Exemplo n.º 1
0
def main():
    # part 1
    memory_ = numpy.loadtxt('day9\input.txt', delimiter=',', dtype=numpy.int64)
    #memory_ = numpy.fromstring('1102,34915192,34915192,7,4,7,99,0', sep=',', dtype=numpy.int64)
    #memory_ = numpy.fromstring('104,1125899906842624,99', sep=',', dtype=numpy.int64)
    #memory_ = numpy.fromstring('109,1,204,-1,1001,100,1,100,1008,100,16,101,1006,101,0,99', sep=',', dtype=numpy.int64)

    ### Part 1
    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.queue_input(1)
    cpu.exec()
    print(f'Part 1 output:')
    try:
        while True:
            print(str(cpu.get_output(False)) + ' ', )
    except Halted:
        print('done')

    ### Part 2
    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.queue_input(2)
    cpu.exec()
    print(f'Part 2 output:')
    try:
        while True:
            print(str(cpu.get_output(False)) + ' ', )
    except Halted:
        print('done')
Exemplo n.º 2
0
def main():
    # part 1
    memory_ = numpy.loadtxt('day11\input.txt',
                            delimiter=',',
                            dtype=numpy.int64)

    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.background_exec()

    (x, y) = (0, 0)
    panels = defaultdict(lambda: BLACK)
    facing = up
    loop_count = 0
    panels[(x, y)] = BLACK
    while (not cpu.done):  # and (len(panels) < 400):
        #print(f'input: {panels[(x,y)]}')
        loop_count += 1
        if not loop_count % 1000:
            print(loop_count)
        try:
            cpu.queue_input(panels[(x, y)])
            color = cpu.get_output(block=True)
            #print(f'{color}')
            direction = cpu.get_output(block=True)
            #print(f'{direction}')
        except Halted:
            print('Program done')
            break

        panels[(x, y)] = color

        # rotate
        facing = facing.rotate(direction)

        # move forward
        if facing is up:
            y -= 1
        elif facing is right:
            x += 1
        elif facing is down:
            y += 1
        elif facing is left:
            x -= 1

    #print(f'Part 1: {len(panels)}')
    min_x = min(panels, key=lambda p: p[0])[0]
    max_x = max(panels, key=lambda p: p[0])[0]
    min_y = min(panels, key=lambda p: p[1])[1]
    max_y = max(panels, key=lambda p: p[1])[1]

    img = numpy.zeros((max_y + 1 - min_y, max_x + 1 - min_x),
                      dtype=numpy.uint8)
    for (panel, color) in panels.items():
        img[panel[1], panel[0]] = color
    #plt.imshow(img)
    #plt.show()
    print(panels)
Exemplo n.º 3
0
def main():
    # part 1
    memory_ = numpy.loadtxt(r'day17\input.txt',
                            delimiter=',',
                            dtype=numpy.int64)
    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.background_exec()

    grid = defaultdict(lambda: ord('.'))
    (x, y) = (0, 0)

    bot_loc = (0, 0)

    while True:
        try:
            val = cpu.get_output(block=True)
            if val == 10:
                # new row
                x = 0
                y += 1
                #print_grid(grid)
                continue
            if val == ord('^'):
                bot_loc = (x, y)
            grid[(x, y)] = val
            x += 1
        except Halted:
            print('Program Halted')
            break

    print(f'Part 1: {sum( x*y for (x,y) in find_intersections(grid))}')

    ### part 2:
    sub_a = 'R,8,L,4,R,4,R,10,R,8\n'
    sub_b = 'L,12,L,12,R,8,R,8\n'
    sub_c = 'R,10,R,4,R,4\n'
    main_routine = 'A,A,B,C,B,C,B,C,C,A\n'

    memory = numpy.array(memory_, copy=True)
    memory[0] = 2  # set to override mode
    cpu = CPU(memory)

    # queue inputs
    for c in main_routine + sub_a + sub_b + sub_c + 'n\n':
        cpu.queue_input(ord(c))

    # run
    cpu.exec()

    while True:
        try:
            space_dust = cpu.get_output()
        except (Empty, Halted):
            break
    print(f'Part 2: {space_dust}')
Exemplo n.º 4
0
def main():
    # part 1
    memory_ = numpy.loadtxt('day13\input.txt',
                            delimiter=',',
                            dtype=numpy.int64)
    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.background_exec()

    screen = defaultdict(lambda: 0)

    while True:
        try:
            x = cpu.get_output(block=True)
            y = cpu.get_output(block=True)
            val = cpu.get_output(block=True)
            screen[(x, y)] = val
            print(f'({x}, {y}) {val}')
        except Halted:
            print('halted')
            break

    blocks = len([i for i in screen.values() if i == BLOCK])
    print(f'Part 1: {blocks}')

    memory = numpy.array(memory_, copy=True)
    memory[0] = 2
    # hack to make paddle the whole width
    memory[1608:1652] = 3

    cpu = CPU(memory)
    for i in range(10000):
        cpu.queue_input(0)
    screen = defaultdict(lambda: 0)

    cpu.background_exec()
    score = 0
    while True:
        try:
            x = cpu.get_output(block=True)
            y = cpu.get_output(block=True)
            val = cpu.get_output(block=True)
            if (x == -1) and (y == 0):
                score = val
            #screen[(x,y)] = val
            #print(f'({x}, {y}) {val}')
        except Halted:
            print('halted')
            break

    print(f'Part 2: {score}')
Exemplo n.º 5
0
def y2021_d7():
    print('2021 Day 7 Easter Egg: run input as intcode program')
    memory_ = numpy.loadtxt('y2021\day7\input.txt',
                            delimiter=',',
                            dtype=numpy.int64)

    memory = numpy.array(memory_, copy=True)
    cpu = CPU(memory)
    cpu.background_exec()

    try:
        while True:
            print(chr(cpu.get_output(block=True)), end='')
    except Halted:
        pass
    print('\nDone')
Exemplo n.º 6
0
def main():
    # part 1
    memory_ = numpy.loadtxt('day7\input.txt', delimiter=',', dtype=numpy.int64)
    ##memory_ = numpy.fromstring('3,15,3,16,1002,16,10,16,1,16,15,15,4,15,99,0,0', sep=',', dtype=numpy.int64)
    ##memory_ = numpy.fromstring('3,23,3,24,1002,24,10,24,1002,23,-1,23,101,5,23,23,1,24,23,23,4,23,99,0,0', sep=',', dtype=numpy.int64)

    max_out = None
    max_seq = None
    for phase_seq in itertools.permutations(range(5), 5):
        last_output = 0
        for phase in phase_seq:
            memory = numpy.array(memory_, copy=True)
            cpu = CPU(memory)
            cpu.queue_input(phase)
            cpu.queue_input(last_output)
            cpu.exec()
            last_output = cpu.get_output()
        if not max_out or (last_output > max_out):
            max_out = last_output
            max_seq = phase_seq

    print(f'Part 1: Max: {max_out}')
    print(f'Part 1: Max Seq: {max_seq}')

    # 3,26,1001,26,-4,26,3,27,1002,27,2,27,1,27,26,27,4,27,1001,28,-1,28,1005,28,6,99,0,0,5
    # part 2
    #memory_ = numpy.fromstring('3,26,1001,26,-4,26,3,27,1002,27,2,27,1,27,26,27,4,27,1001,28,-1,28,1005,28,6,99,0,0,5', sep=',', dtype=numpy.int64)

    max_out = None
    max_seq = None
    for phase_seq in itertools.permutations(range(5, 10), 5):
        cpu_a = CPU(numpy.array(memory_, copy=True), input_block=True)
        cpu_b = CPU(numpy.array(memory_, copy=True),
                    input_block=True,
                    input_q=cpu_a.output_q)
        cpu_c = CPU(numpy.array(memory_, copy=True),
                    input_block=True,
                    input_q=cpu_b.output_q)
        cpu_d = CPU(numpy.array(memory_, copy=True),
                    input_block=True,
                    input_q=cpu_c.output_q)
        cpu_e = CPU(numpy.array(memory_, copy=True),
                    input_block=True,
                    input_q=cpu_d.output_q)

        cpu_a.input_q = cpu_e.output_q

        cpu_a.queue_input(phase_seq[0])
        cpu_a.queue_input(0)
        cpu_b.queue_input(phase_seq[1])
        cpu_c.queue_input(phase_seq[2])
        cpu_d.queue_input(phase_seq[3])
        cpu_e.queue_input(phase_seq[4])
        # start CPU's in threads
        a_thread = threading.Thread(target=cpu_a.exec)
        b_thread = threading.Thread(target=cpu_b.exec)
        c_thread = threading.Thread(target=cpu_c.exec)
        d_thread = threading.Thread(target=cpu_d.exec)
        e_thread = threading.Thread(target=cpu_e.exec)

        a_thread.start()
        b_thread.start()
        c_thread.start()
        d_thread.start()
        e_thread.start()

        e_thread.join()
        last_output = cpu_e.get_output()
        if not max_out or (last_output > max_out):
            max_out = last_output
            max_seq = phase_seq

    print(f'Part 2 max out: {max_out}')