# Euler problems/41 to 50

## Contents

## Problem 41

What is the largest n-digit pandigital prime that exists?

Solution:

```
import Data.List
isprime a = isprimehelper a primes
isprimehelper a (p:ps)
| a == 1 = False
| p*p > a = True
| a `mod` p == 0 = False
| otherwise = isprimehelper a ps
primes = 2 : filter isprime [3,5..]
problem_41 =
head.filter isprime.filter fun $ [7654321,7654320..]
where
fun =(=="1234567").sort.show
```

## Problem 42

How many triangle words can you make using the list of common English words?

Solution:

```
import Data.Char
trilist = takeWhile (<300) (scanl1 (+) [1..])
wordscore xs = sum $ map (subtract 64 . ord) xs
problem_42 megalist=
length [ wordscore a |
a <- megalist,
elem (wordscore a) trilist
]
main=do
f<-readFile "words.txt"
let words=read $"["++f++"]"
print $problem_42 words
```

## Problem 43

Find the sum of all pandigital numbers with an unusual sub-string divisibility property.

Solution:

```
import Data.List
l2n :: (Integral a) => [a] -> a
l2n = foldl' (\a b -> 10*a+b) 0
swap (a,b) = (b,a)
explode :: (Integral a) => a -> [a]
explode =
unfoldr (\a -> if a==0 then Nothing else Just $ swap $ quotRem a 10)
problem_43 = sum . map l2n . map (\s -> head ([0..9] \\ s):s)
. filter (elem 0) . genSeq [] $ [17,13,11,7,5,3,2]
mults mi ma n = takeWhile (< ma) $ dropWhile (<mi) $ iterate (+n) n
sequ xs ys = tail xs == init ys
addZ n xs = replicate (n - length xs) 0 ++ xs
genSeq [] (x:xs) = genSeq
(filter (not . doub)
$ map (addZ 3 . reverse . explode) $ mults 9 1000 x)
xs
genSeq ys (x:xs) =
genSeq (do
m <- mults 9 1000 x
let s = addZ 3 . reverse . explode $ m
y <- filter (sequ s . take 3) $ filter (not . elem (head s)) ys
return (head s:y)
) xs
genSeq ys [] = ys
doub xs = nub xs /= xs
```

## Problem 44

Find the smallest pair of pentagonal numbers whose sum and difference is pentagonal.

Solution:

```
import Data.Set
problem_44 =
head solutions
where
solutions =
[a-b |
a <- penta,
b <- takeWhile (<a) penta,
isPenta (a-b),
isPenta (b+a)
]
isPenta = (`member` fromList penta)
penta = [(n * (3*n-1)) `div` 2 | n <- [1..5000]]
```

## Problem 45

After 40755, what is the next triangle number that is also pentagonal and hexagonal?

Solution:

```
isPent n =
(af == 0) && ai `mod` 6 == 5
where
(ai, af) = properFraction $ sqrt $ 1 + 24 * (fromInteger n)
problem_45 = head [x | x <- scanl (+) 1 [5,9..], x > 40755, isPent x]
```

## Problem 46

What is the smallest odd composite that cannot be written as the sum of a prime and twice a square?

Solution:

This solution is inspired by exercise 3.70 in *Structure and Interpretation of Computer Programs*, (2nd ed.).

millerRabinPrimality on the Prime_numbers page

```
import Data.List
isPrime x
|x==3=True
|otherwise=millerRabinPrimality x 2
problem_46 =
find (\x -> not (isPrime x) && check x) [3,5..]
where
check x =
not $ any isPrime $takeWhile (>0) $ map (\y -> x - 2 * y * y) [1..]
```

## Problem 47

Find the first four consecutive integers to have four distinct primes factors.

Solution:

```
import Data.List
problem_47 = find (all ((==4).snd)) . map (take 4) . tails
. zip [1..] . map (length . factors) $ [1..]
fstfac x = [(head a ,length a)|a<-group$primeFactors x]
fac [(x,y)]=[x^a|a<-[0..y]]
fac (x:xs)=[a*b|a<-fac [x],b<-fac xs]
factors x=fac$fstfac x
primes = 2 : filter ((==1) . length . primeFactors) [3,5..]
primeFactors n = factor n primes
where
factor _ [] = []
factor m (p:ps) | p*p > m = [m]
| m `mod` p == 0 = p : [m `div` p]
| otherwise = factor m ps
```

## Problem 48

Find the last ten digits of 1^{1} + 2^{2} + ... + 1000^{1000}.

Solution: If the problem were more computationally intensive, modular exponentiation might be appropriate. With this problem size the naive approach is sufficient.

powMod on the Prime_numbers page

```
problem_48 = flip mod limit$sum [powMod limit n n | n <- [1..1000]]
where
limit=10^10
```

## Problem 49

Find arithmetic sequences, made of prime terms, whose four digits are permutations of each other.

Solution: millerRabinPrimality on the Prime_numbers page

```
import Control.Monad
import Data.List
isPrime x
|x==3=True
|otherwise=millerRabinPrimality x 2
primes4 = takeWhile (<10000) $ dropWhile (<1000) primes
problem_49 = do
a <- primes4
b <- dropWhile (<= a) primes4
guard ((sort $ show a) == (sort $ show b))
let c = 2 * b - a
guard (c < 10000)
guard ((sort $ show a) == (sort $ show c))
guard $ isPrime c
return (a, b, c)
primes = 2 : filter (\x -> isPrime x ) [3..]
```

## Problem 50

Which prime, below one-million, can be written as the sum of the most consecutive primes?

Solution: (prime and isPrime not included)

```
import Control.Monad
findPrimeSum ps
| isPrime sumps = Just sumps
| otherwise = findPrimeSum (tail ps) `mplus` findPrimeSum (init ps)
where
sumps = sum ps
problem_50 = findPrimeSum $ take 546 primes
```