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/*******************************************************************************
 * Copyright (c) 2013, 2014 GK Software AG, and others.
 * All rights reserved. This program and the accompanying materials
 * are made available under the terms of the Eclipse Public License v1.0
 * which accompanies this distribution, and is available at
 * http://www.eclipse.org/legal/epl-v10.html
 *
 * Contributors:
 *     Stephan Herrmann - initial API and implementation
 *     IBM Corporation - Bug fixes
 *******************************************************************************/
package org.eclipse.jdt.internal.compiler.lookup;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Comparator;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Set;

import org.eclipse.jdt.core.compiler.CharOperation;
import org.eclipse.jdt.internal.compiler.ast.ASTNode;
import org.eclipse.jdt.internal.compiler.ast.ConditionalExpression;
import org.eclipse.jdt.internal.compiler.ast.Expression;
import org.eclipse.jdt.internal.compiler.ast.FunctionalExpression;
import org.eclipse.jdt.internal.compiler.ast.Invocation;
import org.eclipse.jdt.internal.compiler.ast.LambdaExpression;
import org.eclipse.jdt.internal.compiler.ast.MessageSend;
import org.eclipse.jdt.internal.compiler.ast.NullAnnotationMatching;
import org.eclipse.jdt.internal.compiler.ast.ReferenceExpression;
import org.eclipse.jdt.internal.compiler.ast.Statement;
import org.eclipse.jdt.internal.compiler.ast.Wildcard;
import org.eclipse.jdt.internal.compiler.util.Sorting;

/**
 * Main class for new type inference as per JLS8 sect 18.
 * Keeps contextual state and drives the algorithm.
 * 
 * 

Inference Basics

*
    *
  • 18.1.1 Inference variables: {@link InferenceVariable}
  • *
  • 18.1.2 Constraint Formulas: subclasses of {@link ConstraintFormula}
  • *
  • 18.1.3 Bounds: {@link TypeBound}
    * Capture bounds are directly captured in {@link BoundSet#captures}, throws-bounds in {@link BoundSet#inThrows}.
    * Also: {@link BoundSet}: main state during inference.
  • *
* Each instance of {@link InferenceContext18} manages instances of the above and coordinates the inference process. *

Queries and utilities

*
    *
  • {@link TypeBinding#isProperType(boolean)}: * used to exclude "types" that mention inference variables (18.1.1).
  • *
  • {@link TypeBinding#mentionsAny(TypeBinding[], int)}: * does the receiver type binding mention any of the given types?
  • *
  • {@link TypeBinding#substituteInferenceVariable(InferenceVariable, TypeBinding)}: * replace occurrences of an inference variable with a proper type.
  • *
  • {@link TypeBinding#collectInferenceVariables(Set)}: * collect all inference variables mentioned in the receiver type into the given set.
  • *
  • {@link TypeVariableBinding#getTypeBounds(InferenceVariable, InferenceSubstitution)}: * Compute the initial type bounds for one inference variable as per JLS8 sect 18.1.3.
  • *
*

Phases of Inference

*
    *
  • 18.2 Reduction: {@link #reduce()} with most work happening in implementations of * {@link ConstraintFormula#reduce(InferenceContext18)}: *
      *
    • 18.2.1 Expression Compatibility Constraints: {@link ConstraintExpressionFormula#reduce(InferenceContext18)}.
    • *
    • 18.2.2 Type Compatibility Constraints ff. {@link ConstraintTypeFormula#reduce(InferenceContext18)}.
    • *
  • *
  • 18.3 Incorporation: {@link BoundSet#incorporate(InferenceContext18)}; during inference new constraints * are accepted via {@link BoundSet#reduceOneConstraint(InferenceContext18, ConstraintFormula)} (combining 18.2 & 18.3)
  • *
  • 18.4 Resolution: {@link #resolve(InferenceVariable[])}. *
* Some of the above operations accumulate their results into {@link #currentBounds}, whereas * the last phase returns the resulting bound set while keeping the previous state in {@link #currentBounds}. *

18.5. Uses of Inference

* These are the main entries from the compiler into the inference engine: *
*
18.5.1 Invocation Applicability Inference
*
{@link #inferInvocationApplicability(MethodBinding, TypeBinding[], boolean)}. Prepare the initial state for * inference of a generic invocation - no target type used at this point. * Need to call {@link #solve()} afterwards to produce the intermediate result.
* Called indirectly from {@link Scope#findMethod(ReferenceBinding, char[], TypeBinding[], InvocationSite, boolean)} et al * to select applicable methods into overload resolution.
*
18.5.2 Invocation Type Inference
*
{@link InferenceContext18#inferInvocationType(BoundSet, TypeBinding, InvocationSite, MethodBinding)}. After a * most specific method has been picked, and given a target type determine the final generic instantiation. * As long as a target type is still unavailable this phase keeps getting deferred.
* Different wrappers exist for the convenience of different callers.
*
18.5.3 Functional Interface Parameterization Inference
*
Controlled from {@link LambdaExpression#resolveType(BlockScope)}.
*
18.5.4 More Specific Method Inference
*
Not Yet Implemented
*
* For 18.5.1 and 18.5.2 some high-level control is implemented in * {@link ParameterizedGenericMethodBinding#computeCompatibleMethod(MethodBinding, TypeBinding[], Scope, InvocationSite, int)}. *

Inference Lifecycle

* The separation into 18.5.1 and 18.5.2 causes some complexity: *
    *
  • Calling both parts of inference is directly interwoven with overload resolution. See * {@link ParameterizedGenericMethodBinding#computeCompatibleMethod(MethodBinding, TypeBinding[], Scope, InvocationSite, int) * PGMB#computeCompatibleMethod()} for the basic protocol.
  • *
  • Intermediate state regarding inference must be stored between both phases. Inference is performed with different * inputs for each pair of {@link Invocation} x {@link ParameterizedGenericMethodBinding}, * see {@link Invocation#registerInferenceContext(ParameterizedGenericMethodBinding, InferenceContext18) Invocation.registerInferenceContext()} and * {@link Invocation#getInferenceContext(ParameterizedMethodBinding) getInferenceContext()}.
    * As part of the lifecycle state, each instance of InferenceContext18 remembers the current {@link #inferenceKind} * and {@link #stepCompleted}.
  • *
  • Nested inference/resolving: If an invocation argument is a poly expression itself, final resolving of the argument can only happened * after Invocation Type Inference regarding the outer invocation. Outer inference must produce the target type that drives * the inner inference / resolving. Two different protocols are applied: *
      *
    • If the inner poly expression is an invocation, inner inference is directly incorporated into * the {@link #currentBounds}, see block inside {@link ConstraintExpressionFormula#reduce(InferenceContext18)}.
      * In this case the results of the combined inference need to be applied to all contained inner invocations, * which happens in {@link #rebindInnerPolies(BoundSet, TypeBinding[])}, which must be called whenever * 18.5.2 finishes.
    • *
    • If the inner poly expression is a functional expression or a conditional expression no inference variables * exist representing the inner. In this case the final target type is pushed into the inner using * {@link Expression#checkAgainstFinalTargetType(TypeBinding, Scope)}, which, too, is called from * {@link #rebindInnerPolies(BoundSet, TypeBinding[])}.
    • *
    • For recursively pushing target types into arguments of an invocation * method {@link ASTNode#resolvePolyExpressionArguments(Invocation, MethodBinding, TypeBinding[], Scope)} exists, * which is called in two situations: (1) for non-generic outer invocations from MessageSend#findMethodBinding() and * Statement#findConstructorBinding(); (2) for generic outer invocations from {@link #rebindInnerPolies(BoundSet, TypeBinding[])}.
    • *
    • In some situations invocation arguments that are poly invocations need to be resolved in the middle of overload resolution * to answer {@link Scope#parameterCompatibilityLevel18} (where the outer invocation did not involve any inference).
      *
    * Pushing inference results into an inner invocation happens using {@link Invocation#updateBindings(MethodBinding,TypeBinding)}.
  • *
  • Decision whether or not an invocation is a variable-arity invocation is made by first attempting * to solve 18.5.1 in mode {@link #CHECK_LOOSE}. Only if that fails, another attempt is made in mode {@link #CHECK_VARARG}. * Which of these two attempts was successful is stored in {@link #inferenceKind}. * This field must be consulted whenever arguments of an invocation should be further processed. * See also {@link #getParameter(TypeBinding[], int, boolean)} and its clients.
  • *
*/ public class InferenceContext18 { /** to conform with javac regarding https://bugs.openjdk.java.net/browse/JDK-8026527 */ static final boolean SIMULATE_BUG_JDK_8026527 = true; /** * Detail flag to control the extent of {@link #SIMULATE_BUG_JDK_8026527}. * A setting of 'false' implements the advice from http://mail.openjdk.java.net/pipermail/lambda-spec-experts/2013-December/000447.html * i.e., raw types are not considered as compatible in constraints/bounds derived from invocation arguments, * but only for constraints derived from type variable bounds. */ static final boolean ARGUMENT_CONSTRAINTS_ARE_SOFT = false; // --- Main State of the Inference: --- /** the invocation being inferred (for 18.5.1 and 18.5.2) */ InvocationSite currentInvocation; /** arguments of #currentInvocation, if any */ Expression[] invocationArguments; /** The inference variables for which as solution is sought. */ InferenceVariable[] inferenceVariables; /** Number of inference variables. */ int variableCount = 0; /** Constraints that have not yet been reduced and incorporated. */ ConstraintFormula[] initialConstraints; /** The accumulated type bounds etc. */ BoundSet currentBounds; /** solution of applicability inference, stored for use as fallback, if invocation type inference fails. */ BoundSet storedSolution; /** For each candidate target type imposed from the outside store the solution of invocation type inference. */ Map solutionsPerTargetType = new HashMap(); /** One of CHECK_STRICT, CHECK_LOOSE, or CHECK_VARARGS. */ int inferenceKind; /** Marks how much work has been done so far? Used to avoid performing any of these tasks more than once. */ public int stepCompleted = NOT_INFERRED; public static final int NOT_INFERRED = 0; /** Applicability Inference (18.5.1) has been completed. */ public static final int APPLICABILITY_INFERRED = 1; /** Invocation Type Inference (18.5.2) has been completed (for some target type). */ public static final int TYPE_INFERRED = 2; /** All nested elements have been fully resolved. */ public static final int BINDINGS_UPDATED = 3; /** Signals whether any type compatibility makes use of unchecked conversion. */ public List constraintsWithUncheckedConversion; // --- /** Inner poly invocations which have been included in this inference. */ List innerPolies = new ArrayList(); /** Link to an outer inference context, used for bundled error reporting. */ public InferenceContext18 outerContext; private ArrayList problemMethods; Scope scope; LookupEnvironment environment; ReferenceBinding object; // java.lang.Object public static final int CHECK_STRICT = 1; public static final int CHECK_LOOSE = 2; public static final int CHECK_VARARG = 3; static class SuspendedInferenceRecord { InvocationSite site; Expression[] invocationArguments; InferenceVariable[] inferenceVariables; int inferenceKind; SuspendedInferenceRecord(InvocationSite site, Expression[] invocationArguments, InferenceVariable[] inferenceVariables, int inferenceKind) { this.site = site; this.invocationArguments = invocationArguments; this.inferenceVariables = inferenceVariables; this.inferenceKind = inferenceKind; } } /** Record for a candidate solution of Invocation Type Inference for one specific target type. */ static class Solution { TypeBinding resolvedType; MethodBinding method; BoundSet bounds; Solution(MethodBinding method, BoundSet bounds) { this.method = method; this.resolvedType = method.isConstructor() ? method.declaringClass : method.returnType; this.bounds = bounds; } } /** Construct an inference context for an invocation (method/constructor). */ public InferenceContext18(Scope scope, Expression[] arguments, InvocationSite site) { this.scope = scope; this.environment = scope.environment(); this.object = scope.getJavaLangObject(); this.invocationArguments = arguments; this.currentInvocation = site; } public InferenceContext18(Scope scope) { this.scope = scope; this.environment = scope.environment(); this.object = scope.getJavaLangObject(); } /** * JLS 18.1.3: Create initial bounds from a given set of type parameters declarations. * @return the set of inference variables created for the given typeParameters */ public InferenceVariable[] createInitialBoundSet(TypeVariableBinding[] typeParameters) { // if (this.currentBounds == null) { this.currentBounds = new BoundSet(); } if (typeParameters != null) { InferenceVariable[] newInferenceVariables = addInitialTypeVariableSubstitutions(typeParameters); this.currentBounds.addBoundsFromTypeParameters(this, typeParameters, newInferenceVariables); return newInferenceVariables; } return Binding.NO_INFERENCE_VARIABLES; } /** * Substitute any type variables mentioned in 'type' by the corresponding inference variable, if one exists. */ public TypeBinding substitute(TypeBinding type) { InferenceSubstitution inferenceSubstitution = new InferenceSubstitution(this.environment, this.inferenceVariables); return inferenceSubstitution.substitute(inferenceSubstitution, type); } /** JLS 18.5.1: compute bounds from formal and actual parameters. */ public void createInitialConstraintsForParameters(TypeBinding[] parameters, boolean checkVararg, TypeBinding varArgsType, MethodBinding method) { // TODO discriminate strict vs. loose invocations if (this.invocationArguments == null) return; int len = checkVararg ? parameters.length - 1 : Math.min(parameters.length, this.invocationArguments.length); int maxConstraints = checkVararg ? this.invocationArguments.length : len; int numConstraints = 0; if (this.initialConstraints == null) { this.initialConstraints = new ConstraintFormula[maxConstraints]; } else { numConstraints = this.initialConstraints.length; maxConstraints += numConstraints; System.arraycopy(this.initialConstraints, 0, this.initialConstraints=new ConstraintFormula[maxConstraints], 0, numConstraints); } for (int i = 0; i < len; i++) { if (this.invocationArguments[i].isPertinentToApplicability(parameters[i], method)) { TypeBinding thetaF = substitute(parameters[i]); this.initialConstraints[numConstraints++] = new ConstraintExpressionFormula(this.invocationArguments[i], thetaF, ReductionResult.COMPATIBLE, ARGUMENT_CONSTRAINTS_ARE_SOFT); } } if (checkVararg && varArgsType instanceof ArrayBinding) { varArgsType = ((ArrayBinding)varArgsType).elementsType(); TypeBinding thetaF = substitute(varArgsType); for (int i = len; i < this.invocationArguments.length; i++) { if (this.invocationArguments[i].isPertinentToApplicability(varArgsType, method)) { this.initialConstraints[numConstraints++] = new ConstraintExpressionFormula(this.invocationArguments[i], thetaF, ReductionResult.COMPATIBLE, ARGUMENT_CONSTRAINTS_ARE_SOFT); } } } if (numConstraints == 0) this.initialConstraints = ConstraintFormula.NO_CONSTRAINTS; else if (numConstraints < maxConstraints) System.arraycopy(this.initialConstraints, 0, this.initialConstraints = new ConstraintFormula[numConstraints], 0, numConstraints); } private InferenceVariable[] addInitialTypeVariableSubstitutions(TypeBinding[] typeVariables) { int len = typeVariables.length; if (len == 0) { if (this.inferenceVariables == null) this.inferenceVariables = Binding.NO_INFERENCE_VARIABLES; return Binding.NO_INFERENCE_VARIABLES; } InferenceVariable[] newVariables = new InferenceVariable[len]; for (int i = 0; i < len; i++) newVariables[i] = new InferenceVariable(typeVariables[i], this.variableCount++, this.currentInvocation, this.environment, this.object); if (this.inferenceVariables == null || this.inferenceVariables.length == 0) { this.inferenceVariables = newVariables; } else { // merge into this.inferenceVariables: int prev = this.inferenceVariables.length; System.arraycopy(this.inferenceVariables, 0, this.inferenceVariables = new InferenceVariable[len+prev], 0, prev); System.arraycopy(newVariables, 0, this.inferenceVariables, prev, len); } return newVariables; } /** Add new inference variables for the given type variables. */ public InferenceVariable[] addTypeVariableSubstitutions(TypeBinding[] typeVariables) { int len2 = typeVariables.length; InferenceVariable[] newVariables = new InferenceVariable[len2]; for (int i = 0; i < typeVariables.length; i++) { if (typeVariables[i] instanceof InferenceVariable) newVariables[i] = (InferenceVariable) typeVariables[i]; // prevent double substitution of an already-substituted inferenceVariable else newVariables[i] = new InferenceVariable(typeVariables[i], this.variableCount++, this.currentInvocation, this.environment, this.object); } int start = 0; if (this.inferenceVariables != null) { int len1 = this.inferenceVariables.length; System.arraycopy(this.inferenceVariables, 0, this.inferenceVariables = new InferenceVariable[len1+len2], 0, len1); start = len1; } else { this.inferenceVariables = new InferenceVariable[len2]; } System.arraycopy(newVariables, 0, this.inferenceVariables, start, len2); return newVariables; } /** JLS 18.1.3 Bounds: throws α: the inference variable α appears in a throws clause */ public void addThrowsContraints(TypeBinding[] parameters, InferenceVariable[] variables, ReferenceBinding[] thrownExceptions) { for (int i = 0; i < parameters.length; i++) { TypeBinding parameter = parameters[i]; for (int j = 0; j < thrownExceptions.length; j++) { if (TypeBinding.equalsEquals(parameter, thrownExceptions[j])) { this.currentBounds.inThrows.add(variables[i]); break; } } } } /** JLS 18.5.1 Invocation Applicability Inference. */ public void inferInvocationApplicability(MethodBinding method, TypeBinding[] arguments, boolean isDiamond) { ConstraintExpressionFormula.inferInvocationApplicability(this, method, arguments, isDiamond, this.inferenceKind); } /** JLS 18.5.2 Invocation Type Inference *

Callers are responsible for any post-processing (see {@link #rebindInnerPolies(BoundSet, TypeBinding[])}).

* @param b1 "the bound set produced by reduction in order to demonstrate that m is applicable in 18.5.1" */ public BoundSet inferInvocationType(BoundSet b1, TypeBinding expectedType, InvocationSite invocationSite, MethodBinding method) throws InferenceFailureException { // not JLS: simply ensure that null hints from the return type have been seen even in standalone contexts: if (expectedType == null && method.returnType != null) substitute(method.returnType); // result is ignore, the only effect is on InferenceVariable.nullHints // BoundSet previous = this.currentBounds.copy(); this.currentBounds = b1; try { // bullets 1&2: definitions only. if (expectedType != null && expectedType != TypeBinding.VOID && invocationSite instanceof Expression && ((Expression)invocationSite).isPolyExpression(method)) { // 3. bullet: special treatment for poly expressions if (!ConstraintExpressionFormula.inferPolyInvocationType(this, invocationSite, expectedType, method)) { return null; } } // 4. bullet: assemble C: Set c = new HashSet(); if (!addConstraintsToC(this.invocationArguments, c, method, this.inferenceKind)) return null; // 5. bullet: determine B3 from C while (!c.isEmpty()) { // * Set bottomSet = findBottomSet(c, allOutputVariables(c)); if (bottomSet.isEmpty()) { bottomSet.add(pickFromCycle(c)); } // * c.removeAll(bottomSet); // * The union of the input variables of all the selected constraints, α1, ..., αm, ... Set allInputs = new HashSet(); Iterator bottomIt = bottomSet.iterator(); while (bottomIt.hasNext()) { allInputs.addAll(bottomIt.next().inputVariables(this)); } InferenceVariable[] variablesArray = allInputs.toArray(new InferenceVariable[allInputs.size()]); // ... is resolved this.currentBounds.incorporate(this); BoundSet solution = resolve(variablesArray); // in rare cases resolving just one set of variables doesn't suffice, // don't bother with finding the necessary superset, just resolve all: if (solution == null) solution = resolve(this.inferenceVariables); // * ~ apply substitutions to all constraints: bottomIt = bottomSet.iterator(); while (bottomIt.hasNext()) { ConstraintFormula constraint = bottomIt.next(); if (solution != null) if (!constraint.applySubstitution(solution, variablesArray)) return null; // * reduce and incorporate if (!this.currentBounds.reduceOneConstraint(this, constraint)) return null; } } // 6. bullet: solve BoundSet solution = solve(); if (solution == null || !isResolved(solution)) { this.currentBounds = previous; // don't let bounds from unsuccessful attempt leak into subsequent attempts return null; } // we're done, start reporting: reportUncheckedConversions(solution); return this.currentBounds = solution; // this is final, keep the result: } finally { this.stepCompleted = TYPE_INFERRED; } } private boolean addConstraintsToC(Expression[] exprs, Set c, MethodBinding method, int inferenceKindForMethod) { TypeBinding[] fs; if (exprs != null) { int k = exprs.length; int p = method.parameters.length; if (k < (method.isVarargs() ? p-1 : p)) return false; // insufficient arguments for parameters! switch (inferenceKindForMethod) { case CHECK_STRICT: case CHECK_LOOSE: fs = method.parameters; break; case CHECK_VARARG: fs = varArgTypes(method.parameters, k); break; default: throw new IllegalStateException("Unexpected checkKind "+this.inferenceKind); //$NON-NLS-1$ } for (int i = 0; i < k; i++) { TypeBinding fsi = fs[Math.min(i, p-1)]; TypeBinding substF = substitute(fsi); if (!addConstraintsToC_OneExpr(exprs[i], c, fsi, substF, method)) return false; } } return true; } private boolean addConstraintsToC_OneExpr(Expression expri, Set c, TypeBinding fsi, TypeBinding substF, MethodBinding method) { // For all i (1 ≤ i ≤ k), if ei is not pertinent to applicability, the set contains ⟨ei → θ Fi⟩. if (!expri.isPertinentToApplicability(fsi, method)) { c.add(new ConstraintExpressionFormula(expri, substF, ReductionResult.COMPATIBLE, ARGUMENT_CONSTRAINTS_ARE_SOFT)); } if (expri instanceof FunctionalExpression) { c.add(new ConstraintExceptionFormula((FunctionalExpression) expri, substF)); } else if (expri instanceof Invocation && expri.isPolyExpression()) { Invocation invocation = (Invocation) expri; MethodBinding innerMethod = invocation.binding(null, false, null); if (innerMethod instanceof ParameterizedGenericMethodBinding) { InferenceContext18 innerCtx = invocation.getInferenceContext((ParameterizedMethodBinding) innerMethod); if (innerCtx != null) { // otherwise innerMethod does not participate in inference return addConstraintsToC(invocation.arguments(), c, innerMethod.genericMethod(), innerCtx.inferenceKind); } } } else if (expri instanceof ConditionalExpression) { ConditionalExpression ce = (ConditionalExpression) expri; return addConstraintsToC_OneExpr(ce.valueIfTrue, c, fsi, substF, method) && addConstraintsToC_OneExpr(ce.valueIfFalse, c, fsi, substF, method); } return true; } /** * Simplified API to perform Invocation Type Inference (JLS 18.5.2) * and perform subsequent steps: bound check, rebinding of inner poly expressions, * and creating of a problem method binding if needed. * Should only be called if the inference has not yet finished. * @param invocation invocation being inferred * @param argumentTypes arguments being passed into the invocation * @param method current candidate method binding for this invocation * @return a valid method binding with updated type parameters, * or a problem method binding signaling either inference failure or a bound mismatch. */ /*@NonNull*/ MethodBinding inferInvocationType(Invocation invocation, TypeBinding[] argumentTypes, ParameterizedGenericMethodBinding method) { // TODO optimize: if outerContext exists and is resolved, we probably don't need to infer again. TypeBinding targetType = invocation.invocationTargetType(); ParameterizedGenericMethodBinding finalMethod = null; ParameterizedGenericMethodBinding methodToCheck = method; boolean haveProperTargetType = targetType != null && targetType.isProperType(true); if (haveProperTargetType || !invocation.getExpressionContext().definesTargetType()) { MethodBinding original = method.originalMethod; Solution solution = this.solutionsPerTargetType.get(targetType); BoundSet result = solution != null ? solution.bounds : null; if (result == null) { // start over from a previous candidate but discard its type variable instantiations // TODO: should we retain any instantiations of type variables not owned by the method? try { result = inferInvocationType(this.currentBounds, targetType, invocation, original); } catch (InferenceFailureException e) { // no solution, but do more checks below } } if (result != null) { TypeBinding[] solutions = getSolutions(original.typeVariables(), invocation, result); if (solutions != null) { finalMethod = this.environment.createParameterizedGenericMethod(original, solutions); if (this.scope.compilerOptions().isAnnotationBasedNullAnalysisEnabled) NullAnnotationMatching.checkForContraditions(finalMethod, invocation, this.scope); invocation.registerInferenceContext(finalMethod, this); this.solutionsPerTargetType.put(targetType, new Solution(finalMethod, result)); } } if (finalMethod != null) methodToCheck = finalMethod; } else { finalMethod = method; } MethodBinding problemMethod = methodToCheck.boundCheck18(this.scope, argumentTypes); if (problemMethod != null) return problemMethod; if (!haveProperTargetType && invocation.getExpressionContext().definesTargetType()) return method; // still not ready! if (finalMethod != null) { if (rebindInnerPolies(finalMethod, invocation)) return finalMethod; } return getReturnProblemMethodIfNeeded(targetType, method); } /** * Simplified API to perform Invocation Type Inference (JLS 18.5.2) * and perform subsequent steps: bound check, rebinding of inner poly expressions, * and creating of a problem method binding if needed. * Should only be called if the inference has not yet finished. * Version used for inner invocations, where argument types need to be extracted * from actual invocation arguments. * @param invocation invocation being inferred * @param method current candidate method binding for this invocation * @return a valid method binding with updated type parameters, * or a problem method binding signaling either inference failure or a bound mismatch. */ public /*@NonNull*/ MethodBinding inferInvocationType(Invocation invocation, ParameterizedGenericMethodBinding method) { TypeBinding[] argumentTypes = null; Expression[] arguments = invocation.arguments(); if (arguments != null) { argumentTypes = new TypeBinding[arguments.length]; for (int i = 0; i < arguments.length; i++) argumentTypes[i] = arguments[i].resolvedType; } return inferInvocationType(invocation, argumentTypes, method); } public boolean hasResultFor(TypeBinding targetType) { if (targetType == null) return this.stepCompleted >= TYPE_INFERRED; else return this.solutionsPerTargetType.containsKey(targetType); } public boolean registerSolution(TypeBinding targetType, MethodBinding updatedBinding) { Solution solution = this.solutionsPerTargetType.get(targetType); if (solution != null) return false; // no update this.solutionsPerTargetType.put(targetType, new Solution(updatedBinding, null)); this.stepCompleted = Math.max(this.stepCompleted, TYPE_INFERRED); return true; } /** * 18.5.3 Functional Interface Parameterization Inference */ public ReferenceBinding inferFunctionalInterfaceParameterization(LambdaExpression lambda, BlockScope blockScope, ParameterizedTypeBinding targetTypeWithWildCards) { TypeBinding[] q = createBoundsForFunctionalInterfaceParameterizationInference(targetTypeWithWildCards); if (q == null || q.length != lambda.arguments().length) { // fail TODO: can this still happen here? } else { if (reduceWithEqualityConstraints(lambda.argumentTypes(), q)) { ReferenceBinding genericType = targetTypeWithWildCards.genericType(); TypeBinding[] a = targetTypeWithWildCards.arguments; // a is not-null by construction of parameterizedWithWildcard() TypeBinding[] aprime = getFunctionInterfaceArgumentSolutions(a); // TODO If F is a well-formed type, ... return blockScope.environment().createParameterizedType(genericType, aprime, genericType.enclosingType()); } } return targetTypeWithWildCards; } /** * Create initial bound set for 18.5.3 Functional Interface Parameterization Inference * @param functionalInterface the functional interface F * @return the parameter types Q1..Qk of the function type of the type F<α1, ..., αm>, or null */ TypeBinding[] createBoundsForFunctionalInterfaceParameterizationInference(ParameterizedTypeBinding functionalInterface) { if (this.currentBounds == null) this.currentBounds = new BoundSet(); TypeBinding[] a = functionalInterface.arguments; if (a == null) return null; InferenceVariable[] alpha = addInitialTypeVariableSubstitutions(a); for (int i = 0; i < a.length; i++) { TypeBound bound; if (a[i].kind() == Binding.WILDCARD_TYPE) { WildcardBinding wildcard = (WildcardBinding) a[i]; switch(wildcard.boundKind) { case Wildcard.EXTENDS : bound = new TypeBound(alpha[i], wildcard.allBounds(), ReductionResult.SUBTYPE); break; case Wildcard.SUPER : bound = new TypeBound(alpha[i], wildcard.bound, ReductionResult.SUPERTYPE); break; case Wildcard.UNBOUND : bound = new TypeBound(alpha[i], this.object, ReductionResult.SUBTYPE); break; default: continue; // cannot } } else { bound = new TypeBound(alpha[i], a[i], ReductionResult.SAME); } this.currentBounds.addBound(bound, this.environment); } TypeBinding falpha = substitute(functionalInterface); return falpha.getSingleAbstractMethod(this.scope, true).parameters; } public boolean reduceWithEqualityConstraints(TypeBinding[] p, TypeBinding[] q) { if (p != null) { for (int i = 0; i < p.length; i++) { try { if (!this.reduceAndIncorporate(ConstraintTypeFormula.create(p[i], q[i], ReductionResult.SAME))) return false; } catch (InferenceFailureException e) { return false; } } } return true; } /** * 18.5.4 More Specific Method Inference */ public boolean isMoreSpecificThan(MethodBinding m1, MethodBinding m2, boolean isVarArgs, boolean isVarArgs2) { // TODO: we don't yet distinguish vararg-with-passthrough from vararg-with-exactly-one-vararg-arg if (isVarArgs != isVarArgs2) { return isVarArgs2; } Expression[] arguments = this.invocationArguments; int numInvocArgs = arguments == null ? 0 : arguments.length; TypeVariableBinding[] p = m2.typeVariables(); TypeBinding[] s = m1.parameters; TypeBinding[] t = new TypeBinding[m2.parameters.length]; createInitialBoundSet(p); for (int i = 0; i < t.length; i++) t[i] = substitute(m2.parameters[i]); try { for (int i = 0; i < numInvocArgs; i++) { TypeBinding si = getParameter(s, i, isVarArgs); TypeBinding ti = getParameter(t, i, isVarArgs); Boolean result = moreSpecificMain(si, ti, this.invocationArguments[i]); if (result == Boolean.FALSE) return false; if (result == null) if (!reduceAndIncorporate(ConstraintTypeFormula.create(si, ti, ReductionResult.SUBTYPE))) return false; } if (t.length == numInvocArgs + 1) { TypeBinding skplus1 = getParameter(s, numInvocArgs, true); TypeBinding tkplus1 = getParameter(t, numInvocArgs, true); if (!reduceAndIncorporate(ConstraintTypeFormula.create(skplus1, tkplus1, ReductionResult.SUBTYPE))) return false; } return solve() != null; } catch (InferenceFailureException e) { return false; } } // FALSE: inference fails // TRUE: constraints have been incorporated // null: need the otherwise branch private Boolean moreSpecificMain(TypeBinding si, TypeBinding ti, Expression expri) throws InferenceFailureException { if (si.isProperType(true) && ti.isProperType(true)) { return expri.sIsMoreSpecific(si, ti, this.scope) ? Boolean.TRUE : Boolean.FALSE; } if (si.isFunctionalInterface(this.scope)) { TypeBinding funcI = ti.original(); if (funcI.isFunctionalInterface(this.scope)) { // "... none of the following is true:" if (siSuperI(si, funcI) || siSubI(si, funcI)) return null; if (si instanceof IntersectionCastTypeBinding) { TypeBinding[] elements = ((IntersectionCastTypeBinding)si).intersectingTypes; checkSuper: { for (int i = 0; i < elements.length; i++) if (!siSuperI(elements[i], funcI)) break checkSuper; return null; // each element of the intersection is a superinterface of I, or a parameterization of a superinterface of I. } for (int i = 0; i < elements.length; i++) if (siSubI(elements[i], funcI)) return null; // some element of the intersection is a subinterface of I, or a parameterization of a subinterface of I. } // all passed, time to do some work: TypeBinding siCapture = si.capture(this.scope, this.captureId++); MethodBinding sam = siCapture.getSingleAbstractMethod(this.scope, false); // no wildcards should be left needing replacement TypeBinding[] u = sam.parameters; TypeBinding r1 = sam.isConstructor() ? sam.declaringClass : sam.returnType; sam = ti.getSingleAbstractMethod(this.scope, true); // TODO TypeBinding[] v = sam.parameters; TypeBinding r2 = sam.isConstructor() ? sam.declaringClass : sam.returnType; return Boolean.valueOf(checkExpression(expri, u, r1, v, r2)); } } return null; } private boolean checkExpression(Expression expri, TypeBinding[] u, TypeBinding r1, TypeBinding[] v, TypeBinding r2) throws InferenceFailureException { if (expri instanceof LambdaExpression && !((LambdaExpression)expri).argumentsTypeElided()) { if (r2.id == TypeIds.T_void) return true; LambdaExpression lambda = (LambdaExpression) expri; Expression[] results = lambda.resultExpressions(); if (r1.isFunctionalInterface(this.scope) && r2.isFunctionalInterface(this.scope) && !(r1.isCompatibleWith(r2) || r2.isCompatibleWith(r1))) { // "these rules are applied recursively to R1 and R2, for each result expression in expi." // (what does "applied .. to R1 and R2" mean? Why mention R1/R2 and not U/V?) for (int i = 0; i < results.length; i++) { if (!checkExpression(results[i], u, r1, v, r2)) return false; } return true; } checkPrimitive1: if (r1.isPrimitiveType() && !r2.isPrimitiveType()) { // check: each result expression is a standalone expression of a primitive type for (int i = 0; i < results.length; i++) { if (results[i].isPolyExpression() || (results[i].resolvedType != null && !results[i].resolvedType.isPrimitiveType())) break checkPrimitive1; } return true; } checkPrimitive2: if (r2.isPrimitiveType() && !r1.isPrimitiveType()) { for (int i = 0; i < results.length; i++) { // for all expressions (not for any expression not) if (!( (!results[i].isPolyExpression() && (results[i].resolvedType != null && !results[i].resolvedType.isPrimitiveType())) // standalone of a referencetype || results[i].isPolyExpression())) // or a poly break checkPrimitive2; } return true; } return reduceAndIncorporate(ConstraintTypeFormula.create(r1, r2, ReductionResult.SUBTYPE)); } else if (expri instanceof ReferenceExpression && ((ReferenceExpression)expri).isExactMethodReference()) { for (int i = 0; i < u.length; i++) { ReferenceExpression reference = (ReferenceExpression) expri; if (!reduceAndIncorporate(ConstraintTypeFormula.create(u[i], v[i], ReductionResult.SAME))) return false; if (r2.id == TypeIds.T_void) return true; MethodBinding method = reference.findCompileTimeMethodTargeting(null, this.scope); // TODO directly access exactMethodBinding! TypeBinding returnType = method.isConstructor() ? method.declaringClass : method.returnType; if (r1.isPrimitiveType() && !r2.isPrimitiveType() && returnType.isPrimitiveType()) return true; if (r2.isPrimitiveType() && !r1.isPrimitiveType() && !returnType.isPrimitiveType()) return true; } return reduceAndIncorporate(ConstraintTypeFormula.create(r1, r2, ReductionResult.SUBTYPE)); } else if (expri instanceof ConditionalExpression) { ConditionalExpression cond = (ConditionalExpression) expri; return checkExpression(cond.valueIfTrue, u, r1, v, r2) && checkExpression(cond.valueIfFalse, u, r1, v, r2); } else { return false; } } private boolean siSuperI(TypeBinding si, TypeBinding funcI) { if (TypeBinding.equalsEquals(si, funcI) || TypeBinding.equalsEquals(si.original(), funcI)) return true; TypeBinding[] superIfcs = funcI.superInterfaces(); if (superIfcs == null) return false; for (int i = 0; i < superIfcs.length; i++) { if (siSuperI(si, superIfcs[i])) return true; } return false; } private boolean siSubI(TypeBinding si, TypeBinding funcI) { if (TypeBinding.equalsEquals(si, funcI) || TypeBinding.equalsEquals(si.original(), funcI)) return true; TypeBinding[] superIfcs = si.superInterfaces(); if (superIfcs == null) return false; for (int i = 0; i < superIfcs.length; i++) { if (siSubI(superIfcs[i], funcI)) return true; } return false; } // ========== Below this point: implementation of the generic algorithm: ========== /** * Try to solve the inference problem defined by constraints and bounds previously registered. * @return a bound set representing the solution, or null if inference failed * @throws InferenceFailureException a compile error has been detected during inference */ public /*@Nullable*/ BoundSet solve() throws InferenceFailureException { if (!reduce()) return null; if (!this.currentBounds.incorporate(this)) return null; return resolve(this.inferenceVariables); } public /*@Nullable*/ BoundSet solve(InferenceVariable[] toResolve) throws InferenceFailureException { if (!reduce()) return null; if (!this.currentBounds.incorporate(this)) return null; return resolve(toResolve); } /** * JLS 18.2. reduce all initial constraints * @throws InferenceFailureException */ private boolean reduce() throws InferenceFailureException { if (this.initialConstraints != null) { for (int i = 0; i < this.initialConstraints.length; i++) { if (!this.currentBounds.reduceOneConstraint(this, this.initialConstraints[i])) return false; } } this.initialConstraints = null; return true; } /** * Have all inference variables been instantiated successfully? */ public boolean isResolved(BoundSet boundSet) { if (this.inferenceVariables != null) { for (int i = 0; i < this.inferenceVariables.length; i++) { if (!boundSet.isInstantiated(this.inferenceVariables[i])) return false; } } return true; } /** * Retrieve the resolved solutions for all given type variables. * @param typeParameters * @param boundSet where instantiations are to be found * @return array containing the substituted types or null elements for any type variable that could not be substituted. */ public TypeBinding /*@Nullable*/[] getSolutions(TypeVariableBinding[] typeParameters, InvocationSite site, BoundSet boundSet) { int len = typeParameters.length; TypeBinding[] substitutions = new TypeBinding[len]; for (int i = 0; i < typeParameters.length; i++) { for (int j = 0; j < this.inferenceVariables.length; j++) { InferenceVariable variable = this.inferenceVariables[j]; if (variable.site == site && TypeBinding.equalsEquals(variable.typeParameter, typeParameters[i])) { substitutions[i] = boundSet.getInstantiation(variable, this.environment); break; } } if (substitutions[i] == null) return null; } return substitutions; } /** When inference produces a new constraint, reduce it to a suitable type bound and add the latter to the bound set. */ public boolean reduceAndIncorporate(ConstraintFormula constraint) throws InferenceFailureException { return this.currentBounds.reduceOneConstraint(this, constraint); // TODO(SH): should we immediately call a diat incorporate, or can we simply wait for the next round? } /** * JLS 18.4 Resolution * @return answer null if some constraint resolved to FALSE, otherwise the boundset representing the solution * @throws InferenceFailureException */ private /*@Nullable*/ BoundSet resolve(InferenceVariable[] toResolve) throws InferenceFailureException { this.captureId = 0; // NOTE: 18.5.2 ... // "(While it was necessary to demonstrate that the inference variables in B1 could be resolved // in order to establish applicability, the resulting instantiations are not considered part of B1.) // For this reason, resolve works on a temporary bound set, copied before any modification. BoundSet tmpBoundSet = this.currentBounds; if (this.inferenceVariables != null) { // find a minimal set of dependent variables: Set variableSet; while ((variableSet = getSmallestVariableSet(tmpBoundSet, toResolve)) != null) { int oldNumUninstantiated = tmpBoundSet.numUninstantiatedVariables(this.inferenceVariables); final int numVars = variableSet.size(); if (numVars > 0) { final InferenceVariable[] variables = variableSet.toArray(new InferenceVariable[numVars]); variables: if (!tmpBoundSet.hasCaptureBound(variableSet)) { // try to instantiate this set of variables in a fresh copy of the bound set: BoundSet prevBoundSet = tmpBoundSet; tmpBoundSet = tmpBoundSet.copy(); for (int j = 0; j < variables.length; j++) { InferenceVariable variable = variables[j]; // try lower bounds: TypeBinding[] lowerBounds = tmpBoundSet.lowerBounds(variable, true/*onlyProper*/); if (lowerBounds != Binding.NO_TYPES) { TypeBinding lub = this.scope.lowerUpperBound(lowerBounds); if (lub == TypeBinding.VOID || lub == null) return null; tmpBoundSet.addBound(new TypeBound(variable, lub, ReductionResult.SAME), this.environment); } else { TypeBinding[] upperBounds = tmpBoundSet.upperBounds(variable, true/*onlyProper*/); // check exception bounds: if (tmpBoundSet.inThrows.contains(variable) && tmpBoundSet.hasOnlyTrivialExceptionBounds(variable, upperBounds)) { TypeBinding runtimeException = this.scope.getType(TypeConstants.JAVA_LANG_RUNTIMEEXCEPTION, 3); tmpBoundSet.addBound(new TypeBound(variable, runtimeException, ReductionResult.SAME), this.environment); } else { // try upper bounds: TypeBinding glb = this.object; if (upperBounds != Binding.NO_TYPES) { if (upperBounds.length == 1) { glb = upperBounds[0]; } else { ReferenceBinding[] glbs = Scope.greaterLowerBound((ReferenceBinding[])upperBounds); if (glbs == null) { throw new UnsupportedOperationException("no glb for "+Arrays.asList(upperBounds)); //$NON-NLS-1$ } else if (glbs.length == 1) { glb = glbs[0]; } else { IntersectionCastTypeBinding intersection = new IntersectionCastTypeBinding(glbs, this.environment); if (!ReferenceBinding.isConsistentIntersection(intersection.intersectingTypes)) { tmpBoundSet = prevBoundSet; // clean up break variables; // and start over } glb = intersection; } } } tmpBoundSet.addBound(new TypeBound(variable, glb, ReductionResult.SAME), this.environment); } } } if (tmpBoundSet.incorporate(this)) continue; tmpBoundSet = prevBoundSet;// clean-up for second attempt } // Otherwise, a second attempt is made... Sorting.sortInferenceVariables(variables); // ensure stability of capture IDs final CaptureBinding18[] zs = new CaptureBinding18[numVars]; for (int j = 0; j < numVars; j++) zs[j] = freshCapture(variables[j]); Substitution theta = new Substitution() { public LookupEnvironment environment() { return InferenceContext18.this.environment; } public boolean isRawSubstitution() { return false; } public TypeBinding substitute(TypeVariableBinding typeVariable) { for (int j = 0; j < numVars; j++) if (variables[j] == typeVariable) //$IDENTITY-COMPARISON$ InferenceVariable does not participate in type annotation encoding return zs[j]; return typeVariable; } }; for (int j = 0; j < numVars; j++) { InferenceVariable variable = variables[j]; CaptureBinding18 zsj = zs[j]; // add lower bounds: TypeBinding[] lowerBounds = tmpBoundSet.lowerBounds(variable, true/*onlyProper*/); if (lowerBounds != Binding.NO_TYPES) { lowerBounds = Scope.substitute(theta, lowerBounds); TypeBinding lub = this.scope.lowerUpperBound(lowerBounds); if (lub != TypeBinding.VOID && lub != null) zsj.lowerBound = lub; } // add upper bounds: TypeBinding[] upperBounds = tmpBoundSet.upperBounds(variable, false/*onlyProper*/); if (upperBounds != Binding.NO_TYPES) { for (int k = 0; k < upperBounds.length; k++) upperBounds[k] = Scope.substitute(theta, upperBounds[k]); if (!setUpperBounds(zsj, upperBounds)) continue; // at violation of well-formedness skip this candidate and proceed } if (tmpBoundSet == this.currentBounds) tmpBoundSet = tmpBoundSet.copy(); Iterator captureKeys = tmpBoundSet.captures.keySet().iterator(); Set toRemove = new HashSet(); while (captureKeys.hasNext()) { ParameterizedTypeBinding key = captureKeys.next(); int len = key.arguments.length; for (int i = 0; i < len; i++) { if (key.arguments[i] == variable) { //$IDENTITY-COMPARISON$ toRemove.add(key); break; } } } captureKeys = toRemove.iterator(); while (captureKeys.hasNext()) tmpBoundSet.captures.remove(captureKeys.next()); tmpBoundSet.addBound(new TypeBound(variable, zsj, ReductionResult.SAME), this.environment); } if (tmpBoundSet.incorporate(this)) { if (tmpBoundSet.numUninstantiatedVariables(this.inferenceVariables) == oldNumUninstantiated) return null; // abort because we made no progress continue; } return null; } } } return tmpBoundSet; } int captureId = 0; /** For 18.4: "Let Z1, ..., Zn be fresh type variables" use capture bindings. */ private CaptureBinding18 freshCapture(InferenceVariable variable) { int id = this.captureId++; char[] sourceName = CharOperation.concat("Z".toCharArray(), '#', String.valueOf(id).toCharArray(), '-', variable.sourceName); //$NON-NLS-1$ int position = this.currentInvocation != null ? this.currentInvocation.sourceStart() : 0; return new CaptureBinding18(this.scope.enclosingSourceType(), sourceName, variable.typeParameter.shortReadableName(), position, id, this.environment); } // === === private boolean setUpperBounds(CaptureBinding18 typeVariable, TypeBinding[] substitutedUpperBounds) { // 18.4: ... define the upper bound of Zi as glb(L1θ, ..., Lkθ) if (substitutedUpperBounds.length == 1) { typeVariable.setUpperBounds(substitutedUpperBounds, this.object); // shortcut } else { TypeBinding[] glbs = Scope.greaterLowerBound(substitutedUpperBounds, this.scope, this.environment); if (glbs == null) return false; if (typeVariable.lowerBound != null) { for (int i = 0; i < glbs.length; i++) { if (!typeVariable.lowerBound.isCompatibleWith(glbs[i])) return false; // not well-formed } } // for deterministic results sort this array by id: sortTypes(glbs); if (!typeVariable.setUpperBounds(glbs, this.object)) return false; } return true; } static void sortTypes(TypeBinding[] types) { Arrays.sort(types, new Comparator() { public int compare(TypeBinding o1, TypeBinding o2) { int i1 = o1.id, i2 = o2.id; return (i1 getSmallestVariableSet(BoundSet bounds, InferenceVariable[] subSet) { int min = Integer.MAX_VALUE; Set result = null; for (int i = 0; i < subSet.length; i++) { InferenceVariable currentVariable = subSet[i]; if (!bounds.isInstantiated(currentVariable)) { Set set = new HashSet(); if (!addDependencies(bounds, set, currentVariable, min)) continue; int cur = set.size(); if (cur == 1) return set; // won't get smaller if (cur < min) { result = set; min = cur; } } } return result; } private boolean addDependencies(BoundSet boundSet, Set variableSet, InferenceVariable currentVariable, int min) { if (variableSet.size() >= min) return false; // no improvement if (boundSet.isInstantiated(currentVariable)) return true; // not added if (!variableSet.add(currentVariable)) return true; // already present for (int j = 0; j < this.inferenceVariables.length; j++) { InferenceVariable nextVariable = this.inferenceVariables[j]; if (nextVariable == currentVariable) continue; //$IDENTITY-COMPARISON$ Inference variables if (boundSet.dependsOnResolutionOf(currentVariable, nextVariable)) if (!addDependencies(boundSet, variableSet, nextVariable, min)) return false; // abort traversal: no improvement } return true; } private ConstraintFormula pickFromCycle(Set c) { // Detail from 18.5.2 bullet 6.1 // Note on performance: this implementation could quite possibly be optimized a lot. // However, we only *very rarely* reach here, // so nobody should really be affected by the performance penalty paid here. // Note on spec conformance: the spec seems to require _all_ criteria (i)-(iv) to be fulfilled // with the sole exception of (iii), which should only be used, if _any_ constraints matching (i) & (ii) // also fulfill this condition. // Experiments, however, show that strict application of the above is prone to failing to pick any constraint, // causing non-termination of the algorithm. // Since that is not acceptable, I'm *interpreting* the spec to request a search for a constraint // that "best matches" the given conditions. // collect all constraints participating in a cycle HashMap> dependencies = new HashMap>(); Set cycles = new HashSet(); for (ConstraintFormula constraint : c) { Collection infVars = constraint.inputVariables(this); for (ConstraintFormula other : c) { if (other == constraint) continue; if (dependsOn(infVars, other.outputVariables(this))) { // found a dependency, record it: Set targetSet = dependencies.get(constraint); if (targetSet == null) dependencies.put(constraint, targetSet = new HashSet()); targetSet.add(other); // look for a cycle: Set nodesInCycle = new HashSet(); if (isReachable(dependencies, other, constraint, new HashSet(), nodesInCycle)) { // found a cycle, record the involved nodes: cycles.addAll(nodesInCycle); } } } } Set outside = new HashSet(c); outside.removeAll(cycles); Set candidatesII = new HashSet(); // (i): participates in a cycle: candidates: for (ConstraintFormula candidate : cycles) { Collection infVars = candidate.inputVariables(this); // (ii) does not depend on any constraints outside the cycle for (ConstraintFormula out : outside) { if (dependsOn(infVars, out.outputVariables(this))) continue candidates; } candidatesII.add(candidate); } if (candidatesII.isEmpty()) candidatesII = c; // not spec'ed but needed to avoid returning null below, witness: java.util.stream.Collectors // tentatively: (iii) has the form ⟨Expression → T⟩ Set candidatesIII = new HashSet(); for (ConstraintFormula candidate : candidatesII) { if (candidate instanceof ConstraintExpressionFormula) candidatesIII.add(candidate); } if (candidatesIII.isEmpty()) { candidatesIII = candidatesII; // no constraint fulfills (iii) -> ignore this condition } else { // candidatesIII contains all relevant constraints ⟨Expression → T⟩ // (iv) contains an expression that appears to the left of the expression // of every other constraint satisfying the previous three requirements // collect containment info regarding all expressions in candidate constraints: // (a) find minimal enclosing expressions: Map expressionContainedBy = new HashMap(); for (ConstraintFormula one : candidatesIII) { ConstraintExpressionFormula oneCEF = (ConstraintExpressionFormula) one; Expression exprOne = oneCEF.left; for (ConstraintFormula two : candidatesIII) { if (one == two) continue; ConstraintExpressionFormula twoCEF = (ConstraintExpressionFormula) two; Expression exprTwo = twoCEF.left; if (doesExpressionContain(exprOne, exprTwo)) { ConstraintExpressionFormula previous = expressionContainedBy.get(two); if (previous == null || doesExpressionContain(previous.left, exprOne)) // only if improving expressionContainedBy.put(twoCEF, oneCEF); } } } // (b) build the tree from the above Map> containmentForest = new HashMap>(); for (Map.Entry parentRelation : expressionContainedBy.entrySet()) { ConstraintExpressionFormula parent = parentRelation.getValue(); Set children = containmentForest.get(parent); if (children == null) containmentForest.put(parent, children = new HashSet()); children.add(parentRelation.getKey()); } // approximate the spec by searching the largest containment tree: int bestRank = -1; ConstraintExpressionFormula candidate = null; for (ConstraintExpressionFormula parent : containmentForest.keySet()) { int rank = rankNode(parent, expressionContainedBy, containmentForest); if (rank > bestRank) { bestRank = rank; candidate = parent; } } if (candidate != null) return candidate; } if (candidatesIII.isEmpty()) throw new IllegalStateException("cannot pick constraint from cyclic set"); //$NON-NLS-1$ return candidatesIII.iterator().next(); } /** * Does the first constraint depend on the other? * The first constraint is represented by its input variables and the other constraint by its output variables. */ private boolean dependsOn(Collection inputsOfFirst, Collection outputsOfOther) { for (InferenceVariable iv : inputsOfFirst) { for (InferenceVariable otherIV : outputsOfOther) if (this.currentBounds.dependsOnResolutionOf(iv, otherIV)) return true; } return false; } /** Does 'deps' contain a chain of dependencies leading from 'from' to 'to'? */ private boolean isReachable(Map> deps, ConstraintFormula from, ConstraintFormula to, Set nodesVisited, Set nodesInCycle) { if (from == to) { nodesInCycle.add(from); return true; } if (!nodesVisited.add(from)) return false; Set targetSet = deps.get(from); if (targetSet != null) { for (ConstraintFormula tgt : targetSet) { if (isReachable(deps, tgt, to, nodesVisited, nodesInCycle)) { nodesInCycle.add(from); return true; } } } return false; } /** Does exprOne lexically contain exprTwo? */ private boolean doesExpressionContain(Expression exprOne, Expression exprTwo) { if (exprTwo.sourceStart > exprOne.sourceStart) { return exprTwo.sourceEnd <= exprOne.sourceEnd; } else if (exprTwo.sourceStart == exprOne.sourceStart) { return exprTwo.sourceEnd < exprOne.sourceEnd; } return false; } /** non-roots answer -1, roots answer the size of the spanned tree */ private int rankNode(ConstraintExpressionFormula parent, Map expressionContainedBy, Map> containmentForest) { if (expressionContainedBy.get(parent) != null) return -1; // not a root Set children = containmentForest.get(parent); if (children == null) return 1; // unconnected node or leaf int sum = 1; for (ConstraintExpressionFormula child : children) { int cRank = rankNode(child, expressionContainedBy, containmentForest); if (cRank > 0) sum += cRank; } return sum; } private Set findBottomSet(Set constraints, Set allOutputVariables) { // 18.5.2 bullet 6.1 // A subset of constraints is selected, satisfying the property // that, for each constraint, no input variable depends on an // output variable of another constraint in C ... Set result = new HashSet(); Iterator it = constraints.iterator(); constraintLoop: while (it.hasNext()) { ConstraintFormula constraint = it.next(); Iterator inputIt = constraint.inputVariables(this).iterator(); Iterator outputIt = allOutputVariables.iterator(); while (inputIt.hasNext()) { InferenceVariable in = inputIt.next(); if (allOutputVariables.contains(in)) // not explicit in the spec, but let's assume any inference variable depends on itself continue constraintLoop; while (outputIt.hasNext()) { if (this.currentBounds.dependsOnResolutionOf(in, outputIt.next())) continue constraintLoop; } } result.add(constraint); } return result; } Set allOutputVariables(Set constraints) { Set result = new HashSet(); Iterator it = constraints.iterator(); while (it.hasNext()) { result.addAll(it.next().outputVariables(this)); } return result; } private TypeBinding[] varArgTypes(TypeBinding[] parameters, int k) { TypeBinding[] types = new TypeBinding[k]; int declaredLength = parameters.length-1; System.arraycopy(parameters, 0, types, 0, declaredLength); TypeBinding last = ((ArrayBinding)parameters[declaredLength]).elementsType(); for (int i = declaredLength; i < k; i++) types[i] = last; return types; } public SuspendedInferenceRecord enterPolyInvocation(InvocationSite invocation, Expression[] innerArguments) { SuspendedInferenceRecord record = new SuspendedInferenceRecord(this.currentInvocation, this.invocationArguments, this.inferenceVariables, this.inferenceKind); this.inferenceVariables = null; this.invocationArguments = innerArguments; this.currentInvocation = invocation; // schedule for re-binding the inner after inference success: this.innerPolies.add(invocation); return record; } public SuspendedInferenceRecord enterLambda(LambdaExpression lambda) { SuspendedInferenceRecord record = new SuspendedInferenceRecord(this.currentInvocation, this.invocationArguments, this.inferenceVariables, this.inferenceKind); this.inferenceVariables = null; this.invocationArguments = null; this.currentInvocation = null; return record; } public void resumeSuspendedInference(SuspendedInferenceRecord record) { // merge inference variables: if (this.inferenceVariables == null) { // no new ones, assume we aborted prematurely this.inferenceVariables = record.inferenceVariables; } else { int l1 = this.inferenceVariables.length; int l2 = record.inferenceVariables.length; // move to back, add previous to front: System.arraycopy(this.inferenceVariables, 0, this.inferenceVariables=new InferenceVariable[l1+l2], l2, l1); System.arraycopy(record.inferenceVariables, 0, this.inferenceVariables, 0, l2); } // replace invocation site & arguments: this.currentInvocation = record.site; this.invocationArguments = record.invocationArguments; this.inferenceKind = record.inferenceKind; } public boolean rebindInnerPolies(MethodBinding method, InvocationSite site) { BoundSet bounds = this.currentBounds; TypeBinding targetType = site.invocationTargetType(); if (targetType == null || !targetType.isProperType(true)) { if (!site.getExpressionContext().definesTargetType()) { // in this case we may not yet have the solution(?, get or compute it now: Solution solution = this.solutionsPerTargetType.get(targetType); try { if (solution != null && solution.bounds != null) bounds = solution.bounds; else bounds = inferInvocationType(this.currentBounds, null, site, method.shallowOriginal()); } catch (InferenceFailureException e) { return false; } if (bounds == null) return false; } } else { Solution solution = this.solutionsPerTargetType.get(targetType); if (solution != null && solution.bounds != null) bounds = solution.bounds; } rebindInnerPolies(bounds, method.parameters); return true; } /** * After inference has finished, iterate all inner poly expressions (Invocations), that * have been included in the inference. For each of these update some type information * from the inference result and perhaps trigger follow-up resolving as needed. * Similar for poly expressions that did not directly participate in the inference * but are direct arguments of the current invocation (FunctionalExpression, ConditionalExpression). */ public void rebindInnerPolies(BoundSet bounds, TypeBinding[] parameterTypes) { // This updates all remaining poly expressions that are direct arguments of the current invocation: // (handles FunctionalExpression & ConditionalExpression) boolean isVarargs = this.inferenceKind == CHECK_VARARG; acceptPendingPolyArguments(bounds, parameterTypes, isVarargs); // This loops over all poly expressions for which a sub-inference was triggered: // (handles generic invocations) int len = this.innerPolies.size(); for (int i = 0; i < len; i++) { Expression inner = (Expression) this.innerPolies.get(i); if (inner instanceof Invocation) { Invocation innerMessage = (Invocation) inner; TypeBinding innerTargetType = inner.expectedType(); // may be set from acceptPendingPolyArguments if (innerTargetType != null && !innerTargetType.isProperType(true)) innerTargetType = null; MethodBinding binding = innerMessage.binding(innerTargetType, innerTargetType != null, this.scope); if (binding == null) continue; MethodBinding original = binding.shallowOriginal(); // apply inference results onto the allocation type of inner diamonds: if (original.isConstructor() && inner.isPolyExpression()) { ReferenceBinding declaringClass = original.declaringClass; TypeBinding[] arguments = getSolutions(declaringClass.typeVariables(), innerMessage, bounds); declaringClass = this.environment.createParameterizedType(declaringClass, arguments, declaringClass.enclosingType()); original = ((ParameterizedTypeBinding)declaringClass).createParameterizedMethod(original); inner.checkAgainstFinalTargetType(innerTargetType, this.scope); if (this.environment.globalOptions.isAnnotationBasedNullAnalysisEnabled) NullAnnotationMatching.checkForContraditions(original, innerMessage, this.scope); } // apply results of the combined inference onto the binding of the inner invocation: TypeBinding[] solutions = getSolutions(original.typeVariables(), innerMessage, bounds); if (solutions == null) { if (binding instanceof ParameterizedGenericMethodBinding) { InferenceContext18 innerCtx = innerMessage.getInferenceContext((ParameterizedGenericMethodBinding) binding); if (innerCtx != null && !binding.isValidBinding()) { innerCtx.reportInvalidInvocation(innerMessage, binding); } } continue; // inner inference not requested -> not a problem } ParameterizedGenericMethodBinding innerBinding = this.environment.createParameterizedGenericMethod(original, solutions); if (innerMessage.updateBindings(innerBinding, innerTargetType)) { // only if we are actually improving anything ASTNode.resolvePolyExpressionArguments(innerMessage, innerBinding, this.scope); } } } this.stepCompleted = BINDINGS_UPDATED; // we're done-done } private void acceptPendingPolyArguments(BoundSet acceptedResult, TypeBinding[] parameterTypes, boolean isVarArgs) { if (acceptedResult == null || this.invocationArguments == null) return; Substitution substitution = getResultSubstitution(acceptedResult); for (int i = 0; i < this.invocationArguments.length; i++) { TypeBinding targetType = getParameter(parameterTypes, i, isVarArgs); if (!targetType.isProperType(true)) targetType = Scope.substitute(substitution, targetType); Expression expression = this.invocationArguments[i]; if (expression instanceof Invocation) { Invocation invocation = (Invocation) expression; if (!this.innerPolies.contains(invocation)) { MethodBinding method = invocation.binding(targetType, true, this.scope); if (method instanceof ParameterizedGenericMethodBinding) { ParameterizedGenericMethodBinding previousBinding = (ParameterizedGenericMethodBinding) method; InferenceContext18 innerCtx = invocation.getInferenceContext(previousBinding); if (innerCtx != null) { // we have a non-poly generic invocation, which needs inference but is not connected via innerPolis. // Finish that inner inference now (incl. binding updates): MethodBinding innerBinding = innerCtx.inferInvocationType(invocation, previousBinding); if (!innerBinding.isValidBinding()) { innerCtx.reportInvalidInvocation(invocation, innerBinding); } if (invocation.updateBindings(innerBinding, targetType)) { // only if we are actually improving anything ASTNode.resolvePolyExpressionArguments(invocation, innerBinding, this.scope); } } } else if(method instanceof ParameterizedMethodBinding){ expression.checkAgainstFinalTargetType(targetType, this.scope); } } else { expression.setExpectedType(targetType); } } else { expression.checkAgainstFinalTargetType(targetType, this.scope); } } } private Substitution getResultSubstitution(final BoundSet result) { return new Substitution() { public LookupEnvironment environment() { return InferenceContext18.this.environment; } public boolean isRawSubstitution() { return false; } public TypeBinding substitute(TypeVariableBinding typeVariable) { if (typeVariable instanceof InferenceVariable) { return result.getInstantiation((InferenceVariable) typeVariable, InferenceContext18.this.environment); } return typeVariable; } }; } public boolean isVarArgs() { return this.inferenceKind == CHECK_VARARG; } /** * Retrieve the rank'th parameter, possibly respecting varargs invocation, see 15.12.2.4. * Returns null if out of bounds and CHECK_VARARG was not requested. * Precondition: isVarArgs implies method.isVarargs() */ public static TypeBinding getParameter(TypeBinding[] parameters, int rank, boolean isVarArgs) { if (isVarArgs) { if (rank >= parameters.length-1) return ((ArrayBinding)parameters[parameters.length-1]).elementsType(); } else if (rank >= parameters.length) { return null; } return parameters[rank]; } /** * Create a problem method signaling failure of invocation type inference, * unless the given candidate is tolerable to be compatible with buggy javac. */ public MethodBinding getReturnProblemMethodIfNeeded(TypeBinding expectedType, MethodBinding method) { if (InferenceContext18.SIMULATE_BUG_JDK_8026527 && expectedType != null && method.returnType instanceof ReferenceBinding) { if (method.returnType.erasure().isCompatibleWith(expectedType)) return method; // don't count as problem. } if (expectedType == null) return method; // assume inference failure concerned another expression ProblemMethodBinding problemMethod = new ProblemMethodBinding(method, method.selector, method.parameters, ProblemReasons.ParameterizedMethodExpectedTypeProblem); problemMethod.returnType = expectedType; problemMethod.inferenceContext = this; return problemMethod; } public void reportInvalidInvocation(Invocation invocation, MethodBinding binding) { if (invocation instanceof MessageSend) this.scope.problemReporter().invalidMethod((MessageSend) invocation, binding); else this.scope.problemReporter().invalidConstructor((Statement)invocation, binding); } // debugging: public String toString() { StringBuffer buf = new StringBuffer("Inference Context"); //$NON-NLS-1$ switch (this.stepCompleted) { case NOT_INFERRED: buf.append(" (initial)");break; //$NON-NLS-1$ case APPLICABILITY_INFERRED: buf.append(" (applicability inferred)");break; //$NON-NLS-1$ case TYPE_INFERRED: buf.append(" (type inferred)");break; //$NON-NLS-1$ case BINDINGS_UPDATED: buf.append(" (bindings updated)");break; //$NON-NLS-1$ } switch (this.inferenceKind) { case CHECK_STRICT: buf.append(" (strict)");break; //$NON-NLS-1$ case CHECK_LOOSE: buf.append(" (loose)");break; //$NON-NLS-1$ case CHECK_VARARG: buf.append(" (vararg)");break; //$NON-NLS-1$ } if (this.currentBounds != null && isResolved(this.currentBounds)) buf.append(" (resolved)"); //$NON-NLS-1$ buf.append('\n'); if (this.inferenceVariables != null) { buf.append("Inference Variables:\n"); //$NON-NLS-1$ for (int i = 0; i < this.inferenceVariables.length; i++) { buf.append('\t').append(this.inferenceVariables[i].sourceName).append("\t:\t"); //$NON-NLS-1$ if (this.currentBounds != null && this.currentBounds.isInstantiated(this.inferenceVariables[i])) buf.append(this.currentBounds.getInstantiation(this.inferenceVariables[i], this.environment).readableName()); else buf.append("NOT INSTANTIATED"); //$NON-NLS-1$ buf.append('\n'); } } if (this.initialConstraints != null) { buf.append("Initial Constraints:\n"); //$NON-NLS-1$ for (int i = 0; i < this.initialConstraints.length; i++) if (this.initialConstraints[i] != null) buf.append('\t').append(this.initialConstraints[i].toString()).append('\n'); } if (this.currentBounds != null) buf.append(this.currentBounds.toString()); return buf.toString(); } public void addProblemMethod(ProblemMethodBinding problemMethod) { if (this.problemMethods == null) this.problemMethods = new ArrayList(); this.problemMethods.add(problemMethod); } /** * If 'type' is a parameterized type and one of its arguments is a wildcard answer the casted type, else null. * A nonnull answer is ensured to also have nonnull arguments. */ public static ParameterizedTypeBinding parameterizedWithWildcard(TypeBinding type) { if (type == null || type.kind() != Binding.PARAMETERIZED_TYPE) return null; ParameterizedTypeBinding parameterizedType = (ParameterizedTypeBinding) type; TypeBinding[] arguments = parameterizedType.arguments; if (arguments != null) { for (int i = 0; i < arguments.length; i++) if (arguments[i].isWildcard()) return parameterizedType; } return null; } public TypeBinding[] getFunctionInterfaceArgumentSolutions(TypeBinding[] a) { int m = a.length; TypeBinding[] aprime = new TypeBinding[m]; for (int i = 0; i < this.inferenceVariables.length; i++) { InferenceVariable alphai = this.inferenceVariables[i]; TypeBinding t = this.currentBounds.getInstantiation(alphai, this.environment); if (t != null) aprime[i] = t; else aprime[i] = a[i]; } return aprime; } /** Record the fact that the given constraint requires unchecked conversion. */ public void recordUncheckedConversion(ConstraintTypeFormula constraint) { if (this.constraintsWithUncheckedConversion == null) this.constraintsWithUncheckedConversion = new ArrayList(); this.constraintsWithUncheckedConversion.add(constraint); } void reportUncheckedConversions(BoundSet solution) { if (this.constraintsWithUncheckedConversion != null) { int len = this.constraintsWithUncheckedConversion.size(); Substitution substitution = getResultSubstitution(solution); for (int i = 0; i < len; i++) { ConstraintTypeFormula constraint = (ConstraintTypeFormula) this.constraintsWithUncheckedConversion.get(i); TypeBinding expectedType = constraint.right; TypeBinding providedType = constraint.left; if (!expectedType.isProperType(true)) { expectedType = Scope.substitute(substitution, expectedType); } if (!providedType.isProperType(true)) { providedType = Scope.substitute(substitution, providedType); } /* FIXME(stephan): enable once we solved: (a) avoid duplication with traditional reporting (b) improve location to report against if (this.currentInvocation instanceof Expression) this.scope.problemReporter().unsafeTypeConversion((Expression) this.currentInvocation, providedType, expectedType); */ } } } /** For use by 15.12.2.6 Method Invocation Type */ public boolean usesUncheckedConversion() { return this.constraintsWithUncheckedConversion != null; } // INTERIM: infrastructure for detecting failures caused by specific known incompleteness: public static void missingImplementation(String msg) { throw new UnsupportedOperationException(msg); } }




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