How can I make an algorithm in C++ for finding variations of a set without repetition (i.e. n elements,...












7















For example, (n = 3, k = 2), I have set {1, 2, 3} and I need my algorithm to find:
{1, 2}, {1, 3}, {2, 1}, {2, 3}, {3, 1}, {3, 2}.



I was able to make an algorithm with next_permutation, but it works very slow for n = 10, k = 4 (which is what I need).



Here's my code:



#include <iostream>
#include <algorithm>

#define pb push_back

using namespace std;

int main() {
vector <int> s = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int k = 4; // (n = 10, k = 4)
map <string, int> m; // To check if we already have that variation

vector <string> v; // Variations
do {
string str = "";
for (int i = 0; i < k; i++) str += to_string(s[i]);
if (m[str] == 0) {
m[str] = 1;
v.pb(str);
}
} while (next_permutation(s.begin(), s.end()));

return 0;
}


How can I make an algorithm that does this faster?










share|improve this question




















  • 1





    You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

    – Jarod42
    12 hours ago













  • @Jarod42 how do I use next_permutation on bitset? I can't find how to.

    – Pero
    11 hours ago
















7















For example, (n = 3, k = 2), I have set {1, 2, 3} and I need my algorithm to find:
{1, 2}, {1, 3}, {2, 1}, {2, 3}, {3, 1}, {3, 2}.



I was able to make an algorithm with next_permutation, but it works very slow for n = 10, k = 4 (which is what I need).



Here's my code:



#include <iostream>
#include <algorithm>

#define pb push_back

using namespace std;

int main() {
vector <int> s = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int k = 4; // (n = 10, k = 4)
map <string, int> m; // To check if we already have that variation

vector <string> v; // Variations
do {
string str = "";
for (int i = 0; i < k; i++) str += to_string(s[i]);
if (m[str] == 0) {
m[str] = 1;
v.pb(str);
}
} while (next_permutation(s.begin(), s.end()));

return 0;
}


How can I make an algorithm that does this faster?










share|improve this question




















  • 1





    You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

    – Jarod42
    12 hours ago













  • @Jarod42 how do I use next_permutation on bitset? I can't find how to.

    – Pero
    11 hours ago














7












7








7








For example, (n = 3, k = 2), I have set {1, 2, 3} and I need my algorithm to find:
{1, 2}, {1, 3}, {2, 1}, {2, 3}, {3, 1}, {3, 2}.



I was able to make an algorithm with next_permutation, but it works very slow for n = 10, k = 4 (which is what I need).



Here's my code:



#include <iostream>
#include <algorithm>

#define pb push_back

using namespace std;

int main() {
vector <int> s = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int k = 4; // (n = 10, k = 4)
map <string, int> m; // To check if we already have that variation

vector <string> v; // Variations
do {
string str = "";
for (int i = 0; i < k; i++) str += to_string(s[i]);
if (m[str] == 0) {
m[str] = 1;
v.pb(str);
}
} while (next_permutation(s.begin(), s.end()));

return 0;
}


How can I make an algorithm that does this faster?










share|improve this question
















For example, (n = 3, k = 2), I have set {1, 2, 3} and I need my algorithm to find:
{1, 2}, {1, 3}, {2, 1}, {2, 3}, {3, 1}, {3, 2}.



I was able to make an algorithm with next_permutation, but it works very slow for n = 10, k = 4 (which is what I need).



Here's my code:



#include <iostream>
#include <algorithm>

#define pb push_back

using namespace std;

int main() {
vector <int> s = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
int k = 4; // (n = 10, k = 4)
map <string, int> m; // To check if we already have that variation

vector <string> v; // Variations
do {
string str = "";
for (int i = 0; i < k; i++) str += to_string(s[i]);
if (m[str] == 0) {
m[str] = 1;
v.pb(str);
}
} while (next_permutation(s.begin(), s.end()));

return 0;
}


How can I make an algorithm that does this faster?







c++ algorithm permutation






share|improve this question















share|improve this question













share|improve this question




share|improve this question








edited 29 mins ago









Peter Mortensen

13.7k1986112




13.7k1986112










asked 12 hours ago









PeroPero

456




456








  • 1





    You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

    – Jarod42
    12 hours ago













  • @Jarod42 how do I use next_permutation on bitset? I can't find how to.

    – Pero
    11 hours ago














  • 1





    You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

    – Jarod42
    12 hours ago













  • @Jarod42 how do I use next_permutation on bitset? I can't find how to.

    – Pero
    11 hours ago








1




1





You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

– Jarod42
12 hours ago







You might use next_permutation on a bitset (of size n, with k true). bitset shows valid item from the vector.

– Jarod42
12 hours ago















@Jarod42 how do I use next_permutation on bitset? I can't find how to.

– Pero
11 hours ago





@Jarod42 how do I use next_permutation on bitset? I can't find how to.

– Pero
11 hours ago












4 Answers
4






active

oldest

votes


















5














This code generates arrangements of k items from n in lexicographic order, packed into integer for simplicity (so 153 corresponds to (1,5,3))



void GenArrangement(int n, int k, int idx, int used, int arran) {
if (idx == k) {
std::cout << arran << std::endl;
return;
}

for (int i = 0; i < n; i++)
if (0 == (used & (1 << i)))
GenArrangement(n, k, idx + 1, used | (1 << i), arran * 10 + (i + 1));
}

int main()
{
GenArrangement(5, 3, 0, 0, 0);
}


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share|improve this answer































    4














    You can iterate over every subset with a bitmask.



    for(unsigned int i = 0; i < (1<<10);i++)


    When you do not need portable code you could use



    __builtin_popcount(int)


    To get the number of 1s in the binary representation at least in gcc with an x86 processor.



    for(unsigned int i = 0; i < (1<<10);i++) {
    if(__builtin_popcount(i) == 4) { //Check if this subset contains exactly 4 elements
    std::string s;
    for(int j = 0; j < 10; j++) {
    if(i&(1<<j)) { //Check if the bit on the j`th is a one
    s.push_back(to_string(j));
    }
    }
    v.push_back(s);
    }
    }






    share|improve this answer
























    • I am aware of this, but this prints combinations, rather than variations, which is not what I need.

      – Pero
      11 hours ago











    • no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

      – NoSenseEtAl
      11 hours ago











    • @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

      – Unlikus
      11 hours ago



















    3














    The slowness is due to generating all n! permutations, even when only a fraction of them is required. Your complexity is around O(n! * k log n), where O(k log n) is an upper bound on the complexity to query the std::map with all of the permutations.



    The answer by MBo is limited to 9 values (1..9). Even if it is extended to printing longer values, they are still limited by number of bits (usually 31 for int, and 64 bit if uint64_t is available).



    Here it is:



    void print_permutations_impl(std::ostream & out, std::vector<int> & values,
    unsigned k, std::vector<int> & permutation_stack)
    {
    if (k == permutation_stack.size())
    {
    const char* prefix = "";
    for (auto elem: permutation_stack) {
    out << prefix << elem;
    prefix = ", ";
    }
    out << 'n';
    return;
    }
    auto end_valid = values.size() - permutation_stack.size();
    permutation_stack.push_back(0);
    for (unsigned i=0 ; i < end_valid; ++i) {
    permutation_stack.back() = values[i];
    std::swap(values[i], values[end_valid - 1]);
    print_permutations_impl(out, values, k, permutation_stack);
    std::swap(values[i], values[end_valid - 1]);
    }
    permutation_stack.pop_back();
    }

    void print_permutations(std::ostream & out, const std::vector<int> & values, int k)
    {
    std::vector<int> unique = values;
    std::sort(unique.begin(), unique.end());
    unique.erase(std::unique(unique.begin(), unique.end()),
    unique.end());
    std::vector<int> current_permutation;
    print_permutations_impl(out, unique, k, current_permutation);
    }


    It works in sub-second speed for N=100 and K=2.






    share|improve this answer

































      1














      //finds permutations of an array
      #include<iostream>
      #include<vector>
      using namespace std;

      inline void vec_in(vector<unsigned>&, unsigned&);
      inline void vec_out(vector<unsigned>&);
      inline void vec_sub(vector<vector<unsigned>>&, vector<unsigned>&, unsigned&);

      int main(){
      unsigned size;
      cout<<"SIZE : ";
      cin>>size;
      vector<unsigned> vec;
      vec_in(vec,size);
      unsigned choose;
      cout<<"CHOOSE : ";
      cin>>choose;
      vector<vector<unsigned>> sub;
      vec_sub(sub, vec, choose);
      size=sub.size();
      for(unsigned y=0; y<size-2; y++){
      for(unsigned j=0; j<choose-1; j++){
      vector<unsigned> temp;
      for(unsigned i=0; i<=j; i++){
      temp.push_back(sub[y][i]);
      }
      for(unsigned x=y+1; x<size; x++){
      if(temp[0]==sub[x][choose-1]){break;}
      vector<unsigned> _temp;
      _temp=temp;
      for(unsigned i=j+1; i<choose; i++){
      _temp.push_back(sub[x][i]);
      }
      sub.push_back(_temp);
      }
      }
      }
      cout<<sub.size()<<endl;
      for(unsigned i=0; i<sub.size(); i++){
      vec_out(sub[i]);
      }
      return 0;
      }

      inline void vec_in(vector<unsigned>& vec, unsigned& size){
      for(unsigned i=0; i<size; i++){
      unsigned k;
      cin>>k;
      vec.push_back(k);
      }
      }

      inline void vec_out(vector<unsigned>& vec){
      for(unsigned i=0; i<vec.size(); i++){
      cout<<vec[i]<<" ";
      }
      cout<<endl;
      }

      inline void vec_sub(vector<vector<unsigned>>& sub, vector<unsigned>& vec,
      unsigned& size){
      for(unsigned i=0; i<vec.size(); i++){
      //if(i+size==vec.size()){break;}
      vector<unsigned> temp;
      unsigned x=i;
      for(unsigned k=0; k<size; k++){
      temp.push_back(vec[x]);
      x++;
      if(x==vec.size()){x=0;}
      }
      sub.push_back(temp);
      }
      }


      This will not print in reverse order like you have done in you example. Print by reversing the arrays once and you will get your answer completely!

      The idea behind this is :


      1. Say you have 5 numbers : 1 2 3 4 5 and you want to choose 3 at a time then


      2. Find the sub-arrays in serial order :

      1 2 3

      2 3 4

      3 4 5

      4 5 1

      5 1 2


      3. These will be first n sub-arrays of an array of length n


      4. Now, take 1 from 1st sub-array and 3,4 from 2nd sub-array and make another sub-array from these 3 elements, then take 4,5 from 3rd sub-array and do the same. Do not take elements from last two sub arrays as after that the elements will start repeating.


      5. Now take 1,2 from first sub-array and take 4 from 2nd sub-arr make one sub-array and take 5 from 3rd sub-arr and make one array


      6. Push all these arrays back to the list of arrays you are having.


      7. Do the same pattern from the 2nd sub-array but don't take elements from where the fist element of your array starts matching the last element that you will throw back from a sub-array below the array you are working on [ In the previous case the working sub-arr was 1st one and we didn't start taking elements from 4th sub array! ]






      share|improve this answer

























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        4 Answers
        4






        active

        oldest

        votes








        4 Answers
        4






        active

        oldest

        votes









        active

        oldest

        votes






        active

        oldest

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        5














        This code generates arrangements of k items from n in lexicographic order, packed into integer for simplicity (so 153 corresponds to (1,5,3))



        void GenArrangement(int n, int k, int idx, int used, int arran) {
        if (idx == k) {
        std::cout << arran << std::endl;
        return;
        }

        for (int i = 0; i < n; i++)
        if (0 == (used & (1 << i)))
        GenArrangement(n, k, idx + 1, used | (1 << i), arran * 10 + (i + 1));
        }

        int main()
        {
        GenArrangement(5, 3, 0, 0, 0);
        }


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        share|improve this answer




























          5














          This code generates arrangements of k items from n in lexicographic order, packed into integer for simplicity (so 153 corresponds to (1,5,3))



          void GenArrangement(int n, int k, int idx, int used, int arran) {
          if (idx == k) {
          std::cout << arran << std::endl;
          return;
          }

          for (int i = 0; i < n; i++)
          if (0 == (used & (1 << i)))
          GenArrangement(n, k, idx + 1, used | (1 << i), arran * 10 + (i + 1));
          }

          int main()
          {
          GenArrangement(5, 3, 0, 0, 0);
          }


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          share|improve this answer


























            5












            5








            5







            This code generates arrangements of k items from n in lexicographic order, packed into integer for simplicity (so 153 corresponds to (1,5,3))



            void GenArrangement(int n, int k, int idx, int used, int arran) {
            if (idx == k) {
            std::cout << arran << std::endl;
            return;
            }

            for (int i = 0; i < n; i++)
            if (0 == (used & (1 << i)))
            GenArrangement(n, k, idx + 1, used | (1 << i), arran * 10 + (i + 1));
            }

            int main()
            {
            GenArrangement(5, 3, 0, 0, 0);
            }


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            share|improve this answer













            This code generates arrangements of k items from n in lexicographic order, packed into integer for simplicity (so 153 corresponds to (1,5,3))



            void GenArrangement(int n, int k, int idx, int used, int arran) {
            if (idx == k) {
            std::cout << arran << std::endl;
            return;
            }

            for (int i = 0; i < n; i++)
            if (0 == (used & (1 << i)))
            GenArrangement(n, k, idx + 1, used | (1 << i), arran * 10 + (i + 1));
            }

            int main()
            {
            GenArrangement(5, 3, 0, 0, 0);
            }


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            share|improve this answer












            share|improve this answer



            share|improve this answer










            answered 11 hours ago









            MBoMBo

            49k23050




            49k23050

























                4














                You can iterate over every subset with a bitmask.



                for(unsigned int i = 0; i < (1<<10);i++)


                When you do not need portable code you could use



                __builtin_popcount(int)


                To get the number of 1s in the binary representation at least in gcc with an x86 processor.



                for(unsigned int i = 0; i < (1<<10);i++) {
                if(__builtin_popcount(i) == 4) { //Check if this subset contains exactly 4 elements
                std::string s;
                for(int j = 0; j < 10; j++) {
                if(i&(1<<j)) { //Check if the bit on the j`th is a one
                s.push_back(to_string(j));
                }
                }
                v.push_back(s);
                }
                }






                share|improve this answer
























                • I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                  – Pero
                  11 hours ago











                • no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                  – NoSenseEtAl
                  11 hours ago











                • @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                  – Unlikus
                  11 hours ago
















                4














                You can iterate over every subset with a bitmask.



                for(unsigned int i = 0; i < (1<<10);i++)


                When you do not need portable code you could use



                __builtin_popcount(int)


                To get the number of 1s in the binary representation at least in gcc with an x86 processor.



                for(unsigned int i = 0; i < (1<<10);i++) {
                if(__builtin_popcount(i) == 4) { //Check if this subset contains exactly 4 elements
                std::string s;
                for(int j = 0; j < 10; j++) {
                if(i&(1<<j)) { //Check if the bit on the j`th is a one
                s.push_back(to_string(j));
                }
                }
                v.push_back(s);
                }
                }






                share|improve this answer
























                • I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                  – Pero
                  11 hours ago











                • no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                  – NoSenseEtAl
                  11 hours ago











                • @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                  – Unlikus
                  11 hours ago














                4












                4








                4







                You can iterate over every subset with a bitmask.



                for(unsigned int i = 0; i < (1<<10);i++)


                When you do not need portable code you could use



                __builtin_popcount(int)


                To get the number of 1s in the binary representation at least in gcc with an x86 processor.



                for(unsigned int i = 0; i < (1<<10);i++) {
                if(__builtin_popcount(i) == 4) { //Check if this subset contains exactly 4 elements
                std::string s;
                for(int j = 0; j < 10; j++) {
                if(i&(1<<j)) { //Check if the bit on the j`th is a one
                s.push_back(to_string(j));
                }
                }
                v.push_back(s);
                }
                }






                share|improve this answer













                You can iterate over every subset with a bitmask.



                for(unsigned int i = 0; i < (1<<10);i++)


                When you do not need portable code you could use



                __builtin_popcount(int)


                To get the number of 1s in the binary representation at least in gcc with an x86 processor.



                for(unsigned int i = 0; i < (1<<10);i++) {
                if(__builtin_popcount(i) == 4) { //Check if this subset contains exactly 4 elements
                std::string s;
                for(int j = 0; j < 10; j++) {
                if(i&(1<<j)) { //Check if the bit on the j`th is a one
                s.push_back(to_string(j));
                }
                }
                v.push_back(s);
                }
                }







                share|improve this answer












                share|improve this answer



                share|improve this answer










                answered 11 hours ago









                UnlikusUnlikus

                876




                876













                • I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                  – Pero
                  11 hours ago











                • no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                  – NoSenseEtAl
                  11 hours ago











                • @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                  – Unlikus
                  11 hours ago



















                • I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                  – Pero
                  11 hours ago











                • no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                  – NoSenseEtAl
                  11 hours ago











                • @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                  – Unlikus
                  11 hours ago

















                I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                – Pero
                11 hours ago





                I am aware of this, but this prints combinations, rather than variations, which is not what I need.

                – Pero
                11 hours ago













                no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                – NoSenseEtAl
                11 hours ago





                no need to use popcnt, you can use normal slower way of counting en.wikichip.org/wiki/population_count

                – NoSenseEtAl
                11 hours ago













                @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                – Unlikus
                11 hours ago





                @Pero when you have the combinations, you can use next permutation on these (which are much smaller)

                – Unlikus
                11 hours ago











                3














                The slowness is due to generating all n! permutations, even when only a fraction of them is required. Your complexity is around O(n! * k log n), where O(k log n) is an upper bound on the complexity to query the std::map with all of the permutations.



                The answer by MBo is limited to 9 values (1..9). Even if it is extended to printing longer values, they are still limited by number of bits (usually 31 for int, and 64 bit if uint64_t is available).



                Here it is:



                void print_permutations_impl(std::ostream & out, std::vector<int> & values,
                unsigned k, std::vector<int> & permutation_stack)
                {
                if (k == permutation_stack.size())
                {
                const char* prefix = "";
                for (auto elem: permutation_stack) {
                out << prefix << elem;
                prefix = ", ";
                }
                out << 'n';
                return;
                }
                auto end_valid = values.size() - permutation_stack.size();
                permutation_stack.push_back(0);
                for (unsigned i=0 ; i < end_valid; ++i) {
                permutation_stack.back() = values[i];
                std::swap(values[i], values[end_valid - 1]);
                print_permutations_impl(out, values, k, permutation_stack);
                std::swap(values[i], values[end_valid - 1]);
                }
                permutation_stack.pop_back();
                }

                void print_permutations(std::ostream & out, const std::vector<int> & values, int k)
                {
                std::vector<int> unique = values;
                std::sort(unique.begin(), unique.end());
                unique.erase(std::unique(unique.begin(), unique.end()),
                unique.end());
                std::vector<int> current_permutation;
                print_permutations_impl(out, unique, k, current_permutation);
                }


                It works in sub-second speed for N=100 and K=2.






                share|improve this answer






























                  3














                  The slowness is due to generating all n! permutations, even when only a fraction of them is required. Your complexity is around O(n! * k log n), where O(k log n) is an upper bound on the complexity to query the std::map with all of the permutations.



                  The answer by MBo is limited to 9 values (1..9). Even if it is extended to printing longer values, they are still limited by number of bits (usually 31 for int, and 64 bit if uint64_t is available).



                  Here it is:



                  void print_permutations_impl(std::ostream & out, std::vector<int> & values,
                  unsigned k, std::vector<int> & permutation_stack)
                  {
                  if (k == permutation_stack.size())
                  {
                  const char* prefix = "";
                  for (auto elem: permutation_stack) {
                  out << prefix << elem;
                  prefix = ", ";
                  }
                  out << 'n';
                  return;
                  }
                  auto end_valid = values.size() - permutation_stack.size();
                  permutation_stack.push_back(0);
                  for (unsigned i=0 ; i < end_valid; ++i) {
                  permutation_stack.back() = values[i];
                  std::swap(values[i], values[end_valid - 1]);
                  print_permutations_impl(out, values, k, permutation_stack);
                  std::swap(values[i], values[end_valid - 1]);
                  }
                  permutation_stack.pop_back();
                  }

                  void print_permutations(std::ostream & out, const std::vector<int> & values, int k)
                  {
                  std::vector<int> unique = values;
                  std::sort(unique.begin(), unique.end());
                  unique.erase(std::unique(unique.begin(), unique.end()),
                  unique.end());
                  std::vector<int> current_permutation;
                  print_permutations_impl(out, unique, k, current_permutation);
                  }


                  It works in sub-second speed for N=100 and K=2.






                  share|improve this answer




























                    3












                    3








                    3







                    The slowness is due to generating all n! permutations, even when only a fraction of them is required. Your complexity is around O(n! * k log n), where O(k log n) is an upper bound on the complexity to query the std::map with all of the permutations.



                    The answer by MBo is limited to 9 values (1..9). Even if it is extended to printing longer values, they are still limited by number of bits (usually 31 for int, and 64 bit if uint64_t is available).



                    Here it is:



                    void print_permutations_impl(std::ostream & out, std::vector<int> & values,
                    unsigned k, std::vector<int> & permutation_stack)
                    {
                    if (k == permutation_stack.size())
                    {
                    const char* prefix = "";
                    for (auto elem: permutation_stack) {
                    out << prefix << elem;
                    prefix = ", ";
                    }
                    out << 'n';
                    return;
                    }
                    auto end_valid = values.size() - permutation_stack.size();
                    permutation_stack.push_back(0);
                    for (unsigned i=0 ; i < end_valid; ++i) {
                    permutation_stack.back() = values[i];
                    std::swap(values[i], values[end_valid - 1]);
                    print_permutations_impl(out, values, k, permutation_stack);
                    std::swap(values[i], values[end_valid - 1]);
                    }
                    permutation_stack.pop_back();
                    }

                    void print_permutations(std::ostream & out, const std::vector<int> & values, int k)
                    {
                    std::vector<int> unique = values;
                    std::sort(unique.begin(), unique.end());
                    unique.erase(std::unique(unique.begin(), unique.end()),
                    unique.end());
                    std::vector<int> current_permutation;
                    print_permutations_impl(out, unique, k, current_permutation);
                    }


                    It works in sub-second speed for N=100 and K=2.






                    share|improve this answer















                    The slowness is due to generating all n! permutations, even when only a fraction of them is required. Your complexity is around O(n! * k log n), where O(k log n) is an upper bound on the complexity to query the std::map with all of the permutations.



                    The answer by MBo is limited to 9 values (1..9). Even if it is extended to printing longer values, they are still limited by number of bits (usually 31 for int, and 64 bit if uint64_t is available).



                    Here it is:



                    void print_permutations_impl(std::ostream & out, std::vector<int> & values,
                    unsigned k, std::vector<int> & permutation_stack)
                    {
                    if (k == permutation_stack.size())
                    {
                    const char* prefix = "";
                    for (auto elem: permutation_stack) {
                    out << prefix << elem;
                    prefix = ", ";
                    }
                    out << 'n';
                    return;
                    }
                    auto end_valid = values.size() - permutation_stack.size();
                    permutation_stack.push_back(0);
                    for (unsigned i=0 ; i < end_valid; ++i) {
                    permutation_stack.back() = values[i];
                    std::swap(values[i], values[end_valid - 1]);
                    print_permutations_impl(out, values, k, permutation_stack);
                    std::swap(values[i], values[end_valid - 1]);
                    }
                    permutation_stack.pop_back();
                    }

                    void print_permutations(std::ostream & out, const std::vector<int> & values, int k)
                    {
                    std::vector<int> unique = values;
                    std::sort(unique.begin(), unique.end());
                    unique.erase(std::unique(unique.begin(), unique.end()),
                    unique.end());
                    std::vector<int> current_permutation;
                    print_permutations_impl(out, unique, k, current_permutation);
                    }


                    It works in sub-second speed for N=100 and K=2.







                    share|improve this answer














                    share|improve this answer



                    share|improve this answer








                    edited 7 hours ago

























                    answered 7 hours ago









                    Michael VekslerMichael Veksler

                    3,4121517




                    3,4121517























                        1














                        //finds permutations of an array
                        #include<iostream>
                        #include<vector>
                        using namespace std;

                        inline void vec_in(vector<unsigned>&, unsigned&);
                        inline void vec_out(vector<unsigned>&);
                        inline void vec_sub(vector<vector<unsigned>>&, vector<unsigned>&, unsigned&);

                        int main(){
                        unsigned size;
                        cout<<"SIZE : ";
                        cin>>size;
                        vector<unsigned> vec;
                        vec_in(vec,size);
                        unsigned choose;
                        cout<<"CHOOSE : ";
                        cin>>choose;
                        vector<vector<unsigned>> sub;
                        vec_sub(sub, vec, choose);
                        size=sub.size();
                        for(unsigned y=0; y<size-2; y++){
                        for(unsigned j=0; j<choose-1; j++){
                        vector<unsigned> temp;
                        for(unsigned i=0; i<=j; i++){
                        temp.push_back(sub[y][i]);
                        }
                        for(unsigned x=y+1; x<size; x++){
                        if(temp[0]==sub[x][choose-1]){break;}
                        vector<unsigned> _temp;
                        _temp=temp;
                        for(unsigned i=j+1; i<choose; i++){
                        _temp.push_back(sub[x][i]);
                        }
                        sub.push_back(_temp);
                        }
                        }
                        }
                        cout<<sub.size()<<endl;
                        for(unsigned i=0; i<sub.size(); i++){
                        vec_out(sub[i]);
                        }
                        return 0;
                        }

                        inline void vec_in(vector<unsigned>& vec, unsigned& size){
                        for(unsigned i=0; i<size; i++){
                        unsigned k;
                        cin>>k;
                        vec.push_back(k);
                        }
                        }

                        inline void vec_out(vector<unsigned>& vec){
                        for(unsigned i=0; i<vec.size(); i++){
                        cout<<vec[i]<<" ";
                        }
                        cout<<endl;
                        }

                        inline void vec_sub(vector<vector<unsigned>>& sub, vector<unsigned>& vec,
                        unsigned& size){
                        for(unsigned i=0; i<vec.size(); i++){
                        //if(i+size==vec.size()){break;}
                        vector<unsigned> temp;
                        unsigned x=i;
                        for(unsigned k=0; k<size; k++){
                        temp.push_back(vec[x]);
                        x++;
                        if(x==vec.size()){x=0;}
                        }
                        sub.push_back(temp);
                        }
                        }


                        This will not print in reverse order like you have done in you example. Print by reversing the arrays once and you will get your answer completely!

                        The idea behind this is :


                        1. Say you have 5 numbers : 1 2 3 4 5 and you want to choose 3 at a time then


                        2. Find the sub-arrays in serial order :

                        1 2 3

                        2 3 4

                        3 4 5

                        4 5 1

                        5 1 2


                        3. These will be first n sub-arrays of an array of length n


                        4. Now, take 1 from 1st sub-array and 3,4 from 2nd sub-array and make another sub-array from these 3 elements, then take 4,5 from 3rd sub-array and do the same. Do not take elements from last two sub arrays as after that the elements will start repeating.


                        5. Now take 1,2 from first sub-array and take 4 from 2nd sub-arr make one sub-array and take 5 from 3rd sub-arr and make one array


                        6. Push all these arrays back to the list of arrays you are having.


                        7. Do the same pattern from the 2nd sub-array but don't take elements from where the fist element of your array starts matching the last element that you will throw back from a sub-array below the array you are working on [ In the previous case the working sub-arr was 1st one and we didn't start taking elements from 4th sub array! ]






                        share|improve this answer






























                          1














                          //finds permutations of an array
                          #include<iostream>
                          #include<vector>
                          using namespace std;

                          inline void vec_in(vector<unsigned>&, unsigned&);
                          inline void vec_out(vector<unsigned>&);
                          inline void vec_sub(vector<vector<unsigned>>&, vector<unsigned>&, unsigned&);

                          int main(){
                          unsigned size;
                          cout<<"SIZE : ";
                          cin>>size;
                          vector<unsigned> vec;
                          vec_in(vec,size);
                          unsigned choose;
                          cout<<"CHOOSE : ";
                          cin>>choose;
                          vector<vector<unsigned>> sub;
                          vec_sub(sub, vec, choose);
                          size=sub.size();
                          for(unsigned y=0; y<size-2; y++){
                          for(unsigned j=0; j<choose-1; j++){
                          vector<unsigned> temp;
                          for(unsigned i=0; i<=j; i++){
                          temp.push_back(sub[y][i]);
                          }
                          for(unsigned x=y+1; x<size; x++){
                          if(temp[0]==sub[x][choose-1]){break;}
                          vector<unsigned> _temp;
                          _temp=temp;
                          for(unsigned i=j+1; i<choose; i++){
                          _temp.push_back(sub[x][i]);
                          }
                          sub.push_back(_temp);
                          }
                          }
                          }
                          cout<<sub.size()<<endl;
                          for(unsigned i=0; i<sub.size(); i++){
                          vec_out(sub[i]);
                          }
                          return 0;
                          }

                          inline void vec_in(vector<unsigned>& vec, unsigned& size){
                          for(unsigned i=0; i<size; i++){
                          unsigned k;
                          cin>>k;
                          vec.push_back(k);
                          }
                          }

                          inline void vec_out(vector<unsigned>& vec){
                          for(unsigned i=0; i<vec.size(); i++){
                          cout<<vec[i]<<" ";
                          }
                          cout<<endl;
                          }

                          inline void vec_sub(vector<vector<unsigned>>& sub, vector<unsigned>& vec,
                          unsigned& size){
                          for(unsigned i=0; i<vec.size(); i++){
                          //if(i+size==vec.size()){break;}
                          vector<unsigned> temp;
                          unsigned x=i;
                          for(unsigned k=0; k<size; k++){
                          temp.push_back(vec[x]);
                          x++;
                          if(x==vec.size()){x=0;}
                          }
                          sub.push_back(temp);
                          }
                          }


                          This will not print in reverse order like you have done in you example. Print by reversing the arrays once and you will get your answer completely!

                          The idea behind this is :


                          1. Say you have 5 numbers : 1 2 3 4 5 and you want to choose 3 at a time then


                          2. Find the sub-arrays in serial order :

                          1 2 3

                          2 3 4

                          3 4 5

                          4 5 1

                          5 1 2


                          3. These will be first n sub-arrays of an array of length n


                          4. Now, take 1 from 1st sub-array and 3,4 from 2nd sub-array and make another sub-array from these 3 elements, then take 4,5 from 3rd sub-array and do the same. Do not take elements from last two sub arrays as after that the elements will start repeating.


                          5. Now take 1,2 from first sub-array and take 4 from 2nd sub-arr make one sub-array and take 5 from 3rd sub-arr and make one array


                          6. Push all these arrays back to the list of arrays you are having.


                          7. Do the same pattern from the 2nd sub-array but don't take elements from where the fist element of your array starts matching the last element that you will throw back from a sub-array below the array you are working on [ In the previous case the working sub-arr was 1st one and we didn't start taking elements from 4th sub array! ]






                          share|improve this answer




























                            1












                            1








                            1







                            //finds permutations of an array
                            #include<iostream>
                            #include<vector>
                            using namespace std;

                            inline void vec_in(vector<unsigned>&, unsigned&);
                            inline void vec_out(vector<unsigned>&);
                            inline void vec_sub(vector<vector<unsigned>>&, vector<unsigned>&, unsigned&);

                            int main(){
                            unsigned size;
                            cout<<"SIZE : ";
                            cin>>size;
                            vector<unsigned> vec;
                            vec_in(vec,size);
                            unsigned choose;
                            cout<<"CHOOSE : ";
                            cin>>choose;
                            vector<vector<unsigned>> sub;
                            vec_sub(sub, vec, choose);
                            size=sub.size();
                            for(unsigned y=0; y<size-2; y++){
                            for(unsigned j=0; j<choose-1; j++){
                            vector<unsigned> temp;
                            for(unsigned i=0; i<=j; i++){
                            temp.push_back(sub[y][i]);
                            }
                            for(unsigned x=y+1; x<size; x++){
                            if(temp[0]==sub[x][choose-1]){break;}
                            vector<unsigned> _temp;
                            _temp=temp;
                            for(unsigned i=j+1; i<choose; i++){
                            _temp.push_back(sub[x][i]);
                            }
                            sub.push_back(_temp);
                            }
                            }
                            }
                            cout<<sub.size()<<endl;
                            for(unsigned i=0; i<sub.size(); i++){
                            vec_out(sub[i]);
                            }
                            return 0;
                            }

                            inline void vec_in(vector<unsigned>& vec, unsigned& size){
                            for(unsigned i=0; i<size; i++){
                            unsigned k;
                            cin>>k;
                            vec.push_back(k);
                            }
                            }

                            inline void vec_out(vector<unsigned>& vec){
                            for(unsigned i=0; i<vec.size(); i++){
                            cout<<vec[i]<<" ";
                            }
                            cout<<endl;
                            }

                            inline void vec_sub(vector<vector<unsigned>>& sub, vector<unsigned>& vec,
                            unsigned& size){
                            for(unsigned i=0; i<vec.size(); i++){
                            //if(i+size==vec.size()){break;}
                            vector<unsigned> temp;
                            unsigned x=i;
                            for(unsigned k=0; k<size; k++){
                            temp.push_back(vec[x]);
                            x++;
                            if(x==vec.size()){x=0;}
                            }
                            sub.push_back(temp);
                            }
                            }


                            This will not print in reverse order like you have done in you example. Print by reversing the arrays once and you will get your answer completely!

                            The idea behind this is :


                            1. Say you have 5 numbers : 1 2 3 4 5 and you want to choose 3 at a time then


                            2. Find the sub-arrays in serial order :

                            1 2 3

                            2 3 4

                            3 4 5

                            4 5 1

                            5 1 2


                            3. These will be first n sub-arrays of an array of length n


                            4. Now, take 1 from 1st sub-array and 3,4 from 2nd sub-array and make another sub-array from these 3 elements, then take 4,5 from 3rd sub-array and do the same. Do not take elements from last two sub arrays as after that the elements will start repeating.


                            5. Now take 1,2 from first sub-array and take 4 from 2nd sub-arr make one sub-array and take 5 from 3rd sub-arr and make one array


                            6. Push all these arrays back to the list of arrays you are having.


                            7. Do the same pattern from the 2nd sub-array but don't take elements from where the fist element of your array starts matching the last element that you will throw back from a sub-array below the array you are working on [ In the previous case the working sub-arr was 1st one and we didn't start taking elements from 4th sub array! ]






                            share|improve this answer















                            //finds permutations of an array
                            #include<iostream>
                            #include<vector>
                            using namespace std;

                            inline void vec_in(vector<unsigned>&, unsigned&);
                            inline void vec_out(vector<unsigned>&);
                            inline void vec_sub(vector<vector<unsigned>>&, vector<unsigned>&, unsigned&);

                            int main(){
                            unsigned size;
                            cout<<"SIZE : ";
                            cin>>size;
                            vector<unsigned> vec;
                            vec_in(vec,size);
                            unsigned choose;
                            cout<<"CHOOSE : ";
                            cin>>choose;
                            vector<vector<unsigned>> sub;
                            vec_sub(sub, vec, choose);
                            size=sub.size();
                            for(unsigned y=0; y<size-2; y++){
                            for(unsigned j=0; j<choose-1; j++){
                            vector<unsigned> temp;
                            for(unsigned i=0; i<=j; i++){
                            temp.push_back(sub[y][i]);
                            }
                            for(unsigned x=y+1; x<size; x++){
                            if(temp[0]==sub[x][choose-1]){break;}
                            vector<unsigned> _temp;
                            _temp=temp;
                            for(unsigned i=j+1; i<choose; i++){
                            _temp.push_back(sub[x][i]);
                            }
                            sub.push_back(_temp);
                            }
                            }
                            }
                            cout<<sub.size()<<endl;
                            for(unsigned i=0; i<sub.size(); i++){
                            vec_out(sub[i]);
                            }
                            return 0;
                            }

                            inline void vec_in(vector<unsigned>& vec, unsigned& size){
                            for(unsigned i=0; i<size; i++){
                            unsigned k;
                            cin>>k;
                            vec.push_back(k);
                            }
                            }

                            inline void vec_out(vector<unsigned>& vec){
                            for(unsigned i=0; i<vec.size(); i++){
                            cout<<vec[i]<<" ";
                            }
                            cout<<endl;
                            }

                            inline void vec_sub(vector<vector<unsigned>>& sub, vector<unsigned>& vec,
                            unsigned& size){
                            for(unsigned i=0; i<vec.size(); i++){
                            //if(i+size==vec.size()){break;}
                            vector<unsigned> temp;
                            unsigned x=i;
                            for(unsigned k=0; k<size; k++){
                            temp.push_back(vec[x]);
                            x++;
                            if(x==vec.size()){x=0;}
                            }
                            sub.push_back(temp);
                            }
                            }


                            This will not print in reverse order like you have done in you example. Print by reversing the arrays once and you will get your answer completely!

                            The idea behind this is :


                            1. Say you have 5 numbers : 1 2 3 4 5 and you want to choose 3 at a time then


                            2. Find the sub-arrays in serial order :

                            1 2 3

                            2 3 4

                            3 4 5

                            4 5 1

                            5 1 2


                            3. These will be first n sub-arrays of an array of length n


                            4. Now, take 1 from 1st sub-array and 3,4 from 2nd sub-array and make another sub-array from these 3 elements, then take 4,5 from 3rd sub-array and do the same. Do not take elements from last two sub arrays as after that the elements will start repeating.


                            5. Now take 1,2 from first sub-array and take 4 from 2nd sub-arr make one sub-array and take 5 from 3rd sub-arr and make one array


                            6. Push all these arrays back to the list of arrays you are having.


                            7. Do the same pattern from the 2nd sub-array but don't take elements from where the fist element of your array starts matching the last element that you will throw back from a sub-array below the array you are working on [ In the previous case the working sub-arr was 1st one and we didn't start taking elements from 4th sub array! ]







                            share|improve this answer














                            share|improve this answer



                            share|improve this answer








                            edited 8 hours ago

























                            answered 8 hours ago









                            brightprogrammerbrightprogrammer

                            308




                            308






























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