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Testing: More features, but probably not going to finish

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Admin
2025-05-13 15:51:24 +02:00
parent 986d887587
commit 1fe48f2494
3 changed files with 92 additions and 23 deletions
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1
biogascontrollerapp/lib/decoder.py
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@@ -14,4 +14,5 @@ class Decoder:
return struct.unpack('>f', bytes.fromhex(str(value, 'ascii') + '0000'))[0] return struct.unpack('>f', bytes.fromhex(str(value, 'ascii') + '0000'))[0]
def decode_int(self, value: bytes) -> int: def decode_int(self, value: bytes) -> int:
# return int.from_bytes(value, 'big')
return int(value, base=16) return int(value, base=16)

40
biogascontrollerapp/lib/instructions.py
View File

@@ -26,10 +26,7 @@ class Instructions:
return False return False
# Send instruction to microcontroller to start hooking process # Send instruction to microcontroller to start hooking process
# If instruction is an empty string, do not send instruction self._com.send(instruction)
if instruction != "":
self._com.send(instruction)
# Record start time to respond to timeout # Record start time to respond to timeout
start = time.time() start = time.time()
@@ -44,7 +41,7 @@ class Instructions:
while time.time() - start < 5: while time.time() - start < 5:
# If the decoded ascii character is equal to the next expected character, move pointer right by one # If the decoded ascii character is equal to the next expected character, move pointer right by one
# If not, jump back to start # If not, jump back to start
if (decoder.decode_ascii(self._com.receive(1))) == sequence[pointer]: if decoder.decode_ascii(self._com.receive(1)) == sequence[pointer]:
pointer += 1 pointer += 1
else: else:
pointer = 0 pointer = 0
@@ -56,6 +53,39 @@ class Instructions:
# If we time out, which is the only way in which this code can be reached, return False # If we time out, which is the only way in which this code can be reached, return False
return False return False
# Used to hook to the main data stream, as that hooking mechanism is differen
def hook_main(self) -> bool:
# Record start time to respond to timeout
start = time.time()
# Wait to find a CR character (enter)
char = decoder.decode_ascii(self._com.receive(1))
while char != "\n":
if time.time() - start > 3:
return False
char = decoder.decode_ascii(self._com.receive(1))
# Store the position in the hooking process
state = 0
distance = 0
while time.time() - start < 5 and state < 3:
char = decoder.decode_ascii(self._com.receive(1))
if char == " ":
if distance == 4:
state += 1
distance = 0
else:
if distance > 4:
state = 0
distance = 0
else:
distance += 1
self._com.receive(5)
return state == 3
# Private helper method to transmit data using the necessary protocols # Private helper method to transmit data using the necessary protocols
def _change_data( def _change_data(
self, self,

74
biogascontrollerapp/lib/test/com.py
View File

@@ -8,6 +8,7 @@ import queue
import random import random
import serial import serial
import time import time
import struct
from lib.com import ComSuperClass from lib.com import ComSuperClass
@@ -32,18 +33,17 @@ class SimulationError(Exception):
class Com(ComSuperClass): class Com(ComSuperClass):
def __init__(self, baudrate: int = 19200, filters: Optional[list[str]] = None) -> None: def __init__(
self, baudrate: int = 19200, filters: Optional[list[str]] = None
) -> None:
# Calling the constructor of the super class to assign defaults # Calling the constructor of the super class to assign defaults
print("\n\nWARNING: Using testing library for communication!\n\n") print("\n\nWARNING: Using testing library for communication!\n\n")
super().__init__(baudrate, filters); super().__init__(baudrate, filters)
# Initialize queue with values to be sent on call of recieve # Initialize queue with values to be sent on call of recieve
self.__simulated_data: queue.Queue[int] = queue.Queue() self.__simulated_data: queue.Queue[bytes] = queue.Queue()
self.__simulated_data_remaining = 0 self.__simulated_data_remaining = 0
# Keep track of the number of bytes sent to fulfil protocol
self.__bytes_sent: int = 0
# Initially, we are in normal mode (which leads to slower data intervals) # Initially, we are in normal mode (which leads to slower data intervals)
self.__mode = "NM" self.__mode = "NM"
@@ -68,35 +68,73 @@ class Com(ComSuperClass):
pass pass
def receive(self, byte_count: int) -> bytes: def receive(self, byte_count: int) -> bytes:
# TODO: Make it return simulated data -> Refill if queue length is smaller than requested byte_count
data = [] data = []
# If queue is too short, refill it # If queue is too short, refill it
if self.__simulated_data_remaining < byte_count: if self.__simulated_data_remaining < byte_count:
self.__fill_queue() self.__fill_queue()
for i in range(byte_count): for _ in range(byte_count):
if self.__mode == "NM": if self.__mode == "NM":
time.sleep( 0.001 ); time.sleep(0.001)
try: try:
data.append(self.__simulated_data.get_nowait()) data.append(self.__simulated_data.get_nowait())
self.__simulated_data_remaining -= 1
except Exception as e: except Exception as e:
print("ERROR: Simulation could not continue") print("ERROR: Simulation could not continue")
raise SimulationError("Simulation encountered an error with the simulation queue. The error encountered: \n" + str(e)) raise SimulationError(
return bytes(data) "Simulation encountered an error with the simulation queue. The error encountered: \n"
+ str(e)
)
return b''.join(data)
def send(self, msg: str) -> None: def send(self, msg: str) -> None:
# TODO: Use LUT to find what should be added to the queue for read
# Using LUT to reference # Using LUT to reference
readback = instruction_lut.get(msg) readback = instruction_lut.get(msg)
if readback != None: if readback != None:
for i in range(len(readback)): for i in range(len(readback)):
self.__simulated_data.put(ord(readback[i])) self.__simulated_data.put(bytes(readback[i], "ascii"))
if msg == "RD":
# Handle ReadData readback
# self.__simulated_data.put(ord(""))
pass
def send_float(self, msg: float) -> None: def send_float(self, msg: float) -> None:
pass # Encode float as 8 bytes (64 bit)
ba = struct.pack("d", msg)
def __add_random_float(self): for byte in ba:
pass self.__simulated_data.put(byte.to_bytes())
def __fill_queue(self): def __fill_queue(self):
pass # Add some dummy data. The data is randomized and is *not*
# an accurate simulation of what the microcontroller will return
# It only serves to check if the protocol handling works as expected
for _ in range(4):
self.__add_to_queue(self.__generate_int_as_bytes(200))
self.__simulated_data.put(bytes(" ", "ascii"))
self.__add_to_queue(self.__generate_float_as_bytes(size = 6))
self.__simulated_data.put(bytes(" ", "ascii"))
self.__simulated_data_remaining += 2
for _ in range(3):
self.__add_to_queue(self.__generate_int_as_bytes(65535))
self.__simulated_data.put(bytes(" ", "ascii"))
self.__add_to_queue(self.__generate_int_as_bytes(65535))
self.__simulated_data.put(bytes("\n", "ascii"))
self.__simulated_data_remaining += 4
print("Length:", self.__simulated_data_remaining)
def __generate_int_as_bytes(self, upper_limit: int) -> list[bytes]:
byte_array = random.randint(0, upper_limit).to_bytes(4, "big")
return [byte.to_bytes() for byte in byte_array]
def __generate_float_as_bytes(self, upper_limit: int = 200, size: int = 4) -> list[bytes]:
random_float = random.random() * upper_limit
byte_data = struct.pack(">f", random_float)
data = [byte.to_bytes() for byte in byte_data]
for _ in range(size - len(data)):
data.append(b'\x00')
return data
def __add_to_queue(self, data: list[bytes]):
for value in data:
self.__simulated_data_remaining += 1
self.__simulated_data.put(value)