# encoder.py 27/03/2016 D.J.Whale
#
# payload encoder for use with OOK payloads
ALL_SOCKETS = 0
def build_relay_msg(relayState=False):
"""Temporary test code to prove we can turn the relay on or off"""
# This generates a 20*4 bit address i.e. 10 bytes
# The number generated is always the same
# Presumably this is the random 'Energenie address prefix'
# The switch number is encoded in the payload
# Looks like: 0000 00BA gets encoded as:
# 128 64 32 16 8 4 2 1
# 1 B B 0 1 A A 0
#payload = []
#for i in range(10):
# j = i + 5
# payload.append(8 + (j&1) * 6 + 128 + (j&2) * 48)
#dumpPayloadAsHex(payload)
#
# 5 6 7 8 9 10 11 12 13 14
# 1(01) 1(10) 1(11) 0(00) 0(01) 0(10) 0(11) 1(00) 1(01) 1(10)
payload = [0x8e, 0xe8, 0xee, 0x88, 0x8e, 0xe8, 0xee, 0x88, 0x8e, 0xe8]
#TODO: This is taken from the C code, it might be wrong
#(the D bit order seems reversed compared to the pdf spec)
if relayState: # ON
# D0=high, D1=high, D2-high, D3=high (S1 on)
# 128 64 32 16 8 4 2 1 128 64 32 16 8 4 2 1
# 1 B B 0 1 A A 0 1 B B 0 1 A A 0
# 1 1 1 0 1 1 1 0 1 1 1 0 1 1 1 0
payload += [0xEE, 0xEE] # 1111
else: # OFF
# D0=high, D1=high, D2=high, D3=low (S1 off)
# 128 64 32 16 8 4 2 1 128 64 32 16 8 4 2 1
# 1 B B 0 1 A A 0 1 B B 0 1 A A 0
# 1 1 1 0 1 1 1 0 1 1 1 0 1 0 0 0
payload += [0xEE, 0xE8] # 1110
return payload
def build_switch_msg(state, device_address=ALL_SOCKETS, house_address=None):
"""Build a message to turn a switch on or off"""
#print("build: state:%s, device:%d, house:%s" % (str(state), device_address, str(house_address)))
if house_address == None:
#this is just a fixed address generator, from the C code
#payload = []
#for i in range(10):
# j = i + 5
# payload.append(8 + (j&1) * 6 + 128 + (j&2) * 48)
#dumpPayloadAsHex(payload)
# binary = 0110 1100 0110 1100 0110
# hex = 6 C 6 C 6
house_address = 0x6C6C6
payload = encode_bits((house_address & 0x0F0000) >> 16, 4)
payload += encode_bits((house_address & 0x00FF00) >> 8, 8)
payload += encode_bits((house_address & 0x0000FF), 8)
#TODO: D3210 are the other way round in the message??
#This is correct as presented by the PDF from Energenie though.
# Turn switch request into a 4 bit switch command, and add to payload
# D 3210
# 0000 UNUSED
# 0001 UNUSED
# 0010 UNUSED
# 0011 All off (3)
# 0100 socket 4 off (4)
# 0101 socket 3 off (5)
# 0110 socket 2 off (6)
# 0111 socket 1 off (7)
# 1000 UNUSED
# 1101 UNUSED
# 1110 UNUSED
# 1011 All on (3)
# 1100 socket 4 on (4)
# 1101 socket 3 on (5)
# 1110 socket 2 on (6)
# 1111 socket 1 on (7)
if not state: # OFF
bits = 0x00
else: # ON
bits = 0x08
if device_address == ALL_SOCKETS:
bits |= 0x03 # ALL
else:
bits += 7-((device_address-1) & 0x03)
payload += encode_bits(bits, 4)
return payload
def encode_bytes(data):
"""Turn a list of bytes into a modulated pattern equivalent"""
#print("modulate_bytes: %s" % ashex(data))
payload = []
for b in data:
payload += encode_bits(b, 8)
#print(" returns: %s" % ashex(payload))
return payload
ENCODER = [0x88, 0x8E, 0xE8, 0xEE]
def encode_bits(data, number):
"""Turn bits into n bytes of modulation patterns"""
# 0000 00BA gets encoded as:
# 128 64 32 16 8 4 2 1
# 1 B B 0 1 A A 0
# i.e. a 0 is a short pulse, a 1 is a long pulse
#print("modulate_bits %s (%s)" % (ashex(data), str(number)))
shift = number-2
encoded = []
for i in range(number/2):
bits = (data >> shift) & 0x03
#print(" shift %d bits %d" % (shift, bits))
encoded.append(ENCODER[bits])
shift -= 2
#print(" returns:%s" % ashex(modulated))
return encoded
# END
David Whale