
	structures.

	Args:
	elf_fname: Filename of ELF image containing the symbol information for
	entry
	entry: Entry to process
	section: Section which can be used to lookup symbol values
	"""
	fname = tools.get_input_filename(elf_fname)
	syms = GetSymbols(fname, ['image', 'binman'])
	if is_elf:
	if not ELF_TOOLS:
	msg = ("Section '%s': entry '%s'" %
	(section.GetPath(), entry.GetPath()))
	raise ValueError(f'{msg}: Cannot write symbols to an ELF file without Python elftools')
	new_syms = {}
	with open(fname, 'rb') as fd:
	elf = ELFFile(fd)
	for name, sym in syms.items():
	offset = _GetFileOffset(elf, sym.address)
	new_syms[name] = Symbol(sym.section, sym.address, sym.size,
	sym.weak, offset)
	syms = new_syms

	if not syms:
	tout.debug('LookupAndWriteSymbols: no syms')
	return
	base = syms.get('__image_copy_start')
	if not base and not is_elf:
	tout.debug('LookupAndWriteSymbols: no base')
	return
	base_addr = 0 if is_elf else base.address
	for name, sym in syms.items():
	if name.startswith('_binman'):
	msg = ("Section '%s': Symbol '%s'\n in entry '%s'" %
	(section.GetPath(), name, entry.GetPath()))
	if is_elf:
	# For ELF files, use the file offset
	offset = sym.offset
	else:
	# For blobs use the offset of the symbol, calculated by
	# subtracting the base address which by definition is at the
	# start
	offset = sym.address - base.address
	if offset < 0 or offset + sym.size > entry.contents_size:
	raise ValueError('%s has offset %x (size %x) but the contents '
	'size is %x' % (entry.GetPath(), offset,
	sym.size,
	entry.contents_size))
	pack_string = GetPackString(sym, msg)
	if name == '_binman_sym_magic':
	value = BINMAN_SYM_MAGIC_VALUE
	else:
	# Look up the symbol in our entry tables.
	value = section.GetImage().LookupImageSymbol(name, sym.weak,
	msg, base_addr)
	if value is None:
	value = -1
	pack_string = pack_string.lower()
	value_bytes = struct.pack(pack_string, value)
	tout.debug('%s:\n insert %s, offset %x, value %x, length %d' %
	(msg, name, offset, value, len(value_bytes)))
	entry.data = (entry.data[:offset] + value_bytes +
	entry.data[offset + sym.size:])

	def GetSymbolValue(sym, data, msg):
	"""Get the value of a symbol

	This can only be used on symbols with an integer value.

	Args:
	sym (Symbol): Symbol to check
	data (butes): Data for the ELF file - the symbol data appears at offset
	sym.offset
	@msg (str): String which indicates the entry being processed, used for
	errors

	Returns:
	int: Value of the symbol

	Raises:
	ValueError: Symbol has an unexpected size
	"""
	pack_string = GetPackString(sym, msg)
	value = struct.unpack(pack_string, data[sym.offset:sym.offset + sym.size])
	return value[0]

	def MakeElf(elf_fname, text, data):
	"""Make an elf file with the given data in a single section

	The output file has a several section including '.text' and '.data',
	containing the info provided in arguments.

	Args:
	elf_fname: Output filename
	text: Text (code) to put in the file's .text section
	data: Data to put in the file's .data section
	"""
	outdir = tempfile.mkdtemp(prefix='binman.elf.')
	s_file = os.path.join(outdir, 'elf.S')

	# Spilt the text into two parts so that we can make the entry point two
	# bytes after the start of the text section
	text_bytes1 = ['\t.byte\t%#x' % byte for byte in text[:2]]
	text_bytes2 = ['\t.byte\t%#x' % byte for byte in text[2:]]
	data_bytes = ['\t.byte\t%#x' % byte for byte in data]
	with open(s_file, 'w') as fd:
	print('''/* Auto-generated C program to produce an ELF file for testing */

	.section .text
	.code32
	.globl _start
	.type _start, @function
	%s
	_start:
	%s
	.ident "comment"

	.comm fred,8,4

	.section .empty
	.globl _empty
	_empty:
	.byte 1

	.globl ernie
	.data
	.type ernie, @object
	.size ernie, 4
	ernie:
	%s
	''' % ('\n'.join(text_bytes1), '\n'.join(text_bytes2), '\n'.join(data_bytes)),
	file=fd)
	lds_file = os.path.join(outdir, 'elf.lds')

	# Use a linker script to set the alignment and text address.
	with open(lds_file, 'w') as fd:
	print('''/* Auto-generated linker script to produce an ELF file for testing */

	PHDRS
	{
	text PT_LOAD ;
	data PT_LOAD ;
	empty PT_LOAD FLAGS ( 6 ) ;
	note PT_NOTE ;
	}

	SECTIONS
	{
	. = 0xfef20000;
	ENTRY(_start)
	.text . : SUBALIGN(0)
	{
	*(.text)
	} :text
	.data : {
	*(.data)
	} :data
	_bss_start = .;
	.empty : {
	*(.empty)
	} :empty
	/DISCARD/ : {
	*(.note.gnu.property)
	}
	.note : {
	*(.comment)
	} :note
	.bss _bss_start (OVERLAY) : {
	*(.bss)
	}
	}
	''', file=fd)
	# -static: Avoid requiring any shared libraries
	# -nostdlib: Don't link with C library
	# -Wl,--build-id=none: Don't generate a build ID, so that we just get the
	# text section at the start
	# -m32: Build for 32-bit x86
	# -T...: Specifies the link script, which sets the start address
	cc, args = tools.get_target_compile_tool('cc')
	args += ['-static', '-nostdlib', '-Wl,--build-id=none', '-m32', '-T',
	lds_file, '-o', elf_fname, s_file]
	stdout = command.output(cc, *args)
	shutil.rmtree(outdir)

	def DecodeElf(data, location):
	"""Decode an ELF file and return information about it

	Args:
	data: Data from ELF file
	location: Start address of data to return

	Returns:
	ElfInfo object containing information about the decoded ELF file
	"""
	file_size = len(data)
	with io.BytesIO(data) as fd:
	elf = ELFFile(fd)
	data_start = 0xffffffff;
	data_end = 0;
	mem_end = 0;
	virt_to_phys = 0;

	for i in range(elf.num_segments()):
	segment = elf.get_segment(i)
	if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
	skipped = 1 # To make code-coverage see this line
	continue
	start = segment['p_paddr']
	mend = start + segment['p_memsz']
	rend = start + segment['p_filesz']
	data_start = min(data_start, start)
	data_end = max(data_end, rend)
	mem_end = max(mem_end, mend)
	if not virt_to_phys:
	virt_to_phys = segment['p_paddr'] - segment['p_vaddr']

	output = bytearray(data_end - data_start)
	for i in range(elf.num_segments()):
	segment = elf.get_segment(i)
	if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
	skipped = 1 # To make code-coverage see this line
	continue
	start = segment['p_paddr']
	offset = 0
	if start < location:
	offset = location - start
	start = location
	# A legal ELF file can have a program header with non-zero length
	# but zero-length file size and a non-zero offset which, added
	# together, are greater than input->size (i.e. the total file size).
	# So we need to not even test in the case that p_filesz is zero.
	# Note: All of this code is commented out since we don't have a test
	# case for it.
	size = segment['p_filesz']
	#if not size:
	#continue
	#end = segment['p_offset'] + segment['p_filesz']
	#if end > file_size:
	#raise ValueError('Underflow copying out the segment. File has %#x bytes left, segment end is %#x\n',
	#file_size, end)
	output[start - data_start:start - data_start + size] = (
	segment.data()[offset:])
	return ElfInfo(output, data_start, elf.header['e_entry'] + virt_to_phys,
	mem_end - data_start)

	def UpdateFile(infile, outfile, start_sym, end_sym, insert):
	tout.notice("Creating file '%s' with data length %#x (%d) between symbols '%s' and '%s'" %
	(outfile, len(insert), len(insert), start_sym, end_sym))
	syms = GetSymbolFileOffset(infile, [start_sym, end_sym])
	if len(syms) != 2:
	raise ValueError("Expected two symbols '%s' and '%s': got %d: %s" %
	(start_sym, end_sym, len(syms),
	','.join(syms.keys())))

	size = syms[end_sym].offset - syms[start_sym].offset
	if len(insert) > size:
	raise ValueError("Not enough space in '%s' for data length %#x (%d); size is %#x (%d)" %
	(infile, len(insert), len(insert), size, size))

	data = tools.read_file(infile)
	newdata = data[:syms[start_sym].offset]
	newdata += insert + tools.get_bytes(0, size - len(insert))
	newdata += data[syms[end_sym].offset:]
	tools.write_file(outfile, newdata)
	tout.info('Written to offset %#x' % syms[start_sym].offset)

	def read_loadable_segments(data):
	"""Read segments from an ELF file

	Args:
	data (bytes): Contents of file

	Returns:
	tuple:
	list of segments, each:
	int: Segment number (0 = first)
	int: Start address of segment in memory
	bytes: Contents of segment
	int: entry address for image

	Raises:
	ValueError: elftools is not available
	"""
	if not ELF_TOOLS:
	raise ValueError("Python: No module named 'elftools'")
	with io.BytesIO(data) as inf:
	try:
	elf = ELFFile(inf)
	except ELFError as err:
	raise ValueError(err)
	entry = elf.header['e_entry']
	segments = []
	for i in range(elf.num_segments()):
	segment = elf.get_segment(i)
	if segment['p_type'] != 'PT_LOAD' or not segment['p_memsz']:
	skipped = 1 # To make code-coverage see this line
	continue
	start = segment['p_offset']
	rend = start + segment['p_filesz']
	segments.append((i, segment['p_paddr'], data[start:rend]))
	return segments, entry