def main():
config = Config(day=7)
# PART ONE
path_file = os.path.join(config.path_data, "bag_color_rules_test.txt")
data_test = read_txt_file(path_file=path_file)
data_test_parsed = parse_rules(data=data_test)
bags_carrying_shiny_gold = find_gold_carrying_bags(data=data_test_parsed, bag_type="shiny gold bag")
n_bags_carrying_shiny_gold = len(bags_carrying_shiny_gold)
assert 4 == n_bags_carrying_shiny_gold
path_file = os.path.join(config.path_data, "bag_color_rules.txt")
data = read_txt_file(path_file=path_file)
data_parsed = parse_rules(data=data)
bags_carrying_shiny_gold = find_gold_carrying_bags(data=data_parsed)
assert 128 == len(bags_carrying_shiny_gold)
# PART TWO
bags_unpacked = unpack(rules=data_test_parsed, inner_bags=data_test_parsed["shiny gold bags"])
assert 32 == len(bags_unpacked)
path_file = os.path.join(config.path_data, "bag_color_rules_test_part_two.txt")
data_test_two = read_txt_file(path_file=path_file)
data_test_two_parsed = parse_rules(data=data_test_two)
bags_unpacked = unpack(rules=data_test_two_parsed, inner_bags=data_test_two_parsed["shiny gold bags"])
assert 126 == len(bags_unpacked)
bags_unpacked = unpack(rules=data_parsed, inner_bags=data_parsed["shiny gold bags"])
print(f"The total number of bags within a shiny gold bag equals: {len(bags_unpacked)}")
assert 20189 == len(bags_unpacked)
return True
def main():
config = Config(day=4)
path_file = os.path.join(config.path_data, "passport_batch_files.txt")
path_file_invalid = os.path.join(config.path_data, "passport_batch_files_invalid_test.txt")
path_file_valid = os.path.join(config.path_data, "passport_batch_files_valid_test.txt")
with open(path_file, "r") as f:
data = [value.strip("\n") for value in f.readlines()]
data_parsed = parse_data(data=data)
passport_validity = [*map(validate_passport_one, data_parsed)]
print("PART ONE")
print(f"Number of valid passports: {sum(passport_validity)} / {len(passport_validity)}")
with open(path_file_invalid, "r") as f:
data_invalid = [value.strip("\n") for value in f.readlines()]
data_invalid_parsed = parse_data(data=data_invalid)
passport_validity = [*map(validate_passport_two, data_invalid_parsed)]
assert not all(passport_validity)
with open(path_file_valid, "r") as f:
data_valid = [value.strip("\n") for value in f.readlines()]
data_valid_parsed = parse_data(data=data_valid)
passport_validity = [*map(validate_passport_two, data_valid_parsed)]
assert all(passport_validity)
passport_validity = [*map(validate_passport_two, data_parsed)]
print("PART TWO")
print(f"Number of valid passports: {sum(passport_validity)} / {len(passport_validity)}")
return True
def main():
config = Config(day=17)
# PART ONE
# Test
state_initial = parse_initial_state(path_file=os.path.join(config.path_data, 'initial_state_test.txt'))
state_final = simulate_cycles(state_initial=state_initial, n_cycles=6)
assert 112 == state_final.sum().sum()
# Real deal
state_initial = parse_initial_state(path_file=os.path.join(config.path_data, 'initial_state.txt'))
state_final = simulate_cycles(state_initial=state_initial, n_cycles=6)
print(f"The number of active states upon 6 cycles equals: {state_final.sum().sum()}")
assert 255 == state_final.sum().sum()
# PART TWO
# Test
state_initial = parse_initial_state(path_file=os.path.join(config.path_data, 'initial_state_test.txt'), dims=4)
state_final = simulate_cycles(state_initial=state_initial, n_cycles=6, dims=4)
assert 848 == state_final.sum().sum()
# Real deal
state_initial = parse_initial_state(path_file=os.path.join(config.path_data, 'initial_state.txt'), dims=4)
state_final = simulate_cycles(state_initial=state_initial, n_cycles=6, dims=4)
print(f"PART TWO: The number of active states upon 6 cycles equals: {state_final.sum().sum()}")
return True
def main():
config = Config(day=14)
# PART ONE
# Test
path_file_test = os.path.join(config.path_data, "program_test.txt")
program = parse_program(path_file_test)
memory = execute_program(program=program)
assert 165 == get_memory_sum(memory=memory)
# Real deal
path_file = os.path.join(config.path_data, "program.txt")
program = parse_program(path_file)
memory = execute_program(program=program)
memory_sum = get_memory_sum(memory=memory)
print(f"The sum of memory equals: {memory_sum}")
assert 9619656261720 == memory_sum
# PART TWO
# Test
path_file_test = os.path.join(config.path_data, "program_test_two.txt")
program = parse_program(path_file_test)
memory = execute_program_v2(program=program)
assert 208 == get_memory_sum(memory=memory)
# Real deal
program = parse_program(path_file)
memory = execute_program_v2(program=program)
memory_sum = get_memory_sum(memory)
print(f"The sum of memory for part 2 equals: {memory_sum}")
assert 4275496544925 == sum(list(memory.values()))
return True
def main():
config = Config(day=9)
# PART ONE
# Test
path_data = os.path.join(config.path_data, "xmas_test.txt")
data_test = read_txt_file(path_file=path_data)
data_test = [int(val) for val in data_test]
encoding_error_test = detect_encoding_error(sequence=data_test, preamble=5)
assert 127 == encoding_error_test
path_data = os.path.join(config.path_data, "xmas.txt")
data = read_txt_file(path_file=path_data)
data = [int(val) for val in data]
encoding_error = detect_encoding_error(sequence=data, preamble=25)
assert 167829540 == encoding_error
print(f"The first digit which does not abide to XMAX encoding is: {encoding_error}")
# PART TWO
# Test
encoding_weakness_test = detect_encryption_weakness(sequence=data_test, encoding_error=encoding_error_test)
assert 62 == encoding_weakness_test
encoding_weakness = detect_encryption_weakness(sequence=data, encoding_error=encoding_error)
print(
f"The sum of the min and max of the contiguous sequence of numbers, "
f"which sum equals the encoding error equals: {encoding_weakness}"
)
assert 28045630 == encoding_weakness
return True
def main():
config = Config(day=6)
path_file = os.path.join(config.path_data, "custom_declaration_forms.txt")
# PART ONE
path_file_test = os.path.join(config.path_data,
"custom_declaration_forms_test.txt")
data_test = read_txt_file(path_file=path_file_test)
data_test_group = split_group_data(data=data_test)
sum_of_counts = compute_part_one(groups=data_test_group)
assert 11 == sum_of_counts, f"Script does not lead to the correct sum. 11 != {sum_of_counts}"
data = read_txt_file(path_file=path_file)
groups = split_group_data(data=data)
sum_of_counts = compute_part_one(groups=groups)
print(
f"The sum of the counts of the unique questions to which a group answered yes equals: {sum_of_counts}"
)
assert 6585 == sum_of_counts
# PART TWO
data_test_group = split_group_data(data=data_test)
sum_of_counts = compute_part_two(groups=data_test_group)
assert 6 == sum_of_counts, f"Script does not lead to the correct sum. 6 != {sum_of_counts}"
groups = split_group_data(data=data)
sum_of_counts = compute_part_two(groups=groups)
print(
f"The sum of the counts of the questions to which all group members answered yes: {sum_of_counts}"
)
return True
pass
def main():
config = Config(day=11)
# PART ONE
# Test one
path_data = os.path.join(config.path_data, "seating_system_test.txt")
seat_system_test_one = parse_seat_system(path_file=path_data)
path_data = os.path.join(config.path_data, "seating_system_test_exp.txt")
seat_system_exp = parse_seat_system(path_file=path_data)
seat_system_new = fill_seats(seat_plan=seat_system_test_one)
assert np.array_equal(seat_system_exp, seat_system_new)
state_count = get_state_counts(seat_system=seat_system_new)
assert state_count["#"] == 37
path_data = os.path.join(config.path_data, "seating_system.txt")
seat_system = parse_seat_system(path_file=path_data)
# seat_system = fill_seats(seat_plan=seat_system)
# state_count = get_state_counts(seat_system=seat_system)
#
# print(f"Number of occupied seats equals: {state_count['#']}")
# assert state_count["#"] == 2275
# Test get visible seats
path_data = os.path.join(config.path_data, "seating_system_test_two.txt")
seat_system_test_two = parse_seat_system(path_file=path_data)
seats_occupied = get_visible_occupied_seats(seat_plan=seat_system_test_two,
colidx=3,
rowidx=4)
assert seats_occupied == 8
path_data = os.path.join(config.path_data, "seating_system_test_three.txt")
seat_system_test_three = parse_seat_system(path_file=path_data)
seats_occupied = get_visible_occupied_seats(
seat_plan=seat_system_test_three, colidx=1, rowidx=1)
assert seats_occupied == 0
path_data = os.path.join(config.path_data, "seating_system_test_four.txt")
seat_system_test_four = parse_seat_system(path_file=path_data)
seats_occupied = get_visible_occupied_seats(
seat_plan=seat_system_test_four, colidx=3, rowidx=3)
assert seats_occupied == 0
# Test fill_seats_two
seat_system_new = fill_seats_two(seat_plan=seat_system_test_one)
state_count = get_state_counts(seat_system=seat_system_new)
assert state_count["#"] == 26
# Real deal (Does not work)
# seat_system_new = fill_seats_two(seat_plan=seat_system)
# state_count = get_state_counts(seat_system=seat_system_new)
print(f"The number of occupied seats equals: {state_count['#']}")
return True
def main():
config = Config(day=13)
# PART ONE
# Test
path_data_test = os.path.join(config.path_data, "notes_test.txt")
timestamp_test, buslines_test = parse_notes(path_file=path_data_test)
minutes_to_wait, bus_earliest = get_earliest_bus(timestamp=timestamp_test,
buslines=buslines_test)
assert 295 == bus_earliest * minutes_to_wait
# Real deal
path_data = os.path.join(config.path_data, "notes.txt")
timestamp, buslines = parse_notes(path_file=path_data)
minutes_to_wait, bus_earliest = get_earliest_bus(timestamp=timestamp,
buslines=buslines)
print(
f"The earliest bus is {bus_earliest} which arrives in {minutes_to_wait} minutes, making the product equal to: "
f"{minutes_to_wait * bus_earliest}")
assert 410 == bus_earliest * minutes_to_wait
# PART TWO
# Test
timestamp_test, buslines_test = parse_notes_two(path_file=path_data_test)
t = get_t(buslines=buslines_test)
assert 1068781 == t
buslines_test = ["17", "x", "13", "19"]
t = get_t(buslines=buslines_test)
assert 3417 == t
buslines_test = ["67", "7", "59", "61"]
t = get_t(buslines=buslines_test)
assert 754018 == t
buslines_test = ["67", "x", "7", "59", "61"]
t = get_t(buslines=buslines_test)
assert 779210 == t
# Real deal
timestamp, buslines = parse_notes_two(path_file=path_data)
t = get_t(buslines=buslines)
print(f"t equals: {t} minutes")
assert 600691418730595 == t
return True
def main():
config = Config(day=1)
path_file = os.path.join(config.path_data, "expense_report.txt")
with open(path_file, "r") as f:
data = [int(value.strip("\n")) for value in f.readlines()]
for group_size in [2, 3]:
group_2020 = next(get_2020_groups(lst=data, group_size=group_size))
if group_2020:
print(
f"Multiplying the group of size {group_size} which sum equals to 2020 {group_2020} gives: "
f"{multiply(group_2020)}")
return True
def main():
config = Config(day=18)
path_homework = os.path.join(config.path_data, "homework.txt")
# PART ONE
results = execute_homework(path_homework=path_homework,
solver=solve_math_expression_part_one)
print(f"The sum of the resulting values: {sum(results)}")
assert 131076645626 == sum(results)
# PART TWO
results = execute_homework(path_homework=path_homework,
solver=solve_math_expression_part_two)
print(f"The sum of the resulting values (PART TWO): {sum(results)}")
assert 109418509151782 == sum(results)
return True
def main():
config = Config(day=12)
# PART ONE
# Test one
path_data = os.path.join(config.path_data, "evasive_actions_test.txt")
evasive_actions_test = parse_puzzle_input(path_data=path_data)
coordinate_final = execute_actions(actions=evasive_actions_test,
location_init=[0, 0],
direction_init="E")
manhattan_distance = get_manhattan_distance(location=coordinate_final)
assert 25 == manhattan_distance
# Real deal
path_data = os.path.join(config.path_data, "evasive_actions.txt")
evasive_actions = parse_puzzle_input(path_data=path_data)
coordinate_final = execute_actions(actions=evasive_actions,
location_init=[0, 0],
direction_init="E")
manhattan_distance = get_manhattan_distance(location=coordinate_final)
print(
f"The manhattan distance of the final coordinate equals: {manhattan_distance}"
)
assert 2280 == manhattan_distance
# PART TWO
# Test
coordinate_final = execute_actions_two(actions=evasive_actions_test,
location_init=[0, 0],
waypoint_init=[10, 1])
manhattan_distance = get_manhattan_distance(location=coordinate_final)
assert manhattan_distance == 286
coordinate_final = execute_actions_two(actions=evasive_actions,
location_init=[0, 0],
waypoint_init=[10, 1])
manhattan_distance = get_manhattan_distance(location=coordinate_final)
print(
f"The manhattan distance of the final coordinate equals: {manhattan_distance}"
)
assert 38693 == manhattan_distance
return True
def main():
config = Config(day=5)
path_file = os.path.join(config.path_data, "boarding_passes.txt")
with open(path_file, "r") as f:
boarding_passes = [value.strip("\n") for value in f.readlines()]
print(f"The number of boarding passes equals: {len(boarding_passes)}")
boarding_passes_test = ["BFFFBBFRRR", "FFFBBBFRRR", "BBFFBBFRLL"]
row_indices = [*range(0, 128)]
column_indices = [*range(0, 8)]
for boarding_pass, row_number_exp, col_number_exp in zip(
boarding_passes_test, [70, 14, 102], [7, 7, 4]):
row, = get_row(row_sequence=boarding_pass[:7], row_indices=row_indices)
assert row_number_exp == row
column, = get_column(col_sequence=boarding_pass[7:],
col_indices=column_indices)
assert col_number_exp == column
seat_id = get_seat_id(row=row, column=column)
print(
f"Boardingpass {boarding_pass}, sits on row {row} and column {column}, with seat id {seat_id}"
)
seat_ids = []
for boarding_pass in boarding_passes:
row, = get_row(row_sequence=boarding_pass[:7], row_indices=row_indices)
column, = get_column(col_sequence=boarding_pass[7:],
col_indices=column_indices)
seat_ids.append(get_seat_id(row=row, column=column))
print(f"The seat with the highest seat ID equals: {max(seat_ids)}")
# PART TWO
missing_seat_ids = set(range(0, max(seat_ids))).difference(set(seat_ids))
for seat_id in missing_seat_ids:
if seat_id - 1 in seat_ids and seat_id + 1 in seat_ids:
print(f"Your seat ID: {seat_id}")
return True
def main():
config = Config(day=3)
path_test_file = os.path.join(config.path_data, "tree_map_test.txt")
slope = (1, 3)
with open(path_test_file, "r") as f:
data_test = [value.strip("\n") for value in f.readlines()]
tree_count = count_encountered_trees(tree_data=data_test, slope=slope)
assert tree_count == 7, f"The number of encountered trees in the test set != 7 but {tree_count}"
path_file = os.path.join(config.path_data, "day_3", "tree_map.txt")
with open(path_file, "r") as f:
data = [value.strip("\n") for value in f.readlines()]
# Part 1
tree_count = count_encountered_trees(tree_data=data, slope=slope)
print(
f"The total number of encountered trees with slope {slope} are: {tree_count}"
)
# Part 2
slopes = [(1, 1), (1, 3), (1, 5), (1, 7), (2, 1)]
tree_counts = []
tree_counts_test_exp = [2, 7, 3, 4, 2]
for slope, tree_count_exp in zip(slopes, tree_counts_test_exp):
tree_count_test = count_encountered_trees(tree_data=data_test,
slope=slope)
assert tree_count_test == tree_count_exp, f"Tree count != expected tree count. " \
f"{tree_count_test} != {tree_count_exp}"
tree_count = count_encountered_trees(tree_data=data, slope=slope)
tree_counts.append(tree_count)
print(
f"The total number of encountered trees with slope {slope} are: {tree_count}"
)
print(f"The product of all the tree counts is: {math.prod(tree_counts)}")
return True
def main():
config = Config(day=2)
path_file = os.path.join(config.path_data, "password_policies.txt")
with open(path_file, "r") as f:
data = [value.strip("\n") for value in f.readlines()]
valid_passwords_one = []
valid_passwords_two = []
for string in data:
policy, password = split_policy_and_password(string=string)
policy_integers, character = split_policy(policy=policy)
if is_valid_rule_one(character_count_range=policy_integers, character=character, password=password):
valid_passwords_one.append(string)
if is_valid_rule_two(character_indices_policy=policy_integers, character=character, password=password):
valid_passwords_two.append(string)
print(f"The number of valid passwords according to rule #1 is: {len(valid_passwords_one)}")
print(f"The number of valid passwords according to rule #2 is: {len(valid_passwords_two)}")
return True
def main():
config = Config(day=10)
# PART ONE
# Test one
path_data = os.path.join(config.path_data, "adapter_list_test_one.txt")
data_test_one = read_adapter_data(path_file=path_data)
result = compute_part_one(adapters=data_test_one)
assert 35 == result
# Test two
path_data = os.path.join(config.path_data, "adapter_list_test_two.txt")
data_test_two = read_adapter_data(path_file=path_data)
result = compute_part_one(adapters=data_test_two)
assert 220 == result
path_data = os.path.join(config.path_data, "adapter_list.txt")
data = read_adapter_data(path_file=path_data)
result = compute_part_one(adapters=data)
print(f"The number of 1 and 3 joltage differences multiplied equals: {result}")
assert 1876 == result
# PART TWO
# Test one
n_arrangements = get_adapter_arrangements(adapters=data_test_one)
assert 8 == n_arrangements
# Test two
n_arrangements = get_adapter_arrangements(adapters=data_test_two)
assert 19208 == n_arrangements
n_arrangements = get_adapter_arrangements(adapters=data)
print(f"The number of possible adapter arrangements equals: {n_arrangements}")
assert 14173478093824 == n_arrangements
return True
def main():
config = Config(day=16)
# Test
path_ticket_info = os.path.join(config.path_data, "ticket_info_test.txt")
error_rate = compute_error_rate(path_ticket_info=path_ticket_info)
assert 71 == error_rate
# Real deal
path_ticket_info = os.path.join(config.path_data, "ticket_info.txt")
error_rate = compute_error_rate(path_ticket_info=path_ticket_info)
print(f"The ticket scanning error rate equals: {error_rate}")
assert 24980 == error_rate
# PART TWO
# Test
path_ticket_info = os.path.join(config.path_data,
"ticket_info_test_two.txt")
notes, ticket_mine, tickets_nearby = parse_ticket_info(
path_file=path_ticket_info)
field_order = get_field_order(notes=notes, tickets_nearby=tickets_nearby)
assert ["row", "class", "seat"] == field_order
# Real deal
path_ticket_info = os.path.join(config.path_data, "ticket_info.txt")
notes, ticket_mine, tickets_nearby = parse_ticket_info(
path_file=path_ticket_info)
field_order = get_field_order(notes=notes, tickets_nearby=tickets_nearby)
fields_departure = [
i for i, f in enumerate(field_order) if "departure" in f
]
print(
f"The product of the departure fields equals: {prod([ticket_mine[i] for i in fields_departure])}"
)
assert 809376774329 == prod([ticket_mine[i] for i in fields_departure])
return True
def main():
"""
Stolen from
https://dev.to/qviper/advent-of-code-2020-python-solution-day-11-2lkj
"""
config = Config(day=11)
# PART ONE
# Test one
path_data = os.path.join(config.path_data, "seating_system.txt")
with open(path_data, "r") as fp:
lines = [line.rstrip() for line in fp.readlines()]
lines = [list(line) for line in lines]
rows, cols = len(lines), len(lines[0])
deltas = [(-1, -1), (-1, 0), (-1, 1), (0, -1), (0, 1), (1, -1), (1, 0), (1, 1)]
occupancy = check_occupied2(lines, deltas=deltas, rows=rows, cols=cols)
print(f"There are {occupancy} valid seats.")
def main():
config = Config(day=8)
# PART ONE
path_file_test = os.path.join(config.path_data, "boot_code_test.txt")
path_file = os.path.join(config.path_data, "boot_code.txt")
# Test set
data_test = read_txt_file(path_file=path_file_test)
print(f"The test boot code has {len(data_test)} lines")
infinite_loop, accumulator = execute_boot_code(boot_code=data_test)
assert infinite_loop, f"Execution of bootcode did not enter a infinite loop"
assert 5 == accumulator, f"Accumulator value is incorrect. 5 != {accumulator}"
data = read_txt_file(path_file=path_file)
print(f"The boot code has {len(data)} lines")
infinite_loop, accumulator = execute_boot_code(boot_code=data)
print(
f"The boot code accumulator equals {accumulator} before it hits an infinite loop"
)
assert infinite_loop, f"Execution of bootcode did not enter a infinite loop"
assert 1939 == accumulator, f"Accumulator value is incorrect. 1939 != {accumulator}"
# PART TWO
infinite_loop, accumulator, boot_code = fix_boot_code(boot_code=data_test)
assert not infinite_loop
assert 8 == accumulator, f"Accumulator value is incorrect. 8 != {accumulator}"
infinite_loop, accumulator, boot_code = fix_boot_code(boot_code=data)
assert not infinite_loop
print(
f"The fixed boot code accumulator equals {accumulator} after running until termination"
)
assert 2212 == accumulator, f"Accumulator value is incorrect. 2212 != {accumulator}"
return True
