# # MarlinBinaryProtocol.py # Supporting Firmware upload via USB/Serial, saving to the attached media. # import serial import math import time from collections import deque import threading import sys import datetime import random try: import heatshrink2 as heatshrink heatshrink_exists = True except ImportError: try: import heatshrink heatshrink_exists = True except ImportError: heatshrink_exists = False def millis(): return time.perf_counter() * 1000 class TimeOut(object): def __init__(self, milliseconds): self.duration = milliseconds self.reset() def reset(self): self.endtime = millis() + self.duration def timedout(self): return millis() > self.endtime class ReadTimeout(Exception): pass class FatalError(Exception): pass class SycronisationError(Exception): pass class PayloadOverflow(Exception): pass class ConnectionLost(Exception): pass class Protocol(object): device = None baud = None max_block_size = 0 port = None block_size = 0 packet_transit = None packet_status = None packet_ping = None errors = 0 packet_buffer = None simulate_errors = 0 sync = 0 connected = False syncronised = False worker_thread = None response_timeout = 1000 applications = [] responses = deque() def __init__(self, device, baud, bsize, simerr, timeout): print("pySerial Version:", serial.VERSION) self.port = serial.Serial(device, baudrate = baud, write_timeout = 0, timeout = 1) self.device = device self.baud = baud self.block_size = int(bsize) self.simulate_errors = max(min(simerr, 1.0), 0.0); self.connected = True self.response_timeout = timeout self.register(['ok', 'rs', 'ss', 'fe'], self.process_input) self.worker_thread = threading.Thread(target=Protocol.receive_worker, args=(self,)) self.worker_thread.start() def receive_worker(self): while self.port.in_waiting: self.port.reset_input_buffer() def dispatch(data): for tokens, callback in self.applications: for token in tokens: if token == data[:len(token)]: callback((token, data[len(token):])) return def reconnect(): print("Reconnecting..") self.port.close() for x in range(10): try: if self.connected: self.port = serial.Serial(self.device, baudrate = self.baud, write_timeout = 0, timeout = 1) return else: print("Connection closed") return except: time.sleep(1) raise ConnectionLost() while self.connected: try: data = self.port.readline().decode('utf8').rstrip() if len(data): #print(data) dispatch(data) except OSError: reconnect() except UnicodeDecodeError: # dodgy client output or datastream corruption self.port.reset_input_buffer() def shutdown(self): self.connected = False self.worker_thread.join() self.port.close() def process_input(self, data): #print(data) self.responses.append(data) def register(self, tokens, callback): self.applications.append((tokens, callback)) def send(self, protocol, packet_type, data = bytearray()): self.packet_transit = self.build_packet(protocol, packet_type, data) self.packet_status = 0 self.transmit_attempt = 0 timeout = TimeOut(self.response_timeout * 20) while self.packet_status == 0: try: if timeout.timedout(): raise ConnectionLost() self.transmit_packet(self.packet_transit) self.await_response() except ReadTimeout: self.errors += 1 #print("Packetloss detected..") self.packet_transit = None def await_response(self): timeout = TimeOut(self.response_timeout) while not len(self.responses): time.sleep(0.00001) if timeout.timedout(): raise ReadTimeout() while len(self.responses): token, data = self.responses.popleft() switch = {'ok' : self.response_ok, 'rs': self.response_resend, 'ss' : self.response_stream_sync, 'fe' : self.response_fatal_error} switch[token](data) def send_ascii(self, data, send_and_forget = False): self.packet_transit = bytearray(data, "utf8") + b'\n' self.packet_status = 0 self.transmit_attempt = 0 timeout = TimeOut(self.response_timeout * 20) while self.packet_status == 0: try: if timeout.timedout(): return self.port.write(self.packet_transit) if send_and_forget: self.packet_status = 1 else: self.await_response_ascii() except ReadTimeout: self.errors += 1 #print("Packetloss detected..") except serial.serialutil.SerialException: return self.packet_transit = None def await_response_ascii(self): timeout = TimeOut(self.response_timeout) while not len(self.responses): time.sleep(0.00001) if timeout.timedout(): raise ReadTimeout() token, data = self.responses.popleft() self.packet_status = 1 def corrupt_array(self, data): rid = random.randint(0, len(data) - 1) data[rid] ^= 0xAA return data def transmit_packet(self, packet): packet = bytearray(packet) if(self.simulate_errors > 0 and random.random() > (1.0 - self.simulate_errors)): if random.random() > 0.9: #random data drop start = random.randint(0, len(packet)) end = start + random.randint(1, 10) packet = packet[:start] + packet[end:] #print("Dropping {0} bytes".format(end - start)) else: #random corruption packet = self.corrupt_array(packet) #print("Single byte corruption") self.port.write(packet) self.transmit_attempt += 1 def build_packet(self, protocol, packet_type, data = bytearray()): PACKET_TOKEN = 0xB5AD if len(data) > self.max_block_size: raise PayloadOverflow() packet_buffer = bytearray() packet_buffer += self.pack_int8(self.sync) # 8bit sync id packet_buffer += self.pack_int4_2(protocol, packet_type) # 4 bit protocol id, 4 bit packet type packet_buffer += self.pack_int16(len(data)) # 16bit packet length packet_buffer += self.pack_int16(self.build_checksum(packet_buffer)) # 16bit header checksum if len(data): packet_buffer += data packet_buffer += self.pack_int16(self.build_checksum(packet_buffer)) packet_buffer = self.pack_int16(PACKET_TOKEN) + packet_buffer # 16bit start token, not included in checksum return packet_buffer # checksum 16 fletchers def checksum(self, cs, value): cs_low = (((cs & 0xFF) + value) % 255); return ((((cs >> 8) + cs_low) % 255) << 8) | cs_low; def build_checksum(self, buffer): cs = 0 for b in buffer: cs = self.checksum(cs, b) return cs def pack_int32(self, value): return value.to_bytes(4, byteorder='little') def pack_int16(self, value): return value.to_bytes(2, byteorder='little') def pack_int8(self, value): return value.to_bytes(1, byteorder='little') def pack_int4_2(self, vh, vl): value = ((vh & 0xF) << 4) | (vl & 0xF) return value.to_bytes(1, byteorder='little') def connect(self): print("Connecting: Switching Marlin to Binary Protocol...") self.send_ascii("M28B1") self.send(0, 1) def disconnect(self): self.send(0, 2) self.syncronised = False def response_ok(self, data): try: packet_id = int(data); except ValueError: return if packet_id != self.sync: raise SycronisationError() self.sync = (self.sync + 1) % 256 self.packet_status = 1 def response_resend(self, data): packet_id = int(data); self.errors += 1 if not self.syncronised: print("Retrying syncronisation") elif packet_id != self.sync: raise SycronisationError() def response_stream_sync(self, data): sync, max_block_size, protocol_version = data.split(',') self.sync = int(sync) self.max_block_size = int(max_block_size) self.block_size = self.max_block_size if self.max_block_size < self.block_size else self.block_size self.protocol_version = protocol_version self.packet_status = 1 self.syncronised = True print("Connection synced [{0}], binary protocol version {1}, {2} byte payload buffer".format(self.sync, self.protocol_version, self.max_block_size)) def response_fatal_error(self, data): raise FatalError() class FileTransferProtocol(object): protocol_id = 1 class Packet(object): QUERY = 0 OPEN = 1 CLOSE = 2 WRITE = 3 ABORT = 4 responses = deque() def __init__(self, protocol, timeout = None): protocol.register(['PFT:success', 'PFT:version:', 'PFT:fail', 'PFT:busy', 'PFT:ioerror', 'PTF:invalid'], self.process_input) self.protocol = protocol self.response_timeout = timeout or protocol.response_timeout def process_input(self, data): #print(data) self.responses.append(data) def await_response(self, timeout = None): timeout = TimeOut(timeout or self.response_timeout) while not len(self.responses): time.sleep(0.0001) if timeout.timedout(): raise ReadTimeout() return self.responses.popleft() def connect(self): self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.QUERY); token, data = self.await_response() if token != 'PFT:version:': return False self.version, _, compression = data.split(':') if compression != 'none': algorithm, window, lookahead = compression.split(',') self.compression = {'algorithm': algorithm, 'window': int(window), 'lookahead': int(lookahead)} else: self.compression = {'algorithm': 'none'} print("File Transfer version: {0}, compression: {1}".format(self.version, self.compression['algorithm'])) def open(self, filename, compression, dummy): payload = b'\1' if dummy else b'\0' # dummy transfer payload += b'\1' if compression else b'\0' # payload compression payload += bytearray(filename, 'utf8') + b'\0'# target filename + null terminator timeout = TimeOut(5000) token = None self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.OPEN, payload); while token != 'PFT:success' and not timeout.timedout(): try: token, data = self.await_response(1000) if token == 'PFT:success': print(filename,"opened") return elif token == 'PFT:busy': print("Broken transfer detected, purging") self.abort() time.sleep(0.1) self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.OPEN, payload); timeout.reset() elif token == 'PFT:fail': raise Exception("Can not open file on client") except ReadTimeout: pass raise ReadTimeout() def write(self, data): self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.WRITE, data); def close(self): self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.CLOSE); token, data = self.await_response(1000) if token == 'PFT:success': print("File closed") return True elif token == 'PFT:ioerror': print("Client storage device IO error") return False elif token == 'PFT:invalid': print("No open file") return False def abort(self): self.protocol.send(FileTransferProtocol.protocol_id, FileTransferProtocol.Packet.ABORT); token, data = self.await_response() if token == 'PFT:success': print("Transfer Aborted") def copy(self, filename, dest_filename, compression, dummy): self.connect() has_heatshrink = heatshrink_exists and self.compression['algorithm'] == 'heatshrink' if compression and not has_heatshrink: hs = '2' if sys.version_info[0] > 2 else '' print("Compression not supported by client. Use 'pip install heatshrink%s' to fix." % hs) compression = False data = open(filename, "rb").read() filesize = len(data) self.open(dest_filename, compression, dummy) block_size = self.protocol.block_size if compression: data = heatshrink.encode(data, window_sz2=self.compression['window'], lookahead_sz2=self.compression['lookahead']) cratio = filesize / len(data) blocks = math.floor((len(data) + block_size - 1) / block_size) kibs = 0 dump_pctg = 0 start_time = millis() for i in range(blocks): start = block_size * i end = start + block_size self.write(data[start:end]) kibs = (( (i+1) * block_size) / 1024) / (millis() + 1 - start_time) * 1000 if (i / blocks) >= dump_pctg: print("\r{0:2.0f}% {1:4.2f}KiB/s {2} Errors: {3}".format((i / blocks) * 100, kibs, "[{0:4.2f}KiB/s]".format(kibs * cratio) if compression else "", self.protocol.errors), end='') dump_pctg += 0.1 if self.protocol.errors > 0: # Dump last status (errors may not be visible) print("\r{0:2.0f}% {1:4.2f}KiB/s {2} Errors: {3} - Aborting...".format((i / blocks) * 100, kibs, "[{0:4.2f}KiB/s]".format(kibs * cratio) if compression else "", self.protocol.errors), end='') print("") # New line to break the transfer speed line self.close() print("Transfer aborted due to protocol errors") #raise Exception("Transfer aborted due to protocol errors") return False; print("\r{0:2.0f}% {1:4.2f}KiB/s {2} Errors: {3}".format(100, kibs, "[{0:4.2f}KiB/s]".format(kibs * cratio) if compression else "", self.protocol.errors)) # no one likes transfers finishing at 99.8% if not self.close(): print("Transfer failed") return False print("Transfer complete") return True class EchoProtocol(object): def __init__(self, protocol): protocol.register(['echo:'], self.process_input) self.protocol = protocol def process_input(self, data): print(data)