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

 #!/usr/bin/env python3
 #
 # Copyright (c) 2017 Intel Corporation
 #
 # SPDX-License-Identifier: Apache-2.0

 import argparse
 import sys
 import struct
 import os
 import elftools
 from distutils.version import LooseVersion
 from elftools.elf.elffile import ELFFile
 from elftools.elf.sections import SymbolTableSection

 if LooseVersion(elftools.__version__) < LooseVersion('0.24'):
     sys.stderr.write("pyelftools is out of date, need version 0.24 or later\n")
     sys.exit(1)

 def debug(text):
     if not args.verbose:
         return
     sys.stdout.write(os.path.basename(sys.argv[0]) + ": " + text + "\n")

 def error(text):
     sys.stderr.write(os.path.basename(sys.argv[0]) + ": " + text + "\n")
     sys.exit(1)


 gdt_pd_fmt = "<HIH"

 FLAGS_GRAN = 1 << 7 # page granularity
 ACCESS_EX = 1 << 3  # executable
 ACCESS_DC = 1 << 2  # direction/conforming
 ACCESS_RW = 1 << 1  # read or write permission

 # 6 byte pseudo descriptor, but we're going to actually use this as the
 # zero descriptor and return 8 bytes
 def create_gdt_pseudo_desc(addr, size):
     # ...and take back one byte for the Intel god whose Ark this is...
     size = size - 1
     return struct.pack(gdt_pd_fmt, size, addr, 0)


 # Limit argument always in bytes
 def chop_base_limit(base, limit):
     base_lo = base & 0xFFFF
     base_mid = (base >> 16) & 0xFF
     base_hi = (base >> 24) & 0xFF

     limit_lo = limit & 0xFFFF
     limit_hi = (limit >> 16) & 0xF

     return (base_lo, base_mid, base_hi, limit_lo, limit_hi)


 gdt_ent_fmt = "<HHBBBB"

 def create_code_data_entry(base, limit, dpl, flags, access):
     base_lo, base_mid, base_hi, limit_lo, limit_hi = chop_base_limit(base,
             limit)

     # This is a valid descriptor
     present = 1

     # 32-bit protected mode
     size = 1

     # 1 = code or data, 0 = system type
     desc_type = 1

     # Just set accessed to 1 already so the CPU doesn't need it update it,
     # prevents freakouts if the GDT is in ROM, we don't care about this
     # bit in the OS
     accessed = 1

     access = access | (present << 7) | (dpl << 5) | (desc_type << 4) | accessed
     flags = flags | (size << 6) | limit_hi

     return struct.pack(gdt_ent_fmt, limit_lo, base_lo, base_mid,
                        access, flags, base_hi)


 def create_tss_entry(base, limit, dpl):
     present = 1

     base_lo, base_mid, base_hi, limit_lo, limit_hi, = chop_base_limit(base,
             limit)

     type_code = 0x9 # non-busy 32-bit TSS descriptor
     gran = 0

     flags = (gran << 7) | limit_hi
     type_byte = ((present << 7) | (dpl << 5) | type_code)


     return struct.pack(gdt_ent_fmt, limit_lo, base_lo, base_mid,
                        type_byte, flags, base_hi)


 def get_symbols(obj):
     for section in obj.iter_sections():
         if isinstance(section, SymbolTableSection):
             return {sym.name: sym.entry.st_value
                     for sym in section.iter_symbols()}

     raise LookupError("Could not find symbol table")


 def parse_args():
     global args
     parser = argparse.ArgumentParser(description = __doc__,
             formatter_class = argparse.RawDescriptionHelpFormatter)

     parser.add_argument("-k", "--kernel", required=True,
             help="Zephyr kernel image")
     parser.add_argument("-v", "--verbose", action="store_true",
             help="Print extra debugging information")
     parser.add_argument("-o", "--output-gdt", required=True,
             help="output GDT binary")
     args = parser.parse_args()


 def main():
     parse_args()

     with open(args.kernel, "rb") as fp:
         kernel = ELFFile(fp)
         syms = get_symbols(kernel)

     # NOTE: use-cases are extremely limited; we always have a basic flat
     # code/data segments. If we are doing stack protection, we are going to
     # have two TSS to manage the main task and the special task for double
     # fault exception handling

     if "CONFIG_X86_STACK_PROTECTION" in syms:
         stackprot = True
         if "CONFIG_X86_USERSPACE" in syms:
             userspace = True
             num_entries = 7
         else:
             userspace = False
             num_entries = 5
     else:
         stackprot = False
         num_entries = 3

     gdt_base = syms["_gdt"]

     with open(args.output_gdt, "wb") as fp:
         # The pseudo descriptor is stuffed into the NULL descriptor
         # since the CPU never looks at it
         fp.write(create_gdt_pseudo_desc(gdt_base, num_entries * 8))

         # Selector 0x08: code descriptor
         fp.write(create_code_data_entry(0, 0xFFFFF, 0,
                  FLAGS_GRAN, ACCESS_EX | ACCESS_RW))

         # Selector 0x10: data descriptor
         fp.write(create_code_data_entry(0, 0xFFFFF, 0,
                  FLAGS_GRAN, ACCESS_RW))

         if stackprot:
             main_tss = syms["_main_tss"]
             df_tss = syms["_df_tss"]

             # Selector 0x18: main TSS
             fp.write(create_tss_entry(main_tss, 0x67, 0))

             # Selector 0x20: double-fault TSS
             fp.write(create_tss_entry(df_tss, 0x67, 0))

             if userspace:
                 # Selector 0x28: code descriptor, dpl = 3
                 fp.write(create_code_data_entry(0, 0xFFFFF, 3,
                          FLAGS_GRAN, ACCESS_EX | ACCESS_RW))

                 # Selector 0x30: data descriptor, dpl = 3
                 fp.write(create_code_data_entry(0, 0xFFFFF, 3,
                          FLAGS_GRAN, ACCESS_RW))


 if __name__ == "__main__":
     main()
	#!/usr/bin/env python3
	#
	# Copyright (c) 2017 Intel Corporation
	#
	# SPDX-License-Identifier: Apache-2.0

	import argparse
	import sys
	import struct
	import os
	import elftools
	from distutils.version import LooseVersion
	from elftools.elf.elffile import ELFFile
	from elftools.elf.sections import SymbolTableSection

	if LooseVersion(elftools.__version__) < LooseVersion('0.24'):
	sys.stderr.write("pyelftools is out of date, need version 0.24 or later\n")
	sys.exit(1)

	def debug(text):
	if not args.verbose:
	return
	sys.stdout.write(os.path.basename(sys.argv[0]) + ": " + text + "\n")

	def error(text):
	sys.stderr.write(os.path.basename(sys.argv[0]) + ": " + text + "\n")
	sys.exit(1)


	gdt_pd_fmt = "<HIH"

	FLAGS_GRAN = 1 << 7 # page granularity
	ACCESS_EX = 1 << 3 # executable
	ACCESS_DC = 1 << 2 # direction/conforming
	ACCESS_RW = 1 << 1 # read or write permission

	# 6 byte pseudo descriptor, but we're going to actually use this as the
	# zero descriptor and return 8 bytes
	def create_gdt_pseudo_desc(addr, size):
	# ...and take back one byte for the Intel god whose Ark this is...
	size = size - 1
	return struct.pack(gdt_pd_fmt, size, addr, 0)


	# Limit argument always in bytes
	def chop_base_limit(base, limit):
	base_lo = base & 0xFFFF
	base_mid = (base >> 16) & 0xFF
	base_hi = (base >> 24) & 0xFF

	limit_lo = limit & 0xFFFF
	limit_hi = (limit >> 16) & 0xF

	return (base_lo, base_mid, base_hi, limit_lo, limit_hi)


	gdt_ent_fmt = "<HHBBBB"

	def create_code_data_entry(base, limit, dpl, flags, access):
	base_lo, base_mid, base_hi, limit_lo, limit_hi = chop_base_limit(base,
	limit)

	# This is a valid descriptor
	present = 1

	# 32-bit protected mode
	size = 1

	# 1 = code or data, 0 = system type
	desc_type = 1

	# Just set accessed to 1 already so the CPU doesn't need it update it,
	# prevents freakouts if the GDT is in ROM, we don't care about this
	# bit in the OS
	accessed = 1

	access = access \| (present << 7) \| (dpl << 5) \| (desc_type << 4) \| accessed
	flags = flags \| (size << 6) \| limit_hi

	return struct.pack(gdt_ent_fmt, limit_lo, base_lo, base_mid,
	access, flags, base_hi)


	def create_tss_entry(base, limit, dpl):
	present = 1

	base_lo, base_mid, base_hi, limit_lo, limit_hi, = chop_base_limit(base,
	limit)

	type_code = 0x9 # non-busy 32-bit TSS descriptor
	gran = 0

	flags = (gran << 7) \| limit_hi
	type_byte = ((present << 7) \| (dpl << 5) \| type_code)


	return struct.pack(gdt_ent_fmt, limit_lo, base_lo, base_mid,
	type_byte, flags, base_hi)


	def get_symbols(obj):
	for section in obj.iter_sections():
	if isinstance(section, SymbolTableSection):
	return {sym.name: sym.entry.st_value
	for sym in section.iter_symbols()}

	raise LookupError("Could not find symbol table")


	def parse_args():
	global args
	parser = argparse.ArgumentParser(description = __doc__,
	formatter_class = argparse.RawDescriptionHelpFormatter)

	parser.add_argument("-k", "--kernel", required=True,
	help="Zephyr kernel image")
	parser.add_argument("-v", "--verbose", action="store_true",
	help="Print extra debugging information")
	parser.add_argument("-o", "--output-gdt", required=True,
	help="output GDT binary")
	args = parser.parse_args()


	def main():
	parse_args()

	with open(args.kernel, "rb") as fp:
	kernel = ELFFile(fp)
	syms = get_symbols(kernel)

	# NOTE: use-cases are extremely limited; we always have a basic flat
	# code/data segments. If we are doing stack protection, we are going to
	# have two TSS to manage the main task and the special task for double
	# fault exception handling

	if "CONFIG_X86_STACK_PROTECTION" in syms:
	stackprot = True
	if "CONFIG_X86_USERSPACE" in syms:
	userspace = True
	num_entries = 7
	else:
	userspace = False
	num_entries = 5
	else:
	stackprot = False
	num_entries = 3

	gdt_base = syms["_gdt"]

	with open(args.output_gdt, "wb") as fp:
	# The pseudo descriptor is stuffed into the NULL descriptor
	# since the CPU never looks at it
	fp.write(create_gdt_pseudo_desc(gdt_base, num_entries * 8))

	# Selector 0x08: code descriptor
	fp.write(create_code_data_entry(0, 0xFFFFF, 0,
	FLAGS_GRAN, ACCESS_EX \| ACCESS_RW))

	# Selector 0x10: data descriptor
	fp.write(create_code_data_entry(0, 0xFFFFF, 0,
	FLAGS_GRAN, ACCESS_RW))

	if stackprot:
	main_tss = syms["_main_tss"]
	df_tss = syms["_df_tss"]

	# Selector 0x18: main TSS
	fp.write(create_tss_entry(main_tss, 0x67, 0))

	# Selector 0x20: double-fault TSS
	fp.write(create_tss_entry(df_tss, 0x67, 0))

	if userspace:
	# Selector 0x28: code descriptor, dpl = 3
	fp.write(create_code_data_entry(0, 0xFFFFF, 3,
	FLAGS_GRAN, ACCESS_EX \| ACCESS_RW))

	# Selector 0x30: data descriptor, dpl = 3
	fp.write(create_code_data_entry(0, 0xFFFFF, 3,
	FLAGS_GRAN, ACCESS_RW))


	if __name__ == "__main__":
	main()