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add selection sort
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.gitignore
vendored
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# ---> Hugo
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# Generated files by hugo
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/public/
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/resources/_gen/
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/assets/jsconfig.json
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hugo_stats.json
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# Executable may be added to repository
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hugo.exe
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hugo.darwin
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hugo.linux
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# Temporary lock file while building
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/.hugo_build.lock
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# Ignore swap files
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*.swp
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*~
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9
content/_index.md
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content/_index.md
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---
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title: "Data Strcutures and Algorithms"
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date: 2024-05-28T08:15:27+05:30
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type: docs
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---
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# Data Structures and Algorithms
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On this website, I document my explorations into the realm of Data Structures and Algorithms to serve as a personal resource for future reflection.
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content/docs/dsa/sorting/_index.md
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content/docs/dsa/sorting/_index.md
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---
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title: "Sorting"
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date: 2024-05-28T07:49:20+05:30
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bookCollapseSection: true
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---
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# Sorting
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This section contains entries related to sorting algorithms.
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Sorting in data structures and algorithms involves rearranging a collection of items, such as
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numbers or strings, into a sequence or list where the elements are organized according to a
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particular criterion (e.g., ascending numerical value). Various algorithms have been developed for
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this purpose, each with its own advantages and trade-offs in terms of time complexity, space
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efficiency, stability, adaptability, and ease of implementation. Some widely known sorting
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algorithms include:
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1. **Bubble Sort** - A simple comparison-based algorithm that repeatedly steps through the list,
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compares adjacent elements, and swaps them if they are in the wrong order. It has a time complexity
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of O(n^2) in its average and worst cases.
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2. **Selection Sort** - This algorithm divides the input list into two parts: a sorted sublist of
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items that are built up from left to right at the front (or beginning) of the list, and an unsorted
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sublist. On each iteration, it selects the smallest or largest element (depending on sorting order)
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from the unsorted sublist and moves that element to the end of the sorted sublist. Its time
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complexity is O(n^2).
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3. **Insertion Sort** - Builds the final sorted array one item at a time. It has an average and
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worst-case performance of O(n^2), but it's efficient for small datasets or nearly sorted arrays,
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with best-case time complexity being O(n).
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4. **Merge Sort** - A divide-and-conquer algorithm that divides the input array into two halves,
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recursively sorts them, and then merges the two sorted halves together. It has a time complexity of
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O(n log n) in all cases.
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5. **Quick Sort** - Also utilizes a divide-and-conquer strategy by selecting a 'pivot' element from
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the array and partitioning the other elements into two sub-arrays, according to whether they are
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less than or greater than the pivot. The time complexity in average cases is O(n log n), but it can
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degrade to O(n^2) if the smallest or largest element is always chosen as the pivot.
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6. **Heap Sort** - Builds a heap data structure from the input data and then repeatedly extracts
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the maximum (or minimum) element from the heap, swapping it with the last item in the unsorted
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portion of the array, and re-heaping the reduced array. The time complexity is O(n log n).
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7. **Radix Sort** - This non-comparative integer sorting algorithm sorts data with integer keys by
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grouping keys by the individual digits which share the same significant position and value (radix).
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It has a linear time complexity of O(nk) where k is the number of passes of the sorting algorithm
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and n is the number of elements.
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8. **Counting Sort** - Suitable for sorting integer arrays when the range of potential items in the
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input (i.e., their possible key values) is relatively small compared to the number of items. Its
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time complexity varies based on the specific implementation but generally has a linear time
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complexity, O(n+k), where k is the range of the input.
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9. **Bucket Sort** - Works by distributing elements into several 'buckets' and then sorting these
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buckets individually using a different sorting algorithm or by recursively applying bucket sort to
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each bucket. Its time complexity can be as good as O(n+k) where n is the number of elements and k
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is the number of buckets, but it often performs better than O(n log n).
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10. **Timsort** - A hybrid sorting algorithm derived from merge sort and insertion sort designed to
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perform well on many kinds of real-world data. It's used as the default sort in Python and Java.
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Timsort has a time complexity of O(n log n) for average and worst cases.
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The choice of a particular sorting algorithm depends on several factors, including but not limited
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to: the size and nature of the dataset, the computational resources available (such as CPU and
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memory), the desired level of stability in the output, whether parallel computing is involved, etc.
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{{<section summary >}}
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content/docs/dsa/sorting/selection-sort.md
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content/docs/dsa/sorting/selection-sort.md
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---
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title: "Selection Sort"
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date: 2024-05-28T07:49:30+05:30
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---
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# Selection Sort
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Selection Sort is a simple comparison-based sorting algorithm. It operates by repeatedly finding
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the minimum element (considering ascending order) from the unsorted part of an array and putting it
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at the beginning. The process involves dividing the input list into two parts: a sorted sublist
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which is built up from left to right, and an unsorted sublist where elements are not yet in their
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final position.
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<!--more-->
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## Algorithm
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Here's how Selection Sort works step by step:
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1. Start with the first element of the array as the minimum.
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2. Compare this "current" minimum with the rest of the array to find a new minimum.
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3. Once you have found the true minimum, swap it with the value at the current position.
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4. Move one position ahead in the array and consider this element as part of the unsorted segment
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while treating the remaining elements as the sorted sublist.
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5. Repeat steps 2-4 until the entire list is sorted.
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The algorithm's time complexity is O(n<sup>2</sup>) for all cases (worst, average, and best), making it
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inefficient on large lists compared to more advanced algorithms like quicksort, mergesort or
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heapsort. However, Selection Sort has its advantages such as simplicity and performing only a
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minimal number of swaps, which can be beneficial when the cost of swap is high.
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## Code
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Here is an implementation in C++.
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```cpp
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import <print>;
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import <vector>;
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constexpr auto sort(std::vector<ssize_t> &vec) -> void {
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for (auto it1{vec.begin()}; it1 < vec.end(); ++it1) {
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auto it{it1};
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for (auto it2{it1 + 1}; it2 < vec.end(); ++it2) {
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if (*it2 < *it) {
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it = it2;
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}
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}
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auto temp{*it1};
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*it1 = *it;
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*it = temp;
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}
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}
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int main() {
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std::vector<ssize_t> v{4, 7, 3, 7, 2, 7, 4, 64, 32, 65,
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32, 4, 5, 5, 6456, 4, 5, 53, 5};
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sort(v);
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for (const auto &a : v) {
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std::print("{} ", a);
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}
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return 0;
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}
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```
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## Explanation
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### Function Signature
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```cpp
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constexpr auto sort(std::vector<ssize_t> &vec) -> void
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```
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- `constexpr`: This keyword indicates that the function can be evaluated at compile time if provided with constant expressions. This is useful for performance optimization in some cases.
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- `auto sort`: Uses the auto keyword to automatically deduce the return type. In this case, the return type is explicitly specified as `void`.
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- `(std::vector<ssize_t> &vec)`: The function takes a reference to a `std::vector` of `ssize_t` integers as its parameter. Using a reference avoids copying the vector and allows the function to modify the original vector.
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- `-> void`: This specifies the return type of the function, which is `void` (meaning it doesn't return a value).
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### Function Body
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```cpp
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{
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for (auto it1{vec.begin()}; it1 < vec.end(); ++it1) {
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auto it{it1};
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for (auto it2{it1 + 1}; it2 < vec.end(); ++it2) {
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if (*it2 < *it) {
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it = it2;
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}
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}
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auto temp{*it1};
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*it1 = *it;
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*it = temp;
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}
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}
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```
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1. **Outer Loop (Selection Sort)**:
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```cpp
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for (auto it1{vec.begin()}; it1 < vec.end(); ++it1)
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```
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- This loop iterates over each element of the vector from the beginning to the end.
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- `it1` is an iterator starting from the beginning of the vector and moving towards the end.
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2. **Inner Loop (Finding Minimum)**
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```cpp
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auto it{it1};
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for (auto it2{it1 + 1}; it2 < vec.end(); ++it2) {
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if (*it2 < *it) {
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it = it2;
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}
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}
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```
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- The inner loop starts from the next element after `it1` and iterates to the end of the vector.
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- `it` initially points to `it1`, which is the current element in the outer loop.
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- `it2` iterates over the remaining elements to find the smallest element.
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- If `*it2` (the value pointed to by `it2`) is smaller than `*it` (the value pointed to by `it`), `it` is updated to point to `it2`.
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3. **Swapping Elements**:
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```cpp
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auto temp{*it1};
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*it1 = *it;
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*it = temp;
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```
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- After finding the smallest element in the unsorted portion of the vector, the smallest element (pointed to by `it`) is swapped with the element at the position `it1`.
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- `temp` temporarily holds the value of `*it1`.
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- `*it1` is set to `*it` (the smallest element found).
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- `*it` is then set to `temp` to complete the swap.
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## Output
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```console
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❯ ./main
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2 3 4 4 4 4 5 5 5 5 7 7 7 32 32 53 64 65 6456 [ble: EOF]
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```
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