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comparison agent/src/share/classes/sun/jvm/hotspot/utilities/ReversePtrsAnalysis.java @ 0:a61af66fc99e jdk7-b24

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author duke
date Sat, 01 Dec 2007 00:00:00 +0000
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1 /*
2 * Copyright 2002-2006 Sun Microsystems, Inc. All Rights Reserved.
3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
4 *
5 * This code is free software; you can redistribute it and/or modify it
6 * under the terms of the GNU General Public License version 2 only, as
7 * published by the Free Software Foundation.
8 *
9 * This code is distributed in the hope that it will be useful, but WITHOUT
10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
12 * version 2 for more details (a copy is included in the LICENSE file that
13 * accompanied this code).
14 *
15 * You should have received a copy of the GNU General Public License version
16 * 2 along with this work; if not, write to the Free Software Foundation,
17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
18 *
19 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
20 * CA 95054 USA or visit www.sun.com if you need additional information or
21 * have any questions.
22 *
23 */
24
25 package sun.jvm.hotspot.utilities;
26
27 import java.io.*;
28 import java.util.*;
29 import sun.jvm.hotspot.debugger.*;
30 import sun.jvm.hotspot.gc_interface.*;
31 import sun.jvm.hotspot.memory.*;
32 import sun.jvm.hotspot.oops.*;
33 import sun.jvm.hotspot.runtime.*;
34 import sun.jvm.hotspot.utilities.*;
35
36 /** For a set of known roots, descends recursively into the object
37 graph, for each object recording those objects (and their fields)
38 which point to it. NOTE: currently only a subset of the roots
39 known to the VM is exposed to the SA: objects on the stack, static
40 fields in classes, and JNI handles. These should be most of the
41 user-level roots keeping objects alive. */
42
43 public class ReversePtrsAnalysis {
44 // Used for debugging this code
45 private static final boolean DEBUG = false;
46
47 public ReversePtrsAnalysis() {
48 }
49
50 /** Sets an optional progress thunk */
51 public void setHeapProgressThunk(HeapProgressThunk thunk) {
52 progressThunk = thunk;
53 }
54
55
56 /** Runs the analysis algorithm */
57 public void run() {
58 if (VM.getVM().getRevPtrs() != null) {
59 return; // Assume already done
60 }
61
62 VM vm = VM.getVM();
63 rp = new ReversePtrs();
64 vm.setRevPtrs(rp);
65 Universe universe = vm.getUniverse();
66 CollectedHeap collHeap = universe.heap();
67 usedSize = collHeap.used();
68 visitedSize = 0;
69
70 // Note that an experiment to iterate the heap linearly rather
71 // than in recursive-descent order has been done. It turns out
72 // that the recursive-descent algorithm is nearly twice as fast
73 // due to the fact that it scans only live objects and (currently)
74 // only a fraction of the perm gen, namely the static fields
75 // contained in instanceKlasses. (Iterating the heap linearly
76 // would also change the semantics of the result so that
77 // ReversePtrs.get() would return a non-null value even for dead
78 // objects.) Nonetheless, the reverse pointer computation is still
79 // quite slow and optimization in field iteration of objects
80 // should be done.
81
82 if (progressThunk != null) {
83 // Get it started
84 progressThunk.heapIterationFractionUpdate(0);
85 }
86
87 // Allocate mark bits for heap
88 markBits = new MarkBits(collHeap);
89
90 // Get a hold of the object heap
91 heap = vm.getObjectHeap();
92
93 // Do each thread's roots
94 for (JavaThread thread = VM.getVM().getThreads().first();
95 thread != null;
96 thread = thread.next()) {
97 ByteArrayOutputStream bos = new ByteArrayOutputStream();
98 thread.printThreadIDOn(new PrintStream(bos));
99 String threadDesc =
100 " in thread \"" + thread.getThreadName() +
101 "\" (id " + bos.toString() + ")";
102 doStack(thread,
103 new RootVisitor("Stack root" + threadDesc));
104 doJNIHandleBlock(thread.activeHandles(),
105 new RootVisitor("JNI handle root" + threadDesc));
106 }
107
108 // Do global JNI handles
109 JNIHandles handles = VM.getVM().getJNIHandles();
110 doJNIHandleBlock(handles.globalHandles(),
111 new RootVisitor("Global JNI handle root"));
112 doJNIHandleBlock(handles.weakGlobalHandles(),
113 new RootVisitor("Weak global JNI handle root"));
114
115 // Do Java-level static fields in perm gen
116 heap.iteratePerm(new DefaultHeapVisitor() {
117 public boolean doObj(Oop obj) {
118 if (obj instanceof InstanceKlass) {
119 final InstanceKlass ik = (InstanceKlass) obj;
120 ik.iterateFields(
121 new DefaultOopVisitor() {
122 public void doOop(OopField field, boolean isVMField) {
123 Oop next = field.getValue(ik);
124 LivenessPathElement lp = new LivenessPathElement(null,
125 new NamedFieldIdentifier("Static field \"" +
126 field.getID().getName() +
127 "\" in class \"" +
128 ik.getName().asString() + "\""));
129 rp.put(lp, next);
130 try {
131 markAndTraverse(next);
132 } catch (AddressException e) {
133 System.err.print("RevPtrs analysis: WARNING: AddressException at 0x" +
134 Long.toHexString(e.getAddress()) +
135 " while traversing static fields of InstanceKlass ");
136 ik.printValueOn(System.err);
137 System.err.println();
138 } catch (UnknownOopException e) {
139 System.err.println("RevPtrs analysis: WARNING: UnknownOopException while " +
140 "traversing static fields of InstanceKlass ");
141 ik.printValueOn(System.err);
142 System.err.println();
143 }
144 }
145 },
146 false);
147 }
148 return false;
149 }
150 });
151
152 if (progressThunk != null) {
153 progressThunk.heapIterationComplete();
154 }
155
156 // Clear out markBits
157 markBits = null;
158 }
159
160
161 //---------------------------------------------------------------------------
162 // Internals only below this point
163 //
164 private HeapProgressThunk progressThunk;
165 private long usedSize;
166 private long visitedSize;
167 private double lastNotificationFraction;
168 private static final double MINIMUM_NOTIFICATION_FRACTION = 0.01;
169 private ObjectHeap heap;
170 private MarkBits markBits;
171 private int depth; // Debugging only
172 private ReversePtrs rp;
173
174 private void markAndTraverse(OopHandle handle) {
175 try {
176 markAndTraverse(heap.newOop(handle));
177 } catch (AddressException e) {
178 System.err.println("RevPtrs analysis: WARNING: AddressException at 0x" +
179 Long.toHexString(e.getAddress()) +
180 " while traversing oop at " + handle);
181 } catch (UnknownOopException e) {
182 System.err.println("RevPtrs analysis: WARNING: UnknownOopException for " +
183 "oop at " + handle);
184 }
185 }
186
187 private void printHeader() {
188 for (int i = 0; i < depth; i++) {
189 System.err.print(" ");
190 }
191 }
192
193 private void markAndTraverse(final Oop obj) {
194
195 // End of path
196 if (obj == null) {
197 return;
198 }
199
200 // Visited object
201 if (!markBits.mark(obj)) {
202 return;
203 }
204
205 // Root of work list for objects to be visited. A simple
206 // stack for saving new objects to be analyzed.
207
208 final Stack workList = new Stack();
209
210 // Next object to be visited.
211 Oop next = obj;
212
213 try {
214 // Node in the list currently being visited.
215
216 while (true) {
217 final Oop currObj = next;
218
219 // For the progress meter
220 if (progressThunk != null) {
221 visitedSize += currObj.getObjectSize();
222 double curFrac = (double) visitedSize / (double) usedSize;
223 if (curFrac >
224 lastNotificationFraction + MINIMUM_NOTIFICATION_FRACTION) {
225 progressThunk.heapIterationFractionUpdate(curFrac);
226 lastNotificationFraction = curFrac;
227 }
228 }
229
230 if (DEBUG) {
231 ++depth;
232 printHeader();
233 System.err.println("ReversePtrs.markAndTraverse(" +
234 currObj.getHandle() + ")");
235 }
236
237 // Iterate over the references in the object. Do the
238 // reverse pointer analysis for each reference.
239 // Add the reference to the work-list so that its
240 // references will be visited.
241 currObj.iterate(new DefaultOopVisitor() {
242 public void doOop(OopField field, boolean isVMField) {
243 // "field" refers to a reference in currObj
244 Oop next = field.getValue(currObj);
245 rp.put(new LivenessPathElement(currObj, field.getID()), next);
246 if ((next != null) && markBits.mark(next)) {
247 workList.push(next);
248 }
249 }
250 }, false);
251
252 if (DEBUG) {
253 --depth;
254 }
255
256 // Get the next object to visit.
257 next = (Oop) workList.pop();
258 }
259 } catch (EmptyStackException e) {
260 // Done
261 } catch (NullPointerException e) {
262 System.err.println("ReversePtrs: WARNING: " + e +
263 " during traversal");
264 } catch (Exception e) {
265 System.err.println("ReversePtrs: WARNING: " + e +
266 " during traversal");
267 }
268 }
269
270
271 class RootVisitor implements AddressVisitor {
272 RootVisitor(String baseRootDescription) {
273 this.baseRootDescription = baseRootDescription;
274 }
275
276 public void visitAddress(Address addr) {
277 Oop next = heap.newOop(addr.getOopHandleAt(0));
278 LivenessPathElement lp = new LivenessPathElement(null,
279 new NamedFieldIdentifier(baseRootDescription +
280 " @ " + addr));
281 rp.put(lp, next);
282 markAndTraverse(next);
283 }
284
285 private String baseRootDescription;
286 }
287
288 // Traverse the roots on a given thread's stack
289 private void doStack(JavaThread thread, AddressVisitor oopVisitor) {
290 for (StackFrameStream fst = new StackFrameStream(thread); !fst.isDone(); fst.next()) {
291 fst.getCurrent().oopsDo(oopVisitor, fst.getRegisterMap());
292 }
293 }
294
295 // Traverse a JNIHandleBlock
296 private void doJNIHandleBlock(JNIHandleBlock handles, AddressVisitor oopVisitor) {
297 handles.oopsDo(oopVisitor);
298 }
299 }