If I can solve Sudoku, can I solve the Travelling Salesman Problem (TSP)? If so, how?












14












$begingroup$


Let us say there is a program such that if you give a partially filled Sudoku of any size it gives you corresponding completed Sudoku.



Can you treat this program as a black box and use this to solve TSP? I mean is there a way to represent TSP problem as partially filled Sudoku, so that if I give you the answer of that Sudoku, you can tell the solution for TSP in polynomial time?



If yes, how? how do you represent TSP as a partially filled Sudoku and interpret corresponding filled Sudoku for the result.










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Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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  • 1




    $begingroup$
    This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
    $endgroup$
    – C. Windolf
    yesterday










  • $begingroup$
    @C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
    $endgroup$
    – David Richerby
    yesterday
















14












$begingroup$


Let us say there is a program such that if you give a partially filled Sudoku of any size it gives you corresponding completed Sudoku.



Can you treat this program as a black box and use this to solve TSP? I mean is there a way to represent TSP problem as partially filled Sudoku, so that if I give you the answer of that Sudoku, you can tell the solution for TSP in polynomial time?



If yes, how? how do you represent TSP as a partially filled Sudoku and interpret corresponding filled Sudoku for the result.










share|cite|improve this question









New contributor




Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$








  • 1




    $begingroup$
    This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
    $endgroup$
    – C. Windolf
    yesterday










  • $begingroup$
    @C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
    $endgroup$
    – David Richerby
    yesterday














14












14








14


4



$begingroup$


Let us say there is a program such that if you give a partially filled Sudoku of any size it gives you corresponding completed Sudoku.



Can you treat this program as a black box and use this to solve TSP? I mean is there a way to represent TSP problem as partially filled Sudoku, so that if I give you the answer of that Sudoku, you can tell the solution for TSP in polynomial time?



If yes, how? how do you represent TSP as a partially filled Sudoku and interpret corresponding filled Sudoku for the result.










share|cite|improve this question









New contributor




Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.







$endgroup$




Let us say there is a program such that if you give a partially filled Sudoku of any size it gives you corresponding completed Sudoku.



Can you treat this program as a black box and use this to solve TSP? I mean is there a way to represent TSP problem as partially filled Sudoku, so that if I give you the answer of that Sudoku, you can tell the solution for TSP in polynomial time?



If yes, how? how do you represent TSP as a partially filled Sudoku and interpret corresponding filled Sudoku for the result.







algorithms np-complete reductions traveling-salesman sudoku






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Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.











share|cite|improve this question









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edited 14 hours ago









Rodrigo de Azevedo

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asked yesterday









Chakrapani N RaoChakrapani N Rao

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New contributor





Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.






Chakrapani N Rao is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
Check out our Code of Conduct.








  • 1




    $begingroup$
    This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
    $endgroup$
    – C. Windolf
    yesterday










  • $begingroup$
    @C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
    $endgroup$
    – David Richerby
    yesterday














  • 1




    $begingroup$
    This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
    $endgroup$
    – C. Windolf
    yesterday










  • $begingroup$
    @C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
    $endgroup$
    – David Richerby
    yesterday








1




1




$begingroup$
This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
$endgroup$
– C. Windolf
yesterday




$begingroup$
This paper claims to give a constructive reduction from Sudoku to Hamiltonian cycle problem: sciencedirect.com/science/article/pii/S097286001630038X
$endgroup$
– C. Windolf
yesterday












$begingroup$
@C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
$endgroup$
– David Richerby
yesterday




$begingroup$
@C.Windolf The question is asking for the other direction. (Indeed, there's a deleted answer that made the same mistake and cited the same paper.)
$endgroup$
– David Richerby
yesterday










2 Answers
2






active

oldest

votes


















24












$begingroup$

For 9x9 Sudoku, no. It is finite so can be solved in $O(1)$ time.



But if you had a solver for $n^2 times n^2$ Sudoku, that worked for all $n$ and all possible partial boards, then yes, that could be used to solve TSP in polynomial time, as completing a $n^2 times n^2$ Sudoku is NP-complete.



The proof of NP-completeness works by reducing from some NP-complete problem R to Sudoku; then because R is NP-complete, you can reduce from TSP to R (that follows from the definition of NP-completeness); and chaining those reductions gives you a way to use the Sudoku solver to solve TSP.






share|cite|improve this answer











$endgroup$









  • 1




    $begingroup$
    Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
    $endgroup$
    – Chakrapani N Rao
    yesterday






  • 2




    $begingroup$
    @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
    $endgroup$
    – D.W.
    yesterday






  • 6




    $begingroup$
    @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
    $endgroup$
    – David Richerby
    yesterday










  • $begingroup$
    OK, so we do not have a working solution for the above question then?
    $endgroup$
    – Chakrapani N Rao
    yesterday






  • 7




    $begingroup$
    @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
    $endgroup$
    – David Richerby
    yesterday



















18












$begingroup$

It is indeed possible to use a general Sudoku solver to solve instances of TSP, and if this solver takes polynomial time then the whole process will as well (in complexity terminology, there is a polynomial-time reduction from TSP to Sudoku). This is because Sudoku is NP-complete and TSP is in NP. But as is usually the case in this area, looking at the details of the reduction isn't particularly illuminating. If you want, you can piece it together by using the simple reduction from Latin square completion to Sudoku here, the reduction from triangulating uniform tripartite graphs to Latin square completion here, the reduction from 3SAT to triangulation here, and a formulation of TSP as a 3SAT problem. However, if you want to understand the idea behind reducing from Sudoku to TSP I think you would be better off studying Cook's theorem (showing that SAT is NP-complete) and a couple of simple reductions from 3SAT (e.g. to 3-dimensional matching) and being satisfied in the knowledge that the TSP-Sudoku reduction is just the same kind of thing but longer and more fiddly.






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rlms is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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    2 Answers
    2






    active

    oldest

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    2 Answers
    2






    active

    oldest

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    active

    oldest

    votes






    active

    oldest

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    24












    $begingroup$

    For 9x9 Sudoku, no. It is finite so can be solved in $O(1)$ time.



    But if you had a solver for $n^2 times n^2$ Sudoku, that worked for all $n$ and all possible partial boards, then yes, that could be used to solve TSP in polynomial time, as completing a $n^2 times n^2$ Sudoku is NP-complete.



    The proof of NP-completeness works by reducing from some NP-complete problem R to Sudoku; then because R is NP-complete, you can reduce from TSP to R (that follows from the definition of NP-completeness); and chaining those reductions gives you a way to use the Sudoku solver to solve TSP.






    share|cite|improve this answer











    $endgroup$









    • 1




      $begingroup$
      Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 2




      $begingroup$
      @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
      $endgroup$
      – D.W.
      yesterday






    • 6




      $begingroup$
      @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
      $endgroup$
      – David Richerby
      yesterday










    • $begingroup$
      OK, so we do not have a working solution for the above question then?
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 7




      $begingroup$
      @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
      $endgroup$
      – David Richerby
      yesterday
















    24












    $begingroup$

    For 9x9 Sudoku, no. It is finite so can be solved in $O(1)$ time.



    But if you had a solver for $n^2 times n^2$ Sudoku, that worked for all $n$ and all possible partial boards, then yes, that could be used to solve TSP in polynomial time, as completing a $n^2 times n^2$ Sudoku is NP-complete.



    The proof of NP-completeness works by reducing from some NP-complete problem R to Sudoku; then because R is NP-complete, you can reduce from TSP to R (that follows from the definition of NP-completeness); and chaining those reductions gives you a way to use the Sudoku solver to solve TSP.






    share|cite|improve this answer











    $endgroup$









    • 1




      $begingroup$
      Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 2




      $begingroup$
      @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
      $endgroup$
      – D.W.
      yesterday






    • 6




      $begingroup$
      @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
      $endgroup$
      – David Richerby
      yesterday










    • $begingroup$
      OK, so we do not have a working solution for the above question then?
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 7




      $begingroup$
      @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
      $endgroup$
      – David Richerby
      yesterday














    24












    24








    24





    $begingroup$

    For 9x9 Sudoku, no. It is finite so can be solved in $O(1)$ time.



    But if you had a solver for $n^2 times n^2$ Sudoku, that worked for all $n$ and all possible partial boards, then yes, that could be used to solve TSP in polynomial time, as completing a $n^2 times n^2$ Sudoku is NP-complete.



    The proof of NP-completeness works by reducing from some NP-complete problem R to Sudoku; then because R is NP-complete, you can reduce from TSP to R (that follows from the definition of NP-completeness); and chaining those reductions gives you a way to use the Sudoku solver to solve TSP.






    share|cite|improve this answer











    $endgroup$



    For 9x9 Sudoku, no. It is finite so can be solved in $O(1)$ time.



    But if you had a solver for $n^2 times n^2$ Sudoku, that worked for all $n$ and all possible partial boards, then yes, that could be used to solve TSP in polynomial time, as completing a $n^2 times n^2$ Sudoku is NP-complete.



    The proof of NP-completeness works by reducing from some NP-complete problem R to Sudoku; then because R is NP-complete, you can reduce from TSP to R (that follows from the definition of NP-completeness); and chaining those reductions gives you a way to use the Sudoku solver to solve TSP.







    share|cite|improve this answer














    share|cite|improve this answer



    share|cite|improve this answer








    edited yesterday

























    answered yesterday









    D.W.D.W.

    101k12125290




    101k12125290








    • 1




      $begingroup$
      Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 2




      $begingroup$
      @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
      $endgroup$
      – D.W.
      yesterday






    • 6




      $begingroup$
      @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
      $endgroup$
      – David Richerby
      yesterday










    • $begingroup$
      OK, so we do not have a working solution for the above question then?
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 7




      $begingroup$
      @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
      $endgroup$
      – David Richerby
      yesterday














    • 1




      $begingroup$
      Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 2




      $begingroup$
      @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
      $endgroup$
      – D.W.
      yesterday






    • 6




      $begingroup$
      @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
      $endgroup$
      – David Richerby
      yesterday










    • $begingroup$
      OK, so we do not have a working solution for the above question then?
      $endgroup$
      – Chakrapani N Rao
      yesterday






    • 7




      $begingroup$
      @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
      $endgroup$
      – David Richerby
      yesterday








    1




    1




    $begingroup$
    Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
    $endgroup$
    – Chakrapani N Rao
    yesterday




    $begingroup$
    Could you please explain how? Yes lets assume I have general sudoku solver which acts as a black box. So how can you use it? How do you represent TSP as a partially filled Sudoku
    $endgroup$
    – Chakrapani N Rao
    yesterday




    2




    2




    $begingroup$
    @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
    $endgroup$
    – D.W.
    yesterday




    $begingroup$
    @ChakrapaniNRao, see updated answer. Yes, I understand it is a black box. To work out the details, find the proof of NP-completeness for Sudoku and understand how the reduction works.
    $endgroup$
    – D.W.
    yesterday




    6




    6




    $begingroup$
    @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
    $endgroup$
    – David Richerby
    yesterday




    $begingroup$
    @ChakrapaniNRao It doesn't answer the question completely but the full answer would be ridiculously long, be full of intricate details and wouldn't give you any more enlightenment than the sketch here. It's possible that a reduction of some NP-complete problem to $n^2times n^2$ sudoku might be interesting but, unless the proof that sudoku is NP-complete was actually by reduction from TSP (unlikely), the answer is still going to end "and then chain those two reductions together".
    $endgroup$
    – David Richerby
    yesterday












    $begingroup$
    OK, so we do not have a working solution for the above question then?
    $endgroup$
    – Chakrapani N Rao
    yesterday




    $begingroup$
    OK, so we do not have a working solution for the above question then?
    $endgroup$
    – Chakrapani N Rao
    yesterday




    7




    7




    $begingroup$
    @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
    $endgroup$
    – David Richerby
    yesterday




    $begingroup$
    @ChakrapaniNRao You are asking how to solve problem X using a black box for problem Y. That is literally asking for a reduction. That's what "reduction" means. And, as this answer explains, the answer to your yes/no question is yes.
    $endgroup$
    – David Richerby
    yesterday











    18












    $begingroup$

    It is indeed possible to use a general Sudoku solver to solve instances of TSP, and if this solver takes polynomial time then the whole process will as well (in complexity terminology, there is a polynomial-time reduction from TSP to Sudoku). This is because Sudoku is NP-complete and TSP is in NP. But as is usually the case in this area, looking at the details of the reduction isn't particularly illuminating. If you want, you can piece it together by using the simple reduction from Latin square completion to Sudoku here, the reduction from triangulating uniform tripartite graphs to Latin square completion here, the reduction from 3SAT to triangulation here, and a formulation of TSP as a 3SAT problem. However, if you want to understand the idea behind reducing from Sudoku to TSP I think you would be better off studying Cook's theorem (showing that SAT is NP-complete) and a couple of simple reductions from 3SAT (e.g. to 3-dimensional matching) and being satisfied in the knowledge that the TSP-Sudoku reduction is just the same kind of thing but longer and more fiddly.






    share|cite|improve this answer








    New contributor




    rlms is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
    Check out our Code of Conduct.






    $endgroup$


















      18












      $begingroup$

      It is indeed possible to use a general Sudoku solver to solve instances of TSP, and if this solver takes polynomial time then the whole process will as well (in complexity terminology, there is a polynomial-time reduction from TSP to Sudoku). This is because Sudoku is NP-complete and TSP is in NP. But as is usually the case in this area, looking at the details of the reduction isn't particularly illuminating. If you want, you can piece it together by using the simple reduction from Latin square completion to Sudoku here, the reduction from triangulating uniform tripartite graphs to Latin square completion here, the reduction from 3SAT to triangulation here, and a formulation of TSP as a 3SAT problem. However, if you want to understand the idea behind reducing from Sudoku to TSP I think you would be better off studying Cook's theorem (showing that SAT is NP-complete) and a couple of simple reductions from 3SAT (e.g. to 3-dimensional matching) and being satisfied in the knowledge that the TSP-Sudoku reduction is just the same kind of thing but longer and more fiddly.






      share|cite|improve this answer








      New contributor




      rlms is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.






      $endgroup$
















        18












        18








        18





        $begingroup$

        It is indeed possible to use a general Sudoku solver to solve instances of TSP, and if this solver takes polynomial time then the whole process will as well (in complexity terminology, there is a polynomial-time reduction from TSP to Sudoku). This is because Sudoku is NP-complete and TSP is in NP. But as is usually the case in this area, looking at the details of the reduction isn't particularly illuminating. If you want, you can piece it together by using the simple reduction from Latin square completion to Sudoku here, the reduction from triangulating uniform tripartite graphs to Latin square completion here, the reduction from 3SAT to triangulation here, and a formulation of TSP as a 3SAT problem. However, if you want to understand the idea behind reducing from Sudoku to TSP I think you would be better off studying Cook's theorem (showing that SAT is NP-complete) and a couple of simple reductions from 3SAT (e.g. to 3-dimensional matching) and being satisfied in the knowledge that the TSP-Sudoku reduction is just the same kind of thing but longer and more fiddly.






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        $endgroup$



        It is indeed possible to use a general Sudoku solver to solve instances of TSP, and if this solver takes polynomial time then the whole process will as well (in complexity terminology, there is a polynomial-time reduction from TSP to Sudoku). This is because Sudoku is NP-complete and TSP is in NP. But as is usually the case in this area, looking at the details of the reduction isn't particularly illuminating. If you want, you can piece it together by using the simple reduction from Latin square completion to Sudoku here, the reduction from triangulating uniform tripartite graphs to Latin square completion here, the reduction from 3SAT to triangulation here, and a formulation of TSP as a 3SAT problem. However, if you want to understand the idea behind reducing from Sudoku to TSP I think you would be better off studying Cook's theorem (showing that SAT is NP-complete) and a couple of simple reductions from 3SAT (e.g. to 3-dimensional matching) and being satisfied in the knowledge that the TSP-Sudoku reduction is just the same kind of thing but longer and more fiddly.







        share|cite|improve this answer








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        rlms is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
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        share|cite|improve this answer






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        answered yesterday









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