1 /*
2 * Copyright (C) 2008 The Android Open Source Project
3 *
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at
7 *
8 * http://www.apache.org/licenses/LICENSE-2.0
9 *
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
15 */
16
17 /*
18 * Main interpreter entry point and support functions.
19 *
20 * The entry point selects the "standard" or "debug" interpreter and
21 * facilitates switching between them. The standard interpreter may
22 * use the "fast" or "portable" implementation.
23 *
24 * Some debugger support functions are included here.
25 */
26 #include "Dalvik.h"
27 #include "interp/InterpDefs.h"
28 #if defined(WITH_JIT)
29 #include "interp/Jit.h"
30 #endif
31
32
33 /*
34 * ===========================================================================
35 * Debugger support
36 * ===========================================================================
37 */
38
39 // fwd
40 static BreakpointSet* dvmBreakpointSetAlloc();
41 static void dvmBreakpointSetFree(BreakpointSet* pSet);
42
43 #if defined(WITH_JIT)
44 /* Target-specific save/restore */
45 extern "C" void dvmJitCalleeSave(double *saveArea);
46 extern "C" void dvmJitCalleeRestore(double *saveArea);
47 /* Interpreter entry points from compiled code */
48 extern "C" void dvmJitToInterpNormal();
49 extern "C" void dvmJitToInterpNoChain();
50 extern "C" void dvmJitToInterpPunt();
51 extern "C" void dvmJitToInterpSingleStep();
52 extern "C" void dvmJitToInterpTraceSelect();
53 #if defined(WITH_SELF_VERIFICATION)
54 extern "C" void dvmJitToInterpBackwardBranch();
55 #endif
56 #endif
57
58 /*
59 * Initialize global breakpoint structures.
60 */
dvmBreakpointStartup()61 bool dvmBreakpointStartup()
62 {
63 gDvm.breakpointSet = dvmBreakpointSetAlloc();
64 return (gDvm.breakpointSet != NULL);
65 }
66
67 /*
68 * Free resources.
69 */
dvmBreakpointShutdown()70 void dvmBreakpointShutdown()
71 {
72 dvmBreakpointSetFree(gDvm.breakpointSet);
73 }
74
75
76 /*
77 * This represents a breakpoint inserted in the instruction stream.
78 *
79 * The debugger may ask us to create the same breakpoint multiple times.
80 * We only remove the breakpoint when the last instance is cleared.
81 */
82 struct Breakpoint {
83 Method* method; /* method we're associated with */
84 u2* addr; /* absolute memory address */
85 u1 originalOpcode; /* original 8-bit opcode value */
86 int setCount; /* #of times this breakpoint was set */
87 };
88
89 /*
90 * Set of breakpoints.
91 */
92 struct BreakpointSet {
93 /* grab lock before reading or writing anything else in here */
94 pthread_mutex_t lock;
95
96 /* vector of breakpoint structures */
97 int alloc;
98 int count;
99 Breakpoint* breakpoints;
100 };
101
102 /*
103 * Initialize a BreakpointSet. Initially empty.
104 */
dvmBreakpointSetAlloc()105 static BreakpointSet* dvmBreakpointSetAlloc()
106 {
107 BreakpointSet* pSet = (BreakpointSet*) calloc(1, sizeof(*pSet));
108
109 dvmInitMutex(&pSet->lock);
110 /* leave the rest zeroed -- will alloc on first use */
111
112 return pSet;
113 }
114
115 /*
116 * Free storage associated with a BreakpointSet.
117 */
dvmBreakpointSetFree(BreakpointSet * pSet)118 static void dvmBreakpointSetFree(BreakpointSet* pSet)
119 {
120 if (pSet == NULL)
121 return;
122
123 free(pSet->breakpoints);
124 free(pSet);
125 }
126
127 /*
128 * Lock the breakpoint set.
129 *
130 * It's not currently necessary to switch to VMWAIT in the event of
131 * contention, because nothing in here can block. However, it's possible
132 * that the bytecode-updater code could become fancier in the future, so
133 * we do the trylock dance as a bit of future-proofing.
134 */
dvmBreakpointSetLock(BreakpointSet * pSet)135 static void dvmBreakpointSetLock(BreakpointSet* pSet)
136 {
137 if (dvmTryLockMutex(&pSet->lock) != 0) {
138 Thread* self = dvmThreadSelf();
139 ThreadStatus oldStatus = dvmChangeStatus(self, THREAD_VMWAIT);
140 dvmLockMutex(&pSet->lock);
141 dvmChangeStatus(self, oldStatus);
142 }
143 }
144
145 /*
146 * Unlock the breakpoint set.
147 */
dvmBreakpointSetUnlock(BreakpointSet * pSet)148 static void dvmBreakpointSetUnlock(BreakpointSet* pSet)
149 {
150 dvmUnlockMutex(&pSet->lock);
151 }
152
153 /*
154 * Return the #of breakpoints.
155 */
dvmBreakpointSetCount(const BreakpointSet * pSet)156 static int dvmBreakpointSetCount(const BreakpointSet* pSet)
157 {
158 return pSet->count;
159 }
160
161 /*
162 * See if we already have an entry for this address.
163 *
164 * The BreakpointSet's lock must be acquired before calling here.
165 *
166 * Returns the index of the breakpoint entry, or -1 if not found.
167 */
dvmBreakpointSetFind(const BreakpointSet * pSet,const u2 * addr)168 static int dvmBreakpointSetFind(const BreakpointSet* pSet, const u2* addr)
169 {
170 int i;
171
172 for (i = 0; i < pSet->count; i++) {
173 Breakpoint* pBreak = &pSet->breakpoints[i];
174 if (pBreak->addr == addr)
175 return i;
176 }
177
178 return -1;
179 }
180
181 /*
182 * Retrieve the opcode that was originally at the specified location.
183 *
184 * The BreakpointSet's lock must be acquired before calling here.
185 *
186 * Returns "true" with the opcode in *pOrig on success.
187 */
dvmBreakpointSetOriginalOpcode(const BreakpointSet * pSet,const u2 * addr,u1 * pOrig)188 static bool dvmBreakpointSetOriginalOpcode(const BreakpointSet* pSet,
189 const u2* addr, u1* pOrig)
190 {
191 int idx = dvmBreakpointSetFind(pSet, addr);
192 if (idx < 0)
193 return false;
194
195 *pOrig = pSet->breakpoints[idx].originalOpcode;
196 return true;
197 }
198
199 /*
200 * Check the opcode. If it's a "magic" NOP, indicating the start of
201 * switch or array data in the instruction stream, we don't want to set
202 * a breakpoint.
203 *
204 * This can happen because the line number information dx generates
205 * associates the switch data with the switch statement's line number,
206 * and some debuggers put breakpoints at every address associated with
207 * a given line. The result is that the breakpoint stomps on the NOP
208 * instruction that doubles as a data table magic number, and an explicit
209 * check in the interpreter results in an exception being thrown.
210 *
211 * We don't want to simply refuse to add the breakpoint to the table,
212 * because that confuses the housekeeping. We don't want to reject the
213 * debugger's event request, and we want to be sure that there's exactly
214 * one un-set operation for every set op.
215 */
instructionIsMagicNop(const u2 * addr)216 static bool instructionIsMagicNop(const u2* addr)
217 {
218 u2 curVal = *addr;
219 return ((GET_OPCODE(curVal)) == OP_NOP && (curVal >> 8) != 0);
220 }
221
222 /*
223 * Add a breakpoint at a specific address. If the address is already
224 * present in the table, this just increments the count.
225 *
226 * For a new entry, this will extract and preserve the current opcode from
227 * the instruction stream, and replace it with a breakpoint opcode.
228 *
229 * The BreakpointSet's lock must be acquired before calling here.
230 *
231 * Returns "true" on success.
232 */
dvmBreakpointSetAdd(BreakpointSet * pSet,Method * method,unsigned int instrOffset)233 static bool dvmBreakpointSetAdd(BreakpointSet* pSet, Method* method,
234 unsigned int instrOffset)
235 {
236 const int kBreakpointGrowth = 10;
237 const u2* addr = method->insns + instrOffset;
238 int idx = dvmBreakpointSetFind(pSet, addr);
239 Breakpoint* pBreak;
240
241 if (idx < 0) {
242 if (pSet->count == pSet->alloc) {
243 int newSize = pSet->alloc + kBreakpointGrowth;
244 Breakpoint* newVec;
245
246 ALOGV("+++ increasing breakpoint set size to %d", newSize);
247
248 /* pSet->breakpoints will be NULL on first entry */
249 newVec = (Breakpoint*)realloc(pSet->breakpoints, newSize * sizeof(Breakpoint));
250 if (newVec == NULL)
251 return false;
252
253 pSet->breakpoints = newVec;
254 pSet->alloc = newSize;
255 }
256
257 pBreak = &pSet->breakpoints[pSet->count++];
258 pBreak->method = method;
259 pBreak->addr = (u2*)addr;
260 pBreak->originalOpcode = *(u1*)addr;
261 pBreak->setCount = 1;
262
263 /*
264 * Change the opcode. We must ensure that the BreakpointSet
265 * updates happen before we change the opcode.
266 *
267 * If the method has not been verified, we do NOT insert the
268 * breakpoint yet, since that will screw up the verifier. The
269 * debugger is allowed to insert breakpoints in unverified code,
270 * but since we don't execute unverified code we don't need to
271 * alter the bytecode yet.
272 *
273 * The class init code will "flush" all pending opcode writes
274 * before verification completes.
275 */
276 assert(*(u1*)addr != OP_BREAKPOINT);
277 if (dvmIsClassVerified(method->clazz)) {
278 ALOGV("Class %s verified, adding breakpoint at %p",
279 method->clazz->descriptor, addr);
280 if (instructionIsMagicNop(addr)) {
281 ALOGV("Refusing to set breakpoint on %04x at %s.%s + %#x",
282 *addr, method->clazz->descriptor, method->name,
283 instrOffset);
284 } else {
285 ANDROID_MEMBAR_FULL();
286 dvmDexChangeDex1(method->clazz->pDvmDex, (u1*)addr,
287 OP_BREAKPOINT);
288 }
289 } else {
290 ALOGV("Class %s NOT verified, deferring breakpoint at %p",
291 method->clazz->descriptor, addr);
292 }
293 } else {
294 /*
295 * Breakpoint already exists, just increase the count.
296 */
297 pBreak = &pSet->breakpoints[idx];
298 pBreak->setCount++;
299 }
300
301 return true;
302 }
303
304 /*
305 * Remove one instance of the specified breakpoint. When the count
306 * reaches zero, the entry is removed from the table, and the original
307 * opcode is restored.
308 *
309 * The BreakpointSet's lock must be acquired before calling here.
310 */
dvmBreakpointSetRemove(BreakpointSet * pSet,Method * method,unsigned int instrOffset)311 static void dvmBreakpointSetRemove(BreakpointSet* pSet, Method* method,
312 unsigned int instrOffset)
313 {
314 const u2* addr = method->insns + instrOffset;
315 int idx = dvmBreakpointSetFind(pSet, addr);
316
317 if (idx < 0) {
318 /* breakpoint not found in set -- unexpected */
319 if (*(u1*)addr == OP_BREAKPOINT) {
320 ALOGE("Unable to restore breakpoint opcode (%s.%s +%#x)",
321 method->clazz->descriptor, method->name, instrOffset);
322 dvmAbort();
323 } else {
324 ALOGW("Breakpoint was already restored? (%s.%s +%#x)",
325 method->clazz->descriptor, method->name, instrOffset);
326 }
327 } else {
328 Breakpoint* pBreak = &pSet->breakpoints[idx];
329 if (pBreak->setCount == 1) {
330 /*
331 * Must restore opcode before removing set entry.
332 *
333 * If the breakpoint was never flushed, we could be ovewriting
334 * a value with the same value. Not a problem, though we
335 * could end up causing a copy-on-write here when we didn't
336 * need to. (Not worth worrying about.)
337 */
338 dvmDexChangeDex1(method->clazz->pDvmDex, (u1*)addr,
339 pBreak->originalOpcode);
340 ANDROID_MEMBAR_FULL();
341
342 if (idx != pSet->count-1) {
343 /* shift down */
344 memmove(&pSet->breakpoints[idx], &pSet->breakpoints[idx+1],
345 (pSet->count-1 - idx) * sizeof(pSet->breakpoints[0]));
346 }
347 pSet->count--;
348 pSet->breakpoints[pSet->count].addr = (u2*) 0xdecadead; // debug
349 } else {
350 pBreak->setCount--;
351 assert(pBreak->setCount > 0);
352 }
353 }
354 }
355
356 /*
357 * Flush any breakpoints associated with methods in "clazz". We want to
358 * change the opcode, which might not have happened when the breakpoint
359 * was initially set because the class was in the process of being
360 * verified.
361 *
362 * The BreakpointSet's lock must be acquired before calling here.
363 */
dvmBreakpointSetFlush(BreakpointSet * pSet,ClassObject * clazz)364 static void dvmBreakpointSetFlush(BreakpointSet* pSet, ClassObject* clazz)
365 {
366 int i;
367 for (i = 0; i < pSet->count; i++) {
368 Breakpoint* pBreak = &pSet->breakpoints[i];
369 if (pBreak->method->clazz == clazz) {
370 /*
371 * The breakpoint is associated with a method in this class.
372 * It might already be there or it might not; either way,
373 * flush it out.
374 */
375 ALOGV("Flushing breakpoint at %p for %s",
376 pBreak->addr, clazz->descriptor);
377 if (instructionIsMagicNop(pBreak->addr)) {
378 ALOGV("Refusing to flush breakpoint on %04x at %s.%s + %#x",
379 *pBreak->addr, pBreak->method->clazz->descriptor,
380 pBreak->method->name, pBreak->addr - pBreak->method->insns);
381 } else {
382 dvmDexChangeDex1(clazz->pDvmDex, (u1*)pBreak->addr,
383 OP_BREAKPOINT);
384 }
385 }
386 }
387 }
388
389
390 /*
391 * Do any debugger-attach-time initialization.
392 */
dvmInitBreakpoints()393 void dvmInitBreakpoints()
394 {
395 /* quick sanity check */
396 BreakpointSet* pSet = gDvm.breakpointSet;
397 dvmBreakpointSetLock(pSet);
398 if (dvmBreakpointSetCount(pSet) != 0) {
399 ALOGW("WARNING: %d leftover breakpoints", dvmBreakpointSetCount(pSet));
400 /* generally not good, but we can keep going */
401 }
402 dvmBreakpointSetUnlock(pSet);
403 }
404
405 /*
406 * Add an address to the list, putting it in the first non-empty slot.
407 *
408 * Sometimes the debugger likes to add two entries for one breakpoint.
409 * We add two entries here, so that we get the right behavior when it's
410 * removed twice.
411 *
412 * This will only be run from the JDWP thread, and it will happen while
413 * we are updating the event list, which is synchronized. We're guaranteed
414 * to be the only one adding entries, and the lock ensures that nobody
415 * will be trying to remove them while we're in here.
416 *
417 * "addr" is the absolute address of the breakpoint bytecode.
418 */
dvmAddBreakAddr(Method * method,unsigned int instrOffset)419 void dvmAddBreakAddr(Method* method, unsigned int instrOffset)
420 {
421 BreakpointSet* pSet = gDvm.breakpointSet;
422 dvmBreakpointSetLock(pSet);
423 dvmBreakpointSetAdd(pSet, method, instrOffset);
424 dvmBreakpointSetUnlock(pSet);
425 }
426
427 /*
428 * Remove an address from the list by setting the entry to NULL.
429 *
430 * This can be called from the JDWP thread (because the debugger has
431 * cancelled the breakpoint) or from an event thread (because it's a
432 * single-shot breakpoint, e.g. "run to line"). We only get here as
433 * the result of removing an entry from the event list, which is
434 * synchronized, so it should not be possible for two threads to be
435 * updating breakpoints at the same time.
436 */
dvmClearBreakAddr(Method * method,unsigned int instrOffset)437 void dvmClearBreakAddr(Method* method, unsigned int instrOffset)
438 {
439 BreakpointSet* pSet = gDvm.breakpointSet;
440 dvmBreakpointSetLock(pSet);
441 dvmBreakpointSetRemove(pSet, method, instrOffset);
442 dvmBreakpointSetUnlock(pSet);
443 }
444
445 /*
446 * Get the original opcode from under a breakpoint.
447 *
448 * On SMP hardware it's possible one core might try to execute a breakpoint
449 * after another core has cleared it. We need to handle the case where
450 * there's no entry in the breakpoint set. (The memory barriers in the
451 * locks and in the breakpoint update code should ensure that, once we've
452 * observed the absence of a breakpoint entry, we will also now observe
453 * the restoration of the original opcode. The fact that we're holding
454 * the lock prevents other threads from confusing things further.)
455 */
dvmGetOriginalOpcode(const u2 * addr)456 u1 dvmGetOriginalOpcode(const u2* addr)
457 {
458 BreakpointSet* pSet = gDvm.breakpointSet;
459 u1 orig = 0;
460
461 dvmBreakpointSetLock(pSet);
462 if (!dvmBreakpointSetOriginalOpcode(pSet, addr, &orig)) {
463 orig = *(u1*)addr;
464 if (orig == OP_BREAKPOINT) {
465 ALOGE("GLITCH: can't find breakpoint, opcode is still set");
466 dvmAbort();
467 }
468 }
469 dvmBreakpointSetUnlock(pSet);
470
471 return orig;
472 }
473
474 /*
475 * Flush any breakpoints associated with methods in "clazz".
476 *
477 * We don't want to modify the bytecode of a method before the verifier
478 * gets a chance to look at it, so we postpone opcode replacement until
479 * after verification completes.
480 */
dvmFlushBreakpoints(ClassObject * clazz)481 void dvmFlushBreakpoints(ClassObject* clazz)
482 {
483 BreakpointSet* pSet = gDvm.breakpointSet;
484
485 if (pSet == NULL)
486 return;
487
488 assert(dvmIsClassVerified(clazz));
489 dvmBreakpointSetLock(pSet);
490 dvmBreakpointSetFlush(pSet, clazz);
491 dvmBreakpointSetUnlock(pSet);
492 }
493
494 /*
495 * Add a single step event. Currently this is a global item.
496 *
497 * We set up some initial values based on the thread's current state. This
498 * won't work well if the thread is running, so it's up to the caller to
499 * verify that it's suspended.
500 *
501 * This is only called from the JDWP thread.
502 */
dvmAddSingleStep(Thread * thread,int size,int depth)503 bool dvmAddSingleStep(Thread* thread, int size, int depth)
504 {
505 StepControl* pCtrl = &gDvm.stepControl;
506
507 if (pCtrl->active && thread != pCtrl->thread) {
508 ALOGW("WARNING: single-step active for %p; adding %p",
509 pCtrl->thread, thread);
510
511 /*
512 * Keep going, overwriting previous. This can happen if you
513 * suspend a thread in Object.wait, hit the single-step key, then
514 * switch to another thread and do the same thing again.
515 * The first thread's step is still pending.
516 *
517 * TODO: consider making single-step per-thread. Adds to the
518 * overhead, but could be useful in rare situations.
519 */
520 }
521
522 pCtrl->size = static_cast<JdwpStepSize>(size);
523 pCtrl->depth = static_cast<JdwpStepDepth>(depth);
524 pCtrl->thread = thread;
525
526 /*
527 * We may be stepping into or over method calls, or running until we
528 * return from the current method. To make this work we need to track
529 * the current line, current method, and current stack depth. We need
530 * to be checking these after most instructions, notably those that
531 * call methods, return from methods, or are on a different line from the
532 * previous instruction.
533 *
534 * We have to start with a snapshot of the current state. If we're in
535 * an interpreted method, everything we need is in the current frame. If
536 * we're in a native method, possibly with some extra JNI frames pushed
537 * on by PushLocalFrame, we want to use the topmost native method.
538 */
539 const StackSaveArea* saveArea;
540 u4* fp;
541 u4* prevFp = NULL;
542
543 for (fp = thread->interpSave.curFrame; fp != NULL;
544 fp = saveArea->prevFrame) {
545 const Method* method;
546
547 saveArea = SAVEAREA_FROM_FP(fp);
548 method = saveArea->method;
549
550 if (!dvmIsBreakFrame((u4*)fp) && !dvmIsNativeMethod(method))
551 break;
552 prevFp = fp;
553 }
554 if (fp == NULL) {
555 ALOGW("Unexpected: step req in native-only threadid=%d",
556 thread->threadId);
557 return false;
558 }
559 if (prevFp != NULL) {
560 /*
561 * First interpreted frame wasn't the one at the bottom. Break
562 * frames are only inserted when calling from native->interp, so we
563 * don't need to worry about one being here.
564 */
565 ALOGV("##### init step while in native method");
566 fp = prevFp;
567 assert(!dvmIsBreakFrame((u4*)fp));
568 assert(dvmIsNativeMethod(SAVEAREA_FROM_FP(fp)->method));
569 saveArea = SAVEAREA_FROM_FP(fp);
570 }
571
572 /*
573 * Pull the goodies out. "xtra.currentPc" should be accurate since
574 * we update it on every instruction while the debugger is connected.
575 */
576 pCtrl->method = saveArea->method;
577 // Clear out any old address set
578 if (pCtrl->pAddressSet != NULL) {
579 // (discard const)
580 free((void *)pCtrl->pAddressSet);
581 pCtrl->pAddressSet = NULL;
582 }
583 if (dvmIsNativeMethod(pCtrl->method)) {
584 pCtrl->line = -1;
585 } else {
586 pCtrl->line = dvmLineNumFromPC(saveArea->method,
587 saveArea->xtra.currentPc - saveArea->method->insns);
588 pCtrl->pAddressSet
589 = dvmAddressSetForLine(saveArea->method, pCtrl->line);
590 }
591 pCtrl->frameDepth =
592 dvmComputeVagueFrameDepth(thread, thread->interpSave.curFrame);
593 pCtrl->active = true;
594
595 ALOGV("##### step init: thread=%p meth=%p '%s' line=%d frameDepth=%d depth=%s size=%s",
596 pCtrl->thread, pCtrl->method, pCtrl->method->name,
597 pCtrl->line, pCtrl->frameDepth,
598 dvmJdwpStepDepthStr(pCtrl->depth),
599 dvmJdwpStepSizeStr(pCtrl->size));
600
601 return true;
602 }
603
604 /*
605 * Disable a single step event.
606 */
dvmClearSingleStep(Thread * thread)607 void dvmClearSingleStep(Thread* thread)
608 {
609 UNUSED_PARAMETER(thread);
610
611 gDvm.stepControl.active = false;
612 }
613
614 /*
615 * The interpreter just threw. Handle any special subMode requirements.
616 * All interpSave state must be valid on entry.
617 */
dvmReportExceptionThrow(Thread * self,Object * exception)618 void dvmReportExceptionThrow(Thread* self, Object* exception)
619 {
620 const Method* curMethod = self->interpSave.method;
621 #if defined(WITH_JIT)
622 if (self->interpBreak.ctl.subMode & kSubModeJitTraceBuild) {
623 dvmJitEndTraceSelect(self, self->interpSave.pc);
624 }
625 if (self->interpBreak.ctl.breakFlags & kInterpSingleStep) {
626 /* Discard any single-step native returns to translation */
627 self->jitResumeNPC = NULL;
628 }
629 #endif
630 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
631 void *catchFrame;
632 int offset = self->interpSave.pc - curMethod->insns;
633 int catchRelPc = dvmFindCatchBlock(self, offset, exception,
634 true, &catchFrame);
635 dvmDbgPostException(self->interpSave.curFrame, offset, catchFrame,
636 catchRelPc, exception);
637 }
638 }
639
640 /*
641 * The interpreter is preparing to do an invoke (both native & normal).
642 * Handle any special subMode requirements. All interpSave state
643 * must be valid on entry.
644 */
dvmReportInvoke(Thread * self,const Method * methodToCall)645 void dvmReportInvoke(Thread* self, const Method* methodToCall)
646 {
647 TRACE_METHOD_ENTER(self, methodToCall);
648 }
649
650 /*
651 * The interpreter is preparing to do a native invoke. Handle any
652 * special subMode requirements. NOTE: for a native invoke,
653 * dvmReportInvoke() and dvmReportPreNativeInvoke() will both
654 * be called prior to the invoke. fp is the Dalvik FP of the calling
655 * method.
656 */
dvmReportPreNativeInvoke(const Method * methodToCall,Thread * self,u4 * fp)657 void dvmReportPreNativeInvoke(const Method* methodToCall, Thread* self, u4* fp)
658 {
659 #if defined(WITH_JIT)
660 /*
661 * Actively building a trace? If so, end it now. The trace
662 * builder can't follow into or through a native method.
663 */
664 if (self->interpBreak.ctl.subMode & kSubModeJitTraceBuild) {
665 dvmCheckJit(self->interpSave.pc, self);
666 }
667 #endif
668 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
669 Object* thisPtr = dvmGetThisPtr(self->interpSave.method, fp);
670 assert(thisPtr == NULL || dvmIsHeapAddress(thisPtr));
671 dvmDbgPostLocationEvent(methodToCall, -1, thisPtr, DBG_METHOD_ENTRY);
672 }
673 }
674
675 /*
676 * The interpreter has returned from a native invoke. Handle any
677 * special subMode requirements. fp is the Dalvik FP of the calling
678 * method.
679 */
dvmReportPostNativeInvoke(const Method * methodToCall,Thread * self,u4 * fp)680 void dvmReportPostNativeInvoke(const Method* methodToCall, Thread* self, u4* fp)
681 {
682 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
683 Object* thisPtr = dvmGetThisPtr(self->interpSave.method, fp);
684 assert(thisPtr == NULL || dvmIsHeapAddress(thisPtr));
685 dvmDbgPostLocationEvent(methodToCall, -1, thisPtr, DBG_METHOD_EXIT);
686 }
687 if (self->interpBreak.ctl.subMode & kSubModeMethodTrace) {
688 dvmFastNativeMethodTraceExit(methodToCall, self);
689 }
690 }
691
692 /*
693 * The interpreter has returned from a normal method. Handle any special
694 * subMode requirements. All interpSave state must be valid on entry.
695 */
dvmReportReturn(Thread * self)696 void dvmReportReturn(Thread* self)
697 {
698 TRACE_METHOD_EXIT(self, self->interpSave.method);
699 #if defined(WITH_JIT)
700 if (dvmIsBreakFrame(self->interpSave.curFrame) &&
701 (self->interpBreak.ctl.subMode & kSubModeJitTraceBuild)) {
702 dvmCheckJit(self->interpSave.pc, self);
703 }
704 #endif
705 }
706
707 /*
708 * Update the debugger on interesting events, such as hitting a breakpoint
709 * or a single-step point. This is called from the top of the interpreter
710 * loop, before the current instruction is processed.
711 *
712 * Set "methodEntry" if we've just entered the method. This detects
713 * method exit by checking to see if the next instruction is "return".
714 *
715 * This can't catch native method entry/exit, so we have to handle that
716 * at the point of invocation. We also need to catch it in dvmCallMethod
717 * if we want to capture native->native calls made through JNI.
718 *
719 * Notes to self:
720 * - Don't want to switch to VMWAIT while posting events to the debugger.
721 * Let the debugger code decide if we need to change state.
722 * - We may want to check for debugger-induced thread suspensions on
723 * every instruction. That would make a "suspend all" more responsive
724 * and reduce the chances of multiple simultaneous events occurring.
725 * However, it could change the behavior some.
726 *
727 * TODO: method entry/exit events are probably less common than location
728 * breakpoints. We may be able to speed things up a bit if we don't query
729 * the event list unless we know there's at least one lurking within.
730 */
updateDebugger(const Method * method,const u2 * pc,const u4 * fp,Thread * self)731 static void updateDebugger(const Method* method, const u2* pc, const u4* fp,
732 Thread* self)
733 {
734 int eventFlags = 0;
735
736 /*
737 * Update xtra.currentPc on every instruction. We need to do this if
738 * there's a chance that we could get suspended. This can happen if
739 * eventFlags != 0 here, or somebody manually requests a suspend
740 * (which gets handled at PERIOD_CHECKS time). One place where this
741 * needs to be correct is in dvmAddSingleStep().
742 */
743 dvmExportPC(pc, fp);
744
745 if (self->debugIsMethodEntry) {
746 eventFlags |= DBG_METHOD_ENTRY;
747 self->debugIsMethodEntry = false;
748 }
749
750 /*
751 * See if we have a breakpoint here.
752 *
753 * Depending on the "mods" associated with event(s) on this address,
754 * we may or may not actually send a message to the debugger.
755 */
756 if (GET_OPCODE(*pc) == OP_BREAKPOINT) {
757 ALOGV("+++ breakpoint hit at %p", pc);
758 eventFlags |= DBG_BREAKPOINT;
759 }
760
761 /*
762 * If the debugger is single-stepping one of our threads, check to
763 * see if we're that thread and we've reached a step point.
764 */
765 const StepControl* pCtrl = &gDvm.stepControl;
766 if (pCtrl->active && pCtrl->thread == self) {
767 int frameDepth;
768 bool doStop = false;
769 const char* msg = NULL;
770
771 assert(!dvmIsNativeMethod(method));
772
773 if (pCtrl->depth == SD_INTO) {
774 /*
775 * Step into method calls. We break when the line number
776 * or method pointer changes. If we're in SS_MIN mode, we
777 * always stop.
778 */
779 if (pCtrl->method != method) {
780 doStop = true;
781 msg = "new method";
782 } else if (pCtrl->size == SS_MIN) {
783 doStop = true;
784 msg = "new instruction";
785 } else if (!dvmAddressSetGet(
786 pCtrl->pAddressSet, pc - method->insns)) {
787 doStop = true;
788 msg = "new line";
789 }
790 } else if (pCtrl->depth == SD_OVER) {
791 /*
792 * Step over method calls. We break when the line number is
793 * different and the frame depth is <= the original frame
794 * depth. (We can't just compare on the method, because we
795 * might get unrolled past it by an exception, and it's tricky
796 * to identify recursion.)
797 */
798 frameDepth = dvmComputeVagueFrameDepth(self, fp);
799 if (frameDepth < pCtrl->frameDepth) {
800 /* popped up one or more frames, always trigger */
801 doStop = true;
802 msg = "method pop";
803 } else if (frameDepth == pCtrl->frameDepth) {
804 /* same depth, see if we moved */
805 if (pCtrl->size == SS_MIN) {
806 doStop = true;
807 msg = "new instruction";
808 } else if (!dvmAddressSetGet(pCtrl->pAddressSet,
809 pc - method->insns)) {
810 doStop = true;
811 msg = "new line";
812 }
813 }
814 } else {
815 assert(pCtrl->depth == SD_OUT);
816 /*
817 * Return from the current method. We break when the frame
818 * depth pops up.
819 *
820 * This differs from the "method exit" break in that it stops
821 * with the PC at the next instruction in the returned-to
822 * function, rather than the end of the returning function.
823 */
824 frameDepth = dvmComputeVagueFrameDepth(self, fp);
825 if (frameDepth < pCtrl->frameDepth) {
826 doStop = true;
827 msg = "method pop";
828 }
829 }
830
831 if (doStop) {
832 ALOGV("#####S %s", msg);
833 eventFlags |= DBG_SINGLE_STEP;
834 }
835 }
836
837 /*
838 * Check to see if this is a "return" instruction. JDWP says we should
839 * send the event *after* the code has been executed, but it also says
840 * the location we provide is the last instruction. Since the "return"
841 * instruction has no interesting side effects, we should be safe.
842 * (We can't just move this down to the returnFromMethod label because
843 * we potentially need to combine it with other events.)
844 *
845 * We're also not supposed to generate a method exit event if the method
846 * terminates "with a thrown exception".
847 */
848 u2 opcode = GET_OPCODE(*pc);
849 if (opcode == OP_RETURN_VOID || opcode == OP_RETURN || opcode == OP_RETURN_VOID_BARRIER ||
850 opcode == OP_RETURN_OBJECT || opcode == OP_RETURN_WIDE)
851 {
852 eventFlags |= DBG_METHOD_EXIT;
853 }
854
855 /*
856 * If there's something interesting going on, see if it matches one
857 * of the debugger filters.
858 */
859 if (eventFlags != 0) {
860 Object* thisPtr = dvmGetThisPtr(method, fp);
861 if (thisPtr != NULL && !dvmIsHeapAddress(thisPtr)) {
862 /*
863 * TODO: remove this check if we're confident that the "this"
864 * pointer is where it should be -- slows us down, especially
865 * during single-step.
866 */
867 char* desc = dexProtoCopyMethodDescriptor(&method->prototype);
868 ALOGE("HEY: invalid 'this' ptr %p (%s.%s %s)", thisPtr,
869 method->clazz->descriptor, method->name, desc);
870 free(desc);
871 dvmAbort();
872 }
873 dvmDbgPostLocationEvent(method, pc - method->insns, thisPtr,
874 eventFlags);
875 }
876 }
877
878 /*
879 * Recover the "this" pointer from the current interpreted method. "this"
880 * is always in "in0" for non-static methods.
881 *
882 * The "ins" start at (#of registers - #of ins). Note in0 != v0.
883 *
884 * This works because "dx" guarantees that it will work. It's probably
885 * fairly common to have a virtual method that doesn't use its "this"
886 * pointer, in which case we're potentially wasting a register. However,
887 * the debugger doesn't treat "this" as just another argument. For
888 * example, events (such as breakpoints) can be enabled for specific
889 * values of "this". There is also a separate StackFrame.ThisObject call
890 * in JDWP that is expected to work for any non-native non-static method.
891 *
892 * Because we need it when setting up debugger event filters, we want to
893 * be able to do this quickly.
894 */
dvmGetThisPtr(const Method * method,const u4 * fp)895 Object* dvmGetThisPtr(const Method* method, const u4* fp)
896 {
897 if (dvmIsStaticMethod(method))
898 return NULL;
899 return (Object*)fp[method->registersSize - method->insSize];
900 }
901
902
903 #if defined(WITH_TRACKREF_CHECKS)
904 /*
905 * Verify that all internally-tracked references have been released. If
906 * they haven't, print them and abort the VM.
907 *
908 * "debugTrackedRefStart" indicates how many refs were on the list when
909 * we were first invoked.
910 */
dvmInterpCheckTrackedRefs(Thread * self,const Method * method,int debugTrackedRefStart)911 void dvmInterpCheckTrackedRefs(Thread* self, const Method* method,
912 int debugTrackedRefStart)
913 {
914 if (dvmReferenceTableEntries(&self->internalLocalRefTable)
915 != (size_t) debugTrackedRefStart)
916 {
917 char* desc;
918 Object** top;
919 int count;
920
921 count = dvmReferenceTableEntries(&self->internalLocalRefTable);
922
923 ALOGE("TRACK: unreleased internal reference (prev=%d total=%d)",
924 debugTrackedRefStart, count);
925 desc = dexProtoCopyMethodDescriptor(&method->prototype);
926 ALOGE(" current method is %s.%s %s", method->clazz->descriptor,
927 method->name, desc);
928 free(desc);
929 top = self->internalLocalRefTable.table + debugTrackedRefStart;
930 while (top < self->internalLocalRefTable.nextEntry) {
931 ALOGE(" %p (%s)",
932 *top,
933 ((*top)->clazz != NULL) ? (*top)->clazz->descriptor : "");
934 top++;
935 }
936 dvmDumpThread(self, false);
937
938 dvmAbort();
939 }
940 //ALOGI("TRACK OK");
941 }
942 #endif
943
944
945 #ifdef LOG_INSTR
946 /*
947 * Dump the v-registers. Sent to the ILOG log tag.
948 */
dvmDumpRegs(const Method * method,const u4 * framePtr,bool inOnly)949 void dvmDumpRegs(const Method* method, const u4* framePtr, bool inOnly)
950 {
951 int i, localCount;
952
953 localCount = method->registersSize - method->insSize;
954
955 ALOG(LOG_VERBOSE, LOG_TAG"i", "Registers (fp=%p):", framePtr);
956 for (i = method->registersSize-1; i >= 0; i--) {
957 if (i >= localCount) {
958 ALOG(LOG_VERBOSE, LOG_TAG"i", " v%-2d in%-2d : 0x%08x",
959 i, i-localCount, framePtr[i]);
960 } else {
961 if (inOnly) {
962 ALOG(LOG_VERBOSE, LOG_TAG"i", " [...]");
963 break;
964 }
965 const char* name = "";
966 #if 0 // "locals" structure has changed -- need to rewrite this
967 int j;
968 DexFile* pDexFile = method->clazz->pDexFile;
969 const DexCode* pDexCode = dvmGetMethodCode(method);
970 int localsSize = dexGetLocalsSize(pDexFile, pDexCode);
971 const DexLocal* locals = dvmDexGetLocals(pDexFile, pDexCode);
972 for (j = 0; j < localsSize, j++) {
973 if (locals[j].registerNum == (u4) i) {
974 name = dvmDexStringStr(locals[j].pName);
975 break;
976 }
977 }
978 #endif
979 ALOG(LOG_VERBOSE, LOG_TAG"i", " v%-2d : 0x%08x %s",
980 i, framePtr[i], name);
981 }
982 }
983 }
984 #endif
985
986
987 /*
988 * ===========================================================================
989 * Entry point and general support functions
990 * ===========================================================================
991 */
992
993 /*
994 * Find the matching case. Returns the offset to the handler instructions.
995 *
996 * Returns 3 if we don't find a match (it's the size of the packed-switch
997 * instruction).
998 */
dvmInterpHandlePackedSwitch(const u2 * switchData,s4 testVal)999 s4 dvmInterpHandlePackedSwitch(const u2* switchData, s4 testVal)
1000 {
1001 const int kInstrLen = 3;
1002
1003 /*
1004 * Packed switch data format:
1005 * ushort ident = 0x0100 magic value
1006 * ushort size number of entries in the table
1007 * int first_key first (and lowest) switch case value
1008 * int targets[size] branch targets, relative to switch opcode
1009 *
1010 * Total size is (4+size*2) 16-bit code units.
1011 */
1012 if (*switchData++ != kPackedSwitchSignature) {
1013 /* should have been caught by verifier */
1014 dvmThrowInternalError("bad packed switch magic");
1015 return kInstrLen;
1016 }
1017
1018 u2 size = *switchData++;
1019 assert(size > 0);
1020
1021 s4 firstKey = *switchData++;
1022 firstKey |= (*switchData++) << 16;
1023
1024 int index = testVal - firstKey;
1025 if (index < 0 || index >= size) {
1026 LOGVV("Value %d not found in switch (%d-%d)",
1027 testVal, firstKey, firstKey+size-1);
1028 return kInstrLen;
1029 }
1030
1031 /* The entries are guaranteed to be aligned on a 32-bit boundary;
1032 * we can treat them as a native int array.
1033 */
1034 const s4* entries = (const s4*) switchData;
1035 assert(((u4)entries & 0x3) == 0);
1036
1037 assert(index >= 0 && index < size);
1038 LOGVV("Value %d found in slot %d (goto 0x%02x)",
1039 testVal, index,
1040 s4FromSwitchData(&entries[index]));
1041 return s4FromSwitchData(&entries[index]);
1042 }
1043
1044 /*
1045 * Find the matching case. Returns the offset to the handler instructions.
1046 *
1047 * Returns 3 if we don't find a match (it's the size of the sparse-switch
1048 * instruction).
1049 */
dvmInterpHandleSparseSwitch(const u2 * switchData,s4 testVal)1050 s4 dvmInterpHandleSparseSwitch(const u2* switchData, s4 testVal)
1051 {
1052 const int kInstrLen = 3;
1053 u2 size;
1054 const s4* keys;
1055 const s4* entries;
1056
1057 /*
1058 * Sparse switch data format:
1059 * ushort ident = 0x0200 magic value
1060 * ushort size number of entries in the table; > 0
1061 * int keys[size] keys, sorted low-to-high; 32-bit aligned
1062 * int targets[size] branch targets, relative to switch opcode
1063 *
1064 * Total size is (2+size*4) 16-bit code units.
1065 */
1066
1067 if (*switchData++ != kSparseSwitchSignature) {
1068 /* should have been caught by verifier */
1069 dvmThrowInternalError("bad sparse switch magic");
1070 return kInstrLen;
1071 }
1072
1073 size = *switchData++;
1074 assert(size > 0);
1075
1076 /* The keys are guaranteed to be aligned on a 32-bit boundary;
1077 * we can treat them as a native int array.
1078 */
1079 keys = (const s4*) switchData;
1080 assert(((u4)keys & 0x3) == 0);
1081
1082 /* The entries are guaranteed to be aligned on a 32-bit boundary;
1083 * we can treat them as a native int array.
1084 */
1085 entries = keys + size;
1086 assert(((u4)entries & 0x3) == 0);
1087
1088 /*
1089 * Binary-search through the array of keys, which are guaranteed to
1090 * be sorted low-to-high.
1091 */
1092 int lo = 0;
1093 int hi = size - 1;
1094 while (lo <= hi) {
1095 int mid = (lo + hi) >> 1;
1096
1097 s4 foundVal = s4FromSwitchData(&keys[mid]);
1098 if (testVal < foundVal) {
1099 hi = mid - 1;
1100 } else if (testVal > foundVal) {
1101 lo = mid + 1;
1102 } else {
1103 LOGVV("Value %d found in entry %d (goto 0x%02x)",
1104 testVal, mid, s4FromSwitchData(&entries[mid]));
1105 return s4FromSwitchData(&entries[mid]);
1106 }
1107 }
1108
1109 LOGVV("Value %d not found in switch", testVal);
1110 return kInstrLen;
1111 }
1112
1113 /*
1114 * Copy data for a fill-array-data instruction. On a little-endian machine
1115 * we can just do a memcpy(), on a big-endian system we have work to do.
1116 *
1117 * The trick here is that dexopt has byte-swapped each code unit, which is
1118 * exactly what we want for short/char data. For byte data we need to undo
1119 * the swap, and for 4- or 8-byte values we need to swap pieces within
1120 * each word.
1121 */
copySwappedArrayData(void * dest,const u2 * src,u4 size,u2 width)1122 static void copySwappedArrayData(void* dest, const u2* src, u4 size, u2 width)
1123 {
1124 #if __BYTE_ORDER == __LITTLE_ENDIAN
1125 memcpy(dest, src, size*width);
1126 #else
1127 int i;
1128
1129 switch (width) {
1130 case 1:
1131 /* un-swap pairs of bytes as we go */
1132 for (i = (size-1) & ~1; i >= 0; i -= 2) {
1133 ((u1*)dest)[i] = ((u1*)src)[i+1];
1134 ((u1*)dest)[i+1] = ((u1*)src)[i];
1135 }
1136 /*
1137 * "src" is padded to end on a two-byte boundary, but we don't want to
1138 * assume "dest" is, so we handle odd length specially.
1139 */
1140 if ((size & 1) != 0) {
1141 ((u1*)dest)[size-1] = ((u1*)src)[size];
1142 }
1143 break;
1144 case 2:
1145 /* already swapped correctly */
1146 memcpy(dest, src, size*width);
1147 break;
1148 case 4:
1149 /* swap word halves */
1150 for (i = 0; i < (int) size; i++) {
1151 ((u4*)dest)[i] = (src[(i << 1) + 1] << 16) | src[i << 1];
1152 }
1153 break;
1154 case 8:
1155 /* swap word halves and words */
1156 for (i = 0; i < (int) (size << 1); i += 2) {
1157 ((int*)dest)[i] = (src[(i << 1) + 3] << 16) | src[(i << 1) + 2];
1158 ((int*)dest)[i+1] = (src[(i << 1) + 1] << 16) | src[i << 1];
1159 }
1160 break;
1161 default:
1162 ALOGE("Unexpected width %d in copySwappedArrayData", width);
1163 dvmAbort();
1164 break;
1165 }
1166 #endif
1167 }
1168
1169 /*
1170 * Fill the array with predefined constant values.
1171 *
1172 * Returns true if job is completed, otherwise false to indicate that
1173 * an exception has been thrown.
1174 */
dvmInterpHandleFillArrayData(ArrayObject * arrayObj,const u2 * arrayData)1175 bool dvmInterpHandleFillArrayData(ArrayObject* arrayObj, const u2* arrayData)
1176 {
1177 u2 width;
1178 u4 size;
1179
1180 if (arrayObj == NULL) {
1181 dvmThrowNullPointerException(NULL);
1182 return false;
1183 }
1184 assert (!IS_CLASS_FLAG_SET(((Object *)arrayObj)->clazz,
1185 CLASS_ISOBJECTARRAY));
1186
1187 /*
1188 * Array data table format:
1189 * ushort ident = 0x0300 magic value
1190 * ushort width width of each element in the table
1191 * uint size number of elements in the table
1192 * ubyte data[size*width] table of data values (may contain a single-byte
1193 * padding at the end)
1194 *
1195 * Total size is 4+(width * size + 1)/2 16-bit code units.
1196 */
1197 if (arrayData[0] != kArrayDataSignature) {
1198 dvmThrowInternalError("bad array data magic");
1199 return false;
1200 }
1201
1202 width = arrayData[1];
1203 size = arrayData[2] | (((u4)arrayData[3]) << 16);
1204
1205 if (size > arrayObj->length) {
1206 dvmThrowArrayIndexOutOfBoundsException(arrayObj->length, size);
1207 return false;
1208 }
1209 copySwappedArrayData(arrayObj->contents, &arrayData[4], size, width);
1210 return true;
1211 }
1212
1213 /*
1214 * Find the concrete method that corresponds to "methodIdx". The code in
1215 * "method" is executing invoke-method with "thisClass" as its first argument.
1216 *
1217 * Returns NULL with an exception raised on failure.
1218 */
dvmInterpFindInterfaceMethod(ClassObject * thisClass,u4 methodIdx,const Method * method,DvmDex * methodClassDex)1219 Method* dvmInterpFindInterfaceMethod(ClassObject* thisClass, u4 methodIdx,
1220 const Method* method, DvmDex* methodClassDex)
1221 {
1222 Method* absMethod;
1223 Method* methodToCall;
1224 int i, vtableIndex;
1225
1226 /*
1227 * Resolve the method. This gives us the abstract method from the
1228 * interface class declaration.
1229 */
1230 absMethod = dvmDexGetResolvedMethod(methodClassDex, methodIdx);
1231 if (absMethod == NULL) {
1232 absMethod = dvmResolveInterfaceMethod(method->clazz, methodIdx);
1233 if (absMethod == NULL) {
1234 ALOGV("+ unknown method");
1235 return NULL;
1236 }
1237 }
1238
1239 /* make sure absMethod->methodIndex means what we think it means */
1240 assert(dvmIsAbstractMethod(absMethod));
1241
1242 /*
1243 * Run through the "this" object's iftable. Find the entry for
1244 * absMethod's class, then use absMethod->methodIndex to find
1245 * the method's entry. The value there is the offset into our
1246 * vtable of the actual method to execute.
1247 *
1248 * The verifier does not guarantee that objects stored into
1249 * interface references actually implement the interface, so this
1250 * check cannot be eliminated.
1251 */
1252 for (i = 0; i < thisClass->iftableCount; i++) {
1253 if (thisClass->iftable[i].clazz == absMethod->clazz)
1254 break;
1255 }
1256 if (i == thisClass->iftableCount) {
1257 /* impossible in verified DEX, need to check for it in unverified */
1258 dvmThrowIncompatibleClassChangeError("interface not implemented");
1259 return NULL;
1260 }
1261
1262 assert(absMethod->methodIndex <
1263 thisClass->iftable[i].clazz->virtualMethodCount);
1264
1265 vtableIndex =
1266 thisClass->iftable[i].methodIndexArray[absMethod->methodIndex];
1267 assert(vtableIndex >= 0 && vtableIndex < thisClass->vtableCount);
1268 methodToCall = thisClass->vtable[vtableIndex];
1269
1270 #if 0
1271 /* this can happen when there's a stale class file */
1272 if (dvmIsAbstractMethod(methodToCall)) {
1273 dvmThrowAbstractMethodError("interface method not implemented");
1274 return NULL;
1275 }
1276 #else
1277 assert(!dvmIsAbstractMethod(methodToCall) ||
1278 methodToCall->nativeFunc != NULL);
1279 #endif
1280
1281 LOGVV("+++ interface=%s.%s concrete=%s.%s",
1282 absMethod->clazz->descriptor, absMethod->name,
1283 methodToCall->clazz->descriptor, methodToCall->name);
1284 assert(methodToCall != NULL);
1285
1286 return methodToCall;
1287 }
1288
1289
1290
1291 /*
1292 * Helpers for dvmThrowVerificationError().
1293 *
1294 * Each returns a newly-allocated string.
1295 */
1296 #define kThrowShow_accessFromClass 1
classNameFromIndex(const Method * method,int ref,VerifyErrorRefType refType,int flags)1297 static std::string classNameFromIndex(const Method* method, int ref,
1298 VerifyErrorRefType refType, int flags)
1299 {
1300 const DvmDex* pDvmDex = method->clazz->pDvmDex;
1301 if (refType == VERIFY_ERROR_REF_FIELD) {
1302 /* get class ID from field ID */
1303 const DexFieldId* pFieldId = dexGetFieldId(pDvmDex->pDexFile, ref);
1304 ref = pFieldId->classIdx;
1305 } else if (refType == VERIFY_ERROR_REF_METHOD) {
1306 /* get class ID from method ID */
1307 const DexMethodId* pMethodId = dexGetMethodId(pDvmDex->pDexFile, ref);
1308 ref = pMethodId->classIdx;
1309 }
1310
1311 const char* className = dexStringByTypeIdx(pDvmDex->pDexFile, ref);
1312 std::string dotClassName(dvmHumanReadableDescriptor(className));
1313 if (flags == 0) {
1314 return dotClassName;
1315 }
1316
1317 std::string result;
1318 if ((flags & kThrowShow_accessFromClass) != 0) {
1319 result += "tried to access class " + dotClassName;
1320 result += " from class " + dvmHumanReadableDescriptor(method->clazz->descriptor);
1321 } else {
1322 assert(false); // should've been caught above
1323 }
1324
1325 return result;
1326 }
fieldNameFromIndex(const Method * method,int ref,VerifyErrorRefType refType,int flags)1327 static std::string fieldNameFromIndex(const Method* method, int ref,
1328 VerifyErrorRefType refType, int flags)
1329 {
1330 if (refType != VERIFY_ERROR_REF_FIELD) {
1331 ALOGW("Expected ref type %d, got %d", VERIFY_ERROR_REF_FIELD, refType);
1332 return NULL; /* no message */
1333 }
1334
1335 const DvmDex* pDvmDex = method->clazz->pDvmDex;
1336 const DexFieldId* pFieldId = dexGetFieldId(pDvmDex->pDexFile, ref);
1337 const char* className = dexStringByTypeIdx(pDvmDex->pDexFile, pFieldId->classIdx);
1338 const char* fieldName = dexStringById(pDvmDex->pDexFile, pFieldId->nameIdx);
1339
1340 std::string dotName(dvmHumanReadableDescriptor(className));
1341
1342 if ((flags & kThrowShow_accessFromClass) != 0) {
1343 std::string result;
1344 result += "tried to access field ";
1345 result += dotName + "." + fieldName;
1346 result += " from class ";
1347 result += dvmHumanReadableDescriptor(method->clazz->descriptor);
1348 return result;
1349 }
1350 return dotName + "." + fieldName;
1351 }
methodNameFromIndex(const Method * method,int ref,VerifyErrorRefType refType,int flags)1352 static std::string methodNameFromIndex(const Method* method, int ref,
1353 VerifyErrorRefType refType, int flags)
1354 {
1355 if (refType != VERIFY_ERROR_REF_METHOD) {
1356 ALOGW("Expected ref type %d, got %d", VERIFY_ERROR_REF_METHOD,refType);
1357 return NULL; /* no message */
1358 }
1359
1360 const DvmDex* pDvmDex = method->clazz->pDvmDex;
1361 const DexMethodId* pMethodId = dexGetMethodId(pDvmDex->pDexFile, ref);
1362 const char* className = dexStringByTypeIdx(pDvmDex->pDexFile, pMethodId->classIdx);
1363 const char* methodName = dexStringById(pDvmDex->pDexFile, pMethodId->nameIdx);
1364
1365 std::string dotName(dvmHumanReadableDescriptor(className));
1366
1367 if ((flags & kThrowShow_accessFromClass) != 0) {
1368 char* desc = dexProtoCopyMethodDescriptor(&method->prototype);
1369 std::string result;
1370 result += "tried to access method ";
1371 result += dotName + "." + methodName + ":" + desc;
1372 result += " from class " + dvmHumanReadableDescriptor(method->clazz->descriptor);
1373 free(desc);
1374 return result;
1375 }
1376 return dotName + "." + methodName;
1377 }
1378
1379 /*
1380 * Throw an exception for a problem identified by the verifier.
1381 *
1382 * This is used by the invoke-verification-error instruction. It always
1383 * throws an exception.
1384 *
1385 * "kind" indicates the kind of failure encountered by the verifier. It
1386 * has two parts, an error code and an indication of the reference type.
1387 */
dvmThrowVerificationError(const Method * method,int kind,int ref)1388 void dvmThrowVerificationError(const Method* method, int kind, int ref)
1389 {
1390 int errorPart = kind & ~(0xff << kVerifyErrorRefTypeShift);
1391 int errorRefPart = kind >> kVerifyErrorRefTypeShift;
1392 VerifyError errorKind = static_cast<VerifyError>(errorPart);
1393 VerifyErrorRefType refType = static_cast<VerifyErrorRefType>(errorRefPart);
1394 ClassObject* exceptionClass = gDvm.exVerifyError;
1395 std::string msg;
1396
1397 switch ((VerifyError) errorKind) {
1398 case VERIFY_ERROR_NO_CLASS:
1399 exceptionClass = gDvm.exNoClassDefFoundError;
1400 msg = classNameFromIndex(method, ref, refType, 0);
1401 break;
1402 case VERIFY_ERROR_NO_FIELD:
1403 exceptionClass = gDvm.exNoSuchFieldError;
1404 msg = fieldNameFromIndex(method, ref, refType, 0);
1405 break;
1406 case VERIFY_ERROR_NO_METHOD:
1407 exceptionClass = gDvm.exNoSuchMethodError;
1408 msg = methodNameFromIndex(method, ref, refType, 0);
1409 break;
1410 case VERIFY_ERROR_ACCESS_CLASS:
1411 exceptionClass = gDvm.exIllegalAccessError;
1412 msg = classNameFromIndex(method, ref, refType,
1413 kThrowShow_accessFromClass);
1414 break;
1415 case VERIFY_ERROR_ACCESS_FIELD:
1416 exceptionClass = gDvm.exIllegalAccessError;
1417 msg = fieldNameFromIndex(method, ref, refType,
1418 kThrowShow_accessFromClass);
1419 break;
1420 case VERIFY_ERROR_ACCESS_METHOD:
1421 exceptionClass = gDvm.exIllegalAccessError;
1422 msg = methodNameFromIndex(method, ref, refType,
1423 kThrowShow_accessFromClass);
1424 break;
1425 case VERIFY_ERROR_CLASS_CHANGE:
1426 exceptionClass = gDvm.exIncompatibleClassChangeError;
1427 msg = classNameFromIndex(method, ref, refType, 0);
1428 break;
1429 case VERIFY_ERROR_INSTANTIATION:
1430 exceptionClass = gDvm.exInstantiationError;
1431 msg = classNameFromIndex(method, ref, refType, 0);
1432 break;
1433
1434 case VERIFY_ERROR_GENERIC:
1435 /* generic VerifyError; use default exception, no message */
1436 break;
1437 case VERIFY_ERROR_NONE:
1438 /* should never happen; use default exception */
1439 assert(false);
1440 msg = "weird - no error specified";
1441 break;
1442
1443 /* no default clause -- want warning if enum updated */
1444 }
1445
1446 dvmThrowException(exceptionClass, msg.c_str());
1447 }
1448
1449 /*
1450 * Update interpBreak for a single thread.
1451 */
updateInterpBreak(Thread * thread,ExecutionSubModes subMode,bool enable)1452 void updateInterpBreak(Thread* thread, ExecutionSubModes subMode, bool enable)
1453 {
1454 InterpBreak oldValue, newValue;
1455 do {
1456 oldValue = newValue = thread->interpBreak;
1457 newValue.ctl.breakFlags = kInterpNoBreak; // Assume full reset
1458 if (enable)
1459 newValue.ctl.subMode |= subMode;
1460 else
1461 newValue.ctl.subMode &= ~subMode;
1462 if (newValue.ctl.subMode & SINGLESTEP_BREAK_MASK)
1463 newValue.ctl.breakFlags |= kInterpSingleStep;
1464 if (newValue.ctl.subMode & SAFEPOINT_BREAK_MASK)
1465 newValue.ctl.breakFlags |= kInterpSafePoint;
1466 #ifndef DVM_NO_ASM_INTERP
1467 newValue.ctl.curHandlerTable = (newValue.ctl.breakFlags) ?
1468 thread->altHandlerTable : thread->mainHandlerTable;
1469 #endif
1470 } while (dvmQuasiAtomicCas64(oldValue.all, newValue.all,
1471 &thread->interpBreak.all) != 0);
1472 }
1473
1474 /*
1475 * Update interpBreak for all threads.
1476 */
updateAllInterpBreak(ExecutionSubModes subMode,bool enable)1477 void updateAllInterpBreak(ExecutionSubModes subMode, bool enable)
1478 {
1479 Thread* self = dvmThreadSelf();
1480 Thread* thread;
1481
1482 dvmLockThreadList(self);
1483 for (thread = gDvm.threadList; thread != NULL; thread = thread->next) {
1484 updateInterpBreak(thread, subMode, enable);
1485 }
1486 dvmUnlockThreadList();
1487 }
1488
1489 /*
1490 * Update the normal and debugger suspend counts for a thread.
1491 * threadSuspendCount must be acquired before calling this to
1492 * ensure a clean update of suspendCount, dbgSuspendCount and
1493 * sumThreadSuspendCount.
1494 *
1495 * CLEANUP TODO: Currently only the JIT is using sumThreadSuspendCount.
1496 * Move under WITH_JIT ifdefs.
1497 */
dvmAddToSuspendCounts(Thread * thread,int delta,int dbgDelta)1498 void dvmAddToSuspendCounts(Thread* thread, int delta, int dbgDelta)
1499 {
1500 thread->suspendCount += delta;
1501 thread->dbgSuspendCount += dbgDelta;
1502 updateInterpBreak(thread, kSubModeSuspendPending,
1503 (thread->suspendCount != 0));
1504 // Update the global suspend count total
1505 gDvm.sumThreadSuspendCount += delta;
1506 }
1507
1508
dvmDisableSubMode(Thread * thread,ExecutionSubModes subMode)1509 void dvmDisableSubMode(Thread* thread, ExecutionSubModes subMode)
1510 {
1511 updateInterpBreak(thread, subMode, false);
1512 }
1513
dvmEnableSubMode(Thread * thread,ExecutionSubModes subMode)1514 void dvmEnableSubMode(Thread* thread, ExecutionSubModes subMode)
1515 {
1516 updateInterpBreak(thread, subMode, true);
1517 }
1518
dvmEnableAllSubMode(ExecutionSubModes subMode)1519 void dvmEnableAllSubMode(ExecutionSubModes subMode)
1520 {
1521 updateAllInterpBreak(subMode, true);
1522 }
1523
dvmDisableAllSubMode(ExecutionSubModes subMode)1524 void dvmDisableAllSubMode(ExecutionSubModes subMode)
1525 {
1526 updateAllInterpBreak(subMode, false);
1527 }
1528
1529 /*
1530 * Do a sanity check on interpreter state saved to Thread.
1531 * A failure here doesn't necessarily mean that something is wrong,
1532 * so this code should only be used during development to suggest
1533 * a possible problem.
1534 */
dvmCheckInterpStateConsistency()1535 void dvmCheckInterpStateConsistency()
1536 {
1537 Thread* self = dvmThreadSelf();
1538 Thread* thread;
1539 uint8_t breakFlags;
1540 uint8_t subMode;
1541 #ifndef DVM_NO_ASM_INTERP
1542 void* handlerTable;
1543 #endif
1544
1545 dvmLockThreadList(self);
1546 breakFlags = self->interpBreak.ctl.breakFlags;
1547 subMode = self->interpBreak.ctl.subMode;
1548 #ifndef DVM_NO_ASM_INTERP
1549 handlerTable = self->interpBreak.ctl.curHandlerTable;
1550 #endif
1551 for (thread = gDvm.threadList; thread != NULL; thread = thread->next) {
1552 if (subMode != thread->interpBreak.ctl.subMode) {
1553 ALOGD("Warning: subMode mismatch - %#x:%#x, tid[%d]",
1554 subMode,thread->interpBreak.ctl.subMode,thread->threadId);
1555 }
1556 if (breakFlags != thread->interpBreak.ctl.breakFlags) {
1557 ALOGD("Warning: breakFlags mismatch - %#x:%#x, tid[%d]",
1558 breakFlags,thread->interpBreak.ctl.breakFlags,thread->threadId);
1559 }
1560 #ifndef DVM_NO_ASM_INTERP
1561 if (handlerTable != thread->interpBreak.ctl.curHandlerTable) {
1562 ALOGD("Warning: curHandlerTable mismatch - %#x:%#x, tid[%d]",
1563 (int)handlerTable,(int)thread->interpBreak.ctl.curHandlerTable,
1564 thread->threadId);
1565 }
1566 #endif
1567 #if defined(WITH_JIT)
1568 if (thread->pJitProfTable != gDvmJit.pProfTable) {
1569 ALOGD("Warning: pJitProfTable mismatch - %#x:%#x, tid[%d]",
1570 (int)thread->pJitProfTable,(int)gDvmJit.pProfTable,
1571 thread->threadId);
1572 }
1573 if (thread->jitThreshold != gDvmJit.threshold) {
1574 ALOGD("Warning: jitThreshold mismatch - %#x:%#x, tid[%d]",
1575 (int)thread->jitThreshold,(int)gDvmJit.threshold,
1576 thread->threadId);
1577 }
1578 #endif
1579 }
1580 dvmUnlockThreadList();
1581 }
1582
1583 /*
1584 * Arm a safepoint callback for a thread. If funct is null,
1585 * clear any pending callback.
1586 * TODO: only gc is currently using this feature, and will have
1587 * at most a single outstanding callback request. Until we need
1588 * something more capable and flexible, enforce this limit.
1589 */
dvmArmSafePointCallback(Thread * thread,SafePointCallback funct,void * arg)1590 void dvmArmSafePointCallback(Thread* thread, SafePointCallback funct,
1591 void* arg)
1592 {
1593 dvmLockMutex(&thread->callbackMutex);
1594 if ((funct == NULL) || (thread->callback == NULL)) {
1595 thread->callback = funct;
1596 thread->callbackArg = arg;
1597 if (funct != NULL) {
1598 dvmEnableSubMode(thread, kSubModeCallbackPending);
1599 } else {
1600 dvmDisableSubMode(thread, kSubModeCallbackPending);
1601 }
1602 } else {
1603 // Already armed. Different?
1604 if ((funct != thread->callback) ||
1605 (arg != thread->callbackArg)) {
1606 // Yes - report failure and die
1607 ALOGE("ArmSafePointCallback failed, thread %d", thread->threadId);
1608 dvmUnlockMutex(&thread->callbackMutex);
1609 dvmAbort();
1610 }
1611 }
1612 dvmUnlockMutex(&thread->callbackMutex);
1613 }
1614
1615 /*
1616 * One-time initialization at thread creation. Here we initialize
1617 * useful constants.
1618 */
dvmInitInterpreterState(Thread * self)1619 void dvmInitInterpreterState(Thread* self)
1620 {
1621 #if defined(WITH_JIT)
1622 /*
1623 * Reserve a static entity here to quickly setup runtime contents as
1624 * gcc will issue block copy instructions.
1625 */
1626 static struct JitToInterpEntries jitToInterpEntries = {
1627 dvmJitToInterpNormal,
1628 dvmJitToInterpNoChain,
1629 dvmJitToInterpPunt,
1630 dvmJitToInterpSingleStep,
1631 dvmJitToInterpTraceSelect,
1632 #if defined(WITH_SELF_VERIFICATION)
1633 dvmJitToInterpBackwardBranch,
1634 #else
1635 NULL,
1636 #endif
1637 };
1638 #endif
1639
1640 // Begin initialization
1641 self->cardTable = gDvm.biasedCardTableBase;
1642 #if defined(WITH_JIT)
1643 // One-time initializations
1644 self->jitToInterpEntries = jitToInterpEntries;
1645 self->icRechainCount = PREDICTED_CHAIN_COUNTER_RECHAIN;
1646 self->pProfileCountdown = &gDvmJit.profileCountdown;
1647 // Jit state that can change
1648 dvmJitUpdateThreadStateSingle(self);
1649 #endif
1650 dvmInitializeInterpBreak(self);
1651 }
1652
1653 /*
1654 * For a newly-created thread, we need to start off with interpBreak
1655 * set to any existing global modes. The caller must hold the
1656 * thread list lock.
1657 */
dvmInitializeInterpBreak(Thread * thread)1658 void dvmInitializeInterpBreak(Thread* thread)
1659 {
1660 if (gDvm.instructionCountEnableCount > 0) {
1661 dvmEnableSubMode(thread, kSubModeInstCounting);
1662 }
1663 if (dvmIsMethodTraceActive()) {
1664 dvmEnableSubMode(thread, kSubModeMethodTrace);
1665 }
1666 if (gDvm.emulatorTraceEnableCount > 0) {
1667 dvmEnableSubMode(thread, kSubModeEmulatorTrace);
1668 }
1669 if (gDvm.debuggerActive) {
1670 dvmEnableSubMode(thread, kSubModeDebuggerActive);
1671 }
1672 #if defined(WITH_JIT)
1673 dvmJitUpdateThreadStateSingle(thread);
1674 #endif
1675 #if 0
1676 // Debugging stress mode - force checkBefore
1677 dvmEnableSubMode(thread, kSubModeCheckAlways);
1678 #endif
1679 }
1680
1681 /*
1682 * Inter-instruction handler invoked in between instruction interpretations
1683 * to handle exceptional events such as debugging housekeeping, instruction
1684 * count profiling, JIT trace building, etc. Dalvik PC has been exported
1685 * prior to call, but Thread copy of dPC & fp are not current.
1686 */
dvmCheckBefore(const u2 * pc,u4 * fp,Thread * self)1687 void dvmCheckBefore(const u2 *pc, u4 *fp, Thread* self)
1688 {
1689 const Method* method = self->interpSave.method;
1690 assert(pc >= method->insns && pc <
1691 method->insns + dvmGetMethodInsnsSize(method));
1692
1693 #if 0
1694 /*
1695 * When we hit a specific method, enable verbose instruction logging.
1696 * Sometimes it's helpful to use the debugger attach as a trigger too.
1697 */
1698 if (*pIsMethodEntry) {
1699 static const char* cd = "Landroid/test/Arithmetic;";
1700 static const char* mn = "shiftTest2";
1701 static const char* sg = "()V";
1702
1703 if (/*self->interpBreak.ctl.subMode & kSubModeDebuggerActive &&*/
1704 strcmp(method->clazz->descriptor, cd) == 0 &&
1705 strcmp(method->name, mn) == 0 &&
1706 strcmp(method->shorty, sg) == 0)
1707 {
1708 ALOGW("Reached %s.%s, enabling verbose mode",
1709 method->clazz->descriptor, method->name);
1710 android_setMinPriority(LOG_TAG"i", ANDROID_LOG_VERBOSE);
1711 dumpRegs(method, fp, true);
1712 }
1713
1714 if (!gDvm.debuggerActive)
1715 *pIsMethodEntry = false;
1716 }
1717 #endif
1718
1719 /* Safe point handling */
1720 if (self->suspendCount ||
1721 (self->interpBreak.ctl.subMode & kSubModeCallbackPending)) {
1722 // Are we are a safe point?
1723 int flags;
1724 flags = dexGetFlagsFromOpcode(dexOpcodeFromCodeUnit(*pc));
1725 if (flags & (VERIFY_GC_INST_MASK & ~kInstrCanThrow)) {
1726 // Yes, at a safe point. Pending callback?
1727 if (self->interpBreak.ctl.subMode & kSubModeCallbackPending) {
1728 SafePointCallback callback;
1729 void* arg;
1730 // Get consistent funct/arg pair
1731 dvmLockMutex(&self->callbackMutex);
1732 callback = self->callback;
1733 arg = self->callbackArg;
1734 dvmUnlockMutex(&self->callbackMutex);
1735 // Update Thread structure
1736 self->interpSave.pc = pc;
1737 self->interpSave.curFrame = fp;
1738 if (callback != NULL) {
1739 // Do the callback
1740 if (!callback(self,arg)) {
1741 // disarm
1742 dvmArmSafePointCallback(self, NULL, NULL);
1743 }
1744 }
1745 }
1746 // Need to suspend?
1747 if (self->suspendCount) {
1748 dvmExportPC(pc, fp);
1749 dvmCheckSuspendPending(self);
1750 }
1751 }
1752 }
1753
1754 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
1755 updateDebugger(method, pc, fp, self);
1756 }
1757 if (gDvm.instructionCountEnableCount != 0) {
1758 /*
1759 * Count up the #of executed instructions. This isn't synchronized
1760 * for thread-safety; if we need that we should make this
1761 * thread-local and merge counts into the global area when threads
1762 * exit (perhaps suspending all other threads GC-style and pulling
1763 * the data out of them).
1764 */
1765 gDvm.executedInstrCounts[GET_OPCODE(*pc)]++;
1766 }
1767
1768
1769 #if defined(WITH_TRACKREF_CHECKS)
1770 dvmInterpCheckTrackedRefs(self, method,
1771 self->interpSave.debugTrackedRefStart);
1772 #endif
1773
1774 #if defined(WITH_JIT)
1775 // Does the JIT need anything done now?
1776 if (self->interpBreak.ctl.subMode &
1777 (kSubModeJitTraceBuild | kSubModeJitSV)) {
1778 // Are we building a trace?
1779 if (self->interpBreak.ctl.subMode & kSubModeJitTraceBuild) {
1780 dvmCheckJit(pc, self);
1781 }
1782
1783 #if defined(WITH_SELF_VERIFICATION)
1784 // Are we replaying a trace?
1785 if (self->interpBreak.ctl.subMode & kSubModeJitSV) {
1786 dvmCheckSelfVerification(pc, self);
1787 }
1788 #endif
1789 }
1790 #endif
1791
1792 /*
1793 * CountedStep processing. NOTE: must be the last here to allow
1794 * preceeding special case handler to manipulate single-step count.
1795 */
1796 if (self->interpBreak.ctl.subMode & kSubModeCountedStep) {
1797 if (self->singleStepCount == 0) {
1798 // We've exhausted our single step count
1799 dvmDisableSubMode(self, kSubModeCountedStep);
1800 #if defined(WITH_JIT)
1801 #if 0
1802 /*
1803 * For debugging. If jitResumeDPC is non-zero, then
1804 * we expect to return to a trace in progress. There
1805 * are valid reasons why we wouldn't (such as an exception
1806 * throw), but here we can keep track.
1807 */
1808 if (self->jitResumeDPC != NULL) {
1809 if (self->jitResumeDPC == pc) {
1810 if (self->jitResumeNPC != NULL) {
1811 ALOGD("SS return to trace - pc:%#x to 0x:%x",
1812 (int)pc, (int)self->jitResumeNPC);
1813 } else {
1814 ALOGD("SS return to interp - pc:%#x",(int)pc);
1815 }
1816 } else {
1817 ALOGD("SS failed to return. Expected %#x, now at %#x",
1818 (int)self->jitResumeDPC, (int)pc);
1819 }
1820 }
1821 #endif
1822 #if 0
1823 // TODO - fix JIT single-stepping resume mode (b/5551114)
1824 // self->jitResumeNPC needs to be cleared in callPrep
1825
1826 // If we've got a native return and no other reasons to
1827 // remain in singlestep/break mode, do a long jump
1828 if (self->jitResumeNPC != NULL &&
1829 self->interpBreak.ctl.breakFlags == 0) {
1830 assert(self->jitResumeDPC == pc);
1831 self->jitResumeDPC = NULL;
1832 dvmJitResumeTranslation(self, pc, fp);
1833 // Doesn't return
1834 dvmAbort();
1835 }
1836 // In case resume is blocked by non-zero breakFlags, clear
1837 // jitResumeNPC here.
1838 self->jitResumeNPC = NULL;
1839 self->jitResumeDPC = NULL;
1840 self->inJitCodeCache = NULL;
1841 #endif
1842 #endif
1843 } else {
1844 self->singleStepCount--;
1845 #if defined(WITH_JIT)
1846 if ((self->singleStepCount > 0) && (self->jitResumeNPC != NULL)) {
1847 /*
1848 * Direct return to an existing translation following a
1849 * single step is valid only if we step once. If we're
1850 * here, an additional step was added so we need to invalidate
1851 * the return to translation.
1852 */
1853 self->jitResumeNPC = NULL;
1854 self->inJitCodeCache = NULL;
1855 }
1856 #endif
1857 }
1858 }
1859 }
1860
1861 /*
1862 * Main interpreter loop entry point.
1863 *
1864 * This begins executing code at the start of "method". On exit, "pResult"
1865 * holds the return value of the method (or, if "method" returns NULL, it
1866 * holds an undefined value).
1867 *
1868 * The interpreted stack frame, which holds the method arguments, has
1869 * already been set up.
1870 */
dvmInterpret(Thread * self,const Method * method,JValue * pResult)1871 void dvmInterpret(Thread* self, const Method* method, JValue* pResult)
1872 {
1873 InterpSaveState interpSaveState;
1874 ExecutionSubModes savedSubModes;
1875
1876 #if defined(WITH_JIT)
1877 /* Target-specific save/restore */
1878 double calleeSave[JIT_CALLEE_SAVE_DOUBLE_COUNT];
1879 /*
1880 * If the previous VM left the code cache through single-stepping the
1881 * inJitCodeCache flag will be set when the VM is re-entered (for example,
1882 * in self-verification mode we single-step NEW_INSTANCE which may re-enter
1883 * the VM through findClassFromLoaderNoInit). Because of that, we cannot
1884 * assert that self->inJitCodeCache is NULL here.
1885 */
1886 #endif
1887
1888 /*
1889 * Save interpreter state from previous activation, linking
1890 * new to last.
1891 */
1892 interpSaveState = self->interpSave;
1893 self->interpSave.prev = &interpSaveState;
1894 /*
1895 * Strip out and save any flags that should not be inherited by
1896 * nested interpreter activation.
1897 */
1898 savedSubModes = (ExecutionSubModes)(
1899 self->interpBreak.ctl.subMode & LOCAL_SUBMODE);
1900 if (savedSubModes != kSubModeNormal) {
1901 dvmDisableSubMode(self, savedSubModes);
1902 }
1903 #if defined(WITH_JIT)
1904 dvmJitCalleeSave(calleeSave);
1905 #endif
1906
1907
1908 #if defined(WITH_TRACKREF_CHECKS)
1909 self->interpSave.debugTrackedRefStart =
1910 dvmReferenceTableEntries(&self->internalLocalRefTable);
1911 #endif
1912 self->debugIsMethodEntry = true;
1913 #if defined(WITH_JIT)
1914 /* Initialize the state to kJitNot */
1915 self->jitState = kJitNot;
1916 #endif
1917
1918 /*
1919 * Initialize working state.
1920 *
1921 * No need to initialize "retval".
1922 */
1923 self->interpSave.method = method;
1924 self->interpSave.curFrame = (u4*) self->interpSave.curFrame;
1925 self->interpSave.pc = method->insns;
1926
1927 assert(!dvmIsNativeMethod(method));
1928
1929 /*
1930 * Make sure the class is ready to go. Shouldn't be possible to get
1931 * here otherwise.
1932 */
1933 if (method->clazz->status < CLASS_INITIALIZING ||
1934 method->clazz->status == CLASS_ERROR)
1935 {
1936 ALOGE("ERROR: tried to execute code in unprepared class '%s' (%d)",
1937 method->clazz->descriptor, method->clazz->status);
1938 dvmDumpThread(self, false);
1939 dvmAbort();
1940 }
1941
1942 typedef void (*Interpreter)(Thread*);
1943 Interpreter stdInterp;
1944 if (gDvm.executionMode == kExecutionModeInterpFast)
1945 stdInterp = dvmMterpStd;
1946 #if defined(WITH_JIT)
1947 else if (gDvm.executionMode == kExecutionModeJit ||
1948 gDvm.executionMode == kExecutionModeNcgO0 ||
1949 gDvm.executionMode == kExecutionModeNcgO1)
1950 stdInterp = dvmMterpStd;
1951 #endif
1952 else
1953 stdInterp = dvmInterpretPortable;
1954
1955 // Call the interpreter
1956 (*stdInterp)(self);
1957
1958 *pResult = self->interpSave.retval;
1959
1960 /* Restore interpreter state from previous activation */
1961 self->interpSave = interpSaveState;
1962 #if defined(WITH_JIT)
1963 dvmJitCalleeRestore(calleeSave);
1964 #endif
1965 if (savedSubModes != kSubModeNormal) {
1966 dvmEnableSubMode(self, savedSubModes);
1967 }
1968 }
1969