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android / platform / dalvik / fcfb52201103bf732a6233ea45daaa65e253543b / . / vm / interp / Stack.c
blob: 8d8cc1bf23765fce7d8eb447a73962f1812dc8d3 [file] [log] [blame]
/*
* 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.
*/
/*
* Stacks and their uses (e.g. native --> interpreted method calls).
*
* See the majestic ASCII art in Stack.h.
*/
#include "Dalvik.h"
#include "jni.h"
#include <stdlib.h>
#include <stdarg.h>
/*
* Initialize the interpreter stack in a new thread.
*
* Currently this doesn't do much, since we don't need to zero out the
* stack (and we really don't want to if it was created with mmap).
*/
bool dvmInitInterpStack(Thread* thread, int stackSize)
{
assert(thread->interpStackStart != NULL);
assert(thread->curFrame == NULL);
return true;
}
/*
* We're calling an interpreted method from an internal VM function or
* via reflection.
*
* Push a frame for an interpreted method onto the stack. This is only
* used when calling into interpreted code from native code. (The
* interpreter does its own stack frame manipulation for interp-->interp
* calls.)
*
* The size we need to reserve is the sum of parameters, local variables,
* saved goodies, and outbound parameters.
*
* We start by inserting a "break" frame, which ensures that the interpreter
* hands control back to us after the function we call returns or an
* uncaught exception is thrown.
*/
static bool dvmPushInterpFrame(Thread* self, const Method* method)
{
StackSaveArea* saveBlock;
StackSaveArea* breakSaveBlock;
int stackReq;
u1* stackPtr;
assert(!dvmIsNativeMethod(method));
assert(!dvmIsAbstractMethod(method));
stackReq = method->registersSize * 4 // params + locals
+ sizeof(StackSaveArea) * 2 // break frame + regular frame
+ method->outsSize * 4; // args to other methods
if (self->curFrame != NULL)
stackPtr = (u1*) SAVEAREA_FROM_FP(self->curFrame);
else
stackPtr = self->interpStackStart;
if (stackPtr - stackReq < self->interpStackEnd) {
/* not enough space */
LOGW("Stack overflow on call to interp "
"(req=%d top=%p cur=%p size=%d %s.%s)\n",
stackReq, self->interpStackStart, self->curFrame,
self->interpStackSize, method->clazz->descriptor, method->name);
dvmHandleStackOverflow(self, method);
assert(dvmCheckException(self));
return false;
}
/*
* Shift the stack pointer down, leaving space for the function's
* args/registers and save area.
*/
stackPtr -= sizeof(StackSaveArea);
breakSaveBlock = (StackSaveArea*)stackPtr;
stackPtr -= method->registersSize * 4 + sizeof(StackSaveArea);
saveBlock = (StackSaveArea*) stackPtr;
#if !defined(NDEBUG) && !defined(PAD_SAVE_AREA)
/* debug -- memset the new stack, unless we want valgrind's help */
memset(stackPtr - (method->outsSize*4), 0xaf, stackReq);
#endif
#ifdef EASY_GDB
breakSaveBlock->prevSave = FP_FROM_SAVEAREA(self->curFrame);
saveBlock->prevSave = breakSaveBlock;
#endif
breakSaveBlock->prevFrame = self->curFrame;
breakSaveBlock->savedPc = NULL; // not required
breakSaveBlock->xtra.localRefCookie = 0; // not required
breakSaveBlock->method = NULL;
saveBlock->prevFrame = FP_FROM_SAVEAREA(breakSaveBlock);
saveBlock->savedPc = NULL; // not required
saveBlock->xtra.currentPc = NULL; // not required?
saveBlock->method = method;
LOGVV("PUSH frame: old=%p new=%p (size=%d)\n",
self->curFrame, FP_FROM_SAVEAREA(saveBlock),
(u1*)self->curFrame - (u1*)FP_FROM_SAVEAREA(saveBlock));
self->curFrame = FP_FROM_SAVEAREA(saveBlock);
return true;
}
/*
* We're calling a JNI native method from an internal VM fuction or
* via reflection. This is also used to create the "fake" native-method
* frames at the top of the interpreted stack.
*
* This actually pushes two frames; the first is a "break" frame.
*
* The top frame has additional space for JNI local reference tracking.
*/
bool dvmPushJNIFrame(Thread* self, const Method* method)
{
StackSaveArea* saveBlock;
StackSaveArea* breakSaveBlock;
int stackReq;
u1* stackPtr;
assert(dvmIsNativeMethod(method));
stackReq = method->registersSize * 4 // params only
+ sizeof(StackSaveArea) * 2; // break frame + regular frame
if (self->curFrame != NULL)
stackPtr = (u1*) SAVEAREA_FROM_FP(self->curFrame);
else
stackPtr = self->interpStackStart;
if (stackPtr - stackReq < self->interpStackEnd) {
/* not enough space */
LOGW("Stack overflow on call to native "
"(req=%d top=%p cur=%p size=%d '%s')\n",
stackReq, self->interpStackStart, self->curFrame,
self->interpStackSize, method->name);
dvmHandleStackOverflow(self, method);
assert(dvmCheckException(self));
return false;
}
/*
* Shift the stack pointer down, leaving space for just the stack save
* area for the break frame, then shift down farther for the full frame.
* We leave space for the method args, which are copied in later.
*/
stackPtr -= sizeof(StackSaveArea);
breakSaveBlock = (StackSaveArea*)stackPtr;
stackPtr -= method->registersSize * 4 + sizeof(StackSaveArea);
saveBlock = (StackSaveArea*) stackPtr;
#if !defined(NDEBUG) && !defined(PAD_SAVE_AREA)
/* debug -- memset the new stack */
memset(stackPtr, 0xaf, stackReq);
#endif
#ifdef EASY_GDB
if (self->curFrame == NULL)
breakSaveBlock->prevSave = NULL;
else
breakSaveBlock->prevSave = FP_FROM_SAVEAREA(self->curFrame);
saveBlock->prevSave = breakSaveBlock;
#endif
breakSaveBlock->prevFrame = self->curFrame;
breakSaveBlock->savedPc = NULL; // not required
breakSaveBlock->xtra.localRefCookie = 0; // not required
breakSaveBlock->method = NULL;
saveBlock->prevFrame = FP_FROM_SAVEAREA(breakSaveBlock);
saveBlock->savedPc = NULL; // not required
#ifdef USE_INDIRECT_REF
saveBlock->xtra.localRefCookie = self->jniLocalRefTable.segmentState.all;
#else
saveBlock->xtra.localRefCookie = self->jniLocalRefTable.nextEntry;
#endif
saveBlock->method = method;
LOGVV("PUSH JNI frame: old=%p new=%p (size=%d)\n",
self->curFrame, FP_FROM_SAVEAREA(saveBlock),
(u1*)self->curFrame - (u1*)FP_FROM_SAVEAREA(saveBlock));
self->curFrame = FP_FROM_SAVEAREA(saveBlock);
return true;
}
/*
* This is used by the JNI PushLocalFrame call. We push a new frame onto
* the stack that has no ins, outs, or locals, and no break frame above it.
* It's strictly used for tracking JNI local refs, and will be popped off
* by dvmPopFrame if it's not removed explicitly.
*/
bool dvmPushLocalFrame(Thread* self, const Method* method)
{
StackSaveArea* saveBlock;
int stackReq;
u1* stackPtr;
assert(dvmIsNativeMethod(method));
stackReq = sizeof(StackSaveArea); // regular frame
assert(self->curFrame != NULL);
stackPtr = (u1*) SAVEAREA_FROM_FP(self->curFrame);
if (stackPtr - stackReq < self->interpStackEnd) {
/* not enough space; let JNI throw the exception */
LOGW("Stack overflow on PushLocal "
"(req=%d top=%p cur=%p size=%d '%s')\n",
stackReq, self->interpStackStart, self->curFrame,
self->interpStackSize, method->name);
dvmHandleStackOverflow(self, method);
assert(dvmCheckException(self));
return false;
}
/*
* Shift the stack pointer down, leaving space for just the stack save
* area for the break frame, then shift down farther for the full frame.
*/
stackPtr -= sizeof(StackSaveArea);
saveBlock = (StackSaveArea*) stackPtr;
#if !defined(NDEBUG) && !defined(PAD_SAVE_AREA)
/* debug -- memset the new stack */
memset(stackPtr, 0xaf, stackReq);
#endif
#ifdef EASY_GDB
saveBlock->prevSave = FP_FROM_SAVEAREA(self->curFrame);
#endif
saveBlock->prevFrame = self->curFrame;
saveBlock->savedPc = NULL; // not required
#ifdef USE_INDIRECT_REF
saveBlock->xtra.localRefCookie = self->jniLocalRefTable.segmentState.all;
#else
saveBlock->xtra.localRefCookie = self->jniLocalRefTable.nextEntry;
#endif
saveBlock->method = method;
LOGVV("PUSH JNI local frame: old=%p new=%p (size=%d)\n",
self->curFrame, FP_FROM_SAVEAREA(saveBlock),
(u1*)self->curFrame - (u1*)FP_FROM_SAVEAREA(saveBlock));
self->curFrame = FP_FROM_SAVEAREA(saveBlock);
return true;
}
/*
* Pop one frame pushed on by JNI PushLocalFrame.
*
* If we've gone too far, the previous frame is either a break frame or
* an interpreted frame. Either way, the method pointer won't match.
*/
bool dvmPopLocalFrame(Thread* self)
{
StackSaveArea* saveBlock = SAVEAREA_FROM_FP(self->curFrame);
assert(!dvmIsBreakFrame(self->curFrame));
if (saveBlock->method != SAVEAREA_FROM_FP(saveBlock->prevFrame)->method) {
/*
* The previous frame doesn't have the same method pointer -- we've
* been asked to pop too much.
*/
assert(dvmIsBreakFrame(saveBlock->prevFrame) ||
!dvmIsNativeMethod(
SAVEAREA_FROM_FP(saveBlock->prevFrame)->method));
return false;
}
LOGVV("POP JNI local frame: removing %s, now %s\n",
saveBlock->method->name,
SAVEAREA_FROM_FP(saveBlock->prevFrame)->method->name);
dvmPopJniLocals(self, saveBlock);
self->curFrame = saveBlock->prevFrame;
return true;
}
/*
* Pop a frame we added. There should be one method frame and one break
* frame.
*
* If JNI Push/PopLocalFrame calls were mismatched, we might end up
* popping multiple method frames before we find the break.
*
* Returns "false" if there was no frame to pop.
*/
static bool dvmPopFrame(Thread* self)
{
StackSaveArea* saveBlock;
if (self->curFrame == NULL)
return false;
saveBlock = SAVEAREA_FROM_FP(self->curFrame);
assert(!dvmIsBreakFrame(self->curFrame));
/*
* Remove everything up to the break frame. If this was a call into
* native code, pop the JNI local references table.
*/
while (saveBlock->prevFrame != NULL && saveBlock->method != NULL) {
/* probably a native->native JNI call */
if (dvmIsNativeMethod(saveBlock->method)) {
LOGVV("Popping JNI stack frame for %s.%s%s\n",
saveBlock->method->clazz->descriptor,
saveBlock->method->name,
(SAVEAREA_FROM_FP(saveBlock->prevFrame)->method == NULL) ?
"" : " (JNI local)");
assert(saveBlock->xtra.localRefCookie != 0);
//assert(saveBlock->xtra.localRefCookie >= self->jniLocalRefTable.table &&
// saveBlock->xtra.localRefCookie <=self->jniLocalRefTable.nextEntry);
dvmPopJniLocals(self, saveBlock);
}
saveBlock = SAVEAREA_FROM_FP(saveBlock->prevFrame);
}
if (saveBlock->method != NULL) {
LOGE("PopFrame missed the break\n");
assert(false);
dvmAbort(); // stack trashed -- nowhere to go in this thread
}
LOGVV("POP frame: cur=%p new=%p\n",
self->curFrame, saveBlock->prevFrame);
self->curFrame = saveBlock->prevFrame;
return true;
}
/*
* Common code for dvmCallMethodV/A and dvmInvokeMethod.
*
* Pushes a call frame on, advancing self->curFrame.
*/
static ClassObject* callPrep(Thread* self, const Method* method, Object* obj,
bool checkAccess)
{
ClassObject* clazz;
#ifndef NDEBUG
if (self->status != THREAD_RUNNING) {
LOGW("threadid=%d: status=%d on call to %s.%s -\n",
self->threadId, self->status,
method->clazz->descriptor, method->name);
}
#endif
assert(self != NULL);
assert(method != NULL);
if (obj != NULL)
clazz = obj->clazz;
else
clazz = method->clazz;
IF_LOGVV() {
char* desc = dexProtoCopyMethodDescriptor(&method->prototype);
LOGVV("thread=%d native code calling %s.%s %s\n", self->threadId,
clazz->descriptor, method->name, desc);
free(desc);
}
if (checkAccess) {
/* needed for java.lang.reflect.Method.invoke */
if (!dvmCheckMethodAccess(dvmGetCaller2Class(self->curFrame),
method))
{
/* note this throws IAException, not IAError */
dvmThrowException("Ljava/lang/IllegalAccessException;",
"access to method denied");
return NULL;
}
}
/*
* Push a call frame on. If there isn't enough room for ins, locals,
* outs, and the saved state, it will throw an exception.
*
* This updates self->curFrame.
*/
if (dvmIsNativeMethod(method)) {
/* native code calling native code the hard way */
if (!dvmPushJNIFrame(self, method)) {
assert(dvmCheckException(self));
return NULL;
}
} else {
/* native code calling interpreted code */
if (!dvmPushInterpFrame(self, method)) {
assert(dvmCheckException(self));
return NULL;
}
}
return clazz;
}
/*
* Issue a method call.
*
* Pass in NULL for "obj" on calls to static methods.
*
* (Note this can't be inlined because it takes a variable number of args.)
*/
void dvmCallMethod(Thread* self, const Method* method, Object* obj,
JValue* pResult, ...)
{
JValue result;
va_list args;
va_start(args, pResult);
dvmCallMethodV(self, method, obj, false, pResult, args);
va_end(args);
}
/*
* Issue a method call with a variable number of arguments. We process
* the contents of "args" by scanning the method signature.
*
* Pass in NULL for "obj" on calls to static methods.
*
* We don't need to take the class as an argument because, in Dalvik,
* we don't need to worry about static synchronized methods.
*/
void dvmCallMethodV(Thread* self, const Method* method, Object* obj,
bool fromJni, JValue* pResult, va_list args)
{
const char* desc = &(method->shorty[1]); // [0] is the return type.
int verifyCount = 0;
ClassObject* clazz;
u4* ins;
clazz = callPrep(self, method, obj, false);
if (clazz == NULL)
return;
/* "ins" for new frame start at frame pointer plus locals */
ins = ((u4*)self->curFrame) + (method->registersSize - method->insSize);
//LOGD(" FP is %p, INs live at >= %p\n", self->curFrame, ins);
/* put "this" pointer into in0 if appropriate */
if (!dvmIsStaticMethod(method)) {
#ifdef WITH_EXTRA_OBJECT_VALIDATION
assert(obj != NULL && dvmIsValidObject(obj));
#endif
*ins++ = (u4) obj;
verifyCount++;
}
JNIEnv* env = self->jniEnv;
while (*desc != '\0') {
switch (*(desc++)) {
case 'D': case 'J': {
u8 val = va_arg(args, u8);
memcpy(ins, &val, 8); // EABI prevents direct store
ins += 2;
verifyCount += 2;
break;
}
case 'F': {
/* floats were normalized to doubles; convert back */
float f = (float) va_arg(args, double);
*ins++ = dvmFloatToU4(f);
verifyCount++;
break;
}
case 'L': { /* 'shorty' descr uses L for all refs, incl array */
void* argObj = va_arg(args, void*);
assert(obj == NULL || dvmIsValidObject(obj));
if (fromJni)
*ins++ = (u4) dvmDecodeIndirectRef(env, argObj);
else
*ins++ = (u4) argObj;
verifyCount++;
break;
}
default: {
/* Z B C S I -- all passed as 32-bit integers */
*ins++ = va_arg(args, u4);
verifyCount++;
break;
}
}
}
#ifndef NDEBUG
if (verifyCount != method->insSize) {
LOGE("Got vfycount=%d insSize=%d for %s.%s\n", verifyCount,
method->insSize, clazz->descriptor, method->name);
assert(false);
goto bail;
}
#endif
//dvmDumpThreadStack(dvmThreadSelf());
if (dvmIsNativeMethod(method)) {
#ifdef WITH_PROFILER
TRACE_METHOD_ENTER(self, method);
#endif
/*
* Because we leave no space for local variables, "curFrame" points
* directly at the method arguments.
*/
(*method->nativeFunc)(self->curFrame, pResult, method, self);
#ifdef WITH_PROFILER
TRACE_METHOD_EXIT(self, method);
#endif
} else {
dvmInterpret(self, method, pResult);
}
bail:
dvmPopFrame(self);
}
/*
* Issue a method call with arguments provided in an array. We process
* the contents of "args" by scanning the method signature.
*
* The values were likely placed into an uninitialized jvalue array using
* the field specifiers, which means that sub-32-bit fields (e.g. short,
* boolean) may not have 32 or 64 bits of valid data. This is different
* from the varargs invocation where the C compiler does a widening
* conversion when calling a function. As a result, we have to be a
* little more precise when pulling stuff out.
*
* "args" may be NULL if the method has no arguments.
*/
void dvmCallMethodA(Thread* self, const Method* method, Object* obj,
bool fromJni, JValue* pResult, const jvalue* args)
{
const char* desc = &(method->shorty[1]); // [0] is the return type.
int verifyCount = 0;
ClassObject* clazz;
u4* ins;
clazz = callPrep(self, method, obj, false);
if (clazz == NULL)
return;
/* "ins" for new frame start at frame pointer plus locals */
ins = ((u4*)self->curFrame) + (method->registersSize - method->insSize);
/* put "this" pointer into in0 if appropriate */
if (!dvmIsStaticMethod(method)) {
assert(obj != NULL);
*ins++ = (u4) obj; /* obj is a "real" ref */
verifyCount++;
}
JNIEnv* env = self->jniEnv;
while (*desc != '\0') {
switch (*desc++) {
case 'D': /* 64-bit quantity; have to use */
case 'J': /* memcpy() in case of mis-alignment */
memcpy(ins, &args->j, 8);
ins += 2;
verifyCount++; /* this needs an extra push */
break;
case 'L': /* includes array refs */
if (fromJni)
*ins++ = (u4) dvmDecodeIndirectRef(env, args->l);
else
*ins++ = (u4) args->l;
break;
case 'F':
case 'I':
*ins++ = args->i; /* full 32 bits */
break;
case 'S':
*ins++ = args->s; /* 16 bits, sign-extended */
break;
case 'C':
*ins++ = args->c; /* 16 bits, unsigned */
break;
case 'B':
*ins++ = args->b; /* 8 bits, sign-extended */
break;
case 'Z':
*ins++ = args->z; /* 8 bits, zero or non-zero */
break;
default:
LOGE("Invalid char %c in short signature of %s.%s\n",
*(desc-1), clazz->descriptor, method->name);
assert(false);
goto bail;
}
verifyCount++;
args++;
}
#ifndef NDEBUG
if (verifyCount != method->insSize) {
LOGE("Got vfycount=%d insSize=%d for %s.%s\n", verifyCount,
method->insSize, clazz->descriptor, method->name);
assert(false);
goto bail;
}
#endif
if (dvmIsNativeMethod(method)) {
#ifdef WITH_PROFILER
TRACE_METHOD_ENTER(self, method);
#endif
/*
* Because we leave no space for local variables, "curFrame" points
* directly at the method arguments.
*/
(*method->nativeFunc)(self->curFrame, pResult, method, self);
#ifdef WITH_PROFILER
TRACE_METHOD_EXIT(self, method);
#endif
} else {
dvmInterpret(self, method, pResult);
}
bail:
dvmPopFrame(self);
}
/*
* Invoke a method, using the specified arguments and return type, through
* one of the reflection interfaces. Could be a virtual or direct method
* (including constructors). Used for reflection.
*
* Deals with boxing/unboxing primitives and performs widening conversions.
*
* "invokeObj" will be null for a static method.
*
* If the invocation returns with an exception raised, we have to wrap it.
*/
Object* dvmInvokeMethod(Object* obj, const Method* method,
ArrayObject* argList, ArrayObject* params, ClassObject* returnType,
bool noAccessCheck)
{
ClassObject* clazz;
Object* retObj = NULL;
Thread* self = dvmThreadSelf();
s4* ins;
int verifyCount, argListLength;
JValue retval;
/* verify arg count */
if (argList != NULL)
argListLength = argList->length;
else
argListLength = 0;
if (argListLength != (int) params->length) {
LOGI("invoke: expected %d args, received %d args\n",
params->length, argListLength);
dvmThrowException("Ljava/lang/IllegalArgumentException;",
"wrong number of arguments");
return NULL;
}
clazz = callPrep(self, method, obj, !noAccessCheck);
if (clazz == NULL)
return NULL;
/* "ins" for new frame start at frame pointer plus locals */
ins = ((s4*)self->curFrame) + (method->registersSize - method->insSize);
verifyCount = 0;
//LOGD(" FP is %p, INs live at >= %p\n", self->curFrame, ins);
/* put "this" pointer into in0 if appropriate */
if (!dvmIsStaticMethod(method)) {
assert(obj != NULL);
*ins++ = (s4) obj;
verifyCount++;
}
/*
* Copy the args onto the stack. Primitive types are converted when
* necessary, and object types are verified.
*/
DataObject** args;
ClassObject** types;
int i;
args = (DataObject**) argList->contents;
types = (ClassObject**) params->contents;
for (i = 0; i < argListLength; i++) {
int width;
width = dvmConvertArgument(*args++, *types++, ins);
if (width < 0) {
if (*(args-1) != NULL) {
LOGV("invoke: type mismatch on arg %d ('%s' '%s')\n",
i, (*(args-1))->obj.clazz->descriptor,
(*(types-1))->descriptor);
}
dvmPopFrame(self); // throw wants to pull PC out of stack
dvmThrowException("Ljava/lang/IllegalArgumentException;",
"argument type mismatch");
goto bail_popped;
}
ins += width;
verifyCount += width;
}
if (verifyCount != method->insSize) {
LOGE("Got vfycount=%d insSize=%d for %s.%s\n", verifyCount,
method->insSize, clazz->descriptor, method->name);
assert(false);
goto bail;
}
//dvmDumpThreadStack(dvmThreadSelf());
if (dvmIsNativeMethod(method)) {
#ifdef WITH_PROFILER
TRACE_METHOD_ENTER(self, method);
#endif
/*
* Because we leave no space for local variables, "curFrame" points
* directly at the method arguments.
*/
(*method->nativeFunc)(self->curFrame, &retval, method, self);
#ifdef WITH_PROFILER
TRACE_METHOD_EXIT(self, method);
#endif
} else {
dvmInterpret(self, method, &retval);
}
/*
* If an exception is raised, wrap and replace. This is necessary
* because the invoked method could have thrown a checked exception
* that the caller wasn't prepared for.
*
* We might be able to do this up in the interpreted code, but that will
* leave us with a shortened stack trace in the top-level exception.
*/
if (dvmCheckException(self)) {
dvmWrapException("Ljava/lang/reflect/InvocationTargetException;");
} else {
/*
* If this isn't a void method or constructor, convert the return type
* to an appropriate object.
*
* We don't do this when an exception is raised because the value
* in "retval" is undefined.
*/
if (returnType != NULL) {
retObj = (Object*)dvmWrapPrimitive(retval, returnType);
dvmReleaseTrackedAlloc(retObj, NULL);
}
}
bail:
dvmPopFrame(self);
bail_popped:
return retObj;
}
typedef struct LineNumFromPcContext {
u4 address;
u4 lineNum;
} LineNumFromPcContext;
static int lineNumForPcCb(void *cnxt, u4 address, u4 lineNum)
{
LineNumFromPcContext *pContext = (LineNumFromPcContext *)cnxt;
// We know that this callback will be called in
// ascending address order, so keep going until we find
// a match or we've just gone past it.
if (address > pContext->address) {
// The line number from the previous positions callback
// wil be the final result.
return 1;
}
pContext->lineNum = lineNum;
return (address == pContext->address) ? 1 : 0;
}
/*
* Determine the source file line number based on the program counter.
* "pc" is an offset, in 16-bit units, from the start of the method's code.
*
* Returns -1 if no match was found (possibly because the source files were
* compiled without "-g", so no line number information is present).
* Returns -2 for native methods (as expected in exception traces).
*/
int dvmLineNumFromPC(const Method* method, u4 relPc)
{
const DexCode* pDexCode = dvmGetMethodCode(method);
if (pDexCode == NULL) {
if (dvmIsNativeMethod(method) && !dvmIsAbstractMethod(method))
return -2;
return -1; /* can happen for abstract method stub */
}
LineNumFromPcContext context;
memset(&context, 0, sizeof(context));
context.address = relPc;
// A method with no line number info should return -1
context.lineNum = -1;
dexDecodeDebugInfo(method->clazz->pDvmDex->pDexFile, pDexCode,
method->clazz->descriptor,
method->prototype.protoIdx,
method->accessFlags,
lineNumForPcCb, NULL, &context);
return context.lineNum;
}
/*
* Compute the frame depth.
*
* Excludes "break" frames.
*/
int dvmComputeExactFrameDepth(const void* fp)
{
int count = 0;
for ( ; fp != NULL; fp = SAVEAREA_FROM_FP(fp)->prevFrame) {
if (!dvmIsBreakFrame(fp))
count++;
}
return count;
}
/*
* Compute the "vague" frame depth, which is just a pointer subtraction.
* The result is NOT an overly generous assessment of the number of
* frames; the only meaningful use is to compare against the result of
* an earlier invocation.
*
* Useful for implementing single-step debugger modes, which may need to
* call this for every instruction.
*/
int dvmComputeVagueFrameDepth(Thread* thread, const void* fp)
{
const u1* interpStackStart = thread->interpStackStart;
const u1* interpStackBottom = interpStackStart - thread->interpStackSize;
assert((u1*) fp >= interpStackBottom && (u1*) fp < interpStackStart);
return interpStackStart - (u1*) fp;
}
/*
* Get the calling frame. Pass in the current fp.
*
* Skip "break" frames and reflection invoke frames.
*/
void* dvmGetCallerFP(const void* curFrame)
{
void* caller = SAVEAREA_FROM_FP(curFrame)->prevFrame;
StackSaveArea* saveArea;
retry:
if (dvmIsBreakFrame(caller)) {
/* pop up one more */
caller = SAVEAREA_FROM_FP(caller)->prevFrame;
if (caller == NULL)
return NULL; /* hit the top */
/*
* If we got here by java.lang.reflect.Method.invoke(), we don't
* want to return Method's class loader. Shift up one and try
* again.
*/
saveArea = SAVEAREA_FROM_FP(caller);
if (dvmIsReflectionMethod(saveArea->method)) {
caller = saveArea->prevFrame;
assert(caller != NULL);
goto retry;
}
}
return caller;
}
/*
* Get the caller's class. Pass in the current fp.
*
* This is used by e.g. java.lang.Class.
*/
ClassObject* dvmGetCallerClass(const void* curFrame)
{
void* caller;
caller = dvmGetCallerFP(curFrame);
if (caller == NULL)
return NULL;
return SAVEAREA_FROM_FP(caller)->method->clazz;
}
/*
* Get the caller's caller's class. Pass in the current fp.
*
* This is used by e.g. java.lang.Class, which wants to know about the
* class loader of the method that called it.
*/
ClassObject* dvmGetCaller2Class(const void* curFrame)
{
void* caller = SAVEAREA_FROM_FP(curFrame)->prevFrame;
void* callerCaller;
/* at the top? */
if (dvmIsBreakFrame(caller) && SAVEAREA_FROM_FP(caller)->prevFrame == NULL)
return NULL;
/* go one more */
callerCaller = dvmGetCallerFP(caller);
if (callerCaller == NULL)
return NULL;
return SAVEAREA_FROM_FP(callerCaller)->method->clazz;
}
/*
* Get the caller's caller's caller's class. Pass in the current fp.
*
* This is used by e.g. java.lang.Class, which wants to know about the
* class loader of the method that called it.
*/
ClassObject* dvmGetCaller3Class(const void* curFrame)
{
void* caller = SAVEAREA_FROM_FP(curFrame)->prevFrame;
int i;
/* at the top? */
if (dvmIsBreakFrame(caller) && SAVEAREA_FROM_FP(caller)->prevFrame == NULL)
return NULL;
/* Walk up two frames if possible. */
for (i = 0; i < 2; i++) {
caller = dvmGetCallerFP(caller);
if (caller == NULL)
return NULL;
}
return SAVEAREA_FROM_FP(caller)->method->clazz;
}
/*
* Create a flat array of methods that comprise the current interpreter
* stack trace. Pass in the current frame ptr.
*
* Allocates a new array and fills it with method pointers. Break frames
* are skipped, but reflection invocations are not. The caller must free
* "*pArray".
*
* The current frame will be in element 0.
*
* Returns "true" on success, "false" on failure (e.g. malloc failed).
*/
bool dvmCreateStackTraceArray(const void* fp, const Method*** pArray,
int* pLength)
{
const Method** array;
int idx, depth;
depth = dvmComputeExactFrameDepth(fp);
array = (const Method**) malloc(depth * sizeof(Method*));
if (array == NULL)
return false;
for (idx = 0; fp != NULL; fp = SAVEAREA_FROM_FP(fp)->prevFrame) {
if (!dvmIsBreakFrame(fp))
array[idx++] = SAVEAREA_FROM_FP(fp)->method;
}
assert(idx == depth);
*pArray = array;
*pLength = depth;
return true;
}
/*
* Open up the reserved area and throw an exception. The reserved area
* should only be needed to create and initialize the exception itself.
*
* If we already opened it and we're continuing to overflow, abort the VM.
*
* We have to leave the "reserved" area open until the "catch" handler has
* finished doing its processing. This is because the catch handler may
* need to resolve classes, which requires calling into the class loader if
* the classes aren't already in the "initiating loader" list.
*/
void dvmHandleStackOverflow(Thread* self, const Method* method)
{
/*
* Can we make the reserved area available?
*/
if (self->stackOverflowed) {
/*
* Already did, nothing to do but bail.
*/
LOGE("DalvikVM: double-overflow of stack in threadid=%d; aborting\n",
self->threadId);
dvmDumpThread(self, false);
dvmAbort();
}
/* open it up to the full range */
LOGI("threadid=%d: stack overflow on call to %s.%s:%s\n",
self->threadId,
method->clazz->descriptor, method->name, method->shorty);
StackSaveArea* saveArea = SAVEAREA_FROM_FP(self->curFrame);
LOGI(" method requires %d+%d+%d=%d bytes, fp is %p (%d left)\n",
method->registersSize * 4, sizeof(StackSaveArea), method->outsSize * 4,
(method->registersSize + method->outsSize) * 4 + sizeof(StackSaveArea),
saveArea, (u1*) saveArea - self->interpStackEnd);
LOGI(" expanding stack end (%p to %p)\n", self->interpStackEnd,
self->interpStackStart - self->interpStackSize);
//dvmDumpThread(self, false);
self->interpStackEnd = self->interpStackStart - self->interpStackSize;
self->stackOverflowed = true;
/*
* If we were trying to throw an exception when the stack overflowed,
* we will blow up when doing the class lookup on StackOverflowError
* because of the pending exception. So, we clear it and make it
* the cause of the SOE.
*/
Object* excep = dvmGetException(self);
if (excep != NULL) {
LOGW("Stack overflow while throwing exception\n");
dvmClearException(self);
}
dvmThrowChainedExceptionByClass(gDvm.classJavaLangStackOverflowError,
NULL, excep);
}
/*
* Reduce the available stack size. By this point we should have finished
* our overflow processing.
*/
void dvmCleanupStackOverflow(Thread* self, const Object* exception)
{
const u1* newStackEnd;
assert(self->stackOverflowed);
if (exception->clazz != gDvm.classJavaLangStackOverflowError) {
/* exception caused during SOE, not the SOE itself */
return;
}
newStackEnd = (self->interpStackStart - self->interpStackSize)
+ STACK_OVERFLOW_RESERVE;
if ((u1*)self->curFrame <= newStackEnd) {
LOGE("Can't shrink stack: curFrame is in reserved area (%p %p)\n",
self->interpStackEnd, self->curFrame);
dvmDumpThread(self, false);
dvmAbort();
}
self->interpStackEnd = newStackEnd;
self->stackOverflowed = false;
LOGI("Shrank stack (to %p, curFrame is %p)\n", self->interpStackEnd,
self->curFrame);
}
/*
* Dump stack frames, starting from the specified frame and moving down.
*
* Each frame holds a pointer to the currently executing method, and the
* saved program counter from the caller ("previous" frame). This means
* we don't have the PC for the current method on the stack, which is
* pretty reasonable since it's in the "PC register" for the VM. Because
* exceptions need to show the correct line number we actually *do* have
* an updated version in the fame's "xtra.currentPc", but it's unreliable.
*
* Note "framePtr" could be NULL in rare circumstances.
*/
static void dumpFrames(const DebugOutputTarget* target, void* framePtr,
Thread* thread)
{
const StackSaveArea* saveArea;
const Method* method;
int checkCount = 0;
const u2* currentPc = NULL;
bool first = true;
/*
* The "currentPc" is updated whenever we execute an instruction that
* might throw an exception. Show it here.
*/
if (framePtr != NULL && !dvmIsBreakFrame(framePtr)) {
saveArea = SAVEAREA_FROM_FP(framePtr);
if (saveArea->xtra.currentPc != NULL)
currentPc = saveArea->xtra.currentPc;
}
while (framePtr != NULL) {
saveArea = SAVEAREA_FROM_FP(framePtr);
method = saveArea->method;
if (dvmIsBreakFrame(framePtr)) {
//dvmPrintDebugMessage(target, " (break frame)\n");
} else {
int relPc;
if (currentPc != NULL)
relPc = currentPc - saveArea->method->insns;
else
relPc = -1;
char* className = dvmDescriptorToDot(method->clazz->descriptor);
if (dvmIsNativeMethod(method))
dvmPrintDebugMessage(target,
" at %s.%s(Native Method)\n", className, method->name);
else {
dvmPrintDebugMessage(target,
" at %s.%s(%s:%s%d)\n",
className, method->name, dvmGetMethodSourceFile(method),
(relPc >= 0 && first) ? "~" : "",
relPc < 0 ? -1 : dvmLineNumFromPC(method, relPc));
}
free(className);
if (first &&
(thread->status == THREAD_WAIT ||
thread->status == THREAD_TIMED_WAIT))
{
/* warning: wait status not stable, even in suspend */
Monitor* mon = thread->waitMonitor;
Object* obj = dvmGetMonitorObject(mon);
if (obj != NULL) {
className = dvmDescriptorToDot(obj->clazz->descriptor);
dvmPrintDebugMessage(target,
" - waiting on <%p> (a %s)\n", mon, className);
free(className);
}
}
}
/*
* Get saved PC for previous frame. There's no savedPc in a "break"
* frame, because that represents native or interpreted code
* invoked by the VM. The saved PC is sitting in the "PC register",
* a local variable on the native stack.
*/
currentPc = saveArea->savedPc;
first = false;
if (saveArea->prevFrame != NULL && saveArea->prevFrame <= framePtr) {
LOGW("Warning: loop in stack trace at frame %d (%p -> %p)\n",
checkCount, framePtr, saveArea->prevFrame);
break;
}
framePtr = saveArea->prevFrame;
checkCount++;
if (checkCount > 300) {
dvmPrintDebugMessage(target,
" ***** printed %d frames, not showing any more\n",
checkCount);
break;
}
}
dvmPrintDebugMessage(target, "\n");
}
/*
* Dump the stack for the specified thread.
*/
void dvmDumpThreadStack(const DebugOutputTarget* target, Thread* thread)
{
dumpFrames(target, thread->curFrame, thread);
}
/*
* Dump the stack for the specified thread, which is still running.
*
* This is very dangerous, because stack frames are being pushed on and
* popped off, and if the thread exits we'll be looking at freed memory.
* The plan here is to take a snapshot of the stack and then dump that
* to try to minimize the chances of catching it mid-update. This should
* work reasonably well on a single-CPU system.
*
* There is a small chance that calling here will crash the VM.
*/
void dvmDumpRunningThreadStack(const DebugOutputTarget* target, Thread* thread)
{
StackSaveArea* saveArea;
const u1* origStack;
u1* stackCopy = NULL;
int origSize, fpOffset;
void* fp;
int depthLimit = 200;
if (thread == NULL || thread->curFrame == NULL) {
dvmPrintDebugMessage(target,
"DumpRunning: Thread at %p has no curFrame (threadid=%d)\n",
thread, (thread != NULL) ? thread->threadId : 0);
return;
}
/* wait for a full quantum */
sched_yield();
/* copy the info we need, then the stack itself */
origSize = thread->interpStackSize;
origStack = (const u1*) thread->interpStackStart - origSize;
stackCopy = (u1*) malloc(origSize);
fpOffset = (u1*) thread->curFrame - origStack;
memcpy(stackCopy, origStack, origSize);
/*
* Run through the stack and rewrite the "prev" pointers.
*/
//LOGI("DR: fpOff=%d (from %p %p)\n",fpOffset, origStack, thread->curFrame);
fp = stackCopy + fpOffset;
while (true) {
int prevOffset;
if (depthLimit-- < 0) {
/* we're probably screwed */
dvmPrintDebugMessage(target, "DumpRunning: depth limit hit\n");
dvmAbort();
}
saveArea = SAVEAREA_FROM_FP(fp);
if (saveArea->prevFrame == NULL)
break;
prevOffset = (u1*) saveArea->prevFrame - origStack;
if (prevOffset < 0 || prevOffset > origSize) {
dvmPrintDebugMessage(target,
"DumpRunning: bad offset found: %d (from %p %p)\n",
prevOffset, origStack, saveArea->prevFrame);
saveArea->prevFrame = NULL;
break;
}
saveArea->prevFrame = stackCopy + prevOffset;
fp = saveArea->prevFrame;
}
/*
* We still need to pass the Thread for some monitor wait stuff.
*/
dumpFrames(target, stackCopy + fpOffset, thread);
free(stackCopy);
}