Mercurial > hg > jdk9-shenandoah > langtools
view src/jdk.compiler/share/classes/com/sun/tools/sjavac/JavacState.java @ 3022:5ba1a29a0eb0
8129114: Sjavac should stream back compiler output to the client as soon as it becomes available
Summary: Protocol revised, javac output sent back to client slightly earlier.
Reviewed-by: jlahoda
| author | alundblad |
|---|---|
| date | Fri, 04 Sep 2015 13:24:15 +0200 |
| parents | adba44f6b471 |
| children |
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/* * Copyright (c) 2012, 2015, 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 com.sun.tools.sjavac; import java.io.BufferedReader; import java.io.File; import java.io.FileNotFoundException; import java.io.FileReader; import java.io.FileWriter; import java.io.IOException; import java.io.Writer; import java.net.URI; import java.nio.file.NoSuchFileException; import java.text.SimpleDateFormat; import java.util.Collection; import java.util.Collections; import java.util.Date; import java.util.HashMap; import java.util.HashSet; import java.util.List; import java.util.Map; import java.util.Set; import java.util.stream.Collectors; import com.sun.tools.sjavac.comp.CompilationService; import com.sun.tools.sjavac.options.Options; import com.sun.tools.sjavac.pubapi.PubApi; /** * The javac state class maintains the previous (prev) and the current (now) * build states and everything else that goes into the javac_state file. * * <p><b>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.</b> */ public class JavacState { // The arguments to the compile. If not identical, then it cannot // be an incremental build! String theArgs; // The number of cores limits how many threads are used for heavy concurrent work. int numCores; // The bin_dir/javac_state private File javacState; // The previous build state is loaded from javac_state private BuildState prev; // The current build state is constructed during the build, // then saved as the new javac_state. private BuildState now; // Something has changed in the javac_state. It needs to be saved! private boolean needsSaving; // If this is a new javac_state file, then do not print unnecessary messages. private boolean newJavacState; // These are packages where something has changed and the package // needs to be recompiled. Actions that trigger recompilation: // * source belonging to the package has changed // * artifact belonging to the package is lost, or its timestamp has been changed. // * an unknown artifact has appeared, we simply delete it, but we also trigger a recompilation. // * a package that is tainted, taints all packages that depend on it. private Set<String> taintedPackages; // After a compile, the pubapis are compared with the pubapis stored in the javac state file. // Any packages where the pubapi differ are added to this set. // Later we use this set and the dependency information to taint dependent packages. private Set<String> packagesWithChangedPublicApis; // When a module-info.java file is changed, taint the module, // then taint all modules that depend on that that module. // A module dependency can occur directly through a require, or // indirectly through a module that does a public export for the first tainted module. // When all modules are tainted, then taint all packages belonging to these modules. // Then rebuild. It is perhaps possible (and valuable?) to do a more finegrained examination of the // change in module-info.java, but that will have to wait. private Set<String> taintedModules; // The set of all packages that has been recompiled. // Copy over the javac_state for the packages that did not need recompilation, // verbatim from the previous (prev) to the new (now) build state. private Set<String> recompiledPackages; // The output directories filled with tasty artifacts. private File binDir, gensrcDir, headerDir, stateDir; // The current status of the file system. private Set<File> binArtifacts; private Set<File> gensrcArtifacts; private Set<File> headerArtifacts; // The status of the sources. Set<Source> removedSources = null; Set<Source> addedSources = null; Set<Source> modifiedSources = null; // Visible sources for linking. These are the only // ones that -sourcepath is allowed to see. Set<URI> visibleSrcs; // Visible classes for linking. These are the only // ones that -classpath is allowed to see. // It maps from a classpath root to the set of visible classes for that root. // If the set is empty, then all classes are visible for that root. // It can also map from a jar file to the set of visible classes for that jar file. Map<URI,Set<String>> visibleClasses; // Setup transform that always exist. private CompileJavaPackages compileJavaPackages = new CompileJavaPackages(); // Where to send stdout and stderr. private Writer out, err; // Command line options. private Options options; JavacState(Options op, boolean removeJavacState, Writer o, Writer e) { options = op; out = o; err = e; numCores = options.getNumCores(); theArgs = options.getStateArgsString(); binDir = Util.pathToFile(options.getDestDir()); gensrcDir = Util.pathToFile(options.getGenSrcDir()); headerDir = Util.pathToFile(options.getHeaderDir()); stateDir = Util.pathToFile(options.getStateDir()); javacState = new File(stateDir, "javac_state"); if (removeJavacState && javacState.exists()) { javacState.delete(); } newJavacState = false; if (!javacState.exists()) { newJavacState = true; // If there is no javac_state then delete the contents of all the artifact dirs! // We do not want to risk building a broken incremental build. // BUT since the makefiles still copy things straight into the bin_dir et al, // we avoid deleting files here, if the option --permit-unidentified-classes was supplied. if (!options.areUnidentifiedArtifactsPermitted()) { deleteContents(binDir); deleteContents(gensrcDir); deleteContents(headerDir); } needsSaving = true; } prev = new BuildState(); now = new BuildState(); taintedPackages = new HashSet<>(); recompiledPackages = new HashSet<>(); packagesWithChangedPublicApis = new HashSet<>(); } public BuildState prev() { return prev; } public BuildState now() { return now; } /** * Remove args not affecting the state. */ static String[] removeArgsNotAffectingState(String[] args) { String[] out = new String[args.length]; int j = 0; for (int i = 0; i<args.length; ++i) { if (args[i].equals("-j")) { // Just skip it and skip following value i++; } else if (args[i].startsWith("--server:")) { // Just skip it. } else if (args[i].startsWith("--log=")) { // Just skip it. } else if (args[i].equals("--compare-found-sources")) { // Just skip it and skip verify file name i++; } else { // Copy argument. out[j] = args[i]; j++; } } String[] ret = new String[j]; System.arraycopy(out, 0, ret, 0, j); return ret; } /** * Specify which sources are visible to the compiler through -sourcepath. */ public void setVisibleSources(Map<String,Source> vs) { visibleSrcs = new HashSet<>(); for (String s : vs.keySet()) { Source src = vs.get(s); visibleSrcs.add(src.file().toURI()); } } /** * Specify which classes are visible to the compiler through -classpath. */ public void setVisibleClasses(Map<String,Source> vs) { visibleSrcs = new HashSet<>(); for (String s : vs.keySet()) { Source src = vs.get(s); visibleSrcs.add(src.file().toURI()); } } /** * Returns true if this is an incremental build. */ public boolean isIncremental() { return !prev.sources().isEmpty(); } /** * Find all artifacts that exists on disk. */ public void findAllArtifacts() { binArtifacts = findAllFiles(binDir); gensrcArtifacts = findAllFiles(gensrcDir); headerArtifacts = findAllFiles(headerDir); } /** * Lookup the artifacts generated for this package in the previous build. */ private Map<String,File> fetchPrevArtifacts(String pkg) { Package p = prev.packages().get(pkg); if (p != null) { return p.artifacts(); } return new HashMap<>(); } /** * Delete all prev artifacts in the currently tainted packages. */ public void deleteClassArtifactsInTaintedPackages() { for (String pkg : taintedPackages) { Map<String,File> arts = fetchPrevArtifacts(pkg); for (File f : arts.values()) { if (f.exists() && f.getName().endsWith(".class")) { f.delete(); } } } } /** * Mark the javac_state file to be in need of saving and as a side effect, * it gets a new timestamp. */ private void needsSaving() { needsSaving = true; } /** * Save the javac_state file. */ public void save() throws IOException { if (!needsSaving) return; try (FileWriter out = new FileWriter(javacState)) { StringBuilder b = new StringBuilder(); long millisNow = System.currentTimeMillis(); Date d = new Date(millisNow); SimpleDateFormat df = new SimpleDateFormat("yyyy-MM-dd HH:mm:ss SSS"); b.append("# javac_state ver 0.4 generated "+millisNow+" "+df.format(d)+"\n"); b.append("# This format might change at any time. Please do not depend on it.\n"); b.append("# R arguments\n"); b.append("# M module\n"); b.append("# P package\n"); b.append("# S C source_tobe_compiled timestamp\n"); b.append("# S L link_only_source timestamp\n"); b.append("# G C generated_source timestamp\n"); b.append("# A artifact timestamp\n"); b.append("# D S dependant -> source dependency\n"); b.append("# D C dependant -> classpath dependency\n"); b.append("# I pubapi\n"); b.append("R ").append(theArgs).append("\n"); // Copy over the javac_state for the packages that did not need recompilation. now.copyPackagesExcept(prev, recompiledPackages, new HashSet<String>()); // Save the packages, ie package names, dependencies, pubapis and artifacts! // I.e. the lot. Module.saveModules(now.modules(), b); String s = b.toString(); out.write(s, 0, s.length()); } } /** * Load a javac_state file. */ public static JavacState load(Options options, Writer out, Writer err) { JavacState db = new JavacState(options, false, out, err); Module lastModule = null; Package lastPackage = null; Source lastSource = null; boolean noFileFound = false; boolean foundCorrectVerNr = false; boolean newCommandLine = false; boolean syntaxError = false; Log.debug("Loading javac state file: " + db.javacState); try (BufferedReader in = new BufferedReader(new FileReader(db.javacState))) { for (;;) { String l = in.readLine(); if (l==null) break; if (l.length()>=3 && l.charAt(1) == ' ') { char c = l.charAt(0); if (c == 'M') { lastModule = db.prev.loadModule(l); } else if (c == 'P') { if (lastModule == null) { syntaxError = true; break; } lastPackage = db.prev.loadPackage(lastModule, l); } else if (c == 'D') { if (lastModule == null || lastPackage == null) { syntaxError = true; break; } char depType = l.charAt(2); if (depType != 'S' && depType != 'C') throw new RuntimeException("Bad dependency string: " + l); lastPackage.parseAndAddDependency(l.substring(4), depType == 'C'); } else if (c == 'I') { if (lastModule == null || lastPackage == null) { syntaxError = true; break; } lastPackage.getPubApi().appendItem(l.substring(2)); // Strip "I " } else if (c == 'A') { if (lastModule == null || lastPackage == null) { syntaxError = true; break; } lastPackage.loadArtifact(l); } else if (c == 'S') { if (lastModule == null || lastPackage == null) { syntaxError = true; break; } lastSource = db.prev.loadSource(lastPackage, l, false); } else if (c == 'G') { if (lastModule == null || lastPackage == null) { syntaxError = true; break; } lastSource = db.prev.loadSource(lastPackage, l, true); } else if (c == 'R') { String ncmdl = "R "+db.theArgs; if (!l.equals(ncmdl)) { newCommandLine = true; } } else if (c == '#') { if (l.startsWith("# javac_state ver ")) { int sp = l.indexOf(" ", 18); if (sp != -1) { String ver = l.substring(18,sp); if (!ver.equals("0.4")) { break; } foundCorrectVerNr = true; } } } } } } catch (FileNotFoundException | NoSuchFileException e) { // Silently create a new javac_state file. noFileFound = true; } catch (IOException e) { Log.info("Dropping old javac_state because of errors when reading it."); db = new JavacState(options, true, out, err); foundCorrectVerNr = true; newCommandLine = false; syntaxError = false; } if (foundCorrectVerNr == false && !noFileFound) { Log.info("Dropping old javac_state since it is of an old version."); db = new JavacState(options, true, out, err); } else if (newCommandLine == true && !noFileFound) { Log.info("Dropping old javac_state since a new command line is used!"); db = new JavacState(options, true, out, err); } else if (syntaxError == true) { Log.info("Dropping old javac_state since it contains syntax errors."); db = new JavacState(options, true, out, err); } db.prev.calculateDependents(); return db; } /** * Mark a java package as tainted, ie it needs recompilation. */ public void taintPackage(String name, String because) { if (!taintedPackages.contains(name)) { if (because != null) Log.debug("Tainting "+Util.justPackageName(name)+" because "+because); // It has not been tainted before. taintedPackages.add(name); needsSaving(); Package nowp = now.packages().get(name); if (nowp != null) { for (String d : nowp.dependents()) { taintPackage(d, because); } } } } /** * This packages need recompilation. */ public Set<String> taintedPackages() { return taintedPackages; } /** * Clean out the tainted package set, used after the first round of compiles, * prior to propagating dependencies. */ public void clearTaintedPackages() { taintedPackages = new HashSet<>(); } /** * Go through all sources and check which have been removed, added or modified * and taint the corresponding packages. */ public void checkSourceStatus(boolean check_gensrc) { removedSources = calculateRemovedSources(); for (Source s : removedSources) { if (!s.isGenerated() || check_gensrc) { taintPackage(s.pkg().name(), "source "+s.name()+" was removed"); } } addedSources = calculateAddedSources(); for (Source s : addedSources) { String msg = null; if (isIncremental()) { // When building from scratch, there is no point // printing "was added" for every file since all files are added. // However for an incremental build it makes sense. msg = "source "+s.name()+" was added"; } if (!s.isGenerated() || check_gensrc) { taintPackage(s.pkg().name(), msg); } } modifiedSources = calculateModifiedSources(); for (Source s : modifiedSources) { if (!s.isGenerated() || check_gensrc) { taintPackage(s.pkg().name(), "source "+s.name()+" was modified"); } } } /** * Acquire the compile_java_packages suffix rule for .java files. */ public Map<String,Transformer> getJavaSuffixRule() { Map<String,Transformer> sr = new HashMap<>(); sr.put(".java", compileJavaPackages); return sr; } /** * If artifacts have gone missing, force a recompile of the packages * they belong to. */ public void taintPackagesThatMissArtifacts() { for (Package pkg : prev.packages().values()) { for (File f : pkg.artifacts().values()) { if (!f.exists()) { // Hmm, the artifact on disk does not exist! Someone has removed it.... // Lets rebuild the package. taintPackage(pkg.name(), ""+f+" is missing."); } } } } /** * Propagate recompilation through the dependency chains. * Avoid re-tainting packages that have already been compiled. */ public void taintPackagesDependingOnChangedPackages(Set<String> pkgsWithChangedPubApi, Set<String> recentlyCompiled) { // For each to-be-recompiled-candidates... for (Package pkg : new HashSet<>(prev.packages().values())) { // Find out what it depends upon... Set<String> deps = pkg.typeDependencies() .values() .stream() .flatMap(s -> s.stream()) .collect(Collectors.toSet()); for (String dep : deps) { String depPkg = ":" + dep.substring(0, dep.lastIndexOf('.')); if (depPkg.equals(pkg.name())) continue; // Checking if that dependency has changed if (pkgsWithChangedPubApi.contains(depPkg) && !recentlyCompiled.contains(pkg.name())) { taintPackage(pkg.name(), "its depending on " + depPkg); } } } } /** * Compare the javac_state recorded public apis of packages on the classpath * with the actual public apis on the classpath. */ public void taintPackagesDependingOnChangedClasspathPackages() { // 1. Collect fully qualified names of all interesting classpath dependencies Set<String> fqDependencies = new HashSet<>(); for (Package pkg : prev.packages().values()) { // Check if this package was compiled. If it's presence is recorded // because it was on the class path and we needed to save it's // public api, it's not a candidate for tainting. if (pkg.sources().isEmpty()) continue; pkg.typeClasspathDependencies().values().forEach(fqDependencies::addAll); } // 2. Extract the public APIs from the on disk .class files // (Reason for doing step 1 in a separate phase is to avoid extracting // public APIs of the same class twice.) PubApiExtractor pubApiExtractor = new PubApiExtractor(options); Map<String, PubApi> onDiskPubApi = new HashMap<>(); for (String cpDep : fqDependencies) { onDiskPubApi.put(cpDep, pubApiExtractor.getPubApi(cpDep)); } // 3. Compare them with the public APIs as of last compilation (loaded from javac_state) nextPkg: for (Package pkg : prev.packages().values()) { // Check if this package was compiled. If it's presence is recorded // because it was on the class path and we needed to save it's // public api, it's not a candidate for tainting. if (pkg.sources().isEmpty()) continue; Set<String> cpDepsOfThisPkg = new HashSet<>(); for (Set<String> cpDeps : pkg.typeClasspathDependencies().values()) cpDepsOfThisPkg.addAll(cpDeps); for (String fqDep : cpDepsOfThisPkg) { String depPkg = ":" + fqDep.substring(0, fqDep.lastIndexOf('.')); PubApi prevPkgApi = prev.packages().get(depPkg).getPubApi(); // This PubApi directly lists the members of the class, // i.e. [ MEMBER1, MEMBER2, ... ] PubApi prevDepApi = prevPkgApi.types.get(fqDep).pubApi; // In order to dive *into* the class, we need to add // .types.get(fqDep).pubApi below. PubApi currentDepApi = onDiskPubApi.get(fqDep).types.get(fqDep).pubApi; if (!currentDepApi.isBackwardCompatibleWith(prevDepApi)) { List<String> apiDiff = currentDepApi.diff(prevDepApi); taintPackage(pkg.name(), "depends on classpath " + "package which has an updated package api: " + String.join("\n", apiDiff)); //Log.debug("========================================"); //Log.debug("------ PREV API ------------------------"); //prevDepApi.asListOfStrings().forEach(Log::debug); //Log.debug("------ CURRENT API ---------------------"); //currentDepApi.asListOfStrings().forEach(Log::debug); //Log.debug("========================================"); continue nextPkg; } } } } /** * Scan all output dirs for artifacts and remove those files (artifacts?) * that are not recognized as such, in the javac_state file. */ public void removeUnidentifiedArtifacts() { Set<File> allKnownArtifacts = new HashSet<>(); for (Package pkg : prev.packages().values()) { for (File f : pkg.artifacts().values()) { allKnownArtifacts.add(f); } } // Do not forget about javac_state.... allKnownArtifacts.add(javacState); for (File f : binArtifacts) { if (!allKnownArtifacts.contains(f) && !options.isUnidentifiedArtifactPermitted(f.getAbsolutePath())) { Log.debug("Removing "+f.getPath()+" since it is unknown to the javac_state."); f.delete(); } } for (File f : headerArtifacts) { if (!allKnownArtifacts.contains(f)) { Log.debug("Removing "+f.getPath()+" since it is unknown to the javac_state."); f.delete(); } } for (File f : gensrcArtifacts) { if (!allKnownArtifacts.contains(f)) { Log.debug("Removing "+f.getPath()+" since it is unknown to the javac_state."); f.delete(); } } } /** * Remove artifacts that are no longer produced when compiling! */ public void removeSuperfluousArtifacts(Set<String> recentlyCompiled) { // Nothing to do, if nothing was recompiled. if (recentlyCompiled.size() == 0) return; for (String pkg : now.packages().keySet()) { // If this package has not been recompiled, skip the check. if (!recentlyCompiled.contains(pkg)) continue; Collection<File> arts = now.artifacts().values(); for (File f : fetchPrevArtifacts(pkg).values()) { if (!arts.contains(f)) { Log.debug("Removing "+f.getPath()+" since it is now superfluous!"); if (f.exists()) f.delete(); } } } } /** * Return those files belonging to prev, but not now. */ private Set<Source> calculateRemovedSources() { Set<Source> removed = new HashSet<>(); for (String src : prev.sources().keySet()) { if (now.sources().get(src) == null) { removed.add(prev.sources().get(src)); } } return removed; } /** * Return those files belonging to now, but not prev. */ private Set<Source> calculateAddedSources() { Set<Source> added = new HashSet<>(); for (String src : now.sources().keySet()) { if (prev.sources().get(src) == null) { added.add(now.sources().get(src)); } } return added; } /** * Return those files where the timestamp is newer. * If a source file timestamp suddenly is older than what is known * about it in javac_state, then consider it modified, but print * a warning! */ private Set<Source> calculateModifiedSources() { Set<Source> modified = new HashSet<>(); for (String src : now.sources().keySet()) { Source n = now.sources().get(src); Source t = prev.sources().get(src); if (prev.sources().get(src) != null) { if (t != null) { if (n.lastModified() > t.lastModified()) { modified.add(n); } else if (n.lastModified() < t.lastModified()) { modified.add(n); Log.warn("The source file "+n.name()+" timestamp has moved backwards in time."); } } } } return modified; } /** * Recursively delete a directory and all its contents. */ private void deleteContents(File dir) { if (dir != null && dir.exists()) { for (File f : dir.listFiles()) { if (f.isDirectory()) { deleteContents(f); } if (!options.isUnidentifiedArtifactPermitted(f.getAbsolutePath())) { Log.debug("Removing "+f.getAbsolutePath()); f.delete(); } } } } /** * Run the copy translator only. */ public void performCopying(File binDir, Map<String,Transformer> suffixRules) { Map<String,Transformer> sr = new HashMap<>(); for (Map.Entry<String,Transformer> e : suffixRules.entrySet()) { if (e.getValue().getClass().equals(CopyFile.class)) { sr.put(e.getKey(), e.getValue()); } } perform(null, binDir, sr); } /** * Run all the translators that translate into java source code. * I.e. all translators that are not copy nor compile_java_source. */ public void performTranslation(File gensrcDir, Map<String,Transformer> suffixRules) { Map<String,Transformer> sr = new HashMap<>(); for (Map.Entry<String,Transformer> e : suffixRules.entrySet()) { Class<?> trClass = e.getValue().getClass(); if (trClass == CompileJavaPackages.class || trClass == CopyFile.class) continue; sr.put(e.getKey(), e.getValue()); } perform(null, gensrcDir, sr); } /** * Compile all the java sources. Return true, if it needs to be called again! */ public boolean performJavaCompilations(CompilationService sjavac, Options args, Set<String> recentlyCompiled, boolean[] rcValue) { Map<String,Transformer> suffixRules = new HashMap<>(); suffixRules.put(".java", compileJavaPackages); compileJavaPackages.setExtra(args); rcValue[0] = perform(sjavac, binDir, suffixRules); recentlyCompiled.addAll(taintedPackages()); clearTaintedPackages(); boolean again = !packagesWithChangedPublicApis.isEmpty(); taintPackagesDependingOnChangedPackages(packagesWithChangedPublicApis, recentlyCompiled); packagesWithChangedPublicApis = new HashSet<>(); return again && rcValue[0]; // TODO: Figure out why 'again' checks packagesWithChangedPublicAPis. // (It shouldn't matter if packages had changed pub apis as long as no // one depends on them. Wouldn't it make more sense to let 'again' // depend on taintedPackages?) } /** * Store the source into the set of sources belonging to the given transform. */ private void addFileToTransform(Map<Transformer,Map<String,Set<URI>>> gs, Transformer t, Source s) { Map<String,Set<URI>> fs = gs.get(t); if (fs == null) { fs = new HashMap<>(); gs.put(t, fs); } Set<URI> ss = fs.get(s.pkg().name()); if (ss == null) { ss = new HashSet<>(); fs.put(s.pkg().name(), ss); } ss.add(s.file().toURI()); } /** * For all packages, find all sources belonging to the package, group the sources * based on their transformers and apply the transformers on each source code group. */ private boolean perform(CompilationService sjavac, File outputDir, Map<String,Transformer> suffixRules) { boolean rc = true; // Group sources based on transforms. A source file can only belong to a single transform. Map<Transformer,Map<String,Set<URI>>> groupedSources = new HashMap<>(); for (Source src : now.sources().values()) { Transformer t = suffixRules.get(src.suffix()); if (t != null) { if (taintedPackages.contains(src.pkg().name()) && !src.isLinkedOnly()) { addFileToTransform(groupedSources, t, src); } } } // Go through the transforms and transform them. for (Map.Entry<Transformer, Map<String, Set<URI>>> e : groupedSources.entrySet()) { Transformer t = e.getKey(); Map<String, Set<URI>> srcs = e.getValue(); // These maps need to be synchronized since multiple threads will be // writing results into them. Map<String, Set<URI>> packageArtifacts = Collections.synchronizedMap(new HashMap<>()); Map<String, Map<String, Set<String>>> packageDependencies = Collections.synchronizedMap(new HashMap<>()); Map<String, Map<String, Set<String>>> packageCpDependencies = Collections.synchronizedMap(new HashMap<>()); Map<String, PubApi> packagePublicApis = Collections.synchronizedMap(new HashMap<>()); Map<String, PubApi> dependencyPublicApis = Collections.synchronizedMap(new HashMap<>()); boolean r = t.transform(sjavac, srcs, visibleSrcs, visibleClasses, prev.dependents(), outputDir.toURI(), packageArtifacts, packageDependencies, packageCpDependencies, packagePublicApis, dependencyPublicApis, 0, isIncremental(), numCores, out, err); if (!r) rc = false; for (String p : srcs.keySet()) { recompiledPackages.add(p); } // The transform is done! Extract all the artifacts and store the info into the Package objects. for (Map.Entry<String, Set<URI>> a : packageArtifacts.entrySet()) { Module mnow = now.findModuleFromPackageName(a.getKey()); mnow.addArtifacts(a.getKey(), a.getValue()); } // Extract all the dependencies and store the info into the Package objects. for (Map.Entry<String, Map<String, Set<String>>> a : packageDependencies.entrySet()) { Map<String, Set<String>> deps = a.getValue(); Module mnow = now.findModuleFromPackageName(a.getKey()); mnow.setDependencies(a.getKey(), deps, false); } for (Map.Entry<String, Map<String, Set<String>>> a : packageCpDependencies.entrySet()) { Map<String, Set<String>> deps = a.getValue(); Module mnow = now.findModuleFromPackageName(a.getKey()); mnow.setDependencies(a.getKey(), deps, true); } // This map contains the public api of the types that this // compilation depended upon. This means that it may not contain // full packages. In other words, we shouldn't remove knowledge of // public apis but merge these with what we already have. for (Map.Entry<String, PubApi> a : dependencyPublicApis.entrySet()) { String pkg = a.getKey(); PubApi packagePartialPubApi = a.getValue(); Package pkgNow = now.findModuleFromPackageName(pkg).lookupPackage(pkg); PubApi currentPubApi = pkgNow.getPubApi(); PubApi newPubApi = PubApi.mergeTypes(currentPubApi, packagePartialPubApi); pkgNow.setPubapi(newPubApi); // See JDK-8071904 if (now.packages().containsKey(pkg)) now.packages().get(pkg).setPubapi(newPubApi); else now.packages().put(pkg, pkgNow); } // The packagePublicApis cover entire packages (since sjavac compiles // stuff on package level). This means that if a type is missing // in the public api of a given package, it means that it has been // removed. In other words, we should *set* the pubapi to whatever // this map contains, and not merge it with what we already have. for (Map.Entry<String, PubApi> a : packagePublicApis.entrySet()) { String pkg = a.getKey(); PubApi newPubApi = a.getValue(); Module mprev = prev.findModuleFromPackageName(pkg); Module mnow = now.findModuleFromPackageName(pkg); mnow.setPubapi(pkg, newPubApi); if (mprev.hasPubapiChanged(pkg, newPubApi)) { // Aha! The pubapi of this package has changed! // It can also be a new compile from scratch. if (mprev.lookupPackage(pkg).existsInJavacState()) { // This is an incremental compile! The pubapi // did change. Trigger recompilation of dependents. packagesWithChangedPublicApis.add(pkg); Log.info("The API of " + Util.justPackageName(pkg) + " has changed!"); } } } } return rc; } /** * Utility method to recursively find all files below a directory. */ private static Set<File> findAllFiles(File dir) { Set<File> foundFiles = new HashSet<>(); if (dir == null) { return foundFiles; } recurse(dir, foundFiles); return foundFiles; } private static void recurse(File dir, Set<File> foundFiles) { for (File f : dir.listFiles()) { if (f.isFile()) { foundFiles.add(f); } else if (f.isDirectory()) { recurse(f, foundFiles); } } } /** * Compare the calculate source list, with an explicit list, usually * supplied from the makefile. Used to detect bugs where the makefile and * sjavac have different opinions on which files should be compiled. */ public void compareWithMakefileList(File makefileSourceList) throws ProblemException { // If we are building on win32 using for example cygwin the paths in the // makefile source list // might be /cygdrive/c/.... which does not match c:\.... // We need to adjust our calculated sources to be identical, if // necessary. boolean mightNeedRewriting = File.pathSeparatorChar == ';'; if (makefileSourceList == null) return; Set<String> calculatedSources = new HashSet<>(); Set<String> listedSources = new HashSet<>(); // Create a set of filenames with full paths. for (Source s : now.sources().values()) { // Don't include link only sources when comparing sources to compile if (!s.isLinkedOnly()) { String path = s.file().getPath(); if (mightNeedRewriting) path = Util.normalizeDriveLetter(path); calculatedSources.add(path); } } // Read in the file and create another set of filenames with full paths. try { BufferedReader in = new BufferedReader(new FileReader(makefileSourceList)); for (;;) { String l = in.readLine(); if (l==null) break; l = l.trim(); if (mightNeedRewriting) { if (l.indexOf(":") == 1 && l.indexOf("\\") == 2) { // Everything a-ok, the format is already C:\foo\bar } else if (l.indexOf(":") == 1 && l.indexOf("/") == 2) { // The format is C:/foo/bar, rewrite into the above format. l = l.replaceAll("/","\\\\"); } else if (l.charAt(0) == '/' && l.indexOf("/",1) != -1) { // The format might be: /cygdrive/c/foo/bar, rewrite into the above format. // Do not hardcode the name cygdrive here. int slash = l.indexOf("/",1); l = l.replaceAll("/","\\\\"); l = ""+l.charAt(slash+1)+":"+l.substring(slash+2); } if (Character.isLowerCase(l.charAt(0))) { l = Character.toUpperCase(l.charAt(0))+l.substring(1); } } listedSources.add(l); } } catch (FileNotFoundException | NoSuchFileException e) { throw new ProblemException("Could not open "+makefileSourceList.getPath()+" since it does not exist!"); } catch (IOException e) { throw new ProblemException("Could not read "+makefileSourceList.getPath()); } for (String s : listedSources) { if (!calculatedSources.contains(s)) { throw new ProblemException("The makefile listed source "+s+" was not calculated by the smart javac wrapper!"); } } for (String s : calculatedSources) { if (!listedSources.contains(s)) { throw new ProblemException("The smart javac wrapper calculated source "+s+" was not listed by the makefiles!"); } } } }