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

 #!/usr/bin/env python3
 #
 # Copyright (c) 2017 Intel Corporation
 # Copyright (c) 2020 Nordic Semiconductor NA
 #
 # SPDX-License-Identifier: Apache-2.0
 """Translate generic handles into ones optimized for the application.

 Immutable device data includes information about dependencies,
 e.g. that a particular sensor is controlled through a specific I2C bus
 and that it signals event on a pin on a specific GPIO controller.
 This information is encoded in the first-pass binary using identifiers
 derived from the devicetree.  This script extracts those identifiers
 and replaces them with ones optimized for use with the devices
 actually present.

 For example the sensor might have a first-pass handle defined by its
 devicetree ordinal 52, with the I2C driver having ordinal 24 and the
 GPIO controller ordinal 14.  The runtime ordinal is the index of the
 corresponding device in the static devicetree array, which might be 6,
 5, and 3, respectively.

 The output is a C source file that provides alternative definitions
 for the array contents referenced from the immutable device objects.
 In the final link these definitions supersede the ones in the
 driver-specific object file.
 """

 import sys
 import argparse
 import os
 import struct
 import pickle
 from packaging import version

 import elftools
 from elftools.elf.elffile import ELFFile
 from elftools.elf.sections import SymbolTableSection
 import elftools.elf.enums

 # This is needed to load edt.pickle files.
 sys.path.insert(0, os.path.join(os.path.dirname(__file__),
                                 'dts', 'python-devicetree', 'src'))
 from devicetree import edtlib  # pylint: disable=unused-import

 if version.parse(elftools.__version__) < version.parse('0.24'):
     sys.exit("pyelftools is out of date, need version 0.24 or later")

 scr = os.path.basename(sys.argv[0])

 def debug(text):
     if not args.verbose:
         return
     sys.stdout.write(scr + ": " + text + "\n")

 def parse_args():
     global args

     parser = argparse.ArgumentParser(
         description=__doc__,
         formatter_class=argparse.RawDescriptionHelpFormatter)

     parser.add_argument("-k", "--kernel", required=True,
                         help="Input zephyr ELF binary")
     parser.add_argument("-d", "--num-dynamic-devices", required=False, default=0,
                         type=int, help="Input number of dynamic devices allowed")
     parser.add_argument("-o", "--output-source", required=True,
             help="Output source file")

     parser.add_argument("-v", "--verbose", action="store_true",
                         help="Print extra debugging information")

     parser.add_argument("-z", "--zephyr-base",
                         help="Path to current Zephyr base. If this argument \
                         is not provided the environment will be checked for \
                         the ZEPHYR_BASE environment variable.")

     parser.add_argument("-s", "--start-symbol", required=True,
                         help="Symbol name of the section which contains the \
                         devices. The symbol name must point to the first \
                         device in that section.")

     args = parser.parse_args()
     if "VERBOSE" in os.environ:
         args.verbose = 1

     ZEPHYR_BASE = args.zephyr_base or os.getenv("ZEPHYR_BASE")

     if ZEPHYR_BASE is None:
         sys.exit("-z / --zephyr-base not provided. Please provide "
                  "--zephyr-base or set ZEPHYR_BASE in environment")

     sys.path.insert(0, os.path.join(ZEPHYR_BASE, "scripts/dts"))


 def symbol_data(elf, sym):
     addr = sym.entry.st_value
     len = sym.entry.st_size
     for section in elf.iter_sections():
         start = section['sh_addr']
         end = start + section['sh_size']

         if (start <= addr) and (addr + len) <= end:
             offset = addr - section['sh_addr']
             return bytes(section.data()[offset:offset + len])

 def symbol_handle_data(elf, sym):
     data = symbol_data(elf, sym)
     if data:
         format = "<" if elf.little_endian else ">"
         format += "%uh" % (len(data) / 2)
         return struct.unpack(format, data)

 # These match the corresponding constants in <device.h>
 DEVICE_HANDLE_SEP = -32768
 DEVICE_HANDLE_ENDS = 32767
 DEVICE_HANDLE_NULL = 0
 def handle_name(hdl):
     if hdl == DEVICE_HANDLE_SEP:
         return "DEVICE_HANDLE_SEP"
     if hdl == DEVICE_HANDLE_ENDS:
         return "DEVICE_HANDLE_ENDS"
     if hdl == 0:
         return "DEVICE_HANDLE_NULL"
     return str(int(hdl))

 class Device:
     """
     Represents information about a device object and its references to other objects.
     """
     def __init__(self, elf, ld_constants, sym, addr):
         self.elf = elf
         self.ld_constants = ld_constants
         self.sym = sym
         self.addr = addr
         # Point to the handles instance associated with the device;
         # assigned by correlating the device struct handles pointer
         # value with the addr of a Handles instance.
         self.__handles = None
         self.__pm = None

     @property
     def obj_handles(self):
         """
         Returns the value from the device struct handles field, pointing to the
         array of handles for devices this device depends on.
         """
         if self.__handles is None:
             data = symbol_data(self.elf, self.sym)
             format = "<" if self.elf.little_endian else ">"
             if self.elf.elfclass == 32:
                 format += "I"
                 size = 4
             else:
                 format += "Q"
                 size = 8
             offset = self.ld_constants["_DEVICE_STRUCT_HANDLES_OFFSET"]
             self.__handles = struct.unpack(format, data[offset:offset + size])[0]
         return self.__handles

     @property
     def obj_pm(self):
         """
         Returns the value from the device struct pm field, pointing to the
         pm struct for this device.
         """
         if self.__pm is None:
             data = symbol_data(self.elf, self.sym)
             format = "<" if self.elf.little_endian else ">"
             if self.elf.elfclass == 32:
                 format += "I"
                 size = 4
             else:
                 format += "Q"
                 size = 8
             offset = self.ld_constants["_DEVICE_STRUCT_PM_OFFSET"]
             self.__pm = struct.unpack(format, data[offset:offset + size])[0]
         return self.__pm

 class PMDevice:
     """
     Represents information about a pm_device object and its references to other objects.
     """
     def __init__(self, elf, ld_constants, sym, addr):
         self.elf = elf
         self.ld_constants = ld_constants
         self.sym = sym
         self.addr = addr

         # Point to the device instance associated with the pm_device;
         self.__flags = None

     def is_domain(self):
         """
         Checks if the device that this pm struct belongs is a power domain.
         """
         if self.__flags is None:
             data = symbol_data(self.elf, self.sym)
             format = "<" if self.elf.little_endian else ">"
             if self.elf.elfclass == 32:
                 format += "I"
                 size = 4
             else:
                 format += "Q"
                 size = 8
             offset = self.ld_constants["_PM_DEVICE_STRUCT_FLAGS_OFFSET"]
             self.__flags = struct.unpack(format, data[offset:offset + size])[0]
         return self.__flags & (1 << self.ld_constants["_PM_DEVICE_FLAG_PD"])

 class Handles:
     def __init__(self, sym, addr, handles, node):
         self.sym = sym
         self.addr = addr
         self.handles = handles
         self.node = node
         self.dep_ord = None
         self.dev_deps = None
         self.ext_deps = None

 def main():
     parse_args()

     assert args.kernel, "--kernel ELF required to extract data"
     elf = ELFFile(open(args.kernel, "rb"))

     edtser = os.path.join(os.path.split(args.kernel)[0], "edt.pickle")
     with open(edtser, 'rb') as f:
         edt = pickle.load(f)

     pm_devices = {}
     devices = []
     handles = []
     # Leading _ are stripped from the stored constant key

     want_constants = set([args.start_symbol,
                           "_DEVICE_STRUCT_SIZEOF",
                           "_DEVICE_STRUCT_HANDLES_OFFSET"])
     if args.num_dynamic_devices != 0:
         want_constants.update(["_PM_DEVICE_FLAG_PD",
                                "_DEVICE_STRUCT_PM_OFFSET",
                                "_PM_DEVICE_STRUCT_FLAGS_OFFSET"])
     ld_constants = dict()

     for section in elf.iter_sections():
         if isinstance(section, SymbolTableSection):
             for sym in section.iter_symbols():
                 if sym.name in want_constants:
                     ld_constants[sym.name] = sym.entry.st_value
                     continue
                 if sym.entry.st_info.type != 'STT_OBJECT':
                     continue
                 if sym.name.startswith("__device"):
                     addr = sym.entry.st_value
                     if sym.name.startswith("__device_"):
                         devices.append(Device(elf, ld_constants, sym, addr))
                         debug("device %s" % (sym.name,))
                     elif sym.name.startswith("__devicehdl_"):
                         hdls = symbol_handle_data(elf, sym)

                         # The first element of the hdls array is the dependency
                         # ordinal of the device, which identifies the devicetree
                         # node.
                         node = edt.dep_ord2node[hdls[0]] if (hdls and hdls[0] != 0) else None
                         handles.append(Handles(sym, addr, hdls, node))
                         debug("handles %s %d %s" % (sym.name, hdls[0] if hdls else -1, node))
                 if sym.name.startswith("__pm_device__") and not sym.name.endswith("_slot"):
                     addr = sym.entry.st_value
                     pm_devices[addr] = PMDevice(elf, ld_constants, sym, addr)
                     debug("pm device %s" % (sym.name,))

     assert len(want_constants) == len(ld_constants), "linker map data incomplete"

     devices = sorted(devices, key = lambda k: k.sym.entry.st_value)

     device_start_addr = ld_constants[args.start_symbol]
     device_size = 0

     assert len(devices) == len(handles), 'mismatch devices and handles'

     used_nodes = set()
     for handle in handles:
         handle.device = None
         for device in devices:
             if handle.addr == device.obj_handles:
                 handle.device = device
                 break
         device = handle.device
         assert device, 'no device for %s' % (handle.sym.name,)

         device.handle = handle

         if device_size == 0:
             device_size = device.sym.entry.st_size

         # The device handle is one plus the ordinal of this device in
         # the device table.
         device.dev_handle = 1 + int((device.sym.entry.st_value - device_start_addr) / device_size)
         debug("%s dev ordinal %d" % (device.sym.name, device.dev_handle))

         n = handle.node
         if n is not None:
             debug("%s dev ordinal %d\n\t%s" % (n.path, device.dev_handle, ' ; '.join(str(_) for _ in handle.handles)))
             used_nodes.add(n)
             n.__device = device
         else:
             debug("orphan %d" % (device.dev_handle,))
         hv = handle.handles
         hvi = 1
         handle.dev_deps = []
         handle.dev_injected = []
         handle.dev_sups = []
         hdls = handle.dev_deps
         while hvi < len(hv):
             h = hv[hvi]
             if h == DEVICE_HANDLE_ENDS:
                 break
             if h == DEVICE_HANDLE_SEP:
                 if hdls == handle.dev_deps:
                     hdls = handle.dev_injected
                 else:
                     hdls = handle.dev_sups
             else:
                 hdls.append(h)
                 n = edt
             hvi += 1

     # Compute the dependency graph induced from the full graph restricted to the
     # the nodes that exist in the application.  Note that the edges in the
     # induced graph correspond to paths in the full graph.
     root = edt.dep_ord2node[0]
     assert root not in used_nodes

     for n in used_nodes:
         # Where we're storing the final set of nodes: these are all used
         n.__depends = set()
         n.__supports = set()

         deps = set(n.depends_on)
         debug("\nNode: %s\nOrig deps:\n\t%s" % (n.path, "\n\t".join([dn.path for dn in deps])))
         while len(deps) > 0:
             dn = deps.pop()
             if dn in used_nodes:
                 # this is used
                 n.__depends.add(dn)
             elif dn != root:
                 # forward the dependency up one level
                 for ddn in dn.depends_on:
                     deps.add(ddn)
         debug("Final deps:\n\t%s\n" % ("\n\t".join([ _dn.path for _dn in n.__depends])))

         sups = set(n.required_by)
         debug("\nOrig sups:\n\t%s" % ("\n\t".join([dn.path for dn in sups])))
         while len(sups) > 0:
             sn = sups.pop()
             if sn in used_nodes:
                 # this is used
                 n.__supports.add(sn)
             else:
                 # forward the support down one level
                 for ssn in sn.required_by:
                     sups.add(ssn)
         debug("\nFinal sups:\n\t%s" % ("\n\t".join([_sn.path for _sn in n.__supports])))

     with open(args.output_source, "w") as fp:
         fp.write('#include <zephyr/device.h>\n')
         fp.write('#include <zephyr/toolchain.h>\n')

         for dev in devices:
             hs = dev.handle
             assert hs, "no hs for %s" % (dev.sym.name,)
             dep_paths = []
             inj_paths = []
             sup_paths = []
             hdls = []

             sn = hs.node
             if sn:
                 hdls.extend(dn.__device.dev_handle for dn in sn.__depends)
                 for dn in sn.depends_on:
                     if dn in sn.__depends:
                         dep_paths.append(dn.path)
                     else:
                         dep_paths.append('(%s)' % dn.path)
             # Force separator to signal start of injected dependencies
             hdls.append(DEVICE_HANDLE_SEP)
             for inj in hs.dev_injected:
                 if inj not in edt.dep_ord2node:
                     continue
                 expected = edt.dep_ord2node[inj]
                 if expected in used_nodes:
                     inj_paths.append(expected.path)
                     hdls.append(expected.__device.dev_handle)

             # Force separator to signal start of supported devices
             hdls.append(DEVICE_HANDLE_SEP)
             if len(hs.dev_sups) > 0:
                 for dn in sn.required_by:
                     if dn in sn.__supports:
                         sup_paths.append(dn.path)
                     else:
                         sup_paths.append('(%s)' % dn.path)
                 hdls.extend(dn.__device.dev_handle for dn in sn.__supports)

             if args.num_dynamic_devices != 0:
                 pm = pm_devices.get(dev.obj_pm)
                 if pm and pm.is_domain():
                     hdls.extend(DEVICE_HANDLE_NULL for dn in range(args.num_dynamic_devices))

             # Terminate the array with the end symbol
             hdls.append(DEVICE_HANDLE_ENDS)

             lines = [
                 '',
                 '/* %d : %s:' % (dev.dev_handle, (sn and sn.path) or "sysinit"),
             ]

             if len(dep_paths) > 0:
                 lines.append(' * Direct Dependencies:')
                 lines.append(' *   - %s' % ('\n *   - '.join(dep_paths)))
             if len(inj_paths) > 0:
                 lines.append(' * Injected Dependencies:')
                 lines.append(' *   - %s' % ('\n *   - '.join(inj_paths)))
             if len(sup_paths) > 0:
                 lines.append(' * Supported:')
                 lines.append(' *   - %s' % ('\n *   - '.join(sup_paths)))

             lines.extend([
                 ' */',
                 'const device_handle_t __aligned(2) __attribute__((__section__(".__device_handles_pass2")))',
                 '%s[] = { %s };' % (hs.sym.name, ', '.join([handle_name(_h) for _h in hdls])),
                 '',
             ])

             fp.write('\n'.join(lines))

 if __name__ == "__main__":
     main()
	#!/usr/bin/env python3
	#
	# Copyright (c) 2017 Intel Corporation
	# Copyright (c) 2020 Nordic Semiconductor NA
	#
	# SPDX-License-Identifier: Apache-2.0
	"""Translate generic handles into ones optimized for the application.

	Immutable device data includes information about dependencies,
	e.g. that a particular sensor is controlled through a specific I2C bus
	and that it signals event on a pin on a specific GPIO controller.
	This information is encoded in the first-pass binary using identifiers
	derived from the devicetree. This script extracts those identifiers
	and replaces them with ones optimized for use with the devices
	actually present.

	For example the sensor might have a first-pass handle defined by its
	devicetree ordinal 52, with the I2C driver having ordinal 24 and the
	GPIO controller ordinal 14. The runtime ordinal is the index of the
	corresponding device in the static devicetree array, which might be 6,
	5, and 3, respectively.

	The output is a C source file that provides alternative definitions
	for the array contents referenced from the immutable device objects.
	In the final link these definitions supersede the ones in the
	driver-specific object file.
	"""

	import sys
	import argparse
	import os
	import struct
	import pickle
	from packaging import version

	import elftools
	from elftools.elf.elffile import ELFFile
	from elftools.elf.sections import SymbolTableSection
	import elftools.elf.enums

	# This is needed to load edt.pickle files.
	sys.path.insert(0, os.path.join(os.path.dirname(__file__),
	'dts', 'python-devicetree', 'src'))
	from devicetree import edtlib # pylint: disable=unused-import

	if version.parse(elftools.__version__) < version.parse('0.24'):
	sys.exit("pyelftools is out of date, need version 0.24 or later")

	scr = os.path.basename(sys.argv[0])

	def debug(text):
	if not args.verbose:
	return
	sys.stdout.write(scr + ": " + text + "\n")

	def parse_args():
	global args

	parser = argparse.ArgumentParser(
	description=__doc__,
	formatter_class=argparse.RawDescriptionHelpFormatter)

	parser.add_argument("-k", "--kernel", required=True,
	help="Input zephyr ELF binary")
	parser.add_argument("-d", "--num-dynamic-devices", required=False, default=0,
	type=int, help="Input number of dynamic devices allowed")
	parser.add_argument("-o", "--output-source", required=True,
	help="Output source file")

	parser.add_argument("-v", "--verbose", action="store_true",
	help="Print extra debugging information")

	parser.add_argument("-z", "--zephyr-base",
	help="Path to current Zephyr base. If this argument \
	is not provided the environment will be checked for \
	the ZEPHYR_BASE environment variable.")

	parser.add_argument("-s", "--start-symbol", required=True,
	help="Symbol name of the section which contains the \
	devices. The symbol name must point to the first \
	device in that section.")

	args = parser.parse_args()
	if "VERBOSE" in os.environ:
	args.verbose = 1

	ZEPHYR_BASE = args.zephyr_base or os.getenv("ZEPHYR_BASE")

	if ZEPHYR_BASE is None:
	sys.exit("-z / --zephyr-base not provided. Please provide "
	"--zephyr-base or set ZEPHYR_BASE in environment")

	sys.path.insert(0, os.path.join(ZEPHYR_BASE, "scripts/dts"))


	def symbol_data(elf, sym):
	addr = sym.entry.st_value
	len = sym.entry.st_size
	for section in elf.iter_sections():
	start = section['sh_addr']
	end = start + section['sh_size']

	if (start <= addr) and (addr + len) <= end:
	offset = addr - section['sh_addr']
	return bytes(section.data()[offset:offset + len])

	def symbol_handle_data(elf, sym):
	data = symbol_data(elf, sym)
	if data:
	format = "<" if elf.little_endian else ">"
	format += "%uh" % (len(data) / 2)
	return struct.unpack(format, data)

	# These match the corresponding constants in <device.h>
	DEVICE_HANDLE_SEP = -32768
	DEVICE_HANDLE_ENDS = 32767
	DEVICE_HANDLE_NULL = 0
	def handle_name(hdl):
	if hdl == DEVICE_HANDLE_SEP:
	return "DEVICE_HANDLE_SEP"
	if hdl == DEVICE_HANDLE_ENDS:
	return "DEVICE_HANDLE_ENDS"
	if hdl == 0:
	return "DEVICE_HANDLE_NULL"
	return str(int(hdl))

	class Device:
	"""
	Represents information about a device object and its references to other objects.
	"""
	def __init__(self, elf, ld_constants, sym, addr):
	self.elf = elf
	self.ld_constants = ld_constants
	self.sym = sym
	self.addr = addr
	# Point to the handles instance associated with the device;
	# assigned by correlating the device struct handles pointer
	# value with the addr of a Handles instance.
	self.__handles = None
	self.__pm = None

	@property
	def obj_handles(self):
	"""
	Returns the value from the device struct handles field, pointing to the
	array of handles for devices this device depends on.
	"""
	if self.__handles is None:
	data = symbol_data(self.elf, self.sym)
	format = "<" if self.elf.little_endian else ">"
	if self.elf.elfclass == 32:
	format += "I"
	size = 4
	else:
	format += "Q"
	size = 8
	offset = self.ld_constants["_DEVICE_STRUCT_HANDLES_OFFSET"]
	self.__handles = struct.unpack(format, data[offset:offset + size])[0]
	return self.__handles

	@property
	def obj_pm(self):
	"""
	Returns the value from the device struct pm field, pointing to the
	pm struct for this device.
	"""
	if self.__pm is None:
	data = symbol_data(self.elf, self.sym)
	format = "<" if self.elf.little_endian else ">"
	if self.elf.elfclass == 32:
	format += "I"
	size = 4
	else:
	format += "Q"
	size = 8
	offset = self.ld_constants["_DEVICE_STRUCT_PM_OFFSET"]
	self.__pm = struct.unpack(format, data[offset:offset + size])[0]
	return self.__pm

	class PMDevice:
	"""
	Represents information about a pm_device object and its references to other objects.
	"""
	def __init__(self, elf, ld_constants, sym, addr):
	self.elf = elf
	self.ld_constants = ld_constants
	self.sym = sym
	self.addr = addr

	# Point to the device instance associated with the pm_device;
	self.__flags = None

	def is_domain(self):
	"""
	Checks if the device that this pm struct belongs is a power domain.
	"""
	if self.__flags is None:
	data = symbol_data(self.elf, self.sym)
	format = "<" if self.elf.little_endian else ">"
	if self.elf.elfclass == 32:
	format += "I"
	size = 4
	else:
	format += "Q"
	size = 8
	offset = self.ld_constants["_PM_DEVICE_STRUCT_FLAGS_OFFSET"]
	self.__flags = struct.unpack(format, data[offset:offset + size])[0]
	return self.__flags & (1 << self.ld_constants["_PM_DEVICE_FLAG_PD"])

	class Handles:
	def __init__(self, sym, addr, handles, node):
	self.sym = sym
	self.addr = addr
	self.handles = handles
	self.node = node
	self.dep_ord = None
	self.dev_deps = None
	self.ext_deps = None

	def main():
	parse_args()

	assert args.kernel, "--kernel ELF required to extract data"
	elf = ELFFile(open(args.kernel, "rb"))

	edtser = os.path.join(os.path.split(args.kernel)[0], "edt.pickle")
	with open(edtser, 'rb') as f:
	edt = pickle.load(f)

	pm_devices = {}
	devices = []
	handles = []
	# Leading _ are stripped from the stored constant key

	want_constants = set([args.start_symbol,
	"_DEVICE_STRUCT_SIZEOF",
	"_DEVICE_STRUCT_HANDLES_OFFSET"])
	if args.num_dynamic_devices != 0:
	want_constants.update(["_PM_DEVICE_FLAG_PD",
	"_DEVICE_STRUCT_PM_OFFSET",
	"_PM_DEVICE_STRUCT_FLAGS_OFFSET"])
	ld_constants = dict()

	for section in elf.iter_sections():
	if isinstance(section, SymbolTableSection):
	for sym in section.iter_symbols():
	if sym.name in want_constants:
	ld_constants[sym.name] = sym.entry.st_value
	continue
	if sym.entry.st_info.type != 'STT_OBJECT':
	continue
	if sym.name.startswith("__device"):
	addr = sym.entry.st_value
	if sym.name.startswith("__device_"):
	devices.append(Device(elf, ld_constants, sym, addr))
	debug("device %s" % (sym.name,))
	elif sym.name.startswith("__devicehdl_"):
	hdls = symbol_handle_data(elf, sym)

	# The first element of the hdls array is the dependency
	# ordinal of the device, which identifies the devicetree
	# node.
	node = edt.dep_ord2node[hdls[0]] if (hdls and hdls[0] != 0) else None
	handles.append(Handles(sym, addr, hdls, node))
	debug("handles %s %d %s" % (sym.name, hdls[0] if hdls else -1, node))
	if sym.name.startswith("__pm_device__") and not sym.name.endswith("_slot"):
	addr = sym.entry.st_value
	pm_devices[addr] = PMDevice(elf, ld_constants, sym, addr)
	debug("pm device %s" % (sym.name,))

	assert len(want_constants) == len(ld_constants), "linker map data incomplete"

	devices = sorted(devices, key = lambda k: k.sym.entry.st_value)

	device_start_addr = ld_constants[args.start_symbol]
	device_size = 0

	assert len(devices) == len(handles), 'mismatch devices and handles'

	used_nodes = set()
	for handle in handles:
	handle.device = None
	for device in devices:
	if handle.addr == device.obj_handles:
	handle.device = device
	break
	device = handle.device
	assert device, 'no device for %s' % (handle.sym.name,)

	device.handle = handle

	if device_size == 0:
	device_size = device.sym.entry.st_size

	# The device handle is one plus the ordinal of this device in
	# the device table.
	device.dev_handle = 1 + int((device.sym.entry.st_value - device_start_addr) / device_size)
	debug("%s dev ordinal %d" % (device.sym.name, device.dev_handle))

	n = handle.node
	if n is not None:
	debug("%s dev ordinal %d\n\t%s" % (n.path, device.dev_handle, ' ; '.join(str(_) for _ in handle.handles)))
	used_nodes.add(n)
	n.__device = device
	else:
	debug("orphan %d" % (device.dev_handle,))
	hv = handle.handles
	hvi = 1
	handle.dev_deps = []
	handle.dev_injected = []
	handle.dev_sups = []
	hdls = handle.dev_deps
	while hvi < len(hv):
	h = hv[hvi]
	if h == DEVICE_HANDLE_ENDS:
	break
	if h == DEVICE_HANDLE_SEP:
	if hdls == handle.dev_deps:
	hdls = handle.dev_injected
	else:
	hdls = handle.dev_sups
	else:
	hdls.append(h)
	n = edt
	hvi += 1

	# Compute the dependency graph induced from the full graph restricted to the
	# the nodes that exist in the application. Note that the edges in the
	# induced graph correspond to paths in the full graph.
	root = edt.dep_ord2node[0]
	assert root not in used_nodes

	for n in used_nodes:
	# Where we're storing the final set of nodes: these are all used
	n.__depends = set()
	n.__supports = set()

	deps = set(n.depends_on)
	debug("\nNode: %s\nOrig deps:\n\t%s" % (n.path, "\n\t".join([dn.path for dn in deps])))
	while len(deps) > 0:
	dn = deps.pop()
	if dn in used_nodes:
	# this is used
	n.__depends.add(dn)
	elif dn != root:
	# forward the dependency up one level
	for ddn in dn.depends_on:
	deps.add(ddn)
	debug("Final deps:\n\t%s\n" % ("\n\t".join([ _dn.path for _dn in n.__depends])))

	sups = set(n.required_by)
	debug("\nOrig sups:\n\t%s" % ("\n\t".join([dn.path for dn in sups])))
	while len(sups) > 0:
	sn = sups.pop()
	if sn in used_nodes:
	# this is used
	n.__supports.add(sn)
	else:
	# forward the support down one level
	for ssn in sn.required_by:
	sups.add(ssn)
	debug("\nFinal sups:\n\t%s" % ("\n\t".join([_sn.path for _sn in n.__supports])))

	with open(args.output_source, "w") as fp:
	fp.write('#include <zephyr/device.h>\n')
	fp.write('#include <zephyr/toolchain.h>\n')

	for dev in devices:
	hs = dev.handle
	assert hs, "no hs for %s" % (dev.sym.name,)
	dep_paths = []
	inj_paths = []
	sup_paths = []
	hdls = []

	sn = hs.node
	if sn:
	hdls.extend(dn.__device.dev_handle for dn in sn.__depends)
	for dn in sn.depends_on:
	if dn in sn.__depends:
	dep_paths.append(dn.path)
	else:
	dep_paths.append('(%s)' % dn.path)
	# Force separator to signal start of injected dependencies
	hdls.append(DEVICE_HANDLE_SEP)
	for inj in hs.dev_injected:
	if inj not in edt.dep_ord2node:
	continue
	expected = edt.dep_ord2node[inj]
	if expected in used_nodes:
	inj_paths.append(expected.path)
	hdls.append(expected.__device.dev_handle)

	# Force separator to signal start of supported devices
	hdls.append(DEVICE_HANDLE_SEP)
	if len(hs.dev_sups) > 0:
	for dn in sn.required_by:
	if dn in sn.__supports:
	sup_paths.append(dn.path)
	else:
	sup_paths.append('(%s)' % dn.path)
	hdls.extend(dn.__device.dev_handle for dn in sn.__supports)

	if args.num_dynamic_devices != 0:
	pm = pm_devices.get(dev.obj_pm)
	if pm and pm.is_domain():
	hdls.extend(DEVICE_HANDLE_NULL for dn in range(args.num_dynamic_devices))

	# Terminate the array with the end symbol
	hdls.append(DEVICE_HANDLE_ENDS)

	lines = [
	'',
	'/* %d : %s:' % (dev.dev_handle, (sn and sn.path) or "sysinit"),
	]

	if len(dep_paths) > 0:
	lines.append(' * Direct Dependencies:')
	lines.append(' * - %s' % ('\n * - '.join(dep_paths)))
	if len(inj_paths) > 0:
	lines.append(' * Injected Dependencies:')
	lines.append(' * - %s' % ('\n * - '.join(inj_paths)))
	if len(sup_paths) > 0:
	lines.append(' * Supported:')
	lines.append(' * - %s' % ('\n * - '.join(sup_paths)))

	lines.extend([
	' */',
	'const device_handle_t __aligned(2) __attribute__((__section__(".__device_handles_pass2")))',
	'%s[] = { %s };' % (hs.sym.name, ', '.join([handle_name(_h) for _h in hdls])),
	'',
	])

	fp.write('\n'.join(lines))

	if __name__ == "__main__":
	main()