CI: use concrete action version (#1203) #16
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../../../.julia/packages/Documenter/bYYzK/src/Utilities/Utilities.jl#L34
2351 docstrings not included in the manual:
group :: Tuple{AlgGrp}
isindex_divisor
ZZModRingElem
isnormalized
MaximalOrder :: Union{Tuple{NfAbsOrd{S, T}}, Tuple{T}, Tuple{S}} where {S, T}
MaximalOrder :: Union{Tuple{Hecke.AbsAlgAss{S}}, Tuple{S}} where S
MaximalOrder :: Union{Tuple{Hecke.AlgAssAbsOrd{S, T}}, Tuple{S}, Tuple{T}} where {T, S}
symbolic_roots :: Union{Tuple{ZZMPolyRingElem, Integer}, Tuple{ZZMPolyRingElem, Integer, Int64}}
isinfinite
order :: Tuple{NumFieldOrdIdl}
order :: Tuple{Hecke.NfAbsOrdIdlSet}
order :: Union{Tuple{EllCrv{T}}, Tuple{T}} where T<:FinFieldElem
order :: Tuple{Hecke.AlgAssRelOrdIdl}
order :: Union{Tuple{EllCrvPt{T}}, Tuple{T}} where T<:FinFieldElem
order :: Tuple{Hecke.AlgAssAbsOrdIdl}
order :: Tuple{TorQuadModule}
order :: Tuple{Hecke.GenOrdIdl}
order :: Union{Tuple{EllCrvPt{T}}, Tuple{T}} where T<:Union{QQFieldElem, nf_elem}
newton_polygon :: Union{Tuple{T}, Tuple{T, T, ZZRingElem}} where T
newton_polygon :: Union{Tuple{T}, Tuple{S}, Tuple{T, T}} where {S<:Union{padic, qadic, Hecke.LocalFieldElem}, T<:AbstractAlgebra.Generic.Poly{S}}
formal_differential_form :: Union{Tuple{EllCrv}, Tuple{EllCrv, Int64}}
ischaracteristic
iroot :: Tuple{ZZRingElem, Int64}
homogeneous_equation :: Tuple{HypellCrv}
abelian_group :: Union{Tuple{EllCrv{U}}, Tuple{U}} where U<:FinFieldElem
abelian_group :: Tuple{AbstractMatrix{<:Union{Integer, ZZRingElem}}}
abelian_group :: Tuple{AbstractVector{<:Union{Integer, ZZRingElem}}}
negation_map :: Tuple{EllCrv}
NmodRing
ZZRingElem :: Tuple{RealFieldElem}
ZZRingElem :: Tuple{arb}
ZZRingElem :: Tuple{qqbar}
ZZRingElem
isequivalent_with_isometry
const_e :: Union{Tuple{RealField}, Tuple{RealField, Int64}}
const_e :: Tuple{ArbField}
FlintPadicField :: Tuple{Integer, Int64}
FlintPadicField
real_period :: Union{Tuple{EllCrv{QQFieldElem}}, Tuple{EllCrv{QQFieldElem}, Int64}}
isdyadic
restrict_scalars :: Union{Tuple{AbstractLat, QQField}, Tuple{AbstractLat, QQField, FieldElem}}
restrict_scalars :: Tuple{Hecke.AbsAlgAss{nf_elem}, NfToNfMor}
restrict_scalars :: Union{Tuple{T}, Tuple{Hecke.AbsAlgAss{T}, Field}} where T
restrict_scalars :: Tuple{AbstractLat, AbstractSpaceRes}
restrict_scalars :: Union{Tuple{AbstractSpace, QQField}, Tuple{AbstractSpace, QQField, FieldElem}}
TorQuadModuleMor
add_verbose_scope
trace_matrix :: Tuple{NfAbsOrd}
trace_matrix :: Tuple{Hecke.AbsAlgAss}
trace_matrix :: Tuple{AlgAss}
_standard_mass_squared :: Tuple{ZZGenus}
airy_ai_prime :: Union{Tuple{RealFieldElem}, Tuple{RealFieldElem, Int64}}
airy_ai_prime :: Tuple{arb}
airy_ai_prime :: Union{Tuple{ComplexFieldElem}, Tuple{ComplexFieldElem, Int64}}
airy_ai_prime :: Tuple{acb}
FmpzMatSpace
is_unimodular :: Tuple{ZZGenus}
is_unimodular :: Tuple{ZZLat}
FmpzPolyRing
setunion :: Tuple{arb, arb}
setunion :: Union{Tuple{RealFieldElem, RealFieldElem}, Tuple{RealFieldElem, RealFieldElem, Int64}}
genus_field :: Tuple{ClassField}
isfree
TorQuadModMor
isnorm_divisible
trace_lattice_with_isometry_and_transfer_data :: Union{Tuple{AbstractLat{T}}, Tuple{T}} where T
order_via_bsgs :: Union{Tuple{EllCrv{T}}, Tuple{T}} where T<:FinFieldElem
_quadratic_L_function_squared :: Tuple{Any, Any}
flog :: Tuple{ZZRingElem, ZZRingElem}
inv :: Tuple{NfAbsOrdIdl}
inv :: Tuple{Hecke.AlgAssRelOrdIdl}
inv :: Tuple{TorQuadModuleMor}
inv :: Tuple{AlgMatElem}
inv :: Tuple{Hecke.AbsAlgAssElem}
inv :: Tuple{Hecke.AlgAssAbsOrdIdl}
inv :: Tuple{Hecke.NfAbsOrdFracIdl}
inv :: Union{Tuple{OrdLocElem{T}}, Tuple{T}, Tuple{OrdLocElem{T}, Bool}} where T<:nf_elem
inv :: Tuple{GrpGenToGrpGenMor}
inv :: Union{Tuple{Hecke.EllCrvIso{T}}, Tuple{T}} where T<:RingElem
inv :: Union{Tuple{KInftyElem{T}}, Tuple{T}, Tuple{KInftyElem{T}, Bool}} where T<:FieldElement
issimple
local_genera_hermitian
_hensel_qf_modular_odd :: Union{Tuple{T},
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