scripts/build/gen_app_partitions.py - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 #!/usr/bin/env python3
 #
 # Copyright (c) 2018 Intel Corporation
 #
 # SPDX-License-Identifier: Apache-2.0

 """
 Script to generate a linker script organizing application memory partitions

 Applications may declare build-time memory domain partitions with
 K_APPMEM_PARTITION_DEFINE, and assign globals to them using K_APP_DMEM
 or K_APP_BMEM macros. For each of these partitions, we need to
 route all their data into appropriately-sized memory areas which meet the
 size/alignment constraints of the memory protection hardware.

 This linker script is created very early in the build process, before
 the build attempts to link the kernel binary, as the linker script this
 tool generates is a necessary pre-condition for kernel linking. We extract
 the set of memory partitions to generate by looking for variables which
 have been assigned to input sections that follow a defined naming convention.
 We also allow entire libraries to be pulled in to assign their globals
 to a particular memory partition via command line directives.

 This script takes as inputs:

 - The base directory to look for compiled objects
 - key/value pairs mapping static library files to what partitions their globals
   should end up in.

 The output is a linker script fragment containing the definition of the
 app shared memory section, which is further divided, for each partition
 found, into data and BSS for each partition.
 """

 import sys
 import argparse
 import json
 import os
 import re
 from collections import OrderedDict
 from elftools.elf.elffile import ELFFile
 from elftools.elf.sections import SymbolTableSection
 import elftools.common.exceptions

 SZ = 'size'
 SRC = 'sources'
 LIB = 'libraries'

 # This script will create sections and linker variables to place the
 # application shared memory partitions.
 # these are later read by the macros defined in app_memdomain.h for
 # initialization purpose when USERSPACE is enabled.
 data_template = """
 		/* Auto generated code do not modify */
 		SMEM_PARTITION_ALIGN(z_data_smem_{0}_bss_end - z_data_smem_{0}_part_start);
 		z_data_smem_{0}_part_start = .;
 		KEEP(*(data_smem_{0}_data*))
 """

 library_data_template = """
 		*{0}:*(.data .data.* .sdata .sdata.*)
 """

 bss_template = """
 		z_data_smem_{0}_bss_start = .;
 		KEEP(*(data_smem_{0}_bss*))
 """

 library_bss_template = """
 		*{0}:*(.bss .bss.* .sbss .sbss.* COMMON COMMON.*)
 """

 footer_template = """
 		z_data_smem_{0}_bss_end = .;
 		SMEM_PARTITION_ALIGN(z_data_smem_{0}_bss_end - z_data_smem_{0}_part_start);
 		z_data_smem_{0}_part_end = .;
 """

 linker_start_seq = """
 	SECTION_PROLOGUE(_APP_SMEM{1}_SECTION_NAME,,)
 	{{
 		APP_SHARED_ALIGN;
 		_app_smem{0}_start = .;
 """

 linker_end_seq = """
 		APP_SHARED_ALIGN;
 		_app_smem{0}_end = .;
 	}} GROUP_DATA_LINK_IN(RAMABLE_REGION, ROMABLE_REGION)
 """

 empty_app_smem = """
 	SECTION_PROLOGUE(_APP_SMEM{1}_SECTION_NAME,,)
 	{{
 #ifdef EMPTY_APP_SHARED_ALIGN
 		EMPTY_APP_SHARED_ALIGN;
 #endif
 		_app_smem{0}_start = .;
 		_app_smem{0}_end = .;
 	}} GROUP_DATA_LINK_IN(RAMABLE_REGION, ROMABLE_REGION)
 """

 size_cal_string = """
 	z_data_smem_{0}_part_size = z_data_smem_{0}_part_end - z_data_smem_{0}_part_start;
 	z_data_smem_{0}_bss_size = z_data_smem_{0}_bss_end - z_data_smem_{0}_bss_start;
 """

 section_regex = re.compile(r'data_smem_([A-Za-z0-9_]*)_(data|bss)*')

 elf_part_size_regex = re.compile(r'z_data_smem_(.*)_part_size')

 def find_obj_file_partitions(filename, partitions):
     with open(filename, 'rb') as f:
         try:
             full_lib = ELFFile(f)
         except elftools.common.exceptions.ELFError as e:
             exit(f"Error: {filename}: {e}")

         if not full_lib:
             sys.exit("Error parsing file: " + filename)

         sections = [x for x in full_lib.iter_sections()]
         for section in sections:
             m = section_regex.match(section.name)
             if not m:
                 continue

             partition_name = m.groups()[0]
             if partition_name not in partitions:
                 partitions[partition_name] = {SZ: section.header.sh_size}

                 if args.verbose:
                     partitions[partition_name][SRC] = filename

             else:
                 partitions[partition_name][SZ] += section.header.sh_size


     return partitions


 def parse_obj_files(partitions):
     # Iterate over all object files to find partitions
     for dirpath, _, files in os.walk(args.directory):
         for filename in files:
             if re.match(r".*\.obj$", filename):
                 fullname = os.path.join(dirpath, filename)
                 fsize = os.path.getsize(fullname)
                 if fsize != 0:
                     find_obj_file_partitions(fullname, partitions)


 def parse_compile_command_file(partitions):
     # Iterate over all entries to find object files.
     # Thereafter process each object file to find partitions
     object_pattern = re.compile(r'-o\s+(\S*)')
     with open(args.compile_commands_file, 'rb') as f:
         commands = json.load(f)
         for command in commands:
             build_dir = command.get('directory')
             compile_command = command.get('command')
             compile_arg = object_pattern.search(compile_command)
             obj_file = None if compile_arg is None else compile_arg.group(1)
             if obj_file:
                 fullname = os.path.join(build_dir, obj_file)
                 # Because of issue #40635, then not all objects referenced by
                 # the compile_commands.json file may be available, therefore
                 # only include existing files.
                 if os.path.exists(fullname):
                     find_obj_file_partitions(fullname, partitions)


 def parse_elf_file(partitions):
     with open(args.elf, 'rb') as f:
         try:
             elffile = ELFFile(f)
         except elftools.common.exceptions.ELFError as e:
             exit(f"Error: {args.elf}: {e}")

         symbol_tbls = [s for s in elffile.iter_sections()
                        if isinstance(s, SymbolTableSection)]

         for section in symbol_tbls:
             for symbol in section.iter_symbols():
                 if symbol['st_shndx'] != "SHN_ABS":
                     continue

                 x = elf_part_size_regex.match(symbol.name)
                 if not x:
                     continue

                 partition_name = x.groups()[0]
                 size = symbol['st_value']
                 if partition_name not in partitions:
                     partitions[partition_name] = {SZ: size}

                     if args.verbose:
                         partitions[partition_name][SRC] = args.elf

                 else:
                     partitions[partition_name][SZ] += size


 def generate_final_linker(linker_file, partitions, lnkr_sect=""):
     string = ""

     if len(partitions) > 0:
         string = linker_start_seq.format(lnkr_sect, lnkr_sect.upper())
         size_string = ''
         for partition, item in partitions.items():
             string += data_template.format(partition)
             if LIB in item:
                 for lib in item[LIB]:
                     string += library_data_template.format(lib)
             string += bss_template.format(partition, lnkr_sect)
             if LIB in item:
                 for lib in item[LIB]:
                     string += library_bss_template.format(lib)
             string += footer_template.format(partition)
             size_string += size_cal_string.format(partition)

         string += linker_end_seq.format(lnkr_sect)
         string += size_string
     else:
         string = empty_app_smem.format(lnkr_sect, lnkr_sect.upper())

     with open(linker_file, "w") as fw:
         fw.write(string)


 def parse_args():
     global args
     parser = argparse.ArgumentParser(
         description=__doc__,
         formatter_class=argparse.RawDescriptionHelpFormatter)
     parser.add_argument("-d", "--directory", required=False, default=None,
                         help="Root build directory")
     parser.add_argument("-e", "--elf", required=False, default=None,
                         help="ELF file")
     parser.add_argument("-f", "--compile-commands-file", required=False,
                         default=None, help="CMake compile commands file")
     parser.add_argument("-o", "--output", required=False,
                         help="Output ld file")
     parser.add_argument("-v", "--verbose", action="count", default=0,
                         help="Verbose Output")
     parser.add_argument("-l", "--library", nargs=2, action="append", default=[],
                         metavar=("LIBRARY", "PARTITION"),
                         help="Include globals for a particular library or object filename into a designated partition")
     parser.add_argument("--pinoutput", required=False,
                         help="Output ld file for pinned sections")
     parser.add_argument("--pinpartitions", action="store", required=False, default="",
                         help="Comma separated names of partitions to be pinned in physical memory")

     args = parser.parse_args()


 def main():
     parse_args()
     partitions = {}

     if args.directory is not None:
         parse_obj_files(partitions)
     if args.compile_commands_file is not None:
         parse_compile_command_file(partitions)
     elif args.elf is not None:
         parse_elf_file(partitions)
     else:
         return

     for lib, ptn in args.library:
         if ptn not in partitions:
             partitions[ptn] = {}

         if LIB not in partitions[ptn]:
             partitions[ptn][LIB] = [lib]
         else:
             partitions[ptn][LIB].append(lib)

     if args.pinoutput:
         pin_part_names = args.pinpartitions.split(',')

         generic_partitions = {key: value for key, value in partitions.items()
                               if key not in pin_part_names}
         pinned_partitions = {key: value for key, value in partitions.items()
                              if key in pin_part_names}
     else:
         generic_partitions = partitions

     # Sample partitions.items() list before sorting:
     #   [ ('part1', {'size': 64}), ('part3', {'size': 64}, ...
     #     ('part0', {'size': 334}) ]
     decreasing_tuples = sorted(generic_partitions.items(),
                            key=lambda x: (x[1][SZ], x[0]), reverse=True)

     partsorted = OrderedDict(decreasing_tuples)

     generate_final_linker(args.output, partsorted)
     if args.verbose:
         print("Partitions retrieved:")
         for key in partsorted:
             print("    {0}: size {1}: {2}".format(key,
                                                   partsorted[key][SZ],
                                                   partsorted[key][SRC]))

     if args.pinoutput:
         decreasing_tuples = sorted(pinned_partitions.items(),
                                    key=lambda x: (x[1][SZ], x[0]), reverse=True)

         partsorted = OrderedDict(decreasing_tuples)

         generate_final_linker(args.pinoutput, partsorted, lnkr_sect="_pinned")
         if args.verbose:
             print("Pinned partitions retrieved:")
             for key in partsorted:
                 print("    {0}: size {1}: {2}".format(key,
                                                     partsorted[key][SZ],
                                                     partsorted[key][SRC]))


 if __name__ == '__main__':
     main()
	#!/usr/bin/env python3
	#
	# Copyright (c) 2018 Intel Corporation
	#
	# SPDX-License-Identifier: Apache-2.0

	"""
	Script to generate a linker script organizing application memory partitions

	Applications may declare build-time memory domain partitions with
	K_APPMEM_PARTITION_DEFINE, and assign globals to them using K_APP_DMEM
	or K_APP_BMEM macros. For each of these partitions, we need to
	route all their data into appropriately-sized memory areas which meet the
	size/alignment constraints of the memory protection hardware.

	This linker script is created very early in the build process, before
	the build attempts to link the kernel binary, as the linker script this
	tool generates is a necessary pre-condition for kernel linking. We extract
	the set of memory partitions to generate by looking for variables which
	have been assigned to input sections that follow a defined naming convention.
	We also allow entire libraries to be pulled in to assign their globals
	to a particular memory partition via command line directives.

	This script takes as inputs:

	- The base directory to look for compiled objects
	- key/value pairs mapping static library files to what partitions their globals
	should end up in.

	The output is a linker script fragment containing the definition of the
	app shared memory section, which is further divided, for each partition
	found, into data and BSS for each partition.
	"""

	import sys
	import argparse
	import json
	import os
	import re
	from collections import OrderedDict
	from elftools.elf.elffile import ELFFile
	from elftools.elf.sections import SymbolTableSection
	import elftools.common.exceptions

	SZ = 'size'
	SRC = 'sources'
	LIB = 'libraries'

	# This script will create sections and linker variables to place the
	# application shared memory partitions.
	# these are later read by the macros defined in app_memdomain.h for
	# initialization purpose when USERSPACE is enabled.
	data_template = """
	/* Auto generated code do not modify */
	SMEM_PARTITION_ALIGN(z_data_smem_{0}_bss_end - z_data_smem_{0}_part_start);
	z_data_smem_{0}_part_start = .;
	KEEP((data_smem_{0}_data))
	"""

	library_data_template = """
	{0}:(.data .data.* .sdata .sdata.*)
	"""

	bss_template = """
	z_data_smem_{0}_bss_start = .;
	KEEP((data_smem_{0}_bss))
	"""

	library_bss_template = """
	{0}:(.bss .bss.* .sbss .sbss.* COMMON COMMON.*)
	"""

	footer_template = """
	z_data_smem_{0}_bss_end = .;
	SMEM_PARTITION_ALIGN(z_data_smem_{0}_bss_end - z_data_smem_{0}_part_start);
	z_data_smem_{0}_part_end = .;
	"""

	linker_start_seq = """
	SECTION_PROLOGUE(_APP_SMEM{1}_SECTION_NAME,,)
	{{
	APP_SHARED_ALIGN;
	_app_smem{0}_start = .;
	"""

	linker_end_seq = """
	APP_SHARED_ALIGN;
	_app_smem{0}_end = .;
	}} GROUP_DATA_LINK_IN(RAMABLE_REGION, ROMABLE_REGION)
	"""

	empty_app_smem = """
	SECTION_PROLOGUE(_APP_SMEM{1}_SECTION_NAME,,)
	{{
	#ifdef EMPTY_APP_SHARED_ALIGN
	EMPTY_APP_SHARED_ALIGN;
	#endif
	_app_smem{0}_start = .;
	_app_smem{0}_end = .;
	}} GROUP_DATA_LINK_IN(RAMABLE_REGION, ROMABLE_REGION)
	"""

	size_cal_string = """
	z_data_smem_{0}_part_size = z_data_smem_{0}_part_end - z_data_smem_{0}_part_start;
	z_data_smem_{0}_bss_size = z_data_smem_{0}_bss_end - z_data_smem_{0}_bss_start;
	"""

	section_regex = re.compile(r'data_smem_([A-Za-z0-9_])_(data\|bss)')

	elf_part_size_regex = re.compile(r'z_data_smem_(.*)_part_size')

	def find_obj_file_partitions(filename, partitions):
	with open(filename, 'rb') as f:
	try:
	full_lib = ELFFile(f)
	except elftools.common.exceptions.ELFError as e:
	exit(f"Error: {filename}: {e}")

	if not full_lib:
	sys.exit("Error parsing file: " + filename)

	sections = [x for x in full_lib.iter_sections()]
	for section in sections:
	m = section_regex.match(section.name)
	if not m:
	continue

	partition_name = m.groups()[0]
	if partition_name not in partitions:
	partitions[partition_name] = {SZ: section.header.sh_size}

	if args.verbose:
	partitions[partition_name][SRC] = filename

	else:
	partitions[partition_name][SZ] += section.header.sh_size


	return partitions


	def parse_obj_files(partitions):
	# Iterate over all object files to find partitions
	for dirpath, _, files in os.walk(args.directory):
	for filename in files:
	if re.match(r".*\.obj$", filename):
	fullname = os.path.join(dirpath, filename)
	fsize = os.path.getsize(fullname)
	if fsize != 0:
	find_obj_file_partitions(fullname, partitions)


	def parse_compile_command_file(partitions):
	# Iterate over all entries to find object files.
	# Thereafter process each object file to find partitions
	object_pattern = re.compile(r'-o\s+(\S*)')
	with open(args.compile_commands_file, 'rb') as f:
	commands = json.load(f)
	for command in commands:
	build_dir = command.get('directory')
	compile_command = command.get('command')
	compile_arg = object_pattern.search(compile_command)
	obj_file = None if compile_arg is None else compile_arg.group(1)
	if obj_file:
	fullname = os.path.join(build_dir, obj_file)
	# Because of issue #40635, then not all objects referenced by
	# the compile_commands.json file may be available, therefore
	# only include existing files.
	if os.path.exists(fullname):
	find_obj_file_partitions(fullname, partitions)


	def parse_elf_file(partitions):
	with open(args.elf, 'rb') as f:
	try:
	elffile = ELFFile(f)
	except elftools.common.exceptions.ELFError as e:
	exit(f"Error: {args.elf}: {e}")

	symbol_tbls = [s for s in elffile.iter_sections()
	if isinstance(s, SymbolTableSection)]

	for section in symbol_tbls:
	for symbol in section.iter_symbols():
	if symbol['st_shndx'] != "SHN_ABS":
	continue

	x = elf_part_size_regex.match(symbol.name)
	if not x:
	continue

	partition_name = x.groups()[0]
	size = symbol['st_value']
	if partition_name not in partitions:
	partitions[partition_name] = {SZ: size}

	if args.verbose:
	partitions[partition_name][SRC] = args.elf

	else:
	partitions[partition_name][SZ] += size


	def generate_final_linker(linker_file, partitions, lnkr_sect=""):
	string = ""

	if len(partitions) > 0:
	string = linker_start_seq.format(lnkr_sect, lnkr_sect.upper())
	size_string = ''
	for partition, item in partitions.items():
	string += data_template.format(partition)
	if LIB in item:
	for lib in item[LIB]:
	string += library_data_template.format(lib)
	string += bss_template.format(partition, lnkr_sect)
	if LIB in item:
	for lib in item[LIB]:
	string += library_bss_template.format(lib)
	string += footer_template.format(partition)
	size_string += size_cal_string.format(partition)

	string += linker_end_seq.format(lnkr_sect)
	string += size_string
	else:
	string = empty_app_smem.format(lnkr_sect, lnkr_sect.upper())

	with open(linker_file, "w") as fw:
	fw.write(string)


	def parse_args():
	global args
	parser = argparse.ArgumentParser(
	description=__doc__,
	formatter_class=argparse.RawDescriptionHelpFormatter)
	parser.add_argument("-d", "--directory", required=False, default=None,
	help="Root build directory")
	parser.add_argument("-e", "--elf", required=False, default=None,
	help="ELF file")
	parser.add_argument("-f", "--compile-commands-file", required=False,
	default=None, help="CMake compile commands file")
	parser.add_argument("-o", "--output", required=False,
	help="Output ld file")
	parser.add_argument("-v", "--verbose", action="count", default=0,
	help="Verbose Output")
	parser.add_argument("-l", "--library", nargs=2, action="append", default=[],
	metavar=("LIBRARY", "PARTITION"),
	help="Include globals for a particular library or object filename into a designated partition")
	parser.add_argument("--pinoutput", required=False,
	help="Output ld file for pinned sections")
	parser.add_argument("--pinpartitions", action="store", required=False, default="",
	help="Comma separated names of partitions to be pinned in physical memory")

	args = parser.parse_args()


	def main():
	parse_args()
	partitions = {}

	if args.directory is not None:
	parse_obj_files(partitions)
	if args.compile_commands_file is not None:
	parse_compile_command_file(partitions)
	elif args.elf is not None:
	parse_elf_file(partitions)
	else:
	return

	for lib, ptn in args.library:
	if ptn not in partitions:
	partitions[ptn] = {}

	if LIB not in partitions[ptn]:
	partitions[ptn][LIB] = [lib]
	else:
	partitions[ptn][LIB].append(lib)

	if args.pinoutput:
	pin_part_names = args.pinpartitions.split(',')

	generic_partitions = {key: value for key, value in partitions.items()
	if key not in pin_part_names}
	pinned_partitions = {key: value for key, value in partitions.items()
	if key in pin_part_names}
	else:
	generic_partitions = partitions

	# Sample partitions.items() list before sorting:
	# [ ('part1', {'size': 64}), ('part3', {'size': 64}, ...
	# ('part0', {'size': 334}) ]
	decreasing_tuples = sorted(generic_partitions.items(),
	key=lambda x: (x[1][SZ], x[0]), reverse=True)

	partsorted = OrderedDict(decreasing_tuples)

	generate_final_linker(args.output, partsorted)
	if args.verbose:
	print("Partitions retrieved:")
	for key in partsorted:
	print(" {0}: size {1}: {2}".format(key,
	partsorted[key][SZ],
	partsorted[key][SRC]))

	if args.pinoutput:
	decreasing_tuples = sorted(pinned_partitions.items(),
	key=lambda x: (x[1][SZ], x[0]), reverse=True)

	partsorted = OrderedDict(decreasing_tuples)

	generate_final_linker(args.pinoutput, partsorted, lnkr_sect="_pinned")
	if args.verbose:
	print("Pinned partitions retrieved:")
	for key in partsorted:
	print(" {0}: size {1}: {2}".format(key,
	partsorted[key][SZ],
	partsorted[key][SRC]))


	if __name__ == '__main__':
	main()