Difference between revisions of "Euler problems/61 to 70"
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a = map (^3) [0..10000] |
a = map (^3) [0..10000] |
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b = map (sort . show) a |
b = map (sort . show) a |
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| − | c = |
+ | c = filter ((==5) . length) . group . sort $ b |
| − | d = |
+ | Just d = elemIndex (head (head c)) b |
| − | problem_62 = |
+ | problem_62 = toInteger d^3 |
</haskell> |
</haskell> |
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| Line 58: | Line 58: | ||
import Data.List |
import Data.List |
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| − | problem_64 =length $ filter |
+ | problem_64 =length $ filter solve $ [2..9999] \\ (map (^2) [2..100]) |
solve n = even $ length $ cont n 0 1 |
solve n = even $ length $ cont n 0 1 |
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| Line 65: | Line 65: | ||
cont r n d = m : rest |
cont r n d = m : rest |
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where |
where |
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| − | m = truncate |
+ | m = (truncate (sqrt (fromIntegral r)) + n) `div` d |
a = n - d * m |
a = n - d * m |
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| − | rest |
+ | rest | d == 1 && n /= 0 = [] |
| − | + | | otherwise = cont r (-a) ((r - a ^ 2) `div` d) |
|
| − | else cont r (-a) ((r - a ^ 2) `div` d) |
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</haskell> |
</haskell> |
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| Line 80: | Line 79: | ||
import Data.Ratio |
import Data.Ratio |
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| − | e = |
+ | e = 2 : concat [ [1, 2*i, 1] | i <- [1..] ] |
fraction [x] = x%1 |
fraction [x] = x%1 |
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| Line 98: | Line 97: | ||
| otherwise = f n |
| otherwise = f n |
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where |
where |
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| − | f x |
+ | f x | y < x = f y |
| + | | otherwise = x |
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where y = (x + (n `quot` x)) `quot` 2 |
where y = (x + (n `quot` x)) `quot` 2 |
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problem_66 = |
problem_66 = |
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| Line 130: | Line 130: | ||
<haskell> |
<haskell> |
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problem_67 = readFile "triangle.txt" >>= print . solve . parse |
problem_67 = readFile "triangle.txt" >>= print . solve . parse |
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| + | |||
| + | parse :: String -> [[Int]] -- restrict output type for 'read' function |
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parse = map (map read . words) . lines |
parse = map (map read . words) . lines |
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| + | |||
| − | solve = head . foldr1 step |
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| + | solve = head . foldr1 step -- reverse pairewise addition from bottom to top |
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| − | step [] [z] = [z] |
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| + | step [] _ = [] -- returen empty list to avoid eception warning |
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step (x:xs) (y:z:zs) = x + max y z : step xs (z:zs) |
step (x:xs) (y:z:zs) = x + max y z : step xs (z:zs) |
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</haskell> |
</haskell> |
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| + | |||
| + | Alternatively, one could add lists pairewise from top to bottom. However, this would require a check on maximum in the list, after the final step of additions. |
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== [http://projecteuler.net/index.php?section=problems&id=68 Problem 68] == |
== [http://projecteuler.net/index.php?section=problems&id=68 Problem 68] == |
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| Line 144: | Line 149: | ||
permute [] = [[]] |
permute [] = [[]] |
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permute list = |
permute list = |
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| − | + | concatMap (\(x:xs) -> map (x:) (permute xs)) |
|
(take (length list) |
(take (length list) |
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| − | (unfoldr (\x -> Just ( |
+ | (unfoldr (\l@(x:xs) -> Just (l, xs ++ [x])) list)) |
problem_68 = |
problem_68 = |
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| − | maximum $ map ( |
+ | maximum $ map (concatMap show) poel |
where |
where |
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gon68 = [1..10] |
gon68 = [1..10] |
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knip = (length gon68) `div` 2 |
knip = (length gon68) `div` 2 |
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| − | (is,es) = splitAt knip gon68 |
+ | (is,e:es) = splitAt knip gon68 |
| − | extnodes = map ( |
+ | extnodes = map (e:) $ permute es |
| − | intnodes = map (\(p:ps) -> zipWith (\ x y -> [x |
+ | intnodes = map (\(p:ps) -> zipWith (\ x y -> [x, y]) |
(p:ps) (ps++[p])) $ permute is |
(p:ps) (ps++[p])) $ permute is |
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| − | poel = [ concat hs |
+ | poel = [ concat hs | |
| − | + | uitsteeksels <- extnodes, |
|
| + | organen <- intnodes, |
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| ⚫ | |||
| + | let hs = zipWith (:) uitsteeksels organen, |
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| + | let subsom = map sum hs, |
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| ⚫ | |||
</haskell> |
</haskell> |
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| Line 173: | Line 181: | ||
problem_69= |
problem_69= |
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maximum [c| |
maximum [c| |
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| − | + | b<-tail $ inits primes, |
|
| − | let b=take a primes, |
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let c=product b, |
let c=product b, |
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c<10^6 |
c<10^6 |
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| Line 188: | Line 195: | ||
<haskell> |
<haskell> |
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import Data.List |
import Data.List |
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| + | import Data.Function |
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| − | isPerm a b = |
+ | isPerm a b = null $ show a \\ show b |
flsqr n x=x<(floor.sqrt.fromInteger) n |
flsqr n x=x<(floor.sqrt.fromInteger) n |
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pairs n1 = |
pairs n1 = |
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| − | + | fst . minimumBy (compare `on` fn) $ [(m,pm)|a<-gena,b<-genb,let m=a*b,n>m,let pm=m-a-b+1,isPerm m pm] |
|
where |
where |
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n=fromInteger n1 |
n=fromInteger n1 |
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gena = dropWhile (flsqr n)$ takeWhile (flsqr (2*n)) primes |
gena = dropWhile (flsqr n)$ takeWhile (flsqr (2*n)) primes |
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| − | genb = dropWhile (flsqr ( |
+ | genb = dropWhile (flsqr (n `div` 2))$ takeWhile (flsqr n) primes |
| + | fn (x,px) = fromIntegral x / (fromIntegral px) |
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problem_70= pairs (10^7) |
problem_70= pairs (10^7) |
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Latest revision as of 10:20, 18 May 2022
Problem 61
Find the sum of the only set of six 4-digit figurate numbers with a cyclic property.
Solution:
import Data.List
permute [] = [[]]
permute xs = concatMap (\x -> map (x:) $ permute $ delete x xs) xs
figurates n xs = extract $ concatMap (gather (map poly xs)) $ map (:[]) $ poly n
where gather [xs] (v:vs)
= let v' = match xs v
in if v' == [] then [] else map (:v:vs) v'
gather (xs:xss) (v:vs)
= let v' = match xs v
in if v' == [] then [] else concatMap (gather xss) $ map (:v:vs) v'
match xs (_,v) = let p = (v `mod` 100)*100 in sublist (p+10,p+100) xs
sublist (s,e) = takeWhile (\(_,x) -> x<e) . dropWhile (\(_,x) -> x<s)
link ((_,x):xs) = x `mod` 100 == (snd $ last xs) `div` 100
diff (x:y:xs) = if fst x /= fst y then diff (y:xs) else False
diff [x] = True
extract = filter diff . filter link
poly m = [(n, x) | (n, x) <- zip [1..] $ takeWhile (<10000)
$ scanl (+) 1 [m-1,2*m-3..],
1010 < x, x `mod` 100 > 9]
problem_61 = sum $ map snd $ head $ concatMap (figurates 3) $ permute [4..8]
Problem 62
Find the smallest cube for which exactly five permutations of its digits are cube.
Solution:
import Data.List
import Data.Maybe
a = map (^3) [0..10000]
b = map (sort . show) a
c = filter ((==5) . length) . group . sort $ b
Just d = elemIndex (head (head c)) b
problem_62 = toInteger d^3
Problem 63
How many n-digit positive integers exist which are also an nth power?
Solution:
problem_63=length[x^y|x<-[1..9],y<-[1..22],y==(length$show$x^y)]
Problem 64
How many continued fractions for N ≤ 10000 have an odd period?
Solution:
import Data.List
problem_64 =length $ filter solve $ [2..9999] \\ (map (^2) [2..100])
solve n = even $ length $ cont n 0 1
cont :: Int -> Int -> Int -> [Int]
cont r n d = m : rest
where
m = (truncate (sqrt (fromIntegral r)) + n) `div` d
a = n - d * m
rest | d == 1 && n /= 0 = []
| otherwise = cont r (-a) ((r - a ^ 2) `div` d)
Problem 65
Find the sum of digits in the numerator of the 100th convergent of the continued fraction for e.
Solution:
import Data.Char
import Data.Ratio
e = 2 : concat [ [1, 2*i, 1] | i <- [1..] ]
fraction [x] = x%1
fraction (x:xs) = x%1 + 1/(fraction xs)
problem_65 = sum $ map digitToInt $ show $ numerator $ fraction $ take 100 e
Problem 66
Investigate the Diophantine equation x2 − Dy2 = 1.
Solution:
intSqrt :: Integral a => a -> a
intSqrt n
| n < 0 = error "intSqrt: negative n"
| otherwise = f n
where
f x | y < x = f y
| otherwise = x
where y = (x + (n `quot` x)) `quot` 2
problem_66 =
snd$maximum [ (x,d) |
d <- [1..1000],
let b = intSqrt d,
b*b /= d, -- d can't be a perfect square
let (x,_) = pell d b b
]
pell d wd b = piter d wd b 0 1 0 1 1 0
piter d wd b i c l k m n
| cn == 1 = (x, y)
| otherwise = piter d wd bn (i+1) cn k u n v
where
yb = (wd+b) `div` c
bn = yb*c-b
cn = (d-(bn*bn)) `div` c
yn | i == 0 = wd
| otherwise = yb
u = k*yn+l -- u/v is the i-th convergent of sqrt(d)
v = n*yn+m
(x,y) | odd (i+1) = (u*u+d*v*v, 2*u*v)
| otherwise = (u,v)
Problem 67
Using an efficient algorithm find the maximal sum in the triangle?
Solution:
problem_67 = readFile "triangle.txt" >>= print . solve . parse
parse :: String -> [[Int]] -- restrict output type for 'read' function
parse = map (map read . words) . lines
solve = head . foldr1 step -- reverse pairewise addition from bottom to top
step [] _ = [] -- returen empty list to avoid eception warning
step (x:xs) (y:z:zs) = x + max y z : step xs (z:zs)
Alternatively, one could add lists pairewise from top to bottom. However, this would require a check on maximum in the list, after the final step of additions.
Problem 68
What is the maximum 16-digit string for a "magic" 5-gon ring?
Solution:
import Data.List
permute [] = [[]]
permute list =
concatMap (\(x:xs) -> map (x:) (permute xs))
(take (length list)
(unfoldr (\l@(x:xs) -> Just (l, xs ++ [x])) list))
problem_68 =
maximum $ map (concatMap show) poel
where
gon68 = [1..10]
knip = (length gon68) `div` 2
(is,e:es) = splitAt knip gon68
extnodes = map (e:) $ permute es
intnodes = map (\(p:ps) -> zipWith (\ x y -> [x, y])
(p:ps) (ps++[p])) $ permute is
poel = [ concat hs |
uitsteeksels <- extnodes,
organen <- intnodes,
let hs = zipWith (:) uitsteeksels organen,
let subsom = map sum hs,
length (nub subsom) == 1 ]
Problem 69
Find the value of n ≤ 1,000,000 for which n/φ(n) is a maximum.
Solution:
{-phi(n) = n*(1-1/p1)*(1-1/p2)*...*(1-1/pn)
n/phi(n) = 1/(1-1/p1)*(1-1/p2)*...*(1-1/pn)
(1-1/p) will be minimal for a small p and 1/(1-1/p) will then be maximal
-}
primes=[2,3,5,7,11,13,17,19,23]
problem_69=
maximum [c|
b<-tail $ inits primes,
let c=product b,
c<10^6
]
Note: credit for arithmetic functions is due to David Amos.
Problem 70
Investigate values of n for which φ(n) is a permutation of n.
Solution:
import Data.List
import Data.Function
isPerm a b = null $ show a \\ show b
flsqr n x=x<(floor.sqrt.fromInteger) n
pairs n1 =
fst . minimumBy (compare `on` fn) $ [(m,pm)|a<-gena,b<-genb,let m=a*b,n>m,let pm=m-a-b+1,isPerm m pm]
where
n=fromInteger n1
gena = dropWhile (flsqr n)$ takeWhile (flsqr (2*n)) primes
genb = dropWhile (flsqr (n `div` 2))$ takeWhile (flsqr n) primes
fn (x,px) = fromIntegral x / (fromIntegral px)
problem_70= pairs (10^7)