linux/tools/net/ynl/lib/ynl.py
Donald Hunter 8b6811d966 tools/net/ynl: Add binary and pad support to structs for tc
The tc netlink-raw family needs binary and pad types for several
qopt C structs. Add support for them to ynl.

Reviewed-by: Jakub Kicinski <kuba@kernel.org>
Signed-off-by: Donald Hunter <donald.hunter@gmail.com>
Link: https://lore.kernel.org/r/20231215093720.18774-6-donald.hunter@gmail.com
Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2023-12-18 14:39:43 -08:00

824 lines
29 KiB
Python

# SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause
from collections import namedtuple
import functools
import os
import random
import socket
import struct
from struct import Struct
import yaml
import ipaddress
import uuid
from .nlspec import SpecFamily
#
# Generic Netlink code which should really be in some library, but I can't quickly find one.
#
class Netlink:
# Netlink socket
SOL_NETLINK = 270
NETLINK_ADD_MEMBERSHIP = 1
NETLINK_CAP_ACK = 10
NETLINK_EXT_ACK = 11
NETLINK_GET_STRICT_CHK = 12
# Netlink message
NLMSG_ERROR = 2
NLMSG_DONE = 3
NLM_F_REQUEST = 1
NLM_F_ACK = 4
NLM_F_ROOT = 0x100
NLM_F_MATCH = 0x200
NLM_F_REPLACE = 0x100
NLM_F_EXCL = 0x200
NLM_F_CREATE = 0x400
NLM_F_APPEND = 0x800
NLM_F_CAPPED = 0x100
NLM_F_ACK_TLVS = 0x200
NLM_F_DUMP = NLM_F_ROOT | NLM_F_MATCH
NLA_F_NESTED = 0x8000
NLA_F_NET_BYTEORDER = 0x4000
NLA_TYPE_MASK = NLA_F_NESTED | NLA_F_NET_BYTEORDER
# Genetlink defines
NETLINK_GENERIC = 16
GENL_ID_CTRL = 0x10
# nlctrl
CTRL_CMD_GETFAMILY = 3
CTRL_ATTR_FAMILY_ID = 1
CTRL_ATTR_FAMILY_NAME = 2
CTRL_ATTR_MAXATTR = 5
CTRL_ATTR_MCAST_GROUPS = 7
CTRL_ATTR_MCAST_GRP_NAME = 1
CTRL_ATTR_MCAST_GRP_ID = 2
# Extack types
NLMSGERR_ATTR_MSG = 1
NLMSGERR_ATTR_OFFS = 2
NLMSGERR_ATTR_COOKIE = 3
NLMSGERR_ATTR_POLICY = 4
NLMSGERR_ATTR_MISS_TYPE = 5
NLMSGERR_ATTR_MISS_NEST = 6
class NlError(Exception):
def __init__(self, nl_msg):
self.nl_msg = nl_msg
def __str__(self):
return f"Netlink error: {os.strerror(-self.nl_msg.error)}\n{self.nl_msg}"
class NlAttr:
ScalarFormat = namedtuple('ScalarFormat', ['native', 'big', 'little'])
type_formats = {
'u8' : ScalarFormat(Struct('B'), Struct("B"), Struct("B")),
's8' : ScalarFormat(Struct('b'), Struct("b"), Struct("b")),
'u16': ScalarFormat(Struct('H'), Struct(">H"), Struct("<H")),
's16': ScalarFormat(Struct('h'), Struct(">h"), Struct("<h")),
'u32': ScalarFormat(Struct('I'), Struct(">I"), Struct("<I")),
's32': ScalarFormat(Struct('i'), Struct(">i"), Struct("<i")),
'u64': ScalarFormat(Struct('Q'), Struct(">Q"), Struct("<Q")),
's64': ScalarFormat(Struct('q'), Struct(">q"), Struct("<q"))
}
def __init__(self, raw, offset):
self._len, self._type = struct.unpack("HH", raw[offset : offset + 4])
self.type = self._type & ~Netlink.NLA_TYPE_MASK
self.is_nest = self._type & Netlink.NLA_F_NESTED
self.payload_len = self._len
self.full_len = (self.payload_len + 3) & ~3
self.raw = raw[offset + 4 : offset + self.payload_len]
@classmethod
def get_format(cls, attr_type, byte_order=None):
format = cls.type_formats[attr_type]
if byte_order:
return format.big if byte_order == "big-endian" \
else format.little
return format.native
@classmethod
def formatted_string(cls, raw, display_hint):
if display_hint == 'mac':
formatted = ':'.join('%02x' % b for b in raw)
elif display_hint == 'hex':
formatted = bytes.hex(raw, ' ')
elif display_hint in [ 'ipv4', 'ipv6' ]:
formatted = format(ipaddress.ip_address(raw))
elif display_hint == 'uuid':
formatted = str(uuid.UUID(bytes=raw))
else:
formatted = raw
return formatted
def as_scalar(self, attr_type, byte_order=None):
format = self.get_format(attr_type, byte_order)
return format.unpack(self.raw)[0]
def as_auto_scalar(self, attr_type, byte_order=None):
if len(self.raw) != 4 and len(self.raw) != 8:
raise Exception(f"Auto-scalar len payload be 4 or 8 bytes, got {len(self.raw)}")
real_type = attr_type[0] + str(len(self.raw) * 8)
format = self.get_format(real_type, byte_order)
return format.unpack(self.raw)[0]
def as_strz(self):
return self.raw.decode('ascii')[:-1]
def as_bin(self):
return self.raw
def as_c_array(self, type):
format = self.get_format(type)
return [ x[0] for x in format.iter_unpack(self.raw) ]
def as_struct(self, members):
value = dict()
offset = 0
for m in members:
# TODO: handle non-scalar members
if m.type == 'binary':
decoded = self.raw[offset : offset + m['len']]
offset += m['len']
elif m.type in NlAttr.type_formats:
format = self.get_format(m.type, m.byte_order)
[ decoded ] = format.unpack_from(self.raw, offset)
offset += format.size
if m.display_hint:
decoded = self.formatted_string(decoded, m.display_hint)
value[m.name] = decoded
return value
def __repr__(self):
return f"[type:{self.type} len:{self._len}] {self.raw}"
class NlAttrs:
def __init__(self, msg, offset=0):
self.attrs = []
while offset < len(msg):
attr = NlAttr(msg, offset)
offset += attr.full_len
self.attrs.append(attr)
def __iter__(self):
yield from self.attrs
def __repr__(self):
msg = ''
for a in self.attrs:
if msg:
msg += '\n'
msg += repr(a)
return msg
class NlMsg:
def __init__(self, msg, offset, attr_space=None):
self.hdr = msg[offset : offset + 16]
self.nl_len, self.nl_type, self.nl_flags, self.nl_seq, self.nl_portid = \
struct.unpack("IHHII", self.hdr)
self.raw = msg[offset + 16 : offset + self.nl_len]
self.error = 0
self.done = 0
extack_off = None
if self.nl_type == Netlink.NLMSG_ERROR:
self.error = struct.unpack("i", self.raw[0:4])[0]
self.done = 1
extack_off = 20
elif self.nl_type == Netlink.NLMSG_DONE:
self.done = 1
extack_off = 4
self.extack = None
if self.nl_flags & Netlink.NLM_F_ACK_TLVS and extack_off:
self.extack = dict()
extack_attrs = NlAttrs(self.raw[extack_off:])
for extack in extack_attrs:
if extack.type == Netlink.NLMSGERR_ATTR_MSG:
self.extack['msg'] = extack.as_strz()
elif extack.type == Netlink.NLMSGERR_ATTR_MISS_TYPE:
self.extack['miss-type'] = extack.as_scalar('u32')
elif extack.type == Netlink.NLMSGERR_ATTR_MISS_NEST:
self.extack['miss-nest'] = extack.as_scalar('u32')
elif extack.type == Netlink.NLMSGERR_ATTR_OFFS:
self.extack['bad-attr-offs'] = extack.as_scalar('u32')
else:
if 'unknown' not in self.extack:
self.extack['unknown'] = []
self.extack['unknown'].append(extack)
if attr_space:
# We don't have the ability to parse nests yet, so only do global
if 'miss-type' in self.extack and 'miss-nest' not in self.extack:
miss_type = self.extack['miss-type']
if miss_type in attr_space.attrs_by_val:
spec = attr_space.attrs_by_val[miss_type]
desc = spec['name']
if 'doc' in spec:
desc += f" ({spec['doc']})"
self.extack['miss-type'] = desc
def cmd(self):
return self.nl_type
def __repr__(self):
msg = f"nl_len = {self.nl_len} ({len(self.raw)}) nl_flags = 0x{self.nl_flags:x} nl_type = {self.nl_type}\n"
if self.error:
msg += '\terror: ' + str(self.error)
if self.extack:
msg += '\textack: ' + repr(self.extack)
return msg
class NlMsgs:
def __init__(self, data, attr_space=None):
self.msgs = []
offset = 0
while offset < len(data):
msg = NlMsg(data, offset, attr_space=attr_space)
offset += msg.nl_len
self.msgs.append(msg)
def __iter__(self):
yield from self.msgs
genl_family_name_to_id = None
def _genl_msg(nl_type, nl_flags, genl_cmd, genl_version, seq=None):
# we prepend length in _genl_msg_finalize()
if seq is None:
seq = random.randint(1, 1024)
nlmsg = struct.pack("HHII", nl_type, nl_flags, seq, 0)
genlmsg = struct.pack("BBH", genl_cmd, genl_version, 0)
return nlmsg + genlmsg
def _genl_msg_finalize(msg):
return struct.pack("I", len(msg) + 4) + msg
def _genl_load_families():
with socket.socket(socket.AF_NETLINK, socket.SOCK_RAW, Netlink.NETLINK_GENERIC) as sock:
sock.setsockopt(Netlink.SOL_NETLINK, Netlink.NETLINK_CAP_ACK, 1)
msg = _genl_msg(Netlink.GENL_ID_CTRL,
Netlink.NLM_F_REQUEST | Netlink.NLM_F_ACK | Netlink.NLM_F_DUMP,
Netlink.CTRL_CMD_GETFAMILY, 1)
msg = _genl_msg_finalize(msg)
sock.send(msg, 0)
global genl_family_name_to_id
genl_family_name_to_id = dict()
while True:
reply = sock.recv(128 * 1024)
nms = NlMsgs(reply)
for nl_msg in nms:
if nl_msg.error:
print("Netlink error:", nl_msg.error)
return
if nl_msg.done:
return
gm = GenlMsg(nl_msg)
fam = dict()
for attr in NlAttrs(gm.raw):
if attr.type == Netlink.CTRL_ATTR_FAMILY_ID:
fam['id'] = attr.as_scalar('u16')
elif attr.type == Netlink.CTRL_ATTR_FAMILY_NAME:
fam['name'] = attr.as_strz()
elif attr.type == Netlink.CTRL_ATTR_MAXATTR:
fam['maxattr'] = attr.as_scalar('u32')
elif attr.type == Netlink.CTRL_ATTR_MCAST_GROUPS:
fam['mcast'] = dict()
for entry in NlAttrs(attr.raw):
mcast_name = None
mcast_id = None
for entry_attr in NlAttrs(entry.raw):
if entry_attr.type == Netlink.CTRL_ATTR_MCAST_GRP_NAME:
mcast_name = entry_attr.as_strz()
elif entry_attr.type == Netlink.CTRL_ATTR_MCAST_GRP_ID:
mcast_id = entry_attr.as_scalar('u32')
if mcast_name and mcast_id is not None:
fam['mcast'][mcast_name] = mcast_id
if 'name' in fam and 'id' in fam:
genl_family_name_to_id[fam['name']] = fam
class GenlMsg:
def __init__(self, nl_msg):
self.nl = nl_msg
self.genl_cmd, self.genl_version, _ = struct.unpack_from("BBH", nl_msg.raw, 0)
self.raw = nl_msg.raw[4:]
def cmd(self):
return self.genl_cmd
def __repr__(self):
msg = repr(self.nl)
msg += f"\tgenl_cmd = {self.genl_cmd} genl_ver = {self.genl_version}\n"
for a in self.raw_attrs:
msg += '\t\t' + repr(a) + '\n'
return msg
class NetlinkProtocol:
def __init__(self, family_name, proto_num):
self.family_name = family_name
self.proto_num = proto_num
def _message(self, nl_type, nl_flags, seq=None):
if seq is None:
seq = random.randint(1, 1024)
nlmsg = struct.pack("HHII", nl_type, nl_flags, seq, 0)
return nlmsg
def message(self, flags, command, version, seq=None):
return self._message(command, flags, seq)
def _decode(self, nl_msg):
return nl_msg
def decode(self, ynl, nl_msg):
msg = self._decode(nl_msg)
fixed_header_size = 0
if ynl:
op = ynl.rsp_by_value[msg.cmd()]
fixed_header_size = ynl._fixed_header_size(op.fixed_header)
msg.raw_attrs = NlAttrs(msg.raw, fixed_header_size)
return msg
def get_mcast_id(self, mcast_name, mcast_groups):
if mcast_name not in mcast_groups:
raise Exception(f'Multicast group "{mcast_name}" not present in the spec')
return mcast_groups[mcast_name].value
class GenlProtocol(NetlinkProtocol):
def __init__(self, family_name):
super().__init__(family_name, Netlink.NETLINK_GENERIC)
global genl_family_name_to_id
if genl_family_name_to_id is None:
_genl_load_families()
self.genl_family = genl_family_name_to_id[family_name]
self.family_id = genl_family_name_to_id[family_name]['id']
def message(self, flags, command, version, seq=None):
nlmsg = self._message(self.family_id, flags, seq)
genlmsg = struct.pack("BBH", command, version, 0)
return nlmsg + genlmsg
def _decode(self, nl_msg):
return GenlMsg(nl_msg)
def get_mcast_id(self, mcast_name, mcast_groups):
if mcast_name not in self.genl_family['mcast']:
raise Exception(f'Multicast group "{mcast_name}" not present in the family')
return self.genl_family['mcast'][mcast_name]
#
# YNL implementation details.
#
class YnlFamily(SpecFamily):
def __init__(self, def_path, schema=None, process_unknown=False):
super().__init__(def_path, schema)
self.include_raw = False
self.process_unknown = process_unknown
try:
if self.proto == "netlink-raw":
self.nlproto = NetlinkProtocol(self.yaml['name'],
self.yaml['protonum'])
else:
self.nlproto = GenlProtocol(self.yaml['name'])
except KeyError:
raise Exception(f"Family '{self.yaml['name']}' not supported by the kernel")
self.sock = socket.socket(socket.AF_NETLINK, socket.SOCK_RAW, self.nlproto.proto_num)
self.sock.setsockopt(Netlink.SOL_NETLINK, Netlink.NETLINK_CAP_ACK, 1)
self.sock.setsockopt(Netlink.SOL_NETLINK, Netlink.NETLINK_EXT_ACK, 1)
self.sock.setsockopt(Netlink.SOL_NETLINK, Netlink.NETLINK_GET_STRICT_CHK, 1)
self.async_msg_ids = set()
self.async_msg_queue = []
for msg in self.msgs.values():
if msg.is_async:
self.async_msg_ids.add(msg.rsp_value)
for op_name, op in self.ops.items():
bound_f = functools.partial(self._op, op_name)
setattr(self, op.ident_name, bound_f)
def ntf_subscribe(self, mcast_name):
mcast_id = self.nlproto.get_mcast_id(mcast_name, self.mcast_groups)
self.sock.bind((0, 0))
self.sock.setsockopt(Netlink.SOL_NETLINK, Netlink.NETLINK_ADD_MEMBERSHIP,
mcast_id)
def _add_attr(self, space, name, value):
try:
attr = self.attr_sets[space][name]
except KeyError:
raise Exception(f"Space '{space}' has no attribute '{name}'")
nl_type = attr.value
if attr["type"] == 'nest':
nl_type |= Netlink.NLA_F_NESTED
attr_payload = b''
for subname, subvalue in value.items():
attr_payload += self._add_attr(attr['nested-attributes'], subname, subvalue)
elif attr["type"] == 'flag':
attr_payload = b''
elif attr["type"] == 'string':
attr_payload = str(value).encode('ascii') + b'\x00'
elif attr["type"] == 'binary':
if isinstance(value, bytes):
attr_payload = value
elif isinstance(value, str):
attr_payload = bytes.fromhex(value)
else:
raise Exception(f'Unknown type for binary attribute, value: {value}')
elif attr.is_auto_scalar:
scalar = int(value)
real_type = attr["type"][0] + ('32' if scalar.bit_length() <= 32 else '64')
format = NlAttr.get_format(real_type, attr.byte_order)
attr_payload = format.pack(int(value))
elif attr['type'] in NlAttr.type_formats:
format = NlAttr.get_format(attr['type'], attr.byte_order)
attr_payload = format.pack(int(value))
elif attr['type'] in "bitfield32":
attr_payload = struct.pack("II", int(value["value"]), int(value["selector"]))
else:
raise Exception(f'Unknown type at {space} {name} {value} {attr["type"]}')
pad = b'\x00' * ((4 - len(attr_payload) % 4) % 4)
return struct.pack('HH', len(attr_payload) + 4, nl_type) + attr_payload + pad
def _decode_enum(self, raw, attr_spec):
enum = self.consts[attr_spec['enum']]
if enum.type == 'flags' or attr_spec.get('enum-as-flags', False):
i = 0
value = set()
while raw:
if raw & 1:
value.add(enum.entries_by_val[i].name)
raw >>= 1
i += 1
else:
value = enum.entries_by_val[raw].name
return value
def _decode_binary(self, attr, attr_spec):
if attr_spec.struct_name:
members = self.consts[attr_spec.struct_name]
decoded = attr.as_struct(members)
for m in members:
if m.enum:
decoded[m.name] = self._decode_enum(decoded[m.name], m)
elif attr_spec.sub_type:
decoded = attr.as_c_array(attr_spec.sub_type)
else:
decoded = attr.as_bin()
if attr_spec.display_hint:
decoded = NlAttr.formatted_string(decoded, attr_spec.display_hint)
return decoded
def _decode_array_nest(self, attr, attr_spec):
decoded = []
offset = 0
while offset < len(attr.raw):
item = NlAttr(attr.raw, offset)
offset += item.full_len
subattrs = self._decode(NlAttrs(item.raw), attr_spec['nested-attributes'])
decoded.append({ item.type: subattrs })
return decoded
def _decode_unknown(self, attr):
if attr.is_nest:
return self._decode(NlAttrs(attr.raw), None)
else:
return attr.as_bin()
def _rsp_add(self, rsp, name, is_multi, decoded):
if is_multi == None:
if name in rsp and type(rsp[name]) is not list:
rsp[name] = [rsp[name]]
is_multi = True
else:
is_multi = False
if not is_multi:
rsp[name] = decoded
elif name in rsp:
rsp[name].append(decoded)
else:
rsp[name] = [decoded]
def _resolve_selector(self, attr_spec, vals):
sub_msg = attr_spec.sub_message
if sub_msg not in self.sub_msgs:
raise Exception(f"No sub-message spec named {sub_msg} for {attr_spec.name}")
sub_msg_spec = self.sub_msgs[sub_msg]
selector = attr_spec.selector
if selector not in vals:
raise Exception(f"There is no value for {selector} to resolve '{attr_spec.name}'")
value = vals[selector]
if value not in sub_msg_spec.formats:
raise Exception(f"No message format for '{value}' in sub-message spec '{sub_msg}'")
spec = sub_msg_spec.formats[value]
return spec
def _decode_sub_msg(self, attr, attr_spec, rsp):
msg_format = self._resolve_selector(attr_spec, rsp)
decoded = {}
offset = 0
if msg_format.fixed_header:
decoded.update(self._decode_fixed_header(attr, msg_format.fixed_header));
offset = self._fixed_header_size(msg_format.fixed_header)
if msg_format.attr_set:
if msg_format.attr_set in self.attr_sets:
subdict = self._decode(NlAttrs(attr.raw, offset), msg_format.attr_set)
decoded.update(subdict)
else:
raise Exception(f"Unknown attribute-set '{attr_space}' when decoding '{attr_spec.name}'")
return decoded
def _decode(self, attrs, space):
if space:
attr_space = self.attr_sets[space]
rsp = dict()
for attr in attrs:
try:
attr_spec = attr_space.attrs_by_val[attr.type]
except (KeyError, UnboundLocalError):
if not self.process_unknown:
raise Exception(f"Space '{space}' has no attribute with value '{attr.type}'")
attr_name = f"UnknownAttr({attr.type})"
self._rsp_add(rsp, attr_name, None, self._decode_unknown(attr))
continue
if attr_spec["type"] == 'nest':
subdict = self._decode(NlAttrs(attr.raw), attr_spec['nested-attributes'])
decoded = subdict
elif attr_spec["type"] == 'string':
decoded = attr.as_strz()
elif attr_spec["type"] == 'binary':
decoded = self._decode_binary(attr, attr_spec)
elif attr_spec["type"] == 'flag':
decoded = True
elif attr_spec.is_auto_scalar:
decoded = attr.as_auto_scalar(attr_spec['type'], attr_spec.byte_order)
elif attr_spec["type"] in NlAttr.type_formats:
decoded = attr.as_scalar(attr_spec['type'], attr_spec.byte_order)
if 'enum' in attr_spec:
decoded = self._decode_enum(decoded, attr_spec)
elif attr_spec["type"] == 'array-nest':
decoded = self._decode_array_nest(attr, attr_spec)
elif attr_spec["type"] == 'bitfield32':
value, selector = struct.unpack("II", attr.raw)
if 'enum' in attr_spec:
value = self._decode_enum(value, attr_spec)
selector = self._decode_enum(selector, attr_spec)
decoded = {"value": value, "selector": selector}
elif attr_spec["type"] == 'sub-message':
decoded = self._decode_sub_msg(attr, attr_spec, rsp)
else:
if not self.process_unknown:
raise Exception(f'Unknown {attr_spec["type"]} with name {attr_spec["name"]}')
decoded = self._decode_unknown(attr)
self._rsp_add(rsp, attr_spec["name"], attr_spec.is_multi, decoded)
return rsp
def _decode_extack_path(self, attrs, attr_set, offset, target):
for attr in attrs:
try:
attr_spec = attr_set.attrs_by_val[attr.type]
except KeyError:
raise Exception(f"Space '{attr_set.name}' has no attribute with value '{attr.type}'")
if offset > target:
break
if offset == target:
return '.' + attr_spec.name
if offset + attr.full_len <= target:
offset += attr.full_len
continue
if attr_spec['type'] != 'nest':
raise Exception(f"Can't dive into {attr.type} ({attr_spec['name']}) for extack")
offset += 4
subpath = self._decode_extack_path(NlAttrs(attr.raw),
self.attr_sets[attr_spec['nested-attributes']],
offset, target)
if subpath is None:
return None
return '.' + attr_spec.name + subpath
return None
def _decode_extack(self, request, op, extack):
if 'bad-attr-offs' not in extack:
return
msg = self.nlproto.decode(self, NlMsg(request, 0, op.attr_set))
offset = 20 + self._fixed_header_size(op.fixed_header)
path = self._decode_extack_path(msg.raw_attrs, op.attr_set, offset,
extack['bad-attr-offs'])
if path:
del extack['bad-attr-offs']
extack['bad-attr'] = path
def _fixed_header_size(self, name):
if name:
fixed_header_members = self.consts[name].members
size = 0
for m in fixed_header_members:
if m.type in ['pad', 'binary']:
size += m.len
else:
format = NlAttr.get_format(m.type, m.byte_order)
size += format.size
return size
else:
return 0
def _decode_fixed_header(self, msg, name):
fixed_header_members = self.consts[name].members
fixed_header_attrs = dict()
offset = 0
for m in fixed_header_members:
value = None
if m.type == 'pad':
offset += m.len
elif m.type == 'binary':
value = msg.raw[offset : offset + m.len]
offset += m.len
else:
format = NlAttr.get_format(m.type, m.byte_order)
[ value ] = format.unpack_from(msg.raw, offset)
offset += format.size
if value is not None:
if m.enum:
value = self._decode_enum(value, m)
fixed_header_attrs[m.name] = value
return fixed_header_attrs
def handle_ntf(self, decoded):
msg = dict()
if self.include_raw:
msg['raw'] = decoded
op = self.rsp_by_value[decoded.cmd()]
attrs = self._decode(decoded.raw_attrs, op.attr_set.name)
if op.fixed_header:
attrs.update(self._decode_fixed_header(decoded, op.fixed_header))
msg['name'] = op['name']
msg['msg'] = attrs
self.async_msg_queue.append(msg)
def check_ntf(self):
while True:
try:
reply = self.sock.recv(128 * 1024, socket.MSG_DONTWAIT)
except BlockingIOError:
return
nms = NlMsgs(reply)
for nl_msg in nms:
if nl_msg.error:
print("Netlink error in ntf!?", os.strerror(-nl_msg.error))
print(nl_msg)
continue
if nl_msg.done:
print("Netlink done while checking for ntf!?")
continue
decoded = self.nlproto.decode(self, nl_msg)
if decoded.cmd() not in self.async_msg_ids:
print("Unexpected msg id done while checking for ntf", decoded)
continue
self.handle_ntf(decoded)
def operation_do_attributes(self, name):
"""
For a given operation name, find and return a supported
set of attributes (as a dict).
"""
op = self.find_operation(name)
if not op:
return None
return op['do']['request']['attributes'].copy()
def _op(self, method, vals, flags=None, dump=False):
op = self.ops[method]
nl_flags = Netlink.NLM_F_REQUEST | Netlink.NLM_F_ACK
for flag in flags or []:
nl_flags |= flag
if dump:
nl_flags |= Netlink.NLM_F_DUMP
req_seq = random.randint(1024, 65535)
msg = self.nlproto.message(nl_flags, op.req_value, 1, req_seq)
fixed_header_members = []
if op.fixed_header:
fixed_header_members = self.consts[op.fixed_header].members
for m in fixed_header_members:
value = vals.pop(m.name) if m.name in vals else 0
if m.type == 'pad':
msg += bytearray(m.len)
elif m.type == 'binary':
msg += bytes.fromhex(value)
else:
format = NlAttr.get_format(m.type, m.byte_order)
msg += format.pack(value)
for name, value in vals.items():
msg += self._add_attr(op.attr_set.name, name, value)
msg = _genl_msg_finalize(msg)
self.sock.send(msg, 0)
done = False
rsp = []
while not done:
reply = self.sock.recv(128 * 1024)
nms = NlMsgs(reply, attr_space=op.attr_set)
for nl_msg in nms:
if nl_msg.extack:
self._decode_extack(msg, op, nl_msg.extack)
if nl_msg.error:
raise NlError(nl_msg)
if nl_msg.done:
if nl_msg.extack:
print("Netlink warning:")
print(nl_msg)
done = True
break
decoded = self.nlproto.decode(self, nl_msg)
# Check if this is a reply to our request
if nl_msg.nl_seq != req_seq or decoded.cmd() != op.rsp_value:
if decoded.cmd() in self.async_msg_ids:
self.handle_ntf(decoded)
continue
else:
print('Unexpected message: ' + repr(decoded))
continue
rsp_msg = self._decode(decoded.raw_attrs, op.attr_set.name)
if op.fixed_header:
rsp_msg.update(self._decode_fixed_header(decoded, op.fixed_header))
rsp.append(rsp_msg)
if not rsp:
return None
if not dump and len(rsp) == 1:
return rsp[0]
return rsp
def do(self, method, vals, flags=None):
return self._op(method, vals, flags)
def dump(self, method, vals):
return self._op(method, vals, [], dump=True)