def executor(): console.header('day 2, part 2') timer = Timer() used_ids = set([]) pairs = [] ids = DataProvider.load('day2') timer.start() for id in ids: if id not in used_ids: used_ids.add(id) for inner in ids: if inner in used_ids: continue distance = hamming_distance(id, inner) if distance == 1: pairs.append(( id, inner, )) timer.end() console.log(' ', 'Pairs', fg='cyan', bold=True, color_status=True, include_brackets=True) print(pairs) timer.output()
def executor(): console.header('day 3, part 1') max_x = 1000 max_y = 1000 elements = DataProvider.load('day3') claim_ids = [] timer = Timer() timer.start() claims = numpy.zeros([max_x, max_y]) for element in elements: claim = Claim(element) claims = claim.fill_claim(claims) for element in elements: claim = Claim(element) if claim.claim_is_alone(claims): claim_ids.append(claim.claim_id) timer.end() console.log(' ', 'Claim Ids', fg='cyan', bold=True, color_status=True, include_brackets=True) print(claim_ids) timer.output()
def executor(): console.header('day 2, part 1') timer = Timer() pair_count = 0 triplet_count = 0 timer.start() for id in DataProvider.load('day2'): if has(2, id): pair_count += 1 if has(3, id): triplet_count += 1 timer.end() console.log('Pairs', str(pair_count), fg='cyan', bold=True, color_status=True, include_brackets=True) console.log('Triplets', str(triplet_count), fg='cyan', bold=True, color_status=True, include_brackets=True) console.log('Checksum', str(pair_count * triplet_count), fg='cyan', bold=True, color_status=True, include_brackets=True) timer.output()
def executor(): console.header('day 1 - part 2') master_freq = 0 master_freq_set = set([master_freq]) master_freq_list = [master_freq] count = 0 timer = Timer() timer.start() try: while True: count += 1 for freq in DataProvider.load('day1'): master_freq = master_freq + int(freq) master_freq_set.add(master_freq) master_freq_list.append(master_freq) if len(master_freq_set) != len(master_freq_list): raise Exception('Found it!') if count % 10 == 0: console.log(' ', 'Looped {} times so far.'.format(count)) except: pass timer.end() console.log('Dupe', master_freq, fg='cyan', bold=True, color_status=True, include_brackets=True) timer.output()
def executor(): console.header('day 5, part 1') timer = Timer() polymer = DataProvider.read('day5').strip() timer.start() polymer = Polymer.react(polymer) timer.end() console.log('polymer', polymer) console.log('length', str(len(polymer))) timer.output()
def executor(): console.header('day 5, part 2') timer = Timer() polymer = DataProvider.read('day5').strip() timer.start() polymer = Polymer.get_best_score(polymer) timer.end() console.log('Best', polymer) console.log('Length', str(len(polymer))) timer.output()
def executor(): console.header('day 11, part 1') timer = Timer() serial_number = 3214 GRID_X = 300 GRID_Y = 300 timer.start() console.log('Task', 'Building empty power grid') grid = [[0] * GRID_Y for i in range(GRID_X)] console.log('Task', 'Calculating power levels') for x in range(GRID_X): for y in range(GRID_Y): grid[x][y] = power_level(x, y, serial_number) max_x = GRID_X - 3 max_y = GRID_Y - 3 max_power = -999 target_x = -1 target_y = -1 console.log('Task', 'Finding 3x3 grid with the highest power level') for x in range(max_x): for y in range(max_y): cell = grid[x:x + 3] cell = [inner[y:y + 3] for inner in cell] power = 0 for row in cell: power += sum(row) if power > max_power: max_power = power target_x = x target_y = y timer.end() console.header('output') console.log('Power', max_power) console.log('X', target_x) console.log('Y', target_y) timer.output()
def executor(): console.header('day 8, part 1') console.log('Task', 'Configure application...') timer = Timer() data = DataProvider.read('day8').strip() #data = '2 3 0 3 10 11 12 1 1 0 1 99 2 1 1 2' elements = [int(el) for el in data.split(' ')] timer.start() console.header('executing') score, rest = parse(elements) timer.end() console.header('output') console.log('Score', score) console.log('Rest', rest) timer.output()
def executor(): console.header('day 4, part 2') timer = Timer() days = DataProvider.load('day4') fsm = FiniteStateMachine(StartState) timer.start() days.sort() for day in days: fsm.execute(day.strip()) fsm.to(End2State) fsm.execute(None) timer.end() console.log('Minute', '', fg='cyan', bold=True, color_status=True, include_brackets=True) timer.output()
def executor(): console.header('day 3, part 1') max_x = 1000 max_y = 1000 count = 0 timer = Timer() timer.start() claims = numpy.zeros([max_x, max_y]) for element in DataProvider.load('day3'): claim = Claim(element) claims = claim.fill_claim(claims) for x in range(max_x): for y in range(max_y): if claims[x][y] > 1: count += 1 timer.end() console.log('Count', str(count), fg='cyan', bold=True, color_status=True, include_brackets=True) timer.output()
def executor(ctx): console.header('day 10, both parts') timer = Timer() data = DataProvider.load('day10') # data = [ # 'position=< 9, 1> velocity=< 0, 2>', # 'position=< 7, 0> velocity=<-1, 0>', # 'position=< 3, -2> velocity=<-1, 1>', # 'position=< 6, 10> velocity=<-2, -1>', # 'position=< 2, -4> velocity=< 2, 2>', # 'position=<-6, 10> velocity=< 2, -2>', # 'position=< 1, 8> velocity=< 1, -1>', # 'position=< 1, 7> velocity=< 1, 0>', # 'position=<-3, 11> velocity=< 1, -2>', # 'position=< 7, 6> velocity=<-1, -1>', # 'position=<-2, 3> velocity=< 1, 0>', # 'position=<-4, 3> velocity=< 2, 0>', # 'position=<10, -3> velocity=<-1, 1>', # 'position=< 5, 11> velocity=< 1, -2>', # 'position=< 4, 7> velocity=< 0, -1>', # 'position=< 8, -2> velocity=< 0, 1>', # 'position=<15, 0> velocity=<-2, 0>', # 'position=< 1, 6> velocity=< 1, 0>', # 'position=< 8, 9> velocity=< 0, -1>', # 'position=< 3, 3> velocity=<-1, 1>', # 'position=< 0, 5> velocity=< 0, -1>', # 'position=<-2, 2> velocity=< 2, 0>', # 'position=< 5, -2> velocity=< 1, 2>', # 'position=< 1, 4> velocity=< 2, 1>', # 'position=<-2, 7> velocity=< 2, -2>', # 'position=< 3, 6> velocity=<-1, -1>', # 'position=< 5, 0> velocity=< 1, 0>', # 'position=<-6, 0> velocity=< 2, 0>', # 'position=< 5, 9> velocity=< 1, -2>', # 'position=<14, 7> velocity=<-2, 0>', # 'position=<-3, 6> velocity=< 2, -1>', # ] lines = [[int(i) for i in re.findall(r'-?\d+', line)] for line in data] index = -1 size = -1 console.log('Task', 'Finding smallest sized object to work with') timer.start() for i in range(20000): minx = min(x + i * vx for (x, y, vx, vy) in lines) maxx = max(x + i * vx for (x, y, vx, vy) in lines) miny = min(y + i * vy for (x, y, vx, vy) in lines) maxy = max(y + i * vy for (x, y, vx, vy) in lines) test_size = maxx - minx + maxy - miny if size == -1 or test_size < size: size = test_size index = i console.log('Found', 'Min Size {} for index {}'.format(size, index)) console.log('Task', 'Building data map') my_map = [[' '] * 200 for j in range(400)] for (x, y, vx, vy) in lines: my_map[y + index * vy][x + index * vx - 250] = '*' console.log('Task', 'Saving map to file') with open(join(ctx.obj['BASE_PATH'], 'output.txt'), 'w+') as handle: for m in my_map: handle.write(''.join(m) + '\n') timer.end() console.header('output') timer.output()
def executor(): console.header('day 7, part 1') timer = Timer() steps = DataProvider.load('day7') # steps = [ # 'Step C must be finished before step A can begin.', # 'Step C must be finished before step F can begin.', # 'Step A must be finished before step B can begin.', # 'Step A must be finished before step D can begin.', # 'Step B must be finished before step E can begin.', # 'Step D must be finished before step E can begin.', # 'Step F must be finished before step E can begin.', # ] timer.start() console.log('Task', 'Build nodes') node_names = set([]) for step in steps: [parent, child] = re.match(r'Step ([A-Z]) .*? step ([A-Z]).*', step).group(1, 2) node_names.add(parent) node_names.add(child) console.log('Info', 'Creating {} nodes'.format(len(node_names))) nodes = [] for node_name in node_names: nodes.append(Node(node_name)) console.log('Info', 'Executing steps') count = 0 for step in steps: count += 1 console.log('Info', 'Step {} / {}'.format(count, len(steps))) [parent, child] = re.match(r'Step ([A-Z]) .*? step ([A-Z]).*', step).group(1, 2) parent = find(parent, nodes) child = find(child, nodes) parent.add_child(child) console.log('Info', 'Creating root node and children') root_node = Node('-') for node in [node for node in nodes if node.is_root()]: root_node.add_child(node) console.header('node picker') available_picks = root_node.child_nodes output = '' while available_picks: picks = set(sorted([n.name for n in available_picks])) pick = min(picks) console.log( 'Info', 'Picking {} from {{ {} }}'.format( pick, ', '.join([n.name for n in available_picks]))) node = find(pick, nodes) node.triggered = True output += node.name available_picks = list( filter(lambda n: n.name != pick, available_picks)) + [ n for n in node.child_nodes if n.can_trigger() ] timer.end() console.header('output') console.log('Output', output) timer.output()