ProB's Prolog Datastructures: Difference between revisions

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Sets
Sets
Here is an overview of the set representations:
  []
  []
  [Val|Set]
  [Val|Set]
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  global_set(GS)
  global_set(GS)
  freetype(T)
  freetype(T)
The empty set is encoded as the empty list.
[]
This represents a set containing at least the value Val and the rest:
[Val|Set]
Note that Set can in principle be any other form (e.g., avl_set(.)).
The predicate <tt>expand_custom_set_to_list</tt> can be used to transform a set into a form using only the empty list and the <tt>[.|.]</tt> functor.
The next are called custom explicit sets, they always represent a fully known set.
A set can be represented by a non-empty AVL tree:
avl_set(AVL)
Given a list of parameter identifiers, a list of types and a predicate AST B, we can represent the set {P| P:T & B} as follows:
closure(P,T,B)
There are custom representations for complete types, these may be phased out in the future and replaced by the closure(.,.,.) representation:
global_set(GS)
freetype(T)


Freetype values
Freetype values

Revision as of 12:20, 12 January 2018

Data Values

Integer value:

int(Nr)

where Nr is an integer

Booleans:

pred_true
pred_false

Enumerated or deferred set elements:

fd(Nr,Type)

where Nr is an integer >= 1 and Type is an atom representing the type of enumerated/deferred set

Strings

string(S)

where S is an atom

Pairs/couples

(Val1,Val2)

where Val1 and Val2 are values


Records

rec(Fields)

where Fields is a list of terms:

field(Name,Val)

where Name is atom representing the field name and Val is a value.

The fields are sorted by name!

Sets Here is an overview of the set representations:

[]
[Val|Set]
avl_set(AVL)
closure(P,T,B)
global_set(GS)
freetype(T)

The empty set is encoded as the empty list.

[]

This represents a set containing at least the value Val and the rest:

[Val|Set]

Note that Set can in principle be any other form (e.g., avl_set(.)). The predicate expand_custom_set_to_list can be used to transform a set into a form using only the empty list and the [.|.] functor.

The next are called custom explicit sets, they always represent a fully known set.

A set can be represented by a non-empty AVL tree:

avl_set(AVL)

Given a list of parameter identifiers, a list of types and a predicate AST B, we can represent the set {P| P:T & B} as follows:

closure(P,T,B)

There are custom representations for complete types, these may be phased out in the future and replaced by the closure(.,.,.) representation:

global_set(GS)
freetype(T)


Freetype values

freeval(Id,Case,Value)

AST (Abstract Syntax Tree)

An AST node has the form:

b(Expr,Type,Infos)

Expr generally has the form Functor(AST1,...,ASTk). Below we list possible cases. The predicate syntaxelement in bsyntaxtree.pl lists all allowed forms of Expr. Type is either pred for predicates, subst for substitutions or the value type for expressions, see below. Infos contains information about the AST node and is explained next.

Information list

Infos should be a ground list of informations. Some important information fields are:

contains_wd_condition
used_ids(Ids)
nodeid(PositionInfo)
refers_to_old_state(References)

AST types

Possible types are:

pred
subst
integer
boolean
string
global(G)
couple(Type1,Type2)
record(FieldTypes)
set(Type)
seq(Type)
freetype(F)

where FieldTypes is a list containing:

field(Name,Type)

Operators without arguments

boolean_false
boolean_true
bool_set

...

Unary operators

card(AST)
domain(AST)
front(AST)

...

Binary operators

cartesian_product(AST1,AST2)
composition(AST1,AST2)
concat(AST1,AST2)
conjunct(AST1,AST2)

...

Special operators

general_sum(Ids,AST,AST)
general_product(Ids,AST,AST)
lambda(Ids,AST,AST)
quantified_union(Ids,AST,AST)
quantified_intersection(Ids,AST,AST)
set_extension(ListOfASTs)
sequence_extension(ListOfASTs)

...