I have an ongoing project investigating the Fibonacci sequence, this is just a personal project, I have created a binary `tree class`

which makes a binary tree of the Fibonacci call graph, so for `f(3)`

I generate the tree:

I want to create a method of my `tree class`

`get_partitions()`

that traverses the tree to generate partitions of the `root value`

, I regard here summands that differ in order as **different** partions; so for the example here of `f(3)`

, the `get_partitions()`

method would traverse the tree and yield:

```
Partion 1: 2,1
Partion 2: 2,1,0
Partion 3: 1,1,1
Partion 4: 1,1,1,0
Partion 5: 1,0,1,1
Partion 6: 1,0,1,1,0
```

As ultimately I want to enumerate every permutation of Fibonacci numbers that Partition the `root value`

, in this case `3`

, so for `Partition 1`

enumerated would be `(2,1),(1,2)`

, or `Partion 2`

would be enumerated `(2,1,0),(2,0,1),(1,2,0),(1,0,2),(0,2,1),(0,1,2)`

, etc…

[Edit 1] My concern is with `Partion 4`

and `Partion 5`

in this examples as enumerating all combinations of these partions would yield **duplicate** partions.

Would it be correct that the number of combinations for a given `root value`

would yield a Catalan number?

My `Tree class`

is:

```
class FibTree(object):
"""Class which builds binary tree from Fibonacci function call graph"""
def __init__(self, n, parent=None, level=None, i=None):
if level is None:
level = 0
if i is None:
i = 1
self.n = n
self.parent = parent
self.level = level
self.i = i # Node index value
if n < 2:
self.left = None
self.right = None
self.value = n
else:
self.left = FibTree(n - 1, self, level + 1, i*2)
self.right = FibTree(n - 2, self, level + 1, (i*2)+1)
self.value = self.left.value + self.right.value
```

I'd be grateful of any help for producing the tree class method and any enlightenment on the maths to my problem.

[EDIT:] How I get my partions
All partions must sum to `Root`

value:

`Partion 1:`

Taken from Level 1 `(2,1)`

`Partion 2:`

Use the `left child node`

value of `root`

, but now take the values of the children of the `right child node`

of the `root`

node `(1,0)`

, to give a Partion of `(2,1,0)`

`Partion 3:`

As traversal of `right child node`

of the `root`

node has been exhausted, traverse to next level of `left child node`

value of `root`

(level 2), and use the these child node values as first part of partion `(1,1)`

then take the `right child node`

value of the `root`

node (1), to give a partion of `(1,1,1)`

`Partion 4:`

Keeping the initial partion values from the previous partion `(1,1)`

, but as with `Partion 2`

take the values of the children of the `right child node`

of the `root`

node `(1,0)`

, to give a Partion of `(1,1,1,0)`

`Partion 5:`

As the left child, of the left child of the root, has children, use these as the first part of the partion `(1,0)`

then take the right child value of the left child of the `root`

(1), giving a partion so far of `(1,0,1)`

, then take the right child node of the root `(1)`

, to give a final partion of `(1,0,1,1)`

`Partion 6:`

As Partion 5, take the first part of Partion 5 `(1,0,1)`

, then as Partion 2 and 4 take the value of the child nodes of the right node of the root.

`1`

nodes have a`1`

and`0`

child? It seems like the recursion should terminate there. If not, one could make a case that you can have arbitrarily many`0`

children, since they don't actually contribute anything.`1`

nodes do have a`1`

and`0`

child, but as you say it may be the arbitrary`0`

children will ultimately prove to be no use to me as they have no magnitude, so I may need to filter them out in some way.1more comment