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/*******************************************************************************
 * Copyright (c) 2000, 2014 IBM Corporation 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:
 *     IBM Corporation - initial API and implementation
 *******************************************************************************/
package org.eclipse.jdt.internal.compiler;

/**
 * A compilation result consists of all information returned by the compiler for
 * a single compiled compilation source unit.  This includes:
 * 
    *
  • the compilation unit that was compiled *
  • for each type produced by compiling the compilation unit, its binary and optionally its principal structure *
  • any problems (errors or warnings) produced *
  • dependency info *
* * The principle structure and binary may be null if the compiler could not produce them. * If neither could be produced, there is no corresponding entry for the type. * * The dependency info includes type references such as supertypes, field types, method * parameter and return types, local variable types, types of intermediate expressions, etc. * It also includes the namespaces (packages) in which names were looked up. * It does not include finer grained dependencies such as information about * specific fields and methods which were referenced, but does contain their * declaring types and any other types used to locate such fields or methods. */ import java.util.Arrays; import java.util.Comparator; import java.util.HashMap; import java.util.HashSet; import java.util.Hashtable; import java.util.Iterator; import java.util.Map; import java.util.Set; import org.eclipse.jdt.core.compiler.CategorizedProblem; import org.eclipse.jdt.core.compiler.CharOperation; import org.eclipse.jdt.core.compiler.IProblem; import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration; import org.eclipse.jdt.internal.compiler.env.ICompilationUnit; import org.eclipse.jdt.internal.compiler.impl.ReferenceContext; import org.eclipse.jdt.internal.compiler.lookup.SourceTypeBinding; import org.eclipse.jdt.internal.compiler.lookup.TypeConstants; import org.eclipse.jdt.internal.compiler.parser.RecoveryScannerData; import org.eclipse.jdt.internal.compiler.util.Util; @SuppressWarnings({ "rawtypes", "unchecked" }) public class CompilationResult { public CategorizedProblem problems[]; public CategorizedProblem tasks[]; public int problemCount; public int taskCount; public ICompilationUnit compilationUnit; private Map problemsMap; private Set firstErrors; private int maxProblemPerUnit; public char[][][] qualifiedReferences; public char[][] simpleNameReferences; public char[][] rootReferences; public boolean hasAnnotations = false; public boolean hasFunctionalTypes = false; public int lineSeparatorPositions[]; public RecoveryScannerData recoveryScannerData; public Map compiledTypes = new Hashtable(11); public int unitIndex, totalUnitsKnown; public boolean hasBeenAccepted = false; public char[] fileName; public boolean hasInconsistentToplevelHierarchies = false; // record the fact some toplevel types have inconsistent hierarchies public boolean hasSyntaxError = false; public char[][] packageName; public boolean checkSecondaryTypes = false; // check for secondary types which were created after the initial buildTypeBindings call private int numberOfErrors; private boolean hasMandatoryErrors; private static final int[] EMPTY_LINE_ENDS = Util.EMPTY_INT_ARRAY; private static final Comparator PROBLEM_COMPARATOR = new Comparator() { public int compare(Object o1, Object o2) { return ((CategorizedProblem) o1).getSourceStart() - ((CategorizedProblem) o2).getSourceStart(); } }; public CompilationResult(char[] fileName, int unitIndex, int totalUnitsKnown, int maxProblemPerUnit){ this.fileName = fileName; this.unitIndex = unitIndex; this.totalUnitsKnown = totalUnitsKnown; this.maxProblemPerUnit = maxProblemPerUnit; } public CompilationResult(ICompilationUnit compilationUnit, int unitIndex, int totalUnitsKnown, int maxProblemPerUnit){ this.fileName = compilationUnit.getFileName(); this.compilationUnit = compilationUnit; this.unitIndex = unitIndex; this.totalUnitsKnown = totalUnitsKnown; this.maxProblemPerUnit = maxProblemPerUnit; } private int computePriority(CategorizedProblem problem){ final int P_STATIC = 10000; final int P_OUTSIDE_METHOD = 40000; final int P_FIRST_ERROR = 20000; final int P_ERROR = 100000; int priority = 10000 - problem.getSourceLineNumber(); // early problems first if (priority < 0) priority = 0; if (problem.isError()){ priority += P_ERROR; } ReferenceContext context = this.problemsMap == null ? null : (ReferenceContext) this.problemsMap.get(problem); if (context != null){ if (context instanceof AbstractMethodDeclaration){ AbstractMethodDeclaration method = (AbstractMethodDeclaration) context; if (method.isStatic()) { priority += P_STATIC; } } else { priority += P_OUTSIDE_METHOD; } if (this.firstErrors.contains(problem)){ // if context is null, firstErrors is null too priority += P_FIRST_ERROR; } } else { priority += P_OUTSIDE_METHOD; } return priority; } public CategorizedProblem[] getAllProblems() { CategorizedProblem[] onlyProblems = getProblems(); int onlyProblemCount = onlyProblems != null ? onlyProblems.length : 0; CategorizedProblem[] onlyTasks = getTasks(); int onlyTaskCount = onlyTasks != null ? onlyTasks.length : 0; if (onlyTaskCount == 0) { return onlyProblems; } if (onlyProblemCount == 0) { return onlyTasks; } int totalNumberOfProblem = onlyProblemCount + onlyTaskCount; CategorizedProblem[] allProblems = new CategorizedProblem[totalNumberOfProblem]; int allProblemIndex = 0; int taskIndex = 0; int problemIndex = 0; while (taskIndex + problemIndex < totalNumberOfProblem) { CategorizedProblem nextTask = null; CategorizedProblem nextProblem = null; if (taskIndex < onlyTaskCount) { nextTask = onlyTasks[taskIndex]; } if (problemIndex < onlyProblemCount) { nextProblem = onlyProblems[problemIndex]; } // select the next problem CategorizedProblem currentProblem = null; if (nextProblem != null) { if (nextTask != null) { if (nextProblem.getSourceStart() < nextTask.getSourceStart()) { currentProblem = nextProblem; problemIndex++; } else { currentProblem = nextTask; taskIndex++; } } else { currentProblem = nextProblem; problemIndex++; } } else { if (nextTask != null) { currentProblem = nextTask; taskIndex++; } } allProblems[allProblemIndex++] = currentProblem; } return allProblems; } public ClassFile[] getClassFiles() { ClassFile[] classFiles = new ClassFile[this.compiledTypes.size()]; this.compiledTypes.values().toArray(classFiles); return classFiles; } /** * Answer the initial compilation unit corresponding to the present compilation result */ public ICompilationUnit getCompilationUnit(){ return this.compilationUnit; } /** * Answer the errors encountered during compilation. */ public CategorizedProblem[] getErrors() { CategorizedProblem[] reportedProblems = getProblems(); int errorCount = 0; for (int i = 0; i < this.problemCount; i++) { if (reportedProblems[i].isError()) errorCount++; } if (errorCount == this.problemCount) return reportedProblems; CategorizedProblem[] errors = new CategorizedProblem[errorCount]; int index = 0; for (int i = 0; i < this.problemCount; i++) { if (reportedProblems[i].isError()) errors[index++] = reportedProblems[i]; } return errors; } /** * Answer the initial file name */ public char[] getFileName(){ return this.fileName; } public int[] getLineSeparatorPositions() { return this.lineSeparatorPositions == null ? CompilationResult.EMPTY_LINE_ENDS : this.lineSeparatorPositions; } /** * Answer the problems (errors and warnings) encountered during compilation. * * This is not a compiler internal API - it has side-effects ! * It is intended to be used only once all problems have been detected, * and makes sure the problems slot as the exact size of the number of * problems. */ public CategorizedProblem[] getProblems() { // Re-adjust the size of the problems if necessary. if (this.problems != null) { if (this.problemCount != this.problems.length) { System.arraycopy(this.problems, 0, (this.problems = new CategorizedProblem[this.problemCount]), 0, this.problemCount); } if (this.maxProblemPerUnit > 0 && this.problemCount > this.maxProblemPerUnit){ quickPrioritize(this.problems, 0, this.problemCount - 1); this.problemCount = this.maxProblemPerUnit; System.arraycopy(this.problems, 0, (this.problems = new CategorizedProblem[this.problemCount]), 0, this.problemCount); } // Stable sort problems per source positions. Arrays.sort(this.problems, 0, this.problems.length, CompilationResult.PROBLEM_COMPARATOR); //quickSort(problems, 0, problems.length-1); } return this.problems; } /** * Same as getProblems() but don't answer problems that actually concern the enclosing package. */ public CategorizedProblem[] getCUProblems() { // Re-adjust the size of the problems if necessary and filter package problems if (this.problems != null) { CategorizedProblem[] filteredProblems = new CategorizedProblem[this.problemCount]; int keep = 0; for (int i=0; i< this.problemCount; i++) { CategorizedProblem problem = this.problems[i]; if (problem.getID() != IProblem.MissingNonNullByDefaultAnnotationOnPackage) { filteredProblems[keep++] = problem; } else if (this.compilationUnit != null) { if (CharOperation.equals(this.compilationUnit.getMainTypeName(), TypeConstants.PACKAGE_INFO_NAME)) { filteredProblems[keep++] = problem; } } } if (keep < this.problemCount) { System.arraycopy(filteredProblems, 0, filteredProblems = new CategorizedProblem[keep], 0, keep); this.problemCount = keep; } this.problems = filteredProblems; if (this.maxProblemPerUnit > 0 && this.problemCount > this.maxProblemPerUnit){ quickPrioritize(this.problems, 0, this.problemCount - 1); this.problemCount = this.maxProblemPerUnit; System.arraycopy(this.problems, 0, (this.problems = new CategorizedProblem[this.problemCount]), 0, this.problemCount); } // Stable sort problems per source positions. Arrays.sort(this.problems, 0, this.problems.length, CompilationResult.PROBLEM_COMPARATOR); //quickSort(problems, 0, problems.length-1); } return this.problems; } /** * Answer the tasks (TO-DO, ...) encountered during compilation. * * This is not a compiler internal API - it has side-effects ! * It is intended to be used only once all problems have been detected, * and makes sure the problems slot as the exact size of the number of * problems. */ public CategorizedProblem[] getTasks() { // Re-adjust the size of the tasks if necessary. if (this.tasks != null) { if (this.taskCount != this.tasks.length) { System.arraycopy(this.tasks, 0, (this.tasks = new CategorizedProblem[this.taskCount]), 0, this.taskCount); } // Stable sort problems per source positions. Arrays.sort(this.tasks, 0, this.tasks.length, CompilationResult.PROBLEM_COMPARATOR); //quickSort(tasks, 0, tasks.length-1); } return this.tasks; } public boolean hasErrors() { return this.numberOfErrors != 0; } public boolean hasMandatoryErrors() { return this.hasMandatoryErrors; } public boolean hasProblems() { return this.problemCount != 0; } public boolean hasTasks() { return this.taskCount != 0; } public boolean hasWarnings() { if (this.problems != null) for (int i = 0; i < this.problemCount; i++) { if (this.problems[i].isWarning()) return true; } return false; } private void quickPrioritize(CategorizedProblem[] problemList, int left, int right) { if (left >= right) return; // sort the problems by their priority... starting with the highest priority int original_left = left; int original_right = right; int mid = computePriority(problemList[left + (right - left) / 2]); do { while (computePriority(problemList[right]) < mid) right--; while (mid < computePriority(problemList[left])) left++; if (left <= right) { CategorizedProblem tmp = problemList[left]; problemList[left] = problemList[right]; problemList[right] = tmp; left++; right--; } } while (left <= right); if (original_left < right) quickPrioritize(problemList, original_left, right); if (left < original_right) quickPrioritize(problemList, left, original_right); } /* * Record the compilation unit result's package name */ public void recordPackageName(char[][] packName) { this.packageName = packName; } public void record(CategorizedProblem newProblem, ReferenceContext referenceContext) { record(newProblem, referenceContext, true); return; } public void record(CategorizedProblem newProblem, ReferenceContext referenceContext, boolean mandatoryError) { //new Exception("VERBOSE PROBLEM REPORTING").printStackTrace(); if(newProblem.getID() == IProblem.Task) { recordTask(newProblem); return; } if (this.problemCount == 0) { this.problems = new CategorizedProblem[5]; } else if (this.problemCount == this.problems.length) { System.arraycopy(this.problems, 0, (this.problems = new CategorizedProblem[this.problemCount * 2]), 0, this.problemCount); } this.problems[this.problemCount++] = newProblem; if (referenceContext != null){ if (this.problemsMap == null) this.problemsMap = new HashMap(5); if (this.firstErrors == null) this.firstErrors = new HashSet(5); if (newProblem.isError() && !referenceContext.hasErrors()) this.firstErrors.add(newProblem); this.problemsMap.put(newProblem, referenceContext); } if (newProblem.isError()) { this.numberOfErrors++; if (mandatoryError) this.hasMandatoryErrors = true; if ((newProblem.getID() & IProblem.Syntax) != 0) { this.hasSyntaxError = true; } } } /** * For now, remember the compiled type using its compound name. */ public void record(char[] typeName, ClassFile classFile) { SourceTypeBinding sourceType = classFile.referenceBinding; if (!sourceType.isLocalType() && sourceType.isHierarchyInconsistent()) { this.hasInconsistentToplevelHierarchies = true; } this.compiledTypes.put(typeName, classFile); } private void recordTask(CategorizedProblem newProblem) { if (this.taskCount == 0) { this.tasks = new CategorizedProblem[5]; } else if (this.taskCount == this.tasks.length) { System.arraycopy(this.tasks, 0, (this.tasks = new CategorizedProblem[this.taskCount * 2]), 0, this.taskCount); } this.tasks[this.taskCount++] = newProblem; } public void removeProblem(CategorizedProblem problem) { if (this.problemsMap != null) this.problemsMap.remove(problem); if (this.firstErrors != null) this.firstErrors.remove(problem); if (problem.isError()) { this.numberOfErrors--; } this.problemCount--; } public CompilationResult tagAsAccepted(){ this.hasBeenAccepted = true; this.problemsMap = null; // flush this.firstErrors = null; // flush return this; } public String toString(){ StringBuffer buffer = new StringBuffer(); if (this.fileName != null){ buffer.append("Filename : ").append(this.fileName).append('\n'); //$NON-NLS-1$ } if (this.compiledTypes != null){ buffer.append("COMPILED type(s) \n"); //$NON-NLS-1$ Iterator keys = this.compiledTypes.keySet().iterator(); while (keys.hasNext()) { char[] typeName = (char[]) keys.next(); buffer.append("\t - ").append(typeName).append('\n'); //$NON-NLS-1$ } } else { buffer.append("No COMPILED type\n"); //$NON-NLS-1$ } if (this.problems != null){ buffer.append(this.problemCount).append(" PROBLEM(s) detected \n"); //$NON-NLS-1$ for (int i = 0; i < this.problemCount; i++){ buffer.append("\t - ").append(this.problems[i]).append('\n'); //$NON-NLS-1$ } } else { buffer.append("No PROBLEM\n"); //$NON-NLS-1$ } return buffer.toString(); } }




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