mirror of
https://github.com/TheAlgorithms/Python.git
synced 2024-12-01 00:41:09 +00:00
106 lines
4.1 KiB
Python
106 lines
4.1 KiB
Python
|
"""
|
|||
|
Project Euler Problem 86: https://projecteuler.net/problem=86
|
|||
|
|
|||
|
A spider, S, sits in one corner of a cuboid room, measuring 6 by 5 by 3, and a fly, F,
|
|||
|
sits in the opposite corner. By travelling on the surfaces of the room the shortest
|
|||
|
"straight line" distance from S to F is 10 and the path is shown on the diagram.
|
|||
|

|
|||
|
However, there are up to three "shortest" path candidates for any given cuboid and the
|
|||
|
shortest route doesn't always have integer length.
|
|||
|
|
|||
|
It can be shown that there are exactly 2060 distinct cuboids, ignoring rotations, with
|
|||
|
integer dimensions, up to a maximum size of M by M by M, for which the shortest route
|
|||
|
has integer length when M = 100. This is the least value of M for which the number of
|
|||
|
solutions first exceeds two thousand; the number of solutions when M = 99 is 1975.
|
|||
|
|
|||
|
Find the least value of M such that the number of solutions first exceeds one million.
|
|||
|
|
|||
|
Solution:
|
|||
|
Label the 3 side-lengths of the cuboid a,b,c such that 1 <= a <= b <= c <= M.
|
|||
|
By conceptually "opening up" the cuboid and laying out its faces on a plane,
|
|||
|
it can be seen that the shortest distance between 2 opposite corners is
|
|||
|
sqrt((a+b)^2 + c^2). This distance is an integer if and only if (a+b),c make up
|
|||
|
the first 2 sides of a pythagorean triplet.
|
|||
|
|
|||
|
The second useful insight is rather than calculate the number of cuboids
|
|||
|
with integral shortest distance for each maximum cuboid side-length M,
|
|||
|
we can calculate this number iteratively each time we increase M, as follows.
|
|||
|
The set of cuboids satisfying this property with maximum side-length M-1 is a
|
|||
|
subset of the cuboids satisfying the property with maximum side-length M
|
|||
|
(since any cuboids with side lengths <= M-1 are also <= M). To calculate the
|
|||
|
number of cuboids in the larger set (corresponding to M) we need only consider
|
|||
|
the cuboids which have at least one side of length M. Since we have ordered the
|
|||
|
side lengths a <= b <= c, we can assume that c = M. Then we just need to count
|
|||
|
the number of pairs a,b satisfying the conditions:
|
|||
|
sqrt((a+b)^2 + M^2) is integer
|
|||
|
1 <= a <= b <= M
|
|||
|
|
|||
|
To count the number of pairs (a,b) satisfying these conditions, write d = a+b.
|
|||
|
Now we have:
|
|||
|
1 <= a <= b <= M => 2 <= d <= 2*M
|
|||
|
we can actually make the second equality strict,
|
|||
|
since d = 2*M => d^2 + M^2 = 5M^2
|
|||
|
=> shortest distance = M * sqrt(5)
|
|||
|
=> not integral.
|
|||
|
a + b = d => b = d - a
|
|||
|
and a <= b
|
|||
|
=> a <= d/2
|
|||
|
also a <= M
|
|||
|
=> a <= min(M, d//2)
|
|||
|
|
|||
|
a + b = d => a = d - b
|
|||
|
and b <= M
|
|||
|
=> a >= d - M
|
|||
|
also a >= 1
|
|||
|
=> a >= max(1, d - M)
|
|||
|
|
|||
|
So a is in range(max(1, d - M), min(M, d // 2) + 1)
|
|||
|
|
|||
|
For a given d, the number of cuboids satisfying the required property with c = M
|
|||
|
and a + b = d is the length of this range, which is
|
|||
|
min(M, d // 2) + 1 - max(1, d - M).
|
|||
|
|
|||
|
In the code below, d is sum_shortest_sides
|
|||
|
and M is max_cuboid_size.
|
|||
|
|
|||
|
|
|||
|
"""
|
|||
|
|
|||
|
|
|||
|
from math import sqrt
|
|||
|
|
|||
|
|
|||
|
def solution(limit: int = 1000000) -> int:
|
|||
|
"""
|
|||
|
Return the least value of M such that there are more than one million cuboids
|
|||
|
of side lengths 1 <= a,b,c <= M such that the shortest distance between two
|
|||
|
opposite vertices of the cuboid is integral.
|
|||
|
>>> solution(100)
|
|||
|
24
|
|||
|
>>> solution(1000)
|
|||
|
72
|
|||
|
>>> solution(2000)
|
|||
|
100
|
|||
|
>>> solution(20000)
|
|||
|
288
|
|||
|
"""
|
|||
|
num_cuboids: int = 0
|
|||
|
max_cuboid_size: int = 0
|
|||
|
sum_shortest_sides: int
|
|||
|
|
|||
|
while num_cuboids <= limit:
|
|||
|
max_cuboid_size += 1
|
|||
|
for sum_shortest_sides in range(2, 2 * max_cuboid_size + 1):
|
|||
|
if sqrt(sum_shortest_sides ** 2 + max_cuboid_size ** 2).is_integer():
|
|||
|
num_cuboids += (
|
|||
|
min(max_cuboid_size, sum_shortest_sides // 2)
|
|||
|
- max(1, sum_shortest_sides - max_cuboid_size)
|
|||
|
+ 1
|
|||
|
)
|
|||
|
|
|||
|
return max_cuboid_size
|
|||
|
|
|||
|
|
|||
|
if __name__ == "__main__":
|
|||
|
print(f"{solution() = }")
|