Donald Knuth has written the paper A Structured Program to Generate all Topological Sorting Arrangements. This paper was originally pupblished in 1974. The following quote from the paper brought me to a better understanding of the problem (in the text the relation i < j stands for "i precedes j"):

A natural way to solve this problem is to let x_{1} be an
element having no predecessors, then to erase all relations of the
from x_{1} < j and to let x_{2} be an element ≠
x_{1} with no predecessors in the system as it now exists,
then to erase all relations of the from x_{2} < j , etc. It is
not difficult to verify that this method will always succeed unless
there is an oriented cycle in the input. Moreover, in a sense it is
the **only** way to proceed, since x_{1} must be an element
without predecessors, and x_{2} must be without predecessors
when all relations x_{1} < j are deleted, etc. This
observation leads naturally to an algorithm that finds **all**
solutions to the topological sorting problem; it is a typical example
of a "backtrack" procedure, where at every stage we consider a
subproblem of the from "Find all ways to complete a given partial
permutation x_{1}x_{2}...x_{k} to a
topological sort x_{1}x_{2}...x_{n} ." The
general method is to branch on all possible choices of
x_{k+1}.

A central problem in backtrack applications is
to find a suitable way to arrange the data so that it is easy to
sequence through the possible choices of x_{k+1} ; in this
case we need an efficient way to discover the set of all elements ≠
{x_{1},...,x_{k}} which have no predecessors other
than x_{1},...,x_{k}, and to maintain this knowledge
efficiently as we move from one subproblem to another.

The paper includes a pseudocode for a efficient algorithm. The time complexity for each output is O(m+n), where m ist the number of input relations and n is the number of letters. I have written a C++ program, that implements the algorithm described in the paper – maintaining variable and function names –, which takes the letters and relations from your question as input. I hope that nobody complains about giving the program to this answer – because of the language-agnostic tag.

```
#include <iostream>
#include <deque>
#include <vector>
#include <iterator>
#include <map>
// Define Input
static const char input[] =
{ 'A', 'D', 'G', 'H', 'B', 'C', 'F', 'M', 'N' };
static const char crel[][2] =
{{'A', 'B'}, {'B', 'F'}, {'G', 'H'}, {'D', 'F'}, {'M', 'N'}};
static const int n = sizeof(input) / sizeof(char);
static const int m = sizeof(crel) / sizeof(*crel);
std::map<char, int> count;
std::map<char, int> top;
std::map<int, char> suc;
std::map<int, int> next;
std::deque<char> D;
std::vector<char> buffer;
void alltopsorts(int k)
{
if (D.empty())
return;
char base = D.back();
do
{
char q = D.back();
D.pop_back();
buffer[k] = q;
if (k == (n - 1))
{
for (std::vector<char>::const_iterator cit = buffer.begin();
cit != buffer.end(); ++cit)
std::cout << (*cit);
std::cout << std::endl;
}
// erase relations beginning with q:
int p = top[q];
while (p >= 0)
{
char j = suc[p];
count[j]--;
if (!count[j])
D.push_back(j);
p = next[p];
}
alltopsorts(k + 1);
// retrieve relations beginning with q:
p = top[q];
while (p >= 0)
{
char j = suc[p];
if (!count[j])
D.pop_back();
count[j]++;
p = next[p];
}
D.push_front(q);
}
while (D.back() != base);
}
int main()
{
// Prepare
std::fill_n(std::back_inserter(buffer), n, 0);
for (int i = 0; i < n; i++) {
count[input[i]] = 0;
top[input[i]] = -1;
}
for (int i = 0; i < m; i++) {
suc[i] = crel[i][1]; next[i] = top[crel[i][0]];
top[crel[i][0]] = i; count[crel[i][1]]++;
}
for (std::map<char, int>::const_iterator cit = count.begin();
cit != count.end(); ++cit)
if (!(*cit).second)
D.push_back((*cit).first);
alltopsorts(0);
}
```

`n!`

, either. It sounds like`m*n^2 * n!`

, where`m`

is the number of rules, although you don't really specify how you would validate each one. – jswolf19 Sep 2 '11 at 10:27`n!`

for the simple reason that if the input is a single word`ABCDE`

then all`5!`

orderings are possible, so you have to output them all. But you can hope to do "better" than`n!`

by some term that depends what constraints are imposed, accepting that the term is`O(bupkis)`

for some inputs. In the best case, where the input is 5 one-letter words,`A B C D E`

then we should be able to answer pretty quickly. – Steve Jessop Sep 2 '11 at 10:37