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Re: Fermat+Euler+Frobenius

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  • paulunderwooduk
    ... gcd(3*a^2+1,n)==1 gcd(10*a^2-2,n)==1 I use the wrong variable. Sorry, Paul
    Message 1 of 24 , Jul 17, 2013
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      --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@...> wrote:

      > I should have stipulated that gcd(3*x^2+1,n)==1 for the it's inversion. Also, in order to stop any more cyclotomic shenanigans, gcd(10*x^2-2,n)==1,

      gcd(3*a^2+1,n)==1
      gcd(10*a^2-2,n)==1

      I use the wrong variable. Sorry,

      Paul
    • djbroadhurst
      ... I doubt it. But they will have to avoid linear terms in a^2. It appears that they are on strike, at present, in protest against your post-hoc wriggling,
      Message 2 of 24 , Jul 17, 2013
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        --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@...> wrote:

        > I notice that for your counterexample (and the one before it):
        > gcd((13*a^2-1)*(7*a^2-3),n)>1,
        >
        > Are the Gremlins now trapped?

        I doubt it. But they will have to avoid linear terms in a^2.

        It appears that they are on strike, at present, in protest
        against your post-hoc wriggling, but I imagine that they
        will retaliate, eventually :-)

        David
      • djbroadhurst
        ... Decidedly not trapped. They now give you wriggle room, where you may invent all sorts of post-hoc evasions. Here is a counterexample to all your previous
        Message 3 of 24 , Jul 17, 2013
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          --- In primenumbers@yahoogroups.com,
          "paulunderwooduk" <paulunderwood@> wrote:

          > Are the Gremlins now trapped?

          Decidedly not trapped. They now give you wriggle room,
          where you may invent all sorts of post-hoc evasions.
          Here is a counterexample to all your previous wriggles:

          {wriggle(a,n)=local(v=[a,3*a^2-1,5*a^2-1,13*a^2-1,3*a^2-7]);
          sum(k=1,#v,gcd(v[k],n)>1)==0;}

          {tst(n,a)=kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
          Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
          Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
          Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
          Mod(Mod(1,n)*(L+a),L^2-2*a*L+1)^(n+1)==3*a^2+1;}

          {n=65886964889495717178571390281373531645585969659081927305601\
          05227985819505433064526820837352190304323548383200875256409729;

          a=28531673532383337956613397336948328674189469877146000735221\
          4200436155528207860632250156996971542498419889463170302428920;

          if(tst(n,a)&&!isprime(n),print(" Gremlins are still happy"));}

          Gremlins are still happy

          My comment: Gremlins are still being very generous; an
          additional post-hoc wriggle, on your part, should not be
          hard to find. Yet beware: Gremlins are cunning and if you
          wriggle out of this counterexample, by invoking yet another
          post-hoc gcd, they will quickly retaliate.

          David (their minder)
        • paulunderwooduk
          ... Thanks again, but rules were not followed; The wriggle is slightly wrong, but the counterexample is good for the Gremlins. It should be:
          Message 4 of 24 , Jul 18, 2013
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            --- In primenumbers@yahoogroups.com, "djbroadhurst" <d.broadhurst@...> wrote:
            >
            >
            >
            > --- In primenumbers@yahoogroups.com,
            > "paulunderwooduk" <paulunderwood@> wrote:
            >
            > > Are the Gremlins now trapped?
            >
            > Decidedly not trapped. They now give you wriggle room,
            > where you may invent all sorts of post-hoc evasions.
            > Here is a counterexample to all your previous wriggles:
            >
            > {wriggle(a,n)=local(v=[a,3*a^2-1,5*a^2-1,13*a^2-1,3*a^2-7]);
            > sum(k=1,#v,gcd(v[k],n)>1)==0;}
            >
            > {tst(n,a)=kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
            > Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
            > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
            > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
            > Mod(Mod(1,n)*(L+a),L^2-2*a*L+1)^(n+1)==3*a^2+1;}
            >
            > {n=65886964889495717178571390281373531645585969659081927305601\
            > 05227985819505433064526820837352190304323548383200875256409729;
            >
            > a=28531673532383337956613397336948328674189469877146000735221\
            > 4200436155528207860632250156996971542498419889463170302428920;
            >
            > if(tst(n,a)&&!isprime(n),print(" Gremlins are still happy"));}
            >
            > Gremlins are still happy
            >
            > My comment: Gremlins are still being very generous; an
            > additional post-hoc wriggle, on your part, should not be
            > hard to find. Yet beware: Gremlins are cunning and if you
            > wriggle out of this counterexample, by invoking yet another
            > post-hoc gcd, they will quickly retaliate.
            >

            Thanks again, but rules were not followed; The wriggle is slightly wrong, but the counterexample is good for the Gremlins. It should be:

            {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
            sum(k=1,#v,gcd(v[k],n)>1)==0;}

            The main test should have the Euler+Lucas instead of Frobenius, but I made an error in previous code. Thanks for correcting that. Now I notice that for the most recent counterexample:
            Mod((3*a^2+1),n)^((n-1)/2) is neither 1 nor -1
            and (equally?)
            Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/(3*a^2+1),n))*L+1)^((n+1)/2) is neither 1 nor -1

            Paul
          • paulunderwooduk
            David, sorry for the noise. Here is what I have in mind: {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]); sum(k=1,#v,gcd(v[k],n) 1)==0;} with
            Message 5 of 24 , Jul 18, 2013
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              David, sorry for the noise. Here is what I have in mind:

              {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
              sum(k=1,#v,gcd(v[k],n)>1)==0;}

              with

              {tst(n,a)=kronecker(a^2-1,n)==-1&&
              gcd(a,n)==1&&
              Mod(a,n)^(n-1)==1&&
              Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
              Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
              Mod(3*a^2+1,n)^((n-1)/2)==kronecker(3*a^2+1,n)&&
              Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/(3*a^2+1),n))*L+1)^((n+1)/2)==kronecker(3*a^2+1,n)
              ;}

              Paul
            • paulunderwooduk
              ... Oh dear, I meant {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&& gcd(a,n)==1&&Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
              Message 6 of 24 , Jul 18, 2013
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                --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@...> wrote:
                >
                >
                > David, sorry for the noise. Here is what I have in mind:
                >
                > {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                > sum(k=1,#v,gcd(v[k],n)>1)==0;}
                >
                > with
                >
                > {tst(n,a)=kronecker(a^2-1,n)==-1&&
                > gcd(a,n)==1&&
                > Mod(a,n)^(n-1)==1&&
                > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                > Mod(3*a^2+1,n)^((n-1)/2)==kronecker(3*a^2+1,n)&&
                > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/(3*a^2+1),n))*L+1)^((n+1)/2)==kronecker(3*a^2+1,n)
                > ;}
                >

                Oh dear, I meant

                {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                gcd(a,n)==1&&Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}

                Paul -- suffering from error-after-posting syndrome
              • djbroadhurst
                ... After tidying up your request, the Gremlims happily obliged: {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,3*a^2-7]); sum(k=1,#v,gcd(v[k],n) 1)==0;}
                Message 7 of 24 , Jul 18, 2013
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                  --- In primenumbers@yahoogroups.com,
                  "paulunderwooduk" <paulunderwood@...> wrote:

                  > > David, sorry for the noise. Here is what I have in mind:
                  > Oh dear, I meant ...
                  > Paul -- suffering from error-after-posting syndrome

                  After tidying up your request, the Gremlims happily obliged:

                  {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,3*a^2-7]);
                  sum(k=1,#v,gcd(v[k],n)>1)==0;}

                  {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                  Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                  Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                  Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                  Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                  Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}

                  {if(tst(9526822969*133375521553,244578343630781166947),
                  print(" Gremlins rule OK"));}

                  Gremlins rule OK

                  David (their minder)
                • paulunderwooduk
                  ... They do indeed rule. I now present a puzzle: make all the tests strong i.e. check roots of 1 where possible. Of course, if n==3 (mod 4) a strong Lucas
                  Message 8 of 24 , Jul 18, 2013
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                    --- In primenumbers@yahoogroups.com, "djbroadhurst" <d.broadhurst@...> wrote:
                    >
                    >
                    >
                    > --- In primenumbers@yahoogroups.com,
                    > "paulunderwooduk" <paulunderwood@> wrote:
                    >
                    > > > David, sorry for the noise. Here is what I have in mind:
                    > > Oh dear, I meant ...
                    > > Paul -- suffering from error-after-posting syndrome
                    >
                    > After tidying up your request, the Gremlims happily obliged:
                    >
                    > {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,3*a^2-7]);
                    > sum(k=1,#v,gcd(v[k],n)>1)==0;}
                    >
                    > {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                    > Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                    > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                    > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                    > Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                    > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}
                    >
                    > {if(tst(9526822969*133375521553,244578343630781166947),
                    > print(" Gremlins rule OK"));}
                    >
                    > Gremlins rule OK
                    >

                    They do indeed rule. I now present a puzzle: make all the tests "strong" i.e. check roots of 1 where possible. Of course, if n==3 (mod 4) a strong Lucas test will be enough,

                    With thanks,

                    Paul
                  • paulunderwooduk
                    ... I mean check that square roots, where the exist, of all 1 are +-1, Paul
                    Message 9 of 24 , Jul 18, 2013
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                      --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@...> wrote:



                      > > {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,3*a^2-7]);
                      > > sum(k=1,#v,gcd(v[k],n)>1)==0;}
                      > >
                      > > {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                      > > Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                      > > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                      > > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                      > > Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                      > > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}

                      > I now present a puzzle: make all the tests "strong" i.e. check roots of 1 where possible. Of course, if n==3 (mod 4) a strong Lucas test will be enough,
                      >

                      I mean check that square roots, where the exist, of all 1 are +-1,

                      Paul
                    • djbroadhurst
                      ... That s your job; not the Gremlins :-) To show that they can still work at 120 digits, even after all your wriggling, they invite you to find gcd s that
                      Message 10 of 24 , Jul 18, 2013
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                        --- In primenumbers@yahoogroups.com,
                        "paulunderwooduk" <paulunderwood@...> wrote:

                        > I now present a puzzle: make all the tests "strong"

                        That's your job; not the Gremlins' :-)

                        To show that they can still work at 120 digits,
                        even after all your wriggling, they invite you to find
                        gcd's that stop these pseudoprimes fooling your test:

                        {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                        sum(k=1,#v,gcd(v[k],n)>1)==0;}

                        {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                        Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                        Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                        Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                        Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                        Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}

                        {fooling=[

                        [16212200212765236462624941301662595905969969921486185624581\
                        42710646148264113979405459683534701445570403174269878228032843,

                        148751952532863090430663215218366305961343757352250610518989\
                        959178089757327365262627066765931489564753215534936293595719],

                        [92856680188887785533016964629715768104484119019221599899820\
                        26844918042826013874700027439880606063780672269637251932365051,

                        246307830695230159344853971299085504661118671451065969332908\
                        6522201134308546059459112977581864702729364124320490100075243]];

                        for(k=1,#fooling,n=fooling[k][1];a=fooling[k][2];
                        if(tst(n,a)&&!isprime(n),print(" Gremlins rule OK")));}

                        Gremlins rule OK
                        Gremlins rule OK

                        They prefer to work around 120 digits, since then
                        you have to be a little smarter to factor the semiprimes.
                        I believe that Kermit will be able to factorize the two
                        above, since he has been using other lists as practice.

                        David
                      • paulunderwooduk
                        ... Well, I can t do what the Gremlins have done to refute my efforts so far, let alone to solve my own puzzle! But I will make a silver sub-puzzle by dropping
                        Message 11 of 24 , Jul 18, 2013
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                          --- In primenumbers@yahoogroups.com, "djbroadhurst" <d.broadhurst@...> wrote:
                          >
                          >
                          >
                          > --- In primenumbers@yahoogroups.com,
                          > "paulunderwooduk" <paulunderwood@> wrote:
                          >
                          > > I now present a puzzle: make all the tests "strong"
                          >
                          > That's your job; not the Gremlins' :-)
                          >

                          Well, I can't do what the Gremlins have done to refute my efforts so far, let alone to solve my own puzzle! But I will make a silver sub-puzzle by dropping any PRP test on "a", but still insisting on strong tests for the other PRP sub-tests including the Lucas PRP test.

                          > To show that they can still work at 120 digits,
                          > even after all your wriggling, they invite you to find
                          > gcd's that stop these pseudoprimes fooling your test:
                          >

                          I am unable to crack the gcd tricks and I am in the dark as to how Kermit factored the numbers in:
                          http://tech.groups.yahoo.com/group/primenumbers/message/25227

                          > {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                          > sum(k=1,#v,gcd(v[k],n)>1)==0;}
                          >
                          > {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                          > Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                          > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                          > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                          > Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                          > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}
                          >
                          > {fooling=[
                          >
                          > [16212200212765236462624941301662595905969969921486185624581\
                          > 42710646148264113979405459683534701445570403174269878228032843,
                          >
                          > 148751952532863090430663215218366305961343757352250610518989\
                          > 959178089757327365262627066765931489564753215534936293595719],
                          >
                          > [92856680188887785533016964629715768104484119019221599899820\
                          > 26844918042826013874700027439880606063780672269637251932365051,
                          >
                          > 246307830695230159344853971299085504661118671451065969332908\
                          > 6522201134308546059459112977581864702729364124320490100075243]];
                          >
                          > for(k=1,#fooling,n=fooling[k][1];a=fooling[k][2];
                          > if(tst(n,a)&&!isprime(n),print(" Gremlins rule OK")));}
                          >
                          > Gremlins rule OK
                          > Gremlins rule OK
                          >
                          > They prefer to work around 120 digits, since then
                          > you have to be a little smarter to factor the semiprimes.
                          > I believe that Kermit will be able to factorize the two
                          > above, since he has been using other lists as practice.
                          >

                          Paul
                        • djbroadhurst
                          ... When n = 3 mod 4, Euler is identical to Miller-Rabin, since (n-1)/2 is odd. Now suppose that n = 3 mod 8 and kronecker(Q,n) = +1. Then the only
                          Message 12 of 24 , Jul 18, 2013
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                            --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@...> wrote:

                            > strong tests

                            When n = 3 mod 4, Euler is identical to Miller-Rabin,
                            since (n-1)/2 is odd.

                            Now suppose that n = 3 mod 8 and kronecker(Q,n) = +1.
                            Then the only stengthening of Lucas is to show that
                            L^((n+1)/4) (mod all that other stuff) is +1 or -1.
                            since (n+1)/4 is odd.

                            {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                            sum(k=1,#v,gcd(v[k],n)>1)==0;}

                            {tst3mod8(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                            !isprime(n)&&n%8==3&&kronecker(Q,n)==1&& \\ just to keep Paul happy
                            Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                            Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                            Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                            Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&(
                            Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/4)==+1||
                            Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/4)==-1);}

                            {if(tst3mod8(1080534578729388602707,3487806307751356235),
                            print(" Done!"));}

                            Done!

                            David
                          • paulunderwooduk
                            ... Wonderful! Thanks for the exposition. It is another example of how a one parameter Lucas plus N Fermat/Euler/M-R PRP test can be counterexampled. Once
                            Message 13 of 24 , Jul 18, 2013
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                              --- In primenumbers@yahoogroups.com, "djbroadhurst" <d.broadhurst@...> wrote:
                              >
                              >
                              >
                              > --- In primenumbers@yahoogroups.com, "paulunderwooduk" <paulunderwood@> wrote:
                              >
                              > > strong tests
                              >
                              > When n = 3 mod 4, Euler is identical to Miller-Rabin,
                              > since (n-1)/2 is odd.
                              >
                              > Now suppose that n = 3 mod 8 and kronecker(Q,n) = +1.
                              > Then the only stengthening of Lucas is to show that
                              > L^((n+1)/4) (mod all that other stuff) is +1 or -1.
                              > since (n+1)/4 is odd.
                              >
                              > {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                              > sum(k=1,#v,gcd(v[k],n)>1)==0;}
                              >
                              > {tst3mod8(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                              > !isprime(n)&&n%8==3&&kronecker(Q,n)==1&& \\ just to keep Paul happy
                              > Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                              > Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                              > Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                              > Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&(
                              > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/4)==+1||
                              > Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/4)==-1);}
                              >
                              > {if(tst3mod8(1080534578729388602707,3487806307751356235),
                              > print(" Done!"));}
                              >
                              > Done!
                              >

                              Wonderful! Thanks for the exposition. It is another example of how a one parameter Lucas plus N Fermat/Euler/M-R PRP test can be counterexampled. Once again you and the Gremlins have rescued a core or two from inane computation,

                              Paul
                            • djbroadhurst
                              ... That s what Gremlins are for. ... Here is one of many ways to evade your wriggles, which had trivial gcds. I give a pair of smarter gcds, which serve for
                              Message 14 of 24 , Jul 19, 2013
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                                --- In primenumbers@yahoogroups.com,
                                "paulunderwooduk" <paulunderwood@...> wrote:

                                > Wonderful! Thanks for the exposition. It is another example
                                > of how a one parameter Lucas plus N Fermat/Euler/M-R PRP test
                                > can be counterexampled.

                                That's what Gremlins are for.

                                > I am unable to crack the gcd tricks

                                Here is one of many ways to evade your wriggles, which had
                                trivial gcds. I give a pair of smarter gcds, which serve
                                for three small examples, But as soon as we include this trap
                                the Gremlins will find another smart way out.

                                {wriggle(a,n)=local(v=[a,3*a^2+1,5*a^2-1,13*a^2-1,7*a^2-3]);
                                sum(k=1,#v,gcd(v[k],n)>1)==0;}

                                {tst(n,a)=local(Q=3*a^2+1);kronecker(a^2-1,n)==-1&&wriggle(a,n)&&
                                Mod(a,n)^((n-1)/2)==kronecker(a,n)&&
                                Mod(a-1,n)^((n-1)/2)==kronecker(a-1,n)&&
                                Mod(a+1,n)^((n-1)/2)==kronecker(a+1,n)&&
                                Mod(Q,n)^((n-1)/2)==kronecker(Q,n)&&
                                Mod(Mod(1,n)*L,L^2-lift(Mod((10*a^2-2)/Q,n))*L+1)^((n+1)/2)==kronecker(Q,n);}

                                {smart(a,n)=local(v=[
                                581130733*a^18-1549681961*a^16+1598109492*a^14-815197364*a^12
                                +219605318*a^10-31108446*a^8+2189796*a^6-67524*a^4+693*a^2-1,
                                290565367*a^18-920123659*a^16+1150154588*a^14-728431196*a^12
                                +250797682*a^10-47124218*a^8+4637292*a^6-217740*a^4+4047*a^2-19]);
                                sum(k=1,#v,gcd(v[k],n)>1)>0;}

                                {fooling=[
                                [2972225251*112944559501,48957135643862669970],
                                [3047555083*115807093117,49017305561177450303],
                                [3130042291*118941607021,169666628495887666139]];

                                for(k=1,#fooling,n=fooling[k][1];a=fooling[k][2];if(tst(n,a)
                                &&smart(a,n),print(" fooled wriggle, trapped smartly")));}

                                fooled wriggle, trapped smartly
                                fooled wriggle, trapped smartly
                                fooled wriggle, trapped smartly

                                The derivation of the pair of polynomials, for
                                these particular cases, is left as an exercise.

                                David (spilling the Gremlins' secrets)
                              • djbroadhurst
                                ... Maybe Kermit read http://selmer.warwick.ac.uk/onelinefactor.pdf {OLF(x)=;i=1;while(i
                                Message 15 of 24 , Jul 31, 2013
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                                  --- In primenumbers@yahoogroups.com,
                                  "paulunderwooduk" <paulunderwood@...> wrote:

                                  > I am in the dark as to how Kermit factored the numbers in:
                                  > http://tech.groups.yahoo.com/group/primenumbers/message/25227

                                  Maybe Kermit read
                                  http://selmer.warwick.ac.uk/onelinefactor.pdf

                                  {OLF(x)=;i=1;while(i<x,if(issquare(ceil(sqrt(i*x))^2%x),
                                  return(gcd(x,floor(ceil(sqrt(i*x))-sqrt((ceil(sqrt(i*x))^2)%x)))));i++);}

                                  {default(realprecision,130);gettime;
                                  N1=16212200212765236462624941301662595905969969921486185624581
                                  42710646148264113979405459683534701445570403174269878228032843;
                                  N2=92856680188887785533016964629715768104484119019221599899820
                                  26844918042826013874700027439880606063780672269637251932365051;
                                  print(OLF(N1)" divides N1");
                                  print(OLF(N2)" divides N2");
                                  print("This took "gettime" millisecond(s)");}

                                  5972172173345601078558810561451365062976970419888735246630677 divides N1
                                  11401725845872759790535993230138294233298881744517681451802021 divides N2
                                  This took 1 millisecond(s)

                                  David
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