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150 lines
5 KiB
Markdown
150 lines
5 KiB
Markdown
---
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id: naive
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slug: /recursion/pyramid-slide-down/naive
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title: Naïve solution
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description: |
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Naïve solution of the Pyramid Slide Down.
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tags:
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- java
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- recursion
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- exponential
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last_update:
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date: 2023-08-17
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---
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Our naïve solution consists of trying out all the possible slides and finding
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the one with maximum sum.
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```java
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public static int longestSlideDown(int[][] pyramid, int row, int col) {
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if (row >= pyramid.length || col < 0 || col >= pyramid[row].length) {
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// BASE: We have gotten out of bounds, there's no reasonable value to
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// return, so we just return the ‹MIN_VALUE› to ensure that it cannot
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// be maximum.
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return Integer.MIN_VALUE;
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}
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if (row == pyramid.length - 1) {
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// BASE: Bottom of the pyramid, we just return the value, there's
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// nowhere to slide anymore.
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return pyramid[row][col];
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}
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// Otherwise we account for the current position and return maximum of the
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// available “slides”.
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return pyramid[row][col] + Math.max(
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longestSlideDown(pyramid, row + 1, col),
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longestSlideDown(pyramid, row + 1, col + 1));
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}
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public static int longestSlideDown(int[][] pyramid) {
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// We start the slide in the top cell of the pyramid.
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return longestSlideDown(pyramid, 0, 0);
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}
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```
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As you can see, we have 2 overloads:
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```java
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int longestSlideDown(int[][] pyramid);
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int longestSlideDown(int[][] pyramid, int row, int col);
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```
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First one is used as a _public interface_ to the solution, you just pass in the
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pyramid itself. Second one is the recursive “algorithm” that finds the slide
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down.
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It is a relatively simple solution… There's nothing to do at the bottom of the
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pyramid, so we just return the value in the _cell_. Otherwise we add it and try
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to slide down the available cells below the current row.
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## Time complexity
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If you get the source code and run it yourself, it runs rather fine… I hope you
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are wondering about the time complexity of the proposed solution and, since it
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really is a naïve solution, the time complexity is pretty bad. Let's find the
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worst case scenario.
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Let's start with the first overload:
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```java
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public static int longestSlideDown(int[][] pyramid) {
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return longestSlideDown(pyramid, 0, 0);
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}
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```
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There's not much to do here, so we can safely say that the time complexity of
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this function is bounded by $$T(n)$$, where $$T$$ is our second overload. This
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doesn't tell us anything, so let's move on to the second overload where we are
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going to define the $$T(n)$$ function.
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```java
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public static int longestSlideDown(int[][] pyramid, int row, int col) {
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if (row >= pyramid.length || col < 0 || col >= pyramid[row].length) {
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// BASE: We have gotten out of bounds, there's no reasonable value to
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// return, so we just return the ‹MIN_VALUE› to ensure that it cannot
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// be maximum.
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return Integer.MIN_VALUE;
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}
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if (row == pyramid.length - 1) {
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// BASE: Bottom of the pyramid, we just return the value, there's
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// nowhere to slide anymore.
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return pyramid[row][col];
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}
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// Otherwise we account for the current position and return maximum of the
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// available “slides”.
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return pyramid[row][col] + Math.max(
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longestSlideDown(pyramid, row + 1, col),
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longestSlideDown(pyramid, row + 1, col + 1));
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}
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```
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Fun fact is that the whole “algorithm” consists of just 2 `return` statements
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and nothing else. Let's dissect them!
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First `return` statement is the base case, so it has a constant time complexity.
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Second one a bit tricky. We add two numbers together, which we'll consider as
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constant, but for the right part of the expression we take maximum from the left
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and right paths. OK… So what happens? We evaluate the `longestSlideDown` while
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choosing the under and right both. They are separate computations though, so we
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are branching from each call of `longestSlideDown`, unless it's a base case.
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What does that mean for us then? We basically get
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$$
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T(y) =
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\begin{cases}
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1 & \text{, if } y = rows \\
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1 + 2 \cdot T(y + 1) & \text{, otherwise}
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\end{cases}
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$$
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That looks rather easy to compute, isn't it? If you sum it up, you'll get:
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$$
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T(rows) \in \mathcal{O}(2^{rows})
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$$
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If you wonder why, I'll try to describe it intuitively:
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1. In each call to `longestSlideDown` we do some work in constant time,
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regardless of being in the base case. Those are the `1`s in both cases.
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2. If we are not in the base case, we move one row down **twice**. That's how we
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obtained `2 *` and `y + 1` in the _otherwise_ case.
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3. We move row-by-row, so we move down `y`-times and each call splits to two
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subtrees.
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4. Overall, if we were to represent the calls as a tree, we would get a full
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binary tree of height `y`, in each node we do some work in constant time,
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therefore we can just sum the ones.
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:::danger
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It would've been more complicated to get an exact result. In the equation above
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we are assuming that the width of the pyramid is bound by the height.
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:::
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Hopefully we can agree that this is not the best we can do. :wink:
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