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/*
* Copyright (C) 2012 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.
*/
#include "interpreter.h"
#include <limits>
#include "common_dex_operations.h"
#include "common_throws.h"
#include "dex/dex_file_types.h"
#include "interpreter_common.h"
#include "interpreter_mterp_impl.h"
#include "interpreter_switch_impl.h"
#include "jit/jit.h"
#include "jit/jit_code_cache.h"
#include "jvalue-inl.h"
#include "mirror/string-inl.h"
#include "mterp/mterp.h"
#include "nativehelper/scoped_local_ref.h"
#include "scoped_thread_state_change-inl.h"
#include "shadow_frame-inl.h"
#include "stack.h"
#include "thread-inl.h"
#include "unstarted_runtime.h"
namespace art {
namespace interpreter {
ALWAYS_INLINE static ObjPtr<mirror::Object> ObjArg(uint32_t arg)
REQUIRES_SHARED(Locks::mutator_lock_) {
return ObjPtr<mirror::Object>(reinterpret_cast<mirror::Object*>(arg));
}
static void InterpreterJni(Thread* self,
ArtMethod* method,
const StringPiece& shorty,
ObjPtr<mirror::Object> receiver,
uint32_t* args,
JValue* result)
REQUIRES_SHARED(Locks::mutator_lock_) {
// TODO: The following enters JNI code using a typedef-ed function rather than the JNI compiler,
// it should be removed and JNI compiled stubs used instead.
ScopedObjectAccessUnchecked soa(self);
if (method->IsStatic()) {
if (shorty == "L") {
typedef jobject (fntype)(JNIEnv*, jclass);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
jobject jresult;
{
ScopedThreadStateChange tsc(self, kNative);
jresult = fn(soa.Env(), klass.get());
}
result->SetL(soa.Decode<mirror::Object>(jresult));
} else if (shorty == "V") {
typedef void (fntype)(JNIEnv*, jclass);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
fn(soa.Env(), klass.get());
} else if (shorty == "Z") {
typedef jboolean (fntype)(JNIEnv*, jclass);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
result->SetZ(fn(soa.Env(), klass.get()));
} else if (shorty == "BI") {
typedef jbyte (fntype)(JNIEnv*, jclass, jint);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
result->SetB(fn(soa.Env(), klass.get(), args[0]));
} else if (shorty == "II") {
typedef jint (fntype)(JNIEnv*, jclass, jint);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
result->SetI(fn(soa.Env(), klass.get(), args[0]));
} else if (shorty == "LL") {
typedef jobject (fntype)(JNIEnv*, jclass, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg0(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[0])));
jobject jresult;
{
ScopedThreadStateChange tsc(self, kNative);
jresult = fn(soa.Env(), klass.get(), arg0.get());
}
result->SetL(soa.Decode<mirror::Object>(jresult));
} else if (shorty == "IIZ") {
typedef jint (fntype)(JNIEnv*, jclass, jint, jboolean);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
result->SetI(fn(soa.Env(), klass.get(), args[0], args[1]));
} else if (shorty == "ILI") {
typedef jint (fntype)(JNIEnv*, jclass, jobject, jint);
fntype* const fn = reinterpret_cast<fntype*>(const_cast<void*>(
method->GetEntryPointFromJni()));
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg0(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[0])));
ScopedThreadStateChange tsc(self, kNative);
result->SetI(fn(soa.Env(), klass.get(), arg0.get(), args[1]));
} else if (shorty == "SIZ") {
typedef jshort (fntype)(JNIEnv*, jclass, jint, jboolean);
fntype* const fn =
reinterpret_cast<fntype*>(const_cast<void*>(method->GetEntryPointFromJni()));
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
result->SetS(fn(soa.Env(), klass.get(), args[0], args[1]));
} else if (shorty == "VIZ") {
typedef void (fntype)(JNIEnv*, jclass, jint, jboolean);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedThreadStateChange tsc(self, kNative);
fn(soa.Env(), klass.get(), args[0], args[1]);
} else if (shorty == "ZLL") {
typedef jboolean (fntype)(JNIEnv*, jclass, jobject, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg0(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[0])));
ScopedLocalRef<jobject> arg1(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[1])));
ScopedThreadStateChange tsc(self, kNative);
result->SetZ(fn(soa.Env(), klass.get(), arg0.get(), arg1.get()));
} else if (shorty == "ZILL") {
typedef jboolean (fntype)(JNIEnv*, jclass, jint, jobject, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg1(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[1])));
ScopedLocalRef<jobject> arg2(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[2])));
ScopedThreadStateChange tsc(self, kNative);
result->SetZ(fn(soa.Env(), klass.get(), args[0], arg1.get(), arg2.get()));
} else if (shorty == "VILII") {
typedef void (fntype)(JNIEnv*, jclass, jint, jobject, jint, jint);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg1(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[1])));
ScopedThreadStateChange tsc(self, kNative);
fn(soa.Env(), klass.get(), args[0], arg1.get(), args[2], args[3]);
} else if (shorty == "VLILII") {
typedef void (fntype)(JNIEnv*, jclass, jobject, jint, jobject, jint, jint);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jclass> klass(soa.Env(),
soa.AddLocalReference<jclass>(method->GetDeclaringClass()));
ScopedLocalRef<jobject> arg0(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[0])));
ScopedLocalRef<jobject> arg2(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[2])));
ScopedThreadStateChange tsc(self, kNative);
fn(soa.Env(), klass.get(), arg0.get(), args[1], arg2.get(), args[3], args[4]);
} else {
LOG(FATAL) << "Do something with static native method: " << method->PrettyMethod()
<< " shorty: " << shorty;
}
} else {
if (shorty == "L") {
typedef jobject (fntype)(JNIEnv*, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jobject> rcvr(soa.Env(),
soa.AddLocalReference<jobject>(receiver));
jobject jresult;
{
ScopedThreadStateChange tsc(self, kNative);
jresult = fn(soa.Env(), rcvr.get());
}
result->SetL(soa.Decode<mirror::Object>(jresult));
} else if (shorty == "V") {
typedef void (fntype)(JNIEnv*, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jobject> rcvr(soa.Env(),
soa.AddLocalReference<jobject>(receiver));
ScopedThreadStateChange tsc(self, kNative);
fn(soa.Env(), rcvr.get());
} else if (shorty == "LL") {
typedef jobject (fntype)(JNIEnv*, jobject, jobject);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jobject> rcvr(soa.Env(),
soa.AddLocalReference<jobject>(receiver));
ScopedLocalRef<jobject> arg0(soa.Env(),
soa.AddLocalReference<jobject>(ObjArg(args[0])));
jobject jresult;
{
ScopedThreadStateChange tsc(self, kNative);
jresult = fn(soa.Env(), rcvr.get(), arg0.get());
}
result->SetL(soa.Decode<mirror::Object>(jresult));
ScopedThreadStateChange tsc(self, kNative);
} else if (shorty == "III") {
typedef jint (fntype)(JNIEnv*, jobject, jint, jint);
fntype* const fn = reinterpret_cast<fntype*>(method->GetEntryPointFromJni());
ScopedLocalRef<jobject> rcvr(soa.Env(),
soa.AddLocalReference<jobject>(receiver));
ScopedThreadStateChange tsc(self, kNative);
result->SetI(fn(soa.Env(), rcvr.get(), args[0], args[1]));
} else {
LOG(FATAL) << "Do something with native method: " << method->PrettyMethod()
<< " shorty: " << shorty;
}
}
}
enum InterpreterImplKind {
kSwitchImplKind, // Switch-based interpreter implementation.
kMterpImplKind // Assembly interpreter
};
static constexpr InterpreterImplKind kInterpreterImplKind = kMterpImplKind;
static inline JValue Execute(
Thread* self,
const CodeItemDataAccessor& accessor,
ShadowFrame& shadow_frame,
JValue result_register,
bool stay_in_interpreter = false,
bool from_deoptimize = false) REQUIRES_SHARED(Locks::mutator_lock_) {
DCHECK(!shadow_frame.GetMethod()->IsAbstract());
DCHECK(!shadow_frame.GetMethod()->IsNative());
if (LIKELY(!from_deoptimize)) { // Entering the method, but not via deoptimization.
if (kIsDebugBuild) {
CHECK_EQ(shadow_frame.GetDexPC(), 0u);
self->AssertNoPendingException();
}
instrumentation::Instrumentation* instrumentation = Runtime::Current()->GetInstrumentation();
ArtMethod *method = shadow_frame.GetMethod();
if (UNLIKELY(instrumentation->HasMethodEntryListeners())) {
instrumentation->MethodEnterEvent(self,
shadow_frame.GetThisObject(accessor.InsSize()),
method,
0);
if (UNLIKELY(self->IsExceptionPending())) {
instrumentation->MethodUnwindEvent(self,
shadow_frame.GetThisObject(accessor.InsSize()),
method,
0);
return JValue();
}
}
if (!stay_in_interpreter) {
jit::Jit* jit = Runtime::Current()->GetJit();
if (jit != nullptr) {
jit->MethodEntered(self, shadow_frame.GetMethod());
if (jit->CanInvokeCompiledCode(method)) {
JValue result;
// Pop the shadow frame before calling into compiled code.
self->PopShadowFrame();
// Calculate the offset of the first input reg. The input registers are in the high regs.
// It's ok to access the code item here since JIT code will have been touched by the
// interpreter and compiler already.
uint16_t arg_offset = accessor.RegistersSize() - accessor.InsSize();
ArtInterpreterToCompiledCodeBridge(self, nullptr, &shadow_frame, arg_offset, &result);
// Push the shadow frame back as the caller will expect it.
self->PushShadowFrame(&shadow_frame);
return result;
}
}
}
}
ArtMethod* method = shadow_frame.GetMethod();
DCheckStaticState(self, method);
// Lock counting is a special version of accessibility checks, and for simplicity and
// reduction of template parameters, we gate it behind access-checks mode.
DCHECK(!method->SkipAccessChecks() || !method->MustCountLocks());
bool transaction_active = Runtime::Current()->IsActiveTransaction();
if (LIKELY(method->SkipAccessChecks())) {
// Enter the "without access check" interpreter.
if (kInterpreterImplKind == kMterpImplKind) {
if (transaction_active) {
// No Mterp variant - just use the switch interpreter.
return ExecuteSwitchImpl<false, true>(self, accessor, shadow_frame, result_register,
false);
} else if (UNLIKELY(!Runtime::Current()->IsStarted())) {
return ExecuteSwitchImpl<false, false>(self, accessor, shadow_frame, result_register,
false);
} else {
while (true) {
// Mterp does not support all instrumentation/debugging.
if (MterpShouldSwitchInterpreters() != 0) {
return ExecuteSwitchImpl<false, false>(self, accessor, shadow_frame, result_register,
false);
}
bool returned = ExecuteMterpImpl(self,
accessor.Insns(),
&shadow_frame,
&result_register);
if (returned) {
return result_register;
} else {
// Mterp didn't like that instruction. Single-step it with the reference interpreter.
result_register = ExecuteSwitchImpl<false, false>(self, accessor, shadow_frame,
result_register, true);
if (shadow_frame.GetDexPC() == dex::kDexNoIndex) {
// Single-stepped a return or an exception not handled locally. Return to caller.
return result_register;
}
}
}
}
} else {
DCHECK_EQ(kInterpreterImplKind, kSwitchImplKind);
if (transaction_active) {
return ExecuteSwitchImpl<false, true>(self, accessor, shadow_frame, result_register,
false);
} else {
return ExecuteSwitchImpl<false, false>(self, accessor, shadow_frame, result_register,
false);
}
}
} else {
// Enter the "with access check" interpreter.
if (kInterpreterImplKind == kMterpImplKind) {
// No access check variants for Mterp. Just use the switch version.
if (transaction_active) {
return ExecuteSwitchImpl<true, true>(self, accessor, shadow_frame, result_register,
false);
} else {
return ExecuteSwitchImpl<true, false>(self, accessor, shadow_frame, result_register,
false);
}
} else {
DCHECK_EQ(kInterpreterImplKind, kSwitchImplKind);
if (transaction_active) {
return ExecuteSwitchImpl<true, true>(self, accessor, shadow_frame, result_register,
false);
} else {
return ExecuteSwitchImpl<true, false>(self, accessor, shadow_frame, result_register,
false);
}
}
}
}
void EnterInterpreterFromInvoke(Thread* self,
ArtMethod* method,
ObjPtr<mirror::Object> receiver,
uint32_t* args,
JValue* result,
bool stay_in_interpreter) {
DCHECK_EQ(self, Thread::Current());
bool implicit_check = !Runtime::Current()->ExplicitStackOverflowChecks();
if (UNLIKELY(__builtin_frame_address(0) < self->GetStackEndForInterpreter(implicit_check))) {
ThrowStackOverflowError(self);
return;
}
// This can happen if we are in forced interpreter mode and an obsolete method is called using
// reflection.
if (UNLIKELY(method->IsObsolete())) {
ThrowInternalError("Attempting to invoke obsolete version of '%s'.",
method->PrettyMethod().c_str());
return;
}
const char* old_cause = self->StartAssertNoThreadSuspension("EnterInterpreterFromInvoke");
CodeItemDataAccessor accessor(method->DexInstructionData());
uint16_t num_regs;
uint16_t num_ins;
if (accessor.HasCodeItem()) {
num_regs = accessor.RegistersSize();
num_ins = accessor.InsSize();
} else if (!method->IsInvokable()) {
self->EndAssertNoThreadSuspension(old_cause);
method->ThrowInvocationTimeError();
return;
} else {
DCHECK(method->IsNative());
num_regs = num_ins = ArtMethod::NumArgRegisters(method->GetShorty());
if (!method->IsStatic()) {
num_regs++;
num_ins++;
}
}
// Set up shadow frame with matching number of reference slots to vregs.
ShadowFrame* last_shadow_frame = self->GetManagedStack()->GetTopShadowFrame();
ShadowFrameAllocaUniquePtr shadow_frame_unique_ptr =
CREATE_SHADOW_FRAME(num_regs, last_shadow_frame, method, /* dex pc */ 0);
ShadowFrame* shadow_frame = shadow_frame_unique_ptr.get();
self->PushShadowFrame(shadow_frame);
size_t cur_reg = num_regs - num_ins;
if (!method->IsStatic()) {
CHECK(receiver != nullptr);
shadow_frame->SetVRegReference(cur_reg, receiver);
++cur_reg;
}
uint32_t shorty_len = 0;
const char* shorty = method->GetShorty(&shorty_len);
for (size_t shorty_pos = 0, arg_pos = 0; cur_reg < num_regs; ++shorty_pos, ++arg_pos, cur_reg++) {
DCHECK_LT(shorty_pos + 1, shorty_len);
switch (shorty[shorty_pos + 1]) {
case 'L': {
ObjPtr<mirror::Object> o =
reinterpret_cast<StackReference<mirror::Object>*>(&args[arg_pos])->AsMirrorPtr();
shadow_frame->SetVRegReference(cur_reg, o);
break;
}
case 'J': case 'D': {
uint64_t wide_value = (static_cast<uint64_t>(args[arg_pos + 1]) << 32) | args[arg_pos];
shadow_frame->SetVRegLong(cur_reg, wide_value);
cur_reg++;
arg_pos++;
break;
}
default:
shadow_frame->SetVReg(cur_reg, args[arg_pos]);
break;
}
}
self->EndAssertNoThreadSuspension(old_cause);
// Do this after populating the shadow frame in case EnsureInitialized causes a GC.
if (method->IsStatic() && UNLIKELY(!method->GetDeclaringClass()->IsInitialized())) {
ClassLinker* class_linker = Runtime::Current()->GetClassLinker();
StackHandleScope<1> hs(self);
Handle<mirror::Class> h_class(hs.NewHandle(method->GetDeclaringClass()));
if (UNLIKELY(!class_linker->EnsureInitialized(self, h_class, true, true))) {
CHECK(self->IsExceptionPending());
self->PopShadowFrame();
return;
}
}
if (LIKELY(!method->IsNative())) {
JValue r = Execute(self, accessor, *shadow_frame, JValue(), stay_in_interpreter);
if (result != nullptr) {
*result = r;
}
} else {
// We don't expect to be asked to interpret native code (which is entered via a JNI compiler
// generated stub) except during testing and image writing.
// Update args to be the args in the shadow frame since the input ones could hold stale
// references pointers due to moving GC.
args = shadow_frame->GetVRegArgs(method->IsStatic() ? 0 : 1);
if (!Runtime::Current()->IsStarted()) {
UnstartedRuntime::Jni(self, method, receiver.Ptr(), args, result);
} else {
InterpreterJni(self, method, shorty, receiver, args, result);
}
}
self->PopShadowFrame();
}
static int16_t GetReceiverRegisterForStringInit(const Instruction* instr) {
DCHECK(instr->Opcode() == Instruction::INVOKE_DIRECT_RANGE ||
instr->Opcode() == Instruction::INVOKE_DIRECT);
return (instr->Opcode() == Instruction::INVOKE_DIRECT_RANGE) ?
instr->VRegC_3rc() : instr->VRegC_35c();
}
void EnterInterpreterFromDeoptimize(Thread* self,
ShadowFrame* shadow_frame,
JValue* ret_val,
bool from_code,
DeoptimizationMethodType deopt_method_type)
REQUIRES_SHARED(Locks::mutator_lock_) {
JValue value;
// Set value to last known result in case the shadow frame chain is empty.
value.SetJ(ret_val->GetJ());
// Are we executing the first shadow frame?
bool first = true;
while (shadow_frame != nullptr) {
// We do not want to recover lock state for lock counting when deoptimizing. Currently,
// the compiler should not have compiled a method that failed structured-locking checks.
DCHECK(!shadow_frame->GetMethod()->MustCountLocks());
self->SetTopOfShadowStack(shadow_frame);
CodeItemDataAccessor accessor(shadow_frame->GetMethod()->DexInstructionData());
const uint32_t dex_pc = shadow_frame->GetDexPC();
uint32_t new_dex_pc = dex_pc;
if (UNLIKELY(self->IsExceptionPending())) {
// If we deoptimize from the QuickExceptionHandler, we already reported the exception to
// the instrumentation. To prevent from reporting it a second time, we simply pass a
// null Instrumentation*.
const instrumentation::Instrumentation* const instrumentation =
first ? nullptr : Runtime::Current()->GetInstrumentation();
new_dex_pc = MoveToExceptionHandler(
self, *shadow_frame, instrumentation) ? shadow_frame->GetDexPC() : dex::kDexNoIndex;
} else if (!from_code) {
// Deoptimization is not called from code directly.
const Instruction* instr = &accessor.InstructionAt(dex_pc);
if (deopt_method_type == DeoptimizationMethodType::kKeepDexPc) {
DCHECK(first);
// Need to re-execute the dex instruction.
// (1) An invocation might be split into class initialization and invoke.
// In this case, the invoke should not be skipped.
// (2) A suspend check should also execute the dex instruction at the
// corresponding dex pc.
DCHECK_EQ(new_dex_pc, dex_pc);
} else if (instr->Opcode() == Instruction::MONITOR_ENTER ||
instr->Opcode() == Instruction::MONITOR_EXIT) {
DCHECK(deopt_method_type == DeoptimizationMethodType::kDefault);
DCHECK(first);
// Non-idempotent dex instruction should not be re-executed.
// On the other hand, if a MONITOR_ENTER is at the dex_pc of a suspend
// check, that MONITOR_ENTER should be executed. That case is handled
// above.
new_dex_pc = dex_pc + instr->SizeInCodeUnits();
} else if (instr->IsInvoke()) {
DCHECK(deopt_method_type == DeoptimizationMethodType::kDefault);
if (IsStringInit(instr, shadow_frame->GetMethod())) {
uint16_t this_obj_vreg = GetReceiverRegisterForStringInit(instr);
// Move the StringFactory.newStringFromChars() result into the register representing
// "this object" when invoking the string constructor in the original dex instruction.
// Also move the result into all aliases.
DCHECK(value.GetL()->IsString());
SetStringInitValueToAllAliases(shadow_frame, this_obj_vreg, value);
// Calling string constructor in the original dex code doesn't generate a result value.
value.SetJ(0);
}
new_dex_pc = dex_pc + instr->SizeInCodeUnits();
} else if (instr->Opcode() == Instruction::NEW_INSTANCE) {
// A NEW_INSTANCE is simply re-executed, including
// "new-instance String" which is compiled into a call into
// StringFactory.newEmptyString().
DCHECK_EQ(new_dex_pc, dex_pc);
} else {
DCHECK(deopt_method_type == DeoptimizationMethodType::kDefault);
DCHECK(first);
// By default, we re-execute the dex instruction since if they are not
// an invoke, so that we don't have to decode the dex instruction to move
// result into the right vreg. All slow paths have been audited to be
// idempotent except monitor-enter/exit and invocation stubs.
// TODO: move result and advance dex pc. That also requires that we
// can tell the return type of a runtime method, possibly by decoding
// the dex instruction at the caller.
DCHECK_EQ(new_dex_pc, dex_pc);
}
} else {
// Nothing to do, the dex_pc is the one at which the code requested
// the deoptimization.
DCHECK(first);
DCHECK_EQ(new_dex_pc, dex_pc);
}
if (new_dex_pc != dex::kDexNoIndex) {
shadow_frame->SetDexPC(new_dex_pc);
value = Execute(self,
accessor,
*shadow_frame,
value,
/* stay_in_interpreter */ true,
/* from_deoptimize */ true);
}
ShadowFrame* old_frame = shadow_frame;
shadow_frame = shadow_frame->GetLink();
ShadowFrame::DeleteDeoptimizedFrame(old_frame);
// Following deoptimizations of shadow frames must be at invocation point
// and should advance dex pc past the invoke instruction.
from_code = false;
deopt_method_type = DeoptimizationMethodType::kDefault;
first = false;
}
ret_val->SetJ(value.GetJ());
}
JValue EnterInterpreterFromEntryPoint(Thread* self, const CodeItemDataAccessor& accessor,
ShadowFrame* shadow_frame) {
DCHECK_EQ(self, Thread::Current());
bool implicit_check = !Runtime::Current()->ExplicitStackOverflowChecks();
if (UNLIKELY(__builtin_frame_address(0) < self->GetStackEndForInterpreter(implicit_check))) {
ThrowStackOverflowError(self);
return JValue();
}
jit::Jit* jit = Runtime::Current()->GetJit();
if (jit != nullptr) {
jit->NotifyCompiledCodeToInterpreterTransition(self, shadow_frame->GetMethod());
}
return Execute(self, accessor, *shadow_frame, JValue());
}
void ArtInterpreterToInterpreterBridge(Thread* self,
const CodeItemDataAccessor& accessor,
ShadowFrame* shadow_frame,
JValue* result) {
bool implicit_check = !Runtime::Current()->ExplicitStackOverflowChecks();
if (UNLIKELY(__builtin_frame_address(0) < self->GetStackEndForInterpreter(implicit_check))) {
ThrowStackOverflowError(self);
return;
}
self->PushShadowFrame(shadow_frame);
ArtMethod* method = shadow_frame->GetMethod();
// Ensure static methods are initialized.
const bool is_static = method->IsStatic();
if (is_static) {
ObjPtr<mirror::Class> declaring_class = method->GetDeclaringClass();
if (UNLIKELY(!declaring_class->IsInitialized())) {
StackHandleScope<1> hs(self);
HandleWrapperObjPtr<mirror::Class> h_declaring_class(hs.NewHandleWrapper(&declaring_class));
if (UNLIKELY(!Runtime::Current()->GetClassLinker()->EnsureInitialized(
self, h_declaring_class, true, true))) {
DCHECK(self->IsExceptionPending());
self->PopShadowFrame();
return;
}
CHECK(h_declaring_class->IsInitializing());
}
}
if (LIKELY(!shadow_frame->GetMethod()->IsNative())) {
result->SetJ(Execute(self, accessor, *shadow_frame, JValue()).GetJ());
} else {
// We don't expect to be asked to interpret native code (which is entered via a JNI compiler
// generated stub) except during testing and image writing.
CHECK(!Runtime::Current()->IsStarted());
ObjPtr<mirror::Object> receiver = is_static ? nullptr : shadow_frame->GetVRegReference(0);
uint32_t* args = shadow_frame->GetVRegArgs(is_static ? 0 : 1);
UnstartedRuntime::Jni(self, shadow_frame->GetMethod(), receiver.Ptr(), args, result);
}
self->PopShadowFrame();
}
void CheckInterpreterAsmConstants() {
CheckMterpAsmConstants();
}
void InitInterpreterTls(Thread* self) {
InitMterpTls(self);
}
} // namespace interpreter
} // namespace art