All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.openjdk.tools.javac.util.RichDiagnosticFormatter Maven / Gradle / Ivy

The newest version!
/*
 * Copyright (c) 2009, 2016, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * 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).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
 */

package org.openjdk.tools.javac.util;

import java.nio.file.Path;
import java.util.EnumMap;
import java.util.EnumSet;
import java.util.HashMap;
import java.util.LinkedHashMap;
import java.util.Locale;
import java.util.Map;

import org.openjdk.tools.javac.code.Printer;
import org.openjdk.tools.javac.code.Symbol;
import org.openjdk.tools.javac.code.Symbol.*;
import org.openjdk.tools.javac.code.Symtab;
import org.openjdk.tools.javac.code.Type;
import org.openjdk.tools.javac.code.Type.*;
import org.openjdk.tools.javac.code.Types;

import static org.openjdk.tools.javac.code.Flags.*;
import static org.openjdk.tools.javac.code.TypeTag.*;
import static org.openjdk.tools.javac.code.Kinds.*;
import static org.openjdk.tools.javac.code.Kinds.Kind.*;
import static org.openjdk.tools.javac.util.LayoutCharacters.*;
import static org.openjdk.tools.javac.util.RichDiagnosticFormatter.RichConfiguration.*;

/**
 * A rich diagnostic formatter is a formatter that provides better integration
 * with javac's type system. A diagostic is first preprocessed in order to keep
 * track of each types/symbols in it; after these informations are collected,
 * the diagnostic is rendered using a standard formatter, whose type/symbol printer
 * has been replaced by a more refined version provided by this rich formatter.
 * The rich formatter currently enables three different features: (i) simple class
 * names - that is class names are displayed used a non qualified name (thus
 * omitting package info) whenever possible - (ii) where clause list - a list of
 * additional subdiagnostics that provide specific info about type-variables,
 * captured types, intersection types that occur in the diagnostic that is to be
 * formatted and (iii) type-variable disambiguation - when the diagnostic refers
 * to two different type-variables with the same name, their representation is
 * disambiguated by appending an index to the type variable name.
 *
 * 

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 RichDiagnosticFormatter extends ForwardingDiagnosticFormatter { final Symtab syms; final Types types; final JCDiagnostic.Factory diags; final JavacMessages messages; /* name simplifier used by this formatter */ protected ClassNameSimplifier nameSimplifier; /* type/symbol printer used by this formatter */ private RichPrinter printer; /* map for keeping track of a where clause associated to a given type */ Map> whereClauses; /** Get the DiagnosticFormatter instance for this context. */ public static RichDiagnosticFormatter instance(Context context) { RichDiagnosticFormatter instance = context.get(RichDiagnosticFormatter.class); if (instance == null) instance = new RichDiagnosticFormatter(context); return instance; } protected RichDiagnosticFormatter(Context context) { super((AbstractDiagnosticFormatter)Log.instance(context).getDiagnosticFormatter()); setRichPrinter(new RichPrinter()); this.syms = Symtab.instance(context); this.diags = JCDiagnostic.Factory.instance(context); this.types = Types.instance(context); this.messages = JavacMessages.instance(context); whereClauses = new EnumMap<>(WhereClauseKind.class); configuration = new RichConfiguration(Options.instance(context), formatter); for (WhereClauseKind kind : WhereClauseKind.values()) whereClauses.put(kind, new LinkedHashMap()); } @Override public String format(JCDiagnostic diag, Locale l) { StringBuilder sb = new StringBuilder(); nameSimplifier = new ClassNameSimplifier(); for (WhereClauseKind kind : WhereClauseKind.values()) whereClauses.get(kind).clear(); preprocessDiagnostic(diag); sb.append(formatter.format(diag, l)); if (getConfiguration().isEnabled(RichFormatterFeature.WHERE_CLAUSES)) { List clauses = getWhereClauses(); String indent = formatter.isRaw() ? "" : formatter.indentString(DetailsInc); for (JCDiagnostic d : clauses) { String whereClause = formatter.format(d, l); if (whereClause.length() > 0) { sb.append('\n' + indent + whereClause); } } } return sb.toString(); } @Override public String formatMessage(JCDiagnostic diag, Locale l) { nameSimplifier = new ClassNameSimplifier(); preprocessDiagnostic(diag); return super.formatMessage(diag, l); } /** * Sets the type/symbol printer used by this formatter. * @param printer the rich printer to be set */ protected void setRichPrinter(RichPrinter printer) { this.printer = printer; formatter.setPrinter(printer); } /** * Returns the type/symbol printer used by this formatter. * @return type/symbol rich printer */ protected RichPrinter getRichPrinter() { return printer; } /** * Preprocess a given diagnostic by looking both into its arguments and into * its subdiagnostics (if any). This preprocessing is responsible for * generating info corresponding to features like where clauses, name * simplification, etc. * * @param diag the diagnostic to be preprocessed */ protected void preprocessDiagnostic(JCDiagnostic diag) { for (Object o : diag.getArgs()) { if (o != null) { preprocessArgument(o); } } if (diag.isMultiline()) { for (JCDiagnostic d : diag.getSubdiagnostics()) preprocessDiagnostic(d); } } /** * Preprocess a diagnostic argument. A type/symbol argument is * preprocessed by specialized type/symbol preprocessors. * * @param arg the argument to be translated */ protected void preprocessArgument(Object arg) { if (arg instanceof Type) { preprocessType((Type)arg); } else if (arg instanceof Symbol) { preprocessSymbol((Symbol)arg); } else if (arg instanceof JCDiagnostic) { preprocessDiagnostic((JCDiagnostic)arg); } else if (arg instanceof Iterable && !(arg instanceof Path)) { for (Object o : (Iterable)arg) { preprocessArgument(o); } } } /** * Build a list of multiline diagnostics containing detailed info about * type-variables, captured types, and intersection types * * @return where clause list */ protected List getWhereClauses() { List clauses = List.nil(); for (WhereClauseKind kind : WhereClauseKind.values()) { List lines = List.nil(); for (Map.Entry entry : whereClauses.get(kind).entrySet()) { lines = lines.prepend(entry.getValue()); } if (!lines.isEmpty()) { String key = kind.key(); if (lines.size() > 1) key += ".1"; JCDiagnostic d = diags.fragment(key, whereClauses.get(kind).keySet()); d = new JCDiagnostic.MultilineDiagnostic(d, lines.reverse()); clauses = clauses.prepend(d); } } return clauses.reverse(); } private int indexOf(Type type, WhereClauseKind kind) { int index = 1; for (Type t : whereClauses.get(kind).keySet()) { if (t.tsym == type.tsym) { return index; } if (kind != WhereClauseKind.TYPEVAR || t.toString().equals(type.toString())) { index++; } } return -1; } private boolean unique(TypeVar typevar) { typevar = (TypeVar) typevar.stripMetadata(); int found = 0; for (Type t : whereClauses.get(WhereClauseKind.TYPEVAR).keySet()) { if (t.stripMetadata().toString().equals(typevar.toString())) { found++; } } if (found < 1) throw new AssertionError("Missing type variable in where clause: " + typevar); return found == 1; } //where /** * This enum defines all posssible kinds of where clauses that can be * attached by a rich diagnostic formatter to a given diagnostic */ enum WhereClauseKind { /** where clause regarding a type variable */ TYPEVAR("where.description.typevar"), /** where clause regarding a captured type */ CAPTURED("where.description.captured"), /** where clause regarding an intersection type */ INTERSECTION("where.description.intersection"); /** resource key for this where clause kind */ private final String key; WhereClauseKind(String key) { this.key = key; } String key() { return key; } } // /** * A name simplifier keeps track of class names usages in order to determine * whether a class name can be compacted or not. Short names are not used * if a conflict is detected, e.g. when two classes with the same simple * name belong to different packages - in this case the formatter reverts * to fullnames as compact names might lead to a confusing diagnostic. */ protected class ClassNameSimplifier { /* table for keeping track of all short name usages */ Map> nameClashes = new HashMap<>(); /** * Add a name usage to the simplifier's internal cache */ protected void addUsage(Symbol sym) { Name n = sym.getSimpleName(); List conflicts = nameClashes.get(n); if (conflicts == null) { conflicts = List.nil(); } if (!conflicts.contains(sym)) nameClashes.put(n, conflicts.append(sym)); } public String simplify(Symbol s) { String name = s.getQualifiedName().toString(); if (!s.type.isCompound() && !s.type.isPrimitive()) { List conflicts = nameClashes.get(s.getSimpleName()); if (conflicts == null || (conflicts.size() == 1 && conflicts.contains(s))) { List l = List.nil(); Symbol s2 = s; while (s2.type.hasTag(CLASS) && s2.type.getEnclosingType().hasTag(CLASS) && s2.owner.kind == TYP) { l = l.prepend(s2.getSimpleName()); s2 = s2.owner; } l = l.prepend(s2.getSimpleName()); StringBuilder buf = new StringBuilder(); String sep = ""; for (Name n2 : l) { buf.append(sep); buf.append(n2); sep = "."; } name = buf.toString(); } } return name; } } // // /** * Enhanced type/symbol printer that provides support for features like simple names * and type variable disambiguation. This enriched printer exploits the info * discovered during type/symbol preprocessing. This printer is set on the delegate * formatter so that rich type/symbol info can be properly rendered. */ protected class RichPrinter extends Printer { @Override public String localize(Locale locale, String key, Object... args) { return formatter.localize(locale, key, args); } @Override public String capturedVarId(CapturedType t, Locale locale) { return indexOf(t, WhereClauseKind.CAPTURED) + ""; } @Override public String visitType(Type t, Locale locale) { String s = super.visitType(t, locale); if (t == syms.botType) s = localize(locale, "compiler.misc.type.null"); return s; } @Override public String visitCapturedType(CapturedType t, Locale locale) { if (getConfiguration().isEnabled(RichFormatterFeature.WHERE_CLAUSES)) { return localize(locale, "compiler.misc.captured.type", indexOf(t, WhereClauseKind.CAPTURED)); } else return super.visitCapturedType(t, locale); } @Override public String visitClassType(ClassType t, Locale locale) { if (t.isCompound() && getConfiguration().isEnabled(RichFormatterFeature.WHERE_CLAUSES)) { return localize(locale, "compiler.misc.intersection.type", indexOf(t, WhereClauseKind.INTERSECTION)); } else return super.visitClassType(t, locale); } @Override protected String className(ClassType t, boolean longform, Locale locale) { Symbol sym = t.tsym; if (sym.name.length() == 0 || !getConfiguration().isEnabled(RichFormatterFeature.SIMPLE_NAMES)) { return super.className(t, longform, locale); } else if (longform) return nameSimplifier.simplify(sym).toString(); else return sym.name.toString(); } @Override public String visitTypeVar(TypeVar t, Locale locale) { if (unique(t) || !getConfiguration().isEnabled(RichFormatterFeature.UNIQUE_TYPEVAR_NAMES)) { return t.toString(); } else { return localize(locale, "compiler.misc.type.var", t.toString(), indexOf(t, WhereClauseKind.TYPEVAR)); } } @Override public String visitClassSymbol(ClassSymbol s, Locale locale) { if (s.type.isCompound()) { return visit(s.type, locale); } String name = nameSimplifier.simplify(s); if (name.length() == 0 || !getConfiguration().isEnabled(RichFormatterFeature.SIMPLE_NAMES)) { return super.visitClassSymbol(s, locale); } else { return name; } } @Override public String visitMethodSymbol(MethodSymbol s, Locale locale) { String ownerName = visit(s.owner, locale); if (s.isStaticOrInstanceInit()) { return ownerName; } else { String ms = (s.name == s.name.table.names.init) ? ownerName : s.name.toString(); if (s.type != null) { if (s.type.hasTag(FORALL)) { ms = "<" + visitTypes(s.type.getTypeArguments(), locale) + ">" + ms; } ms += "(" + printMethodArgs( s.type.getParameterTypes(), (s.flags() & VARARGS) != 0, locale) + ")"; } return ms; } } } // // /** * Preprocess a given type looking for (i) additional info (where clauses) to be * added to the main diagnostic (ii) names to be compacted. */ protected void preprocessType(Type t) { typePreprocessor.visit(t); } //where protected Types.UnaryVisitor typePreprocessor = new Types.UnaryVisitor() { public Void visit(List ts) { for (Type t : ts) visit(t); return null; } @Override public Void visitForAll(ForAll t, Void ignored) { visit(t.tvars); visit(t.qtype); return null; } @Override public Void visitMethodType(MethodType t, Void ignored) { visit(t.argtypes); visit(t.restype); return null; } @Override public Void visitErrorType(ErrorType t, Void ignored) { Type ot = t.getOriginalType(); if (ot != null) visit(ot); return null; } @Override public Void visitArrayType(ArrayType t, Void ignored) { visit(t.elemtype); return null; } @Override public Void visitWildcardType(WildcardType t, Void ignored) { visit(t.type); return null; } public Void visitType(Type t, Void ignored) { return null; } @Override public Void visitCapturedType(CapturedType t, Void ignored) { if (indexOf(t, WhereClauseKind.CAPTURED) == -1) { String suffix = t.lower == syms.botType ? ".1" : ""; JCDiagnostic d = diags.fragment("where.captured"+ suffix, t, t.bound, t.lower, t.wildcard); whereClauses.get(WhereClauseKind.CAPTURED).put(t, d); visit(t.wildcard); visit(t.lower); visit(t.bound); } return null; } @Override public Void visitClassType(ClassType t, Void ignored) { if (t.isCompound()) { if (indexOf(t, WhereClauseKind.INTERSECTION) == -1) { Type supertype = types.supertype(t); List interfaces = types.interfaces(t); JCDiagnostic d = diags.fragment("where.intersection", t, interfaces.prepend(supertype)); whereClauses.get(WhereClauseKind.INTERSECTION).put(t, d); visit(supertype); visit(interfaces); } } else if (t.tsym.name.isEmpty()) { //anon class ClassType norm = (ClassType) t.tsym.type; if (norm != null) { if (norm.interfaces_field != null && norm.interfaces_field.nonEmpty()) { visit(norm.interfaces_field.head); } else { visit(norm.supertype_field); } } } nameSimplifier.addUsage(t.tsym); visit(t.getTypeArguments()); if (t.getEnclosingType() != Type.noType) visit(t.getEnclosingType()); return null; } @Override public Void visitTypeVar(TypeVar t, Void ignored) { t = (TypeVar)t.stripMetadataIfNeeded(); if (indexOf(t, WhereClauseKind.TYPEVAR) == -1) { //access the bound type and skip error types Type bound = t.bound; while ((bound instanceof ErrorType)) bound = ((ErrorType)bound).getOriginalType(); //retrieve the bound list - if the type variable //has not been attributed the bound is not set List bounds = (bound != null) && (bound.hasTag(CLASS) || bound.hasTag(TYPEVAR)) ? types.getBounds(t) : List.nil(); nameSimplifier.addUsage(t.tsym); boolean boundErroneous = bounds.head == null || bounds.head.hasTag(NONE) || bounds.head.hasTag(ERROR); if ((t.tsym.flags() & SYNTHETIC) == 0) { //this is a true typevar JCDiagnostic d = diags.fragment("where.typevar" + (boundErroneous ? ".1" : ""), t, bounds, kindName(t.tsym.location()), t.tsym.location()); whereClauses.get(WhereClauseKind.TYPEVAR).put(t, d); symbolPreprocessor.visit(t.tsym.location(), null); visit(bounds); } else { Assert.check(!boundErroneous); //this is a fresh (synthetic) tvar JCDiagnostic d = diags.fragment("where.fresh.typevar", t, bounds); whereClauses.get(WhereClauseKind.TYPEVAR).put(t, d); visit(bounds); } } return null; } }; // // /** * Preprocess a given symbol looking for (i) additional info (where clauses) to be * added to the main diagnostic (ii) names to be compacted */ protected void preprocessSymbol(Symbol s) { symbolPreprocessor.visit(s, null); } //where protected Types.DefaultSymbolVisitor symbolPreprocessor = new Types.DefaultSymbolVisitor() { @Override public Void visitClassSymbol(ClassSymbol s, Void ignored) { if (s.type.isCompound()) { typePreprocessor.visit(s.type); } else { nameSimplifier.addUsage(s); } return null; } @Override public Void visitSymbol(Symbol s, Void ignored) { return null; } @Override public Void visitMethodSymbol(MethodSymbol s, Void ignored) { visit(s.owner, null); if (s.type != null) typePreprocessor.visit(s.type); return null; } }; // @Override public RichConfiguration getConfiguration() { //the following cast is always safe - see init return (RichConfiguration)configuration; } /** * Configuration object provided by the rich formatter. */ public static class RichConfiguration extends ForwardingDiagnosticFormatter.ForwardingConfiguration { /** set of enabled rich formatter's features */ protected java.util.EnumSet features; @SuppressWarnings("fallthrough") public RichConfiguration(Options options, AbstractDiagnosticFormatter formatter) { super(formatter.getConfiguration()); features = formatter.isRaw() ? EnumSet.noneOf(RichFormatterFeature.class) : EnumSet.of(RichFormatterFeature.SIMPLE_NAMES, RichFormatterFeature.WHERE_CLAUSES, RichFormatterFeature.UNIQUE_TYPEVAR_NAMES); String diagOpts = options.get("diags.formatterOptions"); if (diagOpts != null) { for (String args: diagOpts.split(",")) { if (args.equals("-where")) { features.remove(RichFormatterFeature.WHERE_CLAUSES); } else if (args.equals("where")) { features.add(RichFormatterFeature.WHERE_CLAUSES); } if (args.equals("-simpleNames")) { features.remove(RichFormatterFeature.SIMPLE_NAMES); } else if (args.equals("simpleNames")) { features.add(RichFormatterFeature.SIMPLE_NAMES); } if (args.equals("-disambiguateTvars")) { features.remove(RichFormatterFeature.UNIQUE_TYPEVAR_NAMES); } else if (args.equals("disambiguateTvars")) { features.add(RichFormatterFeature.UNIQUE_TYPEVAR_NAMES); } } } } /** * Returns a list of all the features supported by the rich formatter. * @return list of supported features */ public RichFormatterFeature[] getAvailableFeatures() { return RichFormatterFeature.values(); } /** * Enable a specific feature on this rich formatter. * @param feature feature to be enabled */ public void enable(RichFormatterFeature feature) { features.add(feature); } /** * Disable a specific feature on this rich formatter. * @param feature feature to be disabled */ public void disable(RichFormatterFeature feature) { features.remove(feature); } /** * Is a given feature enabled on this formatter? * @param feature feature to be tested */ public boolean isEnabled(RichFormatterFeature feature) { return features.contains(feature); } /** * The advanced formatting features provided by the rich formatter */ public enum RichFormatterFeature { /** a list of additional info regarding a given type/symbol */ WHERE_CLAUSES, /** full class names simplification (where possible) */ SIMPLE_NAMES, /** type-variable names disambiguation */ UNIQUE_TYPEVAR_NAMES } } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy