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#!/usr/bin/python
# SPDX-License-Identifier: GPL-2.0+
#
# Copyright (C) 2016 Google, Inc
# Written by Simon Glass <sjg@chromium.org>
#
from enum import IntEnum
import struct
import sys
from dtoc import fdt_util
import libfdt
from libfdt import QUIET_NOTFOUND
from patman import tools
# This deals with a device tree, presenting it as an assortment of Node and
# Prop objects, representing nodes and properties, respectively. This file
# contains the base classes and defines the high-level API. You can use
# FdtScan() as a convenience function to create and scan an Fdt.
# This implementation uses a libfdt Python library to access the device tree,
# so it is fairly efficient.
# A list of types we support
class Type(IntEnum):
(BYTE, INT, STRING, BOOL, INT64) = range(5)
def is_wider_than(self, other):
"""Check if another type is 'wider' than this one
A wider type is one that holds more information than an earlier one,
similar to the concept of type-widening in C.
This uses a simple arithmetic comparison, since type values are in order
from narrowest (BYTE) to widest (INT64).
Args:
other: Other type to compare against
Return:
True if the other type is wider
"""
return self.value > other.value
def CheckErr(errnum, msg):
if errnum:
raise ValueError('Error %d: %s: %s' %
(errnum, libfdt.fdt_strerror(errnum), msg))
def BytesToValue(data):
"""Converts a string of bytes into a type and value
Args:
A bytes value (which on Python 2 is an alias for str)
Return:
A tuple:
Type of data
Data, either a single element or a list of elements. Each element
is one of:
Type.STRING: str/bytes value from the property
Type.INT: a byte-swapped integer stored as a 4-byte str/bytes
Type.BYTE: a byte stored as a single-byte str/bytes
"""
data = bytes(data)
size = len(data)
strings = data.split(b'\0')
is_string = True
count = len(strings) - 1
if count > 0 and not len(strings[-1]):
for string in strings[:-1]:
if not string:
is_string = False
break
for ch in string:
if ch < 32 or ch > 127:
is_string = False
break
else:
is_string = False
if is_string:
if count == 1:
return Type.STRING, strings[0].decode()
else:
return Type.STRING, [s.decode() for s in strings[:-1]]
if size % 4:
if size == 1:
return Type.BYTE, chr(data[0])
else:
return Type.BYTE, [chr(ch) for ch in list(data)]
val = []
for i in range(0, size, 4):
val.append(data[i:i + 4])
if size == 4:
return Type.INT, val[0]
else:
return Type.INT, val
class Prop:
"""A device tree property
Properties:
name: Property name (as per the device tree)
value: Property value as a string of bytes, or a list of strings of
bytes
type: Value type
"""
def __init__(self, node, offset, name, data):
self._node = node
self._offset = offset
self.name = name
self.value = None
self.bytes = bytes(data)
self.dirty = False
if not data:
self.type = Type.BOOL
self.value = True
return
self.type, self.value = BytesToValue(bytes(data))
def RefreshOffset(self, poffset):
self._offset = poffset
def Widen(self, newprop):
"""Figure out which property type is more general
Given a current property and a new property, this function returns the
one that is less specific as to type. The less specific property will
be ble to represent the data in the more specific property. This is
used for things like:
node1 {
compatible = "fred";
value = <1>;
};
node1 {
compatible = "fred";
value = <1 2>;
};
He we want to use an int array for 'value'. The first property
suggests that a single int is enough, but the second one shows that
it is not. Calling this function with these two propertes would
update the current property to be like the second, since it is less
specific.
"""
if self.type.is_wider_than(newprop.type):
if self.type == Type.INT and newprop.type == Type.BYTE:
if type(self.value) == list:
new_value = []
for val in self.value:
new_value += [chr(by) for by in val]
else:
new_value = [chr(by) for by in self.value]
self.value = new_value
self.type = newprop.type
if type(newprop.value) == list and type(self.value) != list:
self.value = [self.value]
if type(self.value) == list and len(newprop.value) > len(self.value):
val = self.GetEmpty(self.type)
while len(self.value) < len(newprop.value):
self.value.append(val)
@classmethod
def GetEmpty(self, type):
"""Get an empty / zero value of the given type
Returns:
A single value of the given type
"""
if type == Type.BYTE:
return chr(0)
elif type == Type.INT:
return struct.pack('>I', 0);
elif type == Type.STRING:
return ''
else:
return True
def GetOffset(self):
"""Get the offset of a property
Returns:
The offset of the property (struct fdt_property) within the file
"""
self._node._fdt.CheckCache()
return self._node._fdt.GetStructOffset(self._offset)
def SetInt(self, val):
"""Set the integer value of the property
The device tree is marked dirty so that the value will be written to
the block on the next sync.
Args:
val: Integer value (32-bit, single cell)
"""
self.bytes = struct.pack('>I', val);
self.value = self.bytes
self.type = Type.INT
self.dirty = True
def SetData(self, bytes):
"""Set the value of a property as bytes
Args:
bytes: New property value to set
"""
self.bytes = bytes
self.type, self.value = BytesToValue(bytes)
self.dirty = True
def Sync(self, auto_resize=False):
"""Sync property changes back to the device tree
This updates the device tree blob with any changes to this property
since the last sync.
Args:
auto_resize: Resize the device tree automatically if it does not
have enough space for the update
Raises:
FdtException if auto_resize is False and there is not enough space
"""
if self._offset is None or self.dirty:
node = self._node
fdt_obj = node._fdt._fdt_obj
if auto_resize:
while fdt_obj.setprop(node.Offset(), self.name, self.bytes,
(libfdt.NOSPACE,)) == -libfdt.NOSPACE:
fdt_obj.resize(fdt_obj.totalsize() + 1024 +
len(self.bytes))
fdt_obj.setprop(node.Offset(), self.name, self.bytes)
else:
fdt_obj.setprop(node.Offset(), self.name, self.bytes)
class Node:
"""A device tree node
Properties:
offset: Integer offset in the device tree
name: Device tree node tname
path: Full path to node, along with the node name itself
_fdt: Device tree object
subnodes: A list of subnodes for this node, each a Node object
props: A dict of properties for this node, each a Prop object.
Keyed by property name
"""
def __init__(self, fdt, parent, offset, name, path):
self._fdt = fdt
self.parent = parent
self._offset = offset
self.name = name
self.path = path
self.subnodes = []
self.props = {}
def GetFdt(self):
"""Get the Fdt object for this node
Returns:
Fdt object
"""
return self._fdt
def FindNode(self, name):
"""Find a node given its name
Args:
name: Node name to look for
Returns:
Node object if found, else None
"""
for subnode in self.subnodes:
if subnode.name == name:
return subnode
return None
def Offset(self):
"""Returns the offset of a node, after checking the cache
This should be used instead of self._offset directly, to ensure that
the cache does not contain invalid offsets.
"""
self._fdt.CheckCache()
return self._offset
def Scan(self):
"""Scan a node's properties and subnodes
This fills in the props and subnodes properties, recursively
searching into subnodes so that the entire tree is built.
"""
fdt_obj = self._fdt._fdt_obj
self.props = self._fdt.GetProps(self)
phandle = fdt_obj.get_phandle(self.Offset())
if phandle:
self._fdt.phandle_to_node[phandle] = self
offset = fdt_obj.first_subnode(self.Offset(), QUIET_NOTFOUND)
while offset >= 0:
sep = '' if self.path[-1] == '/' else '/'
name = fdt_obj.get_name(offset)
path = self.path + sep + name
node = Node(self._fdt, self, offset, name, path)
self.subnodes.append(node)
node.Scan()
offset = fdt_obj.next_subnode(offset, QUIET_NOTFOUND)
def Refresh(self, my_offset):
"""Fix up the _offset for each node, recursively
Note: This does not take account of property offsets - these will not
be updated.
"""
fdt_obj = self._fdt._fdt_obj
if self._offset != my_offset:
self._offset = my_offset
offset = fdt_obj.first_subnode(self._offset, QUIET_NOTFOUND)
for subnode in self.subnodes:
if subnode.name != fdt_obj.get_name(offset):
raise ValueError('Internal error, node name mismatch %s != %s' %
(subnode.name, fdt_obj.get_name(offset)))
subnode.Refresh(offset)
offset = fdt_obj.next_subnode(offset, QUIET_NOTFOUND)
if offset != -libfdt.FDT_ERR_NOTFOUND:
raise ValueError('Internal error, offset == %d' % offset)
poffset = fdt_obj.first_property_offset(self._offset, QUIET_NOTFOUND)
while poffset >= 0:
p = fdt_obj.get_property_by_offset(poffset)
prop = self.props.get(p.name)
if not prop:
raise ValueError("Internal error, property '%s' missing, "
'offset %d' % (p.name, poffset))
prop.RefreshOffset(poffset)
poffset = fdt_obj.next_property_offset(poffset, QUIET_NOTFOUND)
def DeleteProp(self, prop_name):
"""Delete a property of a node
The property is deleted and the offset cache is invalidated.
Args:
prop_name: Name of the property to delete
Raises:
ValueError if the property does not exist
"""
CheckErr(self._fdt._fdt_obj.delprop(self.Offset(), prop_name),
"Node '%s': delete property: '%s'" % (self.path, prop_name))
del self.props[prop_name]
self._fdt.Invalidate()
def AddZeroProp(self, prop_name):
"""Add a new property to the device tree with an integer value of 0.
Args:
prop_name: Name of property
"""
self.props[prop_name] = Prop(self, None, prop_name,
tools.GetBytes(0, 4))
def AddEmptyProp(self, prop_name, len):
"""Add a property with a fixed data size, for filling in later
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property
len: Length of data in property
"""
value = tools.GetBytes(0, len)
self.props[prop_name] = Prop(self, None, prop_name, value)
def _CheckProp(self, prop_name):
"""Check if a property is present
Args:
prop_name: Name of property
Returns:
self
Raises:
ValueError if the property is missing
"""
if prop_name not in self.props:
raise ValueError("Fdt '%s', node '%s': Missing property '%s'" %
(self._fdt._fname, self.path, prop_name))
return self
def SetInt(self, prop_name, val):
"""Update an integer property int the device tree.
This is not allowed to change the size of the FDT.
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property
val: Value to set
"""
self._CheckProp(prop_name).props[prop_name].SetInt(val)
def SetData(self, prop_name, val):
"""Set the data value of a property
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property to set
val: Data value to set
"""
self._CheckProp(prop_name).props[prop_name].SetData(val)
def SetString(self, prop_name, val):
"""Set the string value of a property
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property to set
val: String value to set (will be \0-terminated in DT)
"""
if type(val) == str:
val = val.encode('utf-8')
self._CheckProp(prop_name).props[prop_name].SetData(val + b'\0')
def AddData(self, prop_name, val):
"""Add a new property to a node
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property to add
val: Bytes value of property
"""
self.props[prop_name] = Prop(self, None, prop_name, val)
def AddString(self, prop_name, val):
"""Add a new string property to a node
The device tree is marked dirty so that the value will be written to
the blob on the next sync.
Args:
prop_name: Name of property to add
val: String value of property
"""
val = bytes(val, 'utf-8')
self.AddData(prop_name, val + b'\0')
def AddSubnode(self, name):
"""Add a new subnode to the node
Args:
name: name of node to add
Returns:
New subnode that was created
"""
path = self.path + '/' + name
subnode = Node(self._fdt, self, None, name, path)
self.subnodes.append(subnode)
return subnode
def Sync(self, auto_resize=False):
"""Sync node changes back to the device tree
This updates the device tree blob with any changes to this node and its
subnodes since the last sync.
Args:
auto_resize: Resize the device tree automatically if it does not
have enough space for the update
Raises:
FdtException if auto_resize is False and there is not enough space
"""
if self._offset is None:
# The subnode doesn't exist yet, so add it
fdt_obj = self._fdt._fdt_obj
if auto_resize:
while True:
offset = fdt_obj.add_subnode(self.parent._offset, self.name,
(libfdt.NOSPACE,))
if offset != -libfdt.NOSPACE:
break
fdt_obj.resize(fdt_obj.totalsize() + 1024)
else:
offset = fdt_obj.add_subnode(self.parent._offset, self.name)
self._offset = offset
# Sync subnodes in reverse so that we don't disturb node offsets for
# nodes that are earlier in the DT. This avoids an O(n^2) rescan of
# node offsets.
for node in reversed(self.subnodes):
node.Sync(auto_resize)
# Sync properties now, whose offsets should not have been disturbed.
# We do this after subnodes, since this disturbs the offsets of these
# properties. Note that new properties will have an offset of None here,
# which Python 3 cannot sort against int. So use a large value instead
# to ensure that the new properties are added first.
prop_list = sorted(self.props.values(),
key=lambda prop: prop._offset or 1 << 31,
reverse=True)
for prop in prop_list:
prop.Sync(auto_resize)
class Fdt:
"""Provides simple access to a flat device tree blob using libfdts.
Properties:
fname: Filename of fdt
_root: Root of device tree (a Node object)
name: Helpful name for this Fdt for the user (useful when creating the
DT from data rather than a file)
"""
def __init__(self, fname):
self._fname = fname
self._cached_offsets = False
self.phandle_to_node = {}
self.name = ''
if self._fname:
self.name = self._fname
self._fname = fdt_util.EnsureCompiled(self._fname)
with open(self._fname, 'rb') as fd:
self._fdt_obj = libfdt.Fdt(fd.read())
@staticmethod
def FromData(data, name=''):
"""Create a new Fdt object from the given data
Args:
data: Device-tree data blob
name: Helpful name for this Fdt for the user
Returns:
Fdt object containing the data
"""
fdt = Fdt(None)
fdt._fdt_obj = libfdt.Fdt(bytes(data))
fdt.name = name
return fdt
def LookupPhandle(self, phandle):
"""Look up a phandle
Args:
phandle: Phandle to look up (int)
Returns:
Node object the phandle points to
"""
return self.phandle_to_node.get(phandle)
def Scan(self, root='/'):
"""Scan a device tree, building up a tree of Node objects
This fills in the self._root property
Args:
root: Ignored
TODO(sjg@chromium.org): Implement the 'root' parameter
"""
self._cached_offsets = True
self._root = self.Node(self, None, 0, '/', '/')
self._root.Scan()
def GetRoot(self):
"""Get the root Node of the device tree
Returns:
The root Node object
"""
return self._root
def GetNode(self, path):
"""Look up a node from its path
Args:
path: Path to look up, e.g. '/microcode/update@0'
Returns:
Node object, or None if not found
"""
node = self._root
parts = path.split('/')
if len(parts) < 2:
return None
if len(parts) == 2 and parts[1] == '':
return node
for part in parts[1:]:
node = node.FindNode(part)
if not node:
return None
return node
def Flush(self):
"""Flush device tree changes back to the file
If the device tree has changed in memory, write it back to the file.
"""
with open(self._fname, 'wb') as fd:
fd.write(self._fdt_obj.as_bytearray())
def Sync(self, auto_resize=False):
"""Make sure any DT changes are written to the blob
Args:
auto_resize: Resize the device tree automatically if it does not
have enough space for the update
Raises:
FdtException if auto_resize is False and there is not enough space
"""
self._root.Sync(auto_resize)
self.Invalidate()
def Pack(self):
"""Pack the device tree down to its minimum size
When nodes and properties shrink or are deleted, wasted space can
build up in the device tree binary.
"""
CheckErr(self._fdt_obj.pack(), 'pack')
self.Invalidate()
def GetContents(self):
"""Get the contents of the FDT
Returns:
The FDT contents as a string of bytes
"""
return bytes(self._fdt_obj.as_bytearray())
def GetFdtObj(self):
"""Get the contents of the FDT
Returns:
The FDT contents as a libfdt.Fdt object
"""
return self._fdt_obj
def GetProps(self, node):
"""Get all properties from a node.
Args:
node: Full path to node name to look in.
Returns:
A dictionary containing all the properties, indexed by node name.
The entries are Prop objects.
Raises:
ValueError: if the node does not exist.
"""
props_dict = {}
poffset = self._fdt_obj.first_property_offset(node._offset,
QUIET_NOTFOUND)
while poffset >= 0:
p = self._fdt_obj.get_property_by_offset(poffset)
prop = Prop(node, poffset, p.name, p)
props_dict[prop.name] = prop
poffset = self._fdt_obj.next_property_offset(poffset,
QUIET_NOTFOUND)
return props_dict
def Invalidate(self):
"""Mark our offset cache as invalid"""
self._cached_offsets = False
def CheckCache(self):
"""Refresh the offset cache if needed"""
if self._cached_offsets:
return
self.Refresh()
self._cached_offsets = True
def Refresh(self):
"""Refresh the offset cache"""
self._root.Refresh(0)
def GetStructOffset(self, offset):
"""Get the file offset of a given struct offset
Args:
offset: Offset within the 'struct' region of the device tree
Returns:
Position of @offset within the device tree binary
"""
return self._fdt_obj.off_dt_struct() + offset
@classmethod
def Node(self, fdt, parent, offset, name, path):
"""Create a new node
This is used by Fdt.Scan() to create a new node using the correct
class.
Args:
fdt: Fdt object
parent: Parent node, or None if this is the root node
offset: Offset of node
name: Node name
path: Full path to node
"""
node = Node(fdt, parent, offset, name, path)
return node
def GetFilename(self):
"""Get the filename of the device tree
Returns:
String filename
"""
return self._fname
def FdtScan(fname):
"""Returns a new Fdt object"""
dtb = Fdt(fname)
dtb.Scan()
return dtb