I can assure you, the function
strcmp is ABSOLUTELY NOT the bottleneck. Typically, strcmp is well optimized and can do 32 or 64 bit comparisons for strings longer than 4/8 bytes depending on architecture. Both newlib and GNU libc do this. But even if you were to look at each byte in both strings 20 times, it doesn't matter as much as the algo & data structure choices made here.
The real bottle neck is the O(N) search algorithm. A single O(N log N) pass at the file could be used to at appropriate data structure (whether it's a normal BST, a trie, or just a simple sorted array) for doing O(log N) lookups.
Bear with me here--a lot of math follows. But I think this is a good opportunity to illustrate why choice of algorithm & data structure are sometimes FAR more important than method of string comparison. Steve touches on this, but I wanted to explain it in a little more depth.
With N=1e6, log(1e6, 2) = 19.9, so round up to 20 comparisons on an ideal data structure.
Currently you're doing a a worst case search of O(N), or 1e6 operations.
So say you just build a red-black tree with O(log N) insertion time, and you insert N items, that's O(N log N) time to build the tree. So that's 1e6 x 20 or 20e6 operations necessary to build your tree.
In your current approach, building the data structure is O(N), or 1e6 operations, but your worst case search time is O(N) as well. So by the time you read the file and do just 20 search operations, you're up to a theoretical worst case of 21,000,000 operations. By comparison, your worst case with a red-black tree and 20 searches is 20,000,400 operations, or 999,600 operations BETTER than the O(N) search on an unsorted array. So at 20 searches, you're at the first point where a more sophisticated data structure really pays off. But look at what happens at 1000 searches:
Unsorted array = initialization + 1000 x search time = O(N) + 1000 * O(N) = 1,000,000 + 2,000,000,000 = 2,001,000,000 operations.
Red-black = initialization + 1000 x search time = O(N log N) + 1000 * O(log N) = 20,000,000 + 20,000 = 20,020,000 operations.
2,001,000,000 / 20,020,000 ~= 100x as many operations for the O(N) search.
At 1e6 searches, that's (1e6 + 1e6 * 1e6) / (20e6 + 1e6 * 20 ) = 25,000x as many operations.
Assume your computer can handle the 40e6 'operations' it takes to do the log N searches in 1 minute. It would take 25,000 minutes, or 17 DAYS to do the same work with your current algorithm. Or another way to look at is that the O(N) search algorithm can only handle 39 searches in the time the O(log N) algorithm can do 1,000,000. And the more searches you do, the uglier it gets.
See responses from Steve and dirkgently for several better choices of data structures & algorithms. My only additional caution would be that
qsort() suggested by Steve might have a worst-case complexity of O(N*N), which is far, far, worse than the O(N log N) you get with a heapsort or various tree-like structures.