I'm a little bit confused. How is the problem of generating permutations in Lexicographic Order any different from the problem of sorting? Can someone please explain it to me with an example? Thanks
These are two different things. There are Here is an example of a sorted permutation:
Here is a list of permutations in lexicographic order:
Here is a program in C++ to generate permutations in lexicographic order:






There's a fairly easy way to generate the nth permutation in lexicographic order. The set of choices you make in selecting the permutation elements are: pick 1 of N, then 1 of N1, then 1 of N2, ... then 1 of 2, and finally there's just one left. Those choices, as index values into a running "what's left" list, can be looked at as a variablebase number. You can develop the digits from right to left as d[1] = n%2, d[2] = (n/2)%3, d[3] = (n/6)%4, ... d[k] = (n/k!) % (k+1). The result has d[N1]==0 for the first (N1)! permutations, d[N1]==1 for the next (N1)!, and so on. You can see that these index values will be in lex. order. Then choose the symbols out of your sorted set (Any randomaccess collection will do if syms[0], syms[1], ... are in the order you want.) Here's some code I whipped up for working on Project Euler problems. It just generates the index values, and allows for choosing permutations of k symbols out of n. The header file defaults k to 1, and the argument check code converts this to n and generates full length permutations. There's also a change of notation here: "index" is the number of the permutation ("n" above) and "n" is the set size ("N" above).



One way that they could relate is if you generate Permutations that are not in lexicographic order then you sort to get it in lexicographical order. This however would require to have factorial space. Generation usually spits out one element at a time therefore not having to have all elements in memory. 

