837 lines
34 KiB
Plaintext
837 lines
34 KiB
Plaintext
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#############################################################################
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##
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#W examples.gi Examples [loops]
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##
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#H @(#)$Id: examples.gi, v 3.3.0 2016/10/19 gap Exp $
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##
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#Y Copyright (C) 2004, G. P. Nagy (University of Szeged, Hungary),
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#Y P. Vojtechovsky (University of Denver, USA)
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##
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#############################################################################
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## Binding global variable LOOPS_aux
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##
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## The variable is used for temporary storage throughout the package.
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## We therefore do not want the variable to be read only.
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LOOPS_aux := [];
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#############################################################################
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## READING DATA
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## -------------------------------------------------------------------------
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# up to isomorphism
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ReadPackage("loops", "data/leftbol.tbl"); # left Bol loops
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ReadPackage("loops", "data/moufang.tbl"); # Moufang loops
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ReadPackage("loops", "data/paige.tbl"); # Paige loops
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ReadPackage("loops", "data/code.tbl"); # code loops
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ReadPackage("loops", "data/steiner.tbl"); # Steiner loops
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ReadPackage("loops", "data/cc.tbl"); # CC loops
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ReadPackage("loops", "data/rcc.tbl"); # RCC loops (more is read upon calling RCCLoop(n,m) for the first time
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ReadPackage("loops", "data/small.tbl"); # small loops
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ReadPackage("loops", "data/interesting.tbl"); # interesting loops
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ReadPackage("loops", "data/nilpotent.tbl"); # nilpotent loops
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ReadPackage("loops", "data/automorphic.tbl"); # automorphic loops
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# up to isotopism
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ReadPackage("loops", "data/itp_small.tbl"); # small loops up to isotopism
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#############################################################################
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## DISPLAYING INFORMATION ABOUT A LIBRARY
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## -------------------------------------------------------------------------
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#############################################################################
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##
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#F LOOPS_LibraryByName( name )
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##
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## Auxiliary. Returns the library corresponding to <name>.
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InstallGlobalFunction( LOOPS_LibraryByName,
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function( name )
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#up to isomorphism
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if name = "left Bol" then return LOOPS_left_bol_data;
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elif name = "Moufang" then return LOOPS_moufang_data;
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elif name = "Paige" then return LOOPS_paige_data;
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elif name = "code" then return LOOPS_code_data;
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elif name = "Steiner" then return LOOPS_steiner_data;
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elif name = "CC" then return LOOPS_cc_data;
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elif name = "RCC" then return LOOPS_rcc_data;
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elif name = "small" then return LOOPS_small_data;
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elif name = "interesting" then return LOOPS_interesting_data;
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elif name = "nilpotent" then return LOOPS_nilpotent_data;
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elif name = "automorphic" then return LOOPS_automorphic_data;
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#up to isotopism
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elif name = "itp small" then return LOOPS_itp_small_data;
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fi;
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end);
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#############################################################################
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##
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#F DisplayLibraryInfo( name )
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##
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## Display information about library named <name>.
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InstallGlobalFunction( DisplayLibraryInfo, function( name )
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local s, lib, k;
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# up to isomorphism
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if name = "left Bol" then
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s := "The library contains all nonassociative left Bol loops of order less than 17\nand all nonassociative left Bol loops of order p*q, where p>q>2 are primes.";
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elif name = "right Bol" then
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s := "The library contains all nonassociative right Bol loops of order less than 17\nand all nonassociative left Bol loops of order p*q, where p>q>2 are primes.";
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name := "left Bol"; # using dual data
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elif name = "Moufang" then
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s := "The library contains all nonassociative Moufang loops \nof order less than 65, and all nonassociative Moufang \nloops of order 81 and 243.";
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elif name = "Paige" then
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s := "The library contains the smallest nonassociative finite \nsimple Moufang loop.";
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elif name = "code" then
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s := "The library contains all nonassociative even code loops \nof order less than 65.";
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elif name = "Steiner" then
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s := "The library contains all nonassociative Steiner loops \nof order less or equal to 16. It also contains the \nassociative Steiner loops of order 4 and 8.";
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elif name = "CC" then
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s := "The library contains all nonassociative CC loops of order less than 28 \nand all nonassociative CC loops of order p^2 and 2*p for any odd prime p.";
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elif name = "RCC" then
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s := "The library contains all nonassociative RCC loops of order less than 28.";
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elif name = "LCC" then
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s := "The library contains all nonassociative LCC loops of order less than 28.";
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name := "RCC"; # using dual data
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elif name = "small" then
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s := "The library contains all nonassociative loops of order less than 7.";
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elif name = "interesting" then
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s := "The library contains a few interesting loops.";
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elif name = "nilpotent" then
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s := "The library contains all nonassociative nilpotent loops \nof order less than 12.";
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elif name = "automorphic" then
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s := "The library contains:\n";
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s := Concatenation(s," - all nonassociative automorphic loops of order less than 16,\n");
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s := Concatenation(s," - all commutative automorphic loops of order 3, 9, 27, 81,\n");
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s := Concatenation(s," - all commutative automorphic loops of order 243 that are central\n");
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s := Concatenation(s," extensions of Z_3 by F, where F is not the elem. ab. 3-group.\n");
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s := Concatenation(s,"Note: Abelian groups are included among the commutative loops.");
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# up to isotopism
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elif name = "itp small" then
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s := "The library contains all nonassociative loops of order less than 7 up to isotopism.";
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else
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Info( InfoWarning, 1, Concatenation(
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"The admissible names for loop libraries are: \n",
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"[ \"left Bol\", \"right Bol\", \"Moufang\", \"Paige\", \"code\", \"Steiner\", \"CC\", \"RCC\", \"LCC\", \"small\", \"itp small\", \"interesting\", \"nilpotent\", \"automorphic\" ]."
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) );
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return fail;
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fi;
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s := Concatenation( s, "\n------\nExtent of the library:" );
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lib := LOOPS_LibraryByName( name );
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for k in [1..Length( lib[ 1 ] ) ] do
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if lib[ 2 ][ k ] = 1 then
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s := Concatenation( s, "\n ", String( lib[ 2 ][ k ] ), " loop of order ", String( lib[ 1 ][ k ] ) );
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else
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s := Concatenation( s, "\n ", String( lib[ 2 ][ k ] ), " loops of order ", String( lib[ 1 ][ k ] ) );
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fi;
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od;
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if name = "left Bol" or name = "right Bol" then
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s := Concatenation( s, "\n (p-q)/2 loops of order p*q for primes p>q>2 such that q divides p-1");
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s := Concatenation( s, "\n (p-q+2)/2 loops of order p*q for primes p>q>2 such that q divides p+1" );
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fi;
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if name = "CC" then
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s := Concatenation( s, "\n 3 loops of order p^2 for every odd prime p,\n 1 loop of order 2*p for every odd prime p" );
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fi;
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s := Concatenation( s, "\n" );
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Print( s );
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return true;
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end);
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#############################################################################
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## AUXILIARY FUNCTIONS
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## -------------------------------------------------------------------------
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## When the data in the database is encoded in some way, we usually
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## retrieve the loop via function LOOPS_ActivateXLoop, where X is the name
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## of the class.
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#############################################################################
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##
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#F LOOPS_SmallestNonsquare( p )
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##
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## Auxiliary function.
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## Returns the smallest nonsquare modulo p.
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InstallGlobalFunction( LOOPS_SmallestNonsquare,
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function( p )
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local squares, i;
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squares := Set( [1..p-1], i->i^2 mod p );
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for i in [2..p-1] do
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if not i in squares then return i; fi;
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od;
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return fail; # will never happen if p>2 is prime
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end);
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#############################################################################
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##
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#F LOOPS_ActivateLeftBolLoopPQ( p, q, m )
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##
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## Auxiliary function for activating left Bol loop of order p*q.
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## See paper by Kinyon, Nagy and Vojtechovsky.
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## p>q>2 are primes such that q divides p^2-1, m is an integer in the range [1..(p-q)/2] or [1..(p-q+2)/2]
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InstallGlobalFunction( LOOPS_ActivateLeftBolLoopPQ,
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function( p, q, m )
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local F, omega, lambda, ev, inv_ev, params, t, sqrt_t, final_params, alpha, theta, GFp, ct, i, j, k, l, u, v, w, x, y;
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F := GF(p^2);
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omega := PrimitiveRoot( F )^((p^2-1)/q);
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lambda := omega + omega^(-1);
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ev := List([0..q-1], j -> omega^j);
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inv_ev := List([0..q-1], j -> omega^(-j));
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if IsInt((p-1)/q) then
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params := List([2..p-1], j->j*One(F)); # GF(p); 0 and 1 correspond to isomorphic nonabelian groups
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params := Filtered( params, x -> not ((One(F) - x^(-1)) in ev) );
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else # q divides p+1
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t := LOOPS_SmallestNonsquare( p );
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sqrt_t := RootsOfPolynomial( F, X(F,"x")^2 - t )[ 1 ]; # a squre root of t in GF(p^2)
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params := List([0..p-1], j -> (1/2)*One(F) + j*One(F)*sqrt_t ); # 1/2 + GF(p)\sqrt{t}
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params := Filtered( params, x -> not ((One(F) - x^(-1)) in ev) );
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fi;
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final_params := [];
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for x in params do
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if not ( (One(F)-x) in final_params ) then
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Add( final_params, x );
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fi;
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od;
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alpha := final_params[ m ];
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theta := alpha*ev + (One(F)-alpha)*inv_ev;
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theta := List( theta, x -> x^(-1) );
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GFp := List([0..p-1], j -> j*One(F));
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theta := List( theta, x -> Position( GFp, x )-1 );
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# construct the Cayley table according to (a^i b^j)*(a^k b^l) = a^{i+k} b^{ w + (l+w)*theta[k]^{-1}*theta[i+k], where w+w*theta[i] = j
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ct := List([1..p*q], i -> 0*[1..p*q]);
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for i in [0..q-1] do for j in [0..p-1] do for k in [0..q-1] do for l in [0..p-1] do
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u := (i+k) mod q;
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w := ( j/(1+theta[i+1]) ) mod p;
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v := ( w + (l+w)*theta[ ((i+k) mod q) + 1 ]/theta[k+1] ) mod p;
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x := i*p+j+1;
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y := k*p+l+1;
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ct[x][y] := u*p+v+1;
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od; od; od; od;
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# return the loop
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return LoopByCayleyTable( ct );
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end);
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#############################################################################
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##
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#F LOOPS_ActivateLeftBolLoop( pos_n, m, case )
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##
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## Auxiliary function for activating left Bol loops from the database.
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## case = [p,q] if it is a left Bol loop of order p*q, with p>q>2 primes such that q divides p^2-1
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## case = false otherwise
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## pos_n is meaningless when case = [p,q]
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InstallGlobalFunction( LOOPS_ActivateLeftBolLoop,
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function( pos_n, m, case )
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local rep_m, ct, perm;
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if not case=false then # p*q
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return LOOPS_ActivateLeftBolLoopPQ( case[1], case[2], m );
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fi;
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# in database
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rep_m := m;
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# searching for a Cayley table on which the loop is based
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while not IsString( LOOPS_left_bol_data[ 3 ][ pos_n ][ rep_m ] ) do
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rep_m := rep_m - 1;
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od;
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if rep_m = m then # loop given by encoded Cayley table
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ct := LOOPS_DecodeCayleyTable( LOOPS_left_bol_data[ 3 ][ pos_n ][ m ] );
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else # loop given as an isotope of another loop
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ct := LOOPS_DecodeCayleyTable( LOOPS_left_bol_data[ 3 ][ pos_n ][ rep_m ] );
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perm := PermList( ct[ LOOPS_left_bol_data[ 3 ][ pos_n ][ m ] ] );
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ct := Set( List( ct, row -> OnTuples( row, perm^-1 ) ) );
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fi;
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return LoopByCayleyTable( ct );
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end);
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#############################################################################
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##
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#F LOOPS_ActivateMoufangLoop( n, pos_n, m )
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##
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## Auxiliary function for activating Moufang loops from the database.
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InstallGlobalFunction( LOOPS_ActivateMoufangLoop,
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function( n, pos_n, m )
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local d, parent_m, parent, S, a, h, e, f, G, ret, x, row, y, b, c, z;
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d := LOOPS_moufang_data[ 3 ][ pos_n ][ m ]; #data
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# orders 81 and 243 are represented as central extensions
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if n = 81 or n = 243 then
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return LoopByExtension(
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IntoLoop( SmallGroup( d[1], d[2] ) ), # K
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IntoLoop( SmallGroup( d[3], d[4] ) ), # F
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List([1..d[3]], i -> () ), # trivial action F -> Aut( K )
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LOOPS_DecodeCocycle( [ n/d[1], false, d[5] ], [1..d[1]] ) # cocycle
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);
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fi;
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# all other orders
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if d[ 1 ] > 0 then # must activate parent first
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# determine position of parent ( d[1] gives it relative to the class leader )
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while LOOPS_moufang_data[ 3 ][ pos_n ][ m ][ 1 ] > 0 do
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m := m - 1;
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od;
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m := m + d[ 1 ] - 1;
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parent := LOOPS_ActivateMoufangLoop( n, pos_n, m );
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if d[ 2 ] = "C" then #cyclic modification
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S := List( d[ 3 ], i -> Elements( parent )[ i ] );
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a := Elements( parent )[ d[ 4 ] ];
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h := Elements( parent )[ d[ 5 ] ];
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return LoopByCyclicModification( parent, S, a, h );
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fi;
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if d[ 2 ] = "D" then # dihedral modification
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S := List( d[ 3 ], i -> Elements( parent )[ i ] );
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e := Elements( parent )[ d[ 4 ] ];
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f := Elements( parent )[ d[ 5 ] ];
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h := Elements( parent )[ d[ 6 ] ];
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return LoopByDihedralModification( parent, S, e, f, h );
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fi;
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fi;
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# no parent;
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if d[ 2 ]="G" then # loop of type MG2
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G := AllGroups( d[ 3 ], IsCommutative, false)[ d[ 4 ] ]; #relies on GAP group libraries !!
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return LoopMG2( G );
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fi;
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if d[ 2 ]="T" then # special loop (direct product of an old loop and a cyclic group)
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parent := MoufangLoop( d[ 3 ][ 1 ], d[ 3 ][ 2 ]);
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return DirectProduct( parent, CyclicGroup( d[ 3 ][ 3 ] ) );
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fi;
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end);
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#############################################################################
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##
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#F LOOPS_ActivateSteinerLoop( n, pos_n, m )
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##
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## Auxiliary function activating Steiner loops from the database.
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##
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## The database LOOPS_steiner_data contains blocks of steiner triple systems.
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## If the system is on k points, the poitns are labelled 0,...,k-1.
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## The constructed Steiner loop has elements labelled 1,...,k+1=n
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InstallGlobalFunction( LOOPS_ActivateSteinerLoop,
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function( n, pos_n, m )
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local d, blocks, i, T, i_in, ij_in, j, MyInt;
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#############################################################################
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##
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#F MyInt( s )
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##
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## Auxiliary function.
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## Given a digit or a lower case letter, returns the numerical value, where
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## a = 10, f=15
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MyInt := function( s )
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return Position( "0123456789abcdef", s ) - 1;
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end;
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d := LOOPS_steiner_data[ 3 ][ pos_n ][ m ]; # data for the loop = three strings
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# creating the blocks
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blocks := [];
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for i in [1..Length( d[ 1 ] )] do
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Add( blocks, [ MyInt( d[1][i] ), MyInt( d[2][i] ), MyInt( d[3][i] ) ] );
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od;
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#creating the multiplication table
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T := List( [1..n], i->[1..n] );
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for i in [1..n] do T[i][1] := i; od;
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for i in [0..n-2] do
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i_in := Filtered( blocks, B->i in B);
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for j in [0..n-2] do
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if j=i then T[i+2][j+2] := 1; fi;
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if not j=i then
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ij_in := Filtered( i_in, B->j in B )[1]; #unique block;
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T[i+2][j+2] := Difference( ij_in, [i,j])[1] + 2;
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fi;
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od;
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od;
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return LoopByCayleyTable( T );
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end);
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#############################################################################
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##
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#F LOOPS_ActivateRCCLoop( n, pos_n, m )
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##
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## Activates an RCC loop from the library.
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||
|
## See manual for complete discussion concerning this library.
|
||
|
|
||
|
InstallGlobalFunction( LOOPS_ActivateRCCLoop,
|
||
|
function( n, pos_n, m )
|
||
|
local pos_m, g, nr_conj_classes, data, data2, next_compactified, x, i, rel_m, G, section, pos_conjugacy_classes;
|
||
|
|
||
|
if IsEmpty( LOOPS_rcc_transitive_groups ) then # data not read yet
|
||
|
ReadPackage( "loops", "data/rcc/rcc_transitive_groups.tbl" );
|
||
|
fi;
|
||
|
# determining the transitive group corresponding to pos_n, m
|
||
|
pos_m := Length( LOOPS_rcc_data[ 3 ][ pos_n ][ 1 ] ); # nr of transitive groups associated with order n
|
||
|
while LOOPS_rcc_data[ 3 ][ pos_n ][ 2 ][ pos_m ] > m do
|
||
|
pos_m := pos_m - 1;
|
||
|
od;
|
||
|
g := LOOPS_rcc_data[ 3 ][ pos_n ][ 1 ][ pos_m ]; # index of transitive group (of degree n) in GAP library
|
||
|
# activating data for the group, if needed
|
||
|
if not IsBound( LOOPS_rcc_sections[ pos_n ][ pos_m ] ) then
|
||
|
# data must be read from file and decoded
|
||
|
ReadPackage( "loops", Concatenation( "data/rcc/sections", String(n), ".", String(g), ".tbl" ) );
|
||
|
# variable LOOPS_aux is now read and ready to be processed
|
||
|
nr_conj_classes := Length( LOOPS_rcc_transitive_groups[ pos_n ][ pos_m ][ 2 ] );
|
||
|
data := SplitString( LOOPS_aux, " " );
|
||
|
data2 := [];
|
||
|
next_compactified := false;
|
||
|
for x in data do
|
||
|
if x="" then # the next entry is compactified, eg. "a$X" means "a", "$", "X"
|
||
|
next_compactified := true;
|
||
|
elif not next_compactified then
|
||
|
Add( data2, x );
|
||
|
else # compactified string
|
||
|
next_compactified := false;
|
||
|
for i in [1..Length(x)] do
|
||
|
Add( data2, x{[i..i]} ); # Add( data2, x[i] ) is not safe when data2 is empty
|
||
|
od;
|
||
|
fi;
|
||
|
od;
|
||
|
data := List( data2, x -> LOOPS_ConvertToDecimal( x, 91 ) );
|
||
|
# reconstructing the sequence from the difference sequence
|
||
|
for i in [2..Length( data )] do
|
||
|
data[ i ] := data[ i-1 ] - data[ i ];
|
||
|
od;
|
||
|
LOOPS_rcc_sections[ pos_n ][ pos_m ] := data;
|
||
|
fi;
|
||
|
# data is now loaded
|
||
|
G := TransitiveGroup(n, g);
|
||
|
rel_m := m - LOOPS_rcc_data[ 3 ][ pos_n ][ 2 ][ pos_m ] + 1; # relative position of the loop in the file for G
|
||
|
section := [];
|
||
|
nr_conj_classes := Length( LOOPS_rcc_transitive_groups[ pos_n ][ pos_m ][ 2 ] );
|
||
|
if not LOOPS_rcc_conjugacy_classes[ 1 ] = [ n, g ] then # must calculate conjugacy classes, so let's reset old data
|
||
|
LOOPS_rcc_conjugacy_classes[ 1 ] := [ n, g ];
|
||
|
LOOPS_rcc_conjugacy_classes[ 2 ] := List( [1..nr_conj_classes], x->[] );
|
||
|
fi;
|
||
|
x := LOOPS_rcc_sections[ pos_n ][ pos_m ][ rel_m ];
|
||
|
x := LOOPS_ConvertFromDecimal( x, 2, nr_conj_classes ); # convert to a binary string of prescribed length
|
||
|
pos_conjugacy_classes := Positions( x, '1' );
|
||
|
for i in [1..nr_conj_classes] do
|
||
|
if LOOPS_rcc_conjugacy_classes[ 2 ][ i ] = [] then
|
||
|
LOOPS_rcc_conjugacy_classes[ 2 ][ i ] := Elements( ConjugacyClass( G, LOOPS_rcc_transitive_groups[ pos_n ][ pos_m ][ 2 ][ i ] ) );
|
||
|
fi;
|
||
|
od;
|
||
|
section := Concatenation( LOOPS_rcc_conjugacy_classes[ 2 ]{pos_conjugacy_classes} );
|
||
|
Add( section, One( G ) ); # the trivial class is contained in all loops and never stored
|
||
|
Sort( section );
|
||
|
return LoopByRightSection( section );
|
||
|
end);
|
||
|
|
||
|
#############################################################################
|
||
|
##
|
||
|
#F LOOPS_ActivateCCLoop( n, pos_n, m, case )
|
||
|
##
|
||
|
## Activates a CC-loop from the library.
|
||
|
## The argument p_case is set to [p,"p^2"] if n = p^2, to [p,"2*p"] if n=2*p, and false otherwise.
|
||
|
## See manual for complete discussion concerning this library.
|
||
|
|
||
|
InstallGlobalFunction( LOOPS_ActivateCCLoop,
|
||
|
function( n, pos_n, m, case )
|
||
|
local T, x, y, k, a, b, p;
|
||
|
|
||
|
if case=false then # use library of RCC loops, must recalculate pos_n
|
||
|
return LOOPS_ActivateRCCLoop( n, Position(LOOPS_rcc_data[ 1 ], n), LOOPS_cc_data[ 3 ][ pos_n ][ m ] );
|
||
|
fi;
|
||
|
|
||
|
# parameters n, m are already checked to be permissible
|
||
|
p := case[ 1 ];
|
||
|
if case[ 2 ] = "2*p" then # 2*p
|
||
|
T := List( [1..n], i -> [1..n ] );
|
||
|
for a in [0..p-1] do for b in [0..p-1] do
|
||
|
T[a+1][b+1]:= ((a+b) mod p) + 1;
|
||
|
T[a+1][p+b+1] := p + ((-a+b) mod p ) + 1;
|
||
|
T[p+a+1][b+1] := p + ((a+b) mod p) + 1;
|
||
|
T[p+a+1][p+b+1] := ((1-a+b) mod p) + 1;
|
||
|
od; od;
|
||
|
return LoopByCayleyTable( T );
|
||
|
fi;
|
||
|
|
||
|
# p^2
|
||
|
T := List([1..n], i->[1..n]);
|
||
|
if m = 1 then
|
||
|
for x in [0..n-1] do for y in [0..n-1] do
|
||
|
T[ x+1 ][ y+1 ] := ((x + y + p*(x^2)*y) mod n) + 1;
|
||
|
od; od;
|
||
|
elif m = 2 then
|
||
|
k := LOOPS_SmallestNonsquare( p );
|
||
|
for x in [0..n-1] do for y in [0..n-1] do
|
||
|
T[ x+1 ][ y+1 ] := ((x + y + k*p*(x^2)*y) mod n) + 1;
|
||
|
od; od;
|
||
|
elif m = 3 then
|
||
|
for x in [0..p-1] do for y in [0..p-1] do for a in [0..p-1] do for b in [0..p-1] do
|
||
|
T[ x*p+a+1 ][ y*p+b+1 ] := ((x+y) mod p)*p + ((a+b+(x^2)*y) mod p) + 1;
|
||
|
od; od; od; od;
|
||
|
fi;
|
||
|
return LoopByCayleyTable( T );
|
||
|
end);
|
||
|
|
||
|
#############################################################################
|
||
|
##
|
||
|
#F LOOPS_ActivateNilpotentLoop( data )
|
||
|
##
|
||
|
## Activates the nilpotent loop based on data = [ K, F, t ], where
|
||
|
## K determines a central (normal) subloop,
|
||
|
## F determines the factor loop,
|
||
|
## t determines the cocycle.
|
||
|
## Understanding K and F:
|
||
|
## If the value of K or F is in [2,3,4,5], it is the cyclic group of order V.
|
||
|
## If the value of K or F is 0, it is the Klein group.
|
||
|
## Understanding t:
|
||
|
## The cocycle is mapping from F x F to K. Let f = |F|. Let k = |K|.
|
||
|
## The value t corresponds to a (f-1)x(f-1) array of values in [0..k-1].
|
||
|
## It is represented by a single integer in base k, with the least
|
||
|
## significant digit in the first row and first column, then following
|
||
|
## the rows.
|
||
|
## Once t is decoded into a (f-1)x(f-1) array, 1 is added to all entries.
|
||
|
## Then a first row and forst column of all ones is added to t,
|
||
|
## resulting in a f x f array.
|
||
|
## The loop is then obtained via LoopByExtension( K, F, phi, t), where
|
||
|
## phi is trivial.
|
||
|
|
||
|
InstallGlobalFunction( LOOPS_ActivateNilpotentLoop,
|
||
|
function( data )
|
||
|
local K, F, f, k, t, theta, i, j, phi;
|
||
|
|
||
|
# preparing normal subloop and factor loop
|
||
|
if data[ 1 ] = 0 then
|
||
|
K := IntoLoop( Group( (1,2),(3,4) ) );
|
||
|
else
|
||
|
K := IntoLoop( CyclicGroup( data[ 1 ] ) );
|
||
|
fi;
|
||
|
if data[ 2 ] = 0 then
|
||
|
F := IntoLoop( Group( (1,2),(3,4) ) );
|
||
|
else
|
||
|
F := IntoLoop( CyclicGroup( data[ 2 ] ) );
|
||
|
fi;
|
||
|
|
||
|
# preparing cocycle
|
||
|
f := Size( F );
|
||
|
k := Size( K );
|
||
|
t := data[ 3 ];
|
||
|
theta := List( [1..f], i->[1..f] );
|
||
|
for i in [2..f] do
|
||
|
theta[ 1 ][ i ] := 1;
|
||
|
od;
|
||
|
for i in [2..f] do for j in [2..f] do
|
||
|
theta[ i ][ j ] := t mod k;
|
||
|
t := (t - theta[i][j])/k;
|
||
|
theta[ i ][ j ] := theta[ i ][ j ] + 1;
|
||
|
od; od;
|
||
|
|
||
|
# preparing trivial action
|
||
|
phi := List([1..f], i -> () );
|
||
|
|
||
|
# constructing the loop
|
||
|
return LoopByExtension( K, F, phi, theta );
|
||
|
|
||
|
end);
|
||
|
|
||
|
#############################################################################
|
||
|
##
|
||
|
#F LOOPS_ActivateAutomorphicLoop( n, m )
|
||
|
##
|
||
|
## Activates an automorphic loop from the library.
|
||
|
|
||
|
InstallGlobalFunction( LOOPS_ActivateAutomorphicLoop,
|
||
|
function( n, m )
|
||
|
local i, pos_n, factor_id, F, dim, coords, basis, coc;
|
||
|
if IsEmpty( LOOPS_automorphic_cocycles ) then # only read on demand
|
||
|
ReadPackage( "loops", "data/automorphic/automorphic_cocycles.tbl");
|
||
|
# decode cocycles
|
||
|
for i in [1..3] do
|
||
|
LOOPS_automorphic_cocycles[ i ] := List( LOOPS_automorphic_cocycles[ i ],
|
||
|
c -> LOOPS_DecodeCocycle( [ 3^(i+2), true, c ], [0,1,2] )
|
||
|
);
|
||
|
od;
|
||
|
# separate coordinates (from a long string )
|
||
|
for i in [1..3] do
|
||
|
LOOPS_automorphic_coordinates[ i ] := SplitString( LOOPS_automorphic_coordinates[ i ], " " );
|
||
|
od;
|
||
|
fi;
|
||
|
# factor loop
|
||
|
pos_n := Position( [27,81,243], n );
|
||
|
factor_id := LOOPS_CharToDigit( LOOPS_automorphic_coordinates[ pos_n ][ m ][ 1 ] );
|
||
|
F := AutomorphicLoop( n/3, factor_id );
|
||
|
# coordinates determining the cocycle
|
||
|
dim := Length( LOOPS_automorphic_bases[ pos_n ][ factor_id ] );
|
||
|
coords := LOOPS_automorphic_coordinates[ pos_n ][ m ];
|
||
|
coords := coords{[2..Length(coords)]}; # remove the character that determines factor id
|
||
|
coords := LOOPS_ConvertBase( coords, 91, 3, dim );
|
||
|
coords := List( coords, LOOPS_CharToDigit );
|
||
|
# basis
|
||
|
basis := List( LOOPS_automorphic_bases[ pos_n ][ factor_id ],
|
||
|
i -> LOOPS_automorphic_cocycles[ pos_n ][ i ]
|
||
|
);
|
||
|
# calculate cocycle
|
||
|
coc := (coords*basis) mod 3;
|
||
|
coc := List( coc, i -> i+1 );
|
||
|
# return extension of Z_3 by F using cocycle and trivial action
|
||
|
return LoopByExtension( AutomorphicLoop(3,1), F, List([1..n/3], i -> () ), coc );
|
||
|
end);
|
||
|
|
||
|
#############################################################################
|
||
|
## READING LOOPS FROM THE LIBRARY - GENERIC METHOD
|
||
|
## -------------------------------------------------------------------------
|
||
|
|
||
|
#############################################################################
|
||
|
##
|
||
|
#F LibraryLoop( name, n, m )
|
||
|
##
|
||
|
## returns he <m>th loop of order <n> from the library named <name>
|
||
|
|
||
|
InstallGlobalFunction( LibraryLoop, function( name, n, m )
|
||
|
|
||
|
local lib, implemented_orders, NOL, loop, pos_n, p, q, divs, PG, m_inv, root, half, case, g, h;
|
||
|
|
||
|
# selecting data library
|
||
|
if name = "right Bol" then # using dual data
|
||
|
lib := LOOPS_LibraryByName( "left Bol" );
|
||
|
elif name = "LCC" then # using dual data
|
||
|
lib := LOOPS_LibraryByName( "RCC" );
|
||
|
else
|
||
|
lib := LOOPS_LibraryByName( name );
|
||
|
fi;
|
||
|
|
||
|
# extent of the library
|
||
|
implemented_orders := lib[ 1 ];
|
||
|
|
||
|
# number of loops of given order in the library
|
||
|
NOL := lib[ 2 ];
|
||
|
|
||
|
# testing arguments
|
||
|
if (not n in Integers) or (not m in Integers) or not (n>0) or not (m>0) then
|
||
|
Error("LOOPS: Both arguments must be positive integers.");
|
||
|
fi;
|
||
|
# parameters for handling systematic cases, such as CCLoop( p^2, 1 )
|
||
|
pos_n := fail;
|
||
|
case := false;
|
||
|
if name="left Bol" or name="right Bol" then
|
||
|
divs := DivisorsInt( n );
|
||
|
if Length( divs ) = 4 and not IsInt( divs[3]/divs[2] ) then # case n = p*q
|
||
|
q := divs[ 2 ];
|
||
|
p := divs[ 3 ];
|
||
|
case := [p,q];
|
||
|
if not (IsOddInt( q ) and IsInt((p^2-1)/q)) then
|
||
|
Error("LOOPS: Nonassociative ", name, " loops of order p*q exist only for primes p>q>2 such that q divides p^2-1.");
|
||
|
fi;
|
||
|
if IsInt((p-1)/q) and (not m in [1..(p-q)/2]) then
|
||
|
Error("LOOPS: There are only ", (p-q)/2, " nonassociative ", name, " loops of order ", n, ".");
|
||
|
fi;
|
||
|
if IsInt((p+1)/q) and (not m in [1..(p-q+2)/2]) then
|
||
|
Error("LOOPS: There are only ", (p-q+2)/2, " nonassociative ", name, " loops of order ", n, ".");
|
||
|
fi;
|
||
|
fi;
|
||
|
fi;
|
||
|
if name="CC" then
|
||
|
divs := DivisorsInt( n );
|
||
|
if Length( divs ) = 3 then # case p^2
|
||
|
p := divs[ 2 ];
|
||
|
case := [p,"p^2"];
|
||
|
if not m in [1..3] then
|
||
|
Error("LOOPS: There are only 3 nonassociative CC-loops of order p^2 for an odd prime p.");
|
||
|
fi;
|
||
|
elif Length( divs ) = 4 and not IsInt( divs[3]/divs[2] ) then # p*q
|
||
|
p := divs[ 3 ];
|
||
|
case := [p,"2*p"];
|
||
|
if not divs[2] = 2 then
|
||
|
Error("LOOPS: Order ", n, " not implemented.");
|
||
|
fi;
|
||
|
if not m=1 then
|
||
|
Error("LOOPS: There is only 1 nonassociative CC-loop of order 2*p for an odd prime p.");
|
||
|
fi;
|
||
|
fi;
|
||
|
fi;
|
||
|
if case=false then
|
||
|
if not n in implemented_orders then
|
||
|
Error("LOOPS: Order ", n, " not implemented.");
|
||
|
fi;
|
||
|
pos_n := Position( implemented_orders, n );
|
||
|
if NOL[ pos_n ] < m then
|
||
|
if NOL[ pos_n ] = 1 then
|
||
|
Error("LOOPS: There is only ", NOL[ pos_n ], " ", name, " loop of order ", n, " in the library.");
|
||
|
else
|
||
|
Error("LOOPS: There are only ", NOL[ pos_n ], " ", name, " loops of order ", n, " in the library.");
|
||
|
fi;
|
||
|
fi;
|
||
|
fi;
|
||
|
|
||
|
# activating the desired loop (treat cases separately below)
|
||
|
|
||
|
# up to isomorphism
|
||
|
if name = "left Bol" then
|
||
|
loop := LOOPS_ActivateLeftBolLoop( pos_n, m, case );
|
||
|
SetIsLeftBolLoop( loop, true );
|
||
|
elif name = "right Bol" then
|
||
|
loop := OppositeLoop( LOOPS_ActivateLeftBolLoop( pos_n, m, case ) );
|
||
|
SetIsRightBolLoop( loop, true );
|
||
|
elif name = "Moufang" then
|
||
|
# renaming loops so that they agree with Goodaire's classification
|
||
|
PG := List([1..243], i->());
|
||
|
PG[16] := (2,5,3,4);
|
||
|
PG[24] := (1,3,4)(2,5);
|
||
|
PG[32] := (1,4,61,7,64,31,19,44,3,51,24,46,22,49,65,9,50,39,41,2,63,27,57,14,5,55,13,69,32,58,17,53,15)
|
||
|
(6,71,28,36,30,47,18,42,26,60,21,59,35,52,25,40,23,43,29,56,20,66,8,70,33,67,38,54,16,62,37,11,68,34,45,10,48,12);
|
||
|
PG[36] := (1,2);
|
||
|
PG[40] := (1,2,5,3,4);
|
||
|
PG[48] := (1,11,43,49,30,7,28,23,36,21,50,31,41,32,46,51,29,12,42,15)
|
||
|
(2,25,24,35,22,8,39,5,6,38,16,19,17,37,34,33,4,47,13,20,10,40,48,14,3,26,45)
|
||
|
(9,27,44);
|
||
|
PG[56] := (1,2,4);
|
||
|
PG[60] := (1,2);
|
||
|
m_inv := m^Inverse( PG[ n ] );
|
||
|
# activating the loop
|
||
|
loop := LOOPS_ActivateMoufangLoop( n, pos_n, m_inv );
|
||
|
SetIsMoufangLoop( loop, true );
|
||
|
elif name = "Paige" then
|
||
|
loop := LoopByCayleyTable( lib[ 3 ][ 1 ][ 1 ] ); #only one loop there at this point
|
||
|
SetIsMoufangLoop( loop, true );
|
||
|
elif name = "code" then
|
||
|
loop := LibraryLoop( "Moufang", n, lib[ 3 ][ pos_n ][ m ] );
|
||
|
SetIsCodeLoop( loop, true );
|
||
|
elif name = "Steiner" then
|
||
|
loop := LOOPS_ActivateSteinerLoop( n, pos_n, m );
|
||
|
SetIsSteinerLoop( loop, true );
|
||
|
elif name = "CC" then
|
||
|
loop := LOOPS_ActivateCCLoop( n, pos_n, m, case );
|
||
|
SetIsCCLoop( loop, true );
|
||
|
elif name = "RCC" then
|
||
|
loop := LOOPS_ActivateRCCLoop( n, pos_n, m );
|
||
|
SetIsRCCLoop( loop, true );
|
||
|
elif name = "LCC" then
|
||
|
loop := OppositeLoop( LOOPS_ActivateRCCLoop( n, pos_n, m ) );
|
||
|
SetIsLCCLoop( loop, true );
|
||
|
elif name = "small" then
|
||
|
loop := LoopByCayleyTable( LOOPS_DecodeCayleyTable( lib[ 3 ][ pos_n ][ m ] ) );
|
||
|
elif name = "interesting" then
|
||
|
if [n,m] = [96,1] then # simple Bol loop of order 96
|
||
|
g := Group((1,4)(2,9)(3,10)(6,11)(7,12)(13,21)(14,22)(15,24)(16,23)(17,30)(18,29)(19,31)(20,32)(33,35)(38,40),
|
||
|
(1,2,4,6,8,7,5,3)(9,13,25,18,10,14,26,17)(11,15,27,20,12,16,28,19)(21,30,38,34,23,31,40,35)(22,32,39,36,24,29,37,33));
|
||
|
h := Normalizer( g, SylowSubgroup( g, 5) );
|
||
|
g := Action( g, RightCosets( g, h ), OnRight );
|
||
|
loop := LoopByRightSection(Union(Filtered(ConjugacyClasses(g),c->Size(c) in [1,15,80])));
|
||
|
else
|
||
|
loop := LoopByCayleyTable( LOOPS_DecodeCayleyTable( lib[ 3 ][ pos_n ][ m ][ 1 ] ) );
|
||
|
fi;
|
||
|
SetName( loop, lib[ 3 ][ pos_n ][ m ][ 2 ] );
|
||
|
elif name = "nilpotent" then
|
||
|
loop := LOOPS_ActivateNilpotentLoop( lib[ 3 ][ pos_n ][ m ] );
|
||
|
elif name = "automorphic" then
|
||
|
if not n in [27,81,243] then # use Cayley table
|
||
|
loop := LoopByCayleyTable( LOOPS_DecodeCayleyTable( lib[ 3 ][ pos_n ][ m ] ) );
|
||
|
else # use cocycles
|
||
|
loop := LOOPS_ActivateAutomorphicLoop( n, m );
|
||
|
fi;
|
||
|
SetIsAutomorphicLoop( loop, true );
|
||
|
# up to isotopism
|
||
|
elif name = "itp small" then
|
||
|
return LibraryLoop( "small", n, lib[ 3 ][ pos_n ][ m ] );
|
||
|
fi;
|
||
|
|
||
|
# setting the name
|
||
|
if not name = "interesting" then
|
||
|
SetName( loop, Concatenation( "<", name, " loop ", String( n ), "/", String( m ), ">" ) );
|
||
|
fi;
|
||
|
|
||
|
# returning the loop
|
||
|
return loop;
|
||
|
end);
|
||
|
|
||
|
#############################################################################
|
||
|
## READING LOOPS FROM THE LIBRARY - SPECIFIC CALLS
|
||
|
## -------------------------------------------------------------------------
|
||
|
|
||
|
#############################################################################
|
||
|
##
|
||
|
#F LeftBolLoop( n, m )
|
||
|
#F RightBolLoop( n, m )
|
||
|
#F MoufangLoop( n, m )
|
||
|
#F PaigeLoop( q )
|
||
|
#F CodeLoop( n, m )
|
||
|
#F SteinerLoop( n, m )
|
||
|
#F CCLoop( n, m )
|
||
|
#F SmallLoop( n, m )
|
||
|
#F InterestingLoop( n, m )
|
||
|
#F NilpotentLoop( n, m )
|
||
|
#F AutomorphicLoop( n, m )
|
||
|
#F ItpSmallLoop( n, m )
|
||
|
##
|
||
|
|
||
|
InstallGlobalFunction( LeftBolLoop, function( n, m )
|
||
|
return LibraryLoop( "left Bol", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( RightBolLoop, function( n, m )
|
||
|
return LibraryLoop( "right Bol", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( MoufangLoop, function( n, m )
|
||
|
return LibraryLoop( "Moufang", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( PaigeLoop, function( q )
|
||
|
# Paige loop over GF(q)
|
||
|
if not q=2 then return Error("LOOPS: Only q=2 is implemented."); fi;
|
||
|
return LibraryLoop( "Paige", 120, 1 );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( CodeLoop, function( n, m )
|
||
|
return LibraryLoop( "code", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( SteinerLoop, function( n, m )
|
||
|
return LibraryLoop( "Steiner", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( CCLoop, function( n, m )
|
||
|
return LibraryLoop( "CC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( ConjugacyClosedLoop, function( n, m )
|
||
|
return LibraryLoop( "CC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( RCCLoop, function( n, m )
|
||
|
return LibraryLoop( "RCC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( RightConjugacyClosedLoop, function( n, m )
|
||
|
return LibraryLoop( "RCC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( LCCLoop, function( n, m )
|
||
|
return LibraryLoop( "LCC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( LeftConjugacyClosedLoop, function( n, m )
|
||
|
return LibraryLoop( "LCC", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( SmallLoop, function( n, m )
|
||
|
return LibraryLoop( "small", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( InterestingLoop, function( n, m )
|
||
|
return LibraryLoop( "interesting", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( NilpotentLoop, function( n, m )
|
||
|
return LibraryLoop( "nilpotent", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( AutomorphicLoop, function( n, m )
|
||
|
return LibraryLoop( "automorphic", n, m );
|
||
|
end);
|
||
|
|
||
|
InstallGlobalFunction( ItpSmallLoop, function( n, m )
|
||
|
return LibraryLoop( "itp small", n, m );
|
||
|
end);
|