# Determining time and space complexity

I am having some trouble determining space and time complexities. For example, if I have a tree that has a branching factor b and will have at most a depth d, how can I calculate the time and space complexities? I know they are O(b^d) and O(bd) , but my problem is how to get to those values.

Thanks!

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Asymptotic complexities are not values. They are formulae. If you want exact values you should speak of time and space costs. Then the next question, at least for the time cost, will be "time to do what?" Visit every element in the tree? Find the path from the root to a leaf on which the nodes have the smallest sum? Put the tree into some kind of normal form? Only operations have time costs and complexities. Data structures just sit there. –  Norman Ramsey Jan 17 '10 at 6:16

Space complexity amounts to "how much memory will I need to allocate for this algorithm". Time complexity amounts to "how long will it take to execute (in an abstract sense").

A tree with branching factor b and depth d will have one node at its zeroith level, b nodes at its first level, b*b = b^2 nodes at its second level, b^2 * b = b^3 at its third level, etc. In those four levels (depth 3) it has 1 + b + b^2 + b^3. In terms of complexity we only keep around the highest order term and drop any multiplying constants usually. So you end up with a complexity of O(b^d) for space complexity.

Now in time complexity, what your counting is not the number of nodes, but rather the number of loops or recursive calls your algorithm will take to complete (worst case).

I'm going to go out on a limb and assume you're talking about IDDFS. The explanation of where the O(b^d) and O(bd) come from is nicely explained in this wiki article.

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He is asking about calculating the time and space complexity of minimax. O(b^d) is the time complexity and the space complexity is O(bd). So this answer doesn't provide much value. –  danben Jan 17 '10 at 5:35
@danben ah, yes i missed that tag. –  vicatcu Jan 17 '10 at 5:38

## Time

All the nodes in the tree have to be generated once at some point, and the assumption is that it costs a constant time `c` to generate a node (constant times can vary, you can just pick `c` to be the highest constant time to generate any node). The order is determined by the algorithm and ensures that nodes don't have to be repeatedly expanded.

``````nodes          b=2                        b=3
b^0             *                          *
/   \               /        |        \
b^1          *     *             *         *         *
/ \   / \         /  |  \   /  |  \   /  |  \
b^2        *   * *   *       *   *   * *   *   * *   *   *
...                        ...
``````

As you can see in the figure it costs `c*b^0` cost to calculate the first level - exactly `c`. The next level in the tree will contain a `b^1` nodes and it costs `c*b^1 = c*b` to generate the second level. For the third level there will be `b` nodes again for every node in the second level, this means `b*b^1 = b^2\$` nodes and a cost of `c*b^2`.

At the deepest level of the tree at depth `d` there will be `b^d`nodes, the work at that level therefor is `c*b^d`. The total amount of work done to this point is `c*b^0 + c*b^1 + ... + c*b^d`. For the complexity we only look at the fastest rising term and drop the constant so we get:

`O(c + c*b + ... + c*b^d) = O(c*b^d) = O(b^d)`.

In essence: The time is a function `f(d) = SUM(i=1..d){c*b^i}`, and `O(f(d)) = O(b^d)`.

## Space

The figure shows the algorithm at different stages for `b=3`. `*` indicates currently expanded nodes, `?` indicates unknown nodes and `+` indicates nodes who's score has been fully calculated.

``````                    branching factor b = 3                     space
*             *             *             *             b
/ | \         / | \         / | \         / | \
*  ?  ?       *  ?  ?       +  *  ?       +  +  *          b
/ | \         / | \            / | \            / | \
*  ?  ?       +  +  *          +  *  ?          +  +  *       b
/ | \               / | \         / | \               / | \
*  ?  ?             +  *  ?       +  *  ?             +  +  *    b
``````

In order to calculate the score of a node, you expand the node, pick a child and recursively expand until you reach a leaf node at depth `d`. Once a child node is fully calculated you move on to the next child node. Once all `b` child nodes are calculated the parents score is calculated based on the children and at that point the child nodes can be removed from storage. This is illustrated in the figure above, where the algorithm is shown at 4 different stages.

At any time you have one path expanded and you need `c*b` storage to store all the child nodes at every level. Here again the assumption is that you need a constant amount of space per node. The key is that any subtree can summarised by its root. Since the maximal length of a path is `d`, you will maximally need `c*b*d` of space. As above we can drop constant terms and we get `O(c*b*d) = O(b*d)`.

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