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Example 6 with IndexExpressions

use of com.sri.ai.grinder.library.indexexpression.IndexExpressions in project aic-expresso by aic-sri-international.

the class DefaultIntensionalBound method boundProduct.

public static DefaultIntensionalBound boundProduct(Theory theory, Context context, Bound... listOfBounds) {
    if (listOfBounds.length == 0) {
        DefaultIntensionalBound result = new DefaultIntensionalBound();
        return result;
    }
    Set<Expression> alreadyDefined = Util.set();
    alreadyDefined.addAll(context.getSymbols());
    Predicate<Expression> isAlreadyDefined = e -> alreadyDefined.contains(e);
    ArrayList<Expression> productIndexExpressionList = new ArrayList<>();
    Object[] productHeadArray = new Expression[listOfBounds.length];
    Object[] productConditionArray = new Expression[listOfBounds.length];
    int k = 0;
    for (Bound bound : Arrays.asList(listOfBounds)) {
        if (!bound.isIntensionalBound()) {
            return null;
        }
        DefaultIntensionalBound intensionalBound = (DefaultIntensionalBound) bound;
        ExtensionalIndexExpressionsSet indexExpressions = (ExtensionalIndexExpressionsSet) intensionalBound.getIndexExpressions();
        Expression Head = intensionalBound.getHead();
        Expression condition = intensionalBound.getCondition();
        ArrayList<Expression> newIndexExpressionsList = new ArrayList<>(indexExpressions.getList());
        for (int i = 0; i != newIndexExpressionsList.size(); i++) {
            Expression indexExpression = newIndexExpressionsList.get(i);
            Symbol index = (Symbol) indexExpression.get(0);
            Expression type = indexExpression.get(1);
            PairOf<Expression> newIndexAndNewExpressionInScope = Expressions.standardizeApart(index, isAlreadyDefined, Head);
            Expression newIndex = newIndexAndNewExpressionInScope.first;
            Head = newIndexAndNewExpressionInScope.second;
            // type should not contain the index
            Expression newIndexExpression = apply(IN, newIndex, type);
            context = context.extendWithSymbolsAndTypes(newIndex, type);
            newIndexExpressionsList.set(i, newIndexExpression);
            alreadyDefined.add(newIndex);
            for (int j = i + 1; j != newIndexExpressionsList.size(); j++) {
                Expression anotherIndexExpression = newIndexExpressionsList.get(j);
                Expression anotherIndex = anotherIndexExpression.get(0);
                Expression anotherType = anotherIndexExpression.get(1);
                Expression newAnotherType = anotherType.replaceSymbol(index, newIndex, context);
                // anotherIndex is a symbols and does not contain index
                Expression newAnotherIndexExpression = apply(IN, anotherIndex, newAnotherType);
                newIndexExpressionsList.set(j, newAnotherIndexExpression);
            }
        }
        productIndexExpressionList.addAll(newIndexExpressionsList);
        productHeadArray[k] = Head;
        productConditionArray[k] = condition;
        k++;
    }
    Expression productCondition = apply(AND, productConditionArray);
    productCondition = theory.evaluate(productCondition, context);
    Expression productHead = apply(TIMES, productHeadArray);
    productHead = theory.evaluate(productHead, context);
    DefaultIntensionalBound result = new DefaultIntensionalBound(productIndexExpressionList, productHead, productCondition);
    return result;
}
Also used : Arrays(java.util.Arrays) Model(com.sri.ai.grinder.anytime.Model) Expressions(com.sri.ai.expresso.helper.Expressions) PairOf(com.sri.ai.util.base.PairOf) SUM(com.sri.ai.grinder.library.FunctorConstants.SUM) Expression(com.sri.ai.expresso.api.Expression) ArrayList(java.util.ArrayList) EQUAL(com.sri.ai.grinder.library.FunctorConstants.EQUAL) ExtensionalIndexExpressionsSet(com.sri.ai.expresso.core.ExtensionalIndexExpressionsSet) Symbol(com.sri.ai.expresso.api.Symbol) Expressions.apply(com.sri.ai.expresso.helper.Expressions.apply) IN(com.sri.ai.grinder.library.FunctorConstants.IN) IndexExpressions(com.sri.ai.grinder.library.indexexpression.IndexExpressions) IndexExpressionsSet(com.sri.ai.expresso.api.IndexExpressionsSet) AND(com.sri.ai.grinder.library.FunctorConstants.AND) Context(com.sri.ai.grinder.api.Context) DefaultExtensionalUniSet(com.sri.ai.expresso.core.DefaultExtensionalUniSet) Set(java.util.Set) IntensionalSet(com.sri.ai.expresso.api.IntensionalSet) IF_THEN_ELSE(com.sri.ai.grinder.library.FunctorConstants.IF_THEN_ELSE) List(java.util.List) Theory(com.sri.ai.grinder.api.Theory) Expressions.makeSymbol(com.sri.ai.expresso.helper.Expressions.makeSymbol) Predicate(com.google.common.base.Predicate) GrinderUtil.getIndexExpressionsOfFreeVariablesIn(com.sri.ai.grinder.helper.GrinderUtil.getIndexExpressionsOfFreeVariablesIn) Util(com.sri.ai.util.Util) TIMES(com.sri.ai.grinder.library.FunctorConstants.TIMES) Symbol(com.sri.ai.expresso.api.Symbol) Expressions.makeSymbol(com.sri.ai.expresso.helper.Expressions.makeSymbol) ArrayList(java.util.ArrayList) ExtensionalIndexExpressionsSet(com.sri.ai.expresso.core.ExtensionalIndexExpressionsSet) Expression(com.sri.ai.expresso.api.Expression)

Example 7 with IndexExpressions

use of com.sri.ai.grinder.library.indexexpression.IndexExpressions in project aic-expresso by aic-sri-international.

the class GrinderUtil method getTypeExpressionOfExpression.

/**
 * Returns the type of given expression according to registry.
 */
public static Expression getTypeExpressionOfExpression(Expression expression, Registry registry) {
    Expression result;
    if (FormulaUtil.isApplicationOfBooleanConnective(expression)) {
        result = makeSymbol("Boolean");
    } else if (expression.getSyntacticFormType().equals(FunctionApplication.SYNTACTIC_FORM_TYPE) && list(SUM, PRODUCT, MAX).contains(expression.getFunctor().toString())) {
        Expression argument = expression.get(0);
        if (argument.getSyntacticFormType().equals(IntensionalSet.SYNTACTIC_FORM_TYPE)) {
            IntensionalSet intensionalSetArgument = (IntensionalSet) argument;
            Expression head = intensionalSetArgument.getHead();
            // NOTE: Need to extend the registry as the index expressions in the quantifier may
            // declare new types (i.e. function types).
            Registry headRegistry = registry.extendWith(intensionalSetArgument.getIndexExpressions());
            result = getTypeExpressionOfExpression(head, headRegistry);
        } else if (argument.getSyntacticFormType().equals(ExtensionalSets.SYNTACTIC_FORM_TYPE)) {
            List<Expression> arguments = ((AbstractExtensionalSet) argument).getElementsDefinitions();
            result = getTypeOfCollectionOfNumericExpressionsWithDefaultInteger(arguments, registry);
        } else if (expression.hasFunctor(MAX)) {
            // MAX can also be applied to a bunch of numbers
            result = getTypeOfCollectionOfNumericExpressionsWithDefaultInteger(expression.getArguments(), registry);
        } else {
            throw new Error(expression.getFunctor() + " defined for sets only but got " + expression.get(0));
        }
    } else if (Equality.isEquality(expression) || Disequality.isDisequality(expression)) {
        result = makeSymbol("Boolean");
    } else if (expression.equals(FunctorConstants.REAL_INTERVAL_CLOSED_CLOSED) || expression.equals(FunctorConstants.REAL_INTERVAL_CLOSED_OPEN) || expression.equals(FunctorConstants.REAL_INTERVAL_OPEN_CLOSED) || expression.equals(FunctorConstants.REAL_INTERVAL_OPEN_OPEN)) {
        result = FunctionType.make(parse("Set"), parse("Number"), parse("Number"));
    } else if (IfThenElse.isIfThenElse(expression)) {
        Expression thenType = getTypeExpressionOfExpression(IfThenElse.thenBranch(expression), registry);
        Expression elseType = getTypeExpressionOfExpression(IfThenElse.elseBranch(expression), registry);
        if (thenType != null && elseType != null && (thenType.equals("Number") && isIntegerOrReal(elseType) || isIntegerOrReal(thenType) && elseType.equals("Number"))) {
            result = makeSymbol("Number");
        } else if (thenType != null && elseType != null && (thenType.equals("Integer") && elseType.equals("Real") || thenType.equals("Real") && elseType.equals("Integer"))) {
            result = makeSymbol("Real");
        } else if (thenType != null && (elseType == null || thenType.equals(elseType))) {
            result = thenType;
        } else if (elseType != null && (thenType == null || elseType.equals(thenType))) {
            result = elseType;
        } else if (thenType == null) {
            throw new Error("Could not determine the types of then and else branches of '" + expression + "'.");
        } else if (thenType.equals("Integer") && elseType.hasFunctor(INTEGER_INTERVAL)) {
            // TODO: I know, I know, this treatment of integers and interval is terrible... will fix at some point
            result = thenType;
        } else if (thenType.hasFunctor(INTEGER_INTERVAL) && elseType.equals("Integer")) {
            result = elseType;
        } else if (thenType.hasFunctor(INTEGER_INTERVAL) && elseType.hasFunctor(INTEGER_INTERVAL)) {
            IntegerInterval thenInterval = (IntegerInterval) thenType;
            IntegerInterval elseInterval = (IntegerInterval) elseType;
            Expression minimumLowerBound = LessThan.simplify(apply(LESS_THAN, thenInterval.getNonStrictLowerBound(), elseInterval.getNonStrictLowerBound()), registry).booleanValue() ? thenInterval.getNonStrictLowerBound() : elseInterval.getNonStrictLowerBound();
            Expression maximumUpperBound = GreaterThan.simplify(apply(GREATER_THAN, thenInterval.getNonStrictUpperBound(), elseInterval.getNonStrictUpperBound()), registry).booleanValue() ? thenInterval.getNonStrictUpperBound() : elseInterval.getNonStrictUpperBound();
            if (minimumLowerBound.equals(MINUS_INFINITY) && maximumUpperBound.equals(INFINITY)) {
                result = makeSymbol("Integer");
            } else {
                result = apply(INTEGER_INTERVAL, minimumLowerBound, maximumUpperBound);
            }
        } else {
            throw new Error("'" + expression + "' then and else branches have different types (" + thenType + " and " + elseType + " respectively).");
        }
    } else if (isCardinalityExpression(expression)) {
        result = makeSymbol("Integer");
    } else if (isNumericFunctionApplication(expression)) {
        List<Expression> argumentTypes = mapIntoList(expression.getArguments(), e -> getTypeExpressionOfExpression(e, registry));
        int firstNullArgumentTypeIndexIfAny = Util.getIndexOfFirstSatisfyingPredicateOrMinusOne(argumentTypes, t -> t == null);
        if (firstNullArgumentTypeIndexIfAny != -1) {
            throw new Error("Cannot determine type of " + expression.getArguments().get(firstNullArgumentTypeIndexIfAny) + ", which is needed for determining type of " + expression);
        }
        /**
         * commonDomain is the co-domain shared by all argument function types, or empty tuple for arguments that are not function-typed.
         * Therefore, if no argument is function-typed, it will be equal to the empty tuple.
         */
        Expression commonDomain = getCommonDomainIncludingConversionOfNonFunctionTypesToNullaryFunctions(argumentTypes, registry);
        if (commonDomain == null) {
            throw new Error("Operator " + expression.getFunctor() + " applied to arguments of non-compatible types: " + expression + ", types of arguments are " + argumentTypes);
        }
        boolean noArgumentIsFunctionTyped = commonDomain.equals(EMPTY_TUPLE) && !thereExists(argumentTypes, t -> t.hasFunctor(FunctorConstants.FUNCTION_TYPE));
        Expression resultCoDomain;
        if (thereExists(argumentTypes, t -> Util.equals(getCoDomainOrItself(t), "Number"))) {
            resultCoDomain = makeSymbol("Number");
        } else if (thereExists(argumentTypes, t -> Util.equals(getCoDomainOrItself(t), "Real"))) {
            resultCoDomain = makeSymbol("Real");
        } else if (thereExists(argumentTypes, t -> isRealInterval(getCoDomainOrItself(t)))) {
            resultCoDomain = makeSymbol("Real");
        } else {
            resultCoDomain = makeSymbol("Integer");
        }
        if (noArgumentIsFunctionTyped) {
            result = resultCoDomain;
        } else {
            result = apply(FUNCTION_TYPE, commonDomain, resultCoDomain);
        }
    } else if (expression.hasFunctor(FunctorConstants.INTEGER_INTERVAL) || expression.hasFunctor(FunctorConstants.REAL_INTERVAL_CLOSED_CLOSED) || expression.hasFunctor(FunctorConstants.REAL_INTERVAL_OPEN_CLOSED) || expression.hasFunctor(FunctorConstants.REAL_INTERVAL_CLOSED_OPEN) || expression.hasFunctor(FunctorConstants.REAL_INTERVAL_OPEN_OPEN)) {
        result = makeSymbol("Set");
    } else if (isComparisonFunctionApplication(expression)) {
        result = makeSymbol("Boolean");
    } else if (expression.hasFunctor(FunctorConstants.FUNCTION_TYPE)) {
        // very vague type for now
        result = apply(FUNCTION_TYPE, makeSymbol("Set"), makeSymbol("Set"));
    } else if (Sets.isIntensionalMultiSet(expression)) {
        IntensionalSet set = (IntensionalSet) expression;
        // NOTE: Need to extend the registry as the index expressions in the quantifier may
        // declare new types (i.e. function types).
        Registry headRegistry = registry.extendWith(set.getIndexExpressions());
        Expression headType = getTypeExpressionOfExpression(set.getHead(), headRegistry);
        result = new DefaultIntensionalMultiSet(list(), headType, TRUE);
    } else if (Sets.isExtensionalSet(expression)) {
        // very vague type for now
        result = apply(FUNCTION_TYPE, makeSymbol("Set"));
    } else if (expression.hasFunctor(FunctorConstants.INTERSECTION) || expression.hasFunctor(FunctorConstants.UNION) || expression.hasFunctor(FunctorConstants.INTENSIONAL_UNION)) {
        // very vague type for now
        result = apply(FUNCTION_TYPE, makeSymbol("Set"));
    } else if (expression.getSyntacticFormType().equals(Symbol.SYNTACTIC_FORM_TYPE)) {
        if (expression.getValue() instanceof Integer) {
            result = makeSymbol("Integer");
        } else if (expression.getValue() instanceof Double) {
            result = makeSymbol("Real");
        } else if (expression.getValue() instanceof Rational) {
            Rational rational = (Rational) expression.getValue();
            boolean isInteger = rational.isInteger();
            result = makeSymbol(isInteger ? "Integer" : "Real");
        } else if (expression.getValue() instanceof Number) {
            result = makeSymbol("Number");
        } else if (expression.getValue() instanceof String && expression.isStringLiteral()) {
            result = makeSymbol("String");
        } else if (expression.getValue() instanceof Boolean) {
            result = makeSymbol("Boolean");
        } else if (expression.equals(Expressions.INFINITY) || expression.equals(Expressions.MINUS_INFINITY)) {
            result = makeSymbol("Number");
        } else {
            result = registry.getTypeExpressionOfRegisteredSymbol(expression);
            if (result == null) {
                Type type = getFirstSatisfyingPredicateOrNull(registry.getTypes(), t -> t.contains(expression));
                if (type != null) {
                    result = parse(type.getName());
                }
            }
        }
    } else if (expression.hasFunctor(FunctorConstants.GET) && expression.numberOfArguments() == 2 && Expressions.isNumber(expression.get(1))) {
        Expression argType = getTypeExpressionOfExpression(expression.get(0), registry);
        if (TupleType.isTupleType(argType)) {
            TupleType tupleType = (TupleType) GrinderUtil.fromTypeExpressionToItsIntrinsicMeaning(argType, registry);
            result = parse(tupleType.getElementTypes().get(expression.get(1).intValue() - 1).toString());
        } else {
            throw new Error("get type from tuple for '" + expression + "' currently not supported.");
        }
    } else if (expression.hasFunctor(FunctorConstants.TUPLE_TYPE)) {
        // Is a type expression already.
        result = expression;
    } else if (expression.getSyntacticFormType().equals(FunctionApplication.SYNTACTIC_FORM_TYPE)) {
        Expression functionType = getTypeExpressionOfExpression(expression.getFunctor(), registry);
        if (functionType == null) {
            throw new Error("Type of '" + expression.getFunctor() + "' required but unknown.");
        }
        Expression coDomain = FunctionType.getCodomain(functionType);
        List<Expression> argumentsTypesList = FunctionType.getArgumentList(functionType);
        if (expression.getArguments().size() != argumentsTypesList.size()) {
            throw new Error("Function " + expression.getFunctor() + " is of type " + functionType + " but has incorrect number of arguments = " + expression.getArguments());
        }
        for (int idx = 0; idx < expression.getArguments().size(); idx++) {
            Expression arg = expression.get(idx);
            Expression argExprType = argumentsTypesList.get(idx);
            Type argType = registry.getTypeFromTypeExpression(argExprType);
            if (!isSubtypeOf(arg, argType, registry)) {
                throw new Error("Function " + expression.getFunctor() + " is of type " + functionType + " but has arguments that are not legal subtypes [#" + idx + "] = " + expression.getArguments());
            }
        }
        result = coDomain;
    } else if (Tuple.isTuple(expression)) {
        List<Expression> elementTypes = expression.getArguments().stream().map(element -> getTypeExpressionOfExpression(element, registry)).collect(Collectors.toList());
        result = TupleType.make(elementTypes);
    } else if (expression instanceof QuantifiedExpressionWithABody) {
        QuantifiedExpressionWithABody quantifiedExpressionWithABody = (QuantifiedExpressionWithABody) expression;
        // NOTE: Need to extend the registry as the index expressions in the quantifier may
        // declare new types (i.e. function types).
        Registry quantifiedExpressionWithABodyRegistry = registry.extendWith(quantifiedExpressionWithABody.getIndexExpressions());
        result = getTypeExpressionOfExpression(quantifiedExpressionWithABody.getBody(), quantifiedExpressionWithABodyRegistry);
    } else if (expression instanceof LambdaExpression) {
        LambdaExpression lambdaExpression = (LambdaExpression) expression;
        Collection<Expression> domain = IndexExpressions.getIndexDomainsOfQuantifiedExpression(lambdaExpression);
        IndexExpressionsSet indexExpressions = lambdaExpression.getIndexExpressions();
        Registry lambdaExpressionWithABodyRegistry = registry.extendWith(indexExpressions);
        Expression coDomain = getTypeExpressionOfExpression(lambdaExpression.getBody(), lambdaExpressionWithABodyRegistry);
        result = Expressions.apply(FUNCTION_TYPE, domain, coDomain);
    } else if (expression instanceof AbstractExpressionWrapper) {
        Expression innerExpression = ((AbstractExpressionWrapper) expression).getInnerExpression();
        result = getTypeExpressionOfExpression(innerExpression, registry);
    } else {
        throw new Error("GrinderUtil.getType does not yet know how to determine the type of this sort of expression: " + expression);
    }
    return result;
}
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Example 8 with IndexExpressions

use of com.sri.ai.grinder.library.indexexpression.IndexExpressions in project aic-expresso by aic-sri-international.

the class Expressions method makeDefaultUniversallyQuantifiedFormulaFromLabelAndSubTrees.

private static Expression makeDefaultUniversallyQuantifiedFormulaFromLabelAndSubTrees(Object label, Object[] subTreeObjects) {
    ArrayList<Expression> subTreeExpressions = Util.mapIntoArrayList(subTreeObjects, Expressions::makeFromObject);
    Expression indexExpressionsKleeneList = subTreeExpressions.get(0);
    IndexExpressionsSet indexExpressions = new ExtensionalIndexExpressionsSet(ensureListFromKleeneList(indexExpressionsKleeneList));
    Expression body = subTreeExpressions.get(1);
    Expression result = new DefaultUniversallyQuantifiedFormula(indexExpressions, body);
    return result;
}
Also used : ExtensionalIndexExpressionsSet(com.sri.ai.expresso.core.ExtensionalIndexExpressionsSet) DefaultUniversallyQuantifiedFormula(com.sri.ai.expresso.core.DefaultUniversallyQuantifiedFormula) DefaultLambdaExpression(com.sri.ai.expresso.core.DefaultLambdaExpression) Expression(com.sri.ai.expresso.api.Expression) LambdaExpression(com.sri.ai.expresso.api.LambdaExpression) IndexExpressions(com.sri.ai.grinder.library.indexexpression.IndexExpressions) ExtensionalIndexExpressionsSet(com.sri.ai.expresso.core.ExtensionalIndexExpressionsSet) IndexExpressionsSet(com.sri.ai.expresso.api.IndexExpressionsSet)

Aggregations

Expression (com.sri.ai.expresso.api.Expression)8 IndexExpressionsSet (com.sri.ai.expresso.api.IndexExpressionsSet)8 ExtensionalIndexExpressionsSet (com.sri.ai.expresso.core.ExtensionalIndexExpressionsSet)8 IndexExpressions (com.sri.ai.grinder.library.indexexpression.IndexExpressions)8 LambdaExpression (com.sri.ai.expresso.api.LambdaExpression)7 DefaultLambdaExpression (com.sri.ai.expresso.core.DefaultLambdaExpression)6 ArrayList (java.util.ArrayList)3 Predicate (com.google.common.base.Predicate)2 IntensionalSet (com.sri.ai.expresso.api.IntensionalSet)2 Symbol (com.sri.ai.expresso.api.Symbol)2 DefaultIntensionalMultiSet (com.sri.ai.expresso.core.DefaultIntensionalMultiSet)2 DefaultUniversallyQuantifiedFormula (com.sri.ai.expresso.core.DefaultUniversallyQuantifiedFormula)2 Expressions (com.sri.ai.expresso.helper.Expressions)2 Expressions.apply (com.sri.ai.expresso.helper.Expressions.apply)2 Expressions.makeSymbol (com.sri.ai.expresso.helper.Expressions.makeSymbol)2 Context (com.sri.ai.grinder.api.Context)2 Theory (com.sri.ai.grinder.api.Theory)2 Collection (java.util.Collection)2 Beta (com.google.common.annotations.Beta)1 Function (com.google.common.base.Function)1