112 lines
3.3 KiB
Python
Executable file
112 lines
3.3 KiB
Python
Executable file
#!/usr/bin/env python
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import enum
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import functools
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import sys
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from typing import List, Literal, NamedTuple, Optional, Union, cast
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import z3
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Register = Literal["w", "x", "y", "z"]
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class InstructionType(enum.Enum):
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INPUT = "inp"
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ADD = "add"
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MULTIPLY = "mul"
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DIVIDE = "div"
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MODULO = "mod"
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EQUAL = "eql"
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class Instruction(NamedTuple):
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type: InstructionType
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destination: Register
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source: Optional[Union[Register, int]]
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def solve(input: List[str]) -> int:
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def parse() -> List[Instruction]:
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def parse_instruction(line: str) -> Instruction:
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type, *registers = line.split()
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assert registers[0] in ("w", "x", "y", "z") # Sanity check
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destination = cast(Register, registers[0])
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source: Optional[Union[Register, int]] = None
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if type != "inp":
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if registers[1] in ("w", "x", "y", "z"):
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source = cast(Register, registers[1])
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else:
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source = int(registers[1])
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return Instruction(InstructionType(type), destination, source)
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return [parse_instruction(line) for line in input]
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def run_z3(instructions: List[Instruction]) -> int:
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solver = z3.Optimize()
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BITS = 64
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digits = [z3.BitVec(f"input_{i}", BITS) for i in range(14)]
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next_input = iter(digits).__next__
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for d in digits:
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solver.add(z3.And(1 <= d, d <= 9))
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zero, one = z3.BitVecVal(0, BITS), z3.BitVecVal(1, BITS)
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registers = {r: zero for r in ("w", "x", "y", "z")}
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for i, instr in enumerate(instructions):
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if instr.type == InstructionType.INPUT:
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registers[instr.destination] = next_input()
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continue
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assert instr.source is not None # Sanity check
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value = registers[instr.destination]
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if isinstance(instr.source, int):
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source = z3.BitVecVal(instr.source, BITS)
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else:
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source = registers[instr.source]
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res = z3.BitVec(f"result_{i}", BITS)
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if instr.type == InstructionType.ADD:
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solver.add(res == (value + source))
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elif instr.type == InstructionType.MULTIPLY:
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solver.add(res == (value * source))
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elif instr.type == InstructionType.DIVIDE:
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solver.add(source > zero) # Sanity check
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solver.add(res == (value / source))
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elif instr.type == InstructionType.MODULO:
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solver.add(value >= zero) # Sanity check
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solver.add(source > zero) # Sanity check
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solver.add(res == (value % source))
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elif instr.type == InstructionType.EQUAL:
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solver.add(res == z3.If(value == source, one, zero))
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else:
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assert False # Sanity check
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registers[instr.destination] = res
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solver.add(registers["z"] == zero)
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model_number = functools.reduce(lambda a, b: a * 10 + b, digits)
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solver.maximize(model_number)
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assert solver.check() == z3.sat # Sanity check
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return solver.model().eval(model_number)
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return run_z3(parse())
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def main() -> None:
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input = [line.rstrip("\n") for line in sys.stdin.readlines()]
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print(solve(input))
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if __name__ == "__main__":
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main()
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