/*
* 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.
*/
/*
* Operations on an Object.
*/
#include "Dalvik.h"
/*
* Find a matching field, in the current class only.
*
* Returns NULL if the field can't be found. (Does not throw an exception.)
*/
InstField* dvmFindInstanceField(const ClassObject* clazz,
const char* fieldName, const char* signature)
{
InstField* pField;
int i;
assert(clazz != NULL);
/*
* Find a field with a matching name and signature. The Java programming
* language does not allow you to have two fields with the same name
* and different types, but the Java VM spec does allow it, so we can't
* bail out early when the name matches.
*/
pField = clazz->ifields;
for (i = 0; i < clazz->ifieldCount; i++, pField++) {
if (strcmp(fieldName, pField->name) == 0 &&
strcmp(signature, pField->signature) == 0)
{
return pField;
}
}
return NULL;
}
/*
* Find a matching field, in this class or a superclass.
*
* Searching through interfaces isn't necessary, because interface fields
* are inherently public/static/final.
*
* Returns NULL if the field can't be found. (Does not throw an exception.)
*/
InstField* dvmFindInstanceFieldHier(const ClassObject* clazz,
const char* fieldName, const char* signature)
{
InstField* pField;
/*
* Search for a match in the current class.
*/
pField = dvmFindInstanceField(clazz, fieldName, signature);
if (pField != NULL)
return pField;
if (clazz->super != NULL)
return dvmFindInstanceFieldHier(clazz->super, fieldName, signature);
else
return NULL;
}
/*
* Find a matching field, in this class or an interface.
*
* Returns NULL if the field can't be found. (Does not throw an exception.)
*/
StaticField* dvmFindStaticField(const ClassObject* clazz,
const char* fieldName, const char* signature)
{
const StaticField* pField;
int i;
assert(clazz != NULL);
/*
* Find a field with a matching name and signature. As with instance
* fields, the VM allows you to have two fields with the same name so
* long as they have different types.
*/
pField = &clazz->sfields[0];
for (i = 0; i < clazz->sfieldCount; i++, pField++) {
if (strcmp(fieldName, pField->name) == 0 &&
strcmp(signature, pField->signature) == 0)
{
return (StaticField*) pField;
}
}
return NULL;
}
/*
* Find a matching field, in this class or a superclass.
*
* Returns NULL if the field can't be found. (Does not throw an exception.)
*/
StaticField* dvmFindStaticFieldHier(const ClassObject* clazz,
const char* fieldName, const char* signature)
{
StaticField* pField;
/*
* Search for a match in the current class.
*/
pField = dvmFindStaticField(clazz, fieldName, signature);
if (pField != NULL)
return pField;
/*
* See if it's in any of our interfaces. We don't check interfaces
* inherited from the superclass yet.
*
* (Note the set may have been stripped down because of redundancy with
* the superclass; see notes in createIftable.)
*/
int i = 0;
if (clazz->super != NULL) {
assert(clazz->iftableCount >= clazz->super->iftableCount);
i = clazz->super->iftableCount;
}
for ( ; i < clazz->iftableCount; i++) {
ClassObject* iface = clazz->iftable[i].clazz;
pField = dvmFindStaticField(iface, fieldName, signature);
if (pField != NULL)
return pField;
}
if (clazz->super != NULL)
return dvmFindStaticFieldHier(clazz->super, fieldName, signature);
else
return NULL;
}
/*
* Find a matching field, in this class or a superclass.
*
* We scan both the static and instance field lists in the class. If it's
* not found there, we check the direct interfaces, and then recursively
* scan the superclasses. This is the order prescribed in the VM spec
* (v2 5.4.3.2).
*
* In most cases we know that we're looking for either a static or an
* instance field and there's no value in searching through both types.
* During verification we need to recognize and reject certain unusual
* situations, and we won't see them unless we walk the lists this way.
*/
Field* dvmFindFieldHier(const ClassObject* clazz, const char* fieldName,
const char* signature)
{
Field* pField;
/*
* Search for a match in the current class. Which set we scan first
* doesn't really matter.
*/
pField = (Field*) dvmFindStaticField(clazz, fieldName, signature);
if (pField != NULL)
return pField;
pField = (Field*) dvmFindInstanceField(clazz, fieldName, signature);
if (pField != NULL)
return pField;
/*
* See if it's in any of our interfaces. We don't check interfaces
* inherited from the superclass yet.
*/
int i = 0;
if (clazz->super != NULL) {
assert(clazz->iftableCount >= clazz->super->iftableCount);
i = clazz->super->iftableCount;
}
for ( ; i < clazz->iftableCount; i++) {
ClassObject* iface = clazz->iftable[i].clazz;
pField = (Field*) dvmFindStaticField(iface, fieldName, signature);
if (pField != NULL)
return pField;
}
if (clazz->super != NULL)
return dvmFindFieldHier(clazz->super, fieldName, signature);
else
return NULL;
}
/*
* Compare the given name, return type, and argument types with the contents
* of the given method. This returns 0 if they are equal and non-zero if not.
*/
static inline int compareMethodHelper(Method* method, const char* methodName,
const char* returnType, size_t argCount, const char** argTypes)
{
DexParameterIterator iterator;
const DexProto* proto;
if (strcmp(methodName, method->name) != 0) {
return 1;
}
proto = &method->prototype;
if (strcmp(returnType, dexProtoGetReturnType(proto)) != 0) {
return 1;
}
if (dexProtoGetParameterCount(proto) != argCount) {
return 1;
}
dexParameterIteratorInit(&iterator, proto);
for (/*argCount*/; argCount != 0; argCount--, argTypes++) {
const char* argType = *argTypes;
const char* paramType = dexParameterIteratorNextDescriptor(&iterator);
if (paramType == NULL) {
/* Param list ended early; no match */
break;
} else if (strcmp(argType, paramType) != 0) {
/* Types aren't the same; no match. */
break;
}
}
if (argCount == 0) {
/* We ran through all the given arguments... */
if (dexParameterIteratorNextDescriptor(&iterator) == NULL) {
/* ...and through all the method's arguments; success! */
return 0;
}
}
return 1;
}
/*
* Get the count of arguments in the given method descriptor string,
* and also find a pointer to the return type.
*/
static inline size_t countArgsAndFindReturnType(const char* descriptor,
const char** pReturnType)
{
size_t count = 0;
bool bogus = false;
bool done = false;
assert(*descriptor == '(');
descriptor++;
while (!done) {
switch (*descriptor) {
case 'B': case 'C': case 'D': case 'F':
case 'I': case 'J': case 'S': case 'Z': {
count++;
break;
}
case '[': {
do {
descriptor++;
} while (*descriptor == '[');
/*
* Don't increment count, as it will be taken care of
* by the next iteration. Also, decrement descriptor
* to compensate for the increment below the switch.
*/
descriptor--;
break;
}
case 'L': {
do {
descriptor++;
} while ((*descriptor != ';') && (*descriptor != '\0'));
count++;
if (*descriptor == '\0') {
/* Bogus descriptor. */
done = true;
bogus = true;
}
break;
}
case ')': {
/*
* Note: The loop will exit after incrementing descriptor
* one more time, so it then points at the return type.
*/
done = true;
break;
}
default: {
/* Bogus descriptor. */
done = true;
bogus = true;
break;
}
}
descriptor++;
}
if (bogus) {
*pReturnType = NULL;
return 0;
}
*pReturnType = descriptor;
return count;
}
/*
* Copy the argument types into the given array using the given buffer
* for the contents.
*/
static inline void copyTypes(char* buffer, const char** argTypes,
size_t argCount, const char* descriptor)
{
size_t i;
char c;
/* Skip the '('. */
descriptor++;
for (i = 0; i < argCount; i++) {
argTypes[i] = buffer;
/* Copy all the array markers and one extra character. */
do {
c = *(descriptor++);
*(buffer++) = c;
} while (c == '[');
if (c == 'L') {
/* Copy the rest of a class name. */
do {
c = *(descriptor++);
*(buffer++) = c;
} while (c != ';');
}
*(buffer++) = '\0';
}
}
/*
* Look for a match in the given class. Returns the match if found
* or NULL if not.
*/
static Method* findMethodInListByDescriptor(const ClassObject* clazz,
bool findVirtual, bool isHier, const char* name, const char* descriptor)
{
const char* returnType;
size_t argCount = countArgsAndFindReturnType(descriptor, &returnType);
if (returnType == NULL) {
ALOGW("Bogus method descriptor: %s", descriptor);
return NULL;
}
/*
* Make buffer big enough for all the argument type characters and
* one '\0' per argument. The "- 2" is because "returnType -
* descriptor" includes two parens.
*/
char buffer[argCount + (returnType - descriptor) - 2];
const char* argTypes[argCount];
copyTypes(buffer, argTypes, argCount, descriptor);
while (clazz != NULL) {
Method* methods;
size_t methodCount;
size_t i;
if (findVirtual) {
methods = clazz->virtualMethods;
methodCount = clazz->virtualMethodCount;
} else {
methods = clazz->directMethods;
methodCount = clazz->directMethodCount;
}
for (i = 0; i < methodCount; i++) {
Method* method = &methods[i];
if (compareMethodHelper(method, name, returnType, argCount,
argTypes) == 0) {
return method;
}
}
if (! isHier) {
break;
}
clazz = clazz->super;
}
return NULL;
}
/*
* Look for a match in the given clazz. Returns the match if found
* or NULL if not.
*
* "wantedType" should be METHOD_VIRTUAL or METHOD_DIRECT to indicate the
* list to search through. If the match can come from either list, use
* MATCH_UNKNOWN to scan both.
*/
static Method* findMethodInListByProto(const ClassObject* clazz,
MethodType wantedType, bool isHier, const char* name, const DexProto* proto)
{
while (clazz != NULL) {
int i;
/*
* Check the virtual and/or direct method lists.
*/
if (wantedType == METHOD_VIRTUAL || wantedType == METHOD_UNKNOWN) {
for (i = 0; i < clazz->virtualMethodCount; i++) {
Method* method = &clazz->virtualMethods[i];
if (dvmCompareNameProtoAndMethod(name, proto, method) == 0) {
return method;
}
}
}
if (wantedType == METHOD_DIRECT || wantedType == METHOD_UNKNOWN) {
for (i = 0; i < clazz->directMethodCount; i++) {
Method* method = &clazz->directMethods[i];
if (dvmCompareNameProtoAndMethod(name, proto, method) == 0) {
return method;
}
}
}
if (! isHier) {
break;
}
clazz = clazz->super;
}
return NULL;
}
/*
* Find a "virtual" method in a class.
*
* Does not chase into the superclass.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindVirtualMethodByDescriptor(const ClassObject* clazz,
const char* methodName, const char* descriptor)
{
return findMethodInListByDescriptor(clazz, true, false,
methodName, descriptor);
// TODO? - throw IncompatibleClassChangeError if a match is
// found in the directMethods list, rather than NotFoundError.
// Note we could have been called by dvmFindVirtualMethodHier though.
}
/*
* Find a "virtual" method in a class, knowing only the name. This is
* only useful in limited circumstances, e.g. when searching for a member
* of an annotation class.
*
* Does not chase into the superclass.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindVirtualMethodByName(const ClassObject* clazz,
const char* methodName)
{
Method* methods = clazz->virtualMethods;
int methodCount = clazz->virtualMethodCount;
int i;
for (i = 0; i < methodCount; i++) {
if (strcmp(methods[i].name, methodName) == 0)
return &methods[i];
}
return NULL;
}
/*
* Find a "virtual" method in a class.
*
* Does not chase into the superclass.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindVirtualMethod(const ClassObject* clazz, const char* methodName,
const DexProto* proto)
{
return findMethodInListByProto(clazz, METHOD_VIRTUAL, false, methodName,
proto);
}
/*
* Find a "virtual" method in a class. If we don't find it, try the
* superclass. Does not examine interfaces.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindVirtualMethodHierByDescriptor(const ClassObject* clazz,
const char* methodName, const char* descriptor)
{
return findMethodInListByDescriptor(clazz, true, true,
methodName, descriptor);
}
/*
* Find a "virtual" method in a class. If we don't find it, try the
* superclass. Does not examine interfaces.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindVirtualMethodHier(const ClassObject* clazz,
const char* methodName, const DexProto* proto)
{
return findMethodInListByProto(clazz, METHOD_VIRTUAL, true, methodName,
proto);
}
/*
* Find a method in an interface. Searches superinterfaces.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindInterfaceMethodHierByDescriptor(const ClassObject* iface,
const char* methodName, const char* descriptor)
{
Method* resMethod = dvmFindVirtualMethodByDescriptor(iface,
methodName, descriptor);
if (resMethod == NULL) {
/* scan superinterfaces and superclass interfaces */
int i;
for (i = 0; i < iface->iftableCount; i++) {
resMethod = dvmFindVirtualMethodByDescriptor(iface->iftable[i].clazz,
methodName, descriptor);
if (resMethod != NULL)
break;
}
}
return resMethod;
}
/*
* Find a method in an interface. Searches superinterfaces.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindInterfaceMethodHier(const ClassObject* iface,
const char* methodName, const DexProto* proto)
{
Method* resMethod = dvmFindVirtualMethod(iface, methodName, proto);
if (resMethod == NULL) {
/* scan superinterfaces and superclass interfaces */
int i;
for (i = 0; i < iface->iftableCount; i++) {
resMethod = dvmFindVirtualMethod(iface->iftable[i].clazz,
methodName, proto);
if (resMethod != NULL)
break;
}
}
return resMethod;
}
/*
* Find a "direct" method (static, private, or "<*init>").
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindDirectMethodByDescriptor(const ClassObject* clazz,
const char* methodName, const char* descriptor)
{
return findMethodInListByDescriptor(clazz, false, false,
methodName, descriptor);
}
/*
* Find a "direct" method. If we don't find it, try the superclass. This
* is only appropriate for static methods, but will work for all direct
* methods.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindDirectMethodHierByDescriptor(const ClassObject* clazz,
const char* methodName, const char* descriptor)
{
return findMethodInListByDescriptor(clazz, false, true,
methodName, descriptor);
}
/*
* Find a "direct" method (static or "<*init>").
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindDirectMethod(const ClassObject* clazz, const char* methodName,
const DexProto* proto)
{
return findMethodInListByProto(clazz, METHOD_DIRECT, false, methodName,
proto);
}
/*
* Find a "direct" method in a class. If we don't find it, try the
* superclass.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindDirectMethodHier(const ClassObject* clazz,
const char* methodName, const DexProto* proto)
{
return findMethodInListByProto(clazz, METHOD_DIRECT, true, methodName,
proto);
}
/*
* Find a virtual or static method in a class. If we don't find it, try the
* superclass. This is compatible with the VM spec (v2 5.4.3.3) method
* search order, but it stops short of scanning through interfaces (which
* should be done after this function completes).
*
* In most cases we know that we're looking for either a static or an
* instance field and there's no value in searching through both types.
* During verification we need to recognize and reject certain unusual
* situations, and we won't see them unless we walk the lists this way.
*
* Returns NULL if the method can't be found. (Does not throw an exception.)
*/
Method* dvmFindMethodHier(const ClassObject* clazz, const char* methodName,
const DexProto* proto)
{
return findMethodInListByProto(clazz, METHOD_UNKNOWN, true, methodName,
proto);
}
/*
* We have a method pointer for a method in "clazz", but it might be
* pointing to a method in a derived class. We want to find the actual entry
* from the class' vtable. If "clazz" is an interface, we have to do a
* little more digging.
*
* For "direct" methods (private / constructor), we just return the
* original Method.
*
* (This is used for reflection and JNI "call method" calls.)
*/
const Method* dvmGetVirtualizedMethod(const ClassObject* clazz,
const Method* meth)
{
Method* actualMeth;
int methodIndex;
if (dvmIsDirectMethod(meth)) {
/* no vtable entry for these */
assert(!dvmIsStaticMethod(meth));
return meth;
}
/*
* If the method was declared in an interface, we need to scan through
* the class' list of interfaces for it, and find the vtable index
* from that.
*
* TODO: use the interface cache.
*/
if (dvmIsInterfaceClass(meth->clazz)) {
int i;
for (i = 0; i < clazz->iftableCount; i++) {
if (clazz->iftable[i].clazz == meth->clazz)
break;
}
if (i == clazz->iftableCount) {
dvmThrowIncompatibleClassChangeError(
"invoking method from interface not implemented by class");
return NULL;
}
methodIndex = clazz->iftable[i].methodIndexArray[meth->methodIndex];
} else {
methodIndex = meth->methodIndex;
}
assert(methodIndex >= 0 && methodIndex < clazz->vtableCount);
actualMeth = clazz->vtable[methodIndex];
/*
* Make sure there's code to execute.
*/
if (dvmIsAbstractMethod(actualMeth)) {
dvmThrowAbstractMethodError(NULL);
return NULL;
}
assert(!dvmIsMirandaMethod(actualMeth));
return actualMeth;
}
/*
* Get the source file for a method.
*/
const char* dvmGetMethodSourceFile(const Method* meth)
{
/*
* TODO: A method's debug info can override the default source
* file for a class, so we should account for that possibility
* here.
*/
return meth->clazz->sourceFile;
}
/*
* Dump some information about an object.
*/
void dvmDumpObject(const Object* obj)
{
ClassObject* clazz;
int i;
if (obj == NULL || obj->clazz == NULL) {
ALOGW("Null or malformed object not dumped");
return;
}
clazz = obj->clazz;
ALOGD("----- Object dump: %p (%s, %d bytes) -----",
obj, clazz->descriptor, (int) clazz->objectSize);
//printHexDump(obj, clazz->objectSize);
ALOGD(" Fields:");
while (clazz != NULL) {
ALOGD(" -- %s", clazz->descriptor);
for (i = 0; i < clazz->ifieldCount; i++) {
const InstField* pField = &clazz->ifields[i];
char type = pField->signature[0];
if (type == 'F' || type == 'D') {
double dval;
if (type == 'F')
dval = dvmGetFieldFloat(obj, pField->byteOffset);
else
dval = dvmGetFieldDouble(obj, pField->byteOffset);
ALOGD(" %2d: '%s' '%s' af=%04x off=%d %.3f", i,
pField->name, pField->signature,
pField->accessFlags, pField->byteOffset, dval);
} else {
u8 lval;
if (type == 'J')
lval = dvmGetFieldLong(obj, pField->byteOffset);
else if (type == 'Z')
lval = dvmGetFieldBoolean(obj, pField->byteOffset);
else
lval = dvmGetFieldInt(obj, pField->byteOffset);
ALOGD(" %2d: '%s' '%s' af=%04x off=%d 0x%08llx", i,
pField->name, pField->signature,
pField->accessFlags, pField->byteOffset, lval);
}
}
clazz = clazz->super;
}
if (dvmIsClassObject(obj)) {
ALOGD(" Static fields:");
const StaticField* sfields = &((ClassObject *)obj)->sfields[0];
for (i = 0; i < ((ClassObject *)obj)->sfieldCount; ++i) {
const StaticField* pField = &sfields[i];
size_t byteOffset = (size_t)pField - (size_t)sfields;
char type = pField->signature[0];
if (type == 'F' || type == 'D') {
double dval;
if (type == 'F')
dval = pField->value.f;
else
dval = pField->value.d;
ALOGD(" %2d: '%s' '%s' af=%04x off=%zd %.3f", i,
pField->name, pField->signature,
pField->accessFlags, byteOffset, dval);
} else {
u8 lval;
if (type == 'J')
lval = pField->value.j;
else if (type == 'Z')
lval = pField->value.z;
else
lval = pField->value.i;
ALOGD(" %2d: '%s' '%s' af=%04x off=%zd 0x%08llx", i,
pField->name, pField->signature,
pField->accessFlags, byteOffset, lval);
}
}
}
}