def encode(self):
r_prio = struct.pack('H', self['prio'])
r_addr = struct.pack('BBBBBB',
*[int(i, 16) for i in
self['addr'].split(':')])
self['value'] = r_prio + r_addr
nla.encode(self)
def encode(self):
if not isinstance(self['kind'], str):
raise ValueError("kind' keywords must be set!")
kind = self['kind'].lower()
if kind in strings_meta:
self['id'] = TCF_META_TYPE_VAR
else:
self['id'] = TCF_META_TYPE_INT
self['id'] <<= 12
for k, v in META_ID.items():
if kind == k:
self['kind'] = self['id'] | v
break
if isinstance(self['opnd'], str):
for k, v in OPERANDS_DICT.items():
if self['opnd'].lower() in v:
self['opnd'] = k
break
# Perform sanity checks on 'shift' value
if isinstance(self['shift'], str):
# If it fails, it will raise a ValueError
# which is what we want
self['shift'] = int(self['shift'])
if not 0 <= self['shift'] <= 255:
raise ValueError("'shift' value must be between"
"0 and 255 included!")
nla.encode(self)
def encode(self):
r_prio = struct.pack('H', self['prio'])
r_addr = struct.pack('BBBBBB',
*[int(i, 16) for i in
self['addr'].split(':')])
self['value'] = r_prio + r_addr
nla.encode(self)
def encode(self):
family = self.get('family', AF_UNSPEC)
if family in (AF_INET, AF_INET6):
addr = inet_pton(family, self['addr'])
else:
raise TypeError('Family %s not supported for RTA_VIA' % family)
self['value'] = struct.pack('H', family) + addr
nla.encode(self)
def encode(self):
parms = self.parent.get_encoded('TCA_TBF_PARMS') or \
self.parent.get_encoded('TCA_HTB_PARMS') or \
self.parent.get_encoded('TCA_POLICE_TBF')
if parms is not None:
self.value = getattr(parms, self.__class__.__name__)
self['value'] = struct.pack('I' * 256,
*(int(x) for x in self.value))
nla.encode(self)
def encode(self):
# Get action type and convert string to value
action = self['value']
self['value'] = (self.actions.get(
action, self.SEG6_LOCAL_ACTION_UNSPEC))
# Convert action type to u32
self['value'] = self['value'] & 0xffffffff
# Finally encode as nla
nla.encode(self)
def encode(self):
parms = self.parent.get_encoded('TCA_TBF_PARMS') or \
self.parent.get_encoded('TCA_HTB_PARMS') or \
self.parent.get_encoded('TCA_POLICE_TBF')
if parms is not None:
self.value = getattr(parms, self.__class__.__name__)
self['value'] = struct.pack('I' * 256,
*(int(x) for x in self.value))
nla.encode(self)
def encode(self):
family = self.get('family', AF_UNSPEC)
if family in (AF_INET, AF_INET6):
addr = inet_pton(family, self['addr'])
else:
raise TypeError('Family %s not supported for RTA_VIA'
% family)
self['value'] = struct.pack('H', family) + addr
nla.encode(self)
def encode(self):
self.rtab = None
self.ptab = None
if self.get('rate', False):
self.rtab = self.calc_rtab('rate')
if self.get('peak', False):
self.ptab = self.calc_rtab('peak')
if self.get('ceil', False):
self.ctab = self.calc_rtab('ceil')
nla.encode(self)
def encode(self):
self.rtab = None
self.ptab = None
if self.get('rate', False):
self.rtab = self.calc_rtab('rate')
if self.get('peak', False):
self.ptab = self.calc_rtab('peak')
if self.get('ceil', False):
self.ctab = self.calc_rtab('ceil')
nla.encode(self)
def encode(self):
if self['addr'].find(":") > -1:
self['family'] = AF_INET6
self['addr4'] = 0 # Set to NULL
self['addr6'] = inet_pton(AF_INET6, self['addr'])
else:
self['family'] = AF_INET
self['addr4'] = unpack('>I', inet_aton(self['addr']))[0]
self['addr6'] = b'\x00\x00\x00\x00\x00\x00\x00\x00'
self['port'] = int(self['port'])
nla.encode(self)
def encode(self):
# Get action type and convert string to value
action = self['value']
self['value'] = (self
.actions
.get(action,
self.SEG6_LOCAL_ACTION_UNSPEC))
# Convert action type to u32
self['value'] = self['value'] & 0xffffffff
# Finally encode as nla
nla.encode(self)
def encode(self):
#
# for details see:
url = 'https://github.com/svinota/pyroute2/issues/531'
v = self.value
for flag in GRE_VALUES:
v &= ~flag
if v != 0:
log.warning('possibly incorrect GRE flags, '
'see %s' % url)
nla.encode(self)
def encode(self):
#
# for details see:
url = 'https://github.com/svinota/pyroute2/issues/531'
v = self.value
for flag in GRE_VALUES:
v &= ~flag
if v != 0:
log.warning('possibly incorrect GRE flags, '
'see %s' % url)
nla.encode(self)
def encode(self):
if self['addr'].find(":") > -1:
self['family'] = AF_INET6
self['addr4'] = 0 # Set to NULL
self['addr6'] = inet_pton(AF_INET6, self['addr'])
else:
self['family'] = AF_INET
self['addr4'] = unpack('>I',
inet_aton(self['addr']))[0]
self['addr6'] = bytearray(4) # Set 4 bytes to NULL
self['port'] = int(self['port'])
self['__padding'] = 0
nla.encode(self)
def encode(self):
#
# There are two ways to specify netns
#
# 1. provide fd to an open file
# 2. provide a file name
#
# In the first case, the value is passed to the kernel
# as is. In the second case, the object opens appropriate
# file from `self.netns_run_dir` and closes it upon
# `__del__(self)`
if isinstance(self.value, int):
self['value'] = self.value
else:
self.netns_fd = os.open('%s/%s' % (self.netns_run_dir,
self.value), os.O_RDONLY)
self['value'] = self.netns_fd
self.register_clean_cb(self.close)
nla.encode(self)
def encode(self):
#
# There are two ways to specify netns
#
# 1. provide fd to an open file
# 2. provide a file name
#
# In the first case, the value is passed to the kernel
# as is. In the second case, the object opens appropriate
# file from `self.netns_run_dir` and closes it upon
# `__del__(self)`
if isinstance(self.value, int):
self['value'] = self.value
else:
self.netns_fd = os.open('%s/%s' % (self.netns_run_dir,
self.value), os.O_RDONLY)
self['value'] = self.netns_fd
self.register_clean_cb(self.close)
nla.encode(self)
def encode(self):
# Set default values
self['layer_opnd'] = 0
self['align_flags'] = 0
# Build align_flags byte
if 'trans' in self:
self['align_flags'] = TCF_EM_CMP_TRANS << 4
for k, v in ALIGNS_DICT.items():
if self['align'].lower() == v:
self['align_flags'] |= k
break
# Build layer_opnd byte
if isinstance(self['opnd'], int):
self['layer_opnd'] = self['opnd'] << 4
else:
for k, v in OPERANDS_DICT.items():
if self['opnd'].lower() in v:
self['layer_opnd'] = k << 4
break
# Layer code
if isinstance(self['layer'], int):
self['layer_opnd'] |= self['layer']
else:
for k, v in LAYERS_DICT.items():
if self['layer'].lower() in v:
self['layer_opnd'] |= k
break
self['off'] = self.get('offset', 0)
self['val'] = self.get('value', 0)
nla.encode(self)
# Patch NLA structure
self['header']['length'] -= 4
self.data = self.data[4:]
def encode(self):
if 'object' not in self:
raise ValueError('An object definition must be given!')
if 'value' not in self:
raise ValueError('A value must be given!')
# The value can either be a string or an int depending
# on the selected meta kind.
# It is really important to distinct them otherwise
# the kernel won't be nice with us...
value = self['value']
kind = self['object'].get('kind')
if not kind:
raise ValueError('Not meta kind specified!')
else:
if kind in strings_meta:
if not isinstance(value, str):
raise ValueError('{} kinds have to use string value!'
.format(' and '.join(strings_meta)))
else:
value = value.encode('utf-8')
else:
if not isinstance(value, int):
raise ValueError('Invalid value specified, it must '
'be an integer')
else:
value = pack('<I', value)
self['attrs'].append(['TCA_EM_META_HDR', self['object']])
self['attrs'].append(['TCA_EM_META_LVALUE', self.get('mask', 0)])
self['attrs'].append(['TCA_EM_META_RVALUE', value])
nla.encode(self)
# Patch NLA structure
self['header']['length'] -= 4
self.data = self.data[4:]
def encode(self):
self["value"] = state_by_name[self.value]
nla.encode(self)
def encode(self):
self['value'] = struct.pack('B' * 256,
*(int(x) for x in self.value))
nla.encode(self)
def encode(self):
self['value'] = state_by_name[self.value]
nla.encode(self)
def encode(self):
self['mac'] = ([int(x, 16) for x
in self['mac'].split(':')] +
[0] * 26)
nla.encode(self)
def encode(self):
'''
'keys': ['0x0006/0x00ff+8',
'0x0000/0xffc0+2',
'0x5/0xf+0',
'0x10/0xff+33']
=> 00060000/00ff0000 + 8
05000000/0f00ffc0 + 0
00100000/00ff0000 + 32
'''
def cut_field(key, separator):
'''
split a field from the end of the string
'''
field = '0'
pos = key.find(separator)
new_key = key
if pos > 0:
field = key[pos + 1:]
new_key = key[:pos]
return (new_key, field)
# 'header' array to pack keys to
header = [(0, 0) for i in range(256)]
keys = []
# iterate keys and pack them to the 'header'
for key in self['keys']:
# TODO tags: filter
(key, nh) = cut_field(key, '@') # FIXME: do not ignore nh
(key, offset) = cut_field(key, '+')
offset = int(offset, 0)
# a little trick: if you provide /00ff+8, that
# really means /ff+9, so we should take it into
# account
(key, mask) = cut_field(key, '/')
if mask[:2] == '0x':
mask = mask[2:]
while True:
if mask[:2] == '00':
offset += 1
mask = mask[2:]
else:
break
mask = '0x' + mask
mask = int(mask, 0)
value = int(key, 0)
bits = 24
if mask == 0 and value == 0:
key = self.u32_key(self.buf)
key['key_off'] = offset
key['key_mask'] = mask
key['key_val'] = value
keys.append(key)
for bmask in struct.unpack('4B', struct.pack('>I', mask)):
if bmask > 0:
bvalue = (value & (bmask << bits)) >> bits
header[offset] = (bvalue, bmask)
offset += 1
bits -= 8
# recalculate keys from 'header'
key = None
value = 0
mask = 0
for offset in range(256):
(bvalue, bmask) = header[offset]
if bmask > 0 and key is None:
key = self.u32_key(self.buf)
key['key_off'] = offset
key['key_mask'] = 0
key['key_val'] = 0
bits = 24
if key is not None and bits >= 0:
key['key_mask'] |= bmask << bits
key['key_val'] |= bvalue << bits
bits -= 8
if (bits < 0 or offset == 255):
keys.append(key)
key = None
assert keys
self['nkeys'] = len(keys)
# FIXME: do not hardcode flags :)
self['flags'] = 1
start = self.buf.tell()
nla.encode(self)
for key in keys:
key.encode()
self.update_length(start)
def encode(self):
# Convert to network byte order
self['value'] = inet_pton(AF_INET6, self['value'])
# Finally encode as nla
nla.encode(self)
def encode(self):
self['start'], self['end'] = self.value.split(':')
nla.encode(self)
def encode(self):
self['value'] = struct.pack('B' * 256,
*(int(x) for x in self.value))
nla.encode(self)
def encode(self):
# convert flags
if isinstance(self['value'], basestring):
self['value'] = BRIDGE_FLAGS_NAMES['BRIDGE_FLAGS_' +
self['value'].upper()]
nla.encode(self)
def encode(self):
'''
Key sample::
'keys': ['0x0006/0x00ff+8',
'0x0000/0xffc0+2',
'0x5/0xf+0',
'0x10/0xff+33']
=> 00060000/00ff0000 + 8
05000000/0f00ffc0 + 0
00100000/00ff0000 + 32
'''
def cut_field(key, separator):
'''
split a field from the end of the string
'''
field = '0'
pos = key.find(separator)
new_key = key
if pos > 0:
field = key[pos + 1:]
new_key = key[:pos]
return (new_key, field)
# 'header' array to pack keys to
header = [(0, 0) for i in range(256)]
keys = []
# iterate keys and pack them to the 'header'
for key in self['keys']:
# TODO tags: filter
(key, nh) = cut_field(key, '@') # FIXME: do not ignore nh
(key, offset) = cut_field(key, '+')
offset = int(offset, 0)
# a little trick: if you provide /00ff+8, that
# really means /ff+9, so we should take it into
# account
(key, mask) = cut_field(key, '/')
if mask[:2] == '0x':
mask = mask[2:]
while True:
if mask[:2] == '00':
offset += 1
mask = mask[2:]
else:
break
mask = '0x' + mask
mask = int(mask, 0)
value = int(key, 0)
bits = 24
if mask == 0 and value == 0:
key = self.u32_key(self.buf)
key['key_off'] = offset
key['key_mask'] = mask
key['key_val'] = value
keys.append(key)
for bmask in struct.unpack('4B', struct.pack('>I', mask)):
if bmask > 0:
bvalue = (value & (bmask << bits)) >> bits
header[offset] = (bvalue, bmask)
offset += 1
bits -= 8
# recalculate keys from 'header'
key = None
value = 0
mask = 0
for offset in range(256):
(bvalue, bmask) = header[offset]
if bmask > 0 and key is None:
key = self.u32_key(self.buf)
key['key_off'] = offset
key['key_mask'] = 0
key['key_val'] = 0
bits = 24
if key is not None and bits >= 0:
key['key_mask'] |= bmask << bits
key['key_val'] |= bvalue << bits
bits -= 8
if (bits < 0 or offset == 255):
keys.append(key)
key = None
assert keys
self['nkeys'] = len(keys)
# FIXME: do not hardcode flags :)
self['flags'] = 1
start = self.buf.tell()
nla.encode(self)
for key in keys:
key.encode()
self.update_length(start)
def encode(self):
self['flow_keys'] = self['value']
nla.encode(self)
def encode(self):
# convert flags
if isinstance(self['value'], basestring):
self['value'] = BRIDGE_FLAGS_NAMES['BRIDGE_FLAGS_' +
self['value'].upper()]
nla.encode(self)
def encode(self):
family = self.get('family', AF_UNSPEC)
if family in (AF_INET, AF_INET6):
addr = inet_pton(family, self['addr'])
self['value'] = struct.pack('H', family) + addr
nla.encode(self)
def encode(self):
encoded_guid = self['ib_port_guid'].split(':')[::-1]
self['ib_port_guid'] = ([0] * 4 +
[int(x, 16)
for x in encoded_guid] + [0] * 20)
nla.encode(self)
def encode(self):
self['flow_mode'] = self['value']
nla.encode(self)
def encode(self):
# Convert to network byte order
self['value'] = inet_pton(AF_INET6, self['value'])
# Finally encode as nla
nla.encode(self)
def encode(self):
self['flow_keys'] = self['value']
nla.encode(self)
def encode(self):
# Retrieve the family
family = self.get_family()
# Seg6 can be applied only to IPv6
if family == AF_INET6:
# Get mode
mode = self['mode']
# Get segs
segs = self['segs']
# Get hmac
hmac = self.get('hmac', None)
# With "inline" mode there is not
# encap into an outer IPv6 header
if mode == "inline":
# Add :: to segs
segs.insert(0, "::")
# Add mode to value
self['encapmode'] = (self
.encapmodes
.get(mode,
self.SEG6_IPTUN_MODE_ENCAP))
# Calculate srlen
srhlen = 8 + 16 * len(segs)
# If we are using hmac we have a tlv as trailer data
if hmac:
# Since we can use sha1 or sha256
srhlen += 40
# Calculate and set hdrlen
self['hdrlen'] = (srhlen >> 3) - 1
# Add seg6 type
self['type'] = self.SEG6_TYPE
# Add segments left
self['segments_left'] = len(segs) - 1
# Add fitst segment
self['first_segment'] = len(segs) - 1
# If hmac is used we have to set the flags
if hmac:
# Add SR6_FLAG1_HMAC
self['flags'] |= self.SR6_FLAG1_HMAC
# Init segs
self['segs'] = b''
# Iterate over segments
for seg in segs:
# Convert to network byte order and add to value
self['segs'] += inet_pton(family, seg)
# Initialize tlvs
self['tlvs'] = b''
# If hmac is used we have to properly init tlvs
if hmac:
# Put type
self['tlvs'] += struct.pack('B', self.SR6_TLV_HMAC)
# Put length -> 40-2
self['tlvs'] += struct.pack('B', 38)
# Put reserved
self['tlvs'] += struct.pack('H', 0)
# Put hmac key
self['tlvs'] += struct.pack('>I', hmac)
# Put hmac
self['tlvs'] += struct.pack('QQQQ', 0, 0, 0, 0)
else:
raise TypeError('Family %s not supported for seg6 tunnel'
% family)
# Finally encode as nla
nla.encode(self)
def encode(self):
self['flow_mode'] = self['value']
nla.encode(self)
def encode(self):
if not isinstance(self['value'], tuple):
self['value'] = (self['value'] & 0xffffffffffffffff,
self['value'] >> 64)
nla.encode(self)
def encode(self):
# Set default Auto-Rate value
if not self.get_attr('TCA_CAKE_AUTORATE'):
self['attrs'].append(['TCA_CAKE_AUTORATE', 0])
nla.encode(self)
def encode(self):
self['mac'] = (
[int(x, 16)
for x in self['mac'].split(':')] + [0] * 26)
nla.encode(self)
def encode(self):
self['value'] = state_by_name[self.value]
nla.encode(self)
def encode(self):
family = self.get('family', AF_UNSPEC)
if family in (AF_INET, AF_INET6):
addr = inet_pton(family, self['addr'])
self['value'] = struct.pack('H', family) + addr
nla.encode(self)
def encode(self):
self['start'], self['end'] = self.value.split(':')
nla.encode(self)
def encode(self):
# Retrieve the family
family = self.get_family()
# Seg6 can be applied only to IPv6
if family == AF_INET6:
# Get mode
mode = self['mode']
# Get segs
segs = self['segs']
# Get hmac
hmac = self.get('hmac', None)
# With "inline" mode there is not
# encap into an outer IPv6 header
if mode == "inline":
# Add :: to segs
segs.insert(0, "::")
# Add mode to value
self['encapmode'] = (self
.encapmodes
.get(mode,
self.SEG6_IPTUN_MODE_ENCAP))
# Calculate srlen
srhlen = 8 + 16 * len(segs)
# If we are using hmac we have a tlv as trailer data
if hmac:
# Since we can use sha1 or sha256
srhlen += 40
# Calculate and set hdrlen
self['hdrlen'] = (srhlen >> 3) - 1
# Add seg6 type
self['type'] = self.SEG6_TYPE
# Add segments left
self['segments_left'] = len(segs) - 1
# Add fitst segment
self['first_segment'] = len(segs) - 1
# If hmac is used we have to set the flags
if hmac:
# Add SR6_FLAG1_HMAC
self['flags'] |= self.SR6_FLAG1_HMAC
# Init segs
self['segs'] = b''
# Iterate over segments
for seg in segs:
# Convert to network byte order and add to value
self['segs'] += inet_pton(family, seg)
# Initialize tlvs
self['tlvs'] = b''
# If hmac is used we have to properly init tlvs
if hmac:
# Put type
self['tlvs'] += struct.pack('B', self.SR6_TLV_HMAC)
# Put length -> 40-2
self['tlvs'] += struct.pack('B', 38)
# Put reserved
self['tlvs'] += struct.pack('H', 0)
# Put hmac key
self['tlvs'] += struct.pack('>I', hmac)
# Put hmac
self['tlvs'] += struct.pack('QQQQ', 0, 0, 0, 0)
else:
raise TypeError('Family %s not supported for seg6 tunnel'
% family)
# Finally encode as nla
nla.encode(self)
def encode(self):
self['key'] = b64decode(self['value'])
nla.encode(self)
