40 Group Homomorphisms A group homomorphism is a mapping from one group to another that respects multiplication and inverses. They are implemented as a special class of mappings, so in particular all operations for mappings, such as Image (32.4-6), PreImage (32.5-6), PreImagesRepresentative (32.5-4), KernelOfMultiplicativeGeneralMapping (32.9-5), Source (32.3-8), Range (32.3-7), IsInjective (32.3-4) and IsSurjective (32.3-5) (see chapter 32, in particular section 32.9) are applicable to them. Homomorphisms can be used to transfer calculations into isomorphic groups in another representation, for which better algorithms are available. Section 40.5 explains a technique how to enforce this automatically. Homomorphisms are also used to represent group automorphisms, and section 40.6 explains GAP's facilities to work with automorphism groups. Section 40.9 explains how to make GAP to search for all homomorphisms between two groups which fulfill certain specifications. 40.1 Creating Group Homomorphisms The most important way of creating group homomorphisms is to give images for a set of group generators and to extend it to the group generated by them by the homomorphism property. A second way to create homomorphisms is to give functions that compute image and preimage. (A similar case are homomorphisms that are induced by conjugation. Special constructors for such mappings are described in section 40.6). The third class are epimorphisms from a group onto its factor group. Such homomorphisms can be constructed by NaturalHomomorphismByNormalSubgroup (39.18-1). The fourth class is homomorphisms in a permutation group that are induced by an action on a set. Such homomorphisms are described in the context of group actions, see chapter 41 and in particular ActionHomomorphism (41.7-1). 40.1-1 GroupHomomorphismByImages GroupHomomorphismByImages( G, H[[, gens], imgs] )  function GroupHomomorphismByImages returns the group homomorphism with source G and range H that is defined by mapping the list gens of generators of G to the list imgs of images in H. If omitted, the arguments gens and imgs default to the GeneratorsOfGroup (39.2-4) value of G and H, respectively. If H is not given the mapping is automatically considered as surjective. If gens does not generate G or if the mapping of the generators does not extend to a homomorphism (i.e., if mapping the generators describes only a multi-valued mapping) then fail is returned. This test can be quite expensive. If one is certain that the mapping of the generators extends to a homomorphism, one can avoid the checks by calling GroupHomomorphismByImagesNC (40.1-2). (There also is the possibility to construct potentially multi-valued mappings with GroupGeneralMappingByImages (40.1-3) and to test with IsMapping (32.3-3) whether they are indeed homomorphisms.) 40.1-2 GroupHomomorphismByImagesNC GroupHomomorphismByImagesNC( G, H[[, gens], imgs] )  operation GroupHomomorphismByImagesNC creates a homomorphism as GroupHomomorphismByImages (40.1-1) does, however it does not test whether gens generates G and that the mapping of gens to imgs indeed defines a group homomorphism. Because these tests can be expensive it can be substantially faster than GroupHomomorphismByImages (40.1-1). Results are unpredictable if the conditions do not hold. If omitted, the arguments gens and imgs default to the GeneratorsOfGroup (39.2-4) value of G and H, respectively. (For creating a possibly multi-valued mapping from G to H that respects multiplication and inverses, GroupGeneralMappingByImages (40.1-3) can be used.)  Example  gap> gens:=[(1,2,3,4),(1,2)]; [ (1,2,3,4), (1,2) ] gap> g:=Group(gens); Group([ (1,2,3,4), (1,2) ]) gap> h:=Group((1,2,3),(1,2)); Group([ (1,2,3), (1,2) ]) gap> hom:=GroupHomomorphismByImages(g,h,gens,[(1,2),(1,3)]); [ (1,2,3,4), (1,2) ] -> [ (1,2), (1,3) ] gap> Image(hom,(1,4)); (2,3) gap> map:=GroupHomomorphismByImages(g,h,gens,[(1,2,3),(1,2)]); fail  40.1-3 GroupGeneralMappingByImages GroupGeneralMappingByImages( G, H, gens, imgs )  operation GroupGeneralMappingByImages( G, gens, imgs )  operation GroupGeneralMappingByImagesNC( G, H, gens, imgs )  operation GroupGeneralMappingByImagesNC( G, gens, imgs )  operation returns a general mapping defined by extending the mapping from gens to imgs homomorphically. If the range H is not given the mapping will be made automatically surjective. The NC version does not test whether gens are contained in G or imgs are contained in H. (GroupHomomorphismByImages (40.1-1) creates a group general mapping by images and tests whether it is in IsMapping (32.3-3).)  Example  gap> map:=GroupGeneralMappingByImages(g,h,gens,[(1,2,3),(1,2)]); [ (1,2,3,4), (1,2) ] -> [ (1,2,3), (1,2) ] gap> IsMapping(map); false  40.1-4 GroupHomomorphismByFunction GroupHomomorphismByFunction( S, R, fun[, invfun] )  function GroupHomomorphismByFunction( S, R, fun, false, prefun )  function GroupHomomorphismByFunction returns a group homomorphism hom with source S and range R, such that each element s of S is mapped to the element fun( s ), where fun is a GAP function. If the argument invfun is bound then hom is a bijection between S and R, and the preimage of each element r of R is given by invfun( r ), where invfun is a GAP function. If five arguments are given and the fourth argument is false then the GAP function prefun can be used to compute a single preimage also if hom is not bijective. No test is performed on whether the functions actually give an homomorphism between both groups because this would require testing the full multiplication table. GroupHomomorphismByFunction creates a mapping which lies in IsSPGeneralMapping (32.14-1).  Example  gap> hom:=GroupHomomorphismByFunction(g,h, > function(x) if SignPerm(x)=-1 then return (1,2); else return ();fi;end); MappingByFunction( Group([ (1,2,3,4), (1,2) ]), Group( [ (1,2,3), (1,2) ]), function( x ) ... end ) gap> ImagesSource(hom); Group([ (1,2), (1,2) ]) gap> Image(hom,(1,2,3,4)); (1,2)  40.1-5 AsGroupGeneralMappingByImages AsGroupGeneralMappingByImages( map )  attribute If map is a mapping from one group to another this attribute returns a group general mapping that which implements the same abstract mapping. (Some operations can be performed more effective in this representation, see also IsGroupGeneralMappingByAsGroupGeneralMappingByImages (40.10-3).)  Example  gap> AsGroupGeneralMappingByImages(hom); [ (1,2,3,4), (1,2) ] -> [ (1,2), (1,2) ]  40.2 Operations for Group Homomorphisms Group homomorphisms are mappings, so all the operations and properties for mappings described in chapter 32 are applicable to them. (However often much better methods, than for general mappings are available.) Group homomorphisms will map groups to groups by just mapping the set of generators. KernelOfMultiplicativeGeneralMapping (32.9-5) can be used to compute the kernel of a group homomorphism.  Example  gap> hom:=GroupHomomorphismByImages(g,h,gens,[(1,2),(1,3)]);; gap> Kernel(hom); Group([ (1,4)(2,3), (1,2)(3,4) ])  Homomorphisms can map between groups in different representations and are also used to get isomorphic groups in a different representation.  Example  gap> m1:=[[0,-1],[1,0]];;m2:=[[0,-1],[1,1]];; gap> sl2z:=Group(m1,m2);; # SL(2,Integers) as matrix group gap> F:=FreeGroup(2);; gap> psl2z:=F/[F.1^2,F.2^3]; #PSL(2,Z) as FP group  gap> phom:=GroupHomomorphismByImagesNC(sl2z,psl2z,[m1,m2], > GeneratorsOfGroup(psl2z)); # the non NC-version would be expensive [ [ [ 0, -1 ], [ 1, 0 ] ], [ [ 0, -1 ], [ 1, 1 ] ] ] -> [ f1, f2 ] gap> Kernel(phom); # the diagonal matrices Group([ [ [ -1, 0 ], [ 0, -1 ] ], [ [ -1, 0 ], [ 0, -1 ] ] ]) gap> p1:=(1,2)(3,4);;p2:=(2,4,5);;a5:=Group(p1,p2);; gap> ahom:=GroupHomomorphismByImages(psl2z,a5, > GeneratorsOfGroup(psl2z),[p1,p2]); # here homomorphism test is cheap. [ f1, f2 ] -> [ (1,2)(3,4), (2,4,5) ] gap> u:=PreImage(ahom,Group((1,2,3),(1,2)(4,5))); Group() gap> Index(psl2z,u); 10 gap> isofp:=IsomorphismFpGroup(u);; Image(isofp);  gap> RelatorsOfFpGroup(Image(isofp)); [ F1^2, F4^2, F3^3 ] gap> up:=PreImage(phom,u);; gap> List(GeneratorsOfGroup(up),TraceMat); [ -2, -2, 0, -4, 1, 0 ]  For an automorphism aut, Inverse (31.10-8) returns the inverse automorphism aut^{-1}. However if hom is a bijective homomorphism between different groups, or if hom is injective and considered to be a bijection to its image, the operation InverseGeneralMapping (32.2-3) should be used instead. (See Inverse (31.10-8) for a further discussion of this problem.)  Example  gap> iso:=IsomorphismPcGroup(g); Pcgs([ (3,4), (2,4,3), (1,4)(2,3), (1,3)(2,4) ]) -> [ f1, f2, f3, f4 ] gap> Inverse(iso); #I The mapping must be bijective and have source=range #I You might want to use `InverseGeneralMapping' fail gap> InverseGeneralMapping(iso); [ f1, f2, f3, f4 ] -> Pcgs([ (3,4), (2,4,3), (1,4)(2,3), (1,3)(2,4) ])  40.3 Efficiency of Homomorphisms GAP permits to create homomorphisms between arbitrary groups. This section considers the efficiency of the implementation and shows ways how to choose suitable representations. For permutation groups (see 43) or Pc groups (see 46) this is normally nothing to worry about, unless the groups get extremely large. For other groups however certain calculations might be expensive and some precaution might be needed to avoid unnecessarily expensive calculations. In short, it is always worth to tell a mapping that it is a homomorphism (this can be done by calling SetIsMapping) (or to create it directly with GroupHomomorphismByImagesNC (40.1-2)). The basic operations required are to compute image and preimage of elements and to test whether a mapping is a homomorphism. Their cost will differ depending on the type of the mapping. 40.3-1 Mappings given on generators See GroupHomomorphismByImages (40.1-1) and GroupGeneralMappingByImages (40.1-3). Computing images requires to express an element of the source as word in the generators. If it cannot be done effectively (this is determined by KnowsHowToDecompose (39.26-7) which returns true for example for arbitrary permutation groups, for Pc groups or for finitely presented groups with the images of the free generators) the span of the generators has to be computed elementwise which can be very expensive and memory consuming. Computing preimages adheres to the same rules with swapped rôles of generators and their images. The test whether a mapping is a homomorphism requires the computation of a presentation for the source and evaluation of its relators in the images of its generators. For larger groups this can be expensive and GroupHomomorphismByImagesNC (40.1-2) should be used if the mapping is known to be a homomorphism. 40.3-2 Action homomorphisms See ActionHomomorphism (41.7-1). The calculation of images is determined by the acting function used and –for large domains– is often dominated by the search for the position of an image in a list of the domain elements. This can be improved by sorting this list if an efficient method for \< (31.11-1) to compare elements of the domain is available. Once the images of a generating set are computed, computing preimages (which is done via AsGroupGeneralMappingByImages (40.1-5)) and computing the kernel behaves the same as for a homomorphism created with GroupHomomorphismByImages (40.1-1) from a permutation group. GAP will always assume that the acting function provided implements a proper group action and thus that the mapping is indeed a homomorphism. 40.3-3 Mappings given by functions See GroupHomomorphismByFunction (40.1-4). Computing images is wholly determined by the function that performs the image calculation. If no function to compute preimages is given, computing preimages requires mapping every element of the source to find an element that maps to the requested image. This is time and memory consuming. 40.3-4 Other operations To compute the kernel of a homomorphism (unless the mapping is known to be injective) requires the capability to compute a presentation of the image and to evaluate the relators of this presentation in preimages of the presentations generators. The calculation of the Image (32.4-6) (respectively ImagesSource (32.4-1)) value requires to map a generating set of the source, testing surjectivity is a comparison for equality with the range. Testing injectivity is a test for triviality of the kernel. The comparison of mappings is based on a lexicographic comparison of a sorted element list of the source. For group homomorphisms, this can be simplified, using ImagesSmallestGenerators (40.3-5) 40.3-5 ImagesSmallestGenerators ImagesSmallestGenerators( map )  attribute returns the list of images of GeneratorsSmallest(Source(map)). This list can be used to compare group homomorphisms. (The standard comparison is to compare the image lists on the set of elements of the source. If however x and y have the same images under a and b, certainly all their products have. Therefore it is sufficient to test this on the images of the smallest generators.) 40.4 Homomorphism for very large groups Some homomorphisms (notably particular actions) transfer known information about the source group (such as a stabilizer chain) to the image group if this is substantially cheaper than to compute the information in the image group anew. In most cases this is no problem and in fact speeds up further calculations notably. For a huge source group, however this can be time consuming or take a large amount of extra memory for storage. In this case it can be helpful to avoid as much automatism as possible. The following list of tricks might be useful in such a case. (However you will lose much automatic deduction. So please restrict the use of these to cases where the standard approach does not work.)  Compute only images (or the PreImagesRepresentative (32.5-4)) of group elements. Do not compute the images of (sub)groups or the full preimage of a subgroup.  Create action homomorphisms as surjective (see ActionHomomorphism (41.7-1)), otherwise the range is set to be the full symmetric group. However do not compute Range (32.3-7) or Image (32.4-6) values, but only the images of a generator set.  If you suspect an action homomorphism to do too much internally, replace the action function with a function that does the same; i.e. replace OnPoints (41.2-1) by function( p, g ) return p^g; end;. The action will be the same, but as the action function is not OnPoints (41.2-1), the extra processing for special cases is not triggered. 40.5 Nice Monomorphisms GAP contains very efficient algorithms for some special representations of groups (for example pc groups or permutation groups) while for other representations only slow generic methods are available. In this case it can be worthwhile to do all calculations rather in an isomorphic image of the group, which is in a better representation. The way to achieve this in GAP is via nice monomorphisms. For this mechanism to work, of course there must be effective methods to evaluate the NiceMonomorphism (40.5-2) value on elements and to take preimages under it. As by definition no good algorithms exist for the source group, normally this can only be achieved by using the result of a call to ActionHomomorphism (41.7-1) or GroupHomomorphismByFunction (40.1-4) (see also section 40.3). 40.5-1 IsHandledByNiceMonomorphism IsHandledByNiceMonomorphism( obj )  property If this property is true, high-valued methods that translate all calculations in obj in the image under the NiceMonomorphism (40.5-2) value of obj become available for obj. 40.5-2 NiceMonomorphism NiceMonomorphism( obj )  attribute is a homomorphism that is defined (at least) on the whole of obj and whose restriction to obj is injective. The concrete morphism (and also the image group) will depend on the representation of obj. WARNING: The domain of the homomorphism may be larger than obj. To obtain the image of obj under the homomorphism, use NiceObject (40.5-3); see there for an example where it matters. 40.5-3 NiceObject NiceObject( obj )  attribute The NiceObject value of obj is the image of obj under the mapping stored as the value of NiceMonomorphism (40.5-2) for obj. A typical example are finite matrix groups, which use a faithful action on vectors to translate all calculations in a permutation group.  Example  gap> gl:=GL(3,2); SL(3,2) gap> IsHandledByNiceMonomorphism(gl); true gap> NiceObject(gl); Group([ (5,7)(6,8), (2,3,5)(4,7,6) ]) gap> Image(NiceMonomorphism(gl),Z(2)*[[1,0,0],[0,1,1],[1,0,1]]); (2,6)(3,4,7,8)  40.5-4 IsCanonicalNiceMonomorphism IsCanonicalNiceMonomorphism( nhom )  property A nice monomorphism (see NiceMonomorphism (40.5-2) nhom is canonical if the image set will only depend on the set of group elements but not on the generating set and \< (31.11-1) comparison of group elements translates through the nice monomorphism. This implies that equal objects will always have equal NiceObject (40.5-3) values. In some situations however this condition would be expensive to achieve, therefore it is not guaranteed for every nice monomorphism. 40.6 Group Automorphisms Group automorphisms are bijective homomorphism from a group onto itself. An important subclass are automorphisms which are induced by conjugation of the group itself or a supergroup. 40.6-1 ConjugatorIsomorphism ConjugatorIsomorphism( G, g )  operation Let G be a group, and g an element in the same family as the elements of G. ConjugatorIsomorphism returns the isomorphism from G to G^g defined by h ↦ h^g for all h ∈ G. If g normalizes G then ConjugatorIsomorphism does the same as ConjugatorAutomorphismNC (40.6-2). 40.6-2 ConjugatorAutomorphism ConjugatorAutomorphism( G, g )  function ConjugatorAutomorphismNC( G, g )  operation Let G be a group, and g an element in the same family as the elements of G such that g normalizes G. ConjugatorAutomorphism returns the automorphism of G defined by h ↦ h^g for all h ∈ G. If conjugation by g does not leave G invariant, ConjugatorAutomorphism returns fail; in this case, the isomorphism from G to G^g induced by conjugation with g can be constructed with ConjugatorIsomorphism (40.6-1). ConjugatorAutomorphismNC does the same as ConjugatorAutomorphism, except that the check is omitted whether g normalizes G and it is assumed that g is chosen to be in G if possible. 40.6-3 InnerAutomorphism InnerAutomorphism( G, g )  function InnerAutomorphismNC( G, g )  operation Let G be a group, and g ∈ G. InnerAutomorphism returns the automorphism of G defined by h ↦ h^g for all h ∈ G. If g is not an element of G, InnerAutomorphism returns fail; in this case, the isomorphism from G to G^g induced by conjugation with g can be constructed with ConjugatorIsomorphism (40.6-1) or with ConjugatorAutomorphism (40.6-2). InnerAutomorphismNC does the same as InnerAutomorphism, except that the check is omitted whether g ∈ G. 40.6-4 IsConjugatorIsomorphism IsConjugatorIsomorphism( hom )  property IsConjugatorAutomorphism( hom )  property IsInnerAutomorphism( hom )  property Let hom be a group general mapping (see IsGroupGeneralMapping (32.9-4)) with source G. IsConjugatorIsomorphism returns true if hom is induced by conjugation of G by an element g that lies in G or in a group into which G is naturally embedded in the sense described below, and false otherwise. Natural embeddings are dealt with in the case that G is a permutation group (see Chapter 43), a matrix group (see Chapter 44), a finitely presented group (see Chapter 47), or a group given w.r.t. a polycyclic presentation (see Chapter 46). In all other cases, IsConjugatorIsomorphism may return false if hom is induced by conjugation but is not an inner automorphism. If IsConjugatorIsomorphism returns true for hom then an element g that induces hom can be accessed as value of the attribute ConjugatorOfConjugatorIsomorphism (40.6-5). IsConjugatorAutomorphism returns true if hom is an automorphism (see IsEndoGeneralMapping (32.13-3)) that is regarded as a conjugator isomorphism by IsConjugatorIsomorphism, and false otherwise. IsInnerAutomorphism returns true if hom is a conjugator automorphism such that an element g inducing hom can be chosen in G, and false otherwise. 40.6-5 ConjugatorOfConjugatorIsomorphism ConjugatorOfConjugatorIsomorphism( hom )  attribute For a conjugator isomorphism hom (see ConjugatorIsomorphism (40.6-1)), ConjugatorOfConjugatorIsomorphism returns an element g such that mapping under hom is induced by conjugation with g. To avoid problems with IsInnerAutomorphism (40.6-4), it is guaranteed that the conjugator is taken from the source of hom if possible.  Example  gap> hgens:=[(1,2,3),(1,2,4)];;h:=Group(hgens);; gap> hom:=GroupHomomorphismByImages(h,h,hgens,[(1,2,3),(2,3,4)]);; gap> IsInnerAutomorphism(hom); true gap> ConjugatorOfConjugatorIsomorphism(hom); (1,2,3) gap> hom:=GroupHomomorphismByImages(h,h,hgens,[(1,3,2),(1,4,2)]); [ (1,2,3), (1,2,4) ] -> [ (1,3,2), (1,4,2) ] gap> IsInnerAutomorphism(hom); false gap> IsConjugatorAutomorphism(hom); true gap> ConjugatorOfConjugatorIsomorphism(hom); (1,2)  40.7 Groups of Automorphisms Group automorphism can be multiplied and inverted and thus it is possible to form groups of automorphisms. 40.7-1 AutomorphismGroup AutomorphismGroup( G )  attribute returns the full automorphism group of the group G. The automorphisms act on G by the caret operator ^. The automorphism group often stores a NiceMonomorphism (40.5-2) value whose image is a permutation group, obtained by the action on a subset of G. Note that current methods for the calculation of the automorphism group of a group G require G to be a permutation group or a pc group to be efficient. For groups in other representations the calculation is likely very slow. Also, the AutPGrp package installs enhanced methods for AutomorphismGroup for finite p-groups, and the FGA package - for finitely generated subgroups of free groups. Methods may be installed for AutomorphismGroup for other domains, such as e.g. for linear codes in the GUAVA package, loops in the loops package and nilpotent Lie algebras in the Sophus package (see package manuals for their descriptions). 40.7-2 IsGroupOfAutomorphisms IsGroupOfAutomorphisms( G )  property indicates whether G consists of automorphisms of another group H. The group H can be obtained from G via the attribute AutomorphismDomain (40.7-3). 40.7-3 AutomorphismDomain AutomorphismDomain( G )  attribute If G consists of automorphisms of H, this attribute returns H. 40.7-4 IsAutomorphismGroup IsAutomorphismGroup( G )  property indicates whether G, which must be IsGroupOfAutomorphisms (40.7-2), is the full automorphism group of another group H, this group is given as AutomorphismDomain (40.7-3) value of G.  Example  gap> g:=Group((1,2,3,4),(1,3)); Group([ (1,2,3,4), (1,3) ]) gap> au:=AutomorphismGroup(g);  gap> GeneratorsOfGroup(au); [ Pcgs([ (2,4), (1,2,3,4), (1,3)(2,4) ]) ->   [ (1,2)(3,4), (1,2,3,4), (1,3)(2,4) ],   Pcgs([ (2,4), (1,2,3,4), (1,3)(2,4) ]) ->   [ (1,3), (1,2,3,4), (1,3)(2,4) ],   Pcgs([ (2,4), (1,2,3,4), (1,3)(2,4) ]) ->   [ (2,4), (1,4,3,2), (1,3)(2,4) ] ] gap> NiceObject(au); Group([ (1,2,4,6), (1,4)(2,6), (2,6)(3,5) ])  40.7-5 InnerAutomorphismsAutomorphismGroup InnerAutomorphismsAutomorphismGroup( autgroup )  attribute For an automorphism group autgroup of a group this attribute stores the subgroup of inner automorphisms (automorphisms induced by conjugation) of the original group.  Example  gap> InnerAutomorphismsAutomorphismGroup(au);   40.7-6 InnerAutomorphismGroup InnerAutomorphismGroup( G )  attribute For a group G this attribute stores the group of inner automorphisms (automorphisms induced by conjugation) of the original group.  Example  gap> InnerAutomorphismGroup(SymmetricGroup(5));   40.7-7 InducedAutomorphism InducedAutomorphism( epi, aut )  function Let aut be an automorphism of a group G and epi be a homomorphism from G to a group H such that the kernel of epi is fixed under aut. Let U be the image of epi. This command returns the automorphism of U induced by aut via epi, that is, the automorphism of U which maps g^epi to (g^aut)^epi, for g ∈ G.  Example  gap> g:=Group((1,2,3,4),(1,2)); Group([ (1,2,3,4), (1,2) ]) gap> n:=Subgroup(g,[(1,2)(3,4),(1,3)(2,4)]); Group([ (1,2)(3,4), (1,3)(2,4) ]) gap> epi:=NaturalHomomorphismByNormalSubgroup(g,n); [ (1,2,3,4), (1,2) ] -> [ f1*f2, f1 ] gap> aut:=InnerAutomorphism(g,(1,2,3)); ^(1,2,3) gap> InducedAutomorphism(epi,aut); ^f2  40.8 Calculating with Group Automorphisms Usually the best way to calculate in a group of automorphisms is to translate all calculations to an isomorphic group in a representation for which better algorithms are available, such as a permutation group. This translation can be done automatically using NiceMonomorphism (40.5-2). Once a group knows to be a group of automorphisms (this can be achieved by testing or setting the property IsGroupOfAutomorphisms (40.7-2)), GAP will try itself to find such a nice monomorphism once calculations in the automorphism group are done. Note that nice homomorphisms inherit down to subgroups, but cannot necessarily be extended from a subgroup to the whole group. Thus when working with a group of automorphisms, it can be beneficial to enforce calculation of the nice monomorphism for the whole group (for example by explicitly calling Random (30.7-1) and ignoring the result –it will be stored internally) at the start of the calculation. Otherwise GAP might first calculate a nice monomorphism for the subgroup, only to be forced to calculate a new nice monomorphism for the whole group later on. If a good domain for a faithful permutation action is known already, a homomorphism for the action on it can be created using NiceMonomorphismAutomGroup (40.8-2). It might be stored by SetNiceMonomorphism (see NiceMonomorphism (40.5-2)). Another nice way of representing automorphisms as permutations has been described in [Sim97]. It is not yet available in GAP, a description however can be found in section  87.3. 40.8-1 AssignNiceMonomorphismAutomorphismGroup AssignNiceMonomorphismAutomorphismGroup( autgrp, group )  function computes a nice monomorphism for autgroup acting on group and stores it as NiceMonomorphism (40.5-2) value of autgrp. If the centre of AutomorphismDomain (40.7-3) of autgrp is trivial, the operation will first try to represent all automorphisms by conjugation (in group or in a natural parent of group). If this fails the operation tries to find a small subset of group on which the action will be faithful. The operation sets the attribute NiceMonomorphism (40.5-2) and does not return a value. 40.8-2 NiceMonomorphismAutomGroup NiceMonomorphismAutomGroup( autgrp, elms, elmsgens )  function This function creates a monomorphism for an automorphism group autgrp of a group by permuting the group elements in the list elms. This list must be chosen to yield a faithful representation. elmsgens is a list of generators which are a subset of elms. (They can differ from the group's original generators.) It does not yet assign it as NiceMonomorphism (40.5-2) value. 40.9 Searching for Homomorphisms 40.9-1 IsomorphismGroups IsomorphismGroups( G, H )  function computes an isomorphism between the groups G and H if they are isomorphic and returns fail otherwise. With the existing methods the amount of time needed grows with the size of a generating system of G. (Thus in particular for p-groups calculations can be slow.) If you do only need to know whether groups are isomorphic, you might want to consider IdGroup (smallgrp: IdGroup) or the random isomorphism test (see RandomIsomorphismTest (46.10-1)).  Example  gap> g:=Group((1,2,3,4),(1,3));; gap> h:=Group((1,4,6,7)(2,3,5,8), (1,5)(2,6)(3,4)(7,8));; gap> IsomorphismGroups(g,h); [ (1,2,3,4), (1,3) ] -> [ (1,4,6,7)(2,3,5,8), (1,2)(3,7)(4,8)(5,6) ] gap> IsomorphismGroups(g,Group((1,2,3,4),(1,2))); fail  40.9-2 AllHomomorphismClasses AllHomomorphismClasses( G, H )  function For two finite groups G and H, this function returns representatives of all homomorphisms G to H up to H-conjugacy.  Example  gap> AllHomomorphismClasses(SymmetricGroup(4),SymmetricGroup(3));  [ [ (2,4,3), (1,4,2,3) ] -> [ (), () ],  [ (2,4,3), (1,4,2,3) ] -> [ (), (1,2) ],  [ (2,4,3), (1,4,2,3) ] -> [ (1,2,3), (1,2) ] ]  40.9-3 AllHomomorphisms AllHomomorphisms( G, H )  function AllEndomorphisms( G )  function AllAutomorphisms( G )  function For two finite groups G and H, this function returns all homomorphisms G to H. Since this number will grow quickly, AllHomomorphismClasses (40.9-2) should be used in most cases. AllEndomorphisms returns all homomorphisms from G to itself, AllAutomorphisms returns all bijective endomorphisms.  Example  gap> AllHomomorphisms(SymmetricGroup(3),SymmetricGroup(3)); [ [ (2,3), (1,2,3) ] -> [ (), () ],  [ (2,3), (1,2,3) ] -> [ (1,2), () ],  [ (2,3), (1,2,3) ] -> [ (2,3), () ],  [ (2,3), (1,2,3) ] -> [ (1,3), () ],  [ (2,3), (1,2,3) ] -> [ (2,3), (1,2,3) ],  [ (2,3), (1,2,3) ] -> [ (1,3), (1,2,3) ],  [ (2,3), (1,2,3) ] -> [ (1,3), (1,3,2) ],  [ (2,3), (1,2,3) ] -> [ (1,2), (1,2,3) ],  [ (2,3), (1,2,3) ] -> [ (2,3), (1,3,2) ],  [ (2,3), (1,2,3) ] -> [ (1,2), (1,3,2) ] ]  40.9-4 GQuotients GQuotients( F, G )  operation computes all epimorphisms from F onto G up to automorphisms of G. This classifies all factor groups of F which are isomorphic to G. With the existing methods the amount of time needed grows with the size of a generating system of G. (Thus in particular for p-groups calculations can be slow.) If the findall option is set to false, the algorithm will stop once one homomorphism has been found (this can be faster and might be sufficient if not all homomorphisms are needed).  Example  gap> g:=Group((1,2,3,4),(1,2)); Group([ (1,2,3,4), (1,2) ]) gap> h:=Group((1,2,3),(1,2)); Group([ (1,2,3), (1,2) ]) gap> quo:=GQuotients(g,h); [ [ (1,2,3,4), (1,4,3) ] -> [ (2,3), (1,2,3) ] ]  40.9-5 IsomorphicSubgroups IsomorphicSubgroups( G, H )  operation computes all monomorphisms from H into G up to G-conjugacy of the image groups. This classifies all G-classes of subgroups of G which are isomorphic to H. With the existing methods, the amount of time needed grows with the size of a generating system of G. (Thus in particular for p-groups calculations can be slow.) A main use of IsomorphicSubgroups therefore is to find nonsolvable subgroups (which often can be generated by 2 elements). (To find p-subgroups it is often faster to compute the subgroup lattice of the Sylow subgroup and to use IdGroup (smallgrp: IdGroup) to identify the type of the subgroups.) If the findall option is set to false, the algorithm will stop once one homomorphism has been found (this can be faster and might be sufficient if not all homomorphisms are needed).  Example  gap> g:=Group((1,2,3,4),(1,2)); Group([ (1,2,3,4), (1,2) ]) gap> h:=Group((3,4),(1,2));; gap> emb:=IsomorphicSubgroups(g,h); [ [ (3,4), (1,2) ] -> [ (1,2), (3,4) ],   [ (3,4), (1,2) ] -> [ (1,3)(2,4), (1,2)(3,4) ] ]  40.9-6 MorClassLoop MorClassLoop( range, classes, params, action )  function This function loops over element tuples taken from classes and checks these for properties such as generating a given group, or fulfilling relations. This can be used to find small generating sets or all types of Morphisms. The element tuples are used only up to inner automorphisms as all images can be obtained easily from them by conjugation while running through all of them usually would take too long. range is a group from which these elements are taken. The classes are given in a list classes which is a list of records with the following components. classes list of conjugacy classes representative One element in the union of these classes size The sum of the sizes of these classes params is a record containing the following optional components. gens generators that are to be mapped (for testing morphisms). The length of this list determines the length of element tuples considered. from a preimage group (that contains gens) to image group (which might be smaller than range) free free generators, a list of the same length than the generators gens. rels some relations that hold among the generators gens. They are given as a list [ word, order ] where word is a word in the free generators free. dom a set of elements on which automorphisms act faithfully (used to do element tests in partial automorphism groups). aut Subgroup of already known automorphisms. condition A function that will be applied to the homomorphism and must return true for the homomorphism to be accepted. action is a number whose bit-representation indicates the requirements which are enforced on the element tuples found, as follows. 1 homomorphism 2 injective 4 surjective 8 find all (otherwise stops after the first find) If the search is for homomorphisms, the function returns homomorphisms obtained by mapping the given generators gens instead of element tuples. The Morpheus algorithm used to find homomorphisms is described in [Hul96, Section V.5]. 40.10 Representations for Group Homomorphisms The different representations of group homomorphisms are used to indicate from what type of group to what type of group they map and thus determine which methods are used to compute images and preimages. The information in this section is mainly relevant for implementing new methods and not for using homomorphisms. 40.10-1 IsGroupGeneralMappingByImages IsGroupGeneralMappingByImages( map )  Representation Representation for mappings from one group to another that are defined by extending a mapping of group generators homomorphically. Instead of record components, the attribute MappingGeneratorsImages (40.10-2) is used to store generators and their images. 40.10-2 MappingGeneratorsImages MappingGeneratorsImages( map )  attribute This attribute contains a list of length 2, the first entry being a list of generators of the source of map and the second entry a list of their images. This attribute is used, for example, by GroupHomomorphismByImages (40.1-1) to store generators and images. 40.10-3 IsGroupGeneralMappingByAsGroupGeneralMappingByImages IsGroupGeneralMappingByAsGroupGeneralMappingByImages( map )  Representation Representation for mappings that delegate work on a GroupHomomorphismByImages (40.1-1). 40.10-4 IsPreimagesByAsGroupGeneralMappingByImages IsPreimagesByAsGroupGeneralMappingByImages( map )  Representation Representation for mappings that delegate work for preimages to a mapping created with GroupHomomorphismByImages (40.1-1). 40.10-5 IsPermGroupGeneralMapping IsPermGroupGeneralMapping( map )  Representation IsPermGroupGeneralMappingByImages( map )  Representation IsPermGroupHomomorphism( map )  Representation IsPermGroupHomomorphismByImages( map )  Representation are the representations for mappings that map from a perm group 40.10-6 IsToPermGroupGeneralMappingByImages IsToPermGroupGeneralMappingByImages( map )  Representation IsToPermGroupHomomorphismByImages( map )  Representation is the representation for mappings that map to a perm group 40.10-7 IsGroupGeneralMappingByPcgs IsGroupGeneralMappingByPcgs( map )  Representation is the representations for mappings that map a pcgs to images and thus may use exponents to decompose generators. 40.10-8 IsPcGroupGeneralMappingByImages IsPcGroupGeneralMappingByImages( map )  Representation IsPcGroupHomomorphismByImages( map )  Representation is the representation for mappings from a pc group 40.10-9 IsToPcGroupGeneralMappingByImages IsToPcGroupGeneralMappingByImages( map )  Representation IsToPcGroupHomomorphismByImages( map )  Representation is the representation for mappings to a pc group 40.10-10 IsFromFpGroupGeneralMappingByImages IsFromFpGroupGeneralMappingByImages( map )  Representation IsFromFpGroupHomomorphismByImages( map )  Representation is the representation of mappings from an fp group. 40.10-11 IsFromFpGroupStdGensGeneralMappingByImages IsFromFpGroupStdGensGeneralMappingByImages( map )  Representation IsFromFpGroupStdGensHomomorphismByImages( map )  Representation is the representation of total mappings from an fp group that give images of the standard generators.