scripts/make_fit.py - pub/scm/linux/kernel/git/next/linux-next - Git at Google

 #!/usr/bin/env python3
 # SPDX-License-Identifier: GPL-2.0+
 #
 # Copyright 2024 Google LLC
 # Written by Simon Glass <sjg@chromium.org>
 #

 """Build a FIT containing a lot of devicetree files

 Usage:
     make_fit.py -A arm64 -n 'Linux-6.6' -O linux
         -o arch/arm64/boot/image.fit -k /tmp/kern/arch/arm64/boot/image.itk
         @arch/arm64/boot/dts/dtbs-list -E -c gzip

 Creates a FIT containing the supplied kernel and a set of devicetree files,
 either specified individually or listed in a file (with an '@' prefix).

 Use -E to generate an external FIT (where the data is placed after the
 FIT data structure). This allows parsing of the data without loading
 the entire FIT.

 Use -c to compress the data, using bzip2, gzip, lz4, lzma, lzo and
 zstd algorithms.

 The resulting FIT can be booted by bootloaders which support FIT, such
 as U-Boot, Linuxboot, Tianocore, etc.

 Note that this tool does not yet support adding a ramdisk / initrd.
 """

 import argparse
 import collections
 import os
 import subprocess
 import sys
 import tempfile
 import time

 import libfdt


 # Tool extension and the name of the command-line tools
 CompTool = collections.namedtuple('CompTool', 'ext,tools')

 COMP_TOOLS = {
     'bzip2': CompTool('.bz2', 'bzip2'),
     'gzip': CompTool('.gz', 'pigz,gzip'),
     'lz4': CompTool('.lz4', 'lz4'),
     'lzma': CompTool('.lzma', 'lzma'),
     'lzo': CompTool('.lzo', 'lzop'),
     'zstd': CompTool('.zstd', 'zstd'),
 }


 def parse_args():
     """Parse the program ArgumentParser

     Returns:
         Namespace object containing the arguments
     """
     epilog = 'Build a FIT from a directory tree containing .dtb files'
     parser = argparse.ArgumentParser(epilog=epilog, fromfile_prefix_chars='@')
     parser.add_argument('-A', '--arch', type=str, required=True,
           help='Specifies the architecture')
     parser.add_argument('-c', '--compress', type=str, default='none',
           help='Specifies the compression')
     parser.add_argument('-E', '--external', action='store_true',
           help='Convert the FIT to use external data')
     parser.add_argument('-n', '--name', type=str, required=True,
           help='Specifies the name')
     parser.add_argument('-o', '--output', type=str, required=True,
           help='Specifies the output file (.fit)')
     parser.add_argument('-O', '--os', type=str, required=True,
           help='Specifies the operating system')
     parser.add_argument('-k', '--kernel', type=str, required=True,
           help='Specifies the (uncompressed) kernel input file (.itk)')
     parser.add_argument('-v', '--verbose', action='store_true',
                         help='Enable verbose output')
     parser.add_argument('dtbs', type=str, nargs='*',
           help='Specifies the devicetree files to process')

     return parser.parse_args()


 def setup_fit(fsw, name):
     """Make a start on writing the FIT

     Outputs the root properties and the 'images' node

     Args:
         fsw (libfdt.FdtSw): Object to use for writing
         name (str): Name of kernel image
     """
     fsw.INC_SIZE = 65536
     fsw.finish_reservemap()
     fsw.begin_node('')
     fsw.property_string('description', f'{name} with devicetree set')
     fsw.property_u32('#address-cells', 1)

     fsw.property_u32('timestamp', int(time.time()))
     fsw.begin_node('images')


 def write_kernel(fsw, data, args):
     """Write out the kernel image

     Writes a kernel node along with the required properties

     Args:
         fsw (libfdt.FdtSw): Object to use for writing
         data (bytes): Data to write (possibly compressed)
         args (Namespace): Contains necessary strings:
             arch: FIT architecture, e.g. 'arm64'
             fit_os: Operating Systems, e.g. 'linux'
             name: Name of OS, e.g. 'Linux-6.6.0-rc7'
             compress: Compression algorithm to use, e.g. 'gzip'
     """
     with fsw.add_node('kernel'):
         fsw.property_string('description', args.name)
         fsw.property_string('type', 'kernel_noload')
         fsw.property_string('arch', args.arch)
         fsw.property_string('os', args.os)
         fsw.property_string('compression', args.compress)
         fsw.property('data', data)
         fsw.property_u32('load', 0)
         fsw.property_u32('entry', 0)


 def finish_fit(fsw, entries):
     """Finish the FIT ready for use

     Writes the /configurations node and subnodes

     Args:
         fsw (libfdt.FdtSw): Object to use for writing
         entries (list of tuple): List of configurations:
             str: Description of model
             str: Compatible stringlist
     """
     fsw.end_node()
     seq = 0
     with fsw.add_node('configurations'):
         for model, compat in entries:
             seq += 1
             with fsw.add_node(f'conf-{seq}'):
                 fsw.property('compatible', bytes(compat))
                 fsw.property_string('description', model)
                 fsw.property_string('fdt', f'fdt-{seq}')
                 fsw.property_string('kernel', 'kernel')
     fsw.end_node()


 def compress_data(inf, compress):
     """Compress data using a selected algorithm

     Args:
         inf (IOBase): Filename containing the data to compress
         compress (str): Compression algorithm, e.g. 'gzip'

     Return:
         bytes: Compressed data
     """
     if compress == 'none':
         return inf.read()

     comp = COMP_TOOLS.get(compress)
     if not comp:
         raise ValueError(f"Unknown compression algorithm '{compress}'")

     with tempfile.NamedTemporaryFile() as comp_fname:
         with open(comp_fname.name, 'wb') as outf:
             done = False
             for tool in comp.tools.split(','):
                 try:
                     subprocess.call([tool, '-c'], stdin=inf, stdout=outf)
                     done = True
                     break
                 except FileNotFoundError:
                     pass
             if not done:
                 raise ValueError(f'Missing tool(s): {comp.tools}\n')
             with open(comp_fname.name, 'rb') as compf:
                 comp_data = compf.read()
     return comp_data


 def output_dtb(fsw, seq, fname, arch, compress):
     """Write out a single devicetree to the FIT

     Args:
         fsw (libfdt.FdtSw): Object to use for writing
         seq (int): Sequence number (1 for first)
         fname (str): Filename containing the DTB
         arch: FIT architecture, e.g. 'arm64'
         compress (str): Compressed algorithm, e.g. 'gzip'

     Returns:
         tuple:
             str: Model name
             bytes: Compatible stringlist
     """
     with fsw.add_node(f'fdt-{seq}'):
         # Get the compatible / model information
         with open(fname, 'rb') as inf:
             data = inf.read()
         fdt = libfdt.FdtRo(data)
         model = fdt.getprop(0, 'model').as_str()
         compat = fdt.getprop(0, 'compatible')

         fsw.property_string('description', model)
         fsw.property_string('type', 'flat_dt')
         fsw.property_string('arch', arch)
         fsw.property_string('compression', compress)

         with open(fname, 'rb') as inf:
             compressed = compress_data(inf, compress)
         fsw.property('data', compressed)
     return model, compat


 def build_fit(args):
     """Build the FIT from the provided files and arguments

     Args:
         args (Namespace): Program arguments

     Returns:
         tuple:
             bytes: FIT data
             int: Number of configurations generated
             size: Total uncompressed size of data
     """
     seq = 0
     size = 0
     fsw = libfdt.FdtSw()
     setup_fit(fsw, args.name)
     entries = []

     # Handle the kernel
     with open(args.kernel, 'rb') as inf:
         comp_data = compress_data(inf, args.compress)
     size += os.path.getsize(args.kernel)
     write_kernel(fsw, comp_data, args)

     for fname in args.dtbs:
         # Ignore overlay (.dtbo) files
         if os.path.splitext(fname)[1] == '.dtb':
             seq += 1
             size += os.path.getsize(fname)
             model, compat = output_dtb(fsw, seq, fname, args.arch, args.compress)
             entries.append([model, compat])

     finish_fit(fsw, entries)

     # Include the kernel itself in the returned file count
     return fsw.as_fdt().as_bytearray(), seq + 1, size


 def run_make_fit():
     """Run the tool's main logic"""
     args = parse_args()

     out_data, count, size = build_fit(args)
     with open(args.output, 'wb') as outf:
         outf.write(out_data)

     ext_fit_size = None
     if args.external:
         mkimage = os.environ.get('MKIMAGE', 'mkimage')
         subprocess.check_call([mkimage, '-E', '-F', args.output],
                               stdout=subprocess.DEVNULL)

         with open(args.output, 'rb') as inf:
             data = inf.read()
         ext_fit = libfdt.FdtRo(data)
         ext_fit_size = ext_fit.totalsize()

     if args.verbose:
         comp_size = len(out_data)
         print(f'FIT size {comp_size:#x}/{comp_size / 1024 / 1024:.1f} MB',
               end='')
         if ext_fit_size:
             print(f', header {ext_fit_size:#x}/{ext_fit_size / 1024:.1f} KB',
                   end='')
         print(f', {count} files, uncompressed {size / 1024 / 1024:.1f} MB')


 if __name__ == "__main__":
     sys.exit(run_make_fit())
	#!/usr/bin/env python3
	# SPDX-License-Identifier: GPL-2.0+
	#
	# Copyright 2024 Google LLC
	# Written by Simon Glass <sjg@chromium.org>
	#

	"""Build a FIT containing a lot of devicetree files

	Usage:
	make_fit.py -A arm64 -n 'Linux-6.6' -O linux
	-o arch/arm64/boot/image.fit -k /tmp/kern/arch/arm64/boot/image.itk
	@arch/arm64/boot/dts/dtbs-list -E -c gzip

	Creates a FIT containing the supplied kernel and a set of devicetree files,
	either specified individually or listed in a file (with an '@' prefix).

	Use -E to generate an external FIT (where the data is placed after the
	FIT data structure). This allows parsing of the data without loading
	the entire FIT.

	Use -c to compress the data, using bzip2, gzip, lz4, lzma, lzo and
	zstd algorithms.

	The resulting FIT can be booted by bootloaders which support FIT, such
	as U-Boot, Linuxboot, Tianocore, etc.

	Note that this tool does not yet support adding a ramdisk / initrd.
	"""

	import argparse
	import collections
	import os
	import subprocess
	import sys
	import tempfile
	import time

	import libfdt


	# Tool extension and the name of the command-line tools
	CompTool = collections.namedtuple('CompTool', 'ext,tools')

	COMP_TOOLS = {
	'bzip2': CompTool('.bz2', 'bzip2'),
	'gzip': CompTool('.gz', 'pigz,gzip'),
	'lz4': CompTool('.lz4', 'lz4'),
	'lzma': CompTool('.lzma', 'lzma'),
	'lzo': CompTool('.lzo', 'lzop'),
	'zstd': CompTool('.zstd', 'zstd'),
	}


	def parse_args():
	"""Parse the program ArgumentParser

	Returns:
	Namespace object containing the arguments
	"""
	epilog = 'Build a FIT from a directory tree containing .dtb files'
	parser = argparse.ArgumentParser(epilog=epilog, fromfile_prefix_chars='@')
	parser.add_argument('-A', '--arch', type=str, required=True,
	help='Specifies the architecture')
	parser.add_argument('-c', '--compress', type=str, default='none',
	help='Specifies the compression')
	parser.add_argument('-E', '--external', action='store_true',
	help='Convert the FIT to use external data')
	parser.add_argument('-n', '--name', type=str, required=True,
	help='Specifies the name')
	parser.add_argument('-o', '--output', type=str, required=True,
	help='Specifies the output file (.fit)')
	parser.add_argument('-O', '--os', type=str, required=True,
	help='Specifies the operating system')
	parser.add_argument('-k', '--kernel', type=str, required=True,
	help='Specifies the (uncompressed) kernel input file (.itk)')
	parser.add_argument('-v', '--verbose', action='store_true',
	help='Enable verbose output')
	parser.add_argument('dtbs', type=str, nargs='*',
	help='Specifies the devicetree files to process')

	return parser.parse_args()


	def setup_fit(fsw, name):
	"""Make a start on writing the FIT

	Outputs the root properties and the 'images' node

	Args:
	fsw (libfdt.FdtSw): Object to use for writing
	name (str): Name of kernel image
	"""
	fsw.INC_SIZE = 65536
	fsw.finish_reservemap()
	fsw.begin_node('')
	fsw.property_string('description', f'{name} with devicetree set')
	fsw.property_u32('#address-cells', 1)

	fsw.property_u32('timestamp', int(time.time()))
	fsw.begin_node('images')


	def write_kernel(fsw, data, args):
	"""Write out the kernel image

	Writes a kernel node along with the required properties

	Args:
	fsw (libfdt.FdtSw): Object to use for writing
	data (bytes): Data to write (possibly compressed)
	args (Namespace): Contains necessary strings:
	arch: FIT architecture, e.g. 'arm64'
	fit_os: Operating Systems, e.g. 'linux'
	name: Name of OS, e.g. 'Linux-6.6.0-rc7'
	compress: Compression algorithm to use, e.g. 'gzip'
	"""
	with fsw.add_node('kernel'):
	fsw.property_string('description', args.name)
	fsw.property_string('type', 'kernel_noload')
	fsw.property_string('arch', args.arch)
	fsw.property_string('os', args.os)
	fsw.property_string('compression', args.compress)
	fsw.property('data', data)
	fsw.property_u32('load', 0)
	fsw.property_u32('entry', 0)


	def finish_fit(fsw, entries):
	"""Finish the FIT ready for use

	Writes the /configurations node and subnodes

	Args:
	fsw (libfdt.FdtSw): Object to use for writing
	entries (list of tuple): List of configurations:
	str: Description of model
	str: Compatible stringlist
	"""
	fsw.end_node()
	seq = 0
	with fsw.add_node('configurations'):
	for model, compat in entries:
	seq += 1
	with fsw.add_node(f'conf-{seq}'):
	fsw.property('compatible', bytes(compat))
	fsw.property_string('description', model)
	fsw.property_string('fdt', f'fdt-{seq}')
	fsw.property_string('kernel', 'kernel')
	fsw.end_node()


	def compress_data(inf, compress):
	"""Compress data using a selected algorithm

	Args:
	inf (IOBase): Filename containing the data to compress
	compress (str): Compression algorithm, e.g. 'gzip'

	Return:
	bytes: Compressed data
	"""
	if compress == 'none':
	return inf.read()

	comp = COMP_TOOLS.get(compress)
	if not comp:
	raise ValueError(f"Unknown compression algorithm '{compress}'")

	with tempfile.NamedTemporaryFile() as comp_fname:
	with open(comp_fname.name, 'wb') as outf:
	done = False
	for tool in comp.tools.split(','):
	try:
	subprocess.call([tool, '-c'], stdin=inf, stdout=outf)
	done = True
	break
	except FileNotFoundError:
	pass
	if not done:
	raise ValueError(f'Missing tool(s): {comp.tools}\n')
	with open(comp_fname.name, 'rb') as compf:
	comp_data = compf.read()
	return comp_data


	def output_dtb(fsw, seq, fname, arch, compress):
	"""Write out a single devicetree to the FIT

	Args:
	fsw (libfdt.FdtSw): Object to use for writing
	seq (int): Sequence number (1 for first)
	fname (str): Filename containing the DTB
	arch: FIT architecture, e.g. 'arm64'
	compress (str): Compressed algorithm, e.g. 'gzip'

	Returns:
	tuple:
	str: Model name
	bytes: Compatible stringlist
	"""
	with fsw.add_node(f'fdt-{seq}'):
	# Get the compatible / model information
	with open(fname, 'rb') as inf:
	data = inf.read()
	fdt = libfdt.FdtRo(data)
	model = fdt.getprop(0, 'model').as_str()
	compat = fdt.getprop(0, 'compatible')

	fsw.property_string('description', model)
	fsw.property_string('type', 'flat_dt')
	fsw.property_string('arch', arch)
	fsw.property_string('compression', compress)

	with open(fname, 'rb') as inf:
	compressed = compress_data(inf, compress)
	fsw.property('data', compressed)
	return model, compat


	def build_fit(args):
	"""Build the FIT from the provided files and arguments

	Args:
	args (Namespace): Program arguments

	Returns:
	tuple:
	bytes: FIT data
	int: Number of configurations generated
	size: Total uncompressed size of data
	"""
	seq = 0
	size = 0
	fsw = libfdt.FdtSw()
	setup_fit(fsw, args.name)
	entries = []

	# Handle the kernel
	with open(args.kernel, 'rb') as inf:
	comp_data = compress_data(inf, args.compress)
	size += os.path.getsize(args.kernel)
	write_kernel(fsw, comp_data, args)

	for fname in args.dtbs:
	# Ignore overlay (.dtbo) files
	if os.path.splitext(fname)[1] == '.dtb':
	seq += 1
	size += os.path.getsize(fname)
	model, compat = output_dtb(fsw, seq, fname, args.arch, args.compress)
	entries.append([model, compat])

	finish_fit(fsw, entries)

	# Include the kernel itself in the returned file count
	return fsw.as_fdt().as_bytearray(), seq + 1, size


	def run_make_fit():
	"""Run the tool's main logic"""
	args = parse_args()

	out_data, count, size = build_fit(args)
	with open(args.output, 'wb') as outf:
	outf.write(out_data)

	ext_fit_size = None
	if args.external:
	mkimage = os.environ.get('MKIMAGE', 'mkimage')
	subprocess.check_call([mkimage, '-E', '-F', args.output],
	stdout=subprocess.DEVNULL)

	with open(args.output, 'rb') as inf:
	data = inf.read()
	ext_fit = libfdt.FdtRo(data)
	ext_fit_size = ext_fit.totalsize()

	if args.verbose:
	comp_size = len(out_data)
	print(f'FIT size {comp_size:#x}/{comp_size / 1024 / 1024:.1f} MB',
	end='')
	if ext_fit_size:
	print(f', header {ext_fit_size:#x}/{ext_fit_size / 1024:.1f} KB',
	end='')
	print(f', {count} files, uncompressed {size / 1024 / 1024:.1f} MB')


	if __name__ == "__main__":
	sys.exit(run_make_fit())