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 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
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 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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package org.openjdk.tools.javac.comp;

import java.util.Collections;
import java.util.EnumSet;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedHashMap;
import java.util.Map;
import java.util.Set;

import org.openjdk.tools.javac.code.Type;
import org.openjdk.tools.javac.code.Type.ArrayType;
import org.openjdk.tools.javac.code.Type.ClassType;
import org.openjdk.tools.javac.code.Type.TypeVar;
import org.openjdk.tools.javac.code.Type.UndetVar;
import org.openjdk.tools.javac.code.Type.UndetVar.InferenceBound;
import org.openjdk.tools.javac.code.Type.WildcardType;
import org.openjdk.tools.javac.code.TypeTag;
import org.openjdk.tools.javac.code.Types;
import org.openjdk.tools.javac.comp.Infer.FreeTypeListener;
import org.openjdk.tools.javac.comp.Infer.GraphSolver;
import org.openjdk.tools.javac.comp.Infer.GraphStrategy;
import org.openjdk.tools.javac.comp.Infer.InferenceException;
import org.openjdk.tools.javac.comp.Infer.InferenceStep;
import org.openjdk.tools.javac.tree.JCTree;
import org.openjdk.tools.javac.util.Assert;
import org.openjdk.tools.javac.util.Filter;
import org.openjdk.tools.javac.util.List;
import org.openjdk.tools.javac.util.ListBuffer;
import org.openjdk.tools.javac.util.Warner;

/**
 * An inference context keeps track of the set of variables that are free
 * in the current context. It provides utility methods for opening/closing
 * types to their corresponding free/closed forms. It also provide hooks for
 * attaching deferred post-inference action (see PendingCheck). Finally,
 * it can be used as an entry point for performing upper/lower bound inference
 * (see InferenceKind).
 *
 * 

This is NOT part of any supported API. * If you write code that depends on this, you do so at your own risk. * This code and its internal interfaces are subject to change or * deletion without notice. */ public class InferenceContext { /** list of inference vars as undet vars */ List undetvars; Type update(Type t) { return t; } /** list of inference vars in this context */ List inferencevars; Map> freeTypeListeners = new LinkedHashMap<>(); Types types; Infer infer; public InferenceContext(Infer infer, List inferencevars) { this(infer, inferencevars, inferencevars.map(infer.fromTypeVarFun)); } public InferenceContext(Infer infer, List inferencevars, List undetvars) { this.inferencevars = inferencevars; this.undetvars = undetvars; this.infer = infer; this.types = infer.types; } /** * add a new inference var to this inference context */ void addVar(TypeVar t) { this.undetvars = this.undetvars.prepend(infer.fromTypeVarFun.apply(t)); this.inferencevars = this.inferencevars.prepend(t); } /** * returns the list of free variables (as type-variables) in this * inference context */ List inferenceVars() { return inferencevars; } /** * returns the list of undetermined variables in this inference context */ public List undetVars() { return undetvars; } /** * returns the list of uninstantiated variables (as type-variables) in this * inference context */ List restvars() { return filterVars(uv -> uv.getInst() == null); } /** * returns the list of instantiated variables (as type-variables) in this * inference context */ List instvars() { return filterVars(uv -> uv.getInst() != null); } /** * Get list of bounded inference variables (where bound is other than * declared bounds). */ final List boundedVars() { return filterVars(uv -> uv.getBounds(InferenceBound.UPPER) .diff(uv.getDeclaredBounds()) .appendList(uv.getBounds(InferenceBound.EQ, InferenceBound.LOWER)).nonEmpty()); } /* Returns the corresponding inference variables. */ private List filterVars(Filter fu) { ListBuffer res = new ListBuffer<>(); for (Type t : undetvars) { UndetVar uv = (UndetVar)t; if (fu.accepts(uv)) { res.append(uv.qtype); } } return res.toList(); } /** * is this type free? */ final boolean free(Type t) { return t.containsAny(inferencevars); } final boolean free(List ts) { for (Type t : ts) { if (free(t)) return true; } return false; } /** * Returns a list of free variables in a given type */ final List freeVarsIn(Type t) { ListBuffer buf = new ListBuffer<>(); for (Type iv : inferenceVars()) { if (t.contains(iv)) { buf.add(iv); } } return buf.toList(); } final List freeVarsIn(List ts) { ListBuffer buf = new ListBuffer<>(); for (Type t : ts) { buf.appendList(freeVarsIn(t)); } ListBuffer buf2 = new ListBuffer<>(); for (Type t : buf) { if (!buf2.contains(t)) { buf2.add(t); } } return buf2.toList(); } /** * Replace all free variables in a given type with corresponding * undet vars (used ahead of subtyping/compatibility checks to allow propagation * of inference constraints). */ public final Type asUndetVar(Type t) { return types.subst(t, inferencevars, undetvars); } final List asUndetVars(List ts) { ListBuffer buf = new ListBuffer<>(); for (Type t : ts) { buf.append(asUndetVar(t)); } return buf.toList(); } List instTypes() { ListBuffer buf = new ListBuffer<>(); for (Type t : undetvars) { UndetVar uv = (UndetVar)t; buf.append(uv.getInst() != null ? uv.getInst() : uv.qtype); } return buf.toList(); } /** * Replace all free variables in a given type with corresponding * instantiated types - if one or more free variable has not been * fully instantiated, it will still be available in the resulting type. */ Type asInstType(Type t) { return types.subst(t, inferencevars, instTypes()); } List asInstTypes(List ts) { ListBuffer buf = new ListBuffer<>(); for (Type t : ts) { buf.append(asInstType(t)); } return buf.toList(); } /** * Add custom hook for performing post-inference action */ void addFreeTypeListener(List types, FreeTypeListener ftl) { freeTypeListeners.put(ftl, freeVarsIn(types)); } /** * Mark the inference context as complete and trigger evaluation * of all deferred checks. */ void notifyChange() { notifyChange(inferencevars.diff(restvars())); } void notifyChange(List inferredVars) { InferenceException thrownEx = null; for (Map.Entry> entry : new LinkedHashMap<>(freeTypeListeners).entrySet()) { if (!Type.containsAny(entry.getValue(), inferencevars.diff(inferredVars))) { try { entry.getKey().typesInferred(this); freeTypeListeners.remove(entry.getKey()); } catch (InferenceException ex) { if (thrownEx == null) { thrownEx = ex; } } } } //inference exception multiplexing - present any inference exception //thrown when processing listeners as a single one if (thrownEx != null) { throw thrownEx; } } /** * Save the state of this inference context */ public List save() { ListBuffer buf = new ListBuffer<>(); for (Type t : undetvars) { buf.add(((UndetVar)t).dup(infer.types)); } return buf.toList(); } /** Restore the state of this inference context to the previous known checkpoint. * Consider that the number of saved undetermined variables can be different to the current * amount. This is because new captured variables could have been added. */ public void rollback(List saved_undet) { Assert.check(saved_undet != null); //restore bounds (note: we need to preserve the old instances) ListBuffer newUndetVars = new ListBuffer<>(); ListBuffer newInferenceVars = new ListBuffer<>(); while (saved_undet.nonEmpty() && undetvars.nonEmpty()) { UndetVar uv = (UndetVar)undetvars.head; UndetVar uv_saved = (UndetVar)saved_undet.head; if (uv.qtype == uv_saved.qtype) { uv_saved.dupTo(uv, types); undetvars = undetvars.tail; saved_undet = saved_undet.tail; newUndetVars.add(uv); newInferenceVars.add(uv.qtype); } else { undetvars = undetvars.tail; } } undetvars = newUndetVars.toList(); inferencevars = newInferenceVars.toList(); } /** * Copy variable in this inference context to the given context */ void dupTo(final InferenceContext that) { dupTo(that, false); } void dupTo(final InferenceContext that, boolean clone) { that.inferencevars = that.inferencevars.appendList(inferencevars.diff(that.inferencevars)); List undetsToPropagate = clone ? save() : undetvars; that.undetvars = that.undetvars.appendList(undetsToPropagate.diff(that.undetvars)); //propagate cloned undet!! //set up listeners to notify original inference contexts as //propagated vars are inferred in new context for (Type t : inferencevars) { that.freeTypeListeners.put(inferenceContext -> InferenceContext.this.notifyChange(), List.of(t)); } } InferenceContext min(List roots, boolean shouldSolve, Warner warn) { if (roots.length() == inferencevars.length()) { return this; } ReachabilityVisitor rv = new ReachabilityVisitor(); rv.scan(roots); if (rv.min.size() == inferencevars.length()) { return this; } List minVars = List.from(rv.min); List redundantVars = inferencevars.diff(minVars); //compute new undet variables (bounds associated to redundant variables are dropped) ListBuffer minUndetVars = new ListBuffer<>(); for (Type minVar : minVars) { UndetVar uv = (UndetVar)asUndetVar(minVar); Assert.check(uv.incorporationActions.isEmpty()); UndetVar uv2 = uv.dup(types); for (InferenceBound ib : InferenceBound.values()) { List newBounds = uv.getBounds(ib).stream() .filter(b -> !redundantVars.contains(b)) .collect(List.collector()); uv2.setBounds(ib, newBounds); } minUndetVars.add(uv2); } //compute new minimal inference context InferenceContext minContext = new InferenceContext(infer, minVars, minUndetVars.toList()); for (Type t : minContext.inferencevars) { //add listener that forwards notifications to original context minContext.addFreeTypeListener(List.of(t), (inferenceContext) -> { ((UndetVar)asUndetVar(t)).setInst(inferenceContext.asInstType(t)); infer.doIncorporation(inferenceContext, warn); solve(List.from(rv.minMap.get(t)), warn); notifyChange(); }); } if (shouldSolve) { //solve definitively unreachable variables List unreachableVars = redundantVars.diff(List.from(rv.equiv)); minContext.addFreeTypeListener(minVars, (inferenceContext) -> { solve(unreachableVars, warn); notifyChange(); }); } return minContext; } class ReachabilityVisitor extends Types.UnaryVisitor { Set equiv = new HashSet<>(); Set min = new HashSet<>(); Map> minMap = new HashMap<>(); void scan(List roots) { roots.stream().forEach(this::visit); } @Override public Void visitType(Type t, Void _unused) { return null; } @Override public Void visitUndetVar(UndetVar t, Void _unused) { if (min.add(t.qtype)) { Set deps = minMap.getOrDefault(t.qtype, new HashSet<>(Collections.singleton(t.qtype))); for (InferenceBound boundKind : InferenceBound.values()) { for (Type b : t.getBounds(boundKind)) { Type undet = asUndetVar(b); if (!undet.hasTag(TypeTag.UNDETVAR)) { visit(undet); } else if (isEquiv(t, b, boundKind)) { deps.add(b); equiv.add(b); } else { visit(undet); } } } minMap.put(t.qtype, deps); } return null; } @Override public Void visitWildcardType(WildcardType t, Void _unused) { return visit(t.type); } @Override public Void visitTypeVar(TypeVar t, Void aVoid) { Type undet = asUndetVar(t); if (undet.hasTag(TypeTag.UNDETVAR)) { visitUndetVar((UndetVar)undet, null); } return null; } @Override public Void visitArrayType(ArrayType t, Void _unused) { return visit(t.elemtype); } @Override public Void visitClassType(ClassType t, Void _unused) { visit(t.getEnclosingType()); for (Type targ : t.getTypeArguments()) { visit(targ); } return null; } boolean isEquiv(UndetVar from, Type t, InferenceBound boundKind) { UndetVar uv = (UndetVar)asUndetVar(t); for (InferenceBound ib : InferenceBound.values()) { List b1 = from.getBounds(ib); if (ib == boundKind) { b1 = b1.diff(List.of(t)); } List b2 = uv.getBounds(ib); if (ib == boundKind.complement()) { b2 = b2.diff(List.of(from.qtype)); } if (!b1.containsAll(b2) || !b2.containsAll(b1)) { return false; } } return true; } } /** * Solve with given graph strategy. */ private void solve(GraphStrategy ss, Warner warn) { GraphSolver s = infer.new GraphSolver(this, warn); s.solve(ss); } /** * Solve all variables in this context. */ public void solve(Warner warn) { solve(infer.new LeafSolver() { public boolean done() { return restvars().isEmpty(); } }, warn); } /** * Solve all variables in the given list. */ public void solve(final List vars, Warner warn) { solve(infer.new BestLeafSolver(vars) { public boolean done() { return !free(asInstTypes(vars)); } }, warn); } /** * Solve at least one variable in given list. */ public void solveAny(List varsToSolve, Warner warn) { solve(infer.new BestLeafSolver(varsToSolve.intersect(restvars())) { public boolean done() { return instvars().intersect(varsToSolve).nonEmpty(); } }, warn); } /** * Apply a set of inference steps */ private List solveBasic(EnumSet steps) { return solveBasic(inferencevars, steps); } List solveBasic(List varsToSolve, EnumSet steps) { ListBuffer solvedVars = new ListBuffer<>(); for (Type t : varsToSolve.intersect(restvars())) { UndetVar uv = (UndetVar)asUndetVar(t); for (InferenceStep step : steps) { if (step.accepts(uv, this)) { uv.setInst(step.solve(uv, this)); solvedVars.add(uv.qtype); break; } } } return solvedVars.toList(); } /** * Instantiate inference variables in legacy mode (JLS 15.12.2.7, 15.12.2.8). * During overload resolution, instantiation is done by doing a partial * inference process using eq/lower bound instantiation. During check, * we also instantiate any remaining vars by repeatedly using eq/upper * instantiation, until all variables are solved. */ public void solveLegacy(boolean partial, Warner warn, EnumSet steps) { while (true) { List solvedVars = solveBasic(steps); if (restvars().isEmpty() || partial) { //all variables have been instantiated - exit break; } else if (solvedVars.isEmpty()) { //some variables could not be instantiated because of cycles in //upper bounds - provide a (possibly recursive) default instantiation infer.instantiateAsUninferredVars(restvars(), this); break; } else { //some variables have been instantiated - replace newly instantiated //variables in remaining upper bounds and continue for (Type t : undetvars) { UndetVar uv = (UndetVar)t; uv.substBounds(solvedVars, asInstTypes(solvedVars), types); } } } infer.doIncorporation(this, warn); } @Override public String toString() { return "Inference vars: " + inferencevars + '\n' + "Undet vars: " + undetvars; } /* Method Types.capture() generates a new type every time it's applied * to a wildcard parameterized type. This is intended functionality but * there are some cases when what you need is not to generate a new * captured type but to check that a previously generated captured type * is correct. There are cases when caching a captured type for later * reuse is sound. In general two captures from the same AST are equal. * This is why the tree is used as the key of the map below. This map * stores a Type per AST. */ Map captureTypeCache = new HashMap<>(); Type cachedCapture(JCTree tree, Type t, boolean readOnly) { Type captured = captureTypeCache.get(tree); if (captured != null) { return captured; } Type result = types.capture(t); if (result != t && !readOnly) { // then t is a wildcard parameterized type captureTypeCache.put(tree, result); } return result; } }





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