

last edited 15 years ago by page 
1 2 3  
Editor: page
Time: 2007/11/22 20:42:56 GMT8 

Note: fix link 
changed: [SandBox Aldor Category Theory 2] [SandBox Aldor Category Theory Categories]
Miscellaneous Logical helper functions
#include "axiom" #pile
define Domain:Category == with;
+++ +++ A set is often considered to be a collection with "no duplicate elements." +++ Here we have a slightly different definition which is important to +++ understand. We define a Set to be an arbitrary collection together with +++ an equivalence relation "=". Soon this will be made into a mathematical +++ category where the morphisms are "functions",by which we mean maps +++ having the special property that a=a' implies f a = f a'. This definition +++ is more convenient both mathematically and computationally, but you need +++ to keep in mind that a set may have duplicate elements. +++ define Set:Category == Join(Domain, Printable) with { =:(%, %) > Boolean; } +++ +++ A Preorder is a collection with reflexive and transitive <=, but without +++ necessarily being symmetric (x<=y and y<=x) implying x=y. Since +++ (x<=y and y<=x) is always an equivalence relation, our definition of +++ "Set" is always satisfied in any case. +++ define Preorder:Category == Set with { <=: (%, %) > Boolean; >=: (%, %) > Boolean; < : (%, %) > Boolean; > : (%, %) > Boolean; default { (x:%) =(y:%):Boolean == (x<=y) and (y<=x); (x:%)>=(y:%):Boolean == y<=x; (x:%)< (y:%):Boolean == (x<=y) and ~(x=y); (x:%)> (y:%):Boolean == (x>=y) and ~(x=y) } }
define TotalOrder:Category == Preorder with { min: (%,%) > %; max: (%, %) > %; min: Tuple % > %; max: Tuple % > %; default { min(x:%, y:%):% == { x<=y => x; y }; max(x:%, y:%):% == { x<=y => y; x }; import from List %; min(t:Tuple %):% == associativeProduct(%, min, [t]); max(t:Tuple %):% == associativeProduct(%, max, [t]); } } +++ +++ Countable is the category of collections for which every element in the +++ collection can be produced. This is done by the generator "elements" +++ below. Note that there is no guarantee that elements will not produce +++ "duplicates." In fact, a Countable may not be a Set, so duplicates may +++ have no meaning. Also, Countable is not guaranteed to terminate. +++ define Countable:Category == with { elements: () > Generator % }   I'm using an empty function elements() rather than a constant elements  to avoid some compiler problems.  +++ +++ CountablyFinite is the same as Countable except that termination is +++ guaranteed. +++ define CountablyFinite:Category == Countable with
+++ +++ A "Monoids" is the usual Monoid (we don't use Monoid to avoid clashing +++ with axllib): a Set with an associative product (associative relative to +++ the equivalence relation of the Set,of course) and a unit. +++ define Monoids:Category == Set with { *: (%, %) > %; 1: %; ^:(%, Integer) > %; monoidProduct: Tuple % > %;  associative product monoidProduct: List % > %; default { (x:%)^(i:Integer):% == { i=0 => 1; i<0 => error "Monoid negative powers are not defined."; associativeProduct(%, *, x for j:Integer in 1..i) }; monoidProduct(t:Tuple %):% == { import from List %; monoidProduct(t) } monoidProduct(l:List %):% == { import from NonNegativeInteger; #l = 0 => 1; associativeProduct(%, *, l); } } }
+++ +++ Groups are Groups in the usual mathematical sense. We use "Groups" +++ rather than "Group" to avoid clashing with axllib. +++ define Groups:Category == Monoids with { inv: % > % }
+++ +++ Printing is a whole area that I'm going to have a nice categorical +++ solution for,but still it is convenient to have a low level Printable +++ signature for debugging purposes. +++ define Printable:Category == with { coerce: % > OutputForm; coerce: List % > OutputForm; coerce: Generator % > OutputForm; default { (t:OutputForm)**(l:List %):OutputForm == { import from Integer; empty? l => t; hconcat(coerce first l, hspace(1)$OutputForm) ** rest l; }; coerce(l:List %):OutputForm == empty() ** l; coerce(g:Generator %):OutputForm == { import from List %; empty() ** [x for x in g]; } } }
+++ +++ This evaluates associative products. +++ associativeProduct(T:Type,p:(T, T)>T, g:Generator T):T == { l:List T == [t for t in g]; associativeProduct(T, p, l); } associativeProduct(T:Type, p:(T, T)>T, l:List T):T == { if empty? l then error "Empty product."; mb(t:T, l:List T):T == { empty? l => t; mb( p(t, first l), rest l) }; mb(first l, rest l) } +++ +++ Evaluates the logical "For all ..." construction +++ forall?(g:Generator Boolean):Boolean == { q:Boolean := true; for x:Boolean in g repeat { if ~x then { q := false; break } } q }
+++ +++ Evaluates the logical "There exists ..." construction +++ exists?(g:Generator Boolean):Boolean == { q:Boolean := false; for x:Boolean in g repeat { if x then { q := true; break } }; q }
+++ +++ The category of "Maps". There is no implication that a map is a +++ function in the sense of x=x' => f x = f x' +++ define MapCategory(Obj:Category,A:Obj, B:Obj):Category == with { apply: (%, A) > B; hom: (A>B) > %; } +++ +++ One convenient implementation of MapCategory +++ Map(Obj:Category, A:Obj, B:Obj):MapCategory(Obj, A, B) == add { Rep ==> A>B; apply(f:%, a:A):B == (rep f) a; hom (f:A>B):% == per f } +++ +++ This strange function turns any Type into an Aldor Category +++ define Categorify(T:Type):Category == with { value: T } +++ +++ The null function +++ null(A:Type, B:Type):(A>B) == (a:A):B +> error "Attempt to evaluate the null function."
+++ +++ A handy package for composition of morphisms. "o" is meant to suggest morphism composition g "o" f,to be coded "g ** f". +++ o(Obj:Category, A:Obj, B:Obj, C:Obj): with **: (B>C, A>B) > (A>C) == add (g:B>C)**(f:A>B):(A>C) == (a:A):C +> g f a
Compiling FriCAS source code from file /var/lib/zope2.10/instance/axiomwiki/var/LatexWiki/basics.as using Aldor compiler and options O Fasy Fao Flsp lfricas MnoALDOR_W_WillObsolete DFriCAS Y $FRICAS/algebra I $FRICAS/algebra Use the system command )set compiler args to change these options. The )library system command was not called after compilation.
Test Funtions
#include "axiom" #pile #library lbasics "basics.ao" import from lbasics
T:Domain == add S:Set == Integer add P:Preorder == Integer add TO:TotalOrder == Integer add CC:Countable == Integer add  import from Integer,Generator(Integer)  elements():Generator(Integer) == generator (1..10) M:Monoids == Integer add G:Groups == Fraction Integer add MAPS:MapCategory(SetCategory, Integer, Float) == Map(SetCategory, Integer, Float) add INTS:Categorify(Integer) == add value:Integer == 1 Null(n:PositiveInteger):Float==null(PositiveInteger, Float)(n) sincos(x:Expression Integer):Expression Integer == import from o(SetCategory, Expression Integer, Expression Integer, Expression Integer) ( ((a:Expression Integer):Expression Integer +> sin(a)) ** ((b:Expression Integer):Expression Integer +> cos(b)) ) (x)
Compiling FriCAS source code from file /var/lib/zope2.10/instance/axiomwiki/var/LatexWiki/781921764338037207125px002.as using Aldor compiler and options O Fasy Fao Flsp lfricas MnoALDOR_W_WillObsolete DFriCAS Y $FRICAS/algebra I $FRICAS/algebra Use the system command )set compiler args to change these options. The )library system command was not called after compilation.
)show T
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
T is not the name of a known type constructor. If you want to see information about any operations named T ,issue )display operations T
)show S
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
S is not the name of a known type constructor. If you want to see information about any operations named S ,issue )display operations S
)show P
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
P is not the name of a known type constructor. If you want to see information about any operations named P ,issue )display operations P
)show TO
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
TO is not the name of a known type constructor. If you want to see information about any operations named TO ,issue )display operations TO )show CC
)show MAPS
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
MAPS is not the name of a known type constructor. If you want to see information about any operations named MAPS ,issue )display operations MAPS
)show INTS
The )show system command is used to display information about types or partial types. For example,)show Integer will show information about Integer .
INTS is not the name of a known type constructor. If you want to see information about any operations named INTS ,issue )display operations INTS
sincos(x::Expression Integer)
There are no exposed library operations named sincos but there is one unexposed operation with that name. Use HyperDoc Browse or issue )display op sincos to learn more about the available operation.
Cannot find a definition or applicable library operation named sincos with argument type(s) Expression(Integer)
Perhaps you should use "@" to indicate the required return type,or "$" to specify which version of the function you need.
Null(1)
There are no library operations named Null Use HyperDoc Browse or issue )what op Null to learn if there is any operation containing " Null " in its name.
Cannot find a definition or applicable library operation named Null with argument type(s) PositiveInteger
Perhaps you should use "@" to indicate the required return type,or "$" to specify which version of the function you need.