/* * 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. */ /* * Support for -Xcheck:jni (the "careful" version of the JNI interfaces). * * We want to verify types, make sure class and field IDs are valid, and * ensure that JNI's semantic expectations are being met. JNI seems to * be relatively lax when it comes to requirements for permission checks, * e.g. access to private methods is generally allowed from anywhere. */ #include "Dalvik.h" #include "JniInternal.h" #include #include /* * Abort if we are configured to bail out on JNI warnings. */ static void abortMaybe() { if (!gDvmJni.warnOnly) { dvmDumpThread(dvmThreadSelf(), false); dvmAbort(); } } /* * =========================================================================== * JNI call bridge wrapper * =========================================================================== */ /* * Check the result of a native method call that returns an object reference. * * The primary goal here is to verify that native code is returning the * correct type of object. If it's declared to return a String but actually * returns a byte array, things will fail in strange ways later on. * * This can be a fairly expensive operation, since we have to look up the * return type class by name in method->clazz' class loader. We take a * shortcut here and allow the call to succeed if the descriptor strings * match. This will allow some false-positives when a class is redefined * by a class loader, but that's rare enough that it doesn't seem worth * testing for. * * At this point, pResult->l has already been converted to an object pointer. */ static void checkCallResultCommon(const u4* args, const JValue* pResult, const Method* method, Thread* self) { assert(pResult->l != NULL); const Object* resultObj = (const Object*) pResult->l; if (resultObj == kInvalidIndirectRefObject) { ALOGW("JNI WARNING: invalid reference returned from native code"); const Method* method = dvmGetCurrentJNIMethod(); char* desc = dexProtoCopyMethodDescriptor(&method->prototype); ALOGW(" in %s.%s:%s", method->clazz->descriptor, method->name, desc); free(desc); abortMaybe(); return; } ClassObject* objClazz = resultObj->clazz; /* * Make sure that pResult->l is an instance of the type this * method was expected to return. */ const char* declType = dexProtoGetReturnType(&method->prototype); const char* objType = objClazz->descriptor; if (strcmp(declType, objType) == 0) { /* names match; ignore class loader issues and allow it */ ALOGV("Check %s.%s: %s io %s (FAST-OK)", method->clazz->descriptor, method->name, objType, declType); } else { /* * Names didn't match. We need to resolve declType in the context * of method->clazz->classLoader, and compare the class objects * for equality. * * Since we're returning an instance of declType, it's safe to * assume that it has been loaded and initialized (or, for the case * of an array, generated). However, the current class loader may * not be listed as an initiating loader, so we can't just look for * it in the loaded-classes list. */ ClassObject* declClazz = dvmFindClassNoInit(declType, method->clazz->classLoader); if (declClazz == NULL) { ALOGW("JNI WARNING: method declared to return '%s' returned '%s'", declType, objType); ALOGW(" failed in %s.%s ('%s' not found)", method->clazz->descriptor, method->name, declType); abortMaybe(); return; } if (!dvmInstanceof(objClazz, declClazz)) { ALOGW("JNI WARNING: method declared to return '%s' returned '%s'", declType, objType); ALOGW(" failed in %s.%s", method->clazz->descriptor, method->name); abortMaybe(); return; } else { ALOGV("Check %s.%s: %s io %s (SLOW-OK)", method->clazz->descriptor, method->name, objType, declType); } } } /* * Determine if we need to check the return type coming out of the call. * * (We don't simply do this at the top of checkCallResultCommon() because * this is on the critical path for native method calls.) */ static inline bool callNeedsCheck(const u4* args, JValue* pResult, const Method* method, Thread* self) { return (method->shorty[0] == 'L' && !dvmCheckException(self) && pResult->l != NULL); } /* * Check a call into native code. */ void dvmCheckCallJNIMethod(const u4* args, JValue* pResult, const Method* method, Thread* self) { dvmCallJNIMethod(args, pResult, method, self); if (callNeedsCheck(args, pResult, method, self)) { checkCallResultCommon(args, pResult, method, self); } } /* * =========================================================================== * JNI function helpers * =========================================================================== */ static inline const JNINativeInterface* baseEnv(JNIEnv* env) { return ((JNIEnvExt*) env)->baseFuncTable; } static inline const JNIInvokeInterface* baseVm(JavaVM* vm) { return ((JavaVMExt*) vm)->baseFuncTable; } class ScopedCheckJniThreadState { public: explicit ScopedCheckJniThreadState(JNIEnv* env) { dvmChangeStatus(NULL, THREAD_RUNNING); } ~ScopedCheckJniThreadState() { dvmChangeStatus(NULL, THREAD_NATIVE); } private: // Disallow copy and assignment. ScopedCheckJniThreadState(const ScopedCheckJniThreadState&); void operator=(const ScopedCheckJniThreadState&); }; /* * Flags passed into ScopedCheck. */ #define kFlag_Default 0x0000 #define kFlag_CritBad 0x0000 /* calling while in critical is bad */ #define kFlag_CritOkay 0x0001 /* ...okay */ #define kFlag_CritGet 0x0002 /* this is a critical "get" */ #define kFlag_CritRelease 0x0003 /* this is a critical "release" */ #define kFlag_CritMask 0x0003 /* bit mask to get "crit" value */ #define kFlag_ExcepBad 0x0000 /* raised exceptions are bad */ #define kFlag_ExcepOkay 0x0004 /* ...okay */ #define kFlag_Release 0x0010 /* are we in a non-critical release function? */ #define kFlag_NullableUtf 0x0020 /* are our UTF parameters nullable? */ #define kFlag_Invocation 0x8000 /* Part of the invocation interface (JavaVM*) */ static const char* indirectRefKindName(IndirectRef iref) { return indirectRefKindToString(indirectRefKind(iref)); } class ScopedCheck { public: // For JNIEnv* functions. explicit ScopedCheck(JNIEnv* env, int flags, const char* functionName) { init(env, flags, functionName, true); checkThread(flags); } // For JavaVM* functions. explicit ScopedCheck(bool hasMethod, const char* functionName) { init(NULL, kFlag_Invocation, functionName, hasMethod); } /* * In some circumstances the VM will screen class names, but it doesn't * for class lookup. When things get bounced through a class loader, they * can actually get normalized a couple of times; as a result, passing in * a class name like "java.lang.Thread" instead of "java/lang/Thread" will * work in some circumstances. * * This is incorrect and could cause strange behavior or compatibility * problems, so we want to screen that out here. * * We expect "fully-qualified" class names, like "java/lang/Thread" or * "[Ljava/lang/Object;". */ void checkClassName(const char* className) { if (!dexIsValidClassName(className, false)) { ALOGW("JNI WARNING: illegal class name '%s' (%s)", className, mFunctionName); ALOGW(" (should be formed like 'dalvik/system/DexFile')"); ALOGW(" or '[Ldalvik/system/DexFile;' or '[[B')"); abortMaybe(); } } void checkFieldTypeForGet(jfieldID fid, const char* expectedSignature, bool isStatic) { if (fid == NULL) { ALOGW("JNI WARNING: null jfieldID (%s)", mFunctionName); showLocation(); abortMaybe(); } bool printWarn = false; Field* field = (Field*) fid; const char* actualSignature = field->signature; if (*expectedSignature == 'L') { // 'actualSignature' has the exact type. // We just know we're expecting some kind of reference. if (*actualSignature != 'L' && *actualSignature != '[') { printWarn = true; } } else if (*actualSignature != *expectedSignature) { printWarn = true; } if (!printWarn && isStatic && !dvmIsStaticField(field)) { if (isStatic) { ALOGW("JNI WARNING: accessing non-static field %s as static", field->name); } else { ALOGW("JNI WARNING: accessing static field %s as non-static", field->name); } printWarn = true; } if (printWarn) { ALOGW("JNI WARNING: %s for field '%s' of expected type %s, got %s", mFunctionName, field->name, expectedSignature, actualSignature); showLocation(); abortMaybe(); } } /* * Verify that the field is of the appropriate type. If the field has an * object type, "jobj" is the object we're trying to assign into it. * * Works for both static and instance fields. */ void checkFieldTypeForSet(jobject jobj, jfieldID fieldID, PrimitiveType prim, bool isStatic) { if (fieldID == NULL) { ALOGW("JNI WARNING: null jfieldID (%s)", mFunctionName); showLocation(); abortMaybe(); } bool printWarn = false; Field* field = (Field*) fieldID; if ((field->signature[0] == 'L' || field->signature[0] == '[') && jobj != NULL) { ScopedCheckJniThreadState ts(mEnv); Object* obj = dvmDecodeIndirectRef(self(), jobj); /* * If jobj is a weak global ref whose referent has been cleared, * obj will be NULL. Otherwise, obj should always be non-NULL * and valid. */ if (obj != NULL && !dvmIsHeapAddress(obj)) { ALOGW("JNI WARNING: field operation (%s) on invalid %s reference (%p)", mFunctionName, indirectRefKindName(jobj), jobj); printWarn = true; } else { ClassObject* fieldClass = dvmFindLoadedClass(field->signature); ClassObject* objClass = obj->clazz; assert(fieldClass != NULL); assert(objClass != NULL); if (!dvmInstanceof(objClass, fieldClass)) { ALOGW("JNI WARNING: %s for field '%s' expected type %s, got %s", mFunctionName, field->name, field->signature, objClass->descriptor); printWarn = true; } } } else if (dexGetPrimitiveTypeFromDescriptorChar(field->signature[0]) != prim) { ALOGW("JNI WARNING: %s for field '%s' expected type %s, got %s", mFunctionName, field->name, field->signature, primitiveTypeToName(prim)); printWarn = true; } else if (isStatic && !dvmIsStaticField(field)) { if (isStatic) { ALOGW("JNI WARNING: %s for non-static field '%s'", mFunctionName, field->name); } else { ALOGW("JNI WARNING: %s for static field '%s'", mFunctionName, field->name); } printWarn = true; } if (printWarn) { showLocation(); abortMaybe(); } } /* * Verify that this instance field ID is valid for this object. * * Assumes "jobj" has already been validated. */ void checkInstanceFieldID(jobject jobj, jfieldID fieldID) { ScopedCheckJniThreadState ts(mEnv); Object* obj = dvmDecodeIndirectRef(self(), jobj); if (!dvmIsHeapAddress(obj)) { ALOGW("JNI ERROR: %s on invalid reference (%p)", mFunctionName, jobj); dvmAbort(); } /* * Check this class and all of its superclasses for a matching field. * Don't need to scan interfaces. */ ClassObject* clazz = obj->clazz; while (clazz != NULL) { if ((InstField*) fieldID >= clazz->ifields && (InstField*) fieldID < clazz->ifields + clazz->ifieldCount) { return; } clazz = clazz->super; } ALOGW("JNI WARNING: instance jfieldID %p not valid for class %s (%s)", fieldID, obj->clazz->descriptor, mFunctionName); showLocation(); abortMaybe(); } /* * Verify that the pointer value is non-NULL. */ void checkNonNull(const void* ptr) { if (ptr == NULL) { ALOGW("JNI WARNING: invalid null pointer (%s)", mFunctionName); abortMaybe(); } } /* * Verify that the method's return type matches the type of call. * 'expectedType' will be "L" for all objects, including arrays. */ void checkSig(jmethodID methodID, const char* expectedType, bool isStatic) { const Method* method = (const Method*) methodID; bool printWarn = false; if (*expectedType != method->shorty[0]) { ALOGW("JNI WARNING: %s expected return type '%s'", mFunctionName, expectedType); printWarn = true; } else if (isStatic && !dvmIsStaticMethod(method)) { if (isStatic) { ALOGW("JNI WARNING: calling non-static method with static call %s", mFunctionName); } else { ALOGW("JNI WARNING: calling static method with non-static call %s", mFunctionName); } printWarn = true; } if (printWarn) { char* desc = dexProtoCopyMethodDescriptor(&method->prototype); ALOGW(" calling %s.%s %s", method->clazz->descriptor, method->name, desc); free(desc); showLocation(); abortMaybe(); } } /* * Verify that this static field ID is valid for this class. * * Assumes "jclazz" has already been validated. */ void checkStaticFieldID(jclass jclazz, jfieldID fieldID) { ScopedCheckJniThreadState ts(mEnv); ClassObject* clazz = (ClassObject*) dvmDecodeIndirectRef(self(), jclazz); StaticField* base = &clazz->sfields[0]; int fieldCount = clazz->sfieldCount; if ((StaticField*) fieldID < base || (StaticField*) fieldID >= base + fieldCount) { ALOGW("JNI WARNING: static fieldID %p not valid for class %s (%s)", fieldID, clazz->descriptor, mFunctionName); ALOGW(" base=%p count=%d", base, fieldCount); showLocation(); abortMaybe(); } } /* * Verify that "methodID" is appropriate for "clazz". * * A mismatch isn't dangerous, because the jmethodID defines the class. In * fact, jclazz is unused in the implementation. It's best if we don't * allow bad code in the system though. * * Instances of "jclazz" must be instances of the method's declaring class. */ void checkStaticMethod(jclass jclazz, jmethodID methodID) { ScopedCheckJniThreadState ts(mEnv); ClassObject* clazz = (ClassObject*) dvmDecodeIndirectRef(self(), jclazz); const Method* method = (const Method*) methodID; if (!dvmInstanceof(clazz, method->clazz)) { ALOGW("JNI WARNING: can't call static %s.%s on class %s (%s)", method->clazz->descriptor, method->name, clazz->descriptor, mFunctionName); showLocation(); // no abort? } } /* * Verify that "methodID" is appropriate for "jobj". * * Make sure the object is an instance of the method's declaring class. * (Note the methodID might point to a declaration in an interface; this * will be handled automatically by the instanceof check.) */ void checkVirtualMethod(jobject jobj, jmethodID methodID) { ScopedCheckJniThreadState ts(mEnv); Object* obj = dvmDecodeIndirectRef(self(), jobj); const Method* method = (const Method*) methodID; if (!dvmInstanceof(obj->clazz, method->clazz)) { ALOGW("JNI WARNING: can't call %s.%s on instance of %s (%s)", method->clazz->descriptor, method->name, obj->clazz->descriptor, mFunctionName); showLocation(); abortMaybe(); } } /** * The format string is a sequence of the following characters, * and must be followed by arguments of the corresponding types * in the same order. * * Java primitive types: * B - jbyte * C - jchar * D - jdouble * F - jfloat * I - jint * J - jlong * S - jshort * Z - jboolean (shown as true and false) * V - void * * Java reference types: * L - jobject * a - jarray * c - jclass * s - jstring * * JNI types: * b - jboolean (shown as JNI_TRUE and JNI_FALSE) * f - jfieldID * m - jmethodID * p - void* * r - jint (for release mode arguments) * t - thread args (for AttachCurrentThread) * u - const char* (modified UTF-8) * z - jsize (for lengths; use i if negative values are okay) * v - JavaVM* * E - JNIEnv* * . - no argument; just print "..." (used for varargs JNI calls) * * Use the kFlag_NullableUtf flag where 'u' field(s) are nullable. */ void check(bool entry, const char* fmt0, ...) { va_list ap; bool shouldTrace = false; const Method* method = NULL; if ((gDvm.jniTrace || gDvmJni.logThirdPartyJni) && mHasMethod) { // We need to guard some of the invocation interface's calls: a bad caller might // use DetachCurrentThread or GetEnv on a thread that's not yet attached. if ((mFlags & kFlag_Invocation) == 0 || dvmThreadSelf() != NULL) { method = dvmGetCurrentJNIMethod(); } } if (method != NULL) { // If both "-Xcheck:jni" and "-Xjnitrace:" are enabled, we print trace messages // when a native method that matches the Xjnitrace argument calls a JNI function // such as NewByteArray. if (gDvm.jniTrace && strstr(method->clazz->descriptor, gDvm.jniTrace) != NULL) { shouldTrace = true; } // If -Xjniopts:logThirdPartyJni is on, we want to log any JNI function calls // made by a third-party native method. if (gDvmJni.logThirdPartyJni) { shouldTrace |= method->shouldTrace; } } if (shouldTrace) { va_start(ap, fmt0); std::string msg; for (const char* fmt = fmt0; *fmt;) { char ch = *fmt++; if (ch == 'B') { // jbyte jbyte b = va_arg(ap, int); if (b >= 0 && b < 10) { StringAppendF(&msg, "%d", b); } else { StringAppendF(&msg, "%#x (%d)", b, b); } } else if (ch == 'C') { // jchar jchar c = va_arg(ap, int); if (c < 0x7f && c >= ' ') { StringAppendF(&msg, "U+%x ('%c')", c, c); } else { StringAppendF(&msg, "U+%x", c); } } else if (ch == 'F' || ch == 'D') { // jfloat, jdouble StringAppendF(&msg, "%g", va_arg(ap, double)); } else if (ch == 'I' || ch == 'S') { // jint, jshort StringAppendF(&msg, "%d", va_arg(ap, int)); } else if (ch == 'J') { // jlong StringAppendF(&msg, "%lld", va_arg(ap, jlong)); } else if (ch == 'Z') { // jboolean StringAppendF(&msg, "%s", va_arg(ap, int) ? "true" : "false"); } else if (ch == 'V') { // void msg += "void"; } else if (ch == 'v') { // JavaVM* JavaVM* vm = va_arg(ap, JavaVM*); StringAppendF(&msg, "(JavaVM*)%p", vm); } else if (ch == 'E') { // JNIEnv* JNIEnv* env = va_arg(ap, JNIEnv*); StringAppendF(&msg, "(JNIEnv*)%p", env); } else if (ch == 'L' || ch == 'a' || ch == 's') { // jobject, jarray, jstring // For logging purposes, these are identical. jobject o = va_arg(ap, jobject); if (o == NULL) { msg += "NULL"; } else { StringAppendF(&msg, "%p", o); } } else if (ch == 'b') { // jboolean (JNI-style) jboolean b = va_arg(ap, int); msg += (b ? "JNI_TRUE" : "JNI_FALSE"); } else if (ch == 'c') { // jclass jclass jc = va_arg(ap, jclass); Object* c = dvmDecodeIndirectRef(self(), jc); if (c == NULL) { msg += "NULL"; } else if (c == kInvalidIndirectRefObject || !dvmIsHeapAddress(c)) { StringAppendF(&msg, "%p(INVALID)", jc); } else { std::string className(dvmHumanReadableType(c)); StringAppendF(&msg, "%s", className.c_str()); if (!entry) { StringAppendF(&msg, " (%p)", jc); } } } else if (ch == 'f') { // jfieldID jfieldID fid = va_arg(ap, jfieldID); std::string name(dvmHumanReadableField((Field*) fid)); StringAppendF(&msg, "%s", name.c_str()); if (!entry) { StringAppendF(&msg, " (%p)", fid); } } else if (ch == 'z') { // non-negative jsize // You might expect jsize to be size_t, but it's not; it's the same as jint. // We only treat this specially so we can do the non-negative check. // TODO: maybe this wasn't worth it? jint i = va_arg(ap, jint); StringAppendF(&msg, "%d", i); } else if (ch == 'm') { // jmethodID jmethodID mid = va_arg(ap, jmethodID); std::string name(dvmHumanReadableMethod((Method*) mid, true)); StringAppendF(&msg, "%s", name.c_str()); if (!entry) { StringAppendF(&msg, " (%p)", mid); } } else if (ch == 'p' || ch == 't') { // void* ("pointer" or "thread args") void* p = va_arg(ap, void*); if (p == NULL) { msg += "NULL"; } else { StringAppendF(&msg, "(void*) %p", p); } } else if (ch == 'r') { // jint (release mode) jint releaseMode = va_arg(ap, jint); if (releaseMode == 0) { msg += "0"; } else if (releaseMode == JNI_ABORT) { msg += "JNI_ABORT"; } else if (releaseMode == JNI_COMMIT) { msg += "JNI_COMMIT"; } else { StringAppendF(&msg, "invalid release mode %d", releaseMode); } } else if (ch == 'u') { // const char* (modified UTF-8) const char* utf = va_arg(ap, const char*); if (utf == NULL) { msg += "NULL"; } else { StringAppendF(&msg, "\"%s\"", utf); } } else if (ch == '.') { msg += "..."; } else { ALOGE("unknown trace format specifier %c", ch); dvmAbort(); } if (*fmt) { StringAppendF(&msg, ", "); } } va_end(ap); if (entry) { if (mHasMethod) { std::string methodName(dvmHumanReadableMethod(method, false)); ALOGI("JNI: %s -> %s(%s)", methodName.c_str(), mFunctionName, msg.c_str()); mIndent = methodName.size() + 1; } else { ALOGI("JNI: -> %s(%s)", mFunctionName, msg.c_str()); mIndent = 0; } } else { ALOGI("JNI: %*s<- %s returned %s", mIndent, "", mFunctionName, msg.c_str()); } } // We always do the thorough checks on entry, and never on exit... if (entry) { va_start(ap, fmt0); for (const char* fmt = fmt0; *fmt; ++fmt) { char ch = *fmt; if (ch == 'a') { checkArray(va_arg(ap, jarray)); } else if (ch == 'c') { checkClass(va_arg(ap, jclass)); } else if (ch == 'L') { checkObject(va_arg(ap, jobject)); } else if (ch == 'r') { checkReleaseMode(va_arg(ap, jint)); } else if (ch == 's') { checkString(va_arg(ap, jstring)); } else if (ch == 't') { checkThreadArgs(va_arg(ap, void*)); } else if (ch == 'u') { if ((mFlags & kFlag_Release) != 0) { checkNonNull(va_arg(ap, const char*)); } else { bool nullable = ((mFlags & kFlag_NullableUtf) != 0); checkUtfString(va_arg(ap, const char*), nullable); } } else if (ch == 'z') { checkLengthPositive(va_arg(ap, jsize)); } else if (strchr("BCISZbfmpEv", ch) != NULL) { va_arg(ap, int); // Skip this argument. } else if (ch == 'D' || ch == 'F') { va_arg(ap, double); // Skip this argument. } else if (ch == 'J') { va_arg(ap, long); // Skip this argument. } else if (ch == '.') { } else { ALOGE("unknown check format specifier %c", ch); dvmAbort(); } } va_end(ap); } } // Only safe after checkThread returns. Thread* self() { return ((JNIEnvExt*) mEnv)->self; } private: JNIEnv* mEnv; const char* mFunctionName; int mFlags; bool mHasMethod; size_t mIndent; void init(JNIEnv* env, int flags, const char* functionName, bool hasMethod) { mEnv = env; mFlags = flags; // Use +6 to drop the leading "Check_"... mFunctionName = functionName + 6; // Set "hasMethod" to true if we have a valid thread with a method pointer. // We won't have one before attaching a thread, after detaching a thread, or // after destroying the VM. mHasMethod = hasMethod; } /* * Verify that "array" is non-NULL and points to an Array object. * * Since we're dealing with objects, switch to "running" mode. */ void checkArray(jarray jarr) { if (jarr == NULL) { ALOGW("JNI WARNING: %s received null array", mFunctionName); showLocation(); abortMaybe(); return; } ScopedCheckJniThreadState ts(mEnv); bool printWarn = false; Object* obj = dvmDecodeIndirectRef(self(), jarr); if (!dvmIsHeapAddress(obj)) { ALOGW("JNI WARNING: %s: jarray is an invalid %s reference (%p)", mFunctionName, indirectRefKindName(jarr), jarr); printWarn = true; } else if (obj->clazz->descriptor[0] != '[') { ALOGW("JNI WARNING: %s: jarray arg has wrong type (expected array, got %s)", mFunctionName, obj->clazz->descriptor); printWarn = true; } if (printWarn) { showLocation(); abortMaybe(); } } void checkClass(jclass c) { checkInstance(c, gDvm.classJavaLangClass, "jclass"); } void checkLengthPositive(jsize length) { if (length < 0) { ALOGW("JNI WARNING: negative jsize (%s)", mFunctionName); abortMaybe(); } } /* * Verify that "jobj" is a valid object, and that it's an object that JNI * is allowed to know about. We allow NULL references. * * Switches to "running" mode before performing checks. */ void checkObject(jobject jobj) { if (jobj == NULL) { return; } ScopedCheckJniThreadState ts(mEnv); bool printWarn = false; if (dvmGetJNIRefType(self(), jobj) == JNIInvalidRefType) { ALOGW("JNI WARNING: %p is not a valid JNI reference (%s)", jobj, mFunctionName); printWarn = true; } else { Object* obj = dvmDecodeIndirectRef(self(), jobj); if (obj == kInvalidIndirectRefObject) { ALOGW("JNI WARNING: native code passing in invalid reference %p (%s)", jobj, mFunctionName); printWarn = true; } else if (obj != NULL && !dvmIsHeapAddress(obj)) { // TODO: when we remove workAroundAppJniBugs, this should be impossible. ALOGW("JNI WARNING: native code passing in reference to invalid object %p %p (%s)", jobj, obj, mFunctionName); printWarn = true; } } if (printWarn) { showLocation(); abortMaybe(); } } /* * Verify that the "mode" argument passed to a primitive array Release * function is one of the valid values. */ void checkReleaseMode(jint mode) { if (mode != 0 && mode != JNI_COMMIT && mode != JNI_ABORT) { ALOGW("JNI WARNING: bad value for mode (%d) (%s)", mode, mFunctionName); abortMaybe(); } } void checkString(jstring s) { checkInstance(s, gDvm.classJavaLangString, "jstring"); } void checkThreadArgs(void* thread_args) { JavaVMAttachArgs* args = static_cast(thread_args); if (args != NULL && args->version < JNI_VERSION_1_2) { ALOGW("JNI WARNING: bad value for JNI version (%d) (%s)", args->version, mFunctionName); abortMaybe(); } } void checkThread(int flags) { // Get the *correct* JNIEnv by going through our TLS pointer. JNIEnvExt* threadEnv = dvmGetJNIEnvForThread(); /* * Verify that the current thread is (a) attached and (b) associated with * this particular instance of JNIEnv. */ bool printWarn = false; if (threadEnv == NULL) { ALOGE("JNI ERROR: non-VM thread making JNI call (%s)", mFunctionName); // don't set printWarn -- it'll try to call showLocation() dvmAbort(); } else if ((JNIEnvExt*) mEnv != threadEnv) { if (dvmThreadSelf()->threadId != threadEnv->envThreadId) { ALOGE("JNI: threadEnv != thread->env? (%s)", mFunctionName); dvmAbort(); } ALOGW("JNI WARNING: threadid=%d using env from threadid=%d (%s)", threadEnv->envThreadId, ((JNIEnvExt*) mEnv)->envThreadId, mFunctionName); printWarn = true; // If we're keeping broken code limping along, we need to suppress the abort... if (gDvmJni.workAroundAppJniBugs) { printWarn = false; } /* this is a bad idea -- need to throw as we exit, or abort func */ //dvmThrowRuntimeException("invalid use of JNI env ptr"); } else if (((JNIEnvExt*) mEnv)->self != dvmThreadSelf()) { /* correct JNIEnv*; make sure the "self" pointer is correct */ ALOGE("JNI ERROR: env->self != thread-self (%p vs. %p) (%s)", ((JNIEnvExt*) mEnv)->self, dvmThreadSelf(), mFunctionName); dvmAbort(); } /* * Verify that, if this thread previously made a critical "get" call, we * do the corresponding "release" call before we try anything else. */ switch (flags & kFlag_CritMask) { case kFlag_CritOkay: // okay to call this method break; case kFlag_CritBad: // not okay to call if (threadEnv->critical) { ALOGW("JNI WARNING: threadid=%d using JNI after critical get (%s)", threadEnv->envThreadId, mFunctionName); printWarn = true; } break; case kFlag_CritGet: // this is a "get" call /* don't check here; we allow nested gets */ threadEnv->critical++; break; case kFlag_CritRelease: // this is a "release" call threadEnv->critical--; if (threadEnv->critical < 0) { ALOGW("JNI WARNING: threadid=%d called too many critical releases (%s)", threadEnv->envThreadId, mFunctionName); printWarn = true; } break; default: assert(false); } /* * Verify that, if an exception has been raised, the native code doesn't * make any JNI calls other than the Exception* methods. */ bool printException = false; if ((flags & kFlag_ExcepOkay) == 0 && dvmCheckException(dvmThreadSelf())) { ALOGW("JNI WARNING: JNI function %s called with exception pending", mFunctionName); printWarn = true; printException = true; } if (printWarn) { showLocation(); } if (printException) { ALOGW("Pending exception is:"); dvmLogExceptionStackTrace(); } if (printWarn) { abortMaybe(); } } /* * Verify that "bytes" points to valid "modified UTF-8" data. */ void checkUtfString(const char* bytes, bool nullable) { if (bytes == NULL) { if (!nullable) { ALOGW("JNI WARNING: non-nullable const char* was NULL (%s)", mFunctionName); showLocation(); abortMaybe(); } return; } const char* errorKind = NULL; u1 utf8 = checkUtfBytes(bytes, &errorKind); if (errorKind != NULL) { ALOGW("JNI WARNING: %s input is not valid Modified UTF-8: illegal %s byte %#x", mFunctionName, errorKind, utf8); ALOGW(" string: '%s'", bytes); showLocation(); abortMaybe(); } } /* * Verify that "jobj" is a valid non-NULL object reference, and points to * an instance of expectedClass. * * Because we're looking at an object on the GC heap, we have to switch * to "running" mode before doing the checks. */ void checkInstance(jobject jobj, ClassObject* expectedClass, const char* argName) { if (jobj == NULL) { ALOGW("JNI WARNING: received null %s (%s)", argName, mFunctionName); showLocation(); abortMaybe(); return; } ScopedCheckJniThreadState ts(mEnv); bool printWarn = false; Object* obj = dvmDecodeIndirectRef(self(), jobj); if (!dvmIsHeapAddress(obj)) { ALOGW("JNI WARNING: %s is an invalid %s reference (%p) (%s)", argName, indirectRefKindName(jobj), jobj, mFunctionName); printWarn = true; } else if (obj->clazz != expectedClass) { ALOGW("JNI WARNING: %s arg has wrong type (expected %s, got %s) (%s)", argName, expectedClass->descriptor, obj->clazz->descriptor, mFunctionName); printWarn = true; } if (printWarn) { showLocation(); abortMaybe(); } } static u1 checkUtfBytes(const char* bytes, const char** errorKind) { while (*bytes != '\0') { u1 utf8 = *(bytes++); // Switch on the high four bits. switch (utf8 >> 4) { case 0x00: case 0x01: case 0x02: case 0x03: case 0x04: case 0x05: case 0x06: case 0x07: // Bit pattern 0xxx. No need for any extra bytes. break; case 0x08: case 0x09: case 0x0a: case 0x0b: case 0x0f: /* * Bit pattern 10xx or 1111, which are illegal start bytes. * Note: 1111 is valid for normal UTF-8, but not the * modified UTF-8 used here. */ *errorKind = "start"; return utf8; case 0x0e: // Bit pattern 1110, so there are two additional bytes. utf8 = *(bytes++); if ((utf8 & 0xc0) != 0x80) { *errorKind = "continuation"; return utf8; } // Fall through to take care of the final byte. case 0x0c: case 0x0d: // Bit pattern 110x, so there is one additional byte. utf8 = *(bytes++); if ((utf8 & 0xc0) != 0x80) { *errorKind = "continuation"; return utf8; } break; } } return 0; } /** * Returns a human-readable name for the given primitive type. */ static const char* primitiveTypeToName(PrimitiveType primType) { switch (primType) { case PRIM_VOID: return "void"; case PRIM_BOOLEAN: return "boolean"; case PRIM_BYTE: return "byte"; case PRIM_SHORT: return "short"; case PRIM_CHAR: return "char"; case PRIM_INT: return "int"; case PRIM_LONG: return "long"; case PRIM_FLOAT: return "float"; case PRIM_DOUBLE: return "double"; case PRIM_NOT: return "Object/array"; default: return "???"; } } void showLocation() { const Method* method = dvmGetCurrentJNIMethod(); char* desc = dexProtoCopyMethodDescriptor(&method->prototype); ALOGW(" in %s.%s:%s (%s)", method->clazz->descriptor, method->name, desc, mFunctionName); free(desc); } // Disallow copy and assignment. ScopedCheck(const ScopedCheck&); void operator=(const ScopedCheck&); }; /* * =========================================================================== * Guarded arrays * =========================================================================== */ #define kGuardLen 512 /* must be multiple of 2 */ #define kGuardPattern 0xd5e3 /* uncommon values; d5e3d5e3 invalid addr */ #define kGuardMagic 0xffd5aa96 /* this gets tucked in at the start of the buffer; struct size must be even */ struct GuardedCopy { u4 magic; uLong adler; size_t originalLen; const void* originalPtr; /* find the GuardedCopy given the pointer into the "live" data */ static inline const GuardedCopy* fromData(const void* dataBuf) { return reinterpret_cast(actualBuffer(dataBuf)); } /* * Create an over-sized buffer to hold the contents of "buf". Copy it in, * filling in the area around it with guard data. * * We use a 16-bit pattern to make a rogue memset less likely to elude us. */ static void* create(const void* buf, size_t len, bool modOkay) { size_t newLen = actualLength(len); u1* newBuf = debugAlloc(newLen); /* fill it in with a pattern */ u2* pat = (u2*) newBuf; for (size_t i = 0; i < newLen / 2; i++) { *pat++ = kGuardPattern; } /* copy the data in; note "len" could be zero */ memcpy(newBuf + kGuardLen / 2, buf, len); /* if modification is not expected, grab a checksum */ uLong adler = 0; if (!modOkay) { adler = adler32(0L, Z_NULL, 0); adler = adler32(adler, (const Bytef*)buf, len); *(uLong*)newBuf = adler; } GuardedCopy* pExtra = reinterpret_cast(newBuf); pExtra->magic = kGuardMagic; pExtra->adler = adler; pExtra->originalPtr = buf; pExtra->originalLen = len; return newBuf + kGuardLen / 2; } /* * Free up the guard buffer, scrub it, and return the original pointer. */ static void* destroy(void* dataBuf) { const GuardedCopy* pExtra = GuardedCopy::fromData(dataBuf); void* originalPtr = (void*) pExtra->originalPtr; size_t len = pExtra->originalLen; debugFree(dataBuf, len); return originalPtr; } /* * Verify the guard area and, if "modOkay" is false, that the data itself * has not been altered. * * The caller has already checked that "dataBuf" is non-NULL. */ static bool check(const void* dataBuf, bool modOkay) { static const u4 kMagicCmp = kGuardMagic; const u1* fullBuf = actualBuffer(dataBuf); const GuardedCopy* pExtra = GuardedCopy::fromData(dataBuf); /* * Before we do anything with "pExtra", check the magic number. We * do the check with memcmp rather than "==" in case the pointer is * unaligned. If it points to completely bogus memory we're going * to crash, but there's no easy way around that. */ if (memcmp(&pExtra->magic, &kMagicCmp, 4) != 0) { u1 buf[4]; memcpy(buf, &pExtra->magic, 4); ALOGE("JNI: guard magic does not match (found 0x%02x%02x%02x%02x) -- incorrect data pointer %p?", buf[3], buf[2], buf[1], buf[0], dataBuf); /* assume little endian */ return false; } size_t len = pExtra->originalLen; /* check bottom half of guard; skip over optional checksum storage */ const u2* pat = (u2*) fullBuf; for (size_t i = sizeof(GuardedCopy) / 2; i < (kGuardLen / 2 - sizeof(GuardedCopy)) / 2; i++) { if (pat[i] != kGuardPattern) { ALOGE("JNI: guard pattern(1) disturbed at %p + %d", fullBuf, i*2); return false; } } int offset = kGuardLen / 2 + len; if (offset & 0x01) { /* odd byte; expected value depends on endian-ness of host */ const u2 patSample = kGuardPattern; if (fullBuf[offset] != ((const u1*) &patSample)[1]) { ALOGE("JNI: guard pattern disturbed in odd byte after %p (+%d) 0x%02x 0x%02x", fullBuf, offset, fullBuf[offset], ((const u1*) &patSample)[1]); return false; } offset++; } /* check top half of guard */ pat = (u2*) (fullBuf + offset); for (size_t i = 0; i < kGuardLen / 4; i++) { if (pat[i] != kGuardPattern) { ALOGE("JNI: guard pattern(2) disturbed at %p + %d", fullBuf, offset + i*2); return false; } } /* * If modification is not expected, verify checksum. Strictly speaking * this is wrong: if we told the client that we made a copy, there's no * reason they can't alter the buffer. */ if (!modOkay) { uLong adler = adler32(0L, Z_NULL, 0); adler = adler32(adler, (const Bytef*)dataBuf, len); if (pExtra->adler != adler) { ALOGE("JNI: buffer modified (0x%08lx vs 0x%08lx) at addr %p", pExtra->adler, adler, dataBuf); return false; } } return true; } private: static u1* debugAlloc(size_t len) { void* result = mmap(NULL, len, PROT_READ|PROT_WRITE, MAP_PRIVATE|MAP_ANON, -1, 0); if (result == MAP_FAILED) { ALOGE("GuardedCopy::create mmap(%d) failed: %s", len, strerror(errno)); dvmAbort(); } return reinterpret_cast(result); } static void debugFree(void* dataBuf, size_t len) { u1* fullBuf = actualBuffer(dataBuf); size_t totalByteCount = actualLength(len); // TODO: we could mprotect instead, and keep the allocation around for a while. // This would be even more expensive, but it might catch more errors. // if (mprotect(fullBuf, totalByteCount, PROT_NONE) != 0) { // ALOGW("mprotect(PROT_NONE) failed: %s", strerror(errno)); // } if (munmap(fullBuf, totalByteCount) != 0) { ALOGW("munmap failed: %s", strerror(errno)); dvmAbort(); } } static const u1* actualBuffer(const void* dataBuf) { return reinterpret_cast(dataBuf) - kGuardLen / 2; } static u1* actualBuffer(void* dataBuf) { return reinterpret_cast(dataBuf) - kGuardLen / 2; } // Underlying length of a user allocation of 'length' bytes. static size_t actualLength(size_t length) { return (length + kGuardLen + 1) & ~0x01; } }; /* * Return the width, in bytes, of a primitive type. */ static int dvmPrimitiveTypeWidth(PrimitiveType primType) { switch (primType) { case PRIM_BOOLEAN: return 1; case PRIM_BYTE: return 1; case PRIM_SHORT: return 2; case PRIM_CHAR: return 2; case PRIM_INT: return 4; case PRIM_LONG: return 8; case PRIM_FLOAT: return 4; case PRIM_DOUBLE: return 8; case PRIM_VOID: default: { assert(false); return -1; } } } /* * Create a guarded copy of a primitive array. Modifications to the copied * data are allowed. Returns a pointer to the copied data. */ static void* createGuardedPACopy(JNIEnv* env, const jarray jarr, jboolean* isCopy) { ScopedCheckJniThreadState ts(env); ArrayObject* arrObj = (ArrayObject*) dvmDecodeIndirectRef(dvmThreadSelf(), jarr); PrimitiveType primType = arrObj->clazz->elementClass->primitiveType; int len = arrObj->length * dvmPrimitiveTypeWidth(primType); void* result = GuardedCopy::create(arrObj->contents, len, true); if (isCopy != NULL) { *isCopy = JNI_TRUE; } return result; } /* * Perform the array "release" operation, which may or may not copy data * back into the VM, and may or may not release the underlying storage. */ static void* releaseGuardedPACopy(JNIEnv* env, jarray jarr, void* dataBuf, int mode) { ScopedCheckJniThreadState ts(env); ArrayObject* arrObj = (ArrayObject*) dvmDecodeIndirectRef(dvmThreadSelf(), jarr); if (!GuardedCopy::check(dataBuf, true)) { ALOGE("JNI: failed guarded copy check in releaseGuardedPACopy"); abortMaybe(); return NULL; } if (mode != JNI_ABORT) { size_t len = GuardedCopy::fromData(dataBuf)->originalLen; memcpy(arrObj->contents, dataBuf, len); } u1* result = NULL; if (mode != JNI_COMMIT) { result = (u1*) GuardedCopy::destroy(dataBuf); } else { result = (u1*) (void*) GuardedCopy::fromData(dataBuf)->originalPtr; } /* pointer is to the array contents; back up to the array object */ result -= OFFSETOF_MEMBER(ArrayObject, contents); return result; } /* * =========================================================================== * JNI functions * =========================================================================== */ #define CHECK_JNI_ENTRY(flags, types, args...) \ ScopedCheck sc(env, flags, __FUNCTION__); \ sc.check(true, types, ##args) #define CHECK_JNI_EXIT(type, exp) ({ \ typeof (exp) _rc = (exp); \ sc.check(false, type, _rc); \ _rc; }) #define CHECK_JNI_EXIT_VOID() \ sc.check(false, "V") static jint Check_GetVersion(JNIEnv* env) { CHECK_JNI_ENTRY(kFlag_Default, "E", env); return CHECK_JNI_EXIT("I", baseEnv(env)->GetVersion(env)); } static jclass Check_DefineClass(JNIEnv* env, const char* name, jobject loader, const jbyte* buf, jsize bufLen) { CHECK_JNI_ENTRY(kFlag_Default, "EuLpz", env, name, loader, buf, bufLen); sc.checkClassName(name); return CHECK_JNI_EXIT("c", baseEnv(env)->DefineClass(env, name, loader, buf, bufLen)); } static jclass Check_FindClass(JNIEnv* env, const char* name) { CHECK_JNI_ENTRY(kFlag_Default, "Eu", env, name); sc.checkClassName(name); return CHECK_JNI_EXIT("c", baseEnv(env)->FindClass(env, name)); } static jclass Check_GetSuperclass(JNIEnv* env, jclass clazz) { CHECK_JNI_ENTRY(kFlag_Default, "Ec", env, clazz); return CHECK_JNI_EXIT("c", baseEnv(env)->GetSuperclass(env, clazz)); } static jboolean Check_IsAssignableFrom(JNIEnv* env, jclass clazz1, jclass clazz2) { CHECK_JNI_ENTRY(kFlag_Default, "Ecc", env, clazz1, clazz2); return CHECK_JNI_EXIT("b", baseEnv(env)->IsAssignableFrom(env, clazz1, clazz2)); } static jmethodID Check_FromReflectedMethod(JNIEnv* env, jobject method) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, method); // TODO: check that 'field' is a java.lang.reflect.Method. return CHECK_JNI_EXIT("m", baseEnv(env)->FromReflectedMethod(env, method)); } static jfieldID Check_FromReflectedField(JNIEnv* env, jobject field) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, field); // TODO: check that 'field' is a java.lang.reflect.Field. return CHECK_JNI_EXIT("f", baseEnv(env)->FromReflectedField(env, field)); } static jobject Check_ToReflectedMethod(JNIEnv* env, jclass cls, jmethodID methodID, jboolean isStatic) { CHECK_JNI_ENTRY(kFlag_Default, "Ecmb", env, cls, methodID, isStatic); return CHECK_JNI_EXIT("L", baseEnv(env)->ToReflectedMethod(env, cls, methodID, isStatic)); } static jobject Check_ToReflectedField(JNIEnv* env, jclass cls, jfieldID fieldID, jboolean isStatic) { CHECK_JNI_ENTRY(kFlag_Default, "Ecfb", env, cls, fieldID, isStatic); return CHECK_JNI_EXIT("L", baseEnv(env)->ToReflectedField(env, cls, fieldID, isStatic)); } static jint Check_Throw(JNIEnv* env, jthrowable obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); // TODO: check that 'obj' is a java.lang.Throwable. return CHECK_JNI_EXIT("I", baseEnv(env)->Throw(env, obj)); } static jint Check_ThrowNew(JNIEnv* env, jclass clazz, const char* message) { CHECK_JNI_ENTRY(kFlag_NullableUtf, "Ecu", env, clazz, message); return CHECK_JNI_EXIT("I", baseEnv(env)->ThrowNew(env, clazz, message)); } static jthrowable Check_ExceptionOccurred(JNIEnv* env) { CHECK_JNI_ENTRY(kFlag_ExcepOkay, "E", env); return CHECK_JNI_EXIT("L", baseEnv(env)->ExceptionOccurred(env)); } static void Check_ExceptionDescribe(JNIEnv* env) { CHECK_JNI_ENTRY(kFlag_ExcepOkay, "E", env); baseEnv(env)->ExceptionDescribe(env); CHECK_JNI_EXIT_VOID(); } static void Check_ExceptionClear(JNIEnv* env) { CHECK_JNI_ENTRY(kFlag_ExcepOkay, "E", env); baseEnv(env)->ExceptionClear(env); CHECK_JNI_EXIT_VOID(); } static void Check_FatalError(JNIEnv* env, const char* msg) { CHECK_JNI_ENTRY(kFlag_NullableUtf, "Eu", env, msg); baseEnv(env)->FatalError(env, msg); CHECK_JNI_EXIT_VOID(); } static jint Check_PushLocalFrame(JNIEnv* env, jint capacity) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EI", env, capacity); return CHECK_JNI_EXIT("I", baseEnv(env)->PushLocalFrame(env, capacity)); } static jobject Check_PopLocalFrame(JNIEnv* env, jobject res) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EL", env, res); return CHECK_JNI_EXIT("L", baseEnv(env)->PopLocalFrame(env, res)); } static jobject Check_NewGlobalRef(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); return CHECK_JNI_EXIT("L", baseEnv(env)->NewGlobalRef(env, obj)); } static void Check_DeleteGlobalRef(JNIEnv* env, jobject globalRef) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EL", env, globalRef); if (globalRef != NULL && dvmGetJNIRefType(sc.self(), globalRef) != JNIGlobalRefType) { ALOGW("JNI WARNING: DeleteGlobalRef on non-global %p (type=%d)", globalRef, dvmGetJNIRefType(sc.self(), globalRef)); abortMaybe(); } else { baseEnv(env)->DeleteGlobalRef(env, globalRef); CHECK_JNI_EXIT_VOID(); } } static jobject Check_NewLocalRef(JNIEnv* env, jobject ref) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, ref); return CHECK_JNI_EXIT("L", baseEnv(env)->NewLocalRef(env, ref)); } static void Check_DeleteLocalRef(JNIEnv* env, jobject localRef) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EL", env, localRef); if (localRef != NULL && dvmGetJNIRefType(sc.self(), localRef) != JNILocalRefType) { ALOGW("JNI WARNING: DeleteLocalRef on non-local %p (type=%d)", localRef, dvmGetJNIRefType(sc.self(), localRef)); abortMaybe(); } else { baseEnv(env)->DeleteLocalRef(env, localRef); CHECK_JNI_EXIT_VOID(); } } static jint Check_EnsureLocalCapacity(JNIEnv *env, jint capacity) { CHECK_JNI_ENTRY(kFlag_Default, "EI", env, capacity); return CHECK_JNI_EXIT("I", baseEnv(env)->EnsureLocalCapacity(env, capacity)); } static jboolean Check_IsSameObject(JNIEnv* env, jobject ref1, jobject ref2) { CHECK_JNI_ENTRY(kFlag_Default, "ELL", env, ref1, ref2); return CHECK_JNI_EXIT("b", baseEnv(env)->IsSameObject(env, ref1, ref2)); } static jobject Check_AllocObject(JNIEnv* env, jclass clazz) { CHECK_JNI_ENTRY(kFlag_Default, "Ec", env, clazz); return CHECK_JNI_EXIT("L", baseEnv(env)->AllocObject(env, clazz)); } static jobject Check_NewObject(JNIEnv* env, jclass clazz, jmethodID methodID, ...) { CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); va_list args; va_start(args, methodID); jobject result = baseEnv(env)->NewObjectV(env, clazz, methodID, args); va_end(args); return CHECK_JNI_EXIT("L", result); } static jobject Check_NewObjectV(JNIEnv* env, jclass clazz, jmethodID methodID, va_list args) { CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); return CHECK_JNI_EXIT("L", baseEnv(env)->NewObjectV(env, clazz, methodID, args)); } static jobject Check_NewObjectA(JNIEnv* env, jclass clazz, jmethodID methodID, jvalue* args) { CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); return CHECK_JNI_EXIT("L", baseEnv(env)->NewObjectA(env, clazz, methodID, args)); } static jclass Check_GetObjectClass(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); return CHECK_JNI_EXIT("c", baseEnv(env)->GetObjectClass(env, obj)); } static jboolean Check_IsInstanceOf(JNIEnv* env, jobject obj, jclass clazz) { CHECK_JNI_ENTRY(kFlag_Default, "ELc", env, obj, clazz); return CHECK_JNI_EXIT("b", baseEnv(env)->IsInstanceOf(env, obj, clazz)); } static jmethodID Check_GetMethodID(JNIEnv* env, jclass clazz, const char* name, const char* sig) { CHECK_JNI_ENTRY(kFlag_Default, "Ecuu", env, clazz, name, sig); return CHECK_JNI_EXIT("m", baseEnv(env)->GetMethodID(env, clazz, name, sig)); } static jfieldID Check_GetFieldID(JNIEnv* env, jclass clazz, const char* name, const char* sig) { CHECK_JNI_ENTRY(kFlag_Default, "Ecuu", env, clazz, name, sig); return CHECK_JNI_EXIT("f", baseEnv(env)->GetFieldID(env, clazz, name, sig)); } static jmethodID Check_GetStaticMethodID(JNIEnv* env, jclass clazz, const char* name, const char* sig) { CHECK_JNI_ENTRY(kFlag_Default, "Ecuu", env, clazz, name, sig); return CHECK_JNI_EXIT("m", baseEnv(env)->GetStaticMethodID(env, clazz, name, sig)); } static jfieldID Check_GetStaticFieldID(JNIEnv* env, jclass clazz, const char* name, const char* sig) { CHECK_JNI_ENTRY(kFlag_Default, "Ecuu", env, clazz, name, sig); return CHECK_JNI_EXIT("f", baseEnv(env)->GetStaticFieldID(env, clazz, name, sig)); } #define FIELD_ACCESSORS(_ctype, _jname, _ftype, _type) \ static _ctype Check_GetStatic##_jname##Field(JNIEnv* env, jclass clazz, jfieldID fieldID) { \ CHECK_JNI_ENTRY(kFlag_Default, "Ecf", env, clazz, fieldID); \ sc.checkStaticFieldID(clazz, fieldID); \ sc.checkFieldTypeForGet(fieldID, _type, true); \ return CHECK_JNI_EXIT(_type, baseEnv(env)->GetStatic##_jname##Field(env, clazz, fieldID)); \ } \ static _ctype Check_Get##_jname##Field(JNIEnv* env, jobject obj, jfieldID fieldID) { \ CHECK_JNI_ENTRY(kFlag_Default, "ELf", env, obj, fieldID); \ sc.checkInstanceFieldID(obj, fieldID); \ sc.checkFieldTypeForGet(fieldID, _type, false); \ return CHECK_JNI_EXIT(_type, baseEnv(env)->Get##_jname##Field(env, obj, fieldID)); \ } \ static void Check_SetStatic##_jname##Field(JNIEnv* env, jclass clazz, jfieldID fieldID, _ctype value) { \ CHECK_JNI_ENTRY(kFlag_Default, "Ecf" _type, env, clazz, fieldID, value); \ sc.checkStaticFieldID(clazz, fieldID); \ /* "value" arg only used when type == ref */ \ sc.checkFieldTypeForSet((jobject)(u4)value, fieldID, _ftype, true); \ baseEnv(env)->SetStatic##_jname##Field(env, clazz, fieldID, value); \ CHECK_JNI_EXIT_VOID(); \ } \ static void Check_Set##_jname##Field(JNIEnv* env, jobject obj, jfieldID fieldID, _ctype value) { \ CHECK_JNI_ENTRY(kFlag_Default, "ELf" _type, env, obj, fieldID, value); \ sc.checkInstanceFieldID(obj, fieldID); \ /* "value" arg only used when type == ref */ \ sc.checkFieldTypeForSet((jobject)(u4) value, fieldID, _ftype, false); \ baseEnv(env)->Set##_jname##Field(env, obj, fieldID, value); \ CHECK_JNI_EXIT_VOID(); \ } FIELD_ACCESSORS(jobject, Object, PRIM_NOT, "L"); FIELD_ACCESSORS(jboolean, Boolean, PRIM_BOOLEAN, "Z"); FIELD_ACCESSORS(jbyte, Byte, PRIM_BYTE, "B"); FIELD_ACCESSORS(jchar, Char, PRIM_CHAR, "C"); FIELD_ACCESSORS(jshort, Short, PRIM_SHORT, "S"); FIELD_ACCESSORS(jint, Int, PRIM_INT, "I"); FIELD_ACCESSORS(jlong, Long, PRIM_LONG, "J"); FIELD_ACCESSORS(jfloat, Float, PRIM_FLOAT, "F"); FIELD_ACCESSORS(jdouble, Double, PRIM_DOUBLE, "D"); #define CALL(_ctype, _jname, _retdecl, _retasgn, _retok, _retsig) \ /* Virtual... */ \ static _ctype Check_Call##_jname##Method(JNIEnv* env, jobject obj, \ jmethodID methodID, ...) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELm.", env, obj, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ va_list args; \ va_start(args, methodID); \ _retasgn baseEnv(env)->Call##_jname##MethodV(env, obj, methodID, args); \ va_end(args); \ _retok; \ } \ static _ctype Check_Call##_jname##MethodV(JNIEnv* env, jobject obj, \ jmethodID methodID, va_list args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELm.", env, obj, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ _retasgn baseEnv(env)->Call##_jname##MethodV(env, obj, methodID, args); \ _retok; \ } \ static _ctype Check_Call##_jname##MethodA(JNIEnv* env, jobject obj, \ jmethodID methodID, jvalue* args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELm.", env, obj, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ _retasgn baseEnv(env)->Call##_jname##MethodA(env, obj, methodID, args); \ _retok; \ } \ /* Non-virtual... */ \ static _ctype Check_CallNonvirtual##_jname##Method(JNIEnv* env, \ jobject obj, jclass clazz, jmethodID methodID, ...) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELcm.", env, obj, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ va_list args; \ va_start(args, methodID); \ _retasgn baseEnv(env)->CallNonvirtual##_jname##MethodV(env, obj, clazz, methodID, args); \ va_end(args); \ _retok; \ } \ static _ctype Check_CallNonvirtual##_jname##MethodV(JNIEnv* env, \ jobject obj, jclass clazz, jmethodID methodID, va_list args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELcm.", env, obj, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ _retasgn baseEnv(env)->CallNonvirtual##_jname##MethodV(env, obj, clazz, methodID, args); \ _retok; \ } \ static _ctype Check_CallNonvirtual##_jname##MethodA(JNIEnv* env, \ jobject obj, jclass clazz, jmethodID methodID, jvalue* args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "ELcm.", env, obj, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, false); \ sc.checkVirtualMethod(obj, methodID); \ _retdecl; \ _retasgn baseEnv(env)->CallNonvirtual##_jname##MethodA(env, obj, clazz, methodID, args); \ _retok; \ } \ /* Static... */ \ static _ctype Check_CallStatic##_jname##Method(JNIEnv* env, \ jclass clazz, jmethodID methodID, ...) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, true); \ sc.checkStaticMethod(clazz, methodID); \ _retdecl; \ va_list args; \ va_start(args, methodID); \ _retasgn baseEnv(env)->CallStatic##_jname##MethodV(env, clazz, methodID, args); \ va_end(args); \ _retok; \ } \ static _ctype Check_CallStatic##_jname##MethodV(JNIEnv* env, \ jclass clazz, jmethodID methodID, va_list args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, true); \ sc.checkStaticMethod(clazz, methodID); \ _retdecl; \ _retasgn baseEnv(env)->CallStatic##_jname##MethodV(env, clazz, methodID, args); \ _retok; \ } \ static _ctype Check_CallStatic##_jname##MethodA(JNIEnv* env, \ jclass clazz, jmethodID methodID, jvalue* args) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "Ecm.", env, clazz, methodID); /* TODO: args! */ \ sc.checkSig(methodID, _retsig, true); \ sc.checkStaticMethod(clazz, methodID); \ _retdecl; \ _retasgn baseEnv(env)->CallStatic##_jname##MethodA(env, clazz, methodID, args); \ _retok; \ } #define NON_VOID_RETURN(_retsig, _ctype) return CHECK_JNI_EXIT(_retsig, (_ctype) result) #define VOID_RETURN CHECK_JNI_EXIT_VOID() CALL(jobject, Object, Object* result, result=(Object*), NON_VOID_RETURN("L", jobject), "L"); CALL(jboolean, Boolean, jboolean result, result=, NON_VOID_RETURN("Z", jboolean), "Z"); CALL(jbyte, Byte, jbyte result, result=, NON_VOID_RETURN("B", jbyte), "B"); CALL(jchar, Char, jchar result, result=, NON_VOID_RETURN("C", jchar), "C"); CALL(jshort, Short, jshort result, result=, NON_VOID_RETURN("S", jshort), "S"); CALL(jint, Int, jint result, result=, NON_VOID_RETURN("I", jint), "I"); CALL(jlong, Long, jlong result, result=, NON_VOID_RETURN("J", jlong), "J"); CALL(jfloat, Float, jfloat result, result=, NON_VOID_RETURN("F", jfloat), "F"); CALL(jdouble, Double, jdouble result, result=, NON_VOID_RETURN("D", jdouble), "D"); CALL(void, Void, , , VOID_RETURN, "V"); static jstring Check_NewString(JNIEnv* env, const jchar* unicodeChars, jsize len) { CHECK_JNI_ENTRY(kFlag_Default, "Epz", env, unicodeChars, len); return CHECK_JNI_EXIT("s", baseEnv(env)->NewString(env, unicodeChars, len)); } static jsize Check_GetStringLength(JNIEnv* env, jstring string) { CHECK_JNI_ENTRY(kFlag_CritOkay, "Es", env, string); return CHECK_JNI_EXIT("I", baseEnv(env)->GetStringLength(env, string)); } static const jchar* Check_GetStringChars(JNIEnv* env, jstring string, jboolean* isCopy) { CHECK_JNI_ENTRY(kFlag_CritOkay, "Esp", env, string, isCopy); const jchar* result = baseEnv(env)->GetStringChars(env, string, isCopy); if (gDvmJni.forceCopy && result != NULL) { ScopedCheckJniThreadState ts(env); StringObject* strObj = (StringObject*) dvmDecodeIndirectRef(dvmThreadSelf(), string); int byteCount = strObj->length() * 2; result = (const jchar*) GuardedCopy::create(result, byteCount, false); if (isCopy != NULL) { *isCopy = JNI_TRUE; } } return CHECK_JNI_EXIT("p", result); } static void Check_ReleaseStringChars(JNIEnv* env, jstring string, const jchar* chars) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "Esp", env, string, chars); sc.checkNonNull(chars); if (gDvmJni.forceCopy) { if (!GuardedCopy::check(chars, false)) { ALOGE("JNI: failed guarded copy check in ReleaseStringChars"); abortMaybe(); return; } chars = (const jchar*) GuardedCopy::destroy((jchar*)chars); } baseEnv(env)->ReleaseStringChars(env, string, chars); CHECK_JNI_EXIT_VOID(); } static jstring Check_NewStringUTF(JNIEnv* env, const char* bytes) { CHECK_JNI_ENTRY(kFlag_NullableUtf, "Eu", env, bytes); // TODO: show pointer and truncate string. return CHECK_JNI_EXIT("s", baseEnv(env)->NewStringUTF(env, bytes)); } static jsize Check_GetStringUTFLength(JNIEnv* env, jstring string) { CHECK_JNI_ENTRY(kFlag_CritOkay, "Es", env, string); return CHECK_JNI_EXIT("I", baseEnv(env)->GetStringUTFLength(env, string)); } static const char* Check_GetStringUTFChars(JNIEnv* env, jstring string, jboolean* isCopy) { CHECK_JNI_ENTRY(kFlag_CritOkay, "Esp", env, string, isCopy); const char* result = baseEnv(env)->GetStringUTFChars(env, string, isCopy); if (gDvmJni.forceCopy && result != NULL) { result = (const char*) GuardedCopy::create(result, strlen(result) + 1, false); if (isCopy != NULL) { *isCopy = JNI_TRUE; } } return CHECK_JNI_EXIT("u", result); // TODO: show pointer and truncate string. } static void Check_ReleaseStringUTFChars(JNIEnv* env, jstring string, const char* utf) { CHECK_JNI_ENTRY(kFlag_ExcepOkay | kFlag_Release, "Esu", env, string, utf); // TODO: show pointer and truncate string. if (gDvmJni.forceCopy) { if (!GuardedCopy::check(utf, false)) { ALOGE("JNI: failed guarded copy check in ReleaseStringUTFChars"); abortMaybe(); return; } utf = (const char*) GuardedCopy::destroy((char*)utf); } baseEnv(env)->ReleaseStringUTFChars(env, string, utf); CHECK_JNI_EXIT_VOID(); } static jsize Check_GetArrayLength(JNIEnv* env, jarray array) { CHECK_JNI_ENTRY(kFlag_CritOkay, "Ea", env, array); return CHECK_JNI_EXIT("I", baseEnv(env)->GetArrayLength(env, array)); } static jobjectArray Check_NewObjectArray(JNIEnv* env, jsize length, jclass elementClass, jobject initialElement) { CHECK_JNI_ENTRY(kFlag_Default, "EzcL", env, length, elementClass, initialElement); return CHECK_JNI_EXIT("a", baseEnv(env)->NewObjectArray(env, length, elementClass, initialElement)); } static jobject Check_GetObjectArrayElement(JNIEnv* env, jobjectArray array, jsize index) { CHECK_JNI_ENTRY(kFlag_Default, "EaI", env, array, index); return CHECK_JNI_EXIT("L", baseEnv(env)->GetObjectArrayElement(env, array, index)); } static void Check_SetObjectArrayElement(JNIEnv* env, jobjectArray array, jsize index, jobject value) { CHECK_JNI_ENTRY(kFlag_Default, "EaIL", env, array, index, value); baseEnv(env)->SetObjectArrayElement(env, array, index, value); CHECK_JNI_EXIT_VOID(); } #define NEW_PRIMITIVE_ARRAY(_artype, _jname) \ static _artype Check_New##_jname##Array(JNIEnv* env, jsize length) { \ CHECK_JNI_ENTRY(kFlag_Default, "Ez", env, length); \ return CHECK_JNI_EXIT("a", baseEnv(env)->New##_jname##Array(env, length)); \ } NEW_PRIMITIVE_ARRAY(jbooleanArray, Boolean); NEW_PRIMITIVE_ARRAY(jbyteArray, Byte); NEW_PRIMITIVE_ARRAY(jcharArray, Char); NEW_PRIMITIVE_ARRAY(jshortArray, Short); NEW_PRIMITIVE_ARRAY(jintArray, Int); NEW_PRIMITIVE_ARRAY(jlongArray, Long); NEW_PRIMITIVE_ARRAY(jfloatArray, Float); NEW_PRIMITIVE_ARRAY(jdoubleArray, Double); /* * Hack to allow forcecopy to work with jniGetNonMovableArrayElements. * The code deliberately uses an invalid sequence of operations, so we * need to pass it through unmodified. Review that code before making * any changes here. */ #define kNoCopyMagic 0xd5aab57f #define GET_PRIMITIVE_ARRAY_ELEMENTS(_ctype, _jname) \ static _ctype* Check_Get##_jname##ArrayElements(JNIEnv* env, \ _ctype##Array array, jboolean* isCopy) \ { \ CHECK_JNI_ENTRY(kFlag_Default, "Eap", env, array, isCopy); \ u4 noCopy = 0; \ if (gDvmJni.forceCopy && isCopy != NULL) { \ /* capture this before the base call tramples on it */ \ noCopy = *(u4*) isCopy; \ } \ _ctype* result = baseEnv(env)->Get##_jname##ArrayElements(env, array, isCopy); \ if (gDvmJni.forceCopy && result != NULL) { \ if (noCopy == kNoCopyMagic) { \ ALOGV("FC: not copying %p %x", array, noCopy); \ } else { \ result = (_ctype*) createGuardedPACopy(env, array, isCopy); \ } \ } \ return CHECK_JNI_EXIT("p", result); \ } #define RELEASE_PRIMITIVE_ARRAY_ELEMENTS(_ctype, _jname) \ static void Check_Release##_jname##ArrayElements(JNIEnv* env, \ _ctype##Array array, _ctype* elems, jint mode) \ { \ CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "Eapr", env, array, elems, mode); \ sc.checkNonNull(elems); \ if (gDvmJni.forceCopy) { \ if ((uintptr_t)elems == kNoCopyMagic) { \ ALOGV("FC: not freeing %p", array); \ elems = NULL; /* base JNI call doesn't currently need */ \ } else { \ elems = (_ctype*) releaseGuardedPACopy(env, array, elems, mode); \ } \ } \ baseEnv(env)->Release##_jname##ArrayElements(env, array, elems, mode); \ CHECK_JNI_EXIT_VOID(); \ } #define GET_PRIMITIVE_ARRAY_REGION(_ctype, _jname) \ static void Check_Get##_jname##ArrayRegion(JNIEnv* env, \ _ctype##Array array, jsize start, jsize len, _ctype* buf) { \ CHECK_JNI_ENTRY(kFlag_Default, "EaIIp", env, array, start, len, buf); \ baseEnv(env)->Get##_jname##ArrayRegion(env, array, start, len, buf); \ CHECK_JNI_EXIT_VOID(); \ } #define SET_PRIMITIVE_ARRAY_REGION(_ctype, _jname) \ static void Check_Set##_jname##ArrayRegion(JNIEnv* env, \ _ctype##Array array, jsize start, jsize len, const _ctype* buf) { \ CHECK_JNI_ENTRY(kFlag_Default, "EaIIp", env, array, start, len, buf); \ baseEnv(env)->Set##_jname##ArrayRegion(env, array, start, len, buf); \ CHECK_JNI_EXIT_VOID(); \ } #define PRIMITIVE_ARRAY_FUNCTIONS(_ctype, _jname, _typechar) \ GET_PRIMITIVE_ARRAY_ELEMENTS(_ctype, _jname); \ RELEASE_PRIMITIVE_ARRAY_ELEMENTS(_ctype, _jname); \ GET_PRIMITIVE_ARRAY_REGION(_ctype, _jname); \ SET_PRIMITIVE_ARRAY_REGION(_ctype, _jname); /* TODO: verify primitive array type matches call type */ PRIMITIVE_ARRAY_FUNCTIONS(jboolean, Boolean, 'Z'); PRIMITIVE_ARRAY_FUNCTIONS(jbyte, Byte, 'B'); PRIMITIVE_ARRAY_FUNCTIONS(jchar, Char, 'C'); PRIMITIVE_ARRAY_FUNCTIONS(jshort, Short, 'S'); PRIMITIVE_ARRAY_FUNCTIONS(jint, Int, 'I'); PRIMITIVE_ARRAY_FUNCTIONS(jlong, Long, 'J'); PRIMITIVE_ARRAY_FUNCTIONS(jfloat, Float, 'F'); PRIMITIVE_ARRAY_FUNCTIONS(jdouble, Double, 'D'); static jint Check_RegisterNatives(JNIEnv* env, jclass clazz, const JNINativeMethod* methods, jint nMethods) { CHECK_JNI_ENTRY(kFlag_Default, "EcpI", env, clazz, methods, nMethods); return CHECK_JNI_EXIT("I", baseEnv(env)->RegisterNatives(env, clazz, methods, nMethods)); } static jint Check_UnregisterNatives(JNIEnv* env, jclass clazz) { CHECK_JNI_ENTRY(kFlag_Default, "Ec", env, clazz); return CHECK_JNI_EXIT("I", baseEnv(env)->UnregisterNatives(env, clazz)); } static jint Check_MonitorEnter(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); return CHECK_JNI_EXIT("I", baseEnv(env)->MonitorEnter(env, obj)); } static jint Check_MonitorExit(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EL", env, obj); return CHECK_JNI_EXIT("I", baseEnv(env)->MonitorExit(env, obj)); } static jint Check_GetJavaVM(JNIEnv *env, JavaVM **vm) { CHECK_JNI_ENTRY(kFlag_Default, "Ep", env, vm); return CHECK_JNI_EXIT("I", baseEnv(env)->GetJavaVM(env, vm)); } static void Check_GetStringRegion(JNIEnv* env, jstring str, jsize start, jsize len, jchar* buf) { CHECK_JNI_ENTRY(kFlag_CritOkay, "EsIIp", env, str, start, len, buf); baseEnv(env)->GetStringRegion(env, str, start, len, buf); CHECK_JNI_EXIT_VOID(); } static void Check_GetStringUTFRegion(JNIEnv* env, jstring str, jsize start, jsize len, char* buf) { CHECK_JNI_ENTRY(kFlag_CritOkay, "EsIIp", env, str, start, len, buf); baseEnv(env)->GetStringUTFRegion(env, str, start, len, buf); CHECK_JNI_EXIT_VOID(); } static void* Check_GetPrimitiveArrayCritical(JNIEnv* env, jarray array, jboolean* isCopy) { CHECK_JNI_ENTRY(kFlag_CritGet, "Eap", env, array, isCopy); void* result = baseEnv(env)->GetPrimitiveArrayCritical(env, array, isCopy); if (gDvmJni.forceCopy && result != NULL) { result = createGuardedPACopy(env, array, isCopy); } return CHECK_JNI_EXIT("p", result); } static void Check_ReleasePrimitiveArrayCritical(JNIEnv* env, jarray array, void* carray, jint mode) { CHECK_JNI_ENTRY(kFlag_CritRelease | kFlag_ExcepOkay, "Eapr", env, array, carray, mode); sc.checkNonNull(carray); if (gDvmJni.forceCopy) { carray = releaseGuardedPACopy(env, array, carray, mode); } baseEnv(env)->ReleasePrimitiveArrayCritical(env, array, carray, mode); CHECK_JNI_EXIT_VOID(); } static const jchar* Check_GetStringCritical(JNIEnv* env, jstring string, jboolean* isCopy) { CHECK_JNI_ENTRY(kFlag_CritGet, "Esp", env, string, isCopy); const jchar* result = baseEnv(env)->GetStringCritical(env, string, isCopy); if (gDvmJni.forceCopy && result != NULL) { ScopedCheckJniThreadState ts(env); StringObject* strObj = (StringObject*) dvmDecodeIndirectRef(dvmThreadSelf(), string); int byteCount = strObj->length() * 2; result = (const jchar*) GuardedCopy::create(result, byteCount, false); if (isCopy != NULL) { *isCopy = JNI_TRUE; } } return CHECK_JNI_EXIT("p", result); } static void Check_ReleaseStringCritical(JNIEnv* env, jstring string, const jchar* carray) { CHECK_JNI_ENTRY(kFlag_CritRelease | kFlag_ExcepOkay, "Esp", env, string, carray); sc.checkNonNull(carray); if (gDvmJni.forceCopy) { if (!GuardedCopy::check(carray, false)) { ALOGE("JNI: failed guarded copy check in ReleaseStringCritical"); abortMaybe(); return; } carray = (const jchar*) GuardedCopy::destroy((jchar*)carray); } baseEnv(env)->ReleaseStringCritical(env, string, carray); CHECK_JNI_EXIT_VOID(); } static jweak Check_NewWeakGlobalRef(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); return CHECK_JNI_EXIT("L", baseEnv(env)->NewWeakGlobalRef(env, obj)); } static void Check_DeleteWeakGlobalRef(JNIEnv* env, jweak obj) { CHECK_JNI_ENTRY(kFlag_Default | kFlag_ExcepOkay, "EL", env, obj); baseEnv(env)->DeleteWeakGlobalRef(env, obj); CHECK_JNI_EXIT_VOID(); } static jboolean Check_ExceptionCheck(JNIEnv* env) { CHECK_JNI_ENTRY(kFlag_CritOkay | kFlag_ExcepOkay, "E", env); return CHECK_JNI_EXIT("b", baseEnv(env)->ExceptionCheck(env)); } static jobjectRefType Check_GetObjectRefType(JNIEnv* env, jobject obj) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, obj); // TODO: proper decoding of jobjectRefType! return CHECK_JNI_EXIT("I", baseEnv(env)->GetObjectRefType(env, obj)); } static jobject Check_NewDirectByteBuffer(JNIEnv* env, void* address, jlong capacity) { CHECK_JNI_ENTRY(kFlag_Default, "EpJ", env, address, capacity); return CHECK_JNI_EXIT("L", baseEnv(env)->NewDirectByteBuffer(env, address, capacity)); } static void* Check_GetDirectBufferAddress(JNIEnv* env, jobject buf) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, buf); // TODO: check that 'buf' is a java.nio.Buffer. return CHECK_JNI_EXIT("p", baseEnv(env)->GetDirectBufferAddress(env, buf)); } static jlong Check_GetDirectBufferCapacity(JNIEnv* env, jobject buf) { CHECK_JNI_ENTRY(kFlag_Default, "EL", env, buf); // TODO: check that 'buf' is a java.nio.Buffer. return CHECK_JNI_EXIT("J", baseEnv(env)->GetDirectBufferCapacity(env, buf)); } /* * =========================================================================== * JNI invocation functions * =========================================================================== */ static jint Check_DestroyJavaVM(JavaVM* vm) { ScopedCheck sc(false, __FUNCTION__); sc.check(true, "v", vm); return CHECK_JNI_EXIT("I", baseVm(vm)->DestroyJavaVM(vm)); } static jint Check_AttachCurrentThread(JavaVM* vm, JNIEnv** p_env, void* thr_args) { ScopedCheck sc(false, __FUNCTION__); sc.check(true, "vpt", vm, p_env, thr_args); return CHECK_JNI_EXIT("I", baseVm(vm)->AttachCurrentThread(vm, p_env, thr_args)); } static jint Check_AttachCurrentThreadAsDaemon(JavaVM* vm, JNIEnv** p_env, void* thr_args) { ScopedCheck sc(false, __FUNCTION__); sc.check(true, "vpt", vm, p_env, thr_args); return CHECK_JNI_EXIT("I", baseVm(vm)->AttachCurrentThreadAsDaemon(vm, p_env, thr_args)); } static jint Check_DetachCurrentThread(JavaVM* vm) { ScopedCheck sc(true, __FUNCTION__); sc.check(true, "v", vm); return CHECK_JNI_EXIT("I", baseVm(vm)->DetachCurrentThread(vm)); } static jint Check_GetEnv(JavaVM* vm, void** env, jint version) { ScopedCheck sc(true, __FUNCTION__); sc.check(true, "v", vm); return CHECK_JNI_EXIT("I", baseVm(vm)->GetEnv(vm, env, version)); } /* * =========================================================================== * Function tables * =========================================================================== */ static const struct JNINativeInterface gCheckNativeInterface = { NULL, NULL, NULL, NULL, Check_GetVersion, Check_DefineClass, Check_FindClass, Check_FromReflectedMethod, Check_FromReflectedField, Check_ToReflectedMethod, Check_GetSuperclass, Check_IsAssignableFrom, Check_ToReflectedField, Check_Throw, Check_ThrowNew, Check_ExceptionOccurred, Check_ExceptionDescribe, Check_ExceptionClear, Check_FatalError, Check_PushLocalFrame, Check_PopLocalFrame, Check_NewGlobalRef, Check_DeleteGlobalRef, Check_DeleteLocalRef, Check_IsSameObject, Check_NewLocalRef, Check_EnsureLocalCapacity, Check_AllocObject, Check_NewObject, Check_NewObjectV, Check_NewObjectA, Check_GetObjectClass, Check_IsInstanceOf, Check_GetMethodID, Check_CallObjectMethod, Check_CallObjectMethodV, Check_CallObjectMethodA, Check_CallBooleanMethod, Check_CallBooleanMethodV, Check_CallBooleanMethodA, Check_CallByteMethod, Check_CallByteMethodV, Check_CallByteMethodA, Check_CallCharMethod, Check_CallCharMethodV, Check_CallCharMethodA, Check_CallShortMethod, Check_CallShortMethodV, Check_CallShortMethodA, Check_CallIntMethod, Check_CallIntMethodV, Check_CallIntMethodA, Check_CallLongMethod, Check_CallLongMethodV, Check_CallLongMethodA, Check_CallFloatMethod, Check_CallFloatMethodV, Check_CallFloatMethodA, Check_CallDoubleMethod, Check_CallDoubleMethodV, Check_CallDoubleMethodA, Check_CallVoidMethod, Check_CallVoidMethodV, Check_CallVoidMethodA, Check_CallNonvirtualObjectMethod, Check_CallNonvirtualObjectMethodV, Check_CallNonvirtualObjectMethodA, Check_CallNonvirtualBooleanMethod, Check_CallNonvirtualBooleanMethodV, Check_CallNonvirtualBooleanMethodA, Check_CallNonvirtualByteMethod, Check_CallNonvirtualByteMethodV, Check_CallNonvirtualByteMethodA, Check_CallNonvirtualCharMethod, Check_CallNonvirtualCharMethodV, Check_CallNonvirtualCharMethodA, Check_CallNonvirtualShortMethod, Check_CallNonvirtualShortMethodV, Check_CallNonvirtualShortMethodA, Check_CallNonvirtualIntMethod, Check_CallNonvirtualIntMethodV, Check_CallNonvirtualIntMethodA, Check_CallNonvirtualLongMethod, Check_CallNonvirtualLongMethodV, Check_CallNonvirtualLongMethodA, Check_CallNonvirtualFloatMethod, Check_CallNonvirtualFloatMethodV, Check_CallNonvirtualFloatMethodA, Check_CallNonvirtualDoubleMethod, Check_CallNonvirtualDoubleMethodV, Check_CallNonvirtualDoubleMethodA, Check_CallNonvirtualVoidMethod, Check_CallNonvirtualVoidMethodV, Check_CallNonvirtualVoidMethodA, Check_GetFieldID, Check_GetObjectField, Check_GetBooleanField, Check_GetByteField, Check_GetCharField, Check_GetShortField, Check_GetIntField, Check_GetLongField, Check_GetFloatField, Check_GetDoubleField, Check_SetObjectField, Check_SetBooleanField, Check_SetByteField, Check_SetCharField, Check_SetShortField, Check_SetIntField, Check_SetLongField, Check_SetFloatField, Check_SetDoubleField, Check_GetStaticMethodID, Check_CallStaticObjectMethod, Check_CallStaticObjectMethodV, Check_CallStaticObjectMethodA, Check_CallStaticBooleanMethod, Check_CallStaticBooleanMethodV, Check_CallStaticBooleanMethodA, Check_CallStaticByteMethod, Check_CallStaticByteMethodV, Check_CallStaticByteMethodA, Check_CallStaticCharMethod, Check_CallStaticCharMethodV, Check_CallStaticCharMethodA, Check_CallStaticShortMethod, Check_CallStaticShortMethodV, Check_CallStaticShortMethodA, Check_CallStaticIntMethod, Check_CallStaticIntMethodV, Check_CallStaticIntMethodA, Check_CallStaticLongMethod, Check_CallStaticLongMethodV, Check_CallStaticLongMethodA, Check_CallStaticFloatMethod, Check_CallStaticFloatMethodV, Check_CallStaticFloatMethodA, Check_CallStaticDoubleMethod, Check_CallStaticDoubleMethodV, Check_CallStaticDoubleMethodA, Check_CallStaticVoidMethod, Check_CallStaticVoidMethodV, Check_CallStaticVoidMethodA, Check_GetStaticFieldID, Check_GetStaticObjectField, Check_GetStaticBooleanField, Check_GetStaticByteField, Check_GetStaticCharField, Check_GetStaticShortField, Check_GetStaticIntField, Check_GetStaticLongField, Check_GetStaticFloatField, Check_GetStaticDoubleField, Check_SetStaticObjectField, Check_SetStaticBooleanField, Check_SetStaticByteField, Check_SetStaticCharField, Check_SetStaticShortField, Check_SetStaticIntField, Check_SetStaticLongField, Check_SetStaticFloatField, Check_SetStaticDoubleField, Check_NewString, Check_GetStringLength, Check_GetStringChars, Check_ReleaseStringChars, Check_NewStringUTF, Check_GetStringUTFLength, Check_GetStringUTFChars, Check_ReleaseStringUTFChars, Check_GetArrayLength, Check_NewObjectArray, Check_GetObjectArrayElement, Check_SetObjectArrayElement, Check_NewBooleanArray, Check_NewByteArray, Check_NewCharArray, Check_NewShortArray, Check_NewIntArray, Check_NewLongArray, Check_NewFloatArray, Check_NewDoubleArray, Check_GetBooleanArrayElements, Check_GetByteArrayElements, Check_GetCharArrayElements, Check_GetShortArrayElements, Check_GetIntArrayElements, Check_GetLongArrayElements, Check_GetFloatArrayElements, Check_GetDoubleArrayElements, Check_ReleaseBooleanArrayElements, Check_ReleaseByteArrayElements, Check_ReleaseCharArrayElements, Check_ReleaseShortArrayElements, Check_ReleaseIntArrayElements, Check_ReleaseLongArrayElements, Check_ReleaseFloatArrayElements, Check_ReleaseDoubleArrayElements, Check_GetBooleanArrayRegion, Check_GetByteArrayRegion, Check_GetCharArrayRegion, Check_GetShortArrayRegion, Check_GetIntArrayRegion, Check_GetLongArrayRegion, Check_GetFloatArrayRegion, Check_GetDoubleArrayRegion, Check_SetBooleanArrayRegion, Check_SetByteArrayRegion, Check_SetCharArrayRegion, Check_SetShortArrayRegion, Check_SetIntArrayRegion, Check_SetLongArrayRegion, Check_SetFloatArrayRegion, Check_SetDoubleArrayRegion, Check_RegisterNatives, Check_UnregisterNatives, Check_MonitorEnter, Check_MonitorExit, Check_GetJavaVM, Check_GetStringRegion, Check_GetStringUTFRegion, Check_GetPrimitiveArrayCritical, Check_ReleasePrimitiveArrayCritical, Check_GetStringCritical, Check_ReleaseStringCritical, Check_NewWeakGlobalRef, Check_DeleteWeakGlobalRef, Check_ExceptionCheck, Check_NewDirectByteBuffer, Check_GetDirectBufferAddress, Check_GetDirectBufferCapacity, Check_GetObjectRefType }; static const struct JNIInvokeInterface gCheckInvokeInterface = { NULL, NULL, NULL, Check_DestroyJavaVM, Check_AttachCurrentThread, Check_DetachCurrentThread, Check_GetEnv, Check_AttachCurrentThreadAsDaemon, }; /* * Replace the normal table with the checked table. */ void dvmUseCheckedJniEnv(JNIEnvExt* pEnv) { assert(pEnv->funcTable != &gCheckNativeInterface); pEnv->baseFuncTable = pEnv->funcTable; pEnv->funcTable = &gCheckNativeInterface; } /* * Replace the normal table with the checked table. */ void dvmUseCheckedJniVm(JavaVMExt* pVm) { assert(pVm->funcTable != &gCheckInvokeInterface); pVm->baseFuncTable = pVm->funcTable; pVm->funcTable = &gCheckInvokeInterface; }