You are given a integer N which fits in long(less than 2^631) and 50 other integers. Your task is to find how many numbers from 1 to N contain none of the 50 numbers as its substring?
This question is from an interview.
You are given a integer N which fits in long(less than 2^631) and 50 other integers. Your task is to find how many numbers from 1 to N contain none of the 50 numbers as its substring? This question is from an interview. 


You didn't specify a base, but I'll assume decimal without loss of generality. First, recognize that this is a string problem, not a numeric one. Build a finite automaton A to recognize the 50 integers as substrings of other strings. E.g., the two integers 44 and 3 are recognized as substrings by the RE
Build a finite automaton B to recognize all numbers less than N. E.g., to recognize 1 through 27 (inclusive) in decimal, that can be achieved by compiling the RE
Compute the intersection C of the automata A and B, which is in turn an FA. Use a dynamic programming algorithm to compute the size of the language recognized by C. Subtract that from the size of the language recognized by A, computed by the same algorithm. (I am not claiming that this is asymptotically optimal, but it was a fast enough to solve lots of Project Euler problems :) 


This is only an explanation of what larsmans already wrote. If you like this answer, please vote him up in addition. A finite automaton, FA, is just a set of states, and rules saying that if you are in state Now there is a wellknown algorithm for converting a regular expression into a finite automaton that matches a string if and only if that regular expression matches. (If you've read about regular expressions, this is how DFA engines work.) To illustrate I'll use the pattern First let's label all of the positions we can be in in the regular expression when we're looking for the next character: The states of our regular expression engine will be subsets of those positions, and the special state matched. The result of a state transition will be the set of states we could get to if we were at that position, and saw a particular character. Our starting position is at the start of the RE, which is {A}. Here are the states that can be reached:
Here are the transition rules:
Now if you take any string, start that in state We can do this with any regular expression. For instance
and transitions:
OK, so we know what a regular expression is, what a finite automaton, and how they relate. What is the intersection of two finite automata? It is just a finite automaton that matches when both finite automata individually match, and otherwise fails to match. It is easy to construct, its set of states is just the set of pairs of a state in the one, and a state in the other. Its transition rule is to just apply the transition rule for each member independently, if either fails the whole does, if both match they both do. For the above pair, let's actually execute the intersection on the number
And then on the number
Now we come to the whole point of this. Given that final finite automata, we can use dynamic programming to figure out how many strings there are that match it. Here is that calculation:
OK, that's a lot of work, but we found that there are 3 strings that match both of those rules simultaneously. And we did it in a way that is automatable and scaleable to much larger numbers. Of course the question we were originally posed was how many matched the second but not the first. Well we know that 27 match the second rule, 3 match both, so 24 must match the second rule but not the first. As I said before, this is just larsmans solution elucidated. If you learned something, upvote him, vote for his answer. If this material sounds interesting, go buy a book like Progamming Language Pragmatics and learn a lot more about finite automata, parsing, compilation, and the like. It is a very good skillset to have, and far too many programmers don't. 

