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The number 145 is well known for the property that the sum of the factorial of its digits is equal to 145:

~~~
1! + 4! + 5! = 1 + 24 + 120 = 145
~~~

Perhaps less well known is 169, in that it produces the longest chain of numbers that link back to 169;
it turns out that there are only three such loops that exist:

~~~
169 -> 363601 -> 1454 -> 169
871 -> 45361 -> 871
872 -> 45362 -> 872
~~~

It is not difficult to prove that EVERY starting number will eventually get stuck in a loop. For example,

~~~
69 -> 363600 -> 1454 -> 169 -> 363601 (-> 1454)
78 -> 45360 -> 871 -> 45361 (-> 871)
540 -> 145 (-> 145)
~~~

Starting with 69 produces a chain of five non-repeating terms,
but the longest non-repeating chain with a starting number below one million is sixty terms.

How many chains, with a starting number below one million, contain exactly sixty non-repeating terms?
statics data 2017-11-08 17:39:50 +01:00			`The number 145 is well known for the property that the sum of the factorial of its digits is equal to 145:`

			`~~~`
			`1! + 4! + 5! = 1 + 24 + 120 = 145`
			`~~~`

			`Perhaps less well known is 169, in that it produces the longest chain of numbers that link back to 169;`
			`it turns out that there are only three such loops that exist:`

			`~~~`
			`169 -> 363601 -> 1454 -> 169`
			`871 -> 45361 -> 871`
			`872 -> 45362 -> 872`
			`~~~`

			`It is not difficult to prove that EVERY starting number will eventually get stuck in a loop. For example,`

			`~~~`
			`69 -> 363600 -> 1454 -> 169 -> 363601 (-> 1454)`
			`78 -> 45360 -> 871 -> 45361 (-> 871)`
			`540 -> 145 (-> 145)`
			`~~~`

			`Starting with 69 produces a chain of five non-repeating terms,`
			`but the longest non-repeating chain with a starting number below one million is sixty terms.`

			`How many chains, with a starting number below one million, contain exactly sixty non-repeating terms?`