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Introduction to dynamic programming

Dynamic programming is an important algorithmic paradigm that decomposes a problem into a series of smaller subproblems, and stores the solutions of these subproblems to avoid redundant computations, thereby significantly improving time efficiency.

In this section, we start with a classic problem, first presenting its brute force backtracking solution, observing the overlapping subproblems contained within, and then gradually deriving a more efficient dynamic programming solution.

Climbing stairs

Given a staircase with \(n\) steps, where you can climb \(1\) or \(2\) steps at a time, how many different ways are there to reach the top?

As shown in the figure below, there are \(3\) ways to reach the top of a \(3\)-step staircase.

Number of ways to reach the 3rd step

The goal of this problem is to determine the number of ways, considering using backtracking to exhaust all possibilities. Specifically, imagine climbing stairs as a multi-round choice process: starting from the ground, choosing to go up \(1\) or \(2\) steps each round, adding one to the count of ways upon reaching the top of the stairs, and pruning the process when exceeding the top. The code is as follows:

[file]{climbing_stairs_backtrack}-[class]{}-[func]{climbing_stairs_backtrack}

Backtracking algorithms do not explicitly decompose the problem but treat solving the problem as a series of decision steps, searching for all possible solutions through exploration and pruning.

We can try to analyze this problem from the perspective of decomposition. Let \(dp[i]\) be the number of ways to reach the \(i^{th}\) step, then \(dp[i]\) is the original problem, and its subproblems include:

\[ dp[i-1], dp[i-2], \dots, dp[2], dp[1] \]

Since each round can only advance \(1\) or \(2\) steps, when we stand on the \(i^{th}\) step, the previous round must have been either on the \(i-1^{th}\) or the \(i-2^{th}\) step. In other words, we can only step from the \(i-1^{th}\) or the \(i-2^{th}\) step to the \(i^{th}\) step.

This leads to an important conclusion: the number of ways to reach the \(i-1^{th}\) step plus the number of ways to reach the \(i-2^{th}\) step equals the number of ways to reach the \(i^{th}\) step. The formula is as follows:

\[ dp[i] = dp[i-1] + dp[i-2] \]

This means that in the stair climbing problem, there is a recursive relationship between the subproblems, the solution to the original problem can be constructed from the solutions to the subproblems. The figure below shows this recursive relationship.

Recursive relationship of solution counts

We can obtain the brute force search solution according to the recursive formula. Starting with \(dp[n]\), recursively decompose a larger problem into the sum of two smaller problems, until reaching the smallest subproblems \(dp[1]\) and \(dp[2]\) where the solutions are known, with \(dp[1] = 1\) and \(dp[2] = 2\), representing \(1\) and \(2\) ways to climb to the first and second steps, respectively.

Observe the following code, which, like standard backtracking code, belongs to depth-first search but is more concise:

[file]{climbing_stairs_dfs}-[class]{}-[func]{climbing_stairs_dfs}

The figure below shows the recursive tree formed by brute force search. For the problem \(dp[n]\), the depth of its recursive tree is \(n\), with a time complexity of \(O(2^n)\). Exponential order represents explosive growth, and entering a long wait if a relatively large \(n\) is input.

Recursive tree for climbing stairs

Observing the figure above, the exponential time complexity is caused by 'overlapping subproblems'. For example, \(dp[9]\) is decomposed into \(dp[8]\) and \(dp[7]\), \(dp[8]\) into \(dp[7]\) and \(dp[6]\), both containing the subproblem \(dp[7]\).

Thus, subproblems include even smaller overlapping subproblems, endlessly. A vast majority of computational resources are wasted on these overlapping subproblems.

To enhance algorithm efficiency, we hope that all overlapping subproblems are calculated only once. For this purpose, we declare an array mem to record the solution of each subproblem, and prune overlapping subproblems during the search process.

  1. When \(dp[i]\) is calculated for the first time, we record it in mem[i] for later use.
  2. When \(dp[i]\) needs to be calculated again, we can directly retrieve the result from mem[i], thus avoiding redundant calculations of that subproblem.

The code is as follows:

[file]{climbing_stairs_dfs_mem}-[class]{}-[func]{climbing_stairs_dfs_mem}

Observe the figure below, after memoization, all overlapping subproblems need to be calculated only once, optimizing the time complexity to \(O(n)\), which is a significant leap.

Recursive tree with memoized search

Method 3: Dynamic programming

Memoized search is a 'top-down' method: we start with the original problem (root node), recursively decompose larger subproblems into smaller ones until the solutions to the smallest known subproblems (leaf nodes) are reached. Subsequently, by backtracking, we collect the solutions of the subproblems, constructing the solution to the original problem.

On the contrary, dynamic programming is a 'bottom-up' method: starting with the solutions to the smallest subproblems, iteratively construct the solutions to larger subproblems until the original problem is solved.

Since dynamic programming does not include a backtracking process, it only requires looping iteration to implement, without needing recursion. In the following code, we initialize an array dp to store the solutions to the subproblems, serving the same recording function as the array mem in memoized search:

[file]{climbing_stairs_dp}-[class]{}-[func]{climbing_stairs_dp}

The figure below simulates the execution process of the above code.

Dynamic programming process for climbing stairs

Like the backtracking algorithm, dynamic programming also uses the concept of "states" to represent specific stages in problem solving, each state corresponding to a subproblem and its local optimal solution. For example, the state of the climbing stairs problem is defined as the current step number \(i\).

Based on the above content, we can summarize the commonly used terminology in dynamic programming.

  • The array dp is referred to as the DP table, with \(dp[i]\) representing the solution to the subproblem corresponding to state \(i\).
  • The states corresponding to the smallest subproblems (steps \(1\) and \(2\)) are called initial states.
  • The recursive formula \(dp[i] = dp[i-1] + dp[i-2]\) is called the state transition equation.

Space optimization

Observant readers may have noticed that since \(dp[i]\) is only related to \(dp[i-1]\) and \(dp[i-2]\), we do not need to use an array dp to store the solutions to all subproblems, but can simply use two variables to progress iteratively. The code is as follows:

[file]{climbing_stairs_dp}-[class]{}-[func]{climbing_stairs_dp_comp}

Observing the above code, since the space occupied by the array dp is eliminated, the space complexity is reduced from \(O(n)\) to \(O(1)\).

In dynamic programming problems, the current state is often only related to a limited number of previous states, allowing us to retain only the necessary states and save memory space by "dimension reduction". This space optimization technique is known as 'rolling variable' or 'rolling array'.