Do it recursively.

```
def emptyTree():
return None
def node(l,d,r):
return (l,d,r)
def singleton(x):
return (emptyTree(),x,emptyTree())
def allBT(trav,length):
if length == 0:
return [emptyTree()]
if length == 1:
return [singleton(trav[0])]
trees = [node(emptyTree(),trav[0],right) for right in allBT(trav[1:],length-1)]
trees += [node(left,trav[i],right) for i in xrange(1,length-1) for left in allBT(trav[:i],i) for right in allBT(trav[i+1:],length-i-1)]
trees += [node(left,trav[length-1],emptyTree()) for left in allBT(trav[:length-1],length-1)]
return trees
def allBinaryTrees(trav):
return allBT(trav,len(trav))
```

By the way, your number of binary trees is wrong. There is exactly one tree with 0 nodes and one with 1 node, there are 2 with two nodes. The recursion is

```
T(n) = \sum_{i = 0}^{n-1} T(i)*T(n-i-1)
```

since we can pick each item to be the root and can combine each possibility for the `i`

nodes before with each possibility for the `n-i-1`

nodes after. Thus `T(3) = 5, T(4) = 14, T(5) = 42, T(6) = 132, ...`