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17 changed files with 229 additions and 178 deletions
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16
docs/chapter_array_and_linkedlist/array.md
View file

@ -410,14 +410,14 @@ comments: true
=== "Dart"
```dart title="array.dart"
/* 在数组的索引 index 处插入元素 num */
void insert(List<int> nums, int num, int index) {
/* 在数组的索引 index 处插入元素 _num */
void insert(List<int> nums, int _num, int index) {
// 把索引 index 以及之后的所有元素向后移动一位
for (var i = nums.length - 1; i > index; i--) {
nums[i] = nums[i - 1];
}
// 将 num 赋给 index 处元素
nums[index] = num;
// 将 _num 赋给 index 处元素
nums[index] = _num;
}
```
@ -779,12 +779,12 @@ comments: true
count += nums[i];
}
// 直接遍历数组元素
for (int num in nums) {
count += num;
for (int _num in nums) {
count += _num;
}
// 通过 forEach 方法遍历数组
nums.forEach((num) {
count += num;
nums.forEach((_num) {
count += _num;
});
}
```

16
docs/chapter_array_and_linkedlist/list.md
View file

@ -1713,22 +1713,22 @@ comments: true
}
/* 更新元素 */
void set(int index, int num) {
void set(int index, int _num) {
if (index >= _size) throw RangeError('索引越界');
_arr[index] = num;
_arr[index] = _num;
}
/* 尾部添加元素 */
void add(int num) {
void add(int _num) {
// 元素数量超出容量时,触发扩容机制
if (_size == _capacity) extendCapacity();
_arr[_size] = num;
_arr[_size] = _num;
// 更新元素数量
_size++;
}
/* 中间插入元素 */
void insert(int index, int num) {
void insert(int index, int _num) {
if (index >= _size) throw RangeError('索引越界');
// 元素数量超出容量时,触发扩容机制
if (_size == _capacity) extendCapacity();
@ -1736,7 +1736,7 @@ comments: true
for (var j = _size - 1; j >= index; j--) {
_arr[j + 1] = _arr[j];
}
_arr[index] = num;
_arr[index] = _num;
// 更新元素数量
_size++;
}
@ -1744,7 +1744,7 @@ comments: true
/* 删除元素 */
int remove(int index) {
if (index >= _size) throw RangeError('索引越界');
int num = _arr[index];
int _num = _arr[index];
// 将索引 index 之后的元素都向前移动一位
for (var j = index; j < _size - 1; j++) {
_arr[j] = _arr[j + 1];
@ -1752,7 +1752,7 @@ comments: true
// 更新元素数量
_size--;
// 返回被删除元素
return num;
return _num;
}
/* 列表扩容 */

2
docs/chapter_computational_complexity/time_complexity.md
View file

@ -1394,7 +1394,7 @@ $$
int arrayTraversal(List<int> nums) {
int count = 0;
// 循环次数与数组长度成正比
for (var num in nums) {
for (var _num in nums) {
count++;
}
return count;

25
docs/chapter_dynamic_programming/dp_problem_features.md
View file

@ -264,15 +264,18 @@ $$
if (n == 1 || n == 2)
return cost[n];
// 初始化 dp 表,用于存储子问题的解
int dp[n + 1];
int *dp = calloc(n + 1, sizeof(int));
// 初始状态:预设最小子问题的解
dp[1] = cost[1];
dp[2] = cost[2];
// 状态转移:从较小子问题逐步求解较大子问题
for (int i = 3; i <= n; i++) {
dp[i] = min(dp[i - 1], dp[i - 2]) + cost[i];
dp[i] = myMin(dp[i - 1], dp[i - 2]) + cost[i];
}
return dp[n];
int res = dp[n];
// 释放内存
free(dp);
return res;
}
```
@ -503,7 +506,7 @@ $$
int a = cost[1], b = cost[2];
for (int i = 3; i <= n; i++) {
int tmp = b;
b = min(a, tmp) + cost[i];
b = myMin(a, tmp) + cost[i];
a = tmp;
}
return b;
@ -815,8 +818,10 @@ $$
return 1;
}
// 初始化 dp 表,用于存储子问题的解
int dp[n + 1][3];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(3, sizeof(int));
}
// 初始状态:预设最小子问题的解
dp[1][1] = 1;
dp[1][2] = 0;
@ -827,7 +832,13 @@ $$
dp[i][1] = dp[i - 1][2];
dp[i][2] = dp[i - 2][1] + dp[i - 2][2];
}
return dp[n][1] + dp[n][2];
int res = dp[n][1] + dp[n][2];
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
free(dp);
return res;
}
```

43
docs/chapter_dynamic_programming/dp_solution_pipeline.md
View file

@ -326,7 +326,7 @@ $$
```c title="min_path_sum.c"
/* 最小路径和:暴力搜索 */
int minPathSumDFS(int gridCols, int grid[][gridCols], int i, int j) {
int minPathSumDFS(int grid[MAX_SIZE][MAX_SIZE], int i, int j) {
// 若为左上角单元格,则终止搜索
if (i == 0 && j == 0) {
return grid[0][0];
@ -336,10 +336,10 @@ $$
return INT_MAX;
}
// 计算从左上角到 (i-1, j) 和 (i, j-1) 的最小路径代价
int up = minPathSumDFS(gridCols, grid, i - 1, j);
int left = minPathSumDFS(gridCols, grid, i, j - 1);
int up = minPathSumDFS(grid, i - 1, j);
int left = minPathSumDFS(grid, i, j - 1);
// 返回从左上角到 (i, j) 的最小路径代价
return min(left, up) != INT_MAX ? min(left, up) + grid[i][j] : INT_MAX;
return myMin(left, up) != INT_MAX ? myMin(left, up) + grid[i][j] : INT_MAX;
}
```
@ -646,7 +646,7 @@ $$
```c title="min_path_sum.c"
/* 最小路径和:记忆化搜索 */
int minPathSumDFSMem(int gridCols, int grid[][gridCols], int mem[][gridCols], int i, int j) {
int minPathSumDFSMem(int grid[MAX_SIZE][MAX_SIZE], int mem[MAX_SIZE][MAX_SIZE], int i, int j) {
// 若为左上角单元格,则终止搜索
if (i == 0 && j == 0) {
return grid[0][0];
@ -660,10 +660,10 @@ $$
return mem[i][j];
}
// 左边和上边单元格的最小路径代价
int up = minPathSumDFSMem(gridCols, grid, mem, i - 1, j);
int left = minPathSumDFSMem(gridCols, grid, mem, i, j - 1);
int up = minPathSumDFSMem(grid, mem, i - 1, j);
int left = minPathSumDFSMem(grid, mem, i, j - 1);
// 记录并返回左上角到 (i, j) 的最小路径代价
mem[i][j] = min(left, up) != INT_MAX ? min(left, up) + grid[i][j] : INT_MAX;
mem[i][j] = myMin(left, up) != INT_MAX ? myMin(left, up) + grid[i][j] : INT_MAX;
return mem[i][j];
}
```
@ -984,9 +984,12 @@ $$
```c title="min_path_sum.c"
/* 最小路径和:动态规划 */
int minPathSumDP(int gridCols, int grid[][gridCols], int n, int m) {
int minPathSumDP(int grid[MAX_SIZE][MAX_SIZE], int n, int m) {
// 初始化 dp 表
int dp[n][m];
int **dp = malloc(n * sizeof(int *));
for (int i = 0; i < n; i++) {
dp[i] = calloc(m, sizeof(int));
}
dp[0][0] = grid[0][0];
// 状态转移:首行
for (int j = 1; j < m; j++) {
@ -999,10 +1002,15 @@ $$
// 状态转移:其余行列
for (int i = 1; i < n; i++) {
for (int j = 1; j < m; j++) {
dp[i][j] = min(dp[i][j - 1], dp[i - 1][j]) + grid[i][j];
dp[i][j] = myMin(dp[i][j - 1], dp[i - 1][j]) + grid[i][j];
}
}
return dp[n - 1][m - 1];
int res = dp[n - 1][m - 1];
// 释放内存
for (int i = 0; i < n; i++) {
free(dp[i]);
}
return res;
}
```
@ -1344,9 +1352,9 @@ $$
```c title="min_path_sum.c"
/* 最小路径和:空间优化后的动态规划 */
int minPathSumDPComp(int gridCols, int grid[][gridCols], int n, int m) {
int minPathSumDPComp(int grid[MAX_SIZE][MAX_SIZE], int n, int m) {
// 初始化 dp 表
int dp[m];
int *dp = calloc(m, sizeof(int));
// 状态转移:首行
dp[0] = grid[0][0];
for (int j = 1; j < m; j++) {
@ -1358,10 +1366,13 @@ $$
dp[0] = dp[0] + grid[i][0];
// 状态转移:其余列
for (int j = 1; j < m; j++) {
dp[j] = min(dp[j - 1], dp[j]) + grid[i][j];
dp[j] = myMin(dp[j - 1], dp[j]) + grid[i][j];
}
}
return dp[m - 1];
int res = dp[m - 1];
// 释放内存
free(dp);
return res;
}
```

25
docs/chapter_dynamic_programming/edit_distance_problem.md
View file

@ -387,8 +387,10 @@ $$
```c title="edit_distance.c"
/* 编辑距离:动态规划 */
int editDistanceDP(char *s, char *t, int n, int m) {
int dp[n + 1][m + 1];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(m + 1, sizeof(int));
}
// 状态转移:首行首列
for (int i = 1; i <= n; i++) {
dp[i][0] = i;
@ -404,11 +406,16 @@ $$
dp[i][j] = dp[i - 1][j - 1];
} else {
// 最少编辑步数 = 插入、删除、替换这三种操作的最少编辑步数 + 1
dp[i][j] = min(min(dp[i][j - 1], dp[i - 1][j]), dp[i - 1][j - 1]) + 1;
dp[i][j] = myMin(myMin(dp[i][j - 1], dp[i - 1][j]), dp[i - 1][j - 1]) + 1;
}
}
}
return dp[n][m];
int res = dp[n][m];
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
return res;
}
```
@ -832,8 +839,7 @@ $$
```c title="edit_distance.c"
/* 编辑距离:空间优化后的动态规划 */
int editDistanceDPComp(char *s, char *t, int n, int m) {
int dp[m + 1];
memset(dp, 0, sizeof(dp));
int *dp = calloc(m + 1, sizeof(int));
// 状态转移:首行
for (int j = 1; j <= m; j++) {
dp[j] = j;
@ -851,12 +857,15 @@ $$
dp[j] = leftup;
} else {
// 最少编辑步数 = 插入、删除、替换这三种操作的最少编辑步数 + 1
dp[j] = min(min(dp[j - 1], dp[j]), leftup) + 1;
dp[j] = myMin(myMin(dp[j - 1], dp[j]), leftup) + 1;
}
leftup = temp; // 更新为下一轮的 dp[i-1, j-1]
}
}
return dp[m];
int res = dp[m];
// 释放内存
free(dp);
return res;
}
```

31
docs/chapter_dynamic_programming/knapsack_problem.md
View file

@ -291,7 +291,7 @@ $$
int no = knapsackDFS(wgt, val, i - 1, c);
int yes = knapsackDFS(wgt, val, i - 1, c - wgt[i - 1]) + val[i - 1];
// 返回两种方案中价值更大的那一个
return max(no, yes);
return myMax(no, yes);
}
```
@ -606,7 +606,7 @@ $$
```c title="knapsack.c"
/* 0-1 背包:记忆化搜索 */
int knapsackDFSMem(int wgt[], int val[], int memCols, int mem[][memCols], int i, int c) {
int knapsackDFSMem(int wgt[], int val[], int memCols, int **mem, int i, int c) {
// 若已选完所有物品或背包无容量,则返回价值 0
if (i == 0 || c == 0) {
return 0;
@ -623,7 +623,7 @@ $$
int no = knapsackDFSMem(wgt, val, memCols, mem, i - 1, c);
int yes = knapsackDFSMem(wgt, val, memCols, mem, i - 1, c - wgt[i - 1]) + val[i - 1];
// 记录并返回两种方案中价值更大的那一个
mem[i][c] = max(no, yes);
mem[i][c] = myMax(no, yes);
return mem[i][c];
}
```
@ -924,8 +924,10 @@ $$
int knapsackDP(int wgt[], int val[], int cap, int wgtSize) {
int n = wgtSize;
// 初始化 dp 表
int dp[n + 1][cap + 1];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(cap + 1, sizeof(int));
}
// 状态转移
for (int i = 1; i <= n; i++) {
for (int c = 1; c <= cap; c++) {
@ -934,11 +936,16 @@ $$
dp[i][c] = dp[i - 1][c];
} else {
// 不选和选物品 i 这两种方案的较大值
dp[i][c] = max(dp[i - 1][c], dp[i - 1][c - wgt[i - 1]] + val[i - 1]);
dp[i][c] = myMax(dp[i - 1][c], dp[i - 1][c - wgt[i - 1]] + val[i - 1]);
}
}
}
return dp[n][cap];
int res = dp[n][cap];
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
return res;
}
```
@ -1278,19 +1285,21 @@ $$
int knapsackDPComp(int wgt[], int val[], int cap, int wgtSize) {
int n = wgtSize;
// 初始化 dp 表
int dp[cap + 1];
memset(dp, 0, sizeof(dp));
int *dp = calloc(cap + 1, sizeof(int));
// 状态转移
for (int i = 1; i <= n; i++) {
// 倒序遍历
for (int c = cap; c >= 1; c--) {
if (wgt[i - 1] <= c) {
// 不选和选物品 i 这两种方案的较大值
dp[c] = max(dp[c], dp[c - wgt[i - 1]] + val[i - 1]);
dp[c] = myMax(dp[c], dp[c - wgt[i - 1]] + val[i - 1]);
}
}
}
return dp[cap];
int res = dp[cap];
// 释放内存
free(dp);
return res;
}
```

73
docs/chapter_dynamic_programming/unbounded_knapsack_problem.md
View file

@ -298,8 +298,10 @@ $$
int unboundedKnapsackDP(int wgt[], int val[], int cap, int wgtSize) {
int n = wgtSize;
// 初始化 dp 表
int dp[n + 1][cap + 1];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(cap + 1, sizeof(int));
}
// 状态转移
for (int i = 1; i <= n; i++) {
for (int c = 1; c <= cap; c++) {
@ -308,11 +310,16 @@ $$
dp[i][c] = dp[i - 1][c];
} else {
// 不选和选物品 i 这两种方案的较大值
dp[i][c] = max(dp[i - 1][c], dp[i][c - wgt[i - 1]] + val[i - 1]);
dp[i][c] = myMax(dp[i - 1][c], dp[i][c - wgt[i - 1]] + val[i - 1]);
}
}
}
return dp[n][cap];
int res = dp[n][cap];
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
return res;
}
```
@ -616,8 +623,7 @@ $$
int unboundedKnapsackDPComp(int wgt[], int val[], int cap, int wgtSize) {
int n = wgtSize;
// 初始化 dp 表
int dp[cap + 1];
memset(dp, 0, sizeof(dp));
int *dp = calloc(cap + 1, sizeof(int));
// 状态转移
for (int i = 1; i <= n; i++) {
for (int c = 1; c <= cap; c++) {
@ -626,11 +632,14 @@ $$
dp[c] = dp[c];
} else {
// 不选和选物品 i 这两种方案的较大值
dp[c] = max(dp[c], dp[c - wgt[i - 1]] + val[i - 1]);
dp[c] = myMax(dp[c], dp[c - wgt[i - 1]] + val[i - 1]);
}
}
}
return dp[cap];
int res = dp[cap];
// 释放内存
free(dp);
return res;
}
```
@ -1012,8 +1021,10 @@ $$
int n = coinsSize;
int MAX = amt + 1;
// 初始化 dp 表
int dp[n + 1][amt + 1];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(amt + 1, sizeof(int));
}
// 状态转移:首行首列
for (int a = 1; a <= amt; a++) {
dp[0][a] = MAX;
@ -1026,11 +1037,17 @@ $$
dp[i][a] = dp[i - 1][a];
} else {
// 不选和选硬币 i 这两种方案的较小值
dp[i][a] = min(dp[i - 1][a], dp[i][a - coins[i - 1]] + 1);
dp[i][a] = myMin(dp[i - 1][a], dp[i][a - coins[i - 1]] + 1);
}
}
}
return dp[n][amt] != MAX ? dp[n][amt] : -1;
int res = dp[n][amt] != MAX ? dp[n][amt] : -1;
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
free(dp);
return res;
}
```
@ -1394,8 +1411,7 @@ $$
int n = coinsSize;
int MAX = amt + 1;
// 初始化 dp 表
int dp[amt + 1];
memset(dp, MAX, sizeof(dp));
int *dp = calloc(amt + 1, sizeof(int));
dp[0] = 0;
// 状态转移
for (int i = 1; i <= n; i++) {
@ -1405,11 +1421,14 @@ $$
dp[a] = dp[a];
} else {
// 不选和选硬币 i 这两种方案的较小值
dp[a] = min(dp[a], dp[a - coins[i - 1]] + 1);
dp[a] = myMin(dp[a], dp[a - coins[i - 1]] + 1);
}
}
}
return dp[amt] != MAX ? dp[amt] : -1;
int res = dp[amt] != MAX ? dp[amt] : -1;
// 释放内存
free(dp);
return res;
}
```
@ -1757,8 +1776,10 @@ $$
int coinChangeIIDP(int coins[], int amt, int coinsSize) {
int n = coinsSize;
// 初始化 dp 表
int dp[n + 1][amt + 1];
memset(dp, 0, sizeof(dp));
int **dp = malloc((n + 1) * sizeof(int *));
for (int i = 0; i <= n; i++) {
dp[i] = calloc(amt + 1, sizeof(int));
}
// 初始化首列
for (int i = 0; i <= n; i++) {
dp[i][0] = 1;
@ -1775,7 +1796,13 @@ $$
}
}
}
return dp[n][amt];
int res = dp[n][amt];
// 释放内存
for (int i = 0; i <= n; i++) {
free(dp[i]);
}
free(dp);
return res;
}
```
@ -2066,8 +2093,7 @@ $$
int coinChangeIIDPComp(int coins[], int amt, int coinsSize) {
int n = coinsSize;
// 初始化 dp 表
int dp[amt + 1];
memset(dp, 0, sizeof(dp));
int *dp = calloc(amt + 1, sizeof(int));
dp[0] = 1;
// 状态转移
for (int i = 1; i <= n; i++) {
@ -2081,7 +2107,10 @@ $$
}
}
}
return dp[amt];
int res = dp[amt];
// 释放内存
free(dp);
return res;
}
```

4
docs/chapter_greedy/max_capacity_problem.md
View file

@ -355,8 +355,8 @@ $$
// 循环贪心选择,直至两板相遇
while (i < j) {
// 更新最大容量
int capacity = MIN(ht[i], ht[j]) * (j - i);
res = MAX(res, capacity);
int capacity = myMin(ht[i], ht[j]) * (j - i);
res = myMax(res, capacity);
// 向内移动短板
if (ht[i] < ht[j]) {
i++;

2
docs/chapter_heap/top_k.md
View file

@ -392,7 +392,7 @@ comments: true
int *topKHeap(int *nums, int sizeNums, int k) {
// 初始化小顶堆
// 请注意:我们将堆中所有元素取反,从而用大顶堆来模拟小顶堆
int empty[0];
int *empty = (int *)malloc(0);
MaxHeap *maxHeap = newMaxHeap(empty, 0);
// 将数组的前 k 个元素入堆
for (int i = 0; i < k; i++) {

14
docs/chapter_sorting/bucket_sort.md
View file

@ -283,11 +283,11 @@ comments: true
List<List<double>> buckets = List.generate(k, (index) => []);
// 1. 将数组元素分配到各个桶中
for (double num in nums) {
// 输入数据范围 [0, 1),使用 num * k 映射到索引范围 [0, k-1]
int i = (num * k).toInt();
// 将 num 添加进桶 bucket_idx
buckets[i].add(num);
for (double _num in nums) {
// 输入数据范围 [0, 1),使用 _num * k 映射到索引范围 [0, k-1]
int i = (_num * k).toInt();
// 将 _num 添加进桶 bucket_idx
buckets[i].add(_num);
}
// 2. 对各个桶执行排序
for (List<double> bucket in buckets) {
@ -296,8 +296,8 @@ comments: true
// 3. 遍历桶合并结果
int i = 0;
for (List<double> bucket in buckets) {
for (double num in bucket) {
nums[i++] = num;
for (double _num in bucket) {
nums[i++] = _num;
}
}
}

34
docs/chapter_sorting/counting_sort.md
View file

@ -238,20 +238,20 @@ comments: true
void countingSortNaive(List<int> nums) {
// 1. 统计数组最大元素 m
int m = 0;
for (int num in nums) {
m = max(m, num);
for (int _num in nums) {
m = max(m, _num);
}
// 2. 统计各数字的出现次数
// counter[num] 代表 num 的出现次数
// counter[_num] 代表 _num 的出现次数
List<int> counter = List.filled(m + 1, 0);
for (int num in nums) {
counter[num]++;
for (int _num in nums) {
counter[_num]++;
}
// 3. 遍历 counter ,将各元素填入原数组 nums
int i = 0;
for (int num = 0; num < m + 1; num++) {
for (int j = 0; j < counter[num]; j++, i++) {
nums[i] = num;
for (int _num = 0; _num < m + 1; _num++) {
for (int j = 0; j < counter[_num]; j++, i++) {
nums[i] = _num;
}
}
}
@ -666,17 +666,17 @@ $$
void countingSort(List<int> nums) {
// 1. 统计数组最大元素 m
int m = 0;
for (int num in nums) {
m = max(m, num);
for (int _num in nums) {
m = max(m, _num);
}
// 2. 统计各数字的出现次数
// counter[num] 代表 num 的出现次数
// counter[_num] 代表 _num 的出现次数
List<int> counter = List.filled(m + 1, 0);
for (int num in nums) {
counter[num]++;
for (int _num in nums) {
counter[_num]++;
}
// 3. 求 counter 的前缀和,将“出现次数”转换为“尾索引”
// 即 counter[num]-1 是 num 在 res 中最后一次出现的索引
// 即 counter[_num]-1 是 _num 在 res 中最后一次出现的索引
for (int i = 0; i < m; i++) {
counter[i + 1] += counter[i];
}
@ -685,9 +685,9 @@ $$
int n = nums.length;
List<int> res = List.filled(n, 0);
for (int i = n - 1; i >= 0; i--) {
int num = nums[i];
res[counter[num] - 1] = num; // 将 num 放置到对应索引处
counter[num]--; // 令前缀和自减 1 ,得到下次放置 num 的索引
int _num = nums[i];
res[counter[_num] - 1] = _num; // 将 _num 放置到对应索引处
counter[_num]--; // 令前缀和自减 1 ,得到下次放置 _num 的索引
}
// 使用结果数组 res 覆盖原数组 nums
nums.setAll(0, res);

8
docs/chapter_sorting/radix_sort.md
View file

@ -465,10 +465,10 @@ $$
=== "Dart"
```dart title="radix_sort.dart"
/* 获取元素 num 的第 k 位,其中 exp = 10^(k-1) */
int digit(int num, int exp) {
/* 获取元素 _num 的第 k 位,其中 exp = 10^(k-1) */
int digit(int _num, int exp) {
// 传入 exp 而非 k 可以避免在此重复执行昂贵的次方计算
return (num ~/ exp) % 10;
return (_num ~/ exp) % 10;
}
/* 计数排序(根据 nums 第 k 位排序) */
@ -502,7 +502,7 @@ $$
// 获取数组的最大元素,用于判断最大位数
// dart 中 int 的长度是 64 位的
int m = -1 << 63;
for (int num in nums) if (num > m) m = num;
for (int _num in nums) if (_num > m) m = _num;
// 按照从低位到高位的顺序遍历
for (int exp = 1; exp <= m; exp *= 10)
// 对数组元素的第 k 位执行计数排序

45
docs/chapter_stack_and_queue/deque.md
View file

@ -1417,8 +1417,8 @@ comments: true
}
/* 入队操作 */
void push(int num, bool isFront) {
final ListNode node = ListNode(num);
void push(int _num, bool isFront) {
final ListNode node = ListNode(_num);
if (isEmpty()) {
// 若链表为空,则令 _front 和 _rear 都指向 node
_front = _rear = node;
@ -1439,13 +1439,13 @@ comments: true
}
/* 队首入队 */
void pushFirst(int num) {
push(num, true);
void pushFirst(int _num) {
push(_num, true);
}
/* 队尾入队 */
void pushLast(int num) {
push(num, false);
void pushLast(int _num) {
push(_num, false);
}
/* 出队操作 */
@ -1831,7 +1831,7 @@ comments: true
/* 打印队列 */
void printLinkedListDeque(LinkedListDeque *deque) {
int arr[deque->queSize];
int *arr = malloc(sizeof(int) * deque->queSize);
// 拷贝链表中的数据到数组
int i;
DoublyListNode *node;
@ -1840,6 +1840,7 @@ comments: true
node = node->next;
}
printArray(arr, deque->queSize);
free(arr);
}
```
@ -2927,44 +2928,44 @@ comments: true
}
/* 队首入队 */
void pushFirst(int num) {
void pushFirst(int _num) {
if (_queSize == capacity()) {
throw Exception("双向队列已满");
}
// 队首指针向左移动一位
// 通过取余操作,实现 _front 越过数组头部后回到尾部
_front = index(_front - 1);
// 将 num 添加至队首
_nums[_front] = num;
// 将 _num 添加至队首
_nums[_front] = _num;
_queSize++;
}
/* 队尾入队 */
void pushLast(int num) {
void pushLast(int _num) {
if (_queSize == capacity()) {
throw Exception("双向队列已满");
}
// 计算尾指针,指向队尾索引 + 1
int rear = index(_front + _queSize);
// 将 num 添加至队尾
_nums[rear] = num;
// 将 _num 添加至队尾
_nums[rear] = _num;
_queSize++;
}
/* 队首出队 */
int popFirst() {
int num = peekFirst();
int _num = peekFirst();
// 队首指针向右移动一位
_front = index(_front + 1);
_queSize--;
return num;
return _num;
}
/* 队尾出队 */
int popLast() {
int num = peekLast();
int _num = peekLast();
_queSize--;
return num;
return _num;
}
/* 访问队首元素 */
@ -3218,16 +3219,6 @@ comments: true
deque->queSize--;
return num;
}
/* 打印队列 */
void printArrayDeque(ArrayDeque *deque) {
int arr[deque->queSize];
// 拷贝
for (int i = 0, j = deque->front; i < deque->queSize; i++, j++) {
arr[i] = deque->nums[j % deque->queCapacity];
}
printArray(arr, deque->queSize);
}
```
=== "Zig"

33
docs/chapter_stack_and_queue/queue.md
View file

@ -900,9 +900,9 @@ comments: true
}
/* 入队 */
void push(int num) {
// 尾节点后添加 num
final node = ListNode(num);
void push(int _num) {
// 尾节点后添加 _num
final node = ListNode(_num);
// 如果队列为空,则令头、尾节点都指向该节点
if (_front == null) {
_front = node;
@ -917,11 +917,11 @@ comments: true
/* 出队 */
int pop() {
final int num = peek();
final int _num = peek();
// 删除头节点
_front = _front!.next;
_queSize--;
return num;
return _num;
}
/* 访问队首元素 */
@ -1101,7 +1101,7 @@ comments: true
/* 打印队列 */
void printLinkedListQueue(LinkedListQueue *queue) {
int arr[queue->queSize];
int *arr = malloc(sizeof(int) * queue->queSize);
// 拷贝链表中的数据到数组
int i;
ListNode *node;
@ -1110,6 +1110,7 @@ comments: true
node = node->next;
}
printArray(arr, queue->queSize);
free(arr);
}
```
@ -1825,25 +1826,25 @@ comments: true
}
/* 入队 */
void push(int num) {
void push(int _num) {
if (_queSize == capaCity()) {
throw Exception("队列已满");
}
// 计算尾指针,指向队尾索引 + 1
// 通过取余操作,实现 rear 越过数组尾部后回到头部
int rear = (_front + _queSize) % capaCity();
// 将 num 添加至队尾
_nums[rear] = num;
// 将 _num 添加至队尾
_nums[rear] = _num;
_queSize++;
}
/* 出队 */
int pop() {
int num = peek();
int _num = peek();
// 队首指针向后移动一位,若越过尾部则返回到数组头部
_front = (_front + 1) % capaCity();
_queSize--;
return num;
return _num;
}
/* 访问队首元素 */
@ -2017,16 +2018,6 @@ comments: true
queue->front = (queue->front + 1) % queue->queCapacity;
queue->queSize--;
}
/* 打印队列 */
void printArrayQueue(ArrayQueue *queue) {
int arr[queue->queSize];
// 拷贝
for (int i = 0, j = queue->front; i < queue->queSize; i++, j++) {
arr[i] = queue->nums[j % queue->queCapacity];
}
printArray(arr, queue->queSize);
}
```
=== "Zig"

12
docs/chapter_stack_and_queue/stack.md
View file

@ -827,8 +827,8 @@ comments: true
}
/* 入栈 */
void push(int num) {
final ListNode node = ListNode(num);
void push(int _num) {
final ListNode node = ListNode(_num);
node.next = _stackPeek;
_stackPeek = node;
_stkSize++;
@ -836,10 +836,10 @@ comments: true
/* 出栈 */
int pop() {
final int num = peek();
final int _num = peek();
_stackPeek = _stackPeek!.next;
_stkSize--;
return num;
return _num;
}
/* 访问栈顶元素 */
@ -1495,8 +1495,8 @@ comments: true
}
/* 入栈 */
void push(int num) {
_stack.add(num);
void push(int _num) {
_stack.add(_num);
}
/* 出栈 */

24
docs/chapter_tree/binary_search_tree.md
View file

@ -224,15 +224,15 @@ comments: true
```dart title="binary_search_tree.dart"
/* 查找节点 */
TreeNode? search(int num) {
TreeNode? search(int _num) {
TreeNode? cur = _root;
// 循环查找,越过叶节点后跳出
while (cur != null) {
// 目标节点在 cur 的右子树中
if (cur.val < num)
if (cur.val < _num)
cur = cur.right;
// 目标节点在 cur 的左子树中
else if (cur.val > num)
else if (cur.val > _num)
cur = cur.left;
// 找到目标节点,跳出循环
else
@ -601,10 +601,10 @@ comments: true
```dart title="binary_search_tree.dart"
/* 插入节点 */
void insert(int num) {
void insert(int _num) {
// 若树为空,则初始化根节点
if (_root == null) {
_root = TreeNode(num);
_root = TreeNode(_num);
return;
}
TreeNode? cur = _root;
@ -612,18 +612,18 @@ comments: true
// 循环查找,越过叶节点后跳出
while (cur != null) {
// 找到重复节点,直接返回
if (cur.val == num) return;
if (cur.val == _num) return;
pre = cur;
// 插入位置在 cur 的右子树中
if (cur.val < num)
if (cur.val < _num)
cur = cur.right;
// 插入位置在 cur 的左子树中
else
cur = cur.left;
}
// 插入节点
TreeNode? node = TreeNode(num);
if (pre!.val < num)
TreeNode? node = TreeNode(_num);
if (pre!.val < _num)
pre.right = node;
else
pre.left = node;
@ -1234,7 +1234,7 @@ comments: true
```dart title="binary_search_tree.dart"
/* 删除节点 */
void remove(int num) {
void remove(int _num) {
// 若树为空,直接提前返回
if (_root == null) return;
TreeNode? cur = _root;
@ -1242,10 +1242,10 @@ comments: true
// 循环查找,越过叶节点后跳出
while (cur != null) {
// 找到待删除节点,跳出循环
if (cur.val == num) break;
if (cur.val == _num) break;
pre = cur;
// 待删除节点在 cur 的右子树中
if (cur.val < num)
if (cur.val < _num)
cur = cur.right;
// 待删除节点在 cur 的左子树中
else