X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=src%2Forg%2Feclipse%2Fjdt%2Finternal%2Fcompiler%2FCompilationResult.java;fp=src%2Forg%2Feclipse%2Fjdt%2Finternal%2Fcompiler%2FCompilationResult.java;h=684df0be8880609f5a03b67da2150b3f551bf709;hb=040fa5af2cd00017cf3575950cdaade34a6d7f6c;hp=0000000000000000000000000000000000000000;hpb=a580fb8376d315d05e4d6bfdff9ff1101a151cd6;p=org.ibex.tool.git
diff --git a/src/org/eclipse/jdt/internal/compiler/CompilationResult.java b/src/org/eclipse/jdt/internal/compiler/CompilationResult.java
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+/*******************************************************************************
+ * Copyright (c) 2000, 2004 IBM Corporation and others.
+ * All rights reserved. This program and the accompanying materials
+ * are made available under the terms of the Common Public License v1.0
+ * which accompanies this distribution, and is available at
+ * http://www.eclipse.org/legal/cpl-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 org.eclipse.jdt.core.compiler.*;
+import org.eclipse.jdt.internal.compiler.ast.AbstractMethodDeclaration;
+import org.eclipse.jdt.internal.compiler.env.*;
+import org.eclipse.jdt.internal.compiler.impl.ReferenceContext;
+
+import java.util.*;
+
+public class CompilationResult {
+
+ public IProblem problems[];
+ public IProblem tasks[];
+ public int problemCount;
+ public int taskCount;
+ public ICompilationUnit compilationUnit;
+ private Map problemsMap;
+ private Map firstErrorsMap;
+ private int maxProblemPerUnit;
+ public char[][][] qualifiedReferences;
+ public char[][] simpleNameReferences;
+
+ public int lineSeparatorPositions[];
+ public Hashtable compiledTypes = new Hashtable(11);
+ public int unitIndex, totalUnitsKnown;
+ public boolean hasBeenAccepted = false;
+ public char[] fileName;
+
+ 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(IProblem 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 = problemsMap == null ? null : (ReferenceContext) 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;
+ }
+ } else {
+ priority += P_OUTSIDE_METHOD;
+ }
+ if (firstErrorsMap.containsKey(problem)){
+ priority += P_FIRST_ERROR;
+ }
+ return priority;
+ }
+
+
+ public IProblem[] getAllProblems() {
+ IProblem[] onlyProblems = this.getProblems();
+ int onlyProblemCount = onlyProblems != null ? onlyProblems.length : 0;
+ IProblem[] onlyTasks = this.getTasks();
+ int onlyTaskCount = onlyTasks != null ? onlyTasks.length : 0;
+ if (onlyTaskCount == 0) {
+ return onlyProblems;
+ }
+ if (onlyProblemCount == 0) {
+ return onlyTasks;
+ }
+
+ int totalNumberOfProblem = onlyProblemCount + onlyTaskCount;
+ IProblem[] allProblems = new IProblem[totalNumberOfProblem];
+ int allProblemIndex = 0;
+ int taskIndex = 0;
+ int problemIndex = 0;
+ while (taskIndex + problemIndex < totalNumberOfProblem) {
+ IProblem nextTask = null;
+ IProblem nextProblem = null;
+ if (taskIndex < onlyTaskCount) {
+ nextTask = onlyTasks[taskIndex];
+ }
+ if (problemIndex < onlyProblemCount) {
+ nextProblem = onlyProblems[problemIndex];
+ }
+ // select the next problem
+ IProblem 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() {
+ Enumeration files = compiledTypes.elements();
+ ClassFile[] classFiles = new ClassFile[compiledTypes.size()];
+ int index = 0;
+ while (files.hasMoreElements()){
+ classFiles[index++] = (ClassFile)files.nextElement();
+ }
+ return classFiles;
+ }
+
+ /**
+ * Answer the initial compilation unit corresponding to the present compilation result
+ */
+ public ICompilationUnit getCompilationUnit(){
+ return compilationUnit;
+ }
+
+ /**
+ * Answer the initial file name
+ */
+ public char[] getFileName(){
+ return fileName;
+ }
+
+ /**
+ * Answer the errors encountered during compilation.
+ */
+ public IProblem[] getErrors() {
+
+ IProblem[] reportedProblems = getProblems();
+ int errorCount = 0;
+ for (int i = 0; i < this.problemCount; i++) {
+ if (reportedProblems[i].isError()) errorCount++;
+ }
+ if (errorCount == this.problemCount) return reportedProblems;
+ IProblem[] errors = new IProblem[errorCount];
+ int index = 0;
+ for (int i = 0; i < this.problemCount; i++) {
+ if (reportedProblems[i].isError()) errors[index++] = reportedProblems[i];
+ }
+ return errors;
+ }
+
+ /**
+ * 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 IProblem[] getProblems() {
+
+ // Re-adjust the size of the problems if necessary.
+ if (problems != null) {
+
+ if (this.problemCount != problems.length) {
+ System.arraycopy(problems, 0, (problems = new IProblem[problemCount]), 0, problemCount);
+ }
+
+ if (this.maxProblemPerUnit > 0 && this.problemCount > this.maxProblemPerUnit){
+ quickPrioritize(problems, 0, problemCount - 1);
+ this.problemCount = this.maxProblemPerUnit;
+ System.arraycopy(problems, 0, (problems = new IProblem[problemCount]), 0, problemCount);
+ }
+
+ // Sort problems per source positions.
+ quickSort(problems, 0, problems.length-1);
+ }
+ return 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 IProblem[] 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 IProblem[this.taskCount]), 0, this.taskCount);
+ }
+ quickSort(tasks, 0, tasks.length-1);
+ }
+ return this.tasks;
+ }
+
+ public boolean hasErrors() {
+
+ if (problems != null)
+ for (int i = 0; i < problemCount; i++) {
+ if (problems[i].isError())
+ return true;
+ }
+ return false;
+ }
+
+ public boolean hasProblems() {
+
+ return problemCount != 0;
+ }
+
+ public boolean hasSyntaxError(){
+
+ if (problems != null)
+ for (int i = 0; i < problemCount; i++) {
+ IProblem problem = problems[i];
+ if ((problem.getID() & IProblem.Syntax) != 0 && problem.isError())
+ return true;
+ }
+ return false;
+ }
+
+ public boolean hasTasks() {
+ return this.taskCount != 0;
+ }
+
+ public boolean hasWarnings() {
+
+ if (problems != null)
+ for (int i = 0; i < problemCount; i++) {
+ if (problems[i].isWarning())
+ return true;
+ }
+ return false;
+ }
+
+ private static void quickSort(IProblem[] list, int left, int right) {
+
+ if (left >= right) return;
+
+ // sort the problems by their source start position... starting with 0
+ int original_left = left;
+ int original_right = right;
+ int mid = list[(left + right) / 2].getSourceStart();
+ do {
+ while (list[left].getSourceStart() < mid)
+ left++;
+ while (mid < list[right].getSourceStart())
+ right--;
+ if (left <= right) {
+ IProblem tmp = list[left];
+ list[left] = list[right];
+ list[right] = tmp;
+ left++;
+ right--;
+ }
+ } while (left <= right);
+ if (original_left < right)
+ quickSort(list, original_left, right);
+ if (left < original_right)
+ quickSort(list, left, original_right);
+ }
+
+ private void quickPrioritize(IProblem[] list, 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(list[(left + right) / 2]);
+ do {
+ while (computePriority(list[right]) < mid)
+ right--;
+ while (mid < computePriority(list[left]))
+ left++;
+ if (left <= right) {
+ IProblem tmp = list[left];
+ list[left] = list[right];
+ list[right] = tmp;
+ left++;
+ right--;
+ }
+ } while (left <= right);
+ if (original_left < right)
+ quickPrioritize(list, original_left, right);
+ if (left < original_right)
+ quickPrioritize(list, left, original_right);
+ }
+
+ /**
+ * For now, remember the compiled type using its compound name.
+ */
+ public void record(char[] typeName, ClassFile classFile) {
+
+ compiledTypes.put(typeName, classFile);
+ }
+
+ public void record(IProblem newProblem, ReferenceContext referenceContext) {
+
+ if (newProblem.getID() == IProblem.Task) {
+ recordTask(newProblem);
+ return;
+ }
+ if (problemCount == 0) {
+ problems = new IProblem[5];
+ } else if (problemCount == problems.length) {
+ System.arraycopy(problems, 0, (problems = new IProblem[problemCount * 2]), 0, problemCount);
+ }
+ problems[problemCount++] = newProblem;
+ if (referenceContext != null){
+ if (problemsMap == null) problemsMap = new Hashtable(5);
+ if (firstErrorsMap == null) firstErrorsMap = new Hashtable(5);
+ if (newProblem.isError() && !referenceContext.hasErrors()) firstErrorsMap.put(newProblem, newProblem);
+ problemsMap.put(newProblem, referenceContext);
+ }
+ }
+
+ private void recordTask(IProblem newProblem) {
+ if (this.taskCount == 0) {
+ this.tasks = new IProblem[5];
+ } else if (this.taskCount == this.tasks.length) {
+ System.arraycopy(this.tasks, 0, (this.tasks = new IProblem[this.taskCount * 2]), 0, this.taskCount);
+ }
+ this.tasks[this.taskCount++] = newProblem;
+ }
+
+ public CompilationResult tagAsAccepted(){
+
+ this.hasBeenAccepted = true;
+ this.problemsMap = 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"); //$NON-NLS-1$
+ Enumeration typeNames = this.compiledTypes.keys();
+ while (typeNames.hasMoreElements()) {
+ char[] typeName = (char[]) typeNames.nextElement();
+ buffer.append("\t - ").append(typeName).append('\n'); //$NON-NLS-1$
+
+ }
+ } else {
+ buffer.append("No COMPILED type\n"); //$NON-NLS-1$
+ }
+ if (problems != null){
+ buffer.append(this.problemCount).append(" PROBLEM(s) detected \n"); //$NON-NLS-1$//$NON-NLS-2$
+ 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();
+ }
+}