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7 Commits
f92a3f9a40
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2801a3f4cd
Author | SHA1 | Date |
---|---|---|
randomuser | 2801a3f4cd | |
randomuser | 7aff0ace45 | |
randomuser | 041f57f5cb | |
randomuser | 772cfc900c | |
randomuser | e107e28947 | |
randomuser | 733c381b41 | |
randomuser | 409b38f346 |
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@ -0,0 +1,2 @@
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__pycache__
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venv
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@ -0,0 +1,5 @@
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prompt_toolkit
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pyautogui
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pywinctl
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opencv-python
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numpy
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@ -0,0 +1,44 @@
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from modules.wires import WiresModule
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from modules.button import ButtonModule
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from modules.comp_wires import ComplicatedWiresModule
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from modules.password import PasswordModule
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modules = {
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'wires': WiresModule,
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'button': ButtonModule,
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'keypad': None,
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'simon': None,
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'first': None,
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'memory': None,
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'morse': None,
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'compwires': ComplicatedWiresModule,
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'seqwires': None,
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'maze': None,
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'password': PasswordModule,
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'vent': None,
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'discharge': None,
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'knob': None,
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}
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indicators = [
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'SND',
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'CLR',
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'CAR',
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'IND',
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'FRQ',
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'SIG',
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'NSA',
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'MSA',
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'TRN',
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'BOB',
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'FRK',
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]
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ports = [
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'DVI',
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'Para',
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'PS2',
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'RJ45',
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'Serial',
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'RCA',
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]
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@ -0,0 +1,69 @@
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from enum import Enum, auto
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from prompt_toolkit import prompt
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from prompt_toolkit.completion import WordCompleter
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class ButtonAction(Enum):
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RELEASE = auto(),
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HOLD = auto()
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class ButtonModule:
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def __init__(self, color, text, state):
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self.color = color
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self.text = text.lower()
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self.state = state
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def solve(self):
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if self.color == "blue" and self.text == "abort":
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return ButtonAction.HOLD
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elif self.state.batteries > 1 and self.text == "detonate":
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return ButtonAction.RELEASE
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try:
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if self.color == "white" and self.indicators["CAR"] == True:
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return ButtonAction.HOLD
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except KeyError: pass
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try:
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if self.state.batteries > 2 and self.indicators["FRK"] == True:
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return ButtonAction.RELEASE
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except KeyError: pass
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if self.color == "yellow":
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return ButtonAction.HOLD
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elif self.color == "red" and self.text == "hold":
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return ButtonAction.RELEASE
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return ButtonAction.HOLD
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def hold(self, color):
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if color == "blue":
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return 4
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elif color == "white":
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return 1
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elif color == "yellow":
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return 5
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return 1
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@classmethod
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def interactive(cls, state, cmdline):
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print("Please enter button color")
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color = prompt('button> ')
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print("Please enter button text")
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text = prompt('button> ')
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button = cls(color, text, state)
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result = button.solve()
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if result == ButtonAction.HOLD:
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print("What is the held button color")
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heldcolor = prompt('button> ')
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print("Release until the timer has a {} in any position".format(
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str(button.hold(heldcolor))
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))
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else:
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print("Release")
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@ -1,4 +1,6 @@
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from enum import Enum, auto
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from prompt_toolkit import prompt
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from prompt_toolkit.completion import WordCompleter
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class MappedAction(Enum):
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CUT_UNCONDITIONALLY = auto(),
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@ -11,18 +13,7 @@ class FinalAction(Enum):
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CUT = auto(),
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NO_CUT = auto()
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class GlobalState:
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def __init__(self, serial, parallel, batteries):
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self.serial = serial
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self.parallel = parallel
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self.batteries = batteries
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if int(self.serial[-1]) % 2 == 0:
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self.serial_even = True
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else:
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self.serial_even = False
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class ComplicatedWire:
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class ComplicatedWiresModule:
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def __init__(self, red, blue, star, led, state):
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self.red = red
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self.blue = blue
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@ -63,7 +54,6 @@ class ComplicatedWire:
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def resolveAction(self):
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action = self.getAction()
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print(action)
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if action == MappedAction.CUT_UNCONDITIONALLY:
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return FinalAction.CUT
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@ -72,12 +62,12 @@ class ComplicatedWire:
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return FinalAction.NO_CUT
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elif action == MappedAction.CUT_IF_DIGIT_EVEN:
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if self.state.serial_even:
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if self.state.serial.is_even:
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return FinalAction.CUT
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return FinalAction.NO_CUT
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elif action == MappedAction.CUT_IF_PARALLEL:
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if self.state.parallel:
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if 'Para' in self.state.ports:
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return FinalAction.CUT
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return FinalAction.NO_CUT
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@ -87,22 +77,23 @@ class ComplicatedWire:
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return FinalAction.NO_CUT
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@classmethod
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def human_helper(cls):
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serial = input("serial (string)? ")
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parallel = cls.custom_bool(input("parallel (bool)? "))
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batteries = int(input("number of batteries (int)? "))
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def interactive(cls, state, cmdline):
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completer = WordCompleter(['red', 'blue', 'star', 'led', 'quit', 'exit'])
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red = cls.custom_bool(input("is red (bool)? "))
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blue = cls.custom_bool(input("is blue (bool)? "))
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star = cls.custom_bool(input("is star (bool)? "))
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led = cls.custom_bool(input("is led (bool)? "))
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# there are 6 wires in the complicated wires module
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while True:
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text = prompt('compwires> ', completer=completer, complete_while_typing=True)
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print(red, blue, star, led)
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if text == "quit":
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return
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state = GlobalState(serial, parallel, batteries)
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wire = cls(red, blue, star, led, state)
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elif text == "exit":
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return
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print(wire.resolveAction())
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attr = [i in text for i in ['red', 'blue', 'star', 'led']]
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if __name__ == "__main__":
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ComplicatedWire.human_helper()
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try:
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print("CUT" if cls(*attr, state).resolveAction() == FinalAction.CUT else "NO CUT")
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except AttributeError:
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print("the state hasn't been completed. maybe fill out the serial?")
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@ -1,3 +1,6 @@
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from prompt_toolkit import prompt
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from prompt_toolkit.completion import WordCompleter
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class FoundCondition(Exception):
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pass
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@ -60,7 +63,7 @@ class PasswordModule:
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default module execution location
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(hint, default module execution location is where __name__ ==
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"__main__"
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"__main__")
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"""
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responses = []
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@ -71,5 +74,16 @@ class PasswordModule:
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obj = cls(responses)
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return obj.solve()
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@classmethod
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def interactive(cls, state, cmdline):
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responses = []
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for i in range(5):
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print("Enter {}th column of letters:".format(str(i + 1)))
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response = [*prompt('password> ')]
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responses.append(response)
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password = cls(responses)
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print(password.solve())
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if __name__ == "__main__":
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print(PasswordModule.human_helper())
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from prompt_toolkit import prompt
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from prompt_toolkit.completion import WordCompleter
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class WiresModule:
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def __init__(self, wires, state):
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self.state = state
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self.wires = wires.split(' ')
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self.len = len(self.wires)
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def solve(self):
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# prints the solved solution
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if self.len == 3:
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if not 'red' in self.wires:
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return "second wire"
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elif self.wires[-1] == "white":
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return "last wire"
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elif self.wires.count('blue') > 1:
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return "last blue wire"
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else:
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return "last wire"
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elif self.len == 4:
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if self.wires.count('red') > 1 and self.state.serial.is_odd:
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return "last red wire"
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elif self.wires[-1] == 'yellow' and not 'red' in self.wires:
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return "first wire"
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elif self.wires.count('blue') == 1:
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return "first wire"
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elif self.wires.count('yellow') > 1:
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return "last wire"
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else:
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return "second wire"
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elif self.len == 5:
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if self.wires[-1] == 'black' and self.state.serial.is_odd:
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return "fourth wire"
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elif self.wires.count('red') == 1 and self.wires.count('yellow') > 1:
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return "first wire"
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elif not 'black' in self.wires:
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return "second wire"
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else:
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return "first wire"
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elif self.len == 6:
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if not 'yellow' in self.wires and self.state.serial.is_odd:
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return "third wire"
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elif self.wires.count('yellow') == 1 and self.wires.count('white') > 1:
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return "fourth wire"
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elif not 'red' in self.wires:
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return "last wire"
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else:
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return "fourth wire"
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@classmethod
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def interactive(cls, state, cmdline):
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completer = WordCompleter(['red', 'blue', 'yellow', 'white', 'black'])
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print("Please enter wire colors from top to bottom.")
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text = prompt('wires> ', completer=completer, complete_while_typing=True)
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wires = WiresModule(text, state)
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print("cut the {}".format(wires.solve()))
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return
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@ -0,0 +1,131 @@
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from constants import modules, indicators, ports
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from prompt_toolkit import PromptSession
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from prompt_toolkit.completion import NestedCompleter
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maincompleter = NestedCompleter.from_nested_dict({
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'help': None,
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'mark': None,
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'serial': None,
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'strike': None,
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'batteries': None,
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'eval': None,
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'indicator': {*[indicator for indicator in indicators]},
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'ports': {*[port for port in ports]},
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'mod': {*["mod {}".format(module) for module in modules.keys()]},
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})
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class Serial:
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def __init__(self, serial):
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self.serial = serial.lower()
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@property
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def is_even(self):
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if int(self.serial[-1]) % 2 == 0:
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return True
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return False
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@property
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def is_odd(self):
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return not self.is_even
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@property
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def vowel(self):
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for vowel in ['a', 'e', 'i', 'o', 'u']:
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if vowel in self.serial:
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return True
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return False
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@property
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def no_vowel(self):
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return not self.vowel
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@property
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def text(self):
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return self.serial
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class GlobalBombState:
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def __init__(self):
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self.indicators = {}
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self.ports = []
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self._serial = None
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self.batteries = 0
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self.modulecount = 0
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self.strikes = 0
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@property
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def serial(self):
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return self._serial
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@serial.setter
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def serial(self, serial):
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self._serial = Serial(serial)
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def update_toolbar(self):
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return "help for help, ports: {}, ind: {}, batt: {}, serial: {}, strikes {}".format(
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self.ports, self.indicators, str(self.batteries), self.serial.text if self.serial else "?", str(self.strikes)
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)
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session = PromptSession(completer=maincompleter)
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state = GlobalBombState()
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while True:
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userinput = session.prompt("ktane> ", bottom_toolbar=state.update_toolbar(), complete_while_typing=True)
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splitted = userinput.split(' ')
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tokens = len(splitted)
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command = splitted[0]
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if command == "mod":
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if tokens == 1:
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print(modules.keys())
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elif tokens > 1:
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if splitted[1].isnumeric():
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state.modulecount = int(splitted[1])
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print("module count set to {}".format(str(state.modulecount)))
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else:
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try:
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selectedmodule = modules[splitted[1]]
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if selectedmodule:
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selectedmodule.interactive(state, splitted[2:])
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else:
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print("this module doesn't exist!")
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except IndexError:
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print("you didn't specify a module")
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|
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elif command == "serial": # set the serial number
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try:
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state.serial = splitted[1]
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print("serial number set to {}".format(state.serial.text))
|
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except IndexError:
|
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print("specify a serial number, perhaps?")
|
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|
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elif command == "batteries":
|
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try:
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state.batteries = int(splitted[1])
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print("battery count set to {}".format(str(state.batteries)))
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except IndexError:
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print("specify a number of batteries, perhaps?")
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elif command == "strike":
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state.strikes += 1
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print("strike given")
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elif command == "ports":
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try:
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state.ports.append(splitted[1])
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print("appeneded port {}".format(splitted[1]))
|
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except IndexError:
|
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print("specify a port type")
|
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|
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elif command == "indicator":
|
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try:
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state.indicators[splitted[1]] = True if splitted[2] == 't' else False
|
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print("added indicator {} with state {}".format(
|
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splitted[1], state.indicators[splitted[1]]
|
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))
|
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except IndexError: print("specify an indicator and a state")
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elif command == "eval":
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eval(' '.join(splitted[1:]))
|
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@ -0,0 +1,98 @@
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import pyautogui
|
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import colorsys
|
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import pywinctl
|
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import numpy
|
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import cv2 as cv
|
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import struct
|
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import matching
|
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from prompt_toolkit import prompt
|
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from prompt_toolkit.completion import WordCompleter
|
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|
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# get all windows
|
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titles = pywinctl.getAllTitles()
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title_completer = WordCompleter(titles)
|
||||
|
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try:
|
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window = pywinctl.getWindowsWithTitle("Keep Talking and Nobody Explodes")[0]
|
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except IndexError:
|
||||
try:
|
||||
text = prompt("Select window name> ", completer=title_completer)
|
||||
window = pywinctl.getWindowsWithTitle(text)[0]
|
||||
except IndexError:
|
||||
print("invalid title")
|
||||
exit()
|
||||
|
||||
if not window.isVisible:
|
||||
window.show()
|
||||
|
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frame = window.getClientFrame()
|
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print(frame)
|
||||
|
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def get_image(left, top, right, bottom): # returns an opencv image
|
||||
image = pyautogui.screenshot(region=(
|
||||
left, top, right - left, bottom - top
|
||||
))
|
||||
|
||||
numpy_array = numpy.array(image)
|
||||
opencv_image = cv.cvtColor(numpy_array, cv.COLOR_RGB2BGR)
|
||||
|
||||
return opencv_image
|
||||
|
||||
rgb_colors_to_match = [
|
||||
(220, 162, 129),
|
||||
(220, 162, 129),
|
||||
(145, 108, 89),
|
||||
]
|
||||
num_colors_in_range = 9
|
||||
delta_h_value = 10
|
||||
delta_s_value = 50
|
||||
delta_v_value = 50
|
||||
tolerence_value = 20
|
||||
|
||||
ranges = [
|
||||
matching.generate_hex_range(i, num_colors_in_range, delta_h=delta_h_value, delta_s=delta_s_value, delta_v=delta_v_value)
|
||||
for i in rgb_colors_to_match
|
||||
]
|
||||
|
||||
def are_rectangles_close(rect1, rect2):
|
||||
distance_threshold = 20
|
||||
x1, y1, w1, h1 = rect1
|
||||
x2, y2, w2, h2 = rect2
|
||||
return abs(x2 - x1) < distance_threshold and abs(y2 - y1) < distance_threshold
|
||||
|
||||
while True:
|
||||
image = get_image(frame.left, frame.top, frame.right, frame.bottom)
|
||||
blank = numpy.zeros(image.shape, dtype='uint8')
|
||||
|
||||
combined = image
|
||||
matched = matching.color_matching(image, ranges[0])
|
||||
combined = matching.convert_masked_pixels_to_zero(combined, matched)
|
||||
matched = matching.color_matching(image, ranges[1])
|
||||
combined = matching.convert_masked_pixels_to_zero(combined, matched)
|
||||
matched = matching.color_matching(image, ranges[2])
|
||||
combined = matching.convert_masked_pixels_to_zero(combined, matched)
|
||||
|
||||
min_contour_length = 100
|
||||
max_contour_length = 10000
|
||||
|
||||
|
||||
bw = cv.cvtColor(combined, cv.COLOR_BGR2GRAY)
|
||||
ret, thresh = cv.threshold(bw, 127, 255, cv.THRESH_BINARY)
|
||||
contours, hierarchy = cv.findContours(thresh, cv.RETR_TREE, cv.CHAIN_APPROX_SIMPLE)
|
||||
filtered_contours = [cnt for cnt in contours if min_contour_length <= cv.arcLength(cnt, True) <= max_contour_length]
|
||||
monster_contour = numpy.concatenate(filtered_contours)
|
||||
hull = cv.convexHull(monster_contour)
|
||||
bounding_quad = cv.minAreaRect(hull)
|
||||
points = cv.boxPoints(bounding_quad).astype(int)
|
||||
print(points)
|
||||
|
||||
cv.drawContours(combined, [points], 0, (0, 255, 0), 2)
|
||||
|
||||
cv.drawContours(combined, filtered_contours, -1, (0,255,255), 2)
|
||||
|
||||
cv.imshow('test', combined)
|
||||
key = cv.waitKey(1)
|
||||
if (key) == 113: # q key
|
||||
break
|
||||
|
||||
cv.destroyAllWindows()
|
|
@ -0,0 +1,59 @@
|
|||
import cv2
|
||||
import numpy as np
|
||||
|
||||
def rgb_to_hsv(rgb_color):
|
||||
# Convert RGB color to HSV color space
|
||||
hsv_color = cv2.cvtColor(np.uint8([[rgb_color]]), cv2.COLOR_RGB2HSV)[0][0]
|
||||
return hsv_color
|
||||
|
||||
def generate_hex_range(rgb_color, num_colors, delta_h=10, delta_s=50, delta_v=50):
|
||||
# Convert the RGB color to HSV color space
|
||||
hsv_color = rgb_to_hsv(rgb_color)
|
||||
|
||||
# Define ranges in HSV color space
|
||||
h_range = np.linspace(hsv_color[0] - delta_h, hsv_color[0] + delta_h, num_colors)
|
||||
s_range = np.linspace(hsv_color[1] - delta_s, hsv_color[1] + delta_s, num_colors)
|
||||
v_range = np.linspace(hsv_color[2] - delta_v, hsv_color[2] + delta_v, num_colors)
|
||||
|
||||
hex_range = []
|
||||
|
||||
# Generate colors in the HSV color space and convert them to BGR
|
||||
for h_val in h_range:
|
||||
for s_val in s_range:
|
||||
for v_val in v_range:
|
||||
hsv_color_modified = np.array([h_val, s_val, v_val])
|
||||
bgr_color_modified = cv2.cvtColor(np.uint8([[hsv_color_modified]]), cv2.COLOR_HSV2BGR)[0][0]
|
||||
hex_color = "#{:02x}{:02x}{:02x}".format(int(bgr_color_modified[2]),
|
||||
int(bgr_color_modified[1]),
|
||||
int(bgr_color_modified[0]))
|
||||
hex_range.append(hex_color)
|
||||
|
||||
return hex_range
|
||||
|
||||
def color_matching(image, hex_range_colors, tolerance=20):
|
||||
hsv_image = cv2.cvtColor(image, cv2.COLOR_BGR2HSV)
|
||||
|
||||
matched_pixels = np.zeros_like(hsv_image[:, :, 0], dtype=np.uint8)
|
||||
|
||||
for hex_color in hex_range_colors:
|
||||
# Convert the hex color to RGB
|
||||
rgb_color = tuple(int(hex_color[i:i + 2], 16) for i in (1, 3, 5))
|
||||
# Convert the RGB color to HSV
|
||||
hsv_color = rgb_to_hsv(rgb_color)
|
||||
|
||||
lower_bound = np.array([hsv_color[0] - tolerance, hsv_color[1] - tolerance, hsv_color[2] - tolerance])
|
||||
upper_bound = np.array([hsv_color[0] + tolerance, hsv_color[1] + tolerance, hsv_color[2] + tolerance])
|
||||
|
||||
mask = cv2.inRange(hsv_image, lower_bound, upper_bound)
|
||||
matched_pixels |= mask
|
||||
|
||||
return matched_pixels
|
||||
|
||||
def convert_masked_pixels_to_zero(image, mask):
|
||||
# Create an all-white (ones) image with the same shape as the original image
|
||||
white_image = np.ones_like(image) * 255
|
||||
|
||||
# Use the mask to set all masked pixels in the original image to zero
|
||||
result_image = cv2.bitwise_and(image, white_image, mask=cv2.bitwise_not(mask))
|
||||
|
||||
return result_image
|
Loading…
Reference in New Issue