arch/x86/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

 """Generate a Global Descriptor Table (GDT) for x86 CPUs.

 For additional detail on GDT and x86 memory management, please
 consult the IA Architecture SW Developer Manual, vol. 3.

 This script accepts as input the zephyr_prebuilt.elf binary,
 which is a link of the Zephyr kernel without various build-time
 generated data structures (such as the GDT) inserted into it.
 This kernel image has been properly padded such that inserting
 these data structures will not disturb the memory addresses of
 other symbols.

 The output is a GDT whose contents depend on the kernel
 configuration. With no memory protection features enabled,
 we generate flat 32-bit code and data segments. If hardware-
 based stack overflow protection or userspace is enabled,
 we additionally create descriptors for the main and double-
 fault IA tasks, needed for userspace privilege elevation and
 double-fault handling. If userspace is enabled, we also create
 flat code/data segments for ring 3 execution.
 """

 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     sys.exit("pyelftools is out of date, need version 0.24 or later")


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


 def error(text):
     sys.exit(os.path.basename(sys.argv[0]) + ": " + text)


 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):
     debug("create pseudo decriptor: %x %x" % (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):
     debug("create code or data entry: %x %x %x %x %x" %
           (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):
     debug("create TSS entry: %x %x %x" % (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()
     if "VERBOSE" in os.environ:
         args.verbose = 1


 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_USERSPACE" in syms:
         num_entries = 7
     elif "CONFIG_HW_STACK_PROTECTION" in syms:
         num_entries = 5
     else:
         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 num_entries >= 5:
             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 num_entries == 7:
             # 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

	"""Generate a Global Descriptor Table (GDT) for x86 CPUs.

	For additional detail on GDT and x86 memory management, please
	consult the IA Architecture SW Developer Manual, vol. 3.

	This script accepts as input the zephyr_prebuilt.elf binary,
	which is a link of the Zephyr kernel without various build-time
	generated data structures (such as the GDT) inserted into it.
	This kernel image has been properly padded such that inserting
	these data structures will not disturb the memory addresses of
	other symbols.

	The output is a GDT whose contents depend on the kernel
	configuration. With no memory protection features enabled,
	we generate flat 32-bit code and data segments. If hardware-
	based stack overflow protection or userspace is enabled,
	we additionally create descriptors for the main and double-
	fault IA tasks, needed for userspace privilege elevation and
	double-fault handling. If userspace is enabled, we also create
	flat code/data segments for ring 3 execution.
	"""

	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.exit("pyelftools is out of date, need version 0.24 or later")


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


	def error(text):
	sys.exit(os.path.basename(sys.argv[0]) + ": " + text)


	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):
	debug("create pseudo decriptor: %x %x" % (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):
	debug("create code or data entry: %x %x %x %x %x" %
	(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):
	debug("create TSS entry: %x %x %x" % (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()
	if "VERBOSE" in os.environ:
	args.verbose = 1


	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_USERSPACE" in syms:
	num_entries = 7
	elif "CONFIG_HW_STACK_PROTECTION" in syms:
	num_entries = 5
	else:
	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 num_entries >= 5:
	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 num_entries == 7:
	# 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()