pyPLC/pyPlcHomeplug.py

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# Preconditions:
# Library pcap-ct (not libpcap, not pylibpcap, not pypcap)
#
# Version 2022-08-14:
# - Selection of interfaces ok
# - Sniffing of the SLAC-request ok
# - Transmission of a demo message ok
#
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# Test results 2022-10-15
# 1. GET_SW.REQ broadcast is answered by both TPlinks, while the first is connected to eth, the other via PLC at the first.
# 2. Step 1 works also, if we use a different MAC address than the original laptop ethernet MAC.
# 3. CM_SET_KEY addressed to the correct destination works, with the following results:
# - there were cases, when the TPlink responded "negative", but with a "valid" none (each time it used a new mynonce, and correctly
# reflected our mynonce.
# - but also there is "positive" response, also with correct nonces.
# - also the Devolo reponds positive and with correct nonces.
# - not yet checked, whether the NMK is really set
# 4. CM_GET_KEY with wrong NID is refused by the devolo. But at least it delivers the NID (e.g. d57c1fe9544e01), and if we use this NID in the next
# request, it responds with KEY_GRANTED, Keytype=NMK, and a key 7f19ba0261892d59b7ea42aed875d2320000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000
# This key delivers exactly the NMK, which we have set in the CM_SET_KEY.
# But: There are some pitfalls:
# The CM_SET_KEY responds in some cases (wrong request) positive, but does not apply the NMK.
# If the CM_SET_KEY is well-formatted, including the correct NID, we get a false-negative response, and
# we see the LEDs on the adaptor shortly going completely off, completely on, and back to normal state. This
# is the sign, that the new key was accepted. It means, the
# adaptor is making a reset, to apply the new key.
# 5. CM_SET_KEY and CM_GET_KEY works also when sent to broadcast address. For both, devolo and tpLink.
# 2022-10-18 further tests
# 6. The devolo reports the SLAC_PARAM from the standalone-IONIQ to the wirkshark. Even in the case, when the devolo is paired to a tpLink.
# 7. The tpLink does NOT report the SLAC_PARAM to ethernet. Bad.
# 8. The tpLink has software from 2017, maybe the SLAC was removed at this version.
# 9. Article regarding firmware- and configuration update: https://fitzcarraldoblog.wordpress.com/2020/07/22/updating-the-powerline-adapters-in-my-home-network/
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import pcap
import pyPlcIpv6
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import udplog
import time
import os
from helpers import * # prettyMac etc
from pyPlcModes import *
from mytestsuite import *
from random import random
from configmodule import getConfigValue, getConfigValueBool
from datetime import datetime
import sys
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MAC_BROADCAST = [0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF ]
CM_SET_KEY = 0x6008
CM_GET_KEY = 0x600C
CM_SC_JOIN = 0x6010
CM_CHAN_EST = 0x6014
CM_TM_UPDATE = 0x6018
CM_AMP_MAP = 0x601C
CM_BRG_INFO = 0x6020
CM_CONN_NEW = 0x6024
CM_CONN_REL = 0x6028
CM_CONN_MOD = 0x602C
CM_CONN_INFO = 0x6030
CM_STA_CAP = 0x6034
CM_NW_INFO = 0x6038
CM_GET_BEACON = 0x603C
CM_HFID = 0x6040
CM_MME_ERROR = 0x6044
CM_NW_STATS = 0x6048
CM_SLAC_PARAM = 0x6064
CM_START_ATTEN_CHAR = 0x6068
CM_ATTEN_CHAR = 0x606C
CM_PKCS_CERT = 0x6070
CM_MNBC_SOUND = 0x6074
CM_VALIDATE = 0x6078
CM_SLAC_MATCH = 0x607C
CM_SLAC_USER_DATA = 0x6080
CM_ATTEN_PROFILE = 0x6084
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CM_GET_SW = 0xA000
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MMTYPE_REQ = 0x0000
MMTYPE_CNF = 0x0001
MMTYPE_IND = 0x0002
MMTYPE_RSP = 0x0003
STATE_INITIAL = 0
STATE_MODEM_SEARCH_ONGOING = 1
STATE_READY_FOR_SLAC = 2
STATE_WAITING_FOR_MODEM_RESTARTED = 3
STATE_WAITING_FOR_SLAC_PARAM_CNF = 4
STATE_SLAC_PARAM_CNF_RECEIVED = 5
STATE_BEFORE_START_ATTEN_CHAR = 6
STATE_SOUNDING = 7
STATE_WAIT_FOR_ATTEN_CHAR_IND = 8
STATE_ATTEN_CHAR_IND_RECEIVED = 9
STATE_DELAY_BEFORE_MATCH = 10
STATE_WAITING_FOR_SLAC_MATCH_CNF = 11
STATE_WAITING_FOR_RESTART2 = 12
STATE_FIND_MODEMS2 = 13
STATE_WAITING_FOR_SW_VERSIONS = 14
STATE_READY_FOR_SDP = 15
STATE_SDP = 16
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class pyPlcHomeplug():
def showIpAddresses(self, mybytearray):
addr = lambda pkt, offset: '.'.join(str(pkt[i]) for i in range(offset, offset + 4))
self.addToTrace('SRC %-16s\tDST %-16s' % (addr(mybytearray, self.sniffer.dloff + 12), addr(mybytearray, self.sniffer.dloff + 16)))
def showMacAddresses(self, mybytearray):
strDestMac = ""
for i in range(0, 6):
strDestMac = strDestMac + twoCharHex(mybytearray[i]) + ":"
strSourceMac = ""
for i in range(5, 12):
strSourceMac = strSourceMac + twoCharHex(mybytearray[i]) + ":"
lastThreeOfSource = mybytearray[6]*256*256 + mybytearray[7]*256 + mybytearray[8]
strSourceFriendlyName = ""
if (lastThreeOfSource == 0x0a663a):
strSourceFriendlyName="Fritzbox"
if (lastThreeOfSource == 0x0064c3):
strSourceFriendlyName="Ioniq"
self.addToTrace("From " + strSourceMac + strSourceFriendlyName + " to " + strDestMac)
def getSourceMacAddressAsString(self):
strSourceMac = ""
for i in range(6, 12):
strSourceMac = strSourceMac + twoCharHex(self.myreceivebuffer[i])
if (i<11):
strSourceMac = strSourceMac + ":"
return strSourceMac
def getEtherType(self, messagebufferbytearray):
etherType=0
if len(messagebufferbytearray)>(6+6+2):
etherType=messagebufferbytearray[12]*256 + messagebufferbytearray[13]
return etherType
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def fillSourceMac(self, mac, offset=6): # at offset 6 in the ethernet frame, we have the source MAC
# we can give a different offset, to re-use the MAC also in the data area
for i in range(0, 6):
self.mytransmitbuffer[offset+i]=mac[i]
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def fillDestinationMac(self, mac, offset=0): # at offset 0 in the ethernet frame, we have the destination MAC
# we can give a different offset, to re-use the MAC also in the data area
for i in range(0, 6):
self.mytransmitbuffer[offset+i]=mac[i]
def fillRunId(self, offset):
# at the given offset in the transmit buffer, fill the 8-bytes-RunId.
for i in range(0, 8):
self.mytransmitbuffer[offset+i]=self.pevRunId[i]
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def cleanTransmitBuffer(self): # fill the complete ethernet transmit buffer with 0x00
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for i in range(0, len(self.mytransmitbuffer)):
self.mytransmitbuffer[i]=0
def setNmkAt(self, index):
# sets the Network Membership Key (NMK) at a certain position in the transmit buffer
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for i in range(0, 16):
if (self.iAmEvse):
# In EvseMode, the NMK is freely chosen:
self.mytransmitbuffer[index+i]=self.NMK_EVSE_random[i] # NMK
else:
# In PevMode, the NMK is the one which was received in the SlacMatchConf. Or a default, if we did not receive any.
self.mytransmitbuffer[index+i]=self.NMK[i] # NMK
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def setNidAt(self, index):
# (b0f2e695666b03 was NID of TPlink)
# copies the network ID (NID, 7 bytes) into the wished position in the transmit buffer
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for i in range(0, 7):
self.mytransmitbuffer[index+i]=self.NID[i]
def getManagementMessageType(self):
# calculates the MMTYPE (base value + lower two bits), see Table 11-2 of homeplug spec
return (self.myreceivebuffer[16]<<8) + self.myreceivebuffer[15]
def composeGetSwReq(self):
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# GET_SW.REQ request, as used by the win10 laptop
self.mytransmitbuffer = bytearray(60)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
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self.fillSourceMac(self.myMAC)
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# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x00 # version
self.mytransmitbuffer[15]=0x00 # GET_SW.REQ
self.mytransmitbuffer[16]=0xA0 #
self.mytransmitbuffer[17]=0x00 # Vendor OUI
self.mytransmitbuffer[18]=0xB0 #
self.mytransmitbuffer[19]=0x52 #
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def composeGetSwWithRamdomMac(self):
# GET_SW.REQ request, as used by the win10 laptop
self.mytransmitbuffer = bytearray(60)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
self.fillSourceMac(self.myMAC)
# patch the lower three bytes of the MAC with a random value
self.mytransmitbuffer[8] = self.randomMac & 0xff
self.mytransmitbuffer[9] = (self.randomMac>>16) & 0xff
self.mytransmitbuffer[10] = (self.randomMac>>8) & 0xff
self.mytransmitbuffer[11] = self.randomMac & 0xff
if (1):
if ((self.randomMac%16)==0):
self.fillSourceMac([0xb8, 0x27, 0xeb, 0xa3, 0xaf, 0x34 ])
if ((self.randomMac%16)==1):
self.fillSourceMac([0xb8, 0x27, 0xeb, 0x72, 0x66, 0x06 ])
self.randomMac += 1 # new MAC for the next round
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x00 # version
self.mytransmitbuffer[15]=0x00 # GET_SW.REQ
self.mytransmitbuffer[16]=0xA0 #
self.mytransmitbuffer[17]=0x00 # Vendor OUI
self.mytransmitbuffer[18]=0xB0 #
self.mytransmitbuffer[19]=0x52 #
def composeSetKey(self, variation=0):
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# CM_SET_KEY.REQ request
# From example trace from catphish https://openinverter.org/forum/viewtopic.php?p=40558&sid=9c23d8c3842e95c4cf42173996803241#p40558
# Table 11-88 in the homeplug_av21_specification_final_public.pdf
self.mytransmitbuffer = bytearray(60)
self.cleanTransmitBuffer()
# Destination MAC
#self.fillDestinationMac(MAC_DEVOLO_26)
#self.fillDestinationMac(MAC_TPLINK_E4)
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
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self.fillSourceMac(self.myMAC)
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# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x08 # CM_SET_KEY.REQ
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # frag_index
self.mytransmitbuffer[18]=0x00 # frag_seqnum
self.mytransmitbuffer[19]=0x01 # 0 key info type
self.mytransmitbuffer[20]=0xaa # 1 my nonce
self.mytransmitbuffer[21]=0xaa # 2
self.mytransmitbuffer[22]=0xaa # 3
self.mytransmitbuffer[23]=0xaa # 4
self.mytransmitbuffer[24]=0x00 # 5 your nonce
self.mytransmitbuffer[25]=0x00 # 6
self.mytransmitbuffer[26]=0x00 # 7
self.mytransmitbuffer[27]=0x00 # 8
self.mytransmitbuffer[28]=0x04 # 9 nw info pid
self.mytransmitbuffer[29]=0x00 # 10 info prn
self.mytransmitbuffer[30]=0x00 # 11
self.mytransmitbuffer[31]=0x00 # 12 pmn
self.mytransmitbuffer[32]=0x00 # 13 cco cap
self.setNidAt(33) # 14-20 nid 7 bytes from 33 to 39
# Network ID to be associated with the key distributed herein.
# The 54 LSBs of this field contain the NID (refer to Section 3.4.3.1). The
# two MSBs shall be set to 0b00.
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self.mytransmitbuffer[40]=0x01 # 21 peks (payload encryption key select) Table 11-83. 01 is NMK. We had 02 here, why???
# with 0x0F we could choose "no key, payload is sent in the clear"
self.setNmkAt(41)
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self.mytransmitbuffer[41]+=variation # to try different NMKs
# and three remaining zeros
def composeGetKey(self):
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# CM_GET_KEY.REQ request
# from https://github.com/uhi22/plctool2/blob/master/listen_to_eth.c
# and homeplug_av21_specification_final_public.pdf
self.mytransmitbuffer = bytearray(60)
self.cleanTransmitBuffer()
# Destination MAC
#self.fillDestinationMac(MAC_DEVOLO_26)
#self.fillDestinationMac(MAC_TPLINK_E4)
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
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self.fillSourceMac(self.myMAC)
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# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x0C # CM_GET_KEY.REQ https://github.com/uhi22/plctool2/blob/master/plc_homeplug.h
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # 0 Request Type 0=direct
self.mytransmitbuffer[20]=0x01 # 1 RequestedKeyType only "NMK" is permitted over the H1 interface.
# value see HomeplugAV2.1 spec table 11-89. 1 means AES-128.
self.setNidAt(21)# NID starts here (table 11-91 Homeplug spec is wrong. Verified by accepted command.)
self.mytransmitbuffer[28]=0xaa # 10-13 mynonce. The position at 28 is verified by the response of the devolo.
self.mytransmitbuffer[29]=0xaa #
self.mytransmitbuffer[30]=0xaa #
self.mytransmitbuffer[31]=0xaa #
self.mytransmitbuffer[32]=0x04 # 14 PID. According to ISO15118-3 fix value 4, "HLE protocol"
self.mytransmitbuffer[33]=0x00 # 15-16 PRN Protocol run number
self.mytransmitbuffer[34]=0x00 #
self.mytransmitbuffer[35]=0x00 # 17 PMN Protocol message number
def composeSlacParamReq(self):
# SLAC_PARAM request, as it was recorded 2021-12-17 WP charger 2
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self.mytransmitbuffer = bytearray(60)
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self.cleanTransmitBuffer()
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# Destination MAC
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self.fillDestinationMac(MAC_BROADCAST)
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# Source MAC
self.fillSourceMac(self.pevMac)
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# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x64 # SLAC_PARAM.REQ
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
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self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 #
self.mytransmitbuffer[20]=0x00 #
self.fillRunId(21) # 21 to 28: 8 bytes runid. The Ioniq uses the PEV mac plus 00 00. Tesla uses "TESLA EV".
# rest is 00
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def composeSlacParamCnf(self):
self.mytransmitbuffer = bytearray(60)
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self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(self.pevMac)
# Source MAC
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self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x65 # SLAC_PARAM.confirm
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0xff # 19-24 sound target
self.mytransmitbuffer[20]=0xff #
self.mytransmitbuffer[21]=0xff #
self.mytransmitbuffer[22]=0xff #
self.mytransmitbuffer[23]=0xff #
self.mytransmitbuffer[24]=0xff #
self.mytransmitbuffer[25]=0x0A # sound count
self.mytransmitbuffer[26]=0x06 # timeout
self.mytransmitbuffer[27]=0x01 # resptype
self.fillDestinationMac(self.pevMac, 28) # forwarding_sta, same as PEV MAC, plus 2 bytes 00 00
self.mytransmitbuffer[34]=0x00 #
self.mytransmitbuffer[35]=0x00 #
self.fillRunId(36) # 36 to 43 runid 8 bytes
# rest is 00
def composeSpecialMessage(self):
# special "homeplug" message, to control a hardware device.
# We re-purpose the ATTEN_CHAR.IND, because a AR4720 PEV modem is transparent for it also in unpaired state,
# and it contains a lot of space which can be used to transfer data. Also it is not expected to disturb the
# normal traffic, because it may be also caused by cross-coupling from an other charger, and the normal
# communication should be immune to such things.
self.mytransmitbuffer = bytearray(129)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x6E # ATTEN_CHAR.IND
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # security
self.fillDestinationMac(MAC_BROADCAST, 21) # The wireshark calls it source_mac, but alpitronic fills it with PEV mac.
self.fillRunId(27) # runid 8 bytes
self.mytransmitbuffer[35]=0x00 # 35 - 51 source_id, 17 bytes. The alpitronic fills it with 00
self.mytransmitbuffer[52]=0x00 # 52 - 68 response_id, 17 bytes. The alpitronic fills it with 00.
self.mytransmitbuffer[69]=0x0A # Number of sounds. 10 in normal case.
self.mytransmitbuffer[70]=0x3A # Number of groups = 58.
for i in range(71, 129): # 71 to 128: 58 special-purpose-bytes
self.mytransmitbuffer[i]=self.specialMessageTransmitBuffer[i-71]
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def composeStartAttenCharInd(self):
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# reference: see wireshark interpreted frame from ioniq
self.mytransmitbuffer = bytearray(60)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x6A # START_ATTEN_CHAR.IND
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # sectype
self.mytransmitbuffer[21]=0x0a # number of sounds: 10
self.mytransmitbuffer[22]=6 # timeout N*100ms. Normally 6, means in 600ms all sounds must have been tranmitted.
# Todo: As long we are a little bit slow, lets give 1000ms instead of 600, so that the
# charger is able to catch it all.
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self.mytransmitbuffer[23]=0x01 # response type
self.fillSourceMac(self.myMAC, 24) # 24 to 29: sound_forwarding_sta, MAC of the PEV
self.fillRunId(30) # 30 to 37: runid 8 bytes
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# rest is 00
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def composeNmbcSoundInd(self):
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# reference: see wireshark interpreted frame from Ioniq
self.mytransmitbuffer = bytearray(71)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(MAC_BROADCAST)
# Source MAC
self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x76 # NMBC_SOUND.IND
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # sectype
self.mytransmitbuffer[21]=0x00 # 21 to 37 sender ID, all 00
self.mytransmitbuffer[38]=self.remainingNumberOfSounds # countdown. Remaining number of sounds. Starts with 9 and counts down to 0.
self.fillRunId(39) # 39 to 46: runid
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self.mytransmitbuffer[47]=0x00 # 47 to 54: reserved, all 00
# 55 to 70: random number. All 0xff in the ioniq message.
for i in range(55, 71):
self.mytransmitbuffer[i]=0xFF
def composeAttenCharInd(self):
self.mytransmitbuffer = bytearray(129)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(self.pevMac)
# Source MAC
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self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x6E # ATTEN_CHAR.IND
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # security
self.fillDestinationMac(self.pevMac, 21) # The wireshark calls it source_mac, but alpitronic fills it with PEV mac. We use the PEV MAC.
self.fillRunId(27) # runid 8 bytes
self.mytransmitbuffer[35]=0x00 # 35 - 51 source_id, 17 bytes. The alpitronic fills it with 00
self.mytransmitbuffer[52]=0x00 # 52 - 68 response_id, 17 bytes. The alpitronic fills it with 00.
self.mytransmitbuffer[69]=0x0A # Number of sounds. 10 in normal case. Should this be more flexible, e.g. using the counter from first MNBC_SOUND?
self.mytransmitbuffer[70]=0x3A # Number of groups = 58. Should this be more flexible?
for i in range(71, 129): # 71 to 128: The group attenuation for the 58 announced groups.
self.mytransmitbuffer[i]=9 # Typical values are between 1 and 0x19. Since we have no real measurements from the AR7020,
# we just simulate something. 0 seems to be interpreted as "defect", the IONIQ does not send
# a positive response in this case.
# higher attenuation for the higher frequencies, to be a little bit realistic (real data from alpitronic trace)
self.mytransmitbuffer[126]=0x0f
self.mytransmitbuffer[127]=0x13
self.mytransmitbuffer[128]=0x19
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def composeAttenCharRsp(self):
# reference: see wireshark interpreted frame from Ioniq
self.mytransmitbuffer = bytearray(70)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(self.evseMac)
# Source MAC
self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x6F # ATTEN_CHAR.RSP
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # sectype
self.fillSourceMac(self.myMAC, 21) # 21 to 26: source MAC
self.fillRunId(27) # 27 to 34: runid
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# 35 to 51: source_id, all 00
# 52 to 68: resp_id, all 00
# 69: result. 0 is ok
def composeSlacMatchReq(self):
# reference: see wireshark interpreted frame from Ioniq
self.mytransmitbuffer = bytearray(85)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(self.evseMac)
# Source MAC
self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x7C # SLAC_MATCH.REQ
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # sectype
self.mytransmitbuffer[21]=0x3E # 21 to 22: length
self.mytransmitbuffer[22]=0x00 #
# 23 to 39: pev_id, all 00
self.fillSourceMac(self.myMAC, 40) # 40 to 45: PEV MAC
# 46 to 62: evse_id, all 00
self.fillDestinationMac(self.evseMac, 63) # 63 to 68: EVSE MAC
self.fillRunId(69) # 69 to 76: runid
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# 77 to 84: reserved, all 00
def composeSlacMatchCnf(self):
self.mytransmitbuffer = bytearray(109)
self.cleanTransmitBuffer()
# Destination MAC
self.fillDestinationMac(self.pevMac)
# Source MAC
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self.fillSourceMac(self.myMAC)
# Protocol
self.mytransmitbuffer[12]=0x88 # Protocol HomeplugAV
self.mytransmitbuffer[13]=0xE1
self.mytransmitbuffer[14]=0x01 # version
self.mytransmitbuffer[15]=0x7D # SLAC_MATCH.CNF
self.mytransmitbuffer[16]=0x60 #
self.mytransmitbuffer[17]=0x00 # 2 bytes fragmentation information. 0000 means: unfragmented.
self.mytransmitbuffer[18]=0x00 #
self.mytransmitbuffer[19]=0x00 # apptype
self.mytransmitbuffer[20]=0x00 # security
self.mytransmitbuffer[21]=0x56 # length 2 byte
self.mytransmitbuffer[22]=0x00 #
# 23 - 39: pev_id 17 bytes. All zero in alpi/Ioniq trace.
self.fillDestinationMac(self.pevMac, 40) # 40 - 45 pev_mac
# 46 - 62: evse_id 17 bytes. All zero in alpi/Ioniq trace.
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self.fillSourceMac(self.myMAC, 63) # 63 - 68 evse_mac
self.fillRunId(69) # runid 8 bytes 69-76 run_id. Is the ioniq mac plus 00 00.
# 77 to 84 reserved 0
self.setNidAt(85) # 85-91 NID. We can nearly freely choose this, but the upper two bits need to be zero
# 92 reserved 0
self.setNmkAt(93) # 93 to 108 NMK. We can freely choose this. Normally we should use a random number.
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def sendTestFrame(self, selection):
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if (selection=="1"):
self.composeSlacParamReq()
self.addToTrace("transmitting SLAC_PARAM.REQ...")
self.transmit(self.mytransmitbuffer)
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if (selection=="2"):
self.composeSlacParamCnf()
self.addToTrace("transmitting SLAC_PARAM.CNF...")
self.transmit(self.mytransmitbuffer)
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if (selection=="S"):
self.composeGetSwReq()
self.addToTrace("transmitting GetSwReq...")
self.transmit(self.mytransmitbuffer)
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if (selection=="s"):
self.composeSetKey(0)
self.addToTrace("transmitting SET_KEY.REQ (key 0)")
self.transmit(self.mytransmitbuffer)
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if (selection=="t"):
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self.composeSetKey(2) # set key with modified content
self.addToTrace("transmitting SET_KEY.REQ (key 2)")
self.transmit(self.mytransmitbuffer)
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if (selection=="G"):
self.composeGetKey()
self.addToTrace("transmitting GET_KEY")
self.transmit(self.mytransmitbuffer)
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if (selection=="M"):
self.composeGetSwWithRamdomMac()
self.addToTrace("transmitting GetSwWithRamdomMac")
self.transmit(self.mytransmitbuffer)
if (selection=="5"):
self.sendSpecialMessageToControlThePowerSupply(20, 1)
if (selection=="6"):
self.sendSpecialMessageToControlThePowerSupply(100, 1)
if (selection=="7"):
self.sendSpecialMessageToControlThePowerSupply(200, 1)
if (selection=="8"):
self.sendSpecialMessageToControlThePowerSupply(300, 1)
if (selection=="9"):
self.sendSpecialMessageToControlThePowerSupply(400, 1)
if (selection=="0"):
self.sendSpecialMessageToControlThePowerSupply(0, 0)
def transmit(self, pkt):
self.sniffer.sendpacket(bytes(pkt))
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def evaluateGetKeyCnf(self):
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self.addToTrace("received GET_KEY.CNF")
self.numberOfFoundModems += 1
sourceMac=bytearray(6)
for i in range(0, 6):
sourceMac[i] = self.myreceivebuffer[6+i]
strMac=prettyMac(sourceMac)
result = self.myreceivebuffer[19] # 0 in case of success
if (result==0):
strResult="(OK)"
else:
strResult="(NOK)"
self.addToTrace("Modem #" + str(self.numberOfFoundModems) + " has " + strMac + " and result code is " + str(result) + strResult)
if (self.numberOfFoundModems>1):
self.addToTrace("Info: NOK is normal for remote modems.")
# We observed the following cases:
# (A) Result=1 (NOK), NID all 00, key all 00: We requested the key with the wrong NID.
# (B) Result=0 (OK), NID all 00, key non-zero: We used the correct NID for the request.
# It is the local TPlink adaptor. A fresh started non-coordinator, like the PEV side.
# (C) Result=0 (OK), NID non-zero, key non-zero: We used the correct NID for the request.
# It is the local TPlink adaptor.
# (D) Result=1 (NOK), NID non-zero, key all 00: It was a remote device. They are rejecting the GET_KEY.
if (result==0):
# The ok case is for sure the local modem. Let's store its data.
self.localModemMac = sourceMac
self.localModemCurrentKey=bytearray(16)
s=""
for i in range(0, 16): # NMK has 16 bytes
self.localModemCurrentKey[i] = self.myreceivebuffer[41+i]
s=s+hex(self.localModemCurrentKey[i])+ " "
self.addToTrace("The local modem has key " + s)
if (self.localModemCurrentKey == bytearray(self.NMKdevelopment)):
self.addToTrace("This is the developer NMK.")
self.isDeveloperLocalKey = 1
else:
self.addToTrace("This is NOT the developer NMK.")
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s = ""
# The getkey response contains the Network ID (NID), even if the request was rejected. We store the NID,
# to have it available for the next request. Use case: A fresh started, unconnected non-Coordinator
# modem has the default-NID all 00. On the other hand, a fresh started coordinator has the
# NID which he was configured before. We want to be able to cover both cases. That's why we
# ask GET_KEY, it will tell the NID (even if response code is 1 (NOK), and we will use this
# received NID for the next request. This will be ansered positive (for the local modem).
for i in range(0, 7): # NID has 7 bytes
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self.NID[i] = self.myreceivebuffer[29+i]
s=s+hex(self.NID[i])+ " "
self.addToTrace("From GetKeyCnf, got network ID (NID) " + s)
def evaluateSetKeyCnf(self):
# The Setkey confirmation
# In spec, the result 0 means "success". But in reality, the 0 means: did not work. When it works,
# then the LEDs are blinking (device is restarting), and the response is 1.
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self.addToTrace("received SET_KEY.CNF")
result = self.myreceivebuffer[19]
if (result == 0):
self.addToTrace("SetKeyCnf says 0, this would be a bad sign for local modem, but normal for remote.")
else:
self.addToTrace("SetKeyCnf says " + str(result) + ", this is formally 'rejected', but indeed ok.")
self.publishStatus("modem is", "restarting")
self.connMgr.SlacOk()
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def evaluateGetSwCnf(self):
# The GET_SW confirmation. This contains the software version of the homeplug modem.
# Reference: see wireshark interpreted frame from TPlink, Ioniq and Alpitronic charger
self.addToTrace("[SNIFFER] received GET_SW.CNF")
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self.numberOfSoftwareVersionResponses+=1
sourceMac=bytearray(6)
for i in range(0, 6):
sourceMac[i] = self.myreceivebuffer[6+i]
strMac=prettyMac(sourceMac)
verLen = self.myreceivebuffer[22]
strVersion = ""
if ((verLen>0) and (verLen<0x30)):
for i in range(0, verLen):
x = self.myreceivebuffer[23+i]
if (x<0x20):
x=0x20 # make unprintable character to space.
strVersion+=chr(x) # convert ASCII code to string
self.addToTrace("[SNIFFER] For " + strMac + " the software version is " + strVersion)
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def evaluateSlacParamReq(self):
# We received a SLAC_PARAM request from the PEV. This is the initiation of a SLAC procedure.
# We extract the pev MAC from it.
if (self.iAmEvse==1):
self.addToTrace("received SLAC_PARAM.REQ")
for i in range(0, 6):
self.pevMac[i] = self.myreceivebuffer[6+i]
self.addressManager.setPevMac(self.pevMac)
self.showStatus(prettyMac(self.pevMac), "pevmac")
# extract the RunId from the SlacParamReq, and store it for later use
for i in range(0, 8):
self.pevRunId[i] = self.myreceivebuffer[21+i]
# We are EVSE, we want to answer.
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self.showStatus("SLAC started", "evseState")
self.composeSlacParamCnf()
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self.addToTrace("[EVSE] transmitting CM_SLAC_PARAM.CNF")
self.sniffer.sendpacket(bytes(self.mytransmitbuffer))
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def evaluateSlacParamCnf(self):
# As PEV, we receive the first response from the charger.
self.addToTrace("Checkpoint102: received SLAC_PARAM.CNF")
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if (self.iAmPev==1):
if (self.pevSequenceState==STATE_WAITING_FOR_SLAC_PARAM_CNF): # we were waiting for the SlacParamCnf
self.pevSequenceDelayCycles = 4 # original Ioniq is waiting 200ms
self.enterState(STATE_SLAC_PARAM_CNF_RECEIVED) # enter next state. Will be handled in the cyclic runPevSequencer
if ((self.iAmListener==1) or (self.iAmPev==1)):
# Take the MAC of the charger from the frame, and store it for later use.
for i in range(0, 6):
self.evseMac[i] = self.myreceivebuffer[6+i] # source MAC starts at offset 6
self.addressManager.setEvseMac(self.evseMac)
if getConfigValueBool("log_the_evse_mac_to_file"):
# Write the MAC address of the charger to a log file
self.addToTrace("SECC MAC is " + self.getSourceMacAddressAsString())
strDateTime=datetime.today().strftime('%Y-%m-%dT%H:%M:%S.%f')
MacLogFile = open('MacLog.txt', 'a')
MacLogFile.write(strDateTime + " SECC MAC " + self.getSourceMacAddressAsString() + "\n") # write the MAC to the MacLogFile
MacLogFile.close()
def evaluateMnbcSoundInd(self):
# We received MNBC_SOUND.IND from the PEV. Normally this happens 10times, with a countdown (remaining number of sounds)
# running from 9 to 0. If the countdown is 0, this is the last message. In case we are the EVSE, we need
# to answer with a ATTEN_CHAR.IND, which normally contains the attenuation for 10 sounds, 58 groups.
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self.addToTrace("received MNBC_SOUND.IND")
if (self.iAmEvse==1):
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self.showStatus("SLAC 2", "evseState")
countdown = self.myreceivebuffer[38]
if (countdown == 0):
self.composeAttenCharInd()
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self.addToTrace("[EVSE] transmitting ATTEN_CHAR.IND")
self.sniffer.sendpacket(bytes(self.mytransmitbuffer))
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def evaluateStartAttenCharInd(self):
# self.addToTrace("received START_ATTEN_CHAR.IND")
# nothing to do as PEV or EVSE.
# interpretation just in case we use it as special message in EVSE mode to get information from the power supply
if (self.iAmEvse==1):
if ((self.myreceivebuffer[38] == 0xDC) and (self.myreceivebuffer[39] == 0x55) and (self.myreceivebuffer[40] == 0xAA)):
uPresent = self.myreceivebuffer[43]
uPresent*=256
uPresent+=self.myreceivebuffer[44]
uPresent/=10 # scaling in the message is 0.1V
self.callbackShowStatus(str(uPresent), "PowerSupplyUPresent")
# Todo: evaluate other information of the power supply, like cable check result, current, temperature, ...
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def evaluateAttenCharInd(self):
self.addToTrace("received ATTEN_CHAR.IND")
if (self.iAmPev==1):
self.addToTrace("[PEVSLAC] received AttenCharInd in state " + str(self.pevSequenceState))
if (self.pevSequenceState==STATE_WAIT_FOR_ATTEN_CHAR_IND): # we were waiting for the AttenCharInd
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# todo: Handle the case when we receive multiple responses from different chargers.
# Wait a certain time, and compare the attenuation profiles. Decide for the nearest charger.
self.AttenCharIndNumberOfSounds = self.myreceivebuffer[69]
self.addToTrace("[PEVSLAC] number of sounds reported by the EVSE (should be 10): " + str(self.AttenCharIndNumberOfSounds))
self.composeAttenCharRsp()
self.addToTrace("[PEVSLAC] transmitting ATTEN_CHAR.RSP...")
self.transmit(self.mytransmitbuffer)
self.pevSequenceState=STATE_ATTEN_CHAR_IND_RECEIVED # enter next state. Will be handled in the cyclic runPevSequencer
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def evaluateSlacMatchReq(self):
# We received SLAC_MATCH.REQ from the PEV.
# If we are EVSE, we send the response.
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self.addToTrace("received SLAC_MATCH.REQ")
if (self.iAmEvse==1):
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self.showStatus("SLAC match", "evseState")
self.composeSlacMatchCnf()
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self.addToTrace("[EVSE] transmitting SLAC_MATCH.CNF")
self.sniffer.sendpacket(bytes(self.mytransmitbuffer))
def evaluateSlacMatchCnf(self):
# The SLAC_MATCH.CNF contains the NMK and the NID.
# We extract this information, so that we can use it for the CM_SET_KEY afterwards.
# References: https://github.com/qca/open-plc-utils/blob/master/slac/evse_cm_slac_match.c
# 2021-12-16_HPC_säule1_full_slac.pcapng
if (self.iAmEvse==1):
# If we are EVSE, nothing to do. We have sent the match.CNF by our own.
# The SET_KEY was already done at startup.
pass
else:
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self.addToTrace("received SLAC_MATCH.CNF")
s = ""
for i in range(0, 7): # NID has 7 bytes
self.NID[i] = self.myreceivebuffer[85+i]
s=s+hex(self.NID[i])+ " "
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self.addToTrace("From SlacMatchCnf, got network ID (NID) " + s)
s = ""
for i in range(0, 16):
self.NMK[i] = self.myreceivebuffer[93+i]
s=s+hex(self.NMK[i])+ " "
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self.addToTrace("From SlacMatchCnf, got network membership key (NMK) " + s)
# use the extracted NMK and NID to set the key in the adaptor:
self.composeSetKey(0)
self.addToTrace("Checkpoint170: transmitting CM_SET_KEY.REQ")
self.sniffer.sendpacket(bytes(self.mytransmitbuffer))
if (self.pevSequenceState==STATE_WAITING_FOR_SLAC_MATCH_CNF): # we were waiting for finishing the SLAC_MATCH.CNF and SET_KEY.REQ
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if (self.isSimulationMode!=0):
# In simulation mode, we pretend a successful SetKey response:
self.connMgr.SlacOk()
self.enterState(STATE_WAITING_FOR_RESTART2)
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def evaluateReceivedHomeplugPacket(self):
mmt = self.getManagementMessageType()
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# print(hex(mmt))
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if (mmt == CM_GET_KEY + MMTYPE_CNF):
self.evaluateGetKeyCnf()
if (mmt == CM_SLAC_MATCH + MMTYPE_REQ):
self.evaluateSlacMatchReq()
if (mmt == CM_SLAC_MATCH + MMTYPE_CNF):
self.evaluateSlacMatchCnf()
if (mmt == CM_SLAC_PARAM + MMTYPE_REQ):
self.evaluateSlacParamReq()
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if (mmt == CM_SLAC_PARAM + MMTYPE_CNF):
self.evaluateSlacParamCnf()
if (mmt == CM_START_ATTEN_CHAR + MMTYPE_IND):
self.evaluateStartAttenCharInd()
if (mmt == CM_MNBC_SOUND + MMTYPE_IND):
self.evaluateMnbcSoundInd()
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if (mmt == CM_ATTEN_CHAR + MMTYPE_IND):
self.evaluateAttenCharInd()
if (mmt == CM_SET_KEY + MMTYPE_CNF):
self.evaluateSetKeyCnf()
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if (mmt == CM_GET_SW + MMTYPE_CNF):
self.evaluateGetSwCnf()
def isEvseModemFound(self):
#return 0 # todo: look whether the MAC of the EVSE modem is in the list of detected modems
return self.numberOfFoundModems>1
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def enterState(self, n):
self.addToTrace("[PEVSLAC] from " + str(self.pevSequenceState) + " entering " + str(n))
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self.pevSequenceState = n
self.pevSequenceCyclesInState = 0
def isTooLong(self):
# The timeout handling function.
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return (self.pevSequenceCyclesInState > 500)
def runEvseSlacHandler(self):
if (self.evseSlacHandlerState==0):
# we did not yet configure our EVSE modem with the random key. Do it now.
# Fill some of the bytes of the NMK with random numbers. The others stay at 0x77 for easy visibility.
self.NMK_EVSE_random[2] = int(random()*255)
self.NMK_EVSE_random[3] = int(random()*255)
self.composeSetKey(0)
self.addToTrace("transmitting SET_KEY.REQ, to configure the EVSE modem with random NMK")
self.transmit(self.mytransmitbuffer)
self.evseSlacHandlerState = 1 # setkey was done
return
def publishStatus(self, s1, s2="", s3=""):
self.showStatus(s1+s2+s3, "pevState")
def modemFinder_Mainfunction(self):
if ((self.connMgr.getConnectionLevel()==5) and (self.mofi_state==0)):
# We want the modem search only, if no connection is present at all.
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if (self.isSimulationMode!=0):
self.addToTrace("[ModemFinder] We are in SimulationMode. Pretending that one modem is present.")
self.composeGetSwReq() # Send a GetSoftwareVersionRequest never the less. Just to have it in the trace.
self.transmit(self.mytransmitbuffer)
self.numberOfSoftwareVersionResponses = 1 # One pretended modem
self.connMgr.ModemFinderOk(self.numberOfSoftwareVersionResponses) # report "success" to the connection manager
self.mofi_state=2
return
self.addToTrace("[ModemFinder] Starting modem search")
self.publishStatus("Modem search")
self.composeGetSwReq()
self.transmit(self.mytransmitbuffer)
self.numberOfSoftwareVersionResponses = 0 # we want to count the modems. Start from zero.
self.mofi_stateDelay = 15 # 0.5s should be sufficient to receive the software versions from the modems
self.mofi_state = 1
return
if (self.mofi_state==1):
# waiting for responses of the modems
if (self.mofi_stateDelay>0):
self.mofi_stateDelay-=1
return
# waiting time is expired. Lets look how many responses we got.
self.addToTrace("[ModemFinder] Number of modems:" + str(self.numberOfSoftwareVersionResponses))
self.publishStatus("Modems:", str(self.numberOfSoftwareVersionResponses))
if (self.numberOfSoftwareVersionResponses>0):
self.connMgr.ModemFinderOk(self.numberOfSoftwareVersionResponses)
self.mofi_stateDelay = 15 # 0.5s to show the number of modems, before we start a new search if necessary
self.mofi_state=2
return
if (self.mofi_state==2):
# just waiting, to give the user time to read the result.
if (self.mofi_stateDelay>0):
self.mofi_stateDelay-=1
return
self.mofi_state=0 # back to idle state
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def runPevSequencer(self):
# in PevMode, check whether homeplug modem is connected, run the SLAC and SDP
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self.pevSequenceCyclesInState+=1
if (self.connMgr.getConnectionLevel()<10):
# we have no modem seen. --> nothing to do for the SLAC
if (self.pevSequenceState!=STATE_INITIAL):
self.enterState(STATE_INITIAL)
return
if (self.connMgr.getConnectionLevel()>=20):
# we have two modems in the AVLN. This means, the modem pairing is already done. --> nothing to do for the SLAC
if (self.pevSequenceState!=STATE_INITIAL):
self.enterState(STATE_INITIAL)
return
if (self.pevSequenceState==STATE_INITIAL): # Initial state.
# In real life we would check whether we see 5% PWM on the pilot line. We skip this check.
self.isSDPDone = 0
self.isDeveloperLocalKey = 0
self.nEvseModemMissingCounter = 0
self.enterState(STATE_READY_FOR_SLAC)
return
if (self.pevSequenceState==STATE_READY_FOR_SLAC):
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if (self.isSimulationMode!=0):
self.showStatus("Simu SLAC", "pevState")
else:
self.showStatus("Starting SLAC", "pevState")
self.addToTrace("[PEVSLAC] Checkpoint100: Sending SLAC_PARAM.REQ...")
self.composeSlacParamReq()
self.transmit(self.mytransmitbuffer)
self.enterState(STATE_WAITING_FOR_SLAC_PARAM_CNF)
return
if (self.pevSequenceState==STATE_WAITING_FOR_SLAC_PARAM_CNF): # Waiting for slac_param confirmation.
if (self.pevSequenceCyclesInState>=30):
# No response for 1s, this is an error.
self.addToTrace("[PEVSLAC] Timeout while waiting for SLAC_PARAM.CNF")
self.enterState(STATE_INITIAL)
# (the normal state transition is done in the reception handler)
return
if (self.pevSequenceState==STATE_SLAC_PARAM_CNF_RECEIVED): # slac_param confirmation was received.
self.pevSequenceDelayCycles = 1 # 1*30=30ms as preparation for the next state.
# Between the SLAC_PARAM.CNF and the first START_ATTEN_CHAR.IND the Ioniq waits 100ms.
# The allowed time TP_match_sequence is 0 to 100ms.
# Alpitronic and ABB chargers are more tolerant, they worked with a delay of approx
# 250ms. In contrast, Supercharger and Compleo do not respond anymore if we
# wait so long.
self.nRemainingStartAttenChar = 3 # There shall be 3 START_ATTEN_CHAR messages.
self.enterState(STATE_BEFORE_START_ATTEN_CHAR)
return
if (self.pevSequenceState==STATE_BEFORE_START_ATTEN_CHAR): # received SLAC_PARAM.CNF. Multiple transmissions of START_ATTEN_CHAR.
if (self.pevSequenceDelayCycles>0):
self.pevSequenceDelayCycles-=1
return
# The delay time is over. Let's transmit.
if (self.nRemainingStartAttenChar>0):
self.nRemainingStartAttenChar-=1
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self.composeStartAttenCharInd()
self.addToTrace("[PEVSLAC] transmitting START_ATTEN_CHAR.IND...")
self.transmit(self.mytransmitbuffer)
self.pevSequenceDelayCycles = 0 # original from ioniq is 20ms between the START_ATTEN_CHAR. Shall be 20ms to 50ms. So we set to 0 and the normal 30ms call cycle is perfect.
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return
else:
# all three START_ATTEN_CHAR.IND are finished. Now we send 10 MNBC_SOUND.IND
self.pevSequenceDelayCycles = 0 # original from ioniq is 40ms after the last START_ATTEN_CHAR.IND.
# Shall be 20ms to 50ms. So we set to 0 and the normal 30ms call cycle is perfect.
self.remainingNumberOfSounds = 10 # We shall transmit 10 sound messages.
self.enterState(STATE_SOUNDING)
return
if (self.pevSequenceState==STATE_SOUNDING): # Multiple transmissions of MNBC_SOUND.IND.
if (self.pevSequenceDelayCycles>0):
self.pevSequenceDelayCycles-=1
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return
if (self.remainingNumberOfSounds>0):
self.remainingNumberOfSounds-=1
self.composeNmbcSoundInd()
self.addToTrace("[PEVSLAC] transmitting MNBC_SOUND.IND...") # original from ioniq is 40ms after the last START_ATTEN_CHAR.IND
self.transmit(self.mytransmitbuffer)
if (self.remainingNumberOfSounds==0):
self.enterState(STATE_WAIT_FOR_ATTEN_CHAR_IND) # move fast to the next state, so that a fast response is catched in the correct state
self.pevSequenceDelayCycles = 0 # original from ioniq is 20ms between the messages.
# Shall be 20ms to 50ms. So we set to 0 and the normal 30ms call cycle is perfect.
return
if (self.pevSequenceState==STATE_WAIT_FOR_ATTEN_CHAR_IND): # waiting for ATTEN_CHAR.IND
# todo: it is possible that we receive this message from multiple chargers. We need
# to select the charger with the loudest reported signals.
if (self.isTooLong()):
self.enterState(STATE_INITIAL)
return
#(the normal state transition is done in the reception handler)
if (self.pevSequenceState==STATE_ATTEN_CHAR_IND_RECEIVED): # ATTEN_CHAR.IND was received and the
# nearest charger decided and the
# ATTEN_CHAR.RSP was sent.
self.enterState(STATE_DELAY_BEFORE_MATCH)
self.pevSequenceDelayCycles = 30 # original from ioniq is 860ms to 980ms from ATTEN_CHAR.RSP to SLAC_MATCH.REQ
return
if (self.pevSequenceState==STATE_DELAY_BEFORE_MATCH): # Waiting time before SLAC_MATCH.REQ
if (self.pevSequenceDelayCycles>0):
self.pevSequenceDelayCycles-=1
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return
self.composeSlacMatchReq()
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self.showStatus("SLAC match", "pevState")
self.addToTrace("[PEVSLAC] Checkpoint150: transmitting SLAC_MATCH.REQ...")
self.transmit(self.mytransmitbuffer)
self.enterState(STATE_WAITING_FOR_SLAC_MATCH_CNF)
return
if (self.pevSequenceState==STATE_WAITING_FOR_SLAC_MATCH_CNF): # waiting for SLAC_MATCH.CNF
if (self.isTooLong()):
self.enterState(STATE_INITIAL)
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return
self.pevSequenceDelayCycles = 100 # 3s reset wait time (may be a little bit too short, need a retry)
# (the normal state transition is done in the receive handler of SLAC_MATCH.CNF,
# including the transmission of SET_KEY.REQ)
return
if (self.pevSequenceState==STATE_WAITING_FOR_RESTART2): # SLAC is finished, SET_KEY.REQ was
# transmitted. The homeplug modem makes
# the reset and we need to wait until it
# is up with the new key.
if (self.pevSequenceDelayCycles>0):
self.pevSequenceDelayCycles-=1
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return
self.addToTrace("[PEVSLAC] Checking whether the pairing worked, by GET_KEY.REQ...")
self.numberOfFoundModems = 0 # reset the number, we want to count the modems newly.
self.composeGetKey()
self.transmit(self.mytransmitbuffer)
self.enterState(STATE_FIND_MODEMS2)
return
if (self.pevSequenceState==STATE_FIND_MODEMS2): # Waiting for the modems to answer.
if (self.pevSequenceCyclesInState>=10):
# It was sufficient time to get the answers from the modems.
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if (self.isSimulationMode!=0):
self.addToTrace("[PEVSLAC] Simulating that both modems are present now.")
self.nEvseModemMissingCounter=0
self.connMgr.ModemFinderOk(2) # Two modems were found.
# This is the end of the SLAC.
# The simulated AVLN is established, we have at least two modems in the network.
self.enterState(STATE_INITIAL)
return
self.addToTrace("[PEVSLAC] It was sufficient time to get the answers from the modems.")
# Let's see what we received.
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if (not self.isEvseModemFound()):
self.nEvseModemMissingCounter+=1
self.addToTrace("[PEVSLAC] No EVSE seen (yet). Still waiting for it.")
# At the Alpitronic we measured, that it takes 7s between the SlacMatchResponse and
# the chargers modem reacts to GetKeyRequest. So we should wait here at least 10s.
if (self.nEvseModemMissingCounter>10):
# We lost the connection to the EVSE modem. Back to the beginning.
self.addToTrace("[PEVSLAC] We lost the connection to the EVSE modem. Back to the beginning.")
self.enterState(STATE_INITIAL)
return
# The EVSE modem is (shortly) not seen. Ask again.
self.pevSequenceDelayCycles=30
self.enterState(STATE_WAITING_FOR_RESTART2)
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return
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# The EVSE modem is present
self.addToTrace("[PEVSLAC] EVSE is up, pairing successful.")
self.nEvseModemMissingCounter=0
self.connMgr.ModemFinderOk(2) # Two modems were found.
# This is the end of the SLAC.
# The AVLN is established, we have at least two modems in the network.
self.enterState(STATE_INITIAL)
return
# invalid state is reached. As robustness measure, go to initial state.
self.enterState(STATE_INITIAL)
def runSdpStateMachine(self):
if (self.connMgr.getConnectionLevel()<15):
# We have no AVLN established and SLAC not ongoing. It does not make sense to start SDP.
self.sdp_state = 0
return
if (self.connMgr.getConnectionLevel()>20):
# SDP was already successful. No need to run it again.
self.sdp_state = 0
return
# The ConnectionLevel demands the SDP.
if (self.sdp_state==0):
# Next step is to discover the chargers communication controller (SECC) using discovery protocol (SDP).
self.publishStatus("SDP ongoing")
self.addToTrace("[SDP] Checkpoint200: Starting SDP.")
self.pevSequenceDelayCycles=0
self.SdpRepetitionCounter = 50 # prepare the number of retries for the SDP. The more the better.
self.sdp_state = 1
return
if (self.sdp_state == 1): # SDP request transmission and waiting for SDP response.
# The normal state transition in case of received SDP response is done in
# the IPv6 receive handler. This will inform the ConnectionManager, and we will stop here
# because of the increased ConnectionLevel.
if (self.pevSequenceDelayCycles>0):
# just waiting until next action
self.pevSequenceDelayCycles-=1
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return
if (self.SdpRepetitionCounter>0):
# Reference: The Ioniq waits 4.1s from the slac_match.cnf to the SDP request.
# Here we send the SdpRequest. Maybe too early, but we will retry if there is no response.
self.ipv6.initiateSdpRequest()
self.SdpRepetitionCounter-=1
self.pevSequenceDelayCycles = 15 # e.g. half-a-second delay until re-try of the SDP
return
# All repetitions are over, no SDP response was seen. Back to the beginning.
self.addToTrace("[SDP] ERROR: Did not receive SDP response. Giving up.")
self.sdp_state = 0
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def findEthernetAdaptor(self):
if (os.name == 'nt'):
# On Windows
# print("Interfaces:\n" + '\n'.join(pcap.findalldevs()))
# For windows, we use a dirty solution here: The pcap uses numbered interfaces like eth0, eth1 etc.,
# but the mapping between these numbers and the physical devices is not stable. To find out the
# correct interface, we search for its name (e.g. '\Device\NPF_{E4B8176C-8516-4D48-88BC-85225ABCF259}' in
# the list of all interfaces.
strWindowsInterfaceName = getConfigValue("eth_windows_interface_name")
print("The configured windows interface name is " + strWindowsInterfaceName)
self.strInterfaceName = "" # default for "not found"
for i in range(0, 10):
strInterfaceName = pcap.ex_name("eth"+str(i))
if (strInterfaceName == strWindowsInterfaceName):
#print("This is the wanted Ethernet adaptor.")
self.strInterfaceName="eth"+str(i)
print("This interface is in pcap " + self.strInterfaceName)
if (self.strInterfaceName == ""):
print("ERROR: No matching interface was found. Make sure that you configured an existing eth_windows_interface_name in pyPlc.ini.")
print("The following interfaces are available:")
# print("Interfaces:\n" + '\n'.join(pcap.findalldevs()))
for i in range(0, 10):
strInterfaceName = pcap.ex_name("eth"+str(i))
print("eth"+ str(i) + " is " + strInterfaceName)
sys.exit()
else:
# On Linux (e.g. Raspberry)
# Take the interface name from the ini file. For Linux, this is all we need.
self.strInterfaceName=getConfigValue("eth_interface")
print("Linux interface is " + self.strInterfaceName)
def sendSpecialMessageToControlThePowerSupply(self, targetVoltage, targetCurrent):
u = int(targetVoltage*10) # resolution: 0.1 volt
i = int(targetCurrent*10) # resolution: 0.1 ampere
self.specialMessageTransmitBuffer[0] = 0xAF # Header 3 byte
self.specialMessageTransmitBuffer[1] = 0xFE #
self.specialMessageTransmitBuffer[2] = 0xDC #
self.specialMessageTransmitBuffer[3] = u >> 8 # target voltage, MSB first
self.specialMessageTransmitBuffer[4] = u & 0xFF # target voltage, LSB
self.specialMessageTransmitBuffer[5] = u >> 8 # same again, for plausibilization
self.specialMessageTransmitBuffer[6] = u & 0xFF
self.specialMessageTransmitBuffer[7] = i >> 8 # target current, MSB first
self.specialMessageTransmitBuffer[8] = i & 0xFF # target current, LSB
self.specialMessageTransmitBuffer[9] = i >> 8 # same again
self.specialMessageTransmitBuffer[10] = i & 0xFF
self.composeSpecialMessage()
self.addToTrace("transmitting SpecialMessage to control the power supply")
self.transmit(self.mytransmitbuffer)
self.callbackShowStatus(str(targetVoltage), "PowerSupplyUTarget")
def enterPevMode(self):
self.iAmEvse = 0 # not emulating a charging station
self.iAmPev = 1 # emulating a vehicle
self.iAmListener = 0 # not a passive listener
self.ipv6.enterPevMode()
self.showStatus("PEV mode", "mode")
def enterEvseMode(self):
self.iAmEvse = 1 # emulating a charging station
self.iAmPev = 0 # not emulating a vehicle
self.iAmListener = 0 # not a passive listener
self.ipv6.enterEvseMode()
self.showStatus("EVSE mode", "mode")
def enterListenMode(self):
self.iAmEvse = 0 # not emulating a charging station
self.iAmPev = 0 # not emulating a vehicle
self.iAmListener = 1 # just listening
self.ipv6.enterListenMode()
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self.showStatus("LISTEN mode", "mode")
def printToUdp(self, s):
udplog.udplog_log(s)
def __init__(self, callbackAddToTrace=None, callbackShowStatus=None, mode=C_LISTEN_MODE, addrMan=None, connMgr=None, isSimulationMode=0):
self.mytransmitbuffer = bytearray("Hallo das ist ein Test", 'UTF-8')
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self.nPacketsReceived = 0
self.callbackAddToTrace = callbackAddToTrace
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self.callbackShowStatus = callbackShowStatus
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self.addressManager = addrMan
self.connMgr = connMgr
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self.randomMac = 0
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self.pevSequenceState = 0
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self.pevSequenceCyclesInState = 0
self.evseSlacHandlerState = 0
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self.numberOfSoftwareVersionResponses = 0
self.numberOfFoundModems = 0
self.mofi_state = 0
self.mofi_stateDelay = 0
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self.isSimulationMode = isSimulationMode # simulation without homeplug modem
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#self.sniffer = pcap.pcap(name=None, promisc=True, immediate=True, timeout_ms=50)
# eth3 means: Third entry from back, in the list of interfaces, which is provided by pcap.findalldevs.
# Improvement necessary: select the interface based on the name.
# For debugging of the interface names, we can patch the file
# C:\Users\uwemi\AppData\Local\Packages\PythonSoftwareFoundation.Python.3.10_qbz5n2kfra8p0\LocalCache\local-packages\Python310\site-packages\pcap\_pcap_ex.py,
# in the function
# def name(name: bytes) -> bytes:
# in the place after
# if i == idx:
# print("index match at " + str(i) + " dev name=" + str(dev.name) + " dev.description=" + str(dev.description))
# This will print the description of the used interface.
#
# Patch for non-blocking read-iteration:
# in _pcap.py, function def __next__(self), in the case of timeout (if n==0), we need to "raise StopIteration" instead of "continue".
#
self.findEthernetAdaptor()
self.sniffer = pcap.pcap(name=self.strInterfaceName, promisc=True, immediate=True, timeout_ms=50)
self.sniffer.setnonblock(True)
self.NMKdevelopment = [ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 ] # network key for development access
self.NMK = [ 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 ] # a default network key. Will be overwritten later.
self.NMK_EVSE_random = [ 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77, 0x77 ] # In EvseMode, we use this key.
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self.NID = [ 1, 2, 3, 4, 5, 6, 7 ] # a default network ID
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self.pevMac = [0xDC, 0x0E, 0xA1, 0x11, 0x67, 0x08 ] # a default pev MAC. Will be overwritten later.
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self.evseMac = [0x55, 0x56, 0x57, 0xAA, 0xAA, 0xAA ] # a default evse MAC. Will be overwritten later.
# a default pev RunId. Will be overwritten later, if we are evse. If we are the pev, we are free to choose a
# RunID, e.g. the Ioniq uses the MAC plus 0x00 0x00 padding, the Tesla uses "TESLA EV".
self.pevRunId = [0xDC, 0x0E, 0xA1, 0xDE, 0xAD, 0xBE, 0xEF, 0x55 ]
self.specialMessageTransmitBuffer = bytearray(58)
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self.myMAC = self.addressManager.getLocalMacAddress()
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self.runningCounter=0
self.ipv6 = pyPlcIpv6.ipv6handler(self.transmit, self.addressManager, self.connMgr, self.callbackShowStatus)
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self.ipv6.ownMac = self.myMAC
udplog.udplog_init(self.transmit, self.addressManager)
udplog.udplog_log("Test message to verify the syslog. pyPlcHomeplug.py is in the init function.", "initalive")
if (mode == C_LISTEN_MODE):
self.enterListenMode()
if (mode == C_EVSE_MODE):
self.enterEvseMode()
if (mode == C_PEV_MODE):
self.enterPevMode()
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self.pevMac = self.myMAC
self.showStatus(prettyMac(self.pevMac), "pevmac")
print("sniffer created at " + self.strInterfaceName) # we use print, because addToLog does not yet work at this stage in the init.
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def addToTrace(self, s):
self.callbackAddToTrace(s)
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def showStatus(self, s, selection=""):
self.callbackShowStatus(s, selection)
def receiveCallback(self, timestamp, pkt, *args):
self.nPacketsReceived+=1
# print('%d' % (ts)) # the time stamp
# We received an ethernet package. Determine its type, and dispatch it to the related handler.
etherType = self.getEtherType(pkt)
if (etherType == 0x88E1): # it is a HomePlug message
self.myreceivebuffer = pkt
self.evaluateReceivedHomeplugPacket()
if (etherType == 0x86dd): # it is an IPv6 frame
self.ipv6.evaluateReceivedPacket(pkt)
if (etherType == 0x0800): # it is an IPv4 frame
testsuite_evaluateIpv4Packet(pkt)
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def mainfunction(self):
# https://stackoverflow.com/questions/31305712/how-do-i-make-libpcap-pcap-loop-non-blocking
# Tell the sniffer to give max 100 received packets to the callback function:
self.sniffer.dispatch(100, self.receiveCallback, None)
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self.showStatus("nPacketsReceived=" + str(self.nPacketsReceived))
if (self.iAmPev==1):
self.modemFinder_Mainfunction() # run the modem finder cyclic function
self.runPevSequencer() # run the SLAC message sequencer for the PEV side
self.runSdpStateMachine() # run the SDP state machine
if (self.iAmEvse==1):
self.runEvseSlacHandler(); # run the SLAC state machine on EVSE side
def close(self):
self.sniffer.close()