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GAP 4.8.9 installation with standard packages -- copy to your CoCalc project to get it
Project: cocalc-sagemath-dev-slelievre
Views: 418386#(C) Graham Ellis, October 2005 ##################################################################### InstallGlobalFunction(NonabelianTensorProduct, function(AG,AH) local gensAG, NiceGensAG, G, gensG, relsG, BG, GhomBG, BG1homF, gensAH, NiceGensAH, H, gensH, relsH, BH, HhomBH, AHhomH, BG2homF, F, relsT, gensF, gensF1, gensF2, AF, FhomAF, AGhomG, G1homF, G2homF, AG1homF, AG2homF, SF, gensSF, gensSFG, FhomSF, AFhomSF, AG1homSF, AG2homSF, SFhomAG, TensorProduct, delta, Trans, CrossedPairing, i,v,w,x,y,z; # This function is an adaption of the NonabelianTensorSquare() function and # so names of variables are not always the most sensible. For instance, G1 # stands for G, and G2 stands for H. # The group H is a normal subgroup of G. # AG and SF are groups whose elements are essentially enumerated. AG is # isomorphic to G and to BG. SF is equal to F/relsT and AF. Two isomorphic # copies of AG lie inside SF, and the homomorphisms AG1homSF, AG2homSF # identify the two copies. delta is the commutator map from TensorSquare to AG. # The homomorphisms GhomBG, AGhomG, FhomSF, FhomAF, AFhomSF are all # isomorphisms. The relationship between the groups is summarized in the # following diagrams: AG->G->BG->F->AF->SF and SF->AG. if not IsFinite(AG) then return NonabelianTensorProduct_Inf(AG,AH); fi; ############################################################# if Order(AH)=1 then delta:=GroupHomomorphismByFunction(AH,G,x->x); CrossedPairing:=function(x,y); return Identity(G); end; return rec(homomorphism:=delta, pairing:=CrossedPairing); fi; ############################################################ gensAG:=GeneratorsOfGroup(AG); AGhomG:=IsomorphismFpGroupByGenerators(AG,gensAG); G:=Image(AGhomG); gensG:=FreeGeneratorsOfFpGroup(G); relsG:=RelatorsOfFpGroup(G); BG:=Group(gensG); GhomBG:=GroupHomomorphismByImagesNC(G,BG, GeneratorsOfGroup(G),gensG); #I hope GhomBG really is the identity map! gensAH:=GeneratorsOfGroup(AH); AHhomH:=IsomorphismFpGroupByGenerators(AH,gensAH); H:=Image(AHhomH); gensH:=FreeGeneratorsOfFpGroup(H); relsH:=RelatorsOfFpGroup(H); BH:=Group(gensH); HhomBH:=GroupHomomorphismByImagesNC(H,BH, GeneratorsOfGroup(H),gensH); #I hope HhomBH really is the identity map! F:=FreeGroup(Length(gensG)+Length(gensH)); gensF:=GeneratorsOfGroup(F); gensF1:=[]; gensF2:=[]; for i in [1..Length(gensG)] do Append(gensF1,[gensF[i]]); od; for i in [1..Length(gensH)] do Append(gensF2,[gensF[Length(gensG)+i]]); od; BG1homF:=GroupHomomorphismByImagesNC(BG,F,gensG,gensF1); G1homF:=GroupHomomorphismByFunction(G,F,x->Image(BG1homF,Image(GhomBG,x))); BG2homF:=GroupHomomorphismByImagesNC(BH,F,gensH,gensF2); G2homF:=GroupHomomorphismByFunction(H,F,x->Image(BG2homF,Image(HhomBH,x))); AG1homF:=GroupHomomorphismByFunction(AG,F,g->Image(G1homF,Image(AGhomG,g))); AG2homF:=GroupHomomorphismByFunction(AH,F,g->Image(G2homF,Image(AHhomH,g))); if IsSolvable(AG) then # NiceGensAG:=Pcgs(AG); #Need to check the maths here! else # NiceGensAG:=List(UpperCentralSeries(AG),x->GeneratorsOfGroup(x)); NiceGensAG[1]:=[Identity(AG)]; NiceGensAG:=Flat(NiceGensAG); Trans:=RightTransversal(AG,Group(NiceGensAG)); Append(NiceGensAG,Elements(Trans)); fi; # # NiceGensAG:=Elements(AG); #OVERKILL!!! if IsSolvable(AH) then # NiceGensAH:=Pcgs(AH); # Need to check the maths here. If wrong, just delete else # the eight lines ending in #. NiceGensAH:= List(UpperCentralSeries(AG),x->GeneratorsOfGroup(x)); NiceGensAH[1]:=[Identity(AH)]; NiceGensAH:=Flat(NiceGensAH); NiceGensAH:=Filtered(NiceGensAH,x-> (x in AH)); Trans:=RightTransversal(AH,Group(NiceGensAH)); Append(NiceGensAH,Elements(Trans)); fi; # # NiceGensAH:=Elements(AH); #OVERKILL!!! relsT:=[]; for x in relsG do Append(relsT,[Image(BG1homF,x)]); od; for x in relsH do Append(relsT,[Image(BG2homF,x)]); od; for z in NiceGensAG do for x in gensAG do for y in gensAH do v:=Comm(Image(AG1homF,x),Image(AG2homF,y))^Image(AG1homF,z) ; w:=Comm(Image(AG2homF,y^z),Image(AG1homF,x^z) ); Append(relsT,[v*w]); od; od; od; for z in NiceGensAH do for x in gensAG do for y in gensAH do w:=Comm(Image(AG2homF,y^z),Image(AG1homF,x^z) ); v:=Comm(Image(AG1homF,x),Image(AG2homF,y))^Image(AG2homF,z); Append(relsT,[v*w]); od; od; od; relsT:=SSortedList(relsT); #####################################################################IF if not IsSolvable(AG) then AF:=F/relsT; FhomAF:= GroupHomomorphismByImagesNC(F,AF,GeneratorsOfGroup(F),GeneratorsOfGroup(AF)); AFhomSF:=IsomorphismSimplifiedFpGroup(AF); SF:=Image(AFhomSF); FhomSF:= GroupHomomorphismByFunction(F,SF,x->Image(AFhomSF,Image(FhomAF,x)) ); else AF:=F/relsT; FhomAF:= GroupHomomorphismByImagesNC(F,AF,GeneratorsOfGroup(F),GeneratorsOfGroup(AF)); if IsNilpotent(AG) then AFhomSF:=EpimorphismNilpotentQuotient(AF); else AFhomSF:=EpimorphismSolvableQuotient(AF, SSortedList(Factors(Order(G)))); fi; SF:=Image(AFhomSF); FhomSF:= GroupHomomorphismByFunction(F,SF,x->Image(AFhomSF,Image(FhomAF,x)) ); fi; #####################################################################FI AG1homSF:=GroupHomomorphismByFunction(AG,SF,x->Image(FhomSF,Image(AG1homF,x))); AG2homSF:=GroupHomomorphismByFunction(AH,SF,x->Image(FhomSF,Image(AG2homF,x))); TensorProduct:=Intersection( NormalClosure(SF,Group(List(GeneratorsOfGroup(AG),x->Image(AG1homSF,x)))), NormalClosure(SF,Group(List(GeneratorsOfGroup(AH),x->Image(AG2homSF,x)))) ); gensSF:=List(gensF,x->Image(FhomSF,x)); gensSFG:=[]; for i in [1..Length(gensAG)] do Append(gensSFG,[gensAG[i]]); od; for i in [1..Length(gensAH)] do Append(gensSFG,[gensAH[i]]); od; SFhomAG:=GroupHomomorphismByImagesNC(SF,AG,gensSF,gensSFG); delta:=GroupHomomorphismByFunction(TensorProduct,AG,x->Image(SFhomAG,x)); ##################################################################### CrossedPairing:=function(x,y) return Comm(Image(AG1homSF,x), Image(AG2homSF,y)); end; ##################################################################### return rec(homomorphism:=delta, pairing:=CrossedPairing); end); #####################################################################