There are a large number of examples provided with the ANUPQ package. These may be executed or displayed via the function PqExample
(see PqExample
(3.4-4)). Each example resides in a file of the same name in the directory examples
. Most of the examples are translations to GAP of examples provided for the pq
standalone by Eamonn O'Brien; the standalone examples are found in directories standalone/examples
(\(p\)-quotient and \(p\)-group generation examples) and standalone/isom
(standard presentation examples). The first line of each example indicates its origin. All the examples seen in earlier chapters of this manual are also available as examples, in a slightly modified form (the example which one can run in order to see something very close to the text example live
is always indicated near -- usually immediately after -- the text example). The format of the (PqExample
) examples is such that they can be read by the standard Read
function of GAP, but certain features and comments are interpreted by the function PqExample
to do somewhat more than Read
does. In particular, any function without a -i
, -ni
or .g
suffix has both a non-interactive and interactive form; in these cases, the default form is the non-interactive form, and giving PqStart
as second argument generates the interactive form.
Running PqExample
without an argument or with a non-existent example Info
s the available examples and some hints on usage:
gap> PqExample(); #I PqExample Index (Table of Contents) #I ----------------------------------- #I This table of possible examples is displayed when calling `PqExample' #I with no arguments, or with the argument: "index" (meant in the sense #I of ``list''), or with a non-existent example name. #I #I Examples that have a name ending in `-ni' are non-interactive only. #I Examples that have a name ending in `-i' are interactive only. #I Examples with names ending in `.g' also have only one form. Other #I examples have both a non-interactive and an interactive form; call #I `PqExample' with 2nd argument `PqStart' to get the interactive form #I of the example. The substring `PG' in an example name indicates a #I p-Group Generation example, `SP' indicates a Standard Presentation #I example, `Rel' indicates it uses the `Relators' option, and `Id' #I indicates it uses the `Identities' option. #I #I The following ANUPQ examples are available: #I #I p-Quotient examples: #I general: #I "Pq" "Pq-ni" "PqEpimorphism" #I "PqPCover" "PqSupplementInnerAutomorphisms" #I 2-groups: #I "2gp-Rel" "2gp-Rel-i" "2gp-a-Rel-i" #I "B2-4" "B2-4-Id" "B2-8-i" #I "B4-4-i" "B4-4-a-i" "B5-4.g" #I 3-groups: #I "3gp-Rel-i" "3gp-a-Rel" "3gp-a-Rel-i" #I "3gp-a-x-Rel-i" "3gp-maxoccur-Rel-i" #I 5-groups: #I "5gp-Rel-i" "5gp-a-Rel-i" "5gp-b-Rel-i" #I "5gp-c-Rel-i" "5gp-metabelian-Rel-i" "5gp-maxoccur-Rel-i" #I "F2-5-i" "B2-5-i" "R2-5-i" #I "R2-5-x-i" "B5-5-Engel3-Id" #I 7-groups: #I "7gp-Rel-i" #I 11-groups: #I "11gp-i" "11gp-Rel-i" "11gp-a-Rel-i" #I "11gp-3-Engel-Id" "11gp-3-Engel-Id-i" #I #I p-Group Generation examples: #I general: #I "PqDescendants-1" "PqDescendants-2" "PqDescendants-3" #I "PqDescendants-1-i" #I 2-groups: #I "2gp-PG-i" "2gp-PG-2-i" "2gp-PG-3-i" #I "2gp-PG-4-i" "2gp-PG-e4-i" #I "PqDescendantsTreeCoclassOne-16-i" #I 3-groups: #I "3gp-PG-i" "3gp-PG-4-i" "3gp-PG-x-i" #I "3gp-PG-x-1-i" "PqDescendants-treetraverse-i" #I "PqDescendantsTreeCoclassOne-9-i" #I 5-groups: #I "5gp-PG-i" "Nott-PG-Rel-i" "Nott-APG-Rel-i" #I "PqDescendantsTreeCoclassOne-25-i" #I 7,11-groups: #I "7gp-PG-i" "11gp-PG-i" #I #I Standard Presentation examples: #I general: #I "StandardPresentation" "StandardPresentation-i" #I "EpimorphismStandardPresentation" #I "EpimorphismStandardPresentation-i" "IsIsomorphicPGroup-ni" #I 2-groups: #I "2gp-SP-Rel-i" "2gp-SP-1-Rel-i" "2gp-SP-2-Rel-i" #I "2gp-SP-3-Rel-i" "2gp-SP-4-Rel-i" "2gp-SP-d-Rel-i" #I "gp-256-SP-Rel-i" "B2-4-SP-i" "G2-SP-Rel-i" #I 3-groups: #I "3gp-SP-Rel-i" "3gp-SP-1-Rel-i" "3gp-SP-2-Rel-i" #I "3gp-SP-3-Rel-i" "3gp-SP-4-Rel-i" "G3-SP-Rel-i" #I 5-groups: #I "5gp-SP-Rel-i" "5gp-SP-a-Rel-i" "5gp-SP-b-Rel-i" #I "5gp-SP-big-Rel-i" "5gp-SP-d-Rel-i" "G5-SP-Rel-i" #I "G5-SP-a-Rel-i" "Nott-SP-Rel-i" #I 7-groups: #I "7gp-SP-Rel-i" "7gp-SP-a-Rel-i" "7gp-SP-b-Rel-i" #I 11-groups: #I "11gp-SP-a-i" "11gp-SP-a-Rel-i" "11gp-SP-a-Rel-1-i" #I "11gp-SP-b-i" "11gp-SP-b-Rel-i" "11gp-SP-c-Rel-i" #I #I Notes #I ----- #I 1. The example (first) argument of `PqExample' is a string; each #I example above is in double quotes to remind you to include them. #I 2. Some examples accept options. To find out whether a particular #I example accepts options, display it first (by including `Display' #I as last argument) which will also indicate how `PqExample' #I interprets the options, e.g. `PqExample("11gp-SP-a-i", Display);'. #I 3. Try `SetInfoLevel(InfoANUPQ, <n>);' for some <n> in [2 .. 4] #I before calling PqExample, to see what's going on behind the scenes. #I
If on your terminal you are unable to scroll back, an alternative to typing PqExample();
to see the displayed examples is to use on-line help, i.e. you may type:
gap> ?anupq:examples
which will display this appendix in a GAP session. If you are not fussed about the order in which the examples are organised, AllPqExamples();
lists the available examples relatively compactly (see AllPqExamples
(3.4-5)).
In the remainder of this appendix we will discuss particular aspects related to the Relators
(see 6.2) and Identities
(see 6.2) options, and the construction of the Burnside group \(B(5, 4)\).
The Relators
option was included because computations involving words containing commutators that are pre-expanded by GAP before being passed to the pq
program may run considerably more slowly, than the same computations being run with GAP pre-expansions avoided. The following examples demonstrate a case where the performance hit due to pre-expansion of commutators by GAP is a factor of order 100 (in order to see timing information from the pq
program, we set the InfoANUPQ
level to 2).
Firstly, we run the example that allows pre-expansion of commutators (the function PqLeftNormComm
is provided by the ANUPQ package; see PqLeftNormComm
(3.4-1)). Note that since the two commutators of this example are very long (taking more than an page to print), we have edited the output at this point.
gap> SetInfoLevel(InfoANUPQ, 2); #to see timing information gap> PqExample("11gp-i"); #I #Example: "11gp-i" . . . based on: examples/11gp #I F, a, b, c, R, procId are local to `PqExample' gap> F := FreeGroup("a", "b", "c"); a := F.1; b := F.2; c := F.3; <free group on the generators [ a, b, c ]> a b c gap> R := [PqLeftNormComm([b, a, a, b, c])^11, > PqLeftNormComm([a, b, b, a, b, c])^11, (a * b)^11];; gap> procId := PqStart(F/R : Prime := 11); 1 gap> PqPcPresentation(procId : ClassBound := 7, > OutputLevel := 1); #I Lower exponent-11 central series for [grp] #I Group: [grp] to lower exponent-11 central class 1 has order 11^3 #I Group: [grp] to lower exponent-11 central class 2 has order 11^8 #I Group: [grp] to lower exponent-11 central class 3 has order 11^19 #I Group: [grp] to lower exponent-11 central class 4 has order 11^42 #I Group: [grp] to lower exponent-11 central class 5 has order 11^98 #I Group: [grp] to lower exponent-11 central class 6 has order 11^228 #I Group: [grp] to lower exponent-11 central class 7 has order 11^563 #I Computation of presentation took 27.04 seconds gap> PqSavePcPresentation(procId, ANUPQData.outfile); #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'.
Now we do the same calculation using the Relators
option. In this way, the commutators are passed directly as strings to the pq
program, so that GAP does not see
them and pre-expand them.
gap> PqExample("11gp-Rel-i"); #I #Example: "11gp-Rel-i" . . . based on: examples/11gp #I #(equivalent to "11gp-i" example but uses `Relators' option) #I F, rels, procId are local to `PqExample' gap> F := FreeGroup("a", "b", "c"); <free group on the generators [ a, b, c ]> gap> rels := ["[b, a, a, b, c]^11", "[a, b, b, a, b, c]^11", "(a * b)^11"]; [ "[b, a, a, b, c]^11", "[a, b, b, a, b, c]^11", "(a * b)^11" ] gap> procId := PqStart(F : Prime := 11, Relators := rels); 2 gap> PqPcPresentation(procId : ClassBound := 7, > OutputLevel := 1); #I Relators parsed ok. #I Lower exponent-11 central series for [grp] #I Group: [grp] to lower exponent-11 central class 1 has order 11^3 #I Group: [grp] to lower exponent-11 central class 2 has order 11^8 #I Group: [grp] to lower exponent-11 central class 3 has order 11^19 #I Group: [grp] to lower exponent-11 central class 4 has order 11^42 #I Group: [grp] to lower exponent-11 central class 5 has order 11^98 #I Group: [grp] to lower exponent-11 central class 6 has order 11^228 #I Group: [grp] to lower exponent-11 central class 7 has order 11^563 #I Computation of presentation took 0.27 seconds gap> PqSavePcPresentation(procId, ANUPQData.outfile); #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'.
Please pay heed to the warnings given for the Identities
option (see 6.2); it is written mainly at the GAP level and is not particularly optimised. The Identities
option allows one to compute \(p\)-quotients that satisfy an identity. A trivial example better done using the Exponent
option, but which nevertheless demonstrates the usage of the Identities
option, is as follows:
gap> SetInfoLevel(InfoANUPQ, 1); gap> PqExample("B2-4-Id"); #I #Example: "B2-4-Id" . . . alternative way to generate B(2, 4) #I #Generates B(2, 4) by using the `Identities' option #I #... this is not as efficient as using `Exponent' but #I #demonstrates the usage of the `Identities' option. #I F, f, procId are local to `PqExample' gap> F := FreeGroup("a", "b"); <free group on the generators [ a, b ]> gap> # All words w in the pc generators of B(2, 4) satisfy f(w) = 1 gap> f := w -> w^4; function( w ) ... end gap> Pq( F : Prime := 2, Identities := [ f ] ); #I Class 1 with 2 generators. #I Class 2 with 5 generators. #I Class 3 with 7 generators. #I Class 4 with 10 generators. #I Class 5 with 12 generators. #I Class 5 with 12 generators. <pc group of size 4096 with 12 generators> #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'. gap> time; 1400
Note that the time
statement gives the time in milliseconds spent by GAP in executing the PqExample("B2-4-Id");
command (i.e. everything up to the Info
-ing of the variables used), but over 90% of that time is spent in the final Pq
statement. The time spent by the pq
program, which is negligible anyway (you can check this by running the example while the InfoANUPQ
level is set to 2), is not counted by time
.
Since the identity used in the above construction of \(B(2, 4)\) is just an exponent law, the right
way to compute it is via the Exponent
option (see 6.2), which is implemented at the C level and is highly optimised. Consequently, the Exponent
option is significantly faster, generally by several orders of magnitude:
gap> SetInfoLevel(InfoANUPQ, 2); # to see time spent by the `pq' program gap> PqExample("B2-4"); #I #Example: "B2-4" . . . the ``right'' way to generate B(2, 4) #I #Generates B(2, 4) by using the `Exponent' option #I F, procId are local to `PqExample' gap> F := FreeGroup("a", "b"); <free group on the generators [ a, b ]> gap> Pq( F : Prime := 2, Exponent := 4 ); #I Computation of presentation took 0.00 seconds <pc group of size 4096 with 12 generators> #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'. gap> time; # time spent by GAP in executing `PqExample("B2-4");' 50
The following example uses the Identities
option to compute a 3-Engel group for the prime 11. As is the case for the example "B2-4-Id"
, the example has both a non-interactive and an interactive form; below, we demonstrate the interactive form.
gap> SetInfoLevel(InfoANUPQ, 1); # reset InfoANUPQ to default level gap> PqExample("11gp-3-Engel-Id", PqStart); #I #Example: "11gp-3-Engel-Id" . . . 3-Engel group for prime 11 #I #Non-trivial example of using the `Identities' option #I F, a, b, G, f, procId, Q are local to `PqExample' gap> F := FreeGroup("a", "b"); a := F.1; b := F.2; <free group on the generators [ a, b ]> a b gap> G := F/[ a^11, b^11 ]; <fp group on the generators [ a, b ]> gap> # All word pairs u, v in the pc generators of the 11-quotient Q of G gap> # must satisfy the Engel identity: [u, v, v, v] = 1. gap> f := function(u, v) return PqLeftNormComm( [u, v, v, v] ); end; function( u, v ) ... end gap> procId := PqStart( G ); 3 gap> Q := Pq( procId : Prime := 11, Identities := [ f ] ); #I Class 1 with 2 generators. #I Class 2 with 3 generators. #I Class 3 with 5 generators. #I Class 3 with 5 generators. <pc group of size 161051 with 5 generators> gap> # We do a ``sample'' check that pairs of elements of Q do satisfy gap> # the given identity: gap> f( Random(Q), Random(Q) ); <identity> of ... gap> f( Q.1, Q.2 ); <identity> of ... #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'.
The (interactive) call to Pq
above is essentially equivalent to a call to PqPcPresentation
with the same arguments and options followed by a call to PqCurrentGroup
. Moreover, the call to PqPcPresentation
(as described in PqPcPresentation
(5.6-1)) is equivalent to a class 1
call to PqPcPresentation
followed by the requisite number of calls to PqNextClass
, and with the Identities
option set, both PqPcPresentation
and PqNextClass
quietly
perform the equivalent of a PqEvaluateIdentities
call. In the following example we break down the Pq
call into its low-level equivalents, and set and unset the Identities
option to show where PqEvaluateIdentities
fits into this scheme.
gap> PqExample("11gp-3-Engel-Id-i"); #I #Example: "11gp-3-Engel-Id-i" . . . 3-Engel grp for prime 11 #I #Variation of "11gp-3-Engel-Id" broken down into its lower-level component #I #command parts. #I F, a, b, G, f, procId, Q are local to `PqExample' gap> F := FreeGroup("a", "b"); a := F.1; b := F.2; <free group on the generators [ a, b ]> a b gap> G := F/[ a^11, b^11 ]; <fp group on the generators [ a, b ]> gap> # All word pairs u, v in the pc generators of the 11-quotient Q of G gap> # must satisfy the Engel identity: [u, v, v, v] = 1. gap> f := function(u, v) return PqLeftNormComm( [u, v, v, v] ); end; function( u, v ) ... end gap> procId := PqStart( G : Prime := 11 ); 4 gap> PqPcPresentation( procId : ClassBound := 1); gap> PqEvaluateIdentities( procId : Identities := [f] ); #I Class 1 with 2 generators. gap> for c in [2 .. 4] do > PqNextClass( procId : Identities := [] ); #reset `Identities' option > PqEvaluateIdentities( procId : Identities := [f] ); > od; #I Class 2 with 3 generators. #I Class 3 with 5 generators. #I Class 3 with 5 generators. gap> Q := PqCurrentGroup( procId ); <pc group of size 161051 with 5 generators> gap> # We do a ``sample'' check that pairs of elements of Q do satisfy gap> # the given identity: gap> f( Random(Q), Random(Q) ); <identity> of ... gap> f( Q.1, Q.2 ); <identity> of ... #I Variables used in `PqExample' are saved in `ANUPQData.example.vars'.
An example demonstrating how a large computation can be organised with the ANUPQ package is the computation of the Burnside group \(B(5, 4)\), the largest group of exponent 4 generated by 5 elements. It has order \(2^{2728}\) and lower exponent-\(p\) central class 13. The example "B5-4.g"
computes \(B(5, 4)\); it is based on a pq
standalone input file written by M. F. Newman.
To be able to do examples like this was part of the motivation to provide access to the low-level functions of the standalone program from within GAP.
Please note that the construction uses the knowledge gained by Newman and O'Brien in their initial construction of \(B(5, 4)\), in particular, insight into the commutator structure of the group and the knowledge of the \(p\)-central class and the order of \(B(5, 4)\). Therefore, the construction cannot be used to prove that \(B(5, 4)\) has the order and class mentioned above. It is merely a reconstruction of the group. More information is contained in the header of the file examples/B5-4.g
.
procId := PqStart( FreeGroup(5) : Exponent := 4, Prime := 2 ); Pq( procId : ClassBound := 2 ); PqSupplyAutomorphisms( procId, [ [ [ 1, 1, 0, 0, 0], # first automorphism [ 0, 1, 0, 0, 0], [ 0, 0, 1, 0, 0], [ 0, 0, 0, 1, 0], [ 0, 0, 0, 0, 1] ], [ [ 0, 0, 0, 0, 1], # second automorphism [ 1, 0, 0, 0, 0], [ 0, 1, 0, 0, 0], [ 0, 0, 1, 0, 0], [ 0, 0, 0, 1, 0] ] ] );; Relations := [ [], ## class 1 [], ## class 2 [], ## class 3 [], ## class 4 [], ## class 5 [], ## class 6 ## class 7 [ [ "x2","x1","x1","x3","x4","x4","x4" ] ], ## class 8 [ [ "x2","x1","x1","x3","x4","x5","x5","x5" ] ], ## class 9 [ [ "x2","x1","x1","x3","x4","x4","x5","x5","x5" ], [ "x2","x1","x1","x2","x3","x4","x5","x5","x5" ], [ "x2","x1","x1","x3","x3","x4","x5","x5","x5" ] ], ## class 10 [ [ "x2","x1","x1","x2","x3","x3","x4","x5","x5","x5" ], [ "x2","x1","x1","x3","x3","x4","x4","x5","x5","x5" ] ], ## class 11 [ [ "x2","x1","x1","x2","x3","x3","x4","x4","x5","x5","x5" ], [ "x2","x1","x1","x2","x3","x1","x3","x4","x2","x4","x3" ] ], ## class 12 [ [ "x2","x1","x1","x2","x3","x1","x3","x4","x2","x5","x5","x5" ], [ "x2","x1","x1","x3","x2","x4","x3","x5","x4","x5","x5","x5" ] ], ## class 13 [ [ "x2","x1","x1","x2","x3","x1","x3","x4","x2","x4","x5","x5","x5" ] ] ]; for class in [ 3 .. 13 ] do Print( "Computing class ", class, "\n" ); PqSetupTablesForNextClass( procId ); for w in [ class, class-1 .. 7 ] do PqAddTails( procId, w ); PqDisplayPcPresentation( procId ); if Relations[ w ] <> [] then # recalculate automorphisms PqExtendAutomorphisms( procId ); for r in Relations[ w ] do Print( "Collecting ", r, "\n" ); PqCommutator( procId, r, 1 ); PqEchelonise( procId ); PqApplyAutomorphisms( procId, 15 ); #queue factor = 15 od; PqEliminateRedundantGenerators( procId ); fi; PqComputeTails( procId, w ); od; PqDisplayPcPresentation( procId ); smallclass := Minimum( class, 6 ); for w in [ smallclass, smallclass-1 .. 2 ] do PqTails( procId, w ); od; # recalculate automorphisms PqExtendAutomorphisms( procId ); PqCollect( procId, "x5^4" ); PqEchelonise( procId ); PqApplyAutomorphisms( procId, 15 ); #queue factor = 15 PqEliminateRedundantGenerators( procId ); PqDisplayPcPresentation( procId ); od;
In the following example we will explore the 3-groups of rank 2 and 3-coclass 1 up to 3-class 5. This will be done using the \(p\)-group generation machinery of the package. We start with the elementary abelian 3-group of rank 2. From within GAP, run the example "PqDescendants-treetraverse-i"
via PqExample
(see PqExample
(3.4-4)).
gap> G := ElementaryAbelianGroup( 9 ); <pc group of size 9 with 2 generators> gap> procId := PqStart( G ); 5 gap> # gap> # Below, we use the option StepSize in order to construct descendants gap> # of coclass 1. This is equivalent to setting the StepSize to 1 in gap> # each descendant calculation. gap> # gap> # The elementary abelian group of order 9 has 3 descendants of gap> # 3-class 2 and 3-coclass 1, as the result of the next command gap> # shows. gap> # gap> PqDescendants( procId : StepSize := 1 ); [ <pc group of size 27 with 3 generators>, <pc group of size 27 with 3 generators>, <pc group of size 27 with 3 generators> ] gap> # gap> # Now we will compute the descendants of coclass 1 for each of the gap> # groups above. Then we will compute the descendants of coclass 1 gap> # of each descendant and so on. Note that the pq program keeps gap> # one file for each class at a time. For example, the descendants gap> # calculation for the second group of class 2 overwrites the gap> # descendant file obtained from the first group of class 2. gap> # Hence, we have to traverse the descendants tree in depth first gap> # order. gap> # gap> PqPGSetDescendantToPcp( procId, 2, 1 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 2 gap> PqPGSetDescendantToPcp( procId, 3, 1 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 2 gap> PqPGSetDescendantToPcp( procId, 4, 1 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 2 gap> # gap> # At this point we stop traversing the ``left most'' branch of the gap> # descendants tree and move upwards. gap> # gap> PqPGSetDescendantToPcp( procId, 4, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> PqPGSetDescendantToPcp( procId, 3, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> # gap> # The computations above indicate that the descendants subtree under gap> # the first descendant of the elementary abelian group of order 9 gap> # will have only one path of infinite length. gap> # gap> PqPGSetDescendantToPcp( procId, 2, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 4 gap> # gap> # We get four descendants here, three of which will turn out to be gap> # incapable, i.e., they have no descendants and are terminal nodes gap> # in the descendants tree. gap> # gap> PqPGSetDescendantToPcp( procId, 2, 3 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> # gap> # The third descendant of class three is incapable. Let us return gap> # to the second descendant of class 2. gap> # gap> PqPGSetDescendantToPcp( procId, 2, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 4 gap> PqPGSetDescendantToPcp( procId, 3, 1 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> PqPGSetDescendantToPcp( procId, 3, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> # gap> # We skip the third descendant for the moment ... gap> # gap> PqPGSetDescendantToPcp( procId, 3, 4 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> # gap> # ... and look at it now. gap> # gap> PqPGSetDescendantToPcp( procId, 3, 3 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 6 gap> # gap> # In this branch of the descendant tree we get 6 descendants of class gap> # three. Of those 5 will turn out to be incapable and one will have gap> # 7 descendants. gap> # gap> PqPGSetDescendantToPcp( procId, 4, 1 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0 gap> PqPGSetDescendantToPcp( procId, 4, 2 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); 7 gap> PqPGSetDescendantToPcp( procId, 4, 3 ); gap> PqPGExtendAutomorphisms( procId ); gap> PqPGConstructDescendants( procId : StepSize := 1 ); #I group restored from file is incapable 0
To automate the above procedure to some extent we provide:
‣ PqDescendantsTreeCoclassOne ( i ) | ( function ) |
‣ PqDescendantsTreeCoclassOne ( ) | ( function ) |
for the ith or default interactive ANUPQ process, generate a descendant tree for the group of the process (which must be a pc \(p\)-group) consisting of descendants of \(p\)-coclass 1 and extending to the class determined by the option TreeDepth
(or 6 if the option is omitted). In an XGAP session, a graphical representation of the descendants tree appears in a separate window. Subsequent calls to PqDescendantsTreeCoclassOne
for the same process may be used to extend the descendant tree from the last descendant computed that itself has more than one descendant. PqDescendantsTreeCoclassOne
also accepts the options CapableDescendants
(or AllDescendants
) and any options accepted by the interactive PqDescendants
function (see PqDescendants
(5.3-6)).
Notes
PqDescendantsTreeCoclassOne
first calls PqDescendants
. If PqDescendants
has already been called for the process, the previous value computed is used and a warning is Info
-ed at InfoANUPQ
level 1.
As each descendant is processed its unique label defined by the pq
program and number of descendants is Info
-ed at InfoANUPQ
level 1.
PqDescendantsTreeCoclassOne
is an experimental
function that is included to demonstrate the sort of things that are possible with the \(p\)-group generation machinery.
Ignoring the extra functionality provided in an XGAP session, PqDescendantsTreeCoclassOne
, with one argument that is the index of an interactive ANUPQ process, is approximately equivalent to:
PqDescendantsTreeCoclassOne := function( procId ) local des, i; des := PqDescendants( procId : StepSize := 1 ); RecurseDescendants( procId, 2, Length(des) ); end;
where RecurseDescendants
is (approximately) defined as follows:
RecurseDescendants := function( procId, class, n ) local i, nr; if class > ValueOption("TreeDepth") then return; fi; for i in [1..n] do PqPGSetDescendantToPcp( procId, class, i ); PqPGExtendAutomorphisms( procId ); nr := PqPGConstructDescendants( procId : StepSize := 1 ); Print( "Number of descendants of group ", i, " at class ", class, ": ", nr, "\n" ); RecurseDescendants( procId, class+1, nr ); od; return; end;
The following examples (executed via PqExample
; see PqExample
(3.4-4)), demonstrate the use of PqDescendantsTreeCoclassOne
:
"PqDescendantsTreeCoclassOne-9-i"
approximately does example "PqDescendants-treetraverse-i"
again using PqDescendantsTreeCoclassOne
;
"PqDescendantsTreeCoclassOne-16-i"
uses the option CapableDescendants
; and
"PqDescendantsTreeCoclassOne-25-i"
calculates all descendants by omitting the CapableDescendants
option.
The numbers 9
, 16
and 25
respectively, indicate the order of the elementary abelian group to which PqDescendantsTreeCoclassOne
is applied for these examples.
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