vm/mterp/c/header.cpp - platform/dalvik - Gitiles

 /*
  * Copyright (C) 2008 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 /* common includes */
 #include "Dalvik.h"
 #include "interp/InterpDefs.h"
 #include "mterp/Mterp.h"
 #include <math.h>                   // needed for fmod, fmodf
 #include "mterp/common/FindInterface.h"

 /*
  * Configuration defines.  These affect the C implementations, i.e. the
  * portable interpreter(s) and C stubs.
  *
  * Some defines are controlled by the Makefile, e.g.:
  *   WITH_INSTR_CHECKS
  *   WITH_TRACKREF_CHECKS
  *   EASY_GDB
  *   NDEBUG
  */

 #ifdef WITH_INSTR_CHECKS            /* instruction-level paranoia (slow!) */
 # define CHECK_BRANCH_OFFSETS
 # define CHECK_REGISTER_INDICES
 #endif

 /*
  * Some architectures require 64-bit alignment for access to 64-bit data
  * types.  We can't just use pointers to copy 64-bit values out of our
  * interpreted register set, because gcc may assume the pointer target is
  * aligned and generate invalid code.
  *
  * There are two common approaches:
  *  (1) Use a union that defines a 32-bit pair and a 64-bit value.
  *  (2) Call memcpy().
  *
  * Depending upon what compiler you're using and what options are specified,
  * one may be faster than the other.  For example, the compiler might
  * convert a memcpy() of 8 bytes into a series of instructions and omit
  * the call.  The union version could cause some strange side-effects,
  * e.g. for a while ARM gcc thought it needed separate storage for each
  * inlined instance, and generated instructions to zero out ~700 bytes of
  * stack space at the top of the interpreter.
  *
  * The default is to use memcpy().  The current gcc for ARM seems to do
  * better with the union.
  */
 #if defined(__ARM_EABI__)
 # define NO_UNALIGN_64__UNION
 #endif
 /*
  * MIPS ABI requires 64-bit alignment for access to 64-bit data types.
  *
  * Use memcpy() to do the transfer
  */
 #if defined(__mips__)
 /* # define NO_UNALIGN_64__UNION */
 #endif


 //#define LOG_INSTR                   /* verbose debugging */
 /* set and adjust ANDROID_LOG_TAGS='*:i jdwp:i dalvikvm:i dalvikvmi:i' */

 /*
  * Export another copy of the PC on every instruction; this is largely
  * redundant with EXPORT_PC and the debugger code.  This value can be
  * compared against what we have stored on the stack with EXPORT_PC to
  * help ensure that we aren't missing any export calls.
  */
 #if WITH_EXTRA_GC_CHECKS > 1
 # define EXPORT_EXTRA_PC() (self->currentPc2 = pc)
 #else
 # define EXPORT_EXTRA_PC()
 #endif

 /*
  * Adjust the program counter.  "_offset" is a signed int, in 16-bit units.
  *
  * Assumes the existence of "const u2* pc" and "const u2* curMethod->insns".
  *
  * We don't advance the program counter until we finish an instruction or
  * branch, because we do want to have to unroll the PC if there's an
  * exception.
  */
 #ifdef CHECK_BRANCH_OFFSETS
 # define ADJUST_PC(_offset) do {                                            \
         int myoff = _offset;        /* deref only once */                   \
         if (pc + myoff < curMethod->insns ||                                \
             pc + myoff >= curMethod->insns + dvmGetMethodInsnsSize(curMethod)) \
         {                                                                   \
             char* desc;                                                     \
             desc = dexProtoCopyMethodDescriptor(&curMethod->prototype);     \
             ALOGE("Invalid branch %d at 0x%04x in %s.%s %s",                 \
                 myoff, (int) (pc - curMethod->insns),                       \
                 curMethod->clazz->descriptor, curMethod->name, desc);       \
             free(desc);                                                     \
             dvmAbort();                                                     \
         }                                                                   \
         pc += myoff;                                                        \
         EXPORT_EXTRA_PC();                                                  \
     } while (false)
 #else
 # define ADJUST_PC(_offset) do {                                            \
         pc += _offset;                                                      \
         EXPORT_EXTRA_PC();                                                  \
     } while (false)
 #endif

 /*
  * If enabled, log instructions as we execute them.
  */
 #ifdef LOG_INSTR
 # define ILOGD(...) ILOG(LOG_DEBUG, __VA_ARGS__)
 # define ILOGV(...) ILOG(LOG_VERBOSE, __VA_ARGS__)
 # define ILOG(_level, ...) do {                                             \
         char debugStrBuf[128];                                              \
         snprintf(debugStrBuf, sizeof(debugStrBuf), __VA_ARGS__);            \
         if (curMethod != NULL)                                              \
             ALOG(_level, LOG_TAG"i", "%-2d|%04x%s",                          \
                 self->threadId, (int)(pc - curMethod->insns), debugStrBuf); \
         else                                                                \
             ALOG(_level, LOG_TAG"i", "%-2d|####%s",                          \
                 self->threadId, debugStrBuf);                               \
     } while(false)
 void dvmDumpRegs(const Method* method, const u4* framePtr, bool inOnly);
 # define DUMP_REGS(_meth, _frame, _inOnly) dvmDumpRegs(_meth, _frame, _inOnly)
 static const char kSpacing[] = "            ";
 #else
 # define ILOGD(...) ((void)0)
 # define ILOGV(...) ((void)0)
 # define DUMP_REGS(_meth, _frame, _inOnly) ((void)0)
 #endif

 /* get a long from an array of u4 */
 static inline s8 getLongFromArray(const u4* ptr, int idx)
 {
 #if defined(NO_UNALIGN_64__UNION)
     union { s8 ll; u4 parts[2]; } conv;

     ptr += idx;
     conv.parts[0] = ptr[0];
     conv.parts[1] = ptr[1];
     return conv.ll;
 #else
     s8 val;
     memcpy(&val, &ptr[idx], 8);
     return val;
 #endif
 }

 /* store a long into an array of u4 */
 static inline void putLongToArray(u4* ptr, int idx, s8 val)
 {
 #if defined(NO_UNALIGN_64__UNION)
     union { s8 ll; u4 parts[2]; } conv;

     ptr += idx;
     conv.ll = val;
     ptr[0] = conv.parts[0];
     ptr[1] = conv.parts[1];
 #else
     memcpy(&ptr[idx], &val, 8);
 #endif
 }

 /* get a double from an array of u4 */
 static inline double getDoubleFromArray(const u4* ptr, int idx)
 {
 #if defined(NO_UNALIGN_64__UNION)
     union { double d; u4 parts[2]; } conv;

     ptr += idx;
     conv.parts[0] = ptr[0];
     conv.parts[1] = ptr[1];
     return conv.d;
 #else
     double dval;
     memcpy(&dval, &ptr[idx], 8);
     return dval;
 #endif
 }

 /* store a double into an array of u4 */
 static inline void putDoubleToArray(u4* ptr, int idx, double dval)
 {
 #if defined(NO_UNALIGN_64__UNION)
     union { double d; u4 parts[2]; } conv;

     ptr += idx;
     conv.d = dval;
     ptr[0] = conv.parts[0];
     ptr[1] = conv.parts[1];
 #else
     memcpy(&ptr[idx], &dval, 8);
 #endif
 }

 /*
  * If enabled, validate the register number on every access.  Otherwise,
  * just do an array access.
  *
  * Assumes the existence of "u4* fp".
  *
  * "_idx" may be referenced more than once.
  */
 #ifdef CHECK_REGISTER_INDICES
 # define GET_REGISTER(_idx) \
     ( (_idx) < curMethod->registersSize ? \
         (fp[(_idx)]) : (assert(!"bad reg"),1969) )
 # define SET_REGISTER(_idx, _val) \
     ( (_idx) < curMethod->registersSize ? \
         (fp[(_idx)] = (u4)(_val)) : (assert(!"bad reg"),1969) )
 # define GET_REGISTER_AS_OBJECT(_idx)       ((Object *)GET_REGISTER(_idx))
 # define SET_REGISTER_AS_OBJECT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
 # define GET_REGISTER_INT(_idx) ((s4) GET_REGISTER(_idx))
 # define SET_REGISTER_INT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
 # define GET_REGISTER_WIDE(_idx) \
     ( (_idx) < curMethod->registersSize-1 ? \
         getLongFromArray(fp, (_idx)) : (assert(!"bad reg"),1969) )
 # define SET_REGISTER_WIDE(_idx, _val) \
     ( (_idx) < curMethod->registersSize-1 ? \
         (void)putLongToArray(fp, (_idx), (_val)) : assert(!"bad reg") )
 # define GET_REGISTER_FLOAT(_idx) \
     ( (_idx) < curMethod->registersSize ? \
         (*((float*) &fp[(_idx)])) : (assert(!"bad reg"),1969.0f) )
 # define SET_REGISTER_FLOAT(_idx, _val) \
     ( (_idx) < curMethod->registersSize ? \
         (*((float*) &fp[(_idx)]) = (_val)) : (assert(!"bad reg"),1969.0f) )
 # define GET_REGISTER_DOUBLE(_idx) \
     ( (_idx) < curMethod->registersSize-1 ? \
         getDoubleFromArray(fp, (_idx)) : (assert(!"bad reg"),1969.0) )
 # define SET_REGISTER_DOUBLE(_idx, _val) \
     ( (_idx) < curMethod->registersSize-1 ? \
         (void)putDoubleToArray(fp, (_idx), (_val)) : assert(!"bad reg") )
 #else
 # define GET_REGISTER(_idx)                 (fp[(_idx)])
 # define SET_REGISTER(_idx, _val)           (fp[(_idx)] = (_val))
 # define GET_REGISTER_AS_OBJECT(_idx)       ((Object*) fp[(_idx)])
 # define SET_REGISTER_AS_OBJECT(_idx, _val) (fp[(_idx)] = (u4)(_val))
 # define GET_REGISTER_INT(_idx)             ((s4)GET_REGISTER(_idx))
 # define SET_REGISTER_INT(_idx, _val)       SET_REGISTER(_idx, (s4)_val)
 # define GET_REGISTER_WIDE(_idx)            getLongFromArray(fp, (_idx))
 # define SET_REGISTER_WIDE(_idx, _val)      putLongToArray(fp, (_idx), (_val))
 # define GET_REGISTER_FLOAT(_idx)           (*((float*) &fp[(_idx)]))
 # define SET_REGISTER_FLOAT(_idx, _val)     (*((float*) &fp[(_idx)]) = (_val))
 # define GET_REGISTER_DOUBLE(_idx)          getDoubleFromArray(fp, (_idx))
 # define SET_REGISTER_DOUBLE(_idx, _val)    putDoubleToArray(fp, (_idx), (_val))
 #endif

 /*
  * Get 16 bits from the specified offset of the program counter.  We always
  * want to load 16 bits at a time from the instruction stream -- it's more
  * efficient than 8 and won't have the alignment problems that 32 might.
  *
  * Assumes existence of "const u2* pc".
  */
 #define FETCH(_offset)     (pc[(_offset)])

 /*
  * Extract instruction byte from 16-bit fetch (_inst is a u2).
  */
 #define INST_INST(_inst)    ((_inst) & 0xff)

 /*
  * Replace the opcode (used when handling breakpoints).  _opcode is a u1.
  */
 #define INST_REPLACE_OP(_inst, _opcode) (((_inst) & 0xff00) | _opcode)

 /*
  * Extract the "vA, vB" 4-bit registers from the instruction word (_inst is u2).
  */
 #define INST_A(_inst)       (((_inst) >> 8) & 0x0f)
 #define INST_B(_inst)       ((_inst) >> 12)

 /*
  * Get the 8-bit "vAA" 8-bit register index from the instruction word.
  * (_inst is u2)
  */
 #define INST_AA(_inst)      ((_inst) >> 8)

 /*
  * The current PC must be available to Throwable constructors, e.g.
  * those created by the various exception throw routines, so that the
  * exception stack trace can be generated correctly.  If we don't do this,
  * the offset within the current method won't be shown correctly.  See the
  * notes in Exception.c.
  *
  * This is also used to determine the address for precise GC.
  *
  * Assumes existence of "u4* fp" and "const u2* pc".
  */
 #define EXPORT_PC()         (SAVEAREA_FROM_FP(fp)->xtra.currentPc = pc)

 /*
  * Check to see if "obj" is NULL.  If so, throw an exception.  Assumes the
  * pc has already been exported to the stack.
  *
  * Perform additional checks on debug builds.
  *
  * Use this to check for NULL when the instruction handler calls into
  * something that could throw an exception (so we have already called
  * EXPORT_PC at the top).
  */
 static inline bool checkForNull(Object* obj)
 {
     if (obj == NULL) {
         dvmThrowNullPointerException(NULL);
         return false;
     }
 #ifdef WITH_EXTRA_OBJECT_VALIDATION
     if (!dvmIsHeapAddress(obj)) {
         ALOGE("Invalid object %p", obj);
         dvmAbort();
     }
 #endif
 #ifndef NDEBUG
     if (obj->clazz == NULL || ((u4) obj->clazz) <= 65536) {
         /* probable heap corruption */
         ALOGE("Invalid object class %p (in %p)", obj->clazz, obj);
         dvmAbort();
     }
 #endif
     return true;
 }

 /*
  * Check to see if "obj" is NULL.  If so, export the PC into the stack
  * frame and throw an exception.
  *
  * Perform additional checks on debug builds.
  *
  * Use this to check for NULL when the instruction handler doesn't do
  * anything else that can throw an exception.
  */
 static inline bool checkForNullExportPC(Object* obj, u4* fp, const u2* pc)
 {
     if (obj == NULL) {
         EXPORT_PC();
         dvmThrowNullPointerException(NULL);
         return false;
     }
 #ifdef WITH_EXTRA_OBJECT_VALIDATION
     if (!dvmIsHeapAddress(obj)) {
         ALOGE("Invalid object %p", obj);
         dvmAbort();
     }
 #endif
 #ifndef NDEBUG
     if (obj->clazz == NULL || ((u4) obj->clazz) <= 65536) {
         /* probable heap corruption */
         ALOGE("Invalid object class %p (in %p)", obj->clazz, obj);
         dvmAbort();
     }
 #endif
     return true;
 }
	/*
	* Copyright (C) 2008 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	/* common includes */
	#include "Dalvik.h"
	#include "interp/InterpDefs.h"
	#include "mterp/Mterp.h"
	#include <math.h> // needed for fmod, fmodf
	#include "mterp/common/FindInterface.h"

	/*
	* Configuration defines. These affect the C implementations, i.e. the
	* portable interpreter(s) and C stubs.
	*
	* Some defines are controlled by the Makefile, e.g.:
	* WITH_INSTR_CHECKS
	* WITH_TRACKREF_CHECKS
	* EASY_GDB
	* NDEBUG
	*/

	#ifdef WITH_INSTR_CHECKS /* instruction-level paranoia (slow!) */
	# define CHECK_BRANCH_OFFSETS
	# define CHECK_REGISTER_INDICES
	#endif

	/*
	* Some architectures require 64-bit alignment for access to 64-bit data
	* types. We can't just use pointers to copy 64-bit values out of our
	* interpreted register set, because gcc may assume the pointer target is
	* aligned and generate invalid code.
	*
	* There are two common approaches:
	* (1) Use a union that defines a 32-bit pair and a 64-bit value.
	* (2) Call memcpy().
	*
	* Depending upon what compiler you're using and what options are specified,
	* one may be faster than the other. For example, the compiler might
	* convert a memcpy() of 8 bytes into a series of instructions and omit
	* the call. The union version could cause some strange side-effects,
	* e.g. for a while ARM gcc thought it needed separate storage for each
	* inlined instance, and generated instructions to zero out ~700 bytes of
	* stack space at the top of the interpreter.
	*
	* The default is to use memcpy(). The current gcc for ARM seems to do
	* better with the union.
	*/
	#if defined(__ARM_EABI__)
	# define NO_UNALIGN_64__UNION
	#endif
	/*
	* MIPS ABI requires 64-bit alignment for access to 64-bit data types.
	*
	* Use memcpy() to do the transfer
	*/
	#if defined(__mips__)
	/* # define NO_UNALIGN_64__UNION */
	#endif


	//#define LOG_INSTR /* verbose debugging */
	/* set and adjust ANDROID_LOG_TAGS=':i jdwp:i dalvikvm:i dalvikvmi:i' /

	/*
	* Export another copy of the PC on every instruction; this is largely
	* redundant with EXPORT_PC and the debugger code. This value can be
	* compared against what we have stored on the stack with EXPORT_PC to
	* help ensure that we aren't missing any export calls.
	*/
	#if WITH_EXTRA_GC_CHECKS > 1
	# define EXPORT_EXTRA_PC() (self->currentPc2 = pc)
	#else
	# define EXPORT_EXTRA_PC()
	#endif

	/*
	* Adjust the program counter. "_offset" is a signed int, in 16-bit units.
	*
	* Assumes the existence of "const u2* pc" and "const u2* curMethod->insns".
	*
	* We don't advance the program counter until we finish an instruction or
	* branch, because we do want to have to unroll the PC if there's an
	* exception.
	*/
	#ifdef CHECK_BRANCH_OFFSETS
	# define ADJUST_PC(_offset) do { \
	int myoff = _offset; /* deref only once */ \
	if (pc + myoff < curMethod->insns \|\| \
	pc + myoff >= curMethod->insns + dvmGetMethodInsnsSize(curMethod)) \
	{ \
	char* desc; \
	desc = dexProtoCopyMethodDescriptor(&curMethod->prototype); \
	ALOGE("Invalid branch %d at 0x%04x in %s.%s %s", \
	myoff, (int) (pc - curMethod->insns), \
	curMethod->clazz->descriptor, curMethod->name, desc); \
	free(desc); \
	dvmAbort(); \
	} \
	pc += myoff; \
	EXPORT_EXTRA_PC(); \
	} while (false)
	#else
	# define ADJUST_PC(_offset) do { \
	pc += _offset; \
	EXPORT_EXTRA_PC(); \
	} while (false)
	#endif

	/*
	* If enabled, log instructions as we execute them.
	*/
	#ifdef LOG_INSTR
	# define ILOGD(...) ILOG(LOG_DEBUG, __VA_ARGS__)
	# define ILOGV(...) ILOG(LOG_VERBOSE, __VA_ARGS__)
	# define ILOG(_level, ...) do { \
	char debugStrBuf[128]; \
	snprintf(debugStrBuf, sizeof(debugStrBuf), __VA_ARGS__); \
	if (curMethod != NULL) \
	ALOG(_level, LOG_TAG"i", "%-2d\|%04x%s", \
	self->threadId, (int)(pc - curMethod->insns), debugStrBuf); \
	else \
	ALOG(_level, LOG_TAG"i", "%-2d\|####%s", \
	self->threadId, debugStrBuf); \
	} while(false)
	void dvmDumpRegs(const Method* method, const u4* framePtr, bool inOnly);
	# define DUMP_REGS(_meth, _frame, _inOnly) dvmDumpRegs(_meth, _frame, _inOnly)
	static const char kSpacing[] = " ";
	#else
	# define ILOGD(...) ((void)0)
	# define ILOGV(...) ((void)0)
	# define DUMP_REGS(_meth, _frame, _inOnly) ((void)0)
	#endif

	/* get a long from an array of u4 */
	static inline s8 getLongFromArray(const u4* ptr, int idx)
	{
	#if defined(NO_UNALIGN_64__UNION)
	union { s8 ll; u4 parts[2]; } conv;

	ptr += idx;
	conv.parts[0] = ptr[0];
	conv.parts[1] = ptr[1];
	return conv.ll;
	#else
	s8 val;
	memcpy(&val, &ptr[idx], 8);
	return val;
	#endif
	}

	/* store a long into an array of u4 */
	static inline void putLongToArray(u4* ptr, int idx, s8 val)
	{
	#if defined(NO_UNALIGN_64__UNION)
	union { s8 ll; u4 parts[2]; } conv;

	ptr += idx;
	conv.ll = val;
	ptr[0] = conv.parts[0];
	ptr[1] = conv.parts[1];
	#else
	memcpy(&ptr[idx], &val, 8);
	#endif
	}

	/* get a double from an array of u4 */
	static inline double getDoubleFromArray(const u4* ptr, int idx)
	{
	#if defined(NO_UNALIGN_64__UNION)
	union { double d; u4 parts[2]; } conv;

	ptr += idx;
	conv.parts[0] = ptr[0];
	conv.parts[1] = ptr[1];
	return conv.d;
	#else
	double dval;
	memcpy(&dval, &ptr[idx], 8);
	return dval;
	#endif
	}

	/* store a double into an array of u4 */
	static inline void putDoubleToArray(u4* ptr, int idx, double dval)
	{
	#if defined(NO_UNALIGN_64__UNION)
	union { double d; u4 parts[2]; } conv;

	ptr += idx;
	conv.d = dval;
	ptr[0] = conv.parts[0];
	ptr[1] = conv.parts[1];
	#else
	memcpy(&ptr[idx], &dval, 8);
	#endif
	}

	/*
	* If enabled, validate the register number on every access. Otherwise,
	* just do an array access.
	*
	* Assumes the existence of "u4* fp".
	*
	* "_idx" may be referenced more than once.
	*/
	#ifdef CHECK_REGISTER_INDICES
	# define GET_REGISTER(_idx) \
	( (_idx) < curMethod->registersSize ? \
	(fp[(_idx)]) : (assert(!"bad reg"),1969) )
	# define SET_REGISTER(_idx, _val) \
	( (_idx) < curMethod->registersSize ? \
	(fp[(_idx)] = (u4)(_val)) : (assert(!"bad reg"),1969) )
	# define GET_REGISTER_AS_OBJECT(_idx) ((Object *)GET_REGISTER(_idx))
	# define SET_REGISTER_AS_OBJECT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
	# define GET_REGISTER_INT(_idx) ((s4) GET_REGISTER(_idx))
	# define SET_REGISTER_INT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
	# define GET_REGISTER_WIDE(_idx) \
	( (_idx) < curMethod->registersSize-1 ? \
	getLongFromArray(fp, (_idx)) : (assert(!"bad reg"),1969) )
	# define SET_REGISTER_WIDE(_idx, _val) \
	( (_idx) < curMethod->registersSize-1 ? \
	(void)putLongToArray(fp, (_idx), (_val)) : assert(!"bad reg") )
	# define GET_REGISTER_FLOAT(_idx) \
	( (_idx) < curMethod->registersSize ? \
	(((float) &fp[(_idx)])) : (assert(!"bad reg"),1969.0f) )
	# define SET_REGISTER_FLOAT(_idx, _val) \
	( (_idx) < curMethod->registersSize ? \
	(((float) &fp[(_idx)]) = (_val)) : (assert(!"bad reg"),1969.0f) )
	# define GET_REGISTER_DOUBLE(_idx) \
	( (_idx) < curMethod->registersSize-1 ? \
	getDoubleFromArray(fp, (_idx)) : (assert(!"bad reg"),1969.0) )
	# define SET_REGISTER_DOUBLE(_idx, _val) \
	( (_idx) < curMethod->registersSize-1 ? \
	(void)putDoubleToArray(fp, (_idx), (_val)) : assert(!"bad reg") )
	#else
	# define GET_REGISTER(_idx) (fp[(_idx)])
	# define SET_REGISTER(_idx, _val) (fp[(_idx)] = (_val))
	# define GET_REGISTER_AS_OBJECT(_idx) ((Object*) fp[(_idx)])
	# define SET_REGISTER_AS_OBJECT(_idx, _val) (fp[(_idx)] = (u4)(_val))
	# define GET_REGISTER_INT(_idx) ((s4)GET_REGISTER(_idx))
	# define SET_REGISTER_INT(_idx, _val) SET_REGISTER(_idx, (s4)_val)
	# define GET_REGISTER_WIDE(_idx) getLongFromArray(fp, (_idx))
	# define SET_REGISTER_WIDE(_idx, _val) putLongToArray(fp, (_idx), (_val))
	# define GET_REGISTER_FLOAT(_idx) (((float) &fp[(_idx)]))
	# define SET_REGISTER_FLOAT(_idx, _val) (((float) &fp[(_idx)]) = (_val))
	# define GET_REGISTER_DOUBLE(_idx) getDoubleFromArray(fp, (_idx))
	# define SET_REGISTER_DOUBLE(_idx, _val) putDoubleToArray(fp, (_idx), (_val))
	#endif

	/*
	* Get 16 bits from the specified offset of the program counter. We always
	* want to load 16 bits at a time from the instruction stream -- it's more
	* efficient than 8 and won't have the alignment problems that 32 might.
	*
	* Assumes existence of "const u2* pc".
	*/
	#define FETCH(_offset) (pc[(_offset)])

	/*
	* Extract instruction byte from 16-bit fetch (_inst is a u2).
	*/
	#define INST_INST(_inst) ((_inst) & 0xff)

	/*
	* Replace the opcode (used when handling breakpoints). _opcode is a u1.
	*/
	#define INST_REPLACE_OP(_inst, _opcode) (((_inst) & 0xff00) \| _opcode)

	/*
	* Extract the "vA, vB" 4-bit registers from the instruction word (_inst is u2).
	*/
	#define INST_A(_inst) (((_inst) >> 8) & 0x0f)
	#define INST_B(_inst) ((_inst) >> 12)

	/*
	* Get the 8-bit "vAA" 8-bit register index from the instruction word.
	* (_inst is u2)
	*/
	#define INST_AA(_inst) ((_inst) >> 8)

	/*
	* The current PC must be available to Throwable constructors, e.g.
	* those created by the various exception throw routines, so that the
	* exception stack trace can be generated correctly. If we don't do this,
	* the offset within the current method won't be shown correctly. See the
	* notes in Exception.c.
	*
	* This is also used to determine the address for precise GC.
	*
	* Assumes existence of "u4* fp" and "const u2* pc".
	*/
	#define EXPORT_PC() (SAVEAREA_FROM_FP(fp)->xtra.currentPc = pc)

	/*
	* Check to see if "obj" is NULL. If so, throw an exception. Assumes the
	* pc has already been exported to the stack.
	*
	* Perform additional checks on debug builds.
	*
	* Use this to check for NULL when the instruction handler calls into
	* something that could throw an exception (so we have already called
	* EXPORT_PC at the top).
	*/
	static inline bool checkForNull(Object* obj)
	{
	if (obj == NULL) {
	dvmThrowNullPointerException(NULL);
	return false;
	}
	#ifdef WITH_EXTRA_OBJECT_VALIDATION
	if (!dvmIsHeapAddress(obj)) {
	ALOGE("Invalid object %p", obj);
	dvmAbort();
	}
	#endif
	#ifndef NDEBUG
	if (obj->clazz == NULL \|\| ((u4) obj->clazz) <= 65536) {
	/* probable heap corruption */
	ALOGE("Invalid object class %p (in %p)", obj->clazz, obj);
	dvmAbort();
	}
	#endif
	return true;
	}

	/*
	* Check to see if "obj" is NULL. If so, export the PC into the stack
	* frame and throw an exception.
	*
	* Perform additional checks on debug builds.
	*
	* Use this to check for NULL when the instruction handler doesn't do
	* anything else that can throw an exception.
	*/
	static inline bool checkForNullExportPC(Object* obj, u4* fp, const u2* pc)
	{
	if (obj == NULL) {
	EXPORT_PC();
	dvmThrowNullPointerException(NULL);
	return false;
	}
	#ifdef WITH_EXTRA_OBJECT_VALIDATION
	if (!dvmIsHeapAddress(obj)) {
	ALOGE("Invalid object %p", obj);
	dvmAbort();
	}
	#endif
	#ifndef NDEBUG
	if (obj->clazz == NULL \|\| ((u4) obj->clazz) <= 65536) {
	/* probable heap corruption */
	ALOGE("Invalid object class %p (in %p)", obj->clazz, obj);
	dvmAbort();
	}
	#endif
	return true;
	}