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add conformance tests

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kalmarek 2019-06-05 10:19:53 +02:00
parent 85ab7a430a
commit ebf3644682
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2 changed files with 334 additions and 0 deletions

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@ -0,0 +1,325 @@
using Test
using AbstractAlgebra
has_base_ring(R::AbstractAlgebra.NCRing) = base_ring(R) != Union{}
function test_data_type(f,g)
@testset "Data type" begin
f,g = deepcopy(f), deepcopy(g)
if f isa NCRingElem
@test parent(f) isa AbstractAlgebra.NCRing
else
@test parent(f) isa AbstractAlgebra.Ring
end
R = parent(f)
@test typeof(R) <: parent_type(typeof(f))
@test typeof(f) <: elem_type(typeof(R))
@test base_ring(R) isa AbstractAlgebra.Ring || base_ring(R) == Union{}
if f isa RingElement
@test isdomain_type(typeof(f)) isa Bool
end
@test isexact_type(typeof(f)) isa Bool
@test deepcopy(f) isa typeof(f)
@test !(deepcopy(f) === f)
@test parent(deepcopy(f)) === parent(f)
@test hash(f, UInt(0)) isa UInt
@test hash(deepcopy(f)) == hash(f)
end
end
function test_constructors(f,g)
@testset "Constructors" begin
f,g = deepcopy(f), deepcopy(g)
R = parent(f)
@test R() isa typeof(f)
@test R(0) isa typeof(f)
@test R(Int16(0)) isa typeof(f)
@test R(big(1)) isa typeof(f)
@test zero(R) isa typeof(f)
@test one(R) isa typeof(f)
# no copy constructor
@test R(f) === f
if has_base_ring(R)
S = base_ring(R)
@test R(S(0)) isa typeof(f)
@test R(S(1)) isa typeof(f)
end
@test iszero(R(0))
@test !iszero(R(1))
@test isone(R(1))
@test !isone(R(0))
@test !(iszero(f) && isone(f))
if f isa RingElement
@test canonical_unit(f) isa typeof(f)
@test canonical_unit(f)*canonical_unit(g) == canonical_unit(f * g)
if f isa FieldElement
@test canonical_unit(f) === f
end
end
end
end
function test_string_io(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "String I/O" begin
# these go through show unless string() is defined
@test string(f) isa String
@test string(parent(f)) isa String
@test needs_parentheses(f) isa Bool
@test displayed_with_minus_in_front(f) isa Bool
@test show_minus_one(typeof(f)) isa Bool
end
end
function test_comparison(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "Comparison" begin
R = parent(f)
@test R(0) == R()
@test R(Int16(0)) == R()
@test zero(R) == R(0)
@test one(R) == R(1)
@test f == f
@test g == g
@test (f == g) isa Bool
@test isequal(f,g) isa Bool
@test isequal(R(0), R())
@test isequal(R(1), one(R))
@test isequal(f,f)
@test isequal(g,g)
if !isexact_type(typeof(f))
@test isapprox(f, f; atol=1e-12) isa Bool
if has_base_ring(R)
S = base_ring(R)
@test isapprox(f, S(1); atol=1e-12) isa Bool
@test isapprox(S(1), f; atol=1e-12) isa Bool
end
end
end
end
function test_unary_binary_ops(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "Unary/binary operators" begin
R = parent(f)
# check that operations have no side effects:
old_f, old_g = deepcopy(f), deepcopy(g)
@test parent(-f) == parent(f)
@test !(-f === f)
@test f+g isa typeof(f)
@test parent(f) == parent(f+g)
@test !(f+g === f) && !(f+g === g)
@test f == old_f && g == old_g
@test f-g isa typeof(f)
@test parent(f) == parent(f-g)
@test !(f-g === f) && !(f-g === g)
@test f == old_f && g == old_g
@test f*g isa typeof(f)
@test parent(f) == parent(f*g)
@test !(f*g === f) && !(f*g === g)
@test f == old_f && g == old_g
# unary minus
@test -f isa typeof(f)
@test -(-f) == f
@test -R(1) == R(-1)
@test -R(0) == R(0)
# arithmetic binary ops
@test f + g == g + f
@test R(0) + R(1) == R(1)
@test R(1) + R(1) == R(2)
@test R(0) - R(1) == -R(1)
@test f - f == -f + f == R(0)
@test (f + g) + R(1) == g + (f + R(1))
@test R(0) * R(1) == R(0)
@test R(1) * f == f
@test R(0) * f == R(0)
@test f^2 == f * f
@test f^5 == (f * f)^2 * f
@test (f*g)^2 == f*g*f*g
end
end
function test_divexact(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "divexact" begin
R = parent(f)
try
divexact_left(g*f, f)
@test divexact_left(g*f, f) == g
if f isa RingElement && g isa RingElement
@test divexact_left(g*f, g) == divexact_right(g*f, g)
end
catch DivideError
nothing
end
try
divexact_right(f*g, g)
@test divexact_right(f*g, g) == f
if f isa RingElement && g isa RingElement
@test divexact_left(f*g, f) == divexact_right(g*f, f)
end
catch DivideError
nothing
end
if f isa RingElement && g isa RingElement
@test_throws DivideError divexact(f, R(0))
end
@test divexact_left(f, R(1)) == f
@test divexact_right(g, R(1)) == g
@test_throws DivideError divexact_left(f, R(0))
@test_throws DivideError divexact_right(f, R(0))
end
end
function test_unsafe_ops(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "unsafe operators" begin
R = parent(f)
let f = f, g = g
t = deepcopy(f)
@test zero!(t) == R(0)
@test AbstractAlgebra.mul!(t, f, g) == f*g
@test add!(t, f, g) == f+g
@test addeq!(deepcopy(f), g) == f + g
# the same but with aliasing:
v = f * g
@test AbstractAlgebra.mul!(f, f, g) == v
v = f + g
@test add!(f, f, g) == v
v = f + g
@test addeq!(f, g) == v
end
end
end
function test_promote_rules(f,g)
f,g = deepcopy(f), deepcopy(g)
@testset "promote_rules" begin
@test AbstractAlgebra.promote_rule(typeof(f), Int16) == typeof(f)
@test AbstractAlgebra.promote_rule(typeof(f), typeof(g)) == typeof(f)
if has_base_ring(parent(f))
S = base_ring(parent(f))
@test AbstractAlgebra.promote_rule(typeof(f), elem_type(S)) == typeof(f)
end
# @test promote_rupe(typeof(f), BigInt) == typeof(f)
end
end
function test_optional_functionality(f,g)
f,g = deepcopy(f), deepcopy(g)
function test_pmt(f,x, T=typeof(f))
@test f+x isa T
@test x+f isa T
@test f-x isa T
@test x-f isa T
@test f*x isa T
@test x*f isa T
end
@testset "Optional functionality" begin
R = parent(f)
@test R(1) == 1
@test 0 == R(0)
test_pmt(f, 2, typeof(f))
if has_base_ring(R)
S = base_ring(R)
test_pmt(f, S(2), typeof(f))
@test R(1) == S(1)
@test S(0) == R(0)
end
try
divexact(f, 1)
@test divexact(f, 1) == f
catch MethodError
nothing
end
try
isunit(f)
@test isunit(f) isa Bool
catch MethodError
nothing
end
try
f^big(2)
@test f^big(2) == f^2
catch MethodError
nothing
end
try
addmul!(r, f, g, R(0))
r = R(1)
@test addmul!(r, f, g, R(0)) == 1 + f * g
@test r == 1 + f*g
v = deepcopy(f)
@test addmul!(f, f, g, R(0)) == v + v * g
@test f == v + v*g
catch MethodError
nothing
end
end
end
function test_ringinterface(f, g)
@testset "Ring Interface" begin
test_data_type(f,g)
test_constructors(f,g)
test_string_io(f,g)
test_comparison(f,g)
test_unary_binary_ops(f,g)
test_divexact(f,g)
test_unsafe_ops(f,g)
test_promote_rules(f,g)
@testset "rand" begin
# ???
end
test_optional_functionality(f,g)
end
end

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@ -9,6 +9,15 @@ include("unittests.jl")
include("usetests.jl")
let
include("AARing_interface_conformance.jl")
R = AbstractAlgebra.zz
G = PermGroup(4)
RG = GroupRing(R, G, collect(G), halfradius_length=order(G))
X = rand(RG, 0.2, -3:3)
Y = rand(RG, 0.4, -1:1)
test_ringinterface(X, Y)
end