/usr/lib/open-axiom/src/algebra/product.spad is in open-axiom-source 1.4.1+svn~2626-2ubuntu2.
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)abbrev domain PRODUCT Product
++ Description:
++ This domain implements cartesian product
Product (A:SetCategory,B:SetCategory) : C == T
where
C == SetCategory with
if A has Finite and B has Finite then Finite
if A has Monoid and B has Monoid then Monoid
if A has AbelianMonoid and B has AbelianMonoid then AbelianMonoid
if A has CancellationAbelianMonoid and
B has CancellationAbelianMonoid then CancellationAbelianMonoid
if A has Group and B has Group then Group
if A has AbelianGroup and B has AbelianGroup then AbelianGroup
if A has OrderedAbelianMonoidSup and B has OrderedAbelianMonoidSup
then OrderedAbelianMonoidSup
if A has OrderedSet and B has OrderedSet then OrderedSet
makeprod : (A,B) -> %
++ makeprod(a,b) \undocumented
selectfirst : % -> A
++ selectfirst(x) \undocumented
selectsecond : % -> B
++ selectsecond(x) \undocumented
T == add
--representations
Rep := Record(acomp:A,bcomp:B)
--declarations
x,y: %
i: NonNegativeInteger
p: NonNegativeInteger
a: A
b: B
d: Integer
--define
coerce(x):OutputForm == paren [(x.acomp)::OutputForm,
(x.bcomp)::OutputForm]
x=y ==
x.acomp = y.acomp => x.bcomp = y.bcomp
false
makeprod(a:A,b:B) :% == [a,b]
selectfirst(x:%) : A == x.acomp
selectsecond (x:%) : B == x.bcomp
if A has Monoid and B has Monoid then
1 == [1$A,1$B]
x * y == [x.acomp * y.acomp,x.bcomp * y.bcomp]
x ** p == [x.acomp ** p ,x.bcomp ** p]
if A has Finite and B has Finite then
size == size$A () * size$B ()
if A has Group and B has Group then
inv(x) == [inv(x.acomp),inv(x.bcomp)]
if A has AbelianMonoid and B has AbelianMonoid then
0 == [0$A,0$B]
x + y == [x.acomp + y.acomp,x.bcomp + y.bcomp]
c:NonNegativeInteger * x == [c * x.acomp,c*x.bcomp]
if A has CancellationAbelianMonoid and
B has CancellationAbelianMonoid then
subtractIfCan(x, y) : Union(%,"failed") ==
(na:= subtractIfCan(x.acomp, y.acomp)) case "failed" => "failed"
(nb:= subtractIfCan(x.bcomp, y.bcomp)) case "failed" => "failed"
[na::A,nb::B]
if A has AbelianGroup and B has AbelianGroup then
- x == [- x.acomp,-x.bcomp]
(x - y):% == [x.acomp - y.acomp,x.bcomp - y.bcomp]
d * x == [d * x.acomp,d * x.bcomp]
if A has OrderedAbelianMonoidSup and B has OrderedAbelianMonoidSup then
sup(x,y) == [sup(x.acomp,y.acomp),sup(x.bcomp,y.bcomp)]
if A has OrderedSet and B has OrderedSet then
x < y ==
xa:= x.acomp ; ya:= y.acomp
xa < ya => true
xb:= x.bcomp ; yb:= y.bcomp
xa = ya => (xb < yb)
false
-- coerce(x:%):Symbol ==
-- PrintableForm()
-- formList([x.acomp::Expression,x.bcomp::Expression])$PrintableForm
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