seMsg.py

# SolarEdge message protocol

import struct
import time
from seConf import *
from Crypto.Cipher import AES

class SEDecrypt:
    def __init__(self, key, msg0503):
        """
        Initialise a SolarEdge communication decryption object.

        key:     a 16-byte string which consists of the values of
                 parameters 0239, 023a, 023b, and 023c.
        msg0503: a 34-byte string with the contents of a 0503 message.
        """
        enkey1 = map(ord, AES.new(key).encrypt(msg0503[0:16]))
        self.cipher = AES.new("".join(map(chr,
            (enkey1[i] ^ ord(msg0503[i+16]) for i in range(16)))))

    def decrypt(self, msg003d):
        """
        msg003d: the contents of the 003d message to decrypt.

        Returns a tuple(int(sequenceNumber), str(data)).
        """
        rand1 = map(ord, msg003d[0:16])
        rand = map(ord, self.cipher.encrypt(msg003d[0:16]))
        msg003d = map(ord, msg003d)
        posa = 0
        posb = 16
        while posb < len(msg003d):
            msg003d[posb] ^= rand[posa]
            posb += 1
            posa += 1
            if posa == 16:
                posa = 0
                for posc in range(15, -1, -1):
                    rand1[posc] = (rand1[posc] + 1) & 0x0FF
                    if rand1[posc]:
                        break
                rand = map(ord, self.cipher.encrypt("".join(map(chr, rand1))))
        return (msg003d[16] + (msg003d[17] << 8),
                "".join(map(chr, (msg003d[i+22] ^ msg003d[18+(i&3)]
                    for i in range(len(msg003d)-22)))))

# decryption object
decrypt = None

# message constants
magic = "\x12\x34\x56\x79"
magicLen = len(magic)
msgHdrLen = 16
checksumLen = 2

# message debugging sequence numbers
dataInSeq = 0
dataOutSeq = 0
recSeq = 0

# return the next message
def readMsg(inFile, recFile):
    global dataInSeq, recSeq
    dataInSeq += 1
    msg = ""
    if not passiveMode:
        # read the magic number and header
        msg = readBytes(inFile, magicLen+msgHdrLen)
        if msg == "":
            debug("debugFiles", "end of file")
            return msg
        (dataLen, dataLenInv, msgSeq, fromAddr, toAddr, function) = struct.unpack("<HHHLLH", msg[magicLen:])
        # read the data and checksum
        msg += readBytes(inFile, dataLen+checksumLen)
        msg = msg[magicLen:]
    else:
        # read 1 byte at a time until the next magic number
        while msg[-magicLen:] != magic:
            nextByte = readBytes(inFile, 1)
            if nextByte == "":  # end of file
                msg += magic    # pretend there was a magic number
            else:
                msg += nextByte
        msg = msg[:-magicLen]   # drop the magic from the end
    if len(msg) > 0:    # don't log zero length messages
        logMsg("-->", dataInSeq, magic+msg, inFile.name)
    if recFile:
        recSeq += 1
        logMsg("<--", recSeq, magic+msg, recFile.name)
        recFile.write(magic+msg)
        recFile.flush()
    return msg

# return the specified number of bytes
def readBytes(inFile, length):
    try:
        inBuf = inFile.read(length)
        if inBuf == "": # end of file
            if following:
                # wait for more data
                while inBuf == "":
                    time.sleep(sleepInterval)
                    inBuf = inFile.read(length)
        return inBuf
    # treat exceptions as end of file
    except Exception as ex:
        debug("debugEnable", "Exception:", ex.args[0])
        return ""

# parse a message            
def parseMsg(msg):
    global decrypt
    if len(msg) < msgHdrLen + checksumLen:   # throw out messages that are too short
        return (0, 0, 0, 0, "")
    else:
        (msgSeq, fromAddr, toAddr, function, data) = validateMsg(msg)
        # encryption key
        if function == 0x0503:
            if keyStr != "":
                debug("debugData", "creating decryption object with key", keyStr)
                decrypt = SEDecrypt(keyStr.decode("hex"), data)
            return (0, 0, 0, 0, "")
        # encrypted message
        elif function == 0x003d:
            if decrypt:
                # decrypt the data and validate that as a message
                debug("debugData", "decrypting message")
                (seq, dataMsg) = decrypt.decrypt(data)
                (msgSeq, fromAddr, toAddr, function, data) = validateMsg(dataMsg[4:])
            else:   # don't have a key yet
                return (0, 0, 0, 0, "")
        return (msgSeq, fromAddr, toAddr, function, data)

# parse the header and validate the message
def validateMsg(msg):
    # parse the message header
    (dataLen, dataLenInv, msgSeq, fromAddr, toAddr, function) = struct.unpack("<HHHLLH", msg[0:msgHdrLen])
    logMsgHdr(dataLen, dataLenInv, msgSeq, fromAddr, toAddr, function)
    data = msg[msgHdrLen:msgHdrLen+dataLen]
    extraLen = len(msg) - (msgHdrLen + dataLen + checksumLen)
    if extraLen != 0:
        debug("debugData", "Discarding", extraLen, "bytes")
        logData(msg[-extraLen:])
    # validate the message
    checksum = struct.unpack("<H", msg[msgHdrLen+dataLen:msgHdrLen+dataLen+checksumLen])[0]
    calcsum = calcCrc(struct.pack(">HLLH", msgSeq, fromAddr, toAddr, function)+data)
    if calcsum != checksum:
        log("Checksum error. Expected 0x%04x, got 0x%04x" % (checksum, calcsum))
        logData(msg)
        return (0, 0, 0, 0, "")
    if dataLen != ~dataLenInv & 0xffff:
        log("Length error")
        logData(msg)
        return (0, 0, 0, 0, "")
    return (msgSeq, fromAddr, toAddr, function, data)

# format a message
def formatMsg(msgSeq, fromAddr, toAddr, function, data=""):
    checksum = calcCrc(struct.pack(">HLLH", msgSeq, fromAddr, toAddr, function) + data)
    msg = struct.pack("<HHHLLH", len(data), ~len(data) & 0xffff, msgSeq, fromAddr, toAddr, function) + data + struct.pack("<H", checksum)
    logMsgHdr(len(data), ~len(data) & 0xffff, msgSeq, fromAddr, toAddr, function)
    return msg

# send a message
def sendMsg(dataFile, msg, recFile):
    global dataOutSeq, recSeq
    dataOutSeq += 1
    logMsg("<--", dataOutSeq, magic+msg, dataFile.name)
    dataFile.write(magic+msg)
    dataFile.flush()
    if recFile:
        recSeq += 1
        logMsg("<--", recSeq, magic+msg, recFile.name)
        recFile.write(magic+msg)
        recFile.flush()

# crc calculation
#
# CRC-16 with the following parameters:
#
# width=16 poly=0x8005 init=0x5a5a refin=true refout=true xorout=0x0000

crcTable = [
0x0000,  0xc0c1,  0xc181,  0x0140,  0xc301,  0x03c0,  0x0280,  0xc241, 
0xc601,  0x06c0,  0x0780,  0xc741,  0x0500,  0xc5c1,  0xc481,  0x0440, 
0xcc01,  0x0cc0,  0x0d80,  0xcd41,  0x0f00,  0xcfc1,  0xce81,  0x0e40, 
0x0a00,  0xcac1,  0xcb81,  0x0b40,  0xc901,  0x09c0,  0x0880,  0xc841, 
0xd801,  0x18c0,  0x1980,  0xd941,  0x1b00,  0xdbc1,  0xda81,  0x1a40, 
0x1e00,  0xdec1,  0xdf81,  0x1f40,  0xdd01,  0x1dc0,  0x1c80,  0xdc41, 
0x1400,  0xd4c1,  0xd581,  0x1540,  0xd701,  0x17c0,  0x1680,  0xd641, 
0xd201,  0x12c0,  0x1380,  0xd341,  0x1100,  0xd1c1,  0xd081,  0x1040, 
0xf001,  0x30c0,  0x3180,  0xf141,  0x3300,  0xf3c1,  0xf281,  0x3240, 
0x3600,  0xf6c1,  0xf781,  0x3740,  0xf501,  0x35c0,  0x3480,  0xf441, 
0x3c00,  0xfcc1,  0xfd81,  0x3d40,  0xff01,  0x3fc0,  0x3e80,  0xfe41, 
0xfa01,  0x3ac0,  0x3b80,  0xfb41,  0x3900,  0xf9c1,  0xf881,  0x3840, 
0x2800,  0xe8c1,  0xe981,  0x2940,  0xeb01,  0x2bc0,  0x2a80,  0xea41, 
0xee01,  0x2ec0,  0x2f80,  0xef41,  0x2d00,  0xedc1,  0xec81,  0x2c40, 
0xe401,  0x24c0,  0x2580,  0xe541,  0x2700,  0xe7c1,  0xe681,  0x2640, 
0x2200,  0xe2c1,  0xe381,  0x2340,  0xe101,  0x21c0,  0x2080,  0xe041, 
0xa001,  0x60c0,  0x6180,  0xa141,  0x6300,  0xa3c1,  0xa281,  0x6240, 
0x6600,  0xa6c1,  0xa781,  0x6740,  0xa501,  0x65c0,  0x6480,  0xa441, 
0x6c00,  0xacc1,  0xad81,  0x6d40,  0xaf01,  0x6fc0,  0x6e80,  0xae41, 
0xaa01,  0x6ac0,  0x6b80,  0xab41,  0x6900,  0xa9c1,  0xa881,  0x6840, 
0x7800,  0xb8c1,  0xb981,  0x7940,  0xbb01,  0x7bc0,  0x7a80,  0xba41, 
0xbe01,  0x7ec0,  0x7f80,  0xbf41,  0x7d00,  0xbdc1,  0xbc81,  0x7c40, 
0xb401,  0x74c0,  0x7580,  0xb541,  0x7700,  0xb7c1,  0xb681,  0x7640, 
0x7200,  0xb2c1,  0xb381,  0x7340,  0xb101,  0x71c0,  0x7080,  0xb041, 
0x5000,  0x90c1,  0x9181,  0x5140,  0x9301,  0x53c0,  0x5280,  0x9241, 
0x9601,  0x56c0,  0x5780,  0x9741,  0x5500,  0x95c1,  0x9481,  0x5440, 
0x9c01,  0x5cc0,  0x5d80,  0x9d41,  0x5f00,  0x9fc1,  0x9e81,  0x5e40, 
0x5a00,  0x9ac1,  0x9b81,  0x5b40,  0x9901,  0x59c0,  0x5880,  0x9841, 
0x8801,  0x48c0,  0x4980,  0x8941,  0x4b00,  0x8bc1,  0x8a81,  0x4a40, 
0x4e00,  0x8ec1,  0x8f81,  0x4f40,  0x8d01,  0x4dc0,  0x4c80,  0x8c41, 
0x4400,  0x84c1,  0x8581,  0x4540,  0x8701,  0x47c0,  0x4680,  0x8641, 
0x8201,  0x42c0,  0x4380,  0x8341,  0x4100,  0x81c1,  0x8081,  0x4040]

def calcCrc(data):
    crc = 0x5a5a    # initial value
    for d in data:
         crc = crcTable[(crc ^ ord(d)) & 0xff] ^ (crc >> 8)
    return crc

# formatted print a message header
def logMsgHdr(dataLen, dataLenInv, msgSeq, fromAddr, toAddr, function):
    debug("debugData", "dataLen:   ", "%04x" % dataLen)
    debug("debugData", "dataLenInv:", "%04x" % dataLenInv)
    debug("debugData", "sequence:  ", "%04x" % msgSeq)
    debug("debugData", "source:    ", "%08x" % fromAddr)
    debug("debugData", "dest:      ", "%08x" % toAddr)
    debug("debugData", "function:  ", "%04x" % function)