1. Direct Insert Sort
The process of directly inserting a sort can be understood as a fixed-length array that is divided into two sets, that is, sorted and unordered.
Initially, the sorted collection is empty, and the unordered collection is the entire array. When a sort begins to insert an object, the sorted collection element number is 1, the number of unordered collection elements is reduced by 1, and the insertion process is repeated until the unordered collection is emptied, and the sorted collection is the final result. Such as:
C + + implementation is as follows, in order to make the program can be a variety of basic data types can be sorted, using the template class, Notice that the template class declaration and member function implementation must be in the same CPP file, cannot separate!!
1 #ifndef Insertsort_h2 #defineInsertsort_h3#include <vector>4#include <iostream>5 usingstd::cout;6 usingStd::endl;7 usingstd::vector;8 9Template <typename t>Ten classInsertsort One { A Private: - unsigned len; -Vector<t>list; the Public: -Insertsort (vector<t>_list, unsigned _len) - { - for(Unsigned i =0; i < _len; ++i) list.push_back (_list[i]); + This->len =_len; - } + voidInsertsort () A { at T Insertnum; - for(Unsigned i =0; i < Len; ++i)//Insert number for Len Times - { -Insertnum = List[i];//The number is to be inserted -unsigned j =i; - while(J && Insertnum < list[j-1])//Find the position to insert the target number in in { -LIST[J] = list[j-1]; to--J; + } -LIST[J] =Insertnum; the } * } $ void out()Panax Notoginseng { - for(Unsigned i =0; i < Len; ++i) the { +cout << List[i] <<" "; A if((i+1)% -==0) cout <<Endl; the } +cout <<Endl; - } $ }; $ #endif
2. Two-point insertion sort
Because the direct insertion sort is very inefficient when searching for the insertion position, especially for large arrays, the binary insertion sort is called binary insert Sort, and the binary insertion sort is using binary lookup to find the location to insert .
The following shows the position of the binary lookup method to determine the number 35 in the target array:
- First, determine the median position of the target array as 45 digits.
- Because of the > 35, the descending array binary and takes the left half molecule array as the search target, the middle element of the left half is 23
- Since the < 35, so binary, select half of the sub-array as the search target
- And the < 36, so that 35 of the position between 23 and 36.
The C + + implementation is given below:
1 #ifndef Binaryinsertsort_h2 #defineBinaryinsertsort_h3#include <vector>4 usingstd::vector;5Template <typename t>6 classBinaryinsertsort7 {8 Private:9 intLen;TenVector<t>list; One Public: ABinaryinsertsort (vector<t> _list,int_len) - { - for(inti =0; i < _len; ++i) list.push_back (_list[i]); the This->len =_len; - } - voidBinaryinsertsort () - { + intMiddle; - for(inti =0; i < Len; ++i) + { AT Insertnum =List[i]; at intleft =0; - intright = i-1; - while(left <= right)//Find the insertation position with binary search - { -Middle = (left + right)/2; - if(Insertnum >List[middle]) inleft = middle +1; - Else toright = Middle-1; + } - for(intj = i; J > left; --J) List[j] = list[j-1]; theList[left] =Insertnum; * } $ }Panax Notoginseng void out() - { the for(Unsigned i =0; i < Len; ++i) + { Acout << List[i] <<" "; the if((i+1)% -==0) cout <<Endl; + } -cout <<Endl; $ } $ }; - #endif
3. Test run
1#include"InsertSort.h"2#include"BinaryInsertSort.h"3#include <vector>4 using namespacestd;5 6 Constunsigned numele =8;7 intData[numele] = {1,5,7,3,8,2,6,4};8 9 Ten intMain () One { Avector<int>TestData; - for(Unsigned i =0; i < Numele; ++i) testdata.push_back (Data[i]); - //insertsort<int> Test (TestData, numele); the //Test.insertsort (); -binaryinsertsort<int>Test (TestData, numele); - Test.binaryinsertsort (); -Test. out(); + return 0; - +}
4. References
murmured: The principle of C + + data structure and classical problem solving
C + + implementation of direct insertion sorting and binary insertion sorting