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Dave Reed more Prolog test vs. find built-in predicates list operations: member, append, nth0, reverse, not, default vs. logical negation comparison operators ... – PowerPoint PPT presentation

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Title: logic


1
Dave Reed
  • more Prolog
  • test vs. find
  • built-in predicates
  • list operations member, append, nth0, reverse,
  • not, default vs. logical negation
  • comparison operators, arithmetic
  • user-defined operators
  • position, precedence, associativity

2
Test vs. find
  • Prolog programs define relations
  • query w/ constants "test" whether relation holds
    between the constants
  • query w/ variables "find" values for which the
    relation holds

?- member(X, a, b, c). X a X b X
c No ?- member(a, X). X a_G260 X
_G259,a_G262 Yes ?- member(X, Y). X
_G209 Y _G209_G270 X _G209 Y
_G275,_G209_G278 Yes
with a variable as first argument, the query is
used to "find" members of the given list with a
variable as the second argument, the query is
used to "find" lists that have the given item as
member with both variables, the query is used to
"find" general schemas for list membership
3
Append predicate
another useful predefined predicate for list
manipulation append(L1,L2,L3) L3 is the
result of placing the items in L1 at the front
of L2 can be used in reverse to partition a
list
?- append(a,b, c,d, L). L
a,b,c,d Yes ?- append(L1, L2,
a,b,c,d). L1 L2 a,b,c,d L1
a L2 b,c,d L1 a,b L2 c,d L1
a,b,c L2 d L1 a,b,c,d L2 No
  • again, we could define append ourselves
  • append(, L, L).
  • append(HT, L, HA) -
  • append(T, L, A).
  • as we saw with ancestor example,
  • clause ordering is important with
  • recursive definitions
  • if put rule first, infinite loop possible

4
Other list predicates
?- L a,b,c,d, length(L, Len), nth1(Len,
L, X). L a,b,c,d Len 4 X d Yes ?-
reverse(a,b,a,c, Rev), delete(Rev, a,
Del). Rev c,a,b,a Del c,b Yes ?-
select(a, a,b,a,c, R). R b,a,c R
a,b,c No ?- select(a, L, b,c). L
a,b,c L b,a,c L b,c,a No
is_list(Term) succeeds if Term is a
list length(List,Len) Len is the number of
items in List nth0(Index,List,Item) Item is the
item at index Index of List(starting at
0) nth1(Index,List,Item) Item is the item at
index Index of List(starting at
1) reverse(List,RevList) RevList is List with
the items in reverse order delete(List,Item,NewLi
st) NewList is the result of deleting every
occurrence of Item from List select(Item,List,Rem
ain) Remain is the List with an occurrence of
Item removed
5
not predicate
?- is_list(). Yes ?- not(is_list()). No ?-
member(d, a,b,c). No ?- not(member(d,
a,b,c)). Yes ?- member(X, a,b,c). X
a Yes ?- not(member(X, a,b,c)). No ?- X
d, not(member(X, a,b,c)). X d Yes ?-
not(member(X, a,b,c)), X d. No
  • not defines the (default) negation of conditional
    statements
  • when applied to relations with no variables, it
    is equivalent to logical negation (?)
  • in reality, it returns the opposite of whatever
    its argument would return
  • if X would succeed as a query, then not(X) fails
  • if X would fail as a query,
  • then not(X) succeeds
  • anything Prolog can't prove true it assumes to be
    false!

6
Programming exercises
  • suppose we want to define a relation to test if a
    list is palindromic
  • palindrome(List) succeeds if List is a list
    whose elements are the same backwards forwards

palindrome(). palindrome(List) - reverse(List,
Rev), List Rev.
suppose we want to define relation to see if a
list has duplicates has_dupes(List) succeeds
if List has at least one duplicate element
has_dupes(HT) - member(H, T). has_dupes(_T)
- has_dupes(T).
suppose we want the opposite relation, that a
list has no dupes no_dupes(List) succeeds if
List has no duplicate elements
no_dupes(List) - not( has_dupes(List) ).
7
Built-in comparison operators
  • X Y does more than test equality, it matches X
    with Y, instantiating variables if necessary
  • X \ Y determines whether X Y are not unifiable
  • for ground terms, this means inequality
  • can think of as not(X Y)
  • again, doesn't make a lot of sense for variables
  • Note arithmetic operators (, -, , /) are not
    evaluated
  • 4 2 ? (4, 2)
  • can force evaluation using 'is'
  • ?- X 4 2. ?- X is 4 2.

?- foo foo. Yes ?- X foo. X foo
Yes ?- HT a,b,c. H a T b,c
Yes ?- foo \ bar. Yes ?- X \ foo. No ?-
42 6. No
8
Arithmetic operations
  • arithmetic comparisons automatically evaluate
    expressions
  • X Y X and Y must both be arithmetic
    expressions (no variables)
  • X \ Y
  • X gt Y ?- 12 66.
  • X gt Y Yes
  • X lt Y
  • X lt Y ?- X 66.
  • ERROR Arguments are not sufficiently
    instantiated
  • Example
  • sum_of_list(ListOfNums, Sum) Sum is the sum of
    numbers in ListOfNums
  • sum_of_list(, 0).
  • sum_of_list(HT, Sum) -
  • sum_of_list(T,TailSum), Sum is H TailSum.

9
Programming exercise
suppose we want to define relation to see how
many times an item occurs in a list
num_occur(Item,List,N) Item occurs N times in
List
num_occur(_,,0). num_occur(H, HT, N) -
num_occur(H, T, TailN), N is TailN1. num_occur(H
, _T, N) - num_occur(H, T, TailN), N is
TailN.
is the first answer supplied by this relation
correct? are subsequent answers obtained via
backtracking correct?
10
User-defined operators
  • it is sometimes convenient to write
    functors/predicates as operators
  • predefined (2, 3) ? 2 3
  • user defined? likes(dave, cubs) ? dave likes
    cubs
  • operators have the following characteristics
  • position of appearance
  • prefix e.g., -3
  • infix e.g., 2 3
  • postfix e.g., 5!
  • precedence
  • 2 3 4 ? 2 (3 4)
  • associativity
  • 8 5 - 2 ? 8 (5 2)

11
op
  • new operators may be defined as follows
  • - op(Prec, PosAssoc, Name).
  • Name is a constant
  • Prec is an integer in range 0 1200 (lower
    number binds tighter)
  • PosAssoc is a constant of the form
  • xf, yf (postfix)
  • fx, fy (prefix)
  • xfx, xfy, yfx, yfy (infix)
  • the location of f denotes the operator position
  • x means only operators of lower precedence may
    appear here
  • y allows operators of lower or equal
    precedence
  • Example - op(300, xfx, likes).

12
Operator example
  • likes.pro
  • likes(dave, cubs).
  • likes(kelly, and(java,
  • and(scheme,prolog))).

likes.pro - op(300, xfx, likes). - op(250,
xfy, and). dave likes cubs. kelly likes java and
scheme and prolog.
?- likes(dave, X). X cubs Yes ?- likes(Who,
What). Who dave What cubs Who
kelly What and(java, and(scheme,prolog)) No
?- dave likes X. X cubs Yes ?- Who likes
What. Who dave What cubs Who kelly What
java and scheme and prolog No
by defining functors/predicates as operators, can
make code more English-like
13
SWI-Prolog operators
1200 xfx --gt, -
1200 fx -, ?-
1150 fx dynamic, multifile, module_transparent, discontiguous, volatile, initialization
1100 xfy ,
1050 xfy -gt
1000 xfy ,
954 xfy \
900 fy \
900 fx
700 xfx lt, , .., _at_, , lt, , \, gt, gt, _at_lt, _at_lt, _at_gt, _at_gt, \, \, is
600 xfy
500 yfx , -, /\, \/, xor
500 fx , -, ?, \
400 yfx , /, //, ltlt, gtgt, mod, rem
200 xfx
200 xfy
  • the following standard operators are predefined
    in SWI-Prolog
  • to define new operators
  • Name Type are easy
  • Precedence is tricky, must determine place in
    hierarchy
  • Note always define ops at top of the program
    (before use)

14
IQ Test choose the most likely answer by analogy
Question 1
Question 3
Question 2
15
Analogy reasoner
  • want to write a Prolog program for reasoning by
    analogy (Evans, 1968)
  • need to decide on a representation of pictures
  • constants small, large, triangle, square,
    circle
  • functor/operator sized
  • sized(small, triangle) OR small sized triangle
  • sized(large, square) OR large sized square
  • functors inside, above
  • inside(small sized circle, large sized square).
  • above(large sized triangle, small sized square).
  • need to represent questions as well
  • operators is_to, as (bind looser than sized, so
    higher prec )
  • predicate question
  • question(Name, F1 is_to F2 as F3 is_to
    A1,A2,A3).

16
IQ test questions
- op(200, xfy, is_to). - op(200, xfy, as). -
op(180, xfy, sized). question(q1,
inside(small sized square, large sized triangle)
is_to inside(small sized triangle, large
sized square) as inside(small sized
circle, large sized square) is_to
inside(small sized circle, large sized
triangle), inside(small sized square,
large sized circle), inside(small sized
triangle, large sized square)). question(q2,
inside(small sized circle, large sized
square) is_to inside(small sized square,
large sized circle) as above(small sized
triangle, large sized triangle) is_to
above(small sized circle, large sized circle),
inside(small sized triangle, large sized
triangle), above(large sized triangle,
small sized triangle)). question(q3,
above(small sized square, large sized circle)
is_to above(large sized square, small
sized circle) as above(small sized
circle, large sized triangle) is_to
above(large sized circle, small sized
triangle), inside(small sized circle,
large sized triangle), above(large
sized triangle, small sized square)).
17
Analogy transformations
  • also need to represent transformations
  • predicate transform
  • transform(Name, F1 is_to F2).

transform(invertPosition, inside(small
sized Figure1, large sized Figure2) is_to
inside(small sized Figure2, large sized
Figure1)). transform(invertPosition,
above(Size1 sized Figure1, Size2 sized Figure2)
is_to above(Size2 sized Figure2, Size1
sized Figure1)). transform(invertSizes,
inside(small sized Figure1, large sized Figure2)
is_to inside(small sized Figure2, large
sized Figure1)). transform(invertSizes,
above(Size1 sized Figure1, Size2 sized Figure2)
is_to above(Size2 sized Figure1, Size1
sized Figure2)).
Note different but related transformations can
have the same name
18
Analogy reasoner
  • to find an answer
  • look up the question based on its name
  • find a transformation that takes F1 to F2
  • apply that rule to F3 to obtain a potential
    solution
  • test to see if that solution is among the answers
    to choose from


analogy.pro Dave Reed
1/23/02 A program based on Evans' analogy
reasoner.
- op(200, xfy, is_to). - op(200,
xfy, as). - op(180, xfy, sized). analogy(Questi
on, Solution) - question(Question, F1 is_to F2
as F3 is_to Answers), transform(Rule, F1 is_to
F2), transform(Rule, F3 is_to Solution),
member(Solution, Answers). questions (as
before) transformations (as before)
19
Analogy reasoner
?- analogy(q1, Answer). Answer inside(small
sized square, large sized circle) Answer
inside(small sized square, large sized circle)
No ?- analogy(q2, Answer). Answer
above(large sized triangle, small sized triangle)
Answer above(large sized triangle, small
sized triangle) No ?- analogy(q3,
Answer). Answer above(large sized circle,
small sized triangle) No
Note Questions 1 2 yield the same answer
twice. WHY? Is it possible for a questions to
have different answers?
20
Handling ambiguities
Question 4
  • it is possible for 2 different transformations to
    produce different answers
  • must either
  • refine the transformations (difficult)
  • use heuristics to pick most likely answer
    (approach taken by Green)

?- analogy(q4, Answer). Answer above(small
sized triangle, large sized circle) Answer
above(small sized circle, large sized triangle)
No
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