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---
### tree tranversals
### breath-first search
* similar to pre-order, but work with queue (level order problem)
<br>
* **breath-first search**:
- similar to pre-order, but work with queue (level order problem)
* **depth-first search**:
* if the depth of the tree is too large, stack overflow might happen, therefore iterative solutions might be better.
* work with stacks
* **in-order**:
* left -> node -> right
* **pre-order**
* node -> left -> right
* top-down (parameters are passed down to children).
* **post-order**
* left -> right -> node
* bottom-up solution (if you know the answer of the children, can you concatenate the answer of the nodes?):
- deletion process is always post-order: when you delete a node, you will delete its left child and its right child before you delete the node itself.
- also, post-order is used in mathematical expressions as it's easier to write a program to parse a post-order expression. using a stack, each time when you meet a operator, you can just pop 2 elements from the stack, calculate the result and push the result back into the stack.
---
### depth-first search
* if the depth of the tree is too large, stack overflow might happen, therefore iterative solutions might be better.
* work with stacks
<br>
#### in-order
- left -> node -> right
```python
def inorder(self, root):
if root is None:
return []
return inorder(root.left) + [root.val] + inorder(root.right)
````
<br>
#### pre-order
- node -> left -> right
```python
def preorder(self, root):
if root is None:
return []
return [root.val] + preorder(root.left) + preorder(root.right)
````
- top-down (parameters are passed down to children).
<br>
#### post-order
- left -> right -> node
```python
def postorder(self, root):
if root is None:
return []
return postorder(root.left) + postorder(root.right) + [root.val]
````
- bottom-up solution (if you know the answer of the children, can you concatenate the answer of the nodes?):
- deletion process is always post-order: when you delete a node, you will delete its left child and its right child before you delete the node itself.
- also, post-order is used in mathematical expressions as it's easier to write a program to parse a post-order expression. using a stack, each time when you meet a operator, you can just pop 2 elements from the stack, calculate the result and push the result back into the stack.
<br>