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Add letters function for PcGroupElem #4202

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105 changes: 104 additions & 1 deletion src/Groups/pcgroup.jl
Original file line number Diff line number Diff line change
Expand Up @@ -415,7 +415,6 @@ function _GAP_collector_from_the_left(c::GAP_Collector)
return cGAP::GapObj
end


# Create the collector on the GAP side on demand
function underlying_gap_object(c::GAP_Collector)
if ! isdefined(c, :X)
Expand Down Expand Up @@ -473,6 +472,110 @@ function pc_group(c::GAP_Collector)
end
end

"""
letters(g::Union{PcGroupElem, SubPcGroupElem})

Return the letters of `g` as a list of integers, each entry corresponding to
a group generator.
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Note that we can also produce negative numbers: e.g. -3 means "inverse of 3rd generator". This should be explained, and perhaps an example added showing that. E.g. based on this:

julia> x = (gg[1]*gg[2]*gg[3])^-2
g1*g2^-2*g3^3

Perhaps also add something like this (and then mirror it in the other function)

See also [`syllables`](@ref).

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I have added a small example with some brief explanation to letters for this. However I am unsure if the example is good as I was not able to get elements with negative exponents and test.

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For that you need an infinite group. E.g.

julia> g = dihedral_group(PosInf())
Pc group of infinite order

julia> g[1]^-3 * g[2]^-3
g1*g2^-3

or

julia> g = abelian_group(PcGroup, [5, 0])
Pc group of infinite order

julia> g[1]^-3 * g[2]^-3
g1^2*g2^-3


This method can produce letters represented by negative numbers. A negative number
indicates the inverse of the generator at the corresponding positive index.

For example, as shown below, an output of -1 refers to the "inverse of the first generator".
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See also [`syllables`](@ref).
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```jldoctest
julia> gg = small_group(6, 1)
Pc group of order 6

julia> x = gg([1 => ZZ(-3)])
f1^-3

julia> letters(x)
3-element Vector{Int64}:
-1
-1
-1
```

# Examples
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```jldoctest
julia> gg = small_group(6, 1)
Pc group of order 6

julia> x = gg[1]^5*gg[2]^-4
f1*f2^2

julia> letters(x)
3-element Vector{Int64}:
1
2
2
```
"""
function letters(g::Union{PcGroupElem, SubPcGroupElem})
w = GAPWrap.UnderlyingElement(GapObj(g))
return Vector{Int}(GAPWrap.LetterRepAssocWord(w))
end

"""
syllables(g::Union{PcGroupElem, SubPcGroupElem})

Return the syllables of `g` as a list of pairs of integers, each entry corresponding to
a group generator and its exponent.
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# Examples
```jldoctest
julia> gg = small_group(6, 1)
Pc group of order 6

julia> x = gg[1]^5*gg[2]^-4
f1*f2^2

julia> s = syllables(x)
2-element Vector{Pair{Int64, ZZRingElem}}:
1 => 1
2 => 2

julia> gg(s)
f1*f2^2

julia> gg(s) == x
true
```
"""
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function syllables(g::Union{PcGroupElem, SubPcGroupElem})
l = GAPWrap.ExtRepOfObj(GapObj(g))
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@assert iseven(length(l))
return Pair{Int, ZZRingElem}[l[i-1] => l[i] for i = 2:2:length(l)]
end

# Convert syllables in canonical form into exponent vector
function _exponent_vector(sylls::Vector{Pair{Int64, ZZRingElem}}, n)
res = zeros(ZZRingElem, n)
for pair in sylls
@assert res[pair.first] == 0 #just to make sure
res[pair.first] = pair.second
end
return res
end

# Convert syllables in canonical form into group element
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function (G::PcGroup)(sylls::Vector{Pair{Int64, ZZRingElem}}; check::Bool=true)
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Can you also add a similar constructor which takes an exponent vector, i.e., an inverse to letters?

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One needs to watch out for the semantic difference to the already existing function for FPGroups in

function (G::FPGroup)(extrep::AbstractVector{T}) where T <: IntegerUnion
, which expects a flattened list of syllable pairs instead.

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ugh, OK. perhaps we should kill that (is it documented?) first then. In GAP it made some sense to use such a flat list to avoid memory, as there are no tuples in GAP, only lists. But in Julia there is no real benefit of this over a Vector{Pair{Int64, ZZRingElem}}.

But that is way beyond this PR. So let's leave out the constructor I mentioned.

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No, not documented, but used for serialization. I haven't looked into how it is used there, so maybe we can just adapt the deserialization function, in the worst case it needs an upgrade script.

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ugh, OK. perhaps we should kill that (is it documented?) first then.

maybe @ThomasBreuer can look into that?

# check if the syllables are in canonical form
if check
indices = map(p -> p.first, sylls)
@req allunique(indices) "given syllables have repeating generators"
@req issorted(indices) "given syllables must be in ascending order"
end

e = _exponent_vector(sylls, ngens(G))
pcgs = Oscar.GAPWrap.FamilyPcgs(GapObj(G))
x = Oscar.GAPWrap.PcElementByExponentsNC(pcgs, GapObj(e, true))
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return Oscar.group_element(G, x)
end

# Create an Oscar collector from a GAP collector.

Expand Down
45 changes: 45 additions & 0 deletions test/Groups/pcgroup.jl
Original file line number Diff line number Diff line change
Expand Up @@ -83,6 +83,51 @@ end
@test cgg !== c.X
end

@testset "generate letters from polycyclic group element" begin

# finite polycyclic groups
c = collector(2, Int);
set_relative_order!(c, 1, 2)
set_relative_order!(c, 2, 3)
set_power!(c, 1, [2 => 1])
gg = pc_group(c)
@test letters(gg[1]^5*gg[2]^-4) == [1, 2]
@test letters(gg[1]^5*gg[2]^4) == [1] # all positive exp
@test letters(gg[1]^-5*gg[2]^-7) == [1, 2, 2] # all negative exp
@test letters(gg[1]^2*gg[2]^3) == [2] # both identity elements

# finite polycyclic subgroup
gg = pc_group(symmetric_group(4))
G = derived_subgroup(gg)[1]
@test letters(G[1]^2) == [2, 2]
@test letters(G[1]^2*G[2]^3*G[3]^3) == [2, 2, 3, 4]
@test letters(G[1]^-2*G[2]^-3*G[3]^-3) == [2, 3, 4]
end

@testset "create polycyclic group element from syllables" begin

# finite polycyclic groups
c = collector(2, Int);
set_relative_order!(c, 1, 2)
set_relative_order!(c, 2, 3)
set_power!(c, 1, [2 => 1])
gg = pc_group(c)

element = gg[1]^5*gg[2]^-4
sylls = syllables(element)
@test sylls == [1 => ZZ(1), 2 => ZZ(1)] # check general usage
@test gg(sylls) == element # this will pass the check

sylls = [1 => ZZ(1), 2 => ZZ(2), 1 => ZZ(3)]
@test_throws ArgumentError gg(sylls) # repeating generators

sylls = [2 => ZZ(1), 1 => ZZ(2)]
@test_throws ArgumentError gg(sylls) # not in ascending order

sylls = [2 => ZZ(1), 1 => ZZ(2), 1 => ZZ(3)] # both conditions
@test_throws ArgumentError gg(sylls)
end

@testset "create collectors from polycyclic groups" begin
for i in rand(1:number_of_small_groups(96), 10)
g = small_group(96, i)
Expand Down
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