Solution: Sort Colors

Let's solve the Sort Colors problem using the Two Pointers pattern.

Statement

Given an array, colors, which contains a combination of the following three elements:

  • 00 (representing red)

  • 11 (representing white)

  • 22 (representing blue)

Sort the array in place so that the elements of the same color are adjacent, with the colors in the order of red, white, and blue. To improve your problem-solving skills, do not utilize the built-in sort function.

Constraints:

  • 1≤1 \leq colors.length ≤\leq 300
  • colors[i] can only contain 00s, 11s, or 22s.

Solution

So far, you’ve probably brainstormed some approaches and have an idea of how to solve this problem. Let’s explore some of these approaches and figure out which one to follow based on considerations such as time complexity and any implementation constraints.

Naive approach

The naive approach would be to sort the array. This would arrange the elements in the desired positions, i.e., 00s, then 11s, and lastly, 22s. The time complexity of this approach would be O(nlog(n))O(nlog(n)), which is the time required to sort the array. The space complexity of this approach would be O(1)O(1) since no extra space is being used.

Optimized approach using two pointers

The essence of the algorithm lies in efficiently partitioning the array into three sections corresponding to the colors red, white, and blue. We keep track of the boundaries of the red and blue sections while iterating through the array. Reds are kept on the left side of the array, while blues remain on the right side, with whites in between. When encountering a red (00), it’s placed at the end of the red section, and when finding a blue (22), it’s moved to the beginning of the blue section. Elements of value 11 (white) remain in place. This process continues until all the colors are separated, ensuring proper grouping of colors.

To implement it, we use two pointers (start and end) to traverse the array from either end. They keep track of the red and blue elements, respectively. In addition, we maintain another pointer (current) to keep track of the white elements. These pointers are used to traverse the array in one pass. They are initialized as follows:

  • start: This pointer will initially point to the 0th0^{th} index of the array.

  • current: This pointer will initially point to the 0th0^{th} index of the array.

  • end: This pointer will initially point to the last index of the array.

Here’s how the algorithm works:

  • Condition 1: If colors[current] is 0, the current pointer points to red. Swap the elements of colors[current] and colors[start]. Next, move both the start and current pointers one position forward.

  • Condition 2: Otherwise, if colors[current] is 1, the current pointer points to white. Increment the current pointer by 1 to analyze the next element.

  • Condition 3: Otherwise, colors[current] will be 2, i.e., the current pointer points to blue. Swap the elements of colors[current] and colors[end]. Next, move the end pointer one position backward.

    Note: When we decrement the end pointer, the current pointer remains unchanged since it has to analyze the swapped element to determine if further swapping is required with the start pointer.

  • The three steps above are repeated until the end pointer becomes less than the current pointer, i.e., no elements are left to swap.

Let’s look at the following illustration to get a better understanding of the solution:

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