As explained in several SO questions, and more abstractly at mathworld, the sequence of Catalan numbers happens to correspond to the number of parenthetical groupings that can be generated for any given number of operators. But I haven't found an algorithm to generate all these groupings.

This binary bracketing algorithm corresponds to the Tamari Lattice and can be described in a number of different ways. The most obvious practical use for this algorithm is to generate all possible expressions by every possible bracketing around binary operators and the numbers they operate on. This can be used to exhaustively test various types of operations on binary trees.

Web searching did reveal one implementation in C# but I think it would take me a while to understand as I don't know C# syntax.

So, what python code generates all the possible groupings of parenthesis around operators (which can thus be used with an actual expression to generate all the possibilities)? Output would look as follows for 2, 3, and 4:


  1. (x(xx))
  2. ((xx)x)


  1. (((xx)x)x)
  2. ((x(xx))x)
  3. ((xx)(xx))
  4. (x((xx)x))
  5. (x(x(xx)))


  1. (x(x(x(xx))))
  2. (x(x((xx)x)))
  3. (x((xx)(xx)))
  4. (x((x(xx))x))
  5. (x(((xx)x)x))
  6. ((xx)(x(xx)))
  7. ((xx)((xx)x))
  8. ((x(xx))(xx))
  9. (((xx)x)(xx))
  10. ((x(x(xx)))x)
  11. ((x((xx)x))x)
  12. (((xx)(xx))x)
  13. (((x(xx))x)x)
  14. ((((xx)x)x)x)

Even better would be code which did something like the following:



  1. 2+(3/4)
  2. (2+3)/4

How about

def allbinarytrees(s):
    if len(s) == 1:
        yield s
        for i in range(1, len(s), 2):
            for l in allbinarytrees(s[:i]):
                for r in allbinarytrees(s[i+1:]):
                    yield '({}{}{})'.format(l, s[i], r)

Sample usage:

for t in allbinarytrees('1+2-3*4/5'):


  • Very elegant. I'd like to understand why this works so I'll study it on my own. However, if you or anyone else can add some text to explain why this generates valid (but not invalid) trees - that would make this already good answer truly great. Thanks! – Joe Golton Jun 21 '13 at 19:17
  • 1
    @JoeGolton Trees are either a single (number) node, or an operator node with a left and a right subtree. The loop for i in range(1, len(s), 2): iterates through all possibilities for the root operator. for l in allbinarytrees(s[:i]): iterates through all parenthesizations of the numbers and operators to the left of the root. for r in allbinarytrees(s[i+1:]): iterates through all parenthesizations of the numbers and operators to the right of the root. – David Eisenstat Jun 21 '13 at 19:30
  • This solution assumes all numbers are single digit. What modification is needed to make it work for integers of any size? – Joe Golton Jun 21 '13 at 20:02
  • I modified your version to work for integers of any size, and posted as a separate answer. Though of greater practical value, it looks messier than yours so I'll leave your shorter and cleaner version as the accepted answer as it is easier to understand. – Joe Golton Jun 21 '13 at 21:05

The accepted answer only works for single digit numbers, and I will leave it as accepted answer because it illustrates the concept in an easy to read fashion. This modified, messier looking version works for all numbers, not just single digit numbers:

def allbinarytrees(s):
    if s.isdigit():
        yield s
        i = 0
        while i < len(s)-1:
            while i < len(s) and s[i].isdigit():
                i += 1
            if i < len(s) - 1:
                for left in allbinarytrees(s[:i]):
                    for right in allbinarytrees(s[i+1:]):
                        yield '({}{}{})'.format(left, s[i], right)
            i += 1

Sample usage:

for t in allbinarytrees('11+22*3/4456'):
    j += 1
    print j, (t[1:-1])


1 11+(22*(3/4456))
2 11+((22*3)/4456)
3 (11+22)*(3/4456)
4 (11+(22*3))/4456
5 ((11+22)*3)/4456

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