# 3D Matrix traversal Big-O

My attempt for the Big-O of each of these two algorithms..

1) Algorithm threeD(matrix, n)

// a 3D matrix of size n x n x n

``````layer ← 0
while (layer < n)
row ← 0
while (row < layer)
col ← 0
while (col < row)
print matrix[layer][row][col]
col ← col + 1
done
row ← row + 1
done
layer ← layer * 2
done
``````

O((n^2)log(n)) because the two outer loops are each O(N) and the innermost one seems to be O(log n)

2) Algorithm Magic(n)

//Integer, n > 0

``````i ← 0
while (i < n)
j ← 0
while (j < power(2,i))
j ← j + 1
done
i ← i + 1
done
``````

O(N) for outer loop, O(2^n) for inner? = O(n(2^n))?

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### 1. Algorithm

First of all: This algorithm never terminates due to `layer` is initiated with zero. `layer` is only multipyed by `2` so it will never get bigger than zero, specially not bigger than `n`. To get this work, you have to start with `layer > 0`.

So lets start with `layer = 1`.

The time-complexity can be written as `T(n) = T(n/2) + n^2`.
You can get this by looking that way: At the end the layer is setted at most to `n`. Then the inner loops do `n^2` steps. Bevor that, the layer was only half that big. So you have to do the n^2 steps on the last rould of the outer loop and all stepps of the round bevor wirtten as `T(n/2)`.

The masters theorem gets you `Theta(n^2)`.

### 2. Algorithm

You can just count the steps:

``````2^0 + 2^1 + 2^2 + ... + 2^(n-1) = sum_(i=0)^(n-1)2^i = 2^n-1
``````

To get this simplification just take a look at binary numbers: The sum of steps corresponds to a binary number containing only 1's (like `1111 1111`). This number equals `2^n-1`.

So the time complexity is `Theta(2^n)`

Notice: Both your Big-O's are not wrong, there are bette boundings.

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