2023 day 21, version 2.

This commit is contained in:
Mikaël Capelle 2023-12-21 21:56:38 +01:00
parent 9326d6c76c
commit 85fff24cc1

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@ -39,8 +39,7 @@ print(f"answer 1 is {answer_1}")
# rhombus every n steps # rhombus every n steps
# #
# we are going to find the number of cells reached for the initial rhombus, n steps # we are going to find the number of cells reached for the initial rhombus, n steps
# after and n * 2 steps after, and then interpolate the value to get a 2nd order # after and n * 2 steps after
# polynomial
# #
cycle = len(map) cycle = len(map)
rhombus = (len(map) - 3) // 2 + 1 rhombus = (len(map) - 3) // 2 + 1
@ -56,9 +55,9 @@ if logging.root.getEffectiveLevel() == logging.INFO:
rows = [ rows = [
[ [
map[i % n_rows][j % n_cols] if (i, j) not in tiles else "O" map[i % n_rows][j % n_cols] if (i, j) not in tiles else "O"
for j in range(-2 * cycle, 3 * cycle + 1) for j in range(-2 * cycle, 3 * cycle)
] ]
for i in range(-2 * cycle, 3 * cycle + 1) for i in range(-2 * cycle, 3 * cycle)
] ]
for i in range(len(rows)): for i in range(len(rows)):
@ -71,6 +70,64 @@ if logging.root.getEffectiveLevel() == logging.INFO:
logging.info(f"values to fit: {values}") logging.info(f"values to fit: {values}")
# version 1:
#
# after 3 cycles, the figure looks like the following:
#
# I M D
# I J A K D
# H A F A L
# C E A K B
# C G B
#
# after 4 cycles, the figure looks like the following:
#
# I M D
# I J A K D
# I J A B A K D
# H A B A B A L
# C E A B A N F
# C E A N F
# C G F
#
# the 'radius' of the rhombus is the number of cycles minus 1
#
# the 4 'corner' (M, H, L, G) are counted once, the blocks with a corner triangle (D, I,
# C, B) are each counted radius times, the blocks with everything but one corner (J, K,
# E, N) are each counted radius - 1 times
#
# there are two versions of the whole block, A and B in the above (or odd and even),
# depending on the number of cycles, either A or B will be in the center
#
counts = [
[
sum(
(i, j) in tiles
for i in range(ci * cycle, (ci + 1) * cycle)
for j in range(cj * cycle, (cj + 1) * cycle)
)
for cj in range(-2, 3)
]
for ci in range(-2, 3)
]
radius = (26501365 - rhombus) // cycle - 1
A = counts[2][2] if radius % 2 == 0 else counts[2][1]
B = counts[2][2] if radius % 2 == 1 else counts[2][1]
answer_2 = (
(radius + 1) * A
+ radius * B
+ 2 * radius * (radius + 1) // 2 * A
+ 2 * radius * (radius - 1) // 2 * B
+ sum(counts[i][j] for i, j in ((0, 2), (-1, 2), (2, 0), (2, -1)))
+ sum(counts[i][j] for i, j in ((0, 1), (0, 3), (-1, 1), (-1, 3))) * (radius + 1)
+ sum(counts[i][j] for i, j in ((1, 1), (1, 3), (-2, 1), (-2, 3))) * radius
)
print(f"answer 2 (v1) is {answer_2}")
# version 2: fitting a polynomial
#
# the value we are interested in (26501365) can be written as R + K * C where R is the # the value we are interested in (26501365) can be written as R + K * C where R is the
# step at which we find the first rhombus, and K the repeat step, so instead of fitting # step at which we find the first rhombus, and K the repeat step, so instead of fitting
# for X values (R, R + K, R + 2 K), we are going to fit for (0, 1, 2), giving us much # for X values (R, R + K, R + 2 K), we are going to fit for (0, 1, 2), giving us much
@ -89,4 +146,4 @@ a, b, c = (y1 + y3) // 2 - y2, 2 * y2 - (3 * y1 + y3) // 2, y1
n = (26501365 - rhombus) // cycle n = (26501365 - rhombus) // cycle
answer_2 = a * n * n + b * n + c answer_2 = a * n * n + b * n + c
print(f"answer 2 is {answer_2}") print(f"answer 2 (v2) is {answer_2}")