build

en/docs/chapter_divide_and_conquer/build_binary_tree_problem.md

@@ -47,7 +47,7 @@ Based on the above division method, **we have now obtained the index intervals o
 - Let the index of the current tree's root node in `inorder` be denoted as $m$.
 - Let the index interval of the current tree in `inorder` be denoted as $[l, r]$.
 
-As shown in the Table 12-1 , the above variables can represent the index of the root node in `preorder` as well as the index intervals of the subtrees in `inorder`.
+As shown in Table 12-1, the above variables can represent the index of the root node in `preorder` as well as the index intervals of the subtrees in `inorder`.
 
 <p align="center"> Table 12-1 &nbsp; Indexes of the root node and subtrees in preorder and inorder traversals </p>
 

en/docs/chapter_divide_and_conquer/divide_and_conquer.md

@@ -9,7 +9,7 @@ comments: true
 1. **Divide (partition phase)**: Recursively decompose the original problem into two or more sub-problems until the smallest sub-problem is reached and the process terminates.
 2. **Conquer (merge phase)**: Starting from the smallest sub-problem with a known solution, merge the solutions of the sub-problems from bottom to top to construct the solution to the original problem.
 
-As shown in the Figure 12-1 , "merge sort" is one of the typical applications of the divide and conquer strategy.
+As shown in Figure 12-1, "merge sort" is one of the typical applications of the divide and conquer strategy.
 
 1. **Divide**: Recursively divide the original array (original problem) into two sub-arrays (sub-problems), until the sub-array has only one element (smallest sub-problem).
 2. **Conquer**: Merge the ordered sub-arrays (solutions to the sub-problems) from bottom to top to obtain an ordered original array (solution to the original problem).
@@ -40,7 +40,7 @@ Then, we may ask: **Why can divide and conquer improve algorithm efficiency, and
 
 ### 1.   Optimization of operation count
 
-Taking "bubble sort" as an example, it requires $O(n^2)$ time to process an array of length $n$. Suppose we divide the array from the midpoint into two sub-arrays as shown in the Figure 12-2 , then the division requires $O(n)$ time, sorting each sub-array requires $O((n / 2)^2)$ time, and merging the two sub-arrays requires $O(n)$ time, with the total time complexity being:
+Taking "bubble sort" as an example, it requires $O(n^2)$ time to process an array of length $n$. Suppose we divide the array from the midpoint into two sub-arrays as shown in Figure 12-2, then the division requires $O(n)$ time, sorting each sub-array requires $O((n / 2)^2)$ time, and merging the two sub-arrays requires $O(n)$ time, with the total time complexity being:
 
 $$
 O(n + (\frac{n}{2})^2 \times 2 + n) = O(\frac{n^2}{2} + 2n)
@@ -72,7 +72,7 @@ We know that the sub-problems generated by divide and conquer are independent of
 
 Parallel optimization is especially effective in environments with multiple cores or processors, as the system can process multiple sub-problems simultaneously, making fuller use of computing resources and significantly reducing the overall runtime.
 
-For example, in the "bucket sort" shown in the Figure 12-3 , we distribute massive data evenly across various buckets, then the sorting tasks of all buckets can be distributed to different computing units, and the results are merged after completion.
+For example, in the "bucket sort" shown in Figure 12-3, we distribute massive data evenly across various buckets, then the sorting tasks of all buckets can be distributed to different computing units, and the results are merged after completion.
 
 ![Bucket sort's parallel computation](divide_and_conquer.assets/divide_and_conquer_parallel_computing.png){ class="animation-figure" }
 

en/docs/chapter_divide_and_conquer/hanota_problem.md

@@ -8,7 +8,7 @@ In both merge sorting and building binary trees, we decompose the original probl
 
 !!! question
 
-    Given three pillars, denoted as `A`, `B`, and `C`. Initially, pillar `A` is stacked with $n$ discs, arranged in order from top to bottom from smallest to largest. Our task is to move these $n$ discs to pillar `C`, maintaining their original order (as shown below). The following rules must be followed during the disc movement process:
+    Given three pillars, denoted as `A`, `B`, and `C`. Initially, pillar `A` is stacked with $n$ discs, arranged in order from top to bottom from smallest to largest. Our task is to move these $n$ discs to pillar `C`, maintaining their original order (as shown in Figure 12-10). The following rules must be followed during the disc movement process:
     
     1. A disc can only be picked up from the top of a pillar and placed on top of another pillar.
     2. Only one disc can be moved at a time.
@@ -22,7 +22,7 @@ In both merge sorting and building binary trees, we decompose the original probl
 
 ### 1.   Consider the base case
 
-As shown below, for the problem $f(1)$, i.e., when there is only one disc, we can directly move it from `A` to `C`.
+As shown in Figure 12-11, for the problem $f(1)$, i.e., when there is only one disc, we can directly move it from `A` to `C`.
 
 === "<1>"
     ![Solution for a problem of size 1](hanota_problem.assets/hanota_f1_step1.png){ class="animation-figure" }
@@ -32,7 +32,7 @@ As shown below, for the problem $f(1)$, i.e., when there is only one disc, we ca
 
 <p align="center"> Figure 12-11 &nbsp; Solution for a problem of size 1 </p>
 
-As shown below, for the problem $f(2)$, i.e., when there are two discs, **since the smaller disc must always be above the larger disc, `B` is needed to assist in the movement**.
+As shown in Figure 12-12, for the problem $f(2)$, i.e., when there are two discs, **since the smaller disc must always be above the larger disc, `B` is needed to assist in the movement**.
 
 1. First, move the smaller disc from `A` to `B`.
 2. Then move the larger disc from `A` to `C`.
@@ -58,7 +58,7 @@ The process of solving the problem $f(2)$ can be summarized as: **moving two dis
 
 For the problem $f(3)$, i.e., when there are three discs, the situation becomes slightly more complicated.
 
-Since we already know the solutions to $f(1)$ and $f(2)$, we can think from a divide-and-conquer perspective and **consider the two top discs on `A` as a unit**, performing the steps shown below. This way, the three discs are successfully moved from `A` to `C`.
+Since we already know the solutions to $f(1)$ and $f(2)$, we can think from a divide-and-conquer perspective and **consider the two top discs on `A` as a unit**, performing the steps shown in Figure 12-13. This way, the three discs are successfully moved from `A` to `C`.
 
 1. Let `B` be the target pillar and `C` the buffer pillar, and move the two discs from `A` to `B`.
 2. Move the remaining disc from `A` directly to `C`.
@@ -80,7 +80,7 @@ Since we already know the solutions to $f(1)$ and $f(2)$, we can think from a di
 
 Essentially, **we divide the problem $f(3)$ into two subproblems $f(2)$ and one subproblem $f(1)$**. By solving these three subproblems in order, the original problem is resolved. This indicates that the subproblems are independent, and their solutions can be merged.
 
-From this, we can summarize the divide-and-conquer strategy for solving the Tower of Hanoi shown in the following image: divide the original problem $f(n)$ into two subproblems $f(n-1)$ and one subproblem $f(1)$, and solve these three subproblems in the following order.
+From this, we can summarize the divide-and-conquer strategy for solving the Tower of Hanoi shown in Figure 12-14: divide the original problem $f(n)$ into two subproblems $f(n-1)$ and one subproblem $f(1)$, and solve these three subproblems in the following order.
 
 1. Move $n-1$ discs with the help of `C` from `A` to `B`.
 2. Move the remaining one disc directly from `A` to `C`.
@@ -532,7 +532,7 @@ In the code, we declare a recursive function `dfs(i, src, buf, tar)` whose role
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     <div style="margin-top: 5px;"><a href="https://pythontutor.com/iframe-embed.html#code=def%20move%28src%3A%20list%5Bint%5D,%20tar%3A%20list%5Bint%5D%29%3A%0A%20%20%20%20%22%22%22%E7%A7%BB%E5%8A%A8%E4%B8%80%E4%B8%AA%E5%9C%86%E7%9B%98%22%22%22%0A%20%20%20%20%23%20%E4%BB%8E%20src%20%E9%A1%B6%E9%83%A8%E6%8B%BF%E5%87%BA%E4%B8%80%E4%B8%AA%E5%9C%86%E7%9B%98%0A%20%20%20%20pan%20%3D%20src.pop%28%29%0A%20%20%20%20%23%20%E5%B0%86%E5%9C%86%E7%9B%98%E6%94%BE%E5%85%A5%20tar%20%E9%A1%B6%E9%83%A8%0A%20%20%20%20tar.append%28pan%29%0A%0A%0Adef%20dfs%28i%3A%20int,%20src%3A%20list%5Bint%5D,%20buf%3A%20list%5Bint%5D,%20tar%3A%20list%5Bint%5D%29%3A%0A%20%20%20%20%22%22%22%E6%B1%82%E8%A7%A3%E6%B1%89%E8%AF%BA%E5%A1%94%E9%97%AE%E9%A2%98%20f%28i%29%22%22%22%0A%20%20%20%20%23%20%E8%8B%A5%20src%20%E5%8F%AA%E5%89%A9%E4%B8%8B%E4%B8%80%E4%B8%AA%E5%9C%86%E7%9B%98%EF%BC%8C%E5%88%99%E7%9B%B4%E6%8E%A5%E5%B0%86%E5%85%B6%E7%A7%BB%E5%88%B0%20tar%0A%20%20%20%20if%20i%20%3D%3D%201%3A%0A%20%20%20%20%20%20%20%20move%28src,%20tar%29%0A%20%20%20%20%20%20%20%20return%0A%20%20%20%20%23%20%E5%AD%90%E9%97%AE%E9%A2%98%20f%28i-1%29%20%EF%BC%9A%E5%B0%86%20src%20%E9%A1%B6%E9%83%A8%20i-1%20%E4%B8%AA%E5%9C%86%E7%9B%98%E5%80%9F%E5%8A%A9%20tar%20%E7%A7%BB%E5%88%B0%20buf%0A%20%20%20%20dfs%28i%20-%201,%20src,%20tar,%20buf%29%0A%20%20%20%20%23%20%E5%AD%90%E9%97%AE%E9%A2%98%20f%281%29%20%EF%BC%9A%E5%B0%86%20src%20%E5%89%A9%E4%BD%99%E4%B8%80%E4%B8%AA%E5%9C%86%E7%9B%98%E7%A7%BB%E5%88%B0%20tar%0A%20%20%20%20move%28src,%20tar%29%0A%20%20%20%20%23%20%E5%AD%90%E9%97%AE%E9%A2%98%20f%28i-1%29%20%EF%BC%9A%E5%B0%86%20buf%20%E9%A1%B6%E9%83%A8%20i-1%20%E4%B8%AA%E5%9C%86%E7%9B%98%E5%80%9F%E5%8A%A9%20src%20%E7%A7%BB%E5%88%B0%20tar%0A%20%20%20%20dfs%28i%20-%201,%20buf,%20src,%20tar%29%0A%0A%0Adef%20solve_hanota%28A%3A%20list%5Bint%5D,%20B%3A%20list%5Bint%5D,%20C%3A%20list%5Bint%5D%29%3A%0A%20%20%20%20%22%22%22%E6%B1%82%E8%A7%A3%E6%B1%89%E8%AF%BA%E5%A1%94%E9%97%AE%E9%A2%98%22%22%22%0A%20%20%20%20n%20%3D%20len%28A%29%0A%20%20%20%20%23%20%E5%B0%86%20A%20%E9%A1%B6%E9%83%A8%20n%20%E4%B8%AA%E5%9C%86%E7%9B%98%E5%80%9F%E5%8A%A9%20B%20%E7%A7%BB%E5%88%B0%20C%0A%20%20%20%20dfs%28n,%20A,%20B,%20C%29%0A%0A%0A%22%22%22Driver%20Code%22%22%22%0Aif%20__name__%20%3D%3D%20%22__main__%22%3A%0A%20%20%20%20%23%20%E5%88%97%E8%A1%A8%E5%B0%BE%E9%83%A8%E6%98%AF%E6%9F%B1%E5%AD%90%E9%A1%B6%E9%83%A8%0A%20%20%20%20A%20%3D%20%5B5,%204,%203,%202,%201%5D%0A%20%20%20%20B%20%3D%20%5B%5D%0A%20%20%20%20C%20%3D%20%5B%5D%0A%20%20%20%20print%28%22%E5%88%9D%E5%A7%8B%E7%8A%B6%E6%80%81%E4%B8%8B%EF%BC%9A%22%29%0A%20%20%20%20print%28f%22A%20%3D%20%7BA%7D%22%29%0A%20%20%20%20print%28f%22B%20%3D%20%7BB%7D%22%29%0A%20%20%20%20print%28f%22C%20%3D%20%7BC%7D%22%29%0A%0A%20%20%20%20solve_hanota%28A,%20B,%20C%29%0A%0A%20%20%20%20print%28%22%E5%9C%86%E7%9B%98%E7%A7%BB%E5%8A%A8%E5%AE%8C%E6%88%90%E5%90%8E%EF%BC%9A%22%29%0A%20%20%20%20print%28f%22A%20%3D%20%7BA%7D%22%29%0A%20%20%20%20print%28f%22B%20%3D%20%7BB%7D%22%29%0A%20%20%20%20print%28f%22C%20%3D%20%7BC%7D%22%29&codeDivHeight=800&codeDivWidth=600&cumulative=false&curInstr=12&heapPrimitives=nevernest&origin=opt-frontend.js&py=311&rawInputLstJSON=%5B%5D&textReferences=false" target="_blank" rel="noopener noreferrer">Full Screen ></a></div>
 
-As shown below, the Tower of Hanoi forms a recursive tree with a height of $n$, each node representing a subproblem, corresponding to an open `dfs()` function, **thus the time complexity is $O(2^n)$, and the space complexity is $O(n)$**.
+As shown in Figure 12-15, the Tower of Hanoi forms a recursive tree with a height of $n$, each node representing a subproblem, corresponding to an open `dfs()` function, **thus the time complexity is $O(2^n)$, and the space complexity is $O(n)$**.
 
 ![Recursive tree of the Tower of Hanoi](hanota_problem.assets/hanota_recursive_tree.png){ class="animation-figure" }