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gerrit-public.fairphone.software / fp2-dev / platform / dalvik / 08351f6ad0e6efa40955cc37a64cc29a7daa031b / . / vm / mterp / out / InterpC-x86.cpp
blob: 7f89d6204a5dbf893a6f581a652dcb891f01be05 [file] [log] [blame]
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1/*
2 * This file was generated automatically by gen-mterp.py for 'x86'.
3 *
4 * --> DO NOT EDIT <--
5 */
6
7/* File: c/header.cpp */
8/*
9 * Copyright (C) 2008 The Android Open Source Project
10 *
11 * Licensed under the Apache License, Version 2.0 (the "License");
12 * you may not use this file except in compliance with the License.
13 * You may obtain a copy of the License at
14 *
15 * http://www.apache.org/licenses/LICENSE-2.0
16 *
17 * Unless required by applicable law or agreed to in writing, software
18 * distributed under the License is distributed on an "AS IS" BASIS,
19 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
20 * See the License for the specific language governing permissions and
21 * limitations under the License.
22 */
23
24/* common includes */
25#include "Dalvik.h"
26#include "interp/InterpDefs.h"
27#include "mterp/Mterp.h"
28#include <math.h> // needed for fmod, fmodf
29#include "mterp/common/FindInterface.h"
30
31/*
32 * Configuration defines. These affect the C implementations, i.e. the
33 * portable interpreter(s) and C stubs.
34 *
35 * Some defines are controlled by the Makefile, e.g.:
36 * WITH_INSTR_CHECKS
37 * WITH_TRACKREF_CHECKS
38 * EASY_GDB
39 * NDEBUG
40 */
41
42#ifdef WITH_INSTR_CHECKS /* instruction-level paranoia (slow!) */
43# define CHECK_BRANCH_OFFSETS
44# define CHECK_REGISTER_INDICES
45#endif
46
47/*
48 * Some architectures require 64-bit alignment for access to 64-bit data
49 * types. We can't just use pointers to copy 64-bit values out of our
50 * interpreted register set, because gcc may assume the pointer target is
51 * aligned and generate invalid code.
52 *
53 * There are two common approaches:
54 * (1) Use a union that defines a 32-bit pair and a 64-bit value.
55 * (2) Call memcpy().
56 *
57 * Depending upon what compiler you're using and what options are specified,
58 * one may be faster than the other. For example, the compiler might
59 * convert a memcpy() of 8 bytes into a series of instructions and omit
60 * the call. The union version could cause some strange side-effects,
61 * e.g. for a while ARM gcc thought it needed separate storage for each
62 * inlined instance, and generated instructions to zero out ~700 bytes of
63 * stack space at the top of the interpreter.
64 *
65 * The default is to use memcpy(). The current gcc for ARM seems to do
66 * better with the union.
67 */
68#if defined(__ARM_EABI__)
69# define NO_UNALIGN_64__UNION
70#endif
71
72
73//#define LOG_INSTR /* verbose debugging */
74/* set and adjust ANDROID_LOG_TAGS='*:i jdwp:i dalvikvm:i dalvikvmi:i' */
75
76/*
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]77 * Export another copy of the PC on every instruction; this is largely
78 * redundant with EXPORT_PC and the debugger code. This value can be
79 * compared against what we have stored on the stack with EXPORT_PC to
80 * help ensure that we aren't missing any export calls.
81 */
82#if WITH_EXTRA_GC_CHECKS > 1
83# define EXPORT_EXTRA_PC() (self->currentPc2 = pc)
84#else
85# define EXPORT_EXTRA_PC()
86#endif
87
88/*
89 * Adjust the program counter. "_offset" is a signed int, in 16-bit units.
90 *
91 * Assumes the existence of "const u2* pc" and "const u2* curMethod->insns".
92 *
93 * We don't advance the program counter until we finish an instruction or
94 * branch, because we do want to have to unroll the PC if there's an
95 * exception.
96 */
97#ifdef CHECK_BRANCH_OFFSETS
98# define ADJUST_PC(_offset) do { \
99 int myoff = _offset; /* deref only once */ \
100 if (pc + myoff < curMethod->insns || \
101 pc + myoff >= curMethod->insns + dvmGetMethodInsnsSize(curMethod)) \
102 { \
103 char* desc; \
104 desc = dexProtoCopyMethodDescriptor(&curMethod->prototype); \
105 LOGE("Invalid branch %d at 0x%04x in %s.%s %s\n", \
106 myoff, (int) (pc - curMethod->insns), \
107 curMethod->clazz->descriptor, curMethod->name, desc); \
108 free(desc); \
109 dvmAbort(); \
110 } \
111 pc += myoff; \
112 EXPORT_EXTRA_PC(); \
113 } while (false)
114#else
115# define ADJUST_PC(_offset) do { \
116 pc += _offset; \
117 EXPORT_EXTRA_PC(); \
118 } while (false)
119#endif
120
121/*
122 * If enabled, log instructions as we execute them.
123 */
124#ifdef LOG_INSTR
125# define ILOGD(...) ILOG(LOG_DEBUG, __VA_ARGS__)
126# define ILOGV(...) ILOG(LOG_VERBOSE, __VA_ARGS__)
127# define ILOG(_level, ...) do { \
128 char debugStrBuf[128]; \
129 snprintf(debugStrBuf, sizeof(debugStrBuf), __VA_ARGS__); \
130 if (curMethod != NULL) \
131 LOG(_level, LOG_TAG"i", "%-2d|%04x%s\n", \
132 self->threadId, (int)(pc - curMethod->insns), debugStrBuf); \
133 else \
134 LOG(_level, LOG_TAG"i", "%-2d|####%s\n", \
135 self->threadId, debugStrBuf); \
136 } while(false)
137void dvmDumpRegs(const Method* method, const u4* framePtr, bool inOnly);
138# define DUMP_REGS(_meth, _frame, _inOnly) dvmDumpRegs(_meth, _frame, _inOnly)
139static const char kSpacing[] = " ";
140#else
141# define ILOGD(...) ((void)0)
142# define ILOGV(...) ((void)0)
143# define DUMP_REGS(_meth, _frame, _inOnly) ((void)0)
144#endif
145
146/* get a long from an array of u4 */
147static inline s8 getLongFromArray(const u4* ptr, int idx)
148{
149#if defined(NO_UNALIGN_64__UNION)
150 union { s8 ll; u4 parts[2]; } conv;
151
152 ptr += idx;
153 conv.parts[0] = ptr[0];
154 conv.parts[1] = ptr[1];
155 return conv.ll;
156#else
157 s8 val;
158 memcpy(&val, &ptr[idx], 8);
159 return val;
160#endif
161}
162
163/* store a long into an array of u4 */
164static inline void putLongToArray(u4* ptr, int idx, s8 val)
165{
166#if defined(NO_UNALIGN_64__UNION)
167 union { s8 ll; u4 parts[2]; } conv;
168
169 ptr += idx;
170 conv.ll = val;
171 ptr[0] = conv.parts[0];
172 ptr[1] = conv.parts[1];
173#else
174 memcpy(&ptr[idx], &val, 8);
175#endif
176}
177
178/* get a double from an array of u4 */
179static inline double getDoubleFromArray(const u4* ptr, int idx)
180{
181#if defined(NO_UNALIGN_64__UNION)
182 union { double d; u4 parts[2]; } conv;
183
184 ptr += idx;
185 conv.parts[0] = ptr[0];
186 conv.parts[1] = ptr[1];
187 return conv.d;
188#else
189 double dval;
190 memcpy(&dval, &ptr[idx], 8);
191 return dval;
192#endif
193}
194
195/* store a double into an array of u4 */
196static inline void putDoubleToArray(u4* ptr, int idx, double dval)
197{
198#if defined(NO_UNALIGN_64__UNION)
199 union { double d; u4 parts[2]; } conv;
200
201 ptr += idx;
202 conv.d = dval;
203 ptr[0] = conv.parts[0];
204 ptr[1] = conv.parts[1];
205#else
206 memcpy(&ptr[idx], &dval, 8);
207#endif
208}
209
210/*
211 * If enabled, validate the register number on every access. Otherwise,
212 * just do an array access.
213 *
214 * Assumes the existence of "u4* fp".
215 *
216 * "_idx" may be referenced more than once.
217 */
218#ifdef CHECK_REGISTER_INDICES
219# define GET_REGISTER(_idx) \
220 ( (_idx) < curMethod->registersSize ? \
221 (fp[(_idx)]) : (assert(!"bad reg"),1969) )
222# define SET_REGISTER(_idx, _val) \
223 ( (_idx) < curMethod->registersSize ? \
224 (fp[(_idx)] = (u4)(_val)) : (assert(!"bad reg"),1969) )
225# define GET_REGISTER_AS_OBJECT(_idx) ((Object *)GET_REGISTER(_idx))
226# define SET_REGISTER_AS_OBJECT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
227# define GET_REGISTER_INT(_idx) ((s4) GET_REGISTER(_idx))
228# define SET_REGISTER_INT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
229# define GET_REGISTER_WIDE(_idx) \
230 ( (_idx) < curMethod->registersSize-1 ? \
231 getLongFromArray(fp, (_idx)) : (assert(!"bad reg"),1969) )
232# define SET_REGISTER_WIDE(_idx, _val) \
233 ( (_idx) < curMethod->registersSize-1 ? \
234 putLongToArray(fp, (_idx), (_val)) : (assert(!"bad reg"),1969) )
235# define GET_REGISTER_FLOAT(_idx) \
236 ( (_idx) < curMethod->registersSize ? \
237 (*((float*) &fp[(_idx)])) : (assert(!"bad reg"),1969.0f) )
238# define SET_REGISTER_FLOAT(_idx, _val) \
239 ( (_idx) < curMethod->registersSize ? \
240 (*((float*) &fp[(_idx)]) = (_val)) : (assert(!"bad reg"),1969.0f) )
241# define GET_REGISTER_DOUBLE(_idx) \
242 ( (_idx) < curMethod->registersSize-1 ? \
243 getDoubleFromArray(fp, (_idx)) : (assert(!"bad reg"),1969.0) )
244# define SET_REGISTER_DOUBLE(_idx, _val) \
245 ( (_idx) < curMethod->registersSize-1 ? \
246 putDoubleToArray(fp, (_idx), (_val)) : (assert(!"bad reg"),1969.0) )
247#else
248# define GET_REGISTER(_idx) (fp[(_idx)])
249# define SET_REGISTER(_idx, _val) (fp[(_idx)] = (_val))
250# define GET_REGISTER_AS_OBJECT(_idx) ((Object*) fp[(_idx)])
251# define SET_REGISTER_AS_OBJECT(_idx, _val) (fp[(_idx)] = (u4)(_val))
252# define GET_REGISTER_INT(_idx) ((s4)GET_REGISTER(_idx))
253# define SET_REGISTER_INT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
254# define GET_REGISTER_WIDE(_idx) getLongFromArray(fp, (_idx))
255# define SET_REGISTER_WIDE(_idx, _val) putLongToArray(fp, (_idx), (_val))
256# define GET_REGISTER_FLOAT(_idx) (*((float*) &fp[(_idx)]))
257# define SET_REGISTER_FLOAT(_idx, _val) (*((float*) &fp[(_idx)]) = (_val))
258# define GET_REGISTER_DOUBLE(_idx) getDoubleFromArray(fp, (_idx))
259# define SET_REGISTER_DOUBLE(_idx, _val) putDoubleToArray(fp, (_idx), (_val))
260#endif
261
262/*
263 * Get 16 bits from the specified offset of the program counter. We always
264 * want to load 16 bits at a time from the instruction stream -- it's more
265 * efficient than 8 and won't have the alignment problems that 32 might.
266 *
267 * Assumes existence of "const u2* pc".
268 */
269#define FETCH(_offset) (pc[(_offset)])
270
271/*
272 * Extract instruction byte from 16-bit fetch (_inst is a u2).
273 */
274#define INST_INST(_inst) ((_inst) & 0xff)
275
276/*
277 * Replace the opcode (used when handling breakpoints). _opcode is a u1.
278 */
279#define INST_REPLACE_OP(_inst, _opcode) (((_inst) & 0xff00) | _opcode)
280
281/*
282 * Extract the "vA, vB" 4-bit registers from the instruction word (_inst is u2).
283 */
284#define INST_A(_inst) (((_inst) >> 8) & 0x0f)
285#define INST_B(_inst) ((_inst) >> 12)
286
287/*
288 * Get the 8-bit "vAA" 8-bit register index from the instruction word.
289 * (_inst is u2)
290 */
291#define INST_AA(_inst) ((_inst) >> 8)
292
293/*
294 * The current PC must be available to Throwable constructors, e.g.
295 * those created by the various exception throw routines, so that the
296 * exception stack trace can be generated correctly. If we don't do this,
297 * the offset within the current method won't be shown correctly. See the
298 * notes in Exception.c.
299 *
300 * This is also used to determine the address for precise GC.
301 *
302 * Assumes existence of "u4* fp" and "const u2* pc".
303 */
304#define EXPORT_PC() (SAVEAREA_FROM_FP(fp)->xtra.currentPc = pc)
305
306/*
307 * Check to see if "obj" is NULL. If so, throw an exception. Assumes the
308 * pc has already been exported to the stack.
309 *
310 * Perform additional checks on debug builds.
311 *
312 * Use this to check for NULL when the instruction handler calls into
313 * something that could throw an exception (so we have already called
314 * EXPORT_PC at the top).
315 */
316static inline bool checkForNull(Object* obj)
317{
318 if (obj == NULL) {
319 dvmThrowNullPointerException(NULL);
320 return false;
321 }
322#ifdef WITH_EXTRA_OBJECT_VALIDATION
323 if (!dvmIsValidObject(obj)) {
324 LOGE("Invalid object %p\n", obj);
325 dvmAbort();
326 }
327#endif
328#ifndef NDEBUG
329 if (obj->clazz == NULL || ((u4) obj->clazz) <= 65536) {
330 /* probable heap corruption */
331 LOGE("Invalid object class %p (in %p)\n", obj->clazz, obj);
332 dvmAbort();
333 }
334#endif
335 return true;
336}
337
338/*
339 * Check to see if "obj" is NULL. If so, export the PC into the stack
340 * frame and throw an exception.
341 *
342 * Perform additional checks on debug builds.
343 *
344 * Use this to check for NULL when the instruction handler doesn't do
345 * anything else that can throw an exception.
346 */
347static inline bool checkForNullExportPC(Object* obj, u4* fp, const u2* pc)
348{
349 if (obj == NULL) {
350 EXPORT_PC();
351 dvmThrowNullPointerException(NULL);
352 return false;
353 }
354#ifdef WITH_EXTRA_OBJECT_VALIDATION
355 if (!dvmIsValidObject(obj)) {
356 LOGE("Invalid object %p\n", obj);
357 dvmAbort();
358 }
359#endif
360#ifndef NDEBUG
361 if (obj->clazz == NULL || ((u4) obj->clazz) <= 65536) {
362 /* probable heap corruption */
363 LOGE("Invalid object class %p (in %p)\n", obj->clazz, obj);
364 dvmAbort();
365 }
366#endif
367 return true;
368}
369
370/* File: cstubs/stubdefs.cpp */
371/*
372 * In the C mterp stubs, "goto" is a function call followed immediately
373 * by a return.
374 */
375
376#define GOTO_TARGET_DECL(_target, ...) \
377 extern "C" void dvmMterp_##_target(Thread* self, ## __VA_ARGS__);
378
379/* (void)xxx to quiet unused variable compiler warnings. */
380#define GOTO_TARGET(_target, ...) \
381 void dvmMterp_##_target(Thread* self, ## __VA_ARGS__) { \
382 u2 ref, vsrc1, vsrc2, vdst; \
383 u2 inst = FETCH(0); \
384 const Method* methodToCall; \
385 StackSaveArea* debugSaveArea; \
386 (void)ref; (void)vsrc1; (void)vsrc2; (void)vdst; (void)inst; \
387 (void)methodToCall; (void)debugSaveArea;
388
389#define GOTO_TARGET_END }
390
391/*
392 * Redefine what used to be local variable accesses into Thread struct
393 * references. (These are undefined down in "footer.c".)
394 */
395#define retval self->retval
396#define pc self->interpSave.pc
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]397#define fp self->interpSave.curFrame
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]398#define curMethod self->interpSave.method
399#define methodClassDex self->interpSave.methodClassDex
400#define debugTrackedRefStart self->interpSave.debugTrackedRefStart
401
402/* ugh */
403#define STUB_HACK(x) x
404#if defined(WITH_JIT)
405#define JIT_STUB_HACK(x) x
406#else
407#define JIT_STUB_HACK(x)
408#endif
409
410/*
411 * InterpSave's pc and fp must be valid when breaking out to a
412 * "Reportxxx" routine. Because the portable interpreter uses local
413 * variables for these, we must flush prior. Stubs, however, use
414 * the interpSave vars directly, so this is a nop for stubs.
415 */
416#define PC_FP_TO_SELF()
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]417#define PC_TO_SELF()
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]418
419/*
420 * Opcode handler framing macros. Here, each opcode is a separate function
421 * that takes a "self" argument and returns void. We can't declare
422 * these "static" because they may be called from an assembly stub.
423 * (void)xxx to quiet unused variable compiler warnings.
424 */
425#define HANDLE_OPCODE(_op) \
426 extern "C" void dvmMterp_##_op(Thread* self); \
427 void dvmMterp_##_op(Thread* self) { \
428 u4 ref; \
429 u2 vsrc1, vsrc2, vdst; \
430 u2 inst = FETCH(0); \
431 (void)ref; (void)vsrc1; (void)vsrc2; (void)vdst; (void)inst;
432
433#define OP_END }
434
435/*
436 * Like the "portable" FINISH, but don't reload "inst", and return to caller
437 * when done. Further, debugger/profiler checks are handled
438 * before handler execution in mterp, so we don't do them here either.
439 */
440#if defined(WITH_JIT)
441#define FINISH(_offset) { \
442 ADJUST_PC(_offset); \
443 if (self->interpBreak.ctl.subMode & kSubModeJitTraceBuild) { \
444 dvmCheckJit(pc, self); \
445 } \
446 return; \
447 }
448#else
449#define FINISH(_offset) { \
450 ADJUST_PC(_offset); \
451 return; \
452 }
453#endif
454
455
456/*
457 * The "goto label" statements turn into function calls followed by
458 * return statements. Some of the functions take arguments, which in the
459 * portable interpreter are handled by assigning values to globals.
460 */
461
462#define GOTO_exceptionThrown() \
463 do { \
464 dvmMterp_exceptionThrown(self); \
465 return; \
466 } while(false)
467
468#define GOTO_returnFromMethod() \
469 do { \
470 dvmMterp_returnFromMethod(self); \
471 return; \
472 } while(false)
473
474#define GOTO_invoke(_target, _methodCallRange, _jumboFormat) \
475 do { \
476 dvmMterp_##_target(self, _methodCallRange, _jumboFormat); \
477 return; \
478 } while(false)
479
480#define GOTO_invokeMethod(_methodCallRange, _methodToCall, _vsrc1, _vdst) \
481 do { \
482 dvmMterp_invokeMethod(self, _methodCallRange, _methodToCall, \
483 _vsrc1, _vdst); \
484 return; \
485 } while(false)
486
487/*
488 * As a special case, "goto bail" turns into a longjmp.
489 */
490#define GOTO_bail() \
491 dvmMterpStdBail(self, false);
492
493/*
494 * Periodically check for thread suspension.
495 *
496 * While we're at it, see if a debugger has attached or the profiler has
497 * started.
498 */
499#define PERIODIC_CHECKS(_pcadj) { \
500 if (dvmCheckSuspendQuick(self)) { \
501 EXPORT_PC(); /* need for precise GC */ \
502 dvmCheckSuspendPending(self); \
503 } \
504 }
505
506/* File: c/opcommon.cpp */
507/* forward declarations of goto targets */
508GOTO_TARGET_DECL(filledNewArray, bool methodCallRange, bool jumboFormat);
509GOTO_TARGET_DECL(invokeVirtual, bool methodCallRange, bool jumboFormat);
510GOTO_TARGET_DECL(invokeSuper, bool methodCallRange, bool jumboFormat);
511GOTO_TARGET_DECL(invokeInterface, bool methodCallRange, bool jumboFormat);
512GOTO_TARGET_DECL(invokeDirect, bool methodCallRange, bool jumboFormat);
513GOTO_TARGET_DECL(invokeStatic, bool methodCallRange, bool jumboFormat);
514GOTO_TARGET_DECL(invokeVirtualQuick, bool methodCallRange, bool jumboFormat);
515GOTO_TARGET_DECL(invokeSuperQuick, bool methodCallRange, bool jumboFormat);
516GOTO_TARGET_DECL(invokeMethod, bool methodCallRange, const Method* methodToCall,
517 u2 count, u2 regs);
518GOTO_TARGET_DECL(returnFromMethod);
519GOTO_TARGET_DECL(exceptionThrown);
520
521/*
522 * ===========================================================================
523 *
524 * What follows are opcode definitions shared between multiple opcodes with
525 * minor substitutions handled by the C pre-processor. These should probably
526 * use the mterp substitution mechanism instead, with the code here moved
527 * into common fragment files (like the asm "binop.S"), although it's hard
528 * to give up the C preprocessor in favor of the much simpler text subst.
529 *
530 * ===========================================================================
531 */
532
533#define HANDLE_NUMCONV(_opcode, _opname, _fromtype, _totype) \
534 HANDLE_OPCODE(_opcode /*vA, vB*/) \
535 vdst = INST_A(inst); \
536 vsrc1 = INST_B(inst); \
537 ILOGV("|%s v%d,v%d", (_opname), vdst, vsrc1); \
538 SET_REGISTER##_totype(vdst, \
539 GET_REGISTER##_fromtype(vsrc1)); \
540 FINISH(1);
541
542#define HANDLE_FLOAT_TO_INT(_opcode, _opname, _fromvtype, _fromrtype, \
543 _tovtype, _tortype) \
544 HANDLE_OPCODE(_opcode /*vA, vB*/) \
545 { \
546 /* spec defines specific handling for +/- inf and NaN values */ \
547 _fromvtype val; \
548 _tovtype intMin, intMax, result; \
549 vdst = INST_A(inst); \
550 vsrc1 = INST_B(inst); \
551 ILOGV("|%s v%d,v%d", (_opname), vdst, vsrc1); \
552 val = GET_REGISTER##_fromrtype(vsrc1); \
553 intMin = (_tovtype) 1 << (sizeof(_tovtype) * 8 -1); \
554 intMax = ~intMin; \
555 result = (_tovtype) val; \
556 if (val >= intMax) /* +inf */ \
557 result = intMax; \
558 else if (val <= intMin) /* -inf */ \
559 result = intMin; \
560 else if (val != val) /* NaN */ \
561 result = 0; \
562 else \
563 result = (_tovtype) val; \
564 SET_REGISTER##_tortype(vdst, result); \
565 } \
566 FINISH(1);
567
568#define HANDLE_INT_TO_SMALL(_opcode, _opname, _type) \
569 HANDLE_OPCODE(_opcode /*vA, vB*/) \
570 vdst = INST_A(inst); \
571 vsrc1 = INST_B(inst); \
572 ILOGV("|int-to-%s v%d,v%d", (_opname), vdst, vsrc1); \
573 SET_REGISTER(vdst, (_type) GET_REGISTER(vsrc1)); \
574 FINISH(1);
575
576/* NOTE: the comparison result is always a signed 4-byte integer */
577#define HANDLE_OP_CMPX(_opcode, _opname, _varType, _type, _nanVal) \
578 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
579 { \
580 int result; \
581 u2 regs; \
582 _varType val1, val2; \
583 vdst = INST_AA(inst); \
584 regs = FETCH(1); \
585 vsrc1 = regs & 0xff; \
586 vsrc2 = regs >> 8; \
587 ILOGV("|cmp%s v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
588 val1 = GET_REGISTER##_type(vsrc1); \
589 val2 = GET_REGISTER##_type(vsrc2); \
590 if (val1 == val2) \
591 result = 0; \
592 else if (val1 < val2) \
593 result = -1; \
594 else if (val1 > val2) \
595 result = 1; \
596 else \
597 result = (_nanVal); \
598 ILOGV("+ result=%d\n", result); \
599 SET_REGISTER(vdst, result); \
600 } \
601 FINISH(2);
602
603#define HANDLE_OP_IF_XX(_opcode, _opname, _cmp) \
604 HANDLE_OPCODE(_opcode /*vA, vB, +CCCC*/) \
605 vsrc1 = INST_A(inst); \
606 vsrc2 = INST_B(inst); \
607 if ((s4) GET_REGISTER(vsrc1) _cmp (s4) GET_REGISTER(vsrc2)) { \
608 int branchOffset = (s2)FETCH(1); /* sign-extended */ \
609 ILOGV("|if-%s v%d,v%d,+0x%04x", (_opname), vsrc1, vsrc2, \
610 branchOffset); \
611 ILOGV("> branch taken"); \
612 if (branchOffset < 0) \
613 PERIODIC_CHECKS(branchOffset); \
614 FINISH(branchOffset); \
615 } else { \
616 ILOGV("|if-%s v%d,v%d,-", (_opname), vsrc1, vsrc2); \
617 FINISH(2); \
618 }
619
620#define HANDLE_OP_IF_XXZ(_opcode, _opname, _cmp) \
621 HANDLE_OPCODE(_opcode /*vAA, +BBBB*/) \
622 vsrc1 = INST_AA(inst); \
623 if ((s4) GET_REGISTER(vsrc1) _cmp 0) { \
624 int branchOffset = (s2)FETCH(1); /* sign-extended */ \
625 ILOGV("|if-%s v%d,+0x%04x", (_opname), vsrc1, branchOffset); \
626 ILOGV("> branch taken"); \
627 if (branchOffset < 0) \
628 PERIODIC_CHECKS(branchOffset); \
629 FINISH(branchOffset); \
630 } else { \
631 ILOGV("|if-%s v%d,-", (_opname), vsrc1); \
632 FINISH(2); \
633 }
634
635#define HANDLE_UNOP(_opcode, _opname, _pfx, _sfx, _type) \
636 HANDLE_OPCODE(_opcode /*vA, vB*/) \
637 vdst = INST_A(inst); \
638 vsrc1 = INST_B(inst); \
639 ILOGV("|%s v%d,v%d", (_opname), vdst, vsrc1); \
640 SET_REGISTER##_type(vdst, _pfx GET_REGISTER##_type(vsrc1) _sfx); \
641 FINISH(1);
642
643#define HANDLE_OP_X_INT(_opcode, _opname, _op, _chkdiv) \
644 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
645 { \
646 u2 srcRegs; \
647 vdst = INST_AA(inst); \
648 srcRegs = FETCH(1); \
649 vsrc1 = srcRegs & 0xff; \
650 vsrc2 = srcRegs >> 8; \
651 ILOGV("|%s-int v%d,v%d", (_opname), vdst, vsrc1); \
652 if (_chkdiv != 0) { \
653 s4 firstVal, secondVal, result; \
654 firstVal = GET_REGISTER(vsrc1); \
655 secondVal = GET_REGISTER(vsrc2); \
656 if (secondVal == 0) { \
657 EXPORT_PC(); \
658 dvmThrowArithmeticException("divide by zero"); \
659 GOTO_exceptionThrown(); \
660 } \
661 if ((u4)firstVal == 0x80000000 && secondVal == -1) { \
662 if (_chkdiv == 1) \
663 result = firstVal; /* division */ \
664 else \
665 result = 0; /* remainder */ \
666 } else { \
667 result = firstVal _op secondVal; \
668 } \
669 SET_REGISTER(vdst, result); \
670 } else { \
671 /* non-div/rem case */ \
672 SET_REGISTER(vdst, \
673 (s4) GET_REGISTER(vsrc1) _op (s4) GET_REGISTER(vsrc2)); \
674 } \
675 } \
676 FINISH(2);
677
678#define HANDLE_OP_SHX_INT(_opcode, _opname, _cast, _op) \
679 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
680 { \
681 u2 srcRegs; \
682 vdst = INST_AA(inst); \
683 srcRegs = FETCH(1); \
684 vsrc1 = srcRegs & 0xff; \
685 vsrc2 = srcRegs >> 8; \
686 ILOGV("|%s-int v%d,v%d", (_opname), vdst, vsrc1); \
687 SET_REGISTER(vdst, \
688 _cast GET_REGISTER(vsrc1) _op (GET_REGISTER(vsrc2) & 0x1f)); \
689 } \
690 FINISH(2);
691
692#define HANDLE_OP_X_INT_LIT16(_opcode, _opname, _op, _chkdiv) \
693 HANDLE_OPCODE(_opcode /*vA, vB, #+CCCC*/) \
694 vdst = INST_A(inst); \
695 vsrc1 = INST_B(inst); \
696 vsrc2 = FETCH(1); \
697 ILOGV("|%s-int/lit16 v%d,v%d,#+0x%04x", \
698 (_opname), vdst, vsrc1, vsrc2); \
699 if (_chkdiv != 0) { \
700 s4 firstVal, result; \
701 firstVal = GET_REGISTER(vsrc1); \
702 if ((s2) vsrc2 == 0) { \
703 EXPORT_PC(); \
704 dvmThrowArithmeticException("divide by zero"); \
705 GOTO_exceptionThrown(); \
706 } \
707 if ((u4)firstVal == 0x80000000 && ((s2) vsrc2) == -1) { \
708 /* won't generate /lit16 instr for this; check anyway */ \
709 if (_chkdiv == 1) \
710 result = firstVal; /* division */ \
711 else \
712 result = 0; /* remainder */ \
713 } else { \
714 result = firstVal _op (s2) vsrc2; \
715 } \
716 SET_REGISTER(vdst, result); \
717 } else { \
718 /* non-div/rem case */ \
719 SET_REGISTER(vdst, GET_REGISTER(vsrc1) _op (s2) vsrc2); \
720 } \
721 FINISH(2);
722
723#define HANDLE_OP_X_INT_LIT8(_opcode, _opname, _op, _chkdiv) \
724 HANDLE_OPCODE(_opcode /*vAA, vBB, #+CC*/) \
725 { \
726 u2 litInfo; \
727 vdst = INST_AA(inst); \
728 litInfo = FETCH(1); \
729 vsrc1 = litInfo & 0xff; \
730 vsrc2 = litInfo >> 8; /* constant */ \
731 ILOGV("|%s-int/lit8 v%d,v%d,#+0x%02x", \
732 (_opname), vdst, vsrc1, vsrc2); \
733 if (_chkdiv != 0) { \
734 s4 firstVal, result; \
735 firstVal = GET_REGISTER(vsrc1); \
736 if ((s1) vsrc2 == 0) { \
737 EXPORT_PC(); \
738 dvmThrowArithmeticException("divide by zero"); \
739 GOTO_exceptionThrown(); \
740 } \
741 if ((u4)firstVal == 0x80000000 && ((s1) vsrc2) == -1) { \
742 if (_chkdiv == 1) \
743 result = firstVal; /* division */ \
744 else \
745 result = 0; /* remainder */ \
746 } else { \
747 result = firstVal _op ((s1) vsrc2); \
748 } \
749 SET_REGISTER(vdst, result); \
750 } else { \
751 SET_REGISTER(vdst, \
752 (s4) GET_REGISTER(vsrc1) _op (s1) vsrc2); \
753 } \
754 } \
755 FINISH(2);
756
757#define HANDLE_OP_SHX_INT_LIT8(_opcode, _opname, _cast, _op) \
758 HANDLE_OPCODE(_opcode /*vAA, vBB, #+CC*/) \
759 { \
760 u2 litInfo; \
761 vdst = INST_AA(inst); \
762 litInfo = FETCH(1); \
763 vsrc1 = litInfo & 0xff; \
764 vsrc2 = litInfo >> 8; /* constant */ \
765 ILOGV("|%s-int/lit8 v%d,v%d,#+0x%02x", \
766 (_opname), vdst, vsrc1, vsrc2); \
767 SET_REGISTER(vdst, \
768 _cast GET_REGISTER(vsrc1) _op (vsrc2 & 0x1f)); \
769 } \
770 FINISH(2);
771
772#define HANDLE_OP_X_INT_2ADDR(_opcode, _opname, _op, _chkdiv) \
773 HANDLE_OPCODE(_opcode /*vA, vB*/) \
774 vdst = INST_A(inst); \
775 vsrc1 = INST_B(inst); \
776 ILOGV("|%s-int-2addr v%d,v%d", (_opname), vdst, vsrc1); \
777 if (_chkdiv != 0) { \
778 s4 firstVal, secondVal, result; \
779 firstVal = GET_REGISTER(vdst); \
780 secondVal = GET_REGISTER(vsrc1); \
781 if (secondVal == 0) { \
782 EXPORT_PC(); \
783 dvmThrowArithmeticException("divide by zero"); \
784 GOTO_exceptionThrown(); \
785 } \
786 if ((u4)firstVal == 0x80000000 && secondVal == -1) { \
787 if (_chkdiv == 1) \
788 result = firstVal; /* division */ \
789 else \
790 result = 0; /* remainder */ \
791 } else { \
792 result = firstVal _op secondVal; \
793 } \
794 SET_REGISTER(vdst, result); \
795 } else { \
796 SET_REGISTER(vdst, \
797 (s4) GET_REGISTER(vdst) _op (s4) GET_REGISTER(vsrc1)); \
798 } \
799 FINISH(1);
800
801#define HANDLE_OP_SHX_INT_2ADDR(_opcode, _opname, _cast, _op) \
802 HANDLE_OPCODE(_opcode /*vA, vB*/) \
803 vdst = INST_A(inst); \
804 vsrc1 = INST_B(inst); \
805 ILOGV("|%s-int-2addr v%d,v%d", (_opname), vdst, vsrc1); \
806 SET_REGISTER(vdst, \
807 _cast GET_REGISTER(vdst) _op (GET_REGISTER(vsrc1) & 0x1f)); \
808 FINISH(1);
809
810#define HANDLE_OP_X_LONG(_opcode, _opname, _op, _chkdiv) \
811 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
812 { \
813 u2 srcRegs; \
814 vdst = INST_AA(inst); \
815 srcRegs = FETCH(1); \
816 vsrc1 = srcRegs & 0xff; \
817 vsrc2 = srcRegs >> 8; \
818 ILOGV("|%s-long v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
819 if (_chkdiv != 0) { \
820 s8 firstVal, secondVal, result; \
821 firstVal = GET_REGISTER_WIDE(vsrc1); \
822 secondVal = GET_REGISTER_WIDE(vsrc2); \
823 if (secondVal == 0LL) { \
824 EXPORT_PC(); \
825 dvmThrowArithmeticException("divide by zero"); \
826 GOTO_exceptionThrown(); \
827 } \
828 if ((u8)firstVal == 0x8000000000000000ULL && \
829 secondVal == -1LL) \
830 { \
831 if (_chkdiv == 1) \
832 result = firstVal; /* division */ \
833 else \
834 result = 0; /* remainder */ \
835 } else { \
836 result = firstVal _op secondVal; \
837 } \
838 SET_REGISTER_WIDE(vdst, result); \
839 } else { \
840 SET_REGISTER_WIDE(vdst, \
841 (s8) GET_REGISTER_WIDE(vsrc1) _op (s8) GET_REGISTER_WIDE(vsrc2)); \
842 } \
843 } \
844 FINISH(2);
845
846#define HANDLE_OP_SHX_LONG(_opcode, _opname, _cast, _op) \
847 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
848 { \
849 u2 srcRegs; \
850 vdst = INST_AA(inst); \
851 srcRegs = FETCH(1); \
852 vsrc1 = srcRegs & 0xff; \
853 vsrc2 = srcRegs >> 8; \
854 ILOGV("|%s-long v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
855 SET_REGISTER_WIDE(vdst, \
856 _cast GET_REGISTER_WIDE(vsrc1) _op (GET_REGISTER(vsrc2) & 0x3f)); \
857 } \
858 FINISH(2);
859
860#define HANDLE_OP_X_LONG_2ADDR(_opcode, _opname, _op, _chkdiv) \
861 HANDLE_OPCODE(_opcode /*vA, vB*/) \
862 vdst = INST_A(inst); \
863 vsrc1 = INST_B(inst); \
864 ILOGV("|%s-long-2addr v%d,v%d", (_opname), vdst, vsrc1); \
865 if (_chkdiv != 0) { \
866 s8 firstVal, secondVal, result; \
867 firstVal = GET_REGISTER_WIDE(vdst); \
868 secondVal = GET_REGISTER_WIDE(vsrc1); \
869 if (secondVal == 0LL) { \
870 EXPORT_PC(); \
871 dvmThrowArithmeticException("divide by zero"); \
872 GOTO_exceptionThrown(); \
873 } \
874 if ((u8)firstVal == 0x8000000000000000ULL && \
875 secondVal == -1LL) \
876 { \
877 if (_chkdiv == 1) \
878 result = firstVal; /* division */ \
879 else \
880 result = 0; /* remainder */ \
881 } else { \
882 result = firstVal _op secondVal; \
883 } \
884 SET_REGISTER_WIDE(vdst, result); \
885 } else { \
886 SET_REGISTER_WIDE(vdst, \
887 (s8) GET_REGISTER_WIDE(vdst) _op (s8)GET_REGISTER_WIDE(vsrc1));\
888 } \
889 FINISH(1);
890
891#define HANDLE_OP_SHX_LONG_2ADDR(_opcode, _opname, _cast, _op) \
892 HANDLE_OPCODE(_opcode /*vA, vB*/) \
893 vdst = INST_A(inst); \
894 vsrc1 = INST_B(inst); \
895 ILOGV("|%s-long-2addr v%d,v%d", (_opname), vdst, vsrc1); \
896 SET_REGISTER_WIDE(vdst, \
897 _cast GET_REGISTER_WIDE(vdst) _op (GET_REGISTER(vsrc1) & 0x3f)); \
898 FINISH(1);
899
900#define HANDLE_OP_X_FLOAT(_opcode, _opname, _op) \
901 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
902 { \
903 u2 srcRegs; \
904 vdst = INST_AA(inst); \
905 srcRegs = FETCH(1); \
906 vsrc1 = srcRegs & 0xff; \
907 vsrc2 = srcRegs >> 8; \
908 ILOGV("|%s-float v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
909 SET_REGISTER_FLOAT(vdst, \
910 GET_REGISTER_FLOAT(vsrc1) _op GET_REGISTER_FLOAT(vsrc2)); \
911 } \
912 FINISH(2);
913
914#define HANDLE_OP_X_DOUBLE(_opcode, _opname, _op) \
915 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
916 { \
917 u2 srcRegs; \
918 vdst = INST_AA(inst); \
919 srcRegs = FETCH(1); \
920 vsrc1 = srcRegs & 0xff; \
921 vsrc2 = srcRegs >> 8; \
922 ILOGV("|%s-double v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
923 SET_REGISTER_DOUBLE(vdst, \
924 GET_REGISTER_DOUBLE(vsrc1) _op GET_REGISTER_DOUBLE(vsrc2)); \
925 } \
926 FINISH(2);
927
928#define HANDLE_OP_X_FLOAT_2ADDR(_opcode, _opname, _op) \
929 HANDLE_OPCODE(_opcode /*vA, vB*/) \
930 vdst = INST_A(inst); \
931 vsrc1 = INST_B(inst); \
932 ILOGV("|%s-float-2addr v%d,v%d", (_opname), vdst, vsrc1); \
933 SET_REGISTER_FLOAT(vdst, \
934 GET_REGISTER_FLOAT(vdst) _op GET_REGISTER_FLOAT(vsrc1)); \
935 FINISH(1);
936
937#define HANDLE_OP_X_DOUBLE_2ADDR(_opcode, _opname, _op) \
938 HANDLE_OPCODE(_opcode /*vA, vB*/) \
939 vdst = INST_A(inst); \
940 vsrc1 = INST_B(inst); \
941 ILOGV("|%s-double-2addr v%d,v%d", (_opname), vdst, vsrc1); \
942 SET_REGISTER_DOUBLE(vdst, \
943 GET_REGISTER_DOUBLE(vdst) _op GET_REGISTER_DOUBLE(vsrc1)); \
944 FINISH(1);
945
946#define HANDLE_OP_AGET(_opcode, _opname, _type, _regsize) \
947 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
948 { \
949 ArrayObject* arrayObj; \
950 u2 arrayInfo; \
951 EXPORT_PC(); \
952 vdst = INST_AA(inst); \
953 arrayInfo = FETCH(1); \
954 vsrc1 = arrayInfo & 0xff; /* array ptr */ \
955 vsrc2 = arrayInfo >> 8; /* index */ \
956 ILOGV("|aget%s v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
957 arrayObj = (ArrayObject*) GET_REGISTER(vsrc1); \
958 if (!checkForNull((Object*) arrayObj)) \
959 GOTO_exceptionThrown(); \
960 if (GET_REGISTER(vsrc2) >= arrayObj->length) { \
961 dvmThrowArrayIndexOutOfBoundsException( \
962 arrayObj->length, GET_REGISTER(vsrc2)); \
963 GOTO_exceptionThrown(); \
964 } \
965 SET_REGISTER##_regsize(vdst, \
966 ((_type*)(void*)arrayObj->contents)[GET_REGISTER(vsrc2)]); \
967 ILOGV("+ AGET[%d]=0x%x", GET_REGISTER(vsrc2), GET_REGISTER(vdst)); \
968 } \
969 FINISH(2);
970
971#define HANDLE_OP_APUT(_opcode, _opname, _type, _regsize) \
972 HANDLE_OPCODE(_opcode /*vAA, vBB, vCC*/) \
973 { \
974 ArrayObject* arrayObj; \
975 u2 arrayInfo; \
976 EXPORT_PC(); \
977 vdst = INST_AA(inst); /* AA: source value */ \
978 arrayInfo = FETCH(1); \
979 vsrc1 = arrayInfo & 0xff; /* BB: array ptr */ \
980 vsrc2 = arrayInfo >> 8; /* CC: index */ \
981 ILOGV("|aput%s v%d,v%d,v%d", (_opname), vdst, vsrc1, vsrc2); \
982 arrayObj = (ArrayObject*) GET_REGISTER(vsrc1); \
983 if (!checkForNull((Object*) arrayObj)) \
984 GOTO_exceptionThrown(); \
985 if (GET_REGISTER(vsrc2) >= arrayObj->length) { \
986 dvmThrowArrayIndexOutOfBoundsException( \
987 arrayObj->length, GET_REGISTER(vsrc2)); \
988 GOTO_exceptionThrown(); \
989 } \
990 ILOGV("+ APUT[%d]=0x%08x", GET_REGISTER(vsrc2), GET_REGISTER(vdst));\
991 ((_type*)(void*)arrayObj->contents)[GET_REGISTER(vsrc2)] = \
992 GET_REGISTER##_regsize(vdst); \
993 } \
994 FINISH(2);
995
996/*
997 * It's possible to get a bad value out of a field with sub-32-bit stores
998 * because the -quick versions always operate on 32 bits. Consider:
999 * short foo = -1 (sets a 32-bit register to 0xffffffff)
1000 * iput-quick foo (writes all 32 bits to the field)
1001 * short bar = 1 (sets a 32-bit register to 0x00000001)
1002 * iput-short (writes the low 16 bits to the field)
1003 * iget-quick foo (reads all 32 bits from the field, yielding 0xffff0001)
1004 * This can only happen when optimized and non-optimized code has interleaved
1005 * access to the same field. This is unlikely but possible.
1006 *
1007 * The easiest way to fix this is to always read/write 32 bits at a time. On
1008 * a device with a 16-bit data bus this is sub-optimal. (The alternative
1009 * approach is to have sub-int versions of iget-quick, but now we're wasting
1010 * Dalvik instruction space and making it less likely that handler code will
1011 * already be in the CPU i-cache.)
1012 */
1013#define HANDLE_IGET_X(_opcode, _opname, _ftype, _regsize) \
1014 HANDLE_OPCODE(_opcode /*vA, vB, field@CCCC*/) \
1015 { \
1016 InstField* ifield; \
1017 Object* obj; \
1018 EXPORT_PC(); \
1019 vdst = INST_A(inst); \
1020 vsrc1 = INST_B(inst); /* object ptr */ \
1021 ref = FETCH(1); /* field ref */ \
1022 ILOGV("|iget%s v%d,v%d,field@0x%04x", (_opname), vdst, vsrc1, ref); \
1023 obj = (Object*) GET_REGISTER(vsrc1); \
1024 if (!checkForNull(obj)) \
1025 GOTO_exceptionThrown(); \
1026 ifield = (InstField*) dvmDexGetResolvedField(methodClassDex, ref); \
1027 if (ifield == NULL) { \
1028 ifield = dvmResolveInstField(curMethod->clazz, ref); \
1029 if (ifield == NULL) \
1030 GOTO_exceptionThrown(); \
1031 } \
1032 SET_REGISTER##_regsize(vdst, \
1033 dvmGetField##_ftype(obj, ifield->byteOffset)); \
1034 ILOGV("+ IGET '%s'=0x%08llx", ifield->field.name, \
1035 (u8) GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1036 } \
1037 FINISH(2);
1038
1039#define HANDLE_IGET_X_JUMBO(_opcode, _opname, _ftype, _regsize) \
1040 HANDLE_OPCODE(_opcode /*vBBBB, vCCCC, class@AAAAAAAA*/) \
1041 { \
1042 InstField* ifield; \
1043 Object* obj; \
1044 EXPORT_PC(); \
1045 ref = FETCH(1) | (u4)FETCH(2) << 16; /* field ref */ \
1046 vdst = FETCH(3); \
1047 vsrc1 = FETCH(4); /* object ptr */ \
1048 ILOGV("|iget%s/jumbo v%d,v%d,field@0x%08x", \
1049 (_opname), vdst, vsrc1, ref); \
1050 obj = (Object*) GET_REGISTER(vsrc1); \
1051 if (!checkForNull(obj)) \
1052 GOTO_exceptionThrown(); \
1053 ifield = (InstField*) dvmDexGetResolvedField(methodClassDex, ref); \
1054 if (ifield == NULL) { \
1055 ifield = dvmResolveInstField(curMethod->clazz, ref); \
1056 if (ifield == NULL) \
1057 GOTO_exceptionThrown(); \
1058 } \
1059 SET_REGISTER##_regsize(vdst, \
1060 dvmGetField##_ftype(obj, ifield->byteOffset)); \
1061 ILOGV("+ IGET '%s'=0x%08llx", ifield->field.name, \
1062 (u8) GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1063 } \
1064 FINISH(5);
1065
1066#define HANDLE_IGET_X_QUICK(_opcode, _opname, _ftype, _regsize) \
1067 HANDLE_OPCODE(_opcode /*vA, vB, field@CCCC*/) \
1068 { \
1069 Object* obj; \
1070 vdst = INST_A(inst); \
1071 vsrc1 = INST_B(inst); /* object ptr */ \
1072 ref = FETCH(1); /* field offset */ \
1073 ILOGV("|iget%s-quick v%d,v%d,field@+%u", \
1074 (_opname), vdst, vsrc1, ref); \
1075 obj = (Object*) GET_REGISTER(vsrc1); \
1076 if (!checkForNullExportPC(obj, fp, pc)) \
1077 GOTO_exceptionThrown(); \
1078 SET_REGISTER##_regsize(vdst, dvmGetField##_ftype(obj, ref)); \
1079 ILOGV("+ IGETQ %d=0x%08llx", ref, \
1080 (u8) GET_REGISTER##_regsize(vdst)); \
1081 } \
1082 FINISH(2);
1083
1084#define HANDLE_IPUT_X(_opcode, _opname, _ftype, _regsize) \
1085 HANDLE_OPCODE(_opcode /*vA, vB, field@CCCC*/) \
1086 { \
1087 InstField* ifield; \
1088 Object* obj; \
1089 EXPORT_PC(); \
1090 vdst = INST_A(inst); \
1091 vsrc1 = INST_B(inst); /* object ptr */ \
1092 ref = FETCH(1); /* field ref */ \
1093 ILOGV("|iput%s v%d,v%d,field@0x%04x", (_opname), vdst, vsrc1, ref); \
1094 obj = (Object*) GET_REGISTER(vsrc1); \
1095 if (!checkForNull(obj)) \
1096 GOTO_exceptionThrown(); \
1097 ifield = (InstField*) dvmDexGetResolvedField(methodClassDex, ref); \
1098 if (ifield == NULL) { \
1099 ifield = dvmResolveInstField(curMethod->clazz, ref); \
1100 if (ifield == NULL) \
1101 GOTO_exceptionThrown(); \
1102 } \
1103 dvmSetField##_ftype(obj, ifield->byteOffset, \
1104 GET_REGISTER##_regsize(vdst)); \
1105 ILOGV("+ IPUT '%s'=0x%08llx", ifield->field.name, \
1106 (u8) GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1107 } \
1108 FINISH(2);
1109
1110#define HANDLE_IPUT_X_JUMBO(_opcode, _opname, _ftype, _regsize) \
1111 HANDLE_OPCODE(_opcode /*vBBBB, vCCCC, class@AAAAAAAA*/) \
1112 { \
1113 InstField* ifield; \
1114 Object* obj; \
1115 EXPORT_PC(); \
1116 ref = FETCH(1) | (u4)FETCH(2) << 16; /* field ref */ \
1117 vdst = FETCH(3); \
1118 vsrc1 = FETCH(4); /* object ptr */ \
1119 ILOGV("|iput%s/jumbo v%d,v%d,field@0x%08x", \
1120 (_opname), vdst, vsrc1, ref); \
1121 obj = (Object*) GET_REGISTER(vsrc1); \
1122 if (!checkForNull(obj)) \
1123 GOTO_exceptionThrown(); \
1124 ifield = (InstField*) dvmDexGetResolvedField(methodClassDex, ref); \
1125 if (ifield == NULL) { \
1126 ifield = dvmResolveInstField(curMethod->clazz, ref); \
1127 if (ifield == NULL) \
1128 GOTO_exceptionThrown(); \
1129 } \
1130 dvmSetField##_ftype(obj, ifield->byteOffset, \
1131 GET_REGISTER##_regsize(vdst)); \
1132 ILOGV("+ IPUT '%s'=0x%08llx", ifield->field.name, \
1133 (u8) GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1134 } \
1135 FINISH(5);
1136
1137#define HANDLE_IPUT_X_QUICK(_opcode, _opname, _ftype, _regsize) \
1138 HANDLE_OPCODE(_opcode /*vA, vB, field@CCCC*/) \
1139 { \
1140 Object* obj; \
1141 vdst = INST_A(inst); \
1142 vsrc1 = INST_B(inst); /* object ptr */ \
1143 ref = FETCH(1); /* field offset */ \
1144 ILOGV("|iput%s-quick v%d,v%d,field@0x%04x", \
1145 (_opname), vdst, vsrc1, ref); \
1146 obj = (Object*) GET_REGISTER(vsrc1); \
1147 if (!checkForNullExportPC(obj, fp, pc)) \
1148 GOTO_exceptionThrown(); \
1149 dvmSetField##_ftype(obj, ref, GET_REGISTER##_regsize(vdst)); \
1150 ILOGV("+ IPUTQ %d=0x%08llx", ref, \
1151 (u8) GET_REGISTER##_regsize(vdst)); \
1152 } \
1153 FINISH(2);
1154
1155/*
1156 * The JIT needs dvmDexGetResolvedField() to return non-null.
1157 * Because the portable interpreter is not involved with the JIT
1158 * and trace building, we only need the extra check here when this
1159 * code is massaged into a stub called from an assembly interpreter.
1160 * This is controlled by the JIT_STUB_HACK maco.
1161 */
1162
1163#define HANDLE_SGET_X(_opcode, _opname, _ftype, _regsize) \
1164 HANDLE_OPCODE(_opcode /*vAA, field@BBBB*/) \
1165 { \
1166 StaticField* sfield; \
1167 vdst = INST_AA(inst); \
1168 ref = FETCH(1); /* field ref */ \
1169 ILOGV("|sget%s v%d,sfield@0x%04x", (_opname), vdst, ref); \
1170 sfield = (StaticField*)dvmDexGetResolvedField(methodClassDex, ref); \
1171 if (sfield == NULL) { \
1172 EXPORT_PC(); \
1173 sfield = dvmResolveStaticField(curMethod->clazz, ref); \
1174 if (sfield == NULL) \
1175 GOTO_exceptionThrown(); \
1176 if (dvmDexGetResolvedField(methodClassDex, ref) == NULL) { \
1177 JIT_STUB_HACK(dvmJitEndTraceSelect(self,pc)); \
1178 } \
1179 } \
1180 SET_REGISTER##_regsize(vdst, dvmGetStaticField##_ftype(sfield)); \
1181 ILOGV("+ SGET '%s'=0x%08llx", \
1182 sfield->field.name, (u8)GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1183 } \
1184 FINISH(2);
1185
1186#define HANDLE_SGET_X_JUMBO(_opcode, _opname, _ftype, _regsize) \
1187 HANDLE_OPCODE(_opcode /*vBBBB, class@AAAAAAAA*/) \
1188 { \
1189 StaticField* sfield; \
1190 ref = FETCH(1) | (u4)FETCH(2) << 16; /* field ref */ \
1191 vdst = FETCH(3); \
1192 ILOGV("|sget%s/jumbo v%d,sfield@0x%08x", (_opname), vdst, ref); \
1193 sfield = (StaticField*)dvmDexGetResolvedField(methodClassDex, ref); \
1194 if (sfield == NULL) { \
1195 EXPORT_PC(); \
1196 sfield = dvmResolveStaticField(curMethod->clazz, ref); \
1197 if (sfield == NULL) \
1198 GOTO_exceptionThrown(); \
1199 if (dvmDexGetResolvedField(methodClassDex, ref) == NULL) { \
1200 JIT_STUB_HACK(dvmJitEndTraceSelect(self,pc)); \
1201 } \
1202 } \
1203 SET_REGISTER##_regsize(vdst, dvmGetStaticField##_ftype(sfield)); \
1204 ILOGV("+ SGET '%s'=0x%08llx", \
1205 sfield->field.name, (u8)GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1206 } \
1207 FINISH(4);
1208
1209#define HANDLE_SPUT_X(_opcode, _opname, _ftype, _regsize) \
1210 HANDLE_OPCODE(_opcode /*vAA, field@BBBB*/) \
1211 { \
1212 StaticField* sfield; \
1213 vdst = INST_AA(inst); \
1214 ref = FETCH(1); /* field ref */ \
1215 ILOGV("|sput%s v%d,sfield@0x%04x", (_opname), vdst, ref); \
1216 sfield = (StaticField*)dvmDexGetResolvedField(methodClassDex, ref); \
1217 if (sfield == NULL) { \
1218 EXPORT_PC(); \
1219 sfield = dvmResolveStaticField(curMethod->clazz, ref); \
1220 if (sfield == NULL) \
1221 GOTO_exceptionThrown(); \
1222 if (dvmDexGetResolvedField(methodClassDex, ref) == NULL) { \
1223 JIT_STUB_HACK(dvmJitEndTraceSelect(self,pc)); \
1224 } \
1225 } \
1226 dvmSetStaticField##_ftype(sfield, GET_REGISTER##_regsize(vdst)); \
1227 ILOGV("+ SPUT '%s'=0x%08llx", \
1228 sfield->field.name, (u8)GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1229 } \
1230 FINISH(2);
1231
1232#define HANDLE_SPUT_X_JUMBO(_opcode, _opname, _ftype, _regsize) \
1233 HANDLE_OPCODE(_opcode /*vBBBB, class@AAAAAAAA*/) \
1234 { \
1235 StaticField* sfield; \
1236 ref = FETCH(1) | (u4)FETCH(2) << 16; /* field ref */ \
1237 vdst = FETCH(3); \
1238 ILOGV("|sput%s/jumbo v%d,sfield@0x%08x", (_opname), vdst, ref); \
1239 sfield = (StaticField*)dvmDexGetResolvedField(methodClassDex, ref); \
1240 if (sfield == NULL) { \
1241 EXPORT_PC(); \
1242 sfield = dvmResolveStaticField(curMethod->clazz, ref); \
1243 if (sfield == NULL) \
1244 GOTO_exceptionThrown(); \
1245 if (dvmDexGetResolvedField(methodClassDex, ref) == NULL) { \
1246 JIT_STUB_HACK(dvmJitEndTraceSelect(self,pc)); \
1247 } \
1248 } \
1249 dvmSetStaticField##_ftype(sfield, GET_REGISTER##_regsize(vdst)); \
1250 ILOGV("+ SPUT '%s'=0x%08llx", \
1251 sfield->field.name, (u8)GET_REGISTER##_regsize(vdst)); \
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]1252 } \
1253 FINISH(4);
1254
1255/* File: c/OP_IGET_WIDE_VOLATILE.cpp */
1256HANDLE_IGET_X(OP_IGET_WIDE_VOLATILE, "-wide-volatile", LongVolatile, _WIDE)
1257OP_END
1258
1259/* File: c/OP_IPUT_WIDE_VOLATILE.cpp */
1260HANDLE_IPUT_X(OP_IPUT_WIDE_VOLATILE, "-wide-volatile", LongVolatile, _WIDE)
1261OP_END
1262
1263/* File: c/OP_SGET_WIDE_VOLATILE.cpp */
1264HANDLE_SGET_X(OP_SGET_WIDE_VOLATILE, "-wide-volatile", LongVolatile, _WIDE)
1265OP_END
1266
1267/* File: c/OP_SPUT_WIDE_VOLATILE.cpp */
1268HANDLE_SPUT_X(OP_SPUT_WIDE_VOLATILE, "-wide-volatile", LongVolatile, _WIDE)
1269OP_END
1270
1271/* File: c/OP_EXECUTE_INLINE_RANGE.cpp */
1272HANDLE_OPCODE(OP_EXECUTE_INLINE_RANGE /*{vCCCC..v(CCCC+AA-1)}, inline@BBBB*/)
1273 {
1274 u4 arg0, arg1, arg2, arg3;
1275 arg0 = arg1 = arg2 = arg3 = 0; /* placate gcc */
1276
1277 EXPORT_PC();
1278
1279 vsrc1 = INST_AA(inst); /* #of args */
1280 ref = FETCH(1); /* inline call "ref" */
1281 vdst = FETCH(2); /* range base */
1282 ILOGV("|execute-inline-range args=%d @%d {regs=v%d-v%d}",
1283 vsrc1, ref, vdst, vdst+vsrc1-1);
1284
1285 assert((vdst >> 16) == 0); // 16-bit type -or- high 16 bits clear
1286 assert(vsrc1 <= 4);
1287
1288 switch (vsrc1) {
1289 case 4:
1290 arg3 = GET_REGISTER(vdst+3);
1291 /* fall through */
1292 case 3:
1293 arg2 = GET_REGISTER(vdst+2);
1294 /* fall through */
1295 case 2:
1296 arg1 = GET_REGISTER(vdst+1);
1297 /* fall through */
1298 case 1:
1299 arg0 = GET_REGISTER(vdst+0);
1300 /* fall through */
1301 default: // case 0
1302 ;
1303 }
1304
1305 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
1306 if (!dvmPerformInlineOp4Dbg(arg0, arg1, arg2, arg3, &retval, ref))
1307 GOTO_exceptionThrown();
1308 } else {
1309 if (!dvmPerformInlineOp4Std(arg0, arg1, arg2, arg3, &retval, ref))
1310 GOTO_exceptionThrown();
1311 }
1312 }
1313 FINISH(3);
1314OP_END
1315
1316/* File: c/OP_INVOKE_OBJECT_INIT_RANGE.cpp */
1317HANDLE_OPCODE(OP_INVOKE_OBJECT_INIT_RANGE /*{vCCCC..v(CCCC+AA-1)}, meth@BBBB*/)
1318 {
1319 Object* obj;
1320
1321 vsrc1 = FETCH(2); /* reg number of "this" pointer */
1322 obj = GET_REGISTER_AS_OBJECT(vsrc1);
1323
1324 if (!checkForNullExportPC(obj, fp, pc))
1325 GOTO_exceptionThrown();
1326
1327 /*
1328 * The object should be marked "finalizable" when Object.<init>
1329 * completes normally. We're going to assume it does complete
1330 * (by virtue of being nothing but a return-void) and set it now.
1331 */
1332 if (IS_CLASS_FLAG_SET(obj->clazz, CLASS_ISFINALIZABLE)) {
1333 EXPORT_PC();
1334 dvmSetFinalizable(obj);
1335 if (dvmGetException(self))
1336 GOTO_exceptionThrown();
1337 }
1338
1339 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
1340 /* behave like OP_INVOKE_DIRECT_RANGE */
1341 GOTO_invoke(invokeDirect, true, false);
1342 }
1343 FINISH(3);
1344 }
1345OP_END
1346
1347/* File: c/OP_RETURN_VOID_BARRIER.cpp */
1348HANDLE_OPCODE(OP_RETURN_VOID_BARRIER /**/)
1349 ILOGV("|return-void");
1350#ifndef NDEBUG
1351 retval.j = 0xababababULL; /* placate valgrind */
1352#endif
1353 ANDROID_MEMBAR_STORE();
1354 GOTO_returnFromMethod();
1355OP_END
1356
1357/* File: c/OP_INVOKE_OBJECT_INIT_JUMBO.cpp */
1358HANDLE_OPCODE(OP_INVOKE_OBJECT_INIT_JUMBO /*{vCCCC..vNNNN}, meth@AAAAAAAA*/)
1359 {
1360 Object* obj;
1361
1362 vsrc1 = FETCH(4); /* reg number of "this" pointer */
1363 obj = GET_REGISTER_AS_OBJECT(vsrc1);
1364
1365 if (!checkForNullExportPC(obj, fp, pc))
1366 GOTO_exceptionThrown();
1367
1368 /*
1369 * The object should be marked "finalizable" when Object.<init>
1370 * completes normally. We're going to assume it does complete
1371 * (by virtue of being nothing but a return-void) and set it now.
1372 */
1373 if (IS_CLASS_FLAG_SET(obj->clazz, CLASS_ISFINALIZABLE)) {
1374 EXPORT_PC();
1375 dvmSetFinalizable(obj);
1376 if (dvmGetException(self))
1377 GOTO_exceptionThrown();
1378 }
1379
1380 if (self->interpBreak.ctl.subMode & kSubModeDebuggerActive) {
1381 /* behave like OP_INVOKE_DIRECT_RANGE */
1382 GOTO_invoke(invokeDirect, true, true);
1383 }
1384 FINISH(5);
1385 }
1386OP_END
1387
1388/* File: c/OP_IGET_VOLATILE_JUMBO.cpp */
1389HANDLE_IGET_X_JUMBO(OP_IGET_VOLATILE_JUMBO, "-volatile/jumbo", IntVolatile, )
1390OP_END
1391
1392/* File: c/OP_IGET_WIDE_VOLATILE_JUMBO.cpp */
1393HANDLE_IGET_X_JUMBO(OP_IGET_WIDE_VOLATILE_JUMBO, "-wide-volatile/jumbo", LongVolatile, _WIDE)
1394OP_END
1395
1396/* File: c/OP_IGET_OBJECT_VOLATILE_JUMBO.cpp */
1397HANDLE_IGET_X_JUMBO(OP_IGET_OBJECT_VOLATILE_JUMBO, "-object-volatile/jumbo", ObjectVolatile, _AS_OBJECT)
1398OP_END
1399
1400/* File: c/OP_IPUT_VOLATILE_JUMBO.cpp */
1401HANDLE_IPUT_X_JUMBO(OP_IPUT_VOLATILE_JUMBO, "-volatile/jumbo", IntVolatile, )
1402OP_END
1403
1404/* File: c/OP_IPUT_WIDE_VOLATILE_JUMBO.cpp */
1405HANDLE_IPUT_X_JUMBO(OP_IPUT_WIDE_VOLATILE_JUMBO, "-wide-volatile/jumbo", LongVolatile, _WIDE)
1406OP_END
1407
1408/* File: c/OP_IPUT_OBJECT_VOLATILE_JUMBO.cpp */
1409HANDLE_IPUT_X_JUMBO(OP_IPUT_OBJECT_VOLATILE_JUMBO, "-object-volatile/jumbo", ObjectVolatile, _AS_OBJECT)
1410OP_END
1411
1412/* File: c/OP_SGET_VOLATILE_JUMBO.cpp */
1413HANDLE_SGET_X_JUMBO(OP_SGET_VOLATILE_JUMBO, "-volatile/jumbo", IntVolatile, )
1414OP_END
1415
1416/* File: c/OP_SGET_WIDE_VOLATILE_JUMBO.cpp */
1417HANDLE_SGET_X_JUMBO(OP_SGET_WIDE_VOLATILE_JUMBO, "-wide-volatile/jumbo", LongVolatile, _WIDE)
1418OP_END
1419
1420/* File: c/OP_SGET_OBJECT_VOLATILE_JUMBO.cpp */
1421HANDLE_SGET_X_JUMBO(OP_SGET_OBJECT_VOLATILE_JUMBO, "-object-volatile/jumbo", ObjectVolatile, _AS_OBJECT)
1422OP_END
1423
1424/* File: c/OP_SPUT_VOLATILE_JUMBO.cpp */
1425HANDLE_SPUT_X_JUMBO(OP_SPUT_VOLATILE_JUMBO, "-volatile", IntVolatile, )
1426OP_END
1427
1428/* File: c/OP_SPUT_WIDE_VOLATILE_JUMBO.cpp */
1429HANDLE_SPUT_X_JUMBO(OP_SPUT_WIDE_VOLATILE_JUMBO, "-wide-volatile/jumbo", LongVolatile, _WIDE)
1430OP_END
1431
1432/* File: c/OP_SPUT_OBJECT_VOLATILE_JUMBO.cpp */
1433HANDLE_SPUT_X_JUMBO(OP_SPUT_OBJECT_VOLATILE_JUMBO, "-object-volatile/jumbo", ObjectVolatile, _AS_OBJECT)
1434OP_END
1435
1436/* File: c/gotoTargets.cpp */
1437/*
1438 * C footer. This has some common code shared by the various targets.
1439 */
1440
1441/*
1442 * Everything from here on is a "goto target". In the basic interpreter
1443 * we jump into these targets and then jump directly to the handler for
1444 * next instruction. Here, these are subroutines that return to the caller.
1445 */
1446
1447GOTO_TARGET(filledNewArray, bool methodCallRange, bool jumboFormat)
1448 {
1449 ClassObject* arrayClass;
1450 ArrayObject* newArray;
1451 u4* contents;
1452 char typeCh;
1453 int i;
1454 u4 arg5;
1455
1456 EXPORT_PC();
1457
1458 if (jumboFormat) {
1459 ref = FETCH(1) | (u4)FETCH(2) << 16; /* class ref */
1460 vsrc1 = FETCH(3); /* #of elements */
1461 vdst = FETCH(4); /* range base */
1462 arg5 = -1; /* silence compiler warning */
1463 ILOGV("|filled-new-array/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1464 vsrc1, ref, vdst, vdst+vsrc1-1);
1465 } else {
1466 ref = FETCH(1); /* class ref */
1467 vdst = FETCH(2); /* first 4 regs -or- range base */
1468
1469 if (methodCallRange) {
1470 vsrc1 = INST_AA(inst); /* #of elements */
1471 arg5 = -1; /* silence compiler warning */
1472 ILOGV("|filled-new-array-range args=%d @0x%04x {regs=v%d-v%d}",
1473 vsrc1, ref, vdst, vdst+vsrc1-1);
1474 } else {
1475 arg5 = INST_A(inst);
1476 vsrc1 = INST_B(inst); /* #of elements */
1477 ILOGV("|filled-new-array args=%d @0x%04x {regs=0x%04x %x}",
1478 vsrc1, ref, vdst, arg5);
1479 }
1480 }
1481
1482 /*
1483 * Resolve the array class.
1484 */
1485 arrayClass = dvmDexGetResolvedClass(methodClassDex, ref);
1486 if (arrayClass == NULL) {
1487 arrayClass = dvmResolveClass(curMethod->clazz, ref, false);
1488 if (arrayClass == NULL)
1489 GOTO_exceptionThrown();
1490 }
1491 /*
1492 if (!dvmIsArrayClass(arrayClass)) {
1493 dvmThrowRuntimeException(
1494 "filled-new-array needs array class");
1495 GOTO_exceptionThrown();
1496 }
1497 */
1498 /* verifier guarantees this is an array class */
1499 assert(dvmIsArrayClass(arrayClass));
1500 assert(dvmIsClassInitialized(arrayClass));
1501
1502 /*
1503 * Create an array of the specified type.
1504 */
1505 LOGVV("+++ filled-new-array type is '%s'\n", arrayClass->descriptor);
1506 typeCh = arrayClass->descriptor[1];
1507 if (typeCh == 'D' || typeCh == 'J') {
1508 /* category 2 primitives not allowed */
1509 dvmThrowRuntimeException("bad filled array req");
1510 GOTO_exceptionThrown();
1511 } else if (typeCh != 'L' && typeCh != '[' && typeCh != 'I') {
1512 /* TODO: requires multiple "fill in" loops with different widths */
1513 LOGE("non-int primitives not implemented\n");
1514 dvmThrowInternalError(
1515 "filled-new-array not implemented for anything but 'int'");
1516 GOTO_exceptionThrown();
1517 }
1518
1519 newArray = dvmAllocArrayByClass(arrayClass, vsrc1, ALLOC_DONT_TRACK);
1520 if (newArray == NULL)
1521 GOTO_exceptionThrown();
1522
1523 /*
1524 * Fill in the elements. It's legal for vsrc1 to be zero.
1525 */
1526 contents = (u4*)(void*)newArray->contents;
1527 if (methodCallRange) {
1528 for (i = 0; i < vsrc1; i++)
1529 contents[i] = GET_REGISTER(vdst+i);
1530 } else {
1531 assert(vsrc1 <= 5);
1532 if (vsrc1 == 5) {
1533 contents[4] = GET_REGISTER(arg5);
1534 vsrc1--;
1535 }
1536 for (i = 0; i < vsrc1; i++) {
1537 contents[i] = GET_REGISTER(vdst & 0x0f);
1538 vdst >>= 4;
1539 }
1540 }
1541 if (typeCh == 'L' || typeCh == '[') {
1542 dvmWriteBarrierArray(newArray, 0, newArray->length);
1543 }
1544
1545 retval.l = newArray;
1546 }
1547 if (jumboFormat) {
1548 FINISH(5);
1549 } else {
1550 FINISH(3);
1551 }
1552GOTO_TARGET_END
1553
1554
1555GOTO_TARGET(invokeVirtual, bool methodCallRange, bool jumboFormat)
1556 {
1557 Method* baseMethod;
1558 Object* thisPtr;
1559
1560 EXPORT_PC();
1561
1562 if (jumboFormat) {
1563 ref = FETCH(1) | (u4)FETCH(2) << 16; /* method ref */
1564 vsrc1 = FETCH(3); /* count */
1565 vdst = FETCH(4); /* first reg */
1566 ADJUST_PC(2); /* advance pc partially to make returns easier */
1567 ILOGV("|invoke-virtual/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1568 vsrc1, ref, vdst, vdst+vsrc1-1);
1569 thisPtr = (Object*) GET_REGISTER(vdst);
1570 } else {
1571 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1572 ref = FETCH(1); /* method ref */
1573 vdst = FETCH(2); /* 4 regs -or- first reg */
1574
1575 /*
1576 * The object against which we are executing a method is always
1577 * in the first argument.
1578 */
1579 if (methodCallRange) {
1580 assert(vsrc1 > 0);
1581 ILOGV("|invoke-virtual-range args=%d @0x%04x {regs=v%d-v%d}",
1582 vsrc1, ref, vdst, vdst+vsrc1-1);
1583 thisPtr = (Object*) GET_REGISTER(vdst);
1584 } else {
1585 assert((vsrc1>>4) > 0);
1586 ILOGV("|invoke-virtual args=%d @0x%04x {regs=0x%04x %x}",
1587 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1588 thisPtr = (Object*) GET_REGISTER(vdst & 0x0f);
1589 }
1590 }
1591
1592 if (!checkForNull(thisPtr))
1593 GOTO_exceptionThrown();
1594
1595 /*
1596 * Resolve the method. This is the correct method for the static
1597 * type of the object. We also verify access permissions here.
1598 */
1599 baseMethod = dvmDexGetResolvedMethod(methodClassDex, ref);
1600 if (baseMethod == NULL) {
1601 baseMethod = dvmResolveMethod(curMethod->clazz, ref,METHOD_VIRTUAL);
1602 if (baseMethod == NULL) {
1603 ILOGV("+ unknown method or access denied\n");
1604 GOTO_exceptionThrown();
1605 }
1606 }
1607
1608 /*
1609 * Combine the object we found with the vtable offset in the
1610 * method.
1611 */
1612 assert(baseMethod->methodIndex < thisPtr->clazz->vtableCount);
1613 methodToCall = thisPtr->clazz->vtable[baseMethod->methodIndex];
1614
1615#if defined(WITH_JIT) && defined(MTERP_STUB)
1616 self->methodToCall = methodToCall;
1617 self->callsiteClass = thisPtr->clazz;
1618#endif
1619
1620#if 0
1621 if (dvmIsAbstractMethod(methodToCall)) {
1622 /*
1623 * This can happen if you create two classes, Base and Sub, where
1624 * Sub is a sub-class of Base. Declare a protected abstract
1625 * method foo() in Base, and invoke foo() from a method in Base.
1626 * Base is an "abstract base class" and is never instantiated
1627 * directly. Now, Override foo() in Sub, and use Sub. This
1628 * Works fine unless Sub stops providing an implementation of
1629 * the method.
1630 */
1631 dvmThrowAbstractMethodError("abstract method not implemented");
1632 GOTO_exceptionThrown();
1633 }
1634#else
1635 assert(!dvmIsAbstractMethod(methodToCall) ||
1636 methodToCall->nativeFunc != NULL);
1637#endif
1638
1639 LOGVV("+++ base=%s.%s virtual[%d]=%s.%s\n",
1640 baseMethod->clazz->descriptor, baseMethod->name,
1641 (u4) baseMethod->methodIndex,
1642 methodToCall->clazz->descriptor, methodToCall->name);
1643 assert(methodToCall != NULL);
1644
1645#if 0
1646 if (vsrc1 != methodToCall->insSize) {
1647 LOGW("WRONG METHOD: base=%s.%s virtual[%d]=%s.%s\n",
1648 baseMethod->clazz->descriptor, baseMethod->name,
1649 (u4) baseMethod->methodIndex,
1650 methodToCall->clazz->descriptor, methodToCall->name);
1651 //dvmDumpClass(baseMethod->clazz);
1652 //dvmDumpClass(methodToCall->clazz);
1653 dvmDumpAllClasses(0);
1654 }
1655#endif
1656
1657 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1658 }
1659GOTO_TARGET_END
1660
1661GOTO_TARGET(invokeSuper, bool methodCallRange, bool jumboFormat)
1662 {
1663 Method* baseMethod;
1664 u2 thisReg;
1665
1666 EXPORT_PC();
1667
1668 if (jumboFormat) {
1669 ref = FETCH(1) | (u4)FETCH(2) << 16; /* method ref */
1670 vsrc1 = FETCH(3); /* count */
1671 vdst = FETCH(4); /* first reg */
1672 ADJUST_PC(2); /* advance pc partially to make returns easier */
1673 ILOGV("|invoke-super/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1674 vsrc1, ref, vdst, vdst+vsrc1-1);
1675 thisReg = vdst;
1676 } else {
1677 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1678 ref = FETCH(1); /* method ref */
1679 vdst = FETCH(2); /* 4 regs -or- first reg */
1680
1681 if (methodCallRange) {
1682 ILOGV("|invoke-super-range args=%d @0x%04x {regs=v%d-v%d}",
1683 vsrc1, ref, vdst, vdst+vsrc1-1);
1684 thisReg = vdst;
1685 } else {
1686 ILOGV("|invoke-super args=%d @0x%04x {regs=0x%04x %x}",
1687 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1688 thisReg = vdst & 0x0f;
1689 }
1690 }
1691
1692 /* impossible in well-formed code, but we must check nevertheless */
1693 if (!checkForNull((Object*) GET_REGISTER(thisReg)))
1694 GOTO_exceptionThrown();
1695
1696 /*
1697 * Resolve the method. This is the correct method for the static
1698 * type of the object. We also verify access permissions here.
1699 * The first arg to dvmResolveMethod() is just the referring class
1700 * (used for class loaders and such), so we don't want to pass
1701 * the superclass into the resolution call.
1702 */
1703 baseMethod = dvmDexGetResolvedMethod(methodClassDex, ref);
1704 if (baseMethod == NULL) {
1705 baseMethod = dvmResolveMethod(curMethod->clazz, ref,METHOD_VIRTUAL);
1706 if (baseMethod == NULL) {
1707 ILOGV("+ unknown method or access denied\n");
1708 GOTO_exceptionThrown();
1709 }
1710 }
1711
1712 /*
1713 * Combine the object we found with the vtable offset in the
1714 * method's class.
1715 *
1716 * We're using the current method's class' superclass, not the
1717 * superclass of "this". This is because we might be executing
1718 * in a method inherited from a superclass, and we want to run
1719 * in that class' superclass.
1720 */
1721 if (baseMethod->methodIndex >= curMethod->clazz->super->vtableCount) {
1722 /*
1723 * Method does not exist in the superclass. Could happen if
1724 * superclass gets updated.
1725 */
1726 dvmThrowNoSuchMethodError(baseMethod->name);
1727 GOTO_exceptionThrown();
1728 }
1729 methodToCall = curMethod->clazz->super->vtable[baseMethod->methodIndex];
1730
1731#if 0
1732 if (dvmIsAbstractMethod(methodToCall)) {
1733 dvmThrowAbstractMethodError("abstract method not implemented");
1734 GOTO_exceptionThrown();
1735 }
1736#else
1737 assert(!dvmIsAbstractMethod(methodToCall) ||
1738 methodToCall->nativeFunc != NULL);
1739#endif
1740 LOGVV("+++ base=%s.%s super-virtual=%s.%s\n",
1741 baseMethod->clazz->descriptor, baseMethod->name,
1742 methodToCall->clazz->descriptor, methodToCall->name);
1743 assert(methodToCall != NULL);
1744
1745 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1746 }
1747GOTO_TARGET_END
1748
1749GOTO_TARGET(invokeInterface, bool methodCallRange, bool jumboFormat)
1750 {
1751 Object* thisPtr;
1752 ClassObject* thisClass;
1753
1754 EXPORT_PC();
1755
1756 if (jumboFormat) {
1757 ref = FETCH(1) | (u4)FETCH(2) << 16; /* method ref */
1758 vsrc1 = FETCH(3); /* count */
1759 vdst = FETCH(4); /* first reg */
1760 ADJUST_PC(2); /* advance pc partially to make returns easier */
1761 ILOGV("|invoke-interface/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1762 vsrc1, ref, vdst, vdst+vsrc1-1);
1763 thisPtr = (Object*) GET_REGISTER(vdst);
1764 } else {
1765 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1766 ref = FETCH(1); /* method ref */
1767 vdst = FETCH(2); /* 4 regs -or- first reg */
1768
1769 /*
1770 * The object against which we are executing a method is always
1771 * in the first argument.
1772 */
1773 if (methodCallRange) {
1774 assert(vsrc1 > 0);
1775 ILOGV("|invoke-interface-range args=%d @0x%04x {regs=v%d-v%d}",
1776 vsrc1, ref, vdst, vdst+vsrc1-1);
1777 thisPtr = (Object*) GET_REGISTER(vdst);
1778 } else {
1779 assert((vsrc1>>4) > 0);
1780 ILOGV("|invoke-interface args=%d @0x%04x {regs=0x%04x %x}",
1781 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1782 thisPtr = (Object*) GET_REGISTER(vdst & 0x0f);
1783 }
1784 }
1785
1786 if (!checkForNull(thisPtr))
1787 GOTO_exceptionThrown();
1788
1789 thisClass = thisPtr->clazz;
1790
1791
1792 /*
1793 * Given a class and a method index, find the Method* with the
1794 * actual code we want to execute.
1795 */
1796 methodToCall = dvmFindInterfaceMethodInCache(thisClass, ref, curMethod,
1797 methodClassDex);
1798#if defined(WITH_JIT) && defined(MTERP_STUB)
1799 self->callsiteClass = thisClass;
1800 self->methodToCall = methodToCall;
1801#endif
1802 if (methodToCall == NULL) {
1803 assert(dvmCheckException(self));
1804 GOTO_exceptionThrown();
1805 }
1806
1807 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1808 }
1809GOTO_TARGET_END
1810
1811GOTO_TARGET(invokeDirect, bool methodCallRange, bool jumboFormat)
1812 {
1813 u2 thisReg;
1814
1815 EXPORT_PC();
1816
1817 if (jumboFormat) {
1818 ref = FETCH(1) | (u4)FETCH(2) << 16; /* method ref */
1819 vsrc1 = FETCH(3); /* count */
1820 vdst = FETCH(4); /* first reg */
1821 ADJUST_PC(2); /* advance pc partially to make returns easier */
1822 ILOGV("|invoke-direct/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1823 vsrc1, ref, vdst, vdst+vsrc1-1);
1824 thisReg = vdst;
1825 } else {
1826 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1827 ref = FETCH(1); /* method ref */
1828 vdst = FETCH(2); /* 4 regs -or- first reg */
1829
1830 if (methodCallRange) {
1831 ILOGV("|invoke-direct-range args=%d @0x%04x {regs=v%d-v%d}",
1832 vsrc1, ref, vdst, vdst+vsrc1-1);
1833 thisReg = vdst;
1834 } else {
1835 ILOGV("|invoke-direct args=%d @0x%04x {regs=0x%04x %x}",
1836 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1837 thisReg = vdst & 0x0f;
1838 }
1839 }
1840
1841 if (!checkForNull((Object*) GET_REGISTER(thisReg)))
1842 GOTO_exceptionThrown();
1843
1844 methodToCall = dvmDexGetResolvedMethod(methodClassDex, ref);
1845 if (methodToCall == NULL) {
1846 methodToCall = dvmResolveMethod(curMethod->clazz, ref,
1847 METHOD_DIRECT);
1848 if (methodToCall == NULL) {
1849 ILOGV("+ unknown direct method\n"); // should be impossible
1850 GOTO_exceptionThrown();
1851 }
1852 }
1853 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1854 }
1855GOTO_TARGET_END
1856
1857GOTO_TARGET(invokeStatic, bool methodCallRange, bool jumboFormat)
1858 EXPORT_PC();
1859
1860 if (jumboFormat) {
1861 ref = FETCH(1) | (u4)FETCH(2) << 16; /* method ref */
1862 vsrc1 = FETCH(3); /* count */
1863 vdst = FETCH(4); /* first reg */
1864 ADJUST_PC(2); /* advance pc partially to make returns easier */
1865 ILOGV("|invoke-static/jumbo args=%d @0x%08x {regs=v%d-v%d}",
1866 vsrc1, ref, vdst, vdst+vsrc1-1);
1867 } else {
1868 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1869 ref = FETCH(1); /* method ref */
1870 vdst = FETCH(2); /* 4 regs -or- first reg */
1871
1872 if (methodCallRange)
1873 ILOGV("|invoke-static-range args=%d @0x%04x {regs=v%d-v%d}",
1874 vsrc1, ref, vdst, vdst+vsrc1-1);
1875 else
1876 ILOGV("|invoke-static args=%d @0x%04x {regs=0x%04x %x}",
1877 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1878 }
1879
1880 methodToCall = dvmDexGetResolvedMethod(methodClassDex, ref);
1881 if (methodToCall == NULL) {
1882 methodToCall = dvmResolveMethod(curMethod->clazz, ref, METHOD_STATIC);
1883 if (methodToCall == NULL) {
1884 ILOGV("+ unknown method\n");
1885 GOTO_exceptionThrown();
1886 }
1887
1888#if defined(WITH_JIT) && defined(MTERP_STUB)
1889 /*
1890 * The JIT needs dvmDexGetResolvedMethod() to return non-null.
1891 * Include the check if this code is being used as a stub
1892 * called from the assembly interpreter.
1893 */
1894 if ((self->interpBreak.ctl.subMode & kSubModeJitTraceBuild) &&
1895 (dvmDexGetResolvedMethod(methodClassDex, ref) == NULL)) {
1896 /* Class initialization is still ongoing */
1897 dvmJitEndTraceSelect(self,pc);
1898 }
1899#endif
1900 }
1901 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1902GOTO_TARGET_END
1903
1904GOTO_TARGET(invokeVirtualQuick, bool methodCallRange, bool jumboFormat)
1905 {
1906 Object* thisPtr;
1907
1908 EXPORT_PC();
1909
1910 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1911 ref = FETCH(1); /* vtable index */
1912 vdst = FETCH(2); /* 4 regs -or- first reg */
1913
1914 /*
1915 * The object against which we are executing a method is always
1916 * in the first argument.
1917 */
1918 if (methodCallRange) {
1919 assert(vsrc1 > 0);
1920 ILOGV("|invoke-virtual-quick-range args=%d @0x%04x {regs=v%d-v%d}",
1921 vsrc1, ref, vdst, vdst+vsrc1-1);
1922 thisPtr = (Object*) GET_REGISTER(vdst);
1923 } else {
1924 assert((vsrc1>>4) > 0);
1925 ILOGV("|invoke-virtual-quick args=%d @0x%04x {regs=0x%04x %x}",
1926 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1927 thisPtr = (Object*) GET_REGISTER(vdst & 0x0f);
1928 }
1929
1930 if (!checkForNull(thisPtr))
1931 GOTO_exceptionThrown();
1932
1933
1934 /*
1935 * Combine the object we found with the vtable offset in the
1936 * method.
1937 */
1938 assert(ref < (unsigned int) thisPtr->clazz->vtableCount);
1939 methodToCall = thisPtr->clazz->vtable[ref];
1940#if defined(WITH_JIT) && defined(MTERP_STUB)
1941 self->callsiteClass = thisPtr->clazz;
1942 self->methodToCall = methodToCall;
1943#endif
1944
1945#if 0
1946 if (dvmIsAbstractMethod(methodToCall)) {
1947 dvmThrowAbstractMethodError("abstract method not implemented");
1948 GOTO_exceptionThrown();
1949 }
1950#else
1951 assert(!dvmIsAbstractMethod(methodToCall) ||
1952 methodToCall->nativeFunc != NULL);
1953#endif
1954
1955 LOGVV("+++ virtual[%d]=%s.%s\n",
1956 ref, methodToCall->clazz->descriptor, methodToCall->name);
1957 assert(methodToCall != NULL);
1958
1959 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
1960 }
1961GOTO_TARGET_END
1962
1963GOTO_TARGET(invokeSuperQuick, bool methodCallRange, bool jumboFormat)
1964 {
1965 u2 thisReg;
1966
1967 EXPORT_PC();
1968
1969 vsrc1 = INST_AA(inst); /* AA (count) or BA (count + arg 5) */
1970 ref = FETCH(1); /* vtable index */
1971 vdst = FETCH(2); /* 4 regs -or- first reg */
1972
1973 if (methodCallRange) {
1974 ILOGV("|invoke-super-quick-range args=%d @0x%04x {regs=v%d-v%d}",
1975 vsrc1, ref, vdst, vdst+vsrc1-1);
1976 thisReg = vdst;
1977 } else {
1978 ILOGV("|invoke-super-quick args=%d @0x%04x {regs=0x%04x %x}",
1979 vsrc1 >> 4, ref, vdst, vsrc1 & 0x0f);
1980 thisReg = vdst & 0x0f;
1981 }
1982 /* impossible in well-formed code, but we must check nevertheless */
1983 if (!checkForNull((Object*) GET_REGISTER(thisReg)))
1984 GOTO_exceptionThrown();
1985
1986#if 0 /* impossible in optimized + verified code */
1987 if (ref >= curMethod->clazz->super->vtableCount) {
1988 dvmThrowNoSuchMethodError(NULL);
1989 GOTO_exceptionThrown();
1990 }
1991#else
1992 assert(ref < (unsigned int) curMethod->clazz->super->vtableCount);
1993#endif
1994
1995 /*
1996 * Combine the object we found with the vtable offset in the
1997 * method's class.
1998 *
1999 * We're using the current method's class' superclass, not the
2000 * superclass of "this". This is because we might be executing
2001 * in a method inherited from a superclass, and we want to run
2002 * in the method's class' superclass.
2003 */
2004 methodToCall = curMethod->clazz->super->vtable[ref];
2005
2006#if 0
2007 if (dvmIsAbstractMethod(methodToCall)) {
2008 dvmThrowAbstractMethodError("abstract method not implemented");
2009 GOTO_exceptionThrown();
2010 }
2011#else
2012 assert(!dvmIsAbstractMethod(methodToCall) ||
2013 methodToCall->nativeFunc != NULL);
2014#endif
2015 LOGVV("+++ super-virtual[%d]=%s.%s\n",
2016 ref, methodToCall->clazz->descriptor, methodToCall->name);
2017 assert(methodToCall != NULL);
2018 GOTO_invokeMethod(methodCallRange, methodToCall, vsrc1, vdst);
2019 }
2020GOTO_TARGET_END
2021
2022
2023 /*
2024 * General handling for return-void, return, and return-wide. Put the
2025 * return value in "retval" before jumping here.
2026 */
2027GOTO_TARGET(returnFromMethod)
2028 {
2029 StackSaveArea* saveArea;
2030
2031 /*
2032 * We must do this BEFORE we pop the previous stack frame off, so
2033 * that the GC can see the return value (if any) in the local vars.
2034 *
2035 * Since this is now an interpreter switch point, we must do it before
2036 * we do anything at all.
2037 */
2038 PERIODIC_CHECKS(0);
2039
2040 ILOGV("> retval=0x%llx (leaving %s.%s %s)",
2041 retval.j, curMethod->clazz->descriptor, curMethod->name,
2042 curMethod->shorty);
2043 //DUMP_REGS(curMethod, fp);
2044
2045 saveArea = SAVEAREA_FROM_FP(fp);
2046
2047#ifdef EASY_GDB
2048 debugSaveArea = saveArea;
2049#endif
2050
2051 /* back up to previous frame and see if we hit a break */
2052 fp = (u4*)saveArea->prevFrame;
2053 assert(fp != NULL);
2054
2055 /* Handle any special subMode requirements */
2056 if (self->interpBreak.ctl.subMode != 0) {
2057 PC_FP_TO_SELF();
2058 dvmReportReturn(self);
2059 }
2060
2061 if (dvmIsBreakFrame(fp)) {
2062 /* bail without popping the method frame from stack */
2063 LOGVV("+++ returned into break frame\n");
2064 GOTO_bail();
2065 }
2066
2067 /* update thread FP, and reset local variables */
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2068 self->interpSave.curFrame = fp;
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2069 curMethod = SAVEAREA_FROM_FP(fp)->method;
2070 self->interpSave.method = curMethod;
2071 //methodClass = curMethod->clazz;
2072 methodClassDex = curMethod->clazz->pDvmDex;
2073 pc = saveArea->savedPc;
2074 ILOGD("> (return to %s.%s %s)", curMethod->clazz->descriptor,
2075 curMethod->name, curMethod->shorty);
2076
2077 /* use FINISH on the caller's invoke instruction */
2078 //u2 invokeInstr = INST_INST(FETCH(0));
2079 if (true /*invokeInstr >= OP_INVOKE_VIRTUAL &&
2080 invokeInstr <= OP_INVOKE_INTERFACE*/)
2081 {
2082 FINISH(3);
2083 } else {
2084 //LOGE("Unknown invoke instr %02x at %d\n",
2085 // invokeInstr, (int) (pc - curMethod->insns));
2086 assert(false);
2087 }
2088 }
2089GOTO_TARGET_END
2090
2091
2092 /*
2093 * Jump here when the code throws an exception.
2094 *
2095 * By the time we get here, the Throwable has been created and the stack
2096 * trace has been saved off.
2097 */
2098GOTO_TARGET(exceptionThrown)
2099 {
2100 Object* exception;
2101 int catchRelPc;
2102
2103 PERIODIC_CHECKS(0);
2104
2105 /*
2106 * We save off the exception and clear the exception status. While
2107 * processing the exception we might need to load some Throwable
2108 * classes, and we don't want class loader exceptions to get
2109 * confused with this one.
2110 */
2111 assert(dvmCheckException(self));
2112 exception = dvmGetException(self);
2113 dvmAddTrackedAlloc(exception, self);
2114 dvmClearException(self);
2115
2116 LOGV("Handling exception %s at %s:%d\n",
2117 exception->clazz->descriptor, curMethod->name,
2118 dvmLineNumFromPC(curMethod, pc - curMethod->insns));
2119
2120 /*
2121 * Report the exception throw to any "subMode" watchers.
2122 *
2123 * TODO: if the exception was thrown by interpreted code, control
2124 * fell through native, and then back to us, we will report the
2125 * exception at the point of the throw and again here. We can avoid
2126 * this by not reporting exceptions when we jump here directly from
2127 * the native call code above, but then we won't report exceptions
2128 * that were thrown *from* the JNI code (as opposed to *through* it).
2129 *
2130 * The correct solution is probably to ignore from-native exceptions
2131 * here, and have the JNI exception code do the reporting to the
2132 * debugger.
2133 */
2134 if (self->interpBreak.ctl.subMode != 0) {
2135 PC_FP_TO_SELF();
2136 dvmReportExceptionThrow(self, exception);
2137 }
2138
2139 /*
2140 * We need to unroll to the catch block or the nearest "break"
2141 * frame.
2142 *
2143 * A break frame could indicate that we have reached an intermediate
2144 * native call, or have gone off the top of the stack and the thread
2145 * needs to exit. Either way, we return from here, leaving the
2146 * exception raised.
2147 *
2148 * If we do find a catch block, we want to transfer execution to
2149 * that point.
2150 *
2151 * Note this can cause an exception while resolving classes in
2152 * the "catch" blocks.
2153 */
2154 catchRelPc = dvmFindCatchBlock(self, pc - curMethod->insns,
2155 exception, false, (void**)(void*)&fp);
2156
2157 /*
2158 * Restore the stack bounds after an overflow. This isn't going to
2159 * be correct in all circumstances, e.g. if JNI code devours the
2160 * exception this won't happen until some other exception gets
2161 * thrown. If the code keeps pushing the stack bounds we'll end
2162 * up aborting the VM.
2163 *
2164 * Note we want to do this *after* the call to dvmFindCatchBlock,
2165 * because that may need extra stack space to resolve exception
2166 * classes (e.g. through a class loader).
2167 *
2168 * It's possible for the stack overflow handling to cause an
2169 * exception (specifically, class resolution in a "catch" block
2170 * during the call above), so we could see the thread's overflow
2171 * flag raised but actually be running in a "nested" interpreter
2172 * frame. We don't allow doubled-up StackOverflowErrors, so
2173 * we can check for this by just looking at the exception type
2174 * in the cleanup function. Also, we won't unroll past the SOE
2175 * point because the more-recent exception will hit a break frame
2176 * as it unrolls to here.
2177 */
2178 if (self->stackOverflowed)
2179 dvmCleanupStackOverflow(self, exception);
2180
2181 if (catchRelPc < 0) {
2182 /* falling through to JNI code or off the bottom of the stack */
2183#if DVM_SHOW_EXCEPTION >= 2
2184 LOGD("Exception %s from %s:%d not caught locally\n",
2185 exception->clazz->descriptor, dvmGetMethodSourceFile(curMethod),
2186 dvmLineNumFromPC(curMethod, pc - curMethod->insns));
2187#endif
2188 dvmSetException(self, exception);
2189 dvmReleaseTrackedAlloc(exception, self);
2190 GOTO_bail();
2191 }
2192
2193#if DVM_SHOW_EXCEPTION >= 3
2194 {
2195 const Method* catchMethod = SAVEAREA_FROM_FP(fp)->method;
2196 LOGD("Exception %s thrown from %s:%d to %s:%d\n",
2197 exception->clazz->descriptor, dvmGetMethodSourceFile(curMethod),
2198 dvmLineNumFromPC(curMethod, pc - curMethod->insns),
2199 dvmGetMethodSourceFile(catchMethod),
2200 dvmLineNumFromPC(catchMethod, catchRelPc));
2201 }
2202#endif
2203
2204 /*
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2205 * Adjust local variables to match self->interpSave.curFrame and the
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2206 * updated PC.
2207 */
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2208 //fp = (u4*) self->interpSave.curFrame;
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2209 curMethod = SAVEAREA_FROM_FP(fp)->method;
2210 self->interpSave.method = curMethod;
2211 //methodClass = curMethod->clazz;
2212 methodClassDex = curMethod->clazz->pDvmDex;
2213 pc = curMethod->insns + catchRelPc;
2214 ILOGV("> pc <-- %s.%s %s", curMethod->clazz->descriptor,
2215 curMethod->name, curMethod->shorty);
2216 DUMP_REGS(curMethod, fp, false); // show all regs
2217
2218 /*
2219 * Restore the exception if the handler wants it.
2220 *
2221 * The Dalvik spec mandates that, if an exception handler wants to
2222 * do something with the exception, the first instruction executed
2223 * must be "move-exception". We can pass the exception along
2224 * through the thread struct, and let the move-exception instruction
2225 * clear it for us.
2226 *
2227 * If the handler doesn't call move-exception, we don't want to
2228 * finish here with an exception still pending.
2229 */
2230 if (INST_INST(FETCH(0)) == OP_MOVE_EXCEPTION)
2231 dvmSetException(self, exception);
2232
2233 dvmReleaseTrackedAlloc(exception, self);
2234 FINISH(0);
2235 }
2236GOTO_TARGET_END
2237
2238
2239
2240 /*
2241 * General handling for invoke-{virtual,super,direct,static,interface},
2242 * including "quick" variants.
2243 *
2244 * Set "methodToCall" to the Method we're calling, and "methodCallRange"
2245 * depending on whether this is a "/range" instruction.
2246 *
2247 * For a range call:
2248 * "vsrc1" holds the argument count (8 bits)
2249 * "vdst" holds the first argument in the range
2250 * For a non-range call:
2251 * "vsrc1" holds the argument count (4 bits) and the 5th argument index
2252 * "vdst" holds four 4-bit register indices
2253 *
2254 * The caller must EXPORT_PC before jumping here, because any method
2255 * call can throw a stack overflow exception.
2256 */
2257GOTO_TARGET(invokeMethod, bool methodCallRange, const Method* _methodToCall,
2258 u2 count, u2 regs)
2259 {
2260 STUB_HACK(vsrc1 = count; vdst = regs; methodToCall = _methodToCall;);
2261
2262 //printf("range=%d call=%p count=%d regs=0x%04x\n",
2263 // methodCallRange, methodToCall, count, regs);
2264 //printf(" --> %s.%s %s\n", methodToCall->clazz->descriptor,
2265 // methodToCall->name, methodToCall->shorty);
2266
2267 u4* outs;
2268 int i;
2269
2270 /*
2271 * Copy args. This may corrupt vsrc1/vdst.
2272 */
2273 if (methodCallRange) {
2274 // could use memcpy or a "Duff's device"; most functions have
2275 // so few args it won't matter much
2276 assert(vsrc1 <= curMethod->outsSize);
2277 assert(vsrc1 == methodToCall->insSize);
2278 outs = OUTS_FROM_FP(fp, vsrc1);
2279 for (i = 0; i < vsrc1; i++)
2280 outs[i] = GET_REGISTER(vdst+i);
2281 } else {
2282 u4 count = vsrc1 >> 4;
2283
2284 assert(count <= curMethod->outsSize);
2285 assert(count == methodToCall->insSize);
2286 assert(count <= 5);
2287
2288 outs = OUTS_FROM_FP(fp, count);
2289#if 0
2290 if (count == 5) {
2291 outs[4] = GET_REGISTER(vsrc1 & 0x0f);
2292 count--;
2293 }
2294 for (i = 0; i < (int) count; i++) {
2295 outs[i] = GET_REGISTER(vdst & 0x0f);
2296 vdst >>= 4;
2297 }
2298#else
2299 // This version executes fewer instructions but is larger
2300 // overall. Seems to be a teensy bit faster.
2301 assert((vdst >> 16) == 0); // 16 bits -or- high 16 bits clear
2302 switch (count) {
2303 case 5:
2304 outs[4] = GET_REGISTER(vsrc1 & 0x0f);
2305 case 4:
2306 outs[3] = GET_REGISTER(vdst >> 12);
2307 case 3:
2308 outs[2] = GET_REGISTER((vdst & 0x0f00) >> 8);
2309 case 2:
2310 outs[1] = GET_REGISTER((vdst & 0x00f0) >> 4);
2311 case 1:
2312 outs[0] = GET_REGISTER(vdst & 0x0f);
2313 default:
2314 ;
2315 }
2316#endif
2317 }
2318 }
2319
2320 /*
2321 * (This was originally a "goto" target; I've kept it separate from the
2322 * stuff above in case we want to refactor things again.)
2323 *
2324 * At this point, we have the arguments stored in the "outs" area of
2325 * the current method's stack frame, and the method to call in
2326 * "methodToCall". Push a new stack frame.
2327 */
2328 {
2329 StackSaveArea* newSaveArea;
2330 u4* newFp;
2331
2332 ILOGV("> %s%s.%s %s",
2333 dvmIsNativeMethod(methodToCall) ? "(NATIVE) " : "",
2334 methodToCall->clazz->descriptor, methodToCall->name,
2335 methodToCall->shorty);
2336
2337 newFp = (u4*) SAVEAREA_FROM_FP(fp) - methodToCall->registersSize;
2338 newSaveArea = SAVEAREA_FROM_FP(newFp);
2339
2340 /* verify that we have enough space */
2341 if (true) {
2342 u1* bottom;
2343 bottom = (u1*) newSaveArea - methodToCall->outsSize * sizeof(u4);
2344 if (bottom < self->interpStackEnd) {
2345 /* stack overflow */
2346 LOGV("Stack overflow on method call (start=%p end=%p newBot=%p(%d) size=%d '%s')\n",
2347 self->interpStackStart, self->interpStackEnd, bottom,
2348 (u1*) fp - bottom, self->interpStackSize,
2349 methodToCall->name);
2350 dvmHandleStackOverflow(self, methodToCall);
2351 assert(dvmCheckException(self));
2352 GOTO_exceptionThrown();
2353 }
2354 //LOGD("+++ fp=%p newFp=%p newSave=%p bottom=%p\n",
2355 // fp, newFp, newSaveArea, bottom);
2356 }
2357
2358#ifdef LOG_INSTR
2359 if (methodToCall->registersSize > methodToCall->insSize) {
2360 /*
2361 * This makes valgrind quiet when we print registers that
2362 * haven't been initialized. Turn it off when the debug
2363 * messages are disabled -- we want valgrind to report any
2364 * used-before-initialized issues.
2365 */
2366 memset(newFp, 0xcc,
2367 (methodToCall->registersSize - methodToCall->insSize) * 4);
2368 }
2369#endif
2370
2371#ifdef EASY_GDB
2372 newSaveArea->prevSave = SAVEAREA_FROM_FP(fp);
2373#endif
2374 newSaveArea->prevFrame = fp;
2375 newSaveArea->savedPc = pc;
2376#if defined(WITH_JIT) && defined(MTERP_STUB)
2377 newSaveArea->returnAddr = 0;
2378#endif
2379 newSaveArea->method = methodToCall;
2380
2381 if (self->interpBreak.ctl.subMode != 0) {
2382 /*
2383 * We mark ENTER here for both native and non-native
2384 * calls. For native calls, we'll mark EXIT on return.
2385 * For non-native calls, EXIT is marked in the RETURN op.
2386 */
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2387 PC_TO_SELF();
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2388 dvmReportInvoke(self, methodToCall);
2389 }
2390
2391 if (!dvmIsNativeMethod(methodToCall)) {
2392 /*
2393 * "Call" interpreted code. Reposition the PC, update the
2394 * frame pointer and other local state, and continue.
2395 */
2396 curMethod = methodToCall;
2397 self->interpSave.method = curMethod;
2398 methodClassDex = curMethod->clazz->pDvmDex;
2399 pc = methodToCall->insns;
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2400 self->interpSave.curFrame = fp = newFp;
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2401#ifdef EASY_GDB
2402 debugSaveArea = SAVEAREA_FROM_FP(newFp);
2403#endif
2404 self->debugIsMethodEntry = true; // profiling, debugging
2405 ILOGD("> pc <-- %s.%s %s", curMethod->clazz->descriptor,
2406 curMethod->name, curMethod->shorty);
2407 DUMP_REGS(curMethod, fp, true); // show input args
2408 FINISH(0); // jump to method start
2409 } else {
2410 /* set this up for JNI locals, even if not a JNI native */
2411 newSaveArea->xtra.localRefCookie = self->jniLocalRefTable.segmentState.all;
2412
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2413 self->interpSave.curFrame = newFp;
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2414
2415 DUMP_REGS(methodToCall, newFp, true); // show input args
2416
2417 if (self->interpBreak.ctl.subMode != 0) {
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2418 dvmReportPreNativeInvoke(methodToCall, self, fp);
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2419 }
2420
2421 ILOGD("> native <-- %s.%s %s", methodToCall->clazz->descriptor,
2422 methodToCall->name, methodToCall->shorty);
2423
2424 /*
2425 * Jump through native call bridge. Because we leave no
2426 * space for locals on native calls, "newFp" points directly
2427 * to the method arguments.
2428 */
2429 (*methodToCall->nativeFunc)(newFp, &retval, methodToCall, self);
2430
2431 if (self->interpBreak.ctl.subMode != 0) {
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2432 dvmReportPostNativeInvoke(methodToCall, self, fp);
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2433 }
2434
2435 /* pop frame off */
2436 dvmPopJniLocals(self, newSaveArea);
buzbee30bc0d42011-04-22 10:27:14 -0700[diff] [blame]2437 self->interpSave.curFrame = fp;
Carl Shapirocd8f5e72011-04-20 16:12:46 -0700[diff] [blame]2438
2439 /*
2440 * If the native code threw an exception, or interpreted code
2441 * invoked by the native call threw one and nobody has cleared
2442 * it, jump to our local exception handling.
2443 */
2444 if (dvmCheckException(self)) {
2445 LOGV("Exception thrown by/below native code\n");
2446 GOTO_exceptionThrown();
2447 }
2448
2449 ILOGD("> retval=0x%llx (leaving native)", retval.j);
2450 ILOGD("> (return from native %s.%s to %s.%s %s)",
2451 methodToCall->clazz->descriptor, methodToCall->name,
2452 curMethod->clazz->descriptor, curMethod->name,
2453 curMethod->shorty);
2454
2455 //u2 invokeInstr = INST_INST(FETCH(0));
2456 if (true /*invokeInstr >= OP_INVOKE_VIRTUAL &&
2457 invokeInstr <= OP_INVOKE_INTERFACE*/)
2458 {
2459 FINISH(3);
2460 } else {
2461 //LOGE("Unknown invoke instr %02x at %d\n",
2462 // invokeInstr, (int) (pc - curMethod->insns));
2463 assert(false);
2464 }
2465 }
2466 }
2467 assert(false); // should not get here
2468GOTO_TARGET_END
2469
2470/* File: cstubs/enddefs.cpp */
2471
2472/* undefine "magic" name remapping */
2473#undef retval
2474#undef pc
2475#undef fp
2476#undef curMethod
2477#undef methodClassDex
2478#undef self
2479#undef debugTrackedRefStart
2480