/* * 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 "reg_type-inl.h" #include "android-base/stringprintf.h" #include "base/arena_bit_vector.h" #include "base/bit_vector-inl.h" #include "base/casts.h" #include "class_linker-inl.h" #include "dex/descriptors_names.h" #include "dex/dex_file-inl.h" #include "method_verifier.h" #include "mirror/class-inl.h" #include "mirror/class.h" #include "mirror/object-inl.h" #include "mirror/object_array-inl.h" #include "reg_type_cache-inl.h" #include "scoped_thread_state_change-inl.h" #include #include namespace art { namespace verifier { using android::base::StringPrintf; const UndefinedType* UndefinedType::instance_ = nullptr; const ConflictType* ConflictType::instance_ = nullptr; const BooleanType* BooleanType::instance_ = nullptr; const ByteType* ByteType::instance_ = nullptr; const ShortType* ShortType::instance_ = nullptr; const CharType* CharType::instance_ = nullptr; const FloatType* FloatType::instance_ = nullptr; const LongLoType* LongLoType::instance_ = nullptr; const LongHiType* LongHiType::instance_ = nullptr; const DoubleLoType* DoubleLoType::instance_ = nullptr; const DoubleHiType* DoubleHiType::instance_ = nullptr; const IntegerType* IntegerType::instance_ = nullptr; const NullType* NullType::instance_ = nullptr; PrimitiveType::PrimitiveType(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) : RegType(klass, descriptor, cache_id) { CHECK(klass != nullptr); CHECK(!descriptor.empty()); } Cat1Type::Cat1Type(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) : PrimitiveType(klass, descriptor, cache_id) { } Cat2Type::Cat2Type(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) : PrimitiveType(klass, descriptor, cache_id) { } std::string PreciseConstType::Dump() const { std::stringstream result; uint32_t val = ConstantValue(); if (val == 0) { CHECK(IsPreciseConstant()); result << "Zero/null"; } else { result << "Precise "; if (IsConstantShort()) { result << StringPrintf("Constant: %d", val); } else { result << StringPrintf("Constant: 0x%x", val); } } return result.str(); } std::string BooleanType::Dump() const { return "Boolean"; } std::string ConflictType::Dump() const { return "Conflict"; } std::string ByteType::Dump() const { return "Byte"; } std::string ShortType::Dump() const { return "Short"; } std::string CharType::Dump() const { return "Char"; } std::string FloatType::Dump() const { return "Float"; } std::string LongLoType::Dump() const { return "Long (Low Half)"; } std::string LongHiType::Dump() const { return "Long (High Half)"; } std::string DoubleLoType::Dump() const { return "Double (Low Half)"; } std::string DoubleHiType::Dump() const { return "Double (High Half)"; } std::string IntegerType::Dump() const { return "Integer"; } const DoubleHiType* DoubleHiType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new DoubleHiType(klass, descriptor, cache_id); return instance_; } void DoubleHiType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const DoubleLoType* DoubleLoType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new DoubleLoType(klass, descriptor, cache_id); return instance_; } void DoubleLoType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const LongLoType* LongLoType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new LongLoType(klass, descriptor, cache_id); return instance_; } const LongHiType* LongHiType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new LongHiType(klass, descriptor, cache_id); return instance_; } void LongHiType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } void LongLoType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const FloatType* FloatType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new FloatType(klass, descriptor, cache_id); return instance_; } void FloatType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const CharType* CharType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new CharType(klass, descriptor, cache_id); return instance_; } void CharType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const ShortType* ShortType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new ShortType(klass, descriptor, cache_id); return instance_; } void ShortType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const ByteType* ByteType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new ByteType(klass, descriptor, cache_id); return instance_; } void ByteType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const IntegerType* IntegerType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new IntegerType(klass, descriptor, cache_id); return instance_; } void IntegerType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const ConflictType* ConflictType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new ConflictType(klass, descriptor, cache_id); return instance_; } void ConflictType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } const BooleanType* BooleanType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(BooleanType::instance_ == nullptr); instance_ = new BooleanType(klass, descriptor, cache_id); return BooleanType::instance_; } void BooleanType::Destroy() { if (BooleanType::instance_ != nullptr) { delete instance_; instance_ = nullptr; } } std::string UndefinedType::Dump() const REQUIRES_SHARED(Locks::mutator_lock_) { return "Undefined"; } const UndefinedType* UndefinedType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new UndefinedType(klass, descriptor, cache_id); return instance_; } void UndefinedType::Destroy() { if (instance_ != nullptr) { delete instance_; instance_ = nullptr; } } PreciseReferenceType::PreciseReferenceType(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) : RegType(klass, descriptor, cache_id) { // Note: no check for IsInstantiable() here. We may produce this in case an InstantiationError // would be thrown at runtime, but we need to continue verification and *not* create a // hard failure or abort. CheckConstructorInvariants(this); } std::string UnresolvedMergedType::Dump() const { std::stringstream result; result << "UnresolvedMergedReferences(" << GetResolvedPart().Dump() << " | "; const BitVector& types = GetUnresolvedTypes(); bool first = true; for (uint32_t idx : types.Indexes()) { if (!first) { result << ", "; } else { first = false; } result << reg_type_cache_->GetFromId(idx).Dump(); } result << ")"; return result.str(); } std::string UnresolvedSuperClass::Dump() const { std::stringstream result; uint16_t super_type_id = GetUnresolvedSuperClassChildId(); result << "UnresolvedSuperClass(" << reg_type_cache_->GetFromId(super_type_id).Dump() << ")"; return result.str(); } std::string UnresolvedReferenceType::Dump() const { std::stringstream result; result << "Unresolved Reference: " << PrettyDescriptor(std::string(GetDescriptor()).c_str()); return result.str(); } std::string UnresolvedUninitializedRefType::Dump() const { std::stringstream result; result << "Unresolved And Uninitialized Reference: " << PrettyDescriptor(std::string(GetDescriptor()).c_str()) << " Allocation PC: " << GetAllocationPc(); return result.str(); } std::string UnresolvedUninitializedThisRefType::Dump() const { std::stringstream result; result << "Unresolved And Uninitialized This Reference: " << PrettyDescriptor(std::string(GetDescriptor()).c_str()); return result.str(); } std::string ReferenceType::Dump() const { std::stringstream result; result << "Reference: " << mirror::Class::PrettyDescriptor(GetClass()); return result.str(); } std::string PreciseReferenceType::Dump() const { std::stringstream result; result << "Precise Reference: " << mirror::Class::PrettyDescriptor(GetClass()); return result.str(); } std::string UninitializedReferenceType::Dump() const { std::stringstream result; result << "Uninitialized Reference: " << mirror::Class::PrettyDescriptor(GetClass()); result << " Allocation PC: " << GetAllocationPc(); return result.str(); } std::string UninitializedThisReferenceType::Dump() const { std::stringstream result; result << "Uninitialized This Reference: " << mirror::Class::PrettyDescriptor(GetClass()); result << "Allocation PC: " << GetAllocationPc(); return result.str(); } std::string ImpreciseConstType::Dump() const { std::stringstream result; uint32_t val = ConstantValue(); if (val == 0) { result << "Zero/null"; } else { result << "Imprecise "; if (IsConstantShort()) { result << StringPrintf("Constant: %d", val); } else { result << StringPrintf("Constant: 0x%x", val); } } return result.str(); } std::string PreciseConstLoType::Dump() const { std::stringstream result; int32_t val = ConstantValueLo(); result << "Precise "; if (val >= std::numeric_limits::min() && val <= std::numeric_limits::max()) { result << StringPrintf("Low-half Constant: %d", val); } else { result << StringPrintf("Low-half Constant: 0x%x", val); } return result.str(); } std::string ImpreciseConstLoType::Dump() const { std::stringstream result; int32_t val = ConstantValueLo(); result << "Imprecise "; if (val >= std::numeric_limits::min() && val <= std::numeric_limits::max()) { result << StringPrintf("Low-half Constant: %d", val); } else { result << StringPrintf("Low-half Constant: 0x%x", val); } return result.str(); } std::string PreciseConstHiType::Dump() const { std::stringstream result; int32_t val = ConstantValueHi(); result << "Precise "; if (val >= std::numeric_limits::min() && val <= std::numeric_limits::max()) { result << StringPrintf("High-half Constant: %d", val); } else { result << StringPrintf("High-half Constant: 0x%x", val); } return result.str(); } std::string ImpreciseConstHiType::Dump() const { std::stringstream result; int32_t val = ConstantValueHi(); result << "Imprecise "; if (val >= std::numeric_limits::min() && val <= std::numeric_limits::max()) { result << StringPrintf("High-half Constant: %d", val); } else { result << StringPrintf("High-half Constant: 0x%x", val); } return result.str(); } const RegType& RegType::HighHalf(RegTypeCache* cache) const { DCHECK(IsLowHalf()); if (IsLongLo()) { return cache->LongHi(); } else if (IsDoubleLo()) { return cache->DoubleHi(); } else { DCHECK(IsImpreciseConstantLo()); const ConstantType* const_val = down_cast(this); return cache->FromCat2ConstHi(const_val->ConstantValue(), false); } } Primitive::Type RegType::GetPrimitiveType() const { if (IsNonZeroReferenceTypes()) { return Primitive::kPrimNot; } else if (IsBooleanTypes()) { return Primitive::kPrimBoolean; } else if (IsByteTypes()) { return Primitive::kPrimByte; } else if (IsShortTypes()) { return Primitive::kPrimShort; } else if (IsCharTypes()) { return Primitive::kPrimChar; } else if (IsFloat()) { return Primitive::kPrimFloat; } else if (IsIntegralTypes()) { return Primitive::kPrimInt; } else if (IsDoubleLo()) { return Primitive::kPrimDouble; } else { DCHECK(IsLongTypes()); return Primitive::kPrimLong; } } bool UninitializedType::IsUninitializedTypes() const { return true; } bool UninitializedType::IsNonZeroReferenceTypes() const { return true; } bool UnresolvedType::IsNonZeroReferenceTypes() const { return true; } const RegType& RegType::GetSuperClass(RegTypeCache* cache) const { if (!IsUnresolvedTypes()) { ObjPtr super_klass = GetClass()->GetSuperClass(); if (super_klass != nullptr) { // A super class of a precise type isn't precise as a precise type indicates the register // holds exactly that type. std::string temp; return cache->FromClass(super_klass->GetDescriptor(&temp), super_klass, false); } else { return cache->Zero(); } } else { if (!IsUnresolvedMergedReference() && !IsUnresolvedSuperClass() && GetDescriptor()[0] == '[') { // Super class of all arrays is Object. return cache->JavaLangObject(true); } else { return cache->FromUnresolvedSuperClass(*this); } } } bool RegType::IsJavaLangObject() const REQUIRES_SHARED(Locks::mutator_lock_) { return IsReference() && GetClass()->IsObjectClass(); } bool RegType::IsObjectArrayTypes() const REQUIRES_SHARED(Locks::mutator_lock_) { if (IsUnresolvedTypes()) { DCHECK(!IsUnresolvedMergedReference()); if (IsUnresolvedSuperClass()) { // Cannot be an array, as the superclass of arrays is java.lang.Object (which cannot be // unresolved). return false; } // Primitive arrays will always resolve. DCHECK(descriptor_[1] == 'L' || descriptor_[1] == '['); return descriptor_[0] == '['; } else if (HasClass()) { ObjPtr type = GetClass(); return type->IsArrayClass() && !type->GetComponentType()->IsPrimitive(); } else { return false; } } bool RegType::IsArrayTypes() const REQUIRES_SHARED(Locks::mutator_lock_) { if (IsUnresolvedTypes()) { DCHECK(!IsUnresolvedMergedReference()); if (IsUnresolvedSuperClass()) { // Cannot be an array, as the superclass of arrays is java.lang.Object (which cannot be // unresolved). return false; } return descriptor_[0] == '['; } else if (HasClass()) { return GetClass()->IsArrayClass(); } else { return false; } } bool RegType::IsJavaLangObjectArray() const { if (HasClass()) { ObjPtr type = GetClass(); return type->IsArrayClass() && type->GetComponentType()->IsObjectClass(); } return false; } bool RegType::IsInstantiableTypes() const { return IsUnresolvedTypes() || (IsNonZeroReferenceTypes() && GetClass()->IsInstantiable()); } static const RegType& SelectNonConstant(const RegType& a, const RegType& b) { return a.IsConstantTypes() ? b : a; } static const RegType& SelectNonConstant2(const RegType& a, const RegType& b) { return a.IsConstantTypes() ? (b.IsZero() ? a : b) : a; } namespace { ObjPtr ArrayClassJoin(ObjPtr s, ObjPtr t, ClassLinker* class_linker) REQUIRES_SHARED(Locks::mutator_lock_); ObjPtr InterfaceClassJoin(ObjPtr s, ObjPtr t) REQUIRES_SHARED(Locks::mutator_lock_); /* * A basic Join operation on classes. For a pair of types S and T the Join, written S v T = J, is * S <: J, T <: J and for-all U such that S <: U, T <: U then J <: U. That is J is the parent of * S and T such that there isn't a parent of both S and T that isn't also the parent of J (ie J * is the deepest (lowest upper bound) parent of S and T). * * This operation applies for regular classes and arrays, however, for interface types there * needn't be a partial ordering on the types. We could solve the problem of a lack of a partial * order by introducing sets of types, however, the only operation permissible on an interface is * invoke-interface. In the tradition of Java verifiers [1] we defer the verification of interface * types until an invoke-interface call on the interface typed reference at runtime and allow * the perversion of Object being assignable to an interface type (note, however, that we don't * allow assignment of Object or Interface to any concrete class and are therefore type safe). * * Note: This may return null in case of internal errors, e.g., OOME when a new class would have * to be created but there is no heap space. The exception will stay pending, and it is * the job of the caller to handle it. * * [1] Java bytecode verification: algorithms and formalizations, Xavier Leroy */ ObjPtr ClassJoin(ObjPtr s, ObjPtr t, ClassLinker* class_linker) REQUIRES_SHARED(Locks::mutator_lock_) { DCHECK(!s->IsPrimitive()) << s->PrettyClass(); DCHECK(!t->IsPrimitive()) << t->PrettyClass(); if (s == t) { return s; } else if (s->IsAssignableFrom(t)) { return s; } else if (t->IsAssignableFrom(s)) { return t; } else if (s->IsArrayClass() && t->IsArrayClass()) { return ArrayClassJoin(s, t, class_linker); } else if (s->IsInterface() || t->IsInterface()) { return InterfaceClassJoin(s, t); } else { size_t s_depth = s->Depth(); size_t t_depth = t->Depth(); // Get s and t to the same depth in the hierarchy if (s_depth > t_depth) { while (s_depth > t_depth) { s = s->GetSuperClass(); s_depth--; } } else { while (t_depth > s_depth) { t = t->GetSuperClass(); t_depth--; } } // Go up the hierarchy until we get to the common parent while (s != t) { s = s->GetSuperClass(); t = t->GetSuperClass(); } return s; } } ObjPtr ArrayClassJoin(ObjPtr s, ObjPtr t, ClassLinker* class_linker) { ObjPtr s_ct = s->GetComponentType(); ObjPtr t_ct = t->GetComponentType(); if (s_ct->IsPrimitive() || t_ct->IsPrimitive()) { // Given the types aren't the same, if either array is of primitive types then the only // common parent is java.lang.Object ObjPtr result = s->GetSuperClass(); // short-cut to java.lang.Object DCHECK(result->IsObjectClass()); return result; } Thread* self = Thread::Current(); ObjPtr common_elem = ClassJoin(s_ct, t_ct, class_linker); if (UNLIKELY(common_elem == nullptr)) { self->AssertPendingException(); return nullptr; } // Note: The following lookup invalidates existing ObjPtr<>s. ObjPtr array_class = class_linker->FindArrayClass(self, common_elem); if (UNLIKELY(array_class == nullptr)) { self->AssertPendingException(); return nullptr; } return array_class; } ObjPtr InterfaceClassJoin(ObjPtr s, ObjPtr t) { // This is expensive, as we do not have good data structures to do this even halfway // efficiently. // // We're not following JVMS for interface verification (not everything is assignable to an // interface, we trade this for IMT dispatch). We also don't have set types to make up for // it. So we choose one arbitrary common ancestor interface by walking the interface tables // backwards. // // For comparison, runtimes following the JVMS will punt all interface type checking to // runtime. ObjPtr s_if = s->GetIfTable(); int32_t s_if_count = s->GetIfTableCount(); ObjPtr t_if = t->GetIfTable(); int32_t t_if_count = t->GetIfTableCount(); // Note: we'll be using index == count to stand for the argument itself. for (int32_t s_it = s_if_count; s_it >= 0; --s_it) { ObjPtr s_cl = s_it == s_if_count ? s : s_if->GetInterface(s_it); if (!s_cl->IsInterface()) { continue; } for (int32_t t_it = t_if_count; t_it >= 0; --t_it) { ObjPtr t_cl = t_it == t_if_count ? t : t_if->GetInterface(t_it); if (!t_cl->IsInterface()) { continue; } if (s_cl == t_cl) { // Found something arbitrary in common. return s_cl; } } } // Return java.lang.Object. ObjPtr obj_class = s->IsInterface() ? s->GetSuperClass() : t->GetSuperClass(); DCHECK(obj_class->IsObjectClass()); return obj_class; } } // namespace const RegType& RegType::Merge(const RegType& incoming_type, RegTypeCache* reg_types, MethodVerifier* verifier) const { DCHECK(!Equals(incoming_type)); // Trivial equality handled by caller // Perform pointer equality tests for undefined and conflict to avoid virtual method dispatch. const UndefinedType& undefined = reg_types->Undefined(); const ConflictType& conflict = reg_types->Conflict(); DCHECK_EQ(this == &undefined, IsUndefined()); DCHECK_EQ(&incoming_type == &undefined, incoming_type.IsUndefined()); DCHECK_EQ(this == &conflict, IsConflict()); DCHECK_EQ(&incoming_type == &conflict, incoming_type.IsConflict()); if (this == &undefined || &incoming_type == &undefined) { // There is a difference between undefined and conflict. Conflicts may be copied around, but // not used. Undefined registers must not be copied. So any merge with undefined should return // undefined. return undefined; } else if (this == &conflict || &incoming_type == &conflict) { return conflict; // (Conflict MERGE *) or (* MERGE Conflict) => Conflict } else if (IsConstant() && incoming_type.IsConstant()) { const ConstantType& type1 = *down_cast(this); const ConstantType& type2 = *down_cast(&incoming_type); int32_t val1 = type1.ConstantValue(); int32_t val2 = type2.ConstantValue(); if (val1 >= 0 && val2 >= 0) { // +ve1 MERGE +ve2 => MAX(+ve1, +ve2) if (val1 >= val2) { if (!type1.IsPreciseConstant()) { return *this; } else { return reg_types->FromCat1Const(val1, false); } } else { if (!type2.IsPreciseConstant()) { return type2; } else { return reg_types->FromCat1Const(val2, false); } } } else if (val1 < 0 && val2 < 0) { // -ve1 MERGE -ve2 => MIN(-ve1, -ve2) if (val1 <= val2) { if (!type1.IsPreciseConstant()) { return *this; } else { return reg_types->FromCat1Const(val1, false); } } else { if (!type2.IsPreciseConstant()) { return type2; } else { return reg_types->FromCat1Const(val2, false); } } } else { // Values are +ve and -ve, choose smallest signed type in which they both fit if (type1.IsConstantByte()) { if (type2.IsConstantByte()) { return reg_types->ByteConstant(); } else if (type2.IsConstantShort()) { return reg_types->ShortConstant(); } else { return reg_types->IntConstant(); } } else if (type1.IsConstantShort()) { if (type2.IsConstantShort()) { return reg_types->ShortConstant(); } else { return reg_types->IntConstant(); } } else { return reg_types->IntConstant(); } } } else if (IsConstantLo() && incoming_type.IsConstantLo()) { const ConstantType& type1 = *down_cast(this); const ConstantType& type2 = *down_cast(&incoming_type); int32_t val1 = type1.ConstantValueLo(); int32_t val2 = type2.ConstantValueLo(); return reg_types->FromCat2ConstLo(val1 | val2, false); } else if (IsConstantHi() && incoming_type.IsConstantHi()) { const ConstantType& type1 = *down_cast(this); const ConstantType& type2 = *down_cast(&incoming_type); int32_t val1 = type1.ConstantValueHi(); int32_t val2 = type2.ConstantValueHi(); return reg_types->FromCat2ConstHi(val1 | val2, false); } else if (IsIntegralTypes() && incoming_type.IsIntegralTypes()) { if (IsBooleanTypes() && incoming_type.IsBooleanTypes()) { return reg_types->Boolean(); // boolean MERGE boolean => boolean } if (IsByteTypes() && incoming_type.IsByteTypes()) { return reg_types->Byte(); // byte MERGE byte => byte } if (IsShortTypes() && incoming_type.IsShortTypes()) { return reg_types->Short(); // short MERGE short => short } if (IsCharTypes() && incoming_type.IsCharTypes()) { return reg_types->Char(); // char MERGE char => char } return reg_types->Integer(); // int MERGE * => int } else if ((IsFloatTypes() && incoming_type.IsFloatTypes()) || (IsLongTypes() && incoming_type.IsLongTypes()) || (IsLongHighTypes() && incoming_type.IsLongHighTypes()) || (IsDoubleTypes() && incoming_type.IsDoubleTypes()) || (IsDoubleHighTypes() && incoming_type.IsDoubleHighTypes())) { // check constant case was handled prior to entry DCHECK(!IsConstant() || !incoming_type.IsConstant()); // float/long/double MERGE float/long/double_constant => float/long/double return SelectNonConstant(*this, incoming_type); } else if (IsReferenceTypes() && incoming_type.IsReferenceTypes()) { if (IsUninitializedTypes() || incoming_type.IsUninitializedTypes()) { // Something that is uninitialized hasn't had its constructor called. Unitialized types are // special. They may only ever be merged with themselves (must be taken care of by the // caller of Merge(), see the DCHECK on entry). So mark any other merge as conflicting here. return conflict; } else if (IsZeroOrNull() || incoming_type.IsZeroOrNull()) { return SelectNonConstant2(*this, incoming_type); // 0 MERGE ref => ref } else if (IsJavaLangObject() || incoming_type.IsJavaLangObject()) { return reg_types->JavaLangObject(false); // Object MERGE ref => Object } else if (IsUnresolvedTypes() || incoming_type.IsUnresolvedTypes()) { // We know how to merge an unresolved type with itself, 0 or Object. In this case we // have two sub-classes and don't know how to merge. Create a new string-based unresolved // type that reflects our lack of knowledge and that allows the rest of the unresolved // mechanics to continue. return reg_types->FromUnresolvedMerge(*this, incoming_type, verifier); } else { // Two reference types, compute Join // Do not cache the classes as ClassJoin() can suspend and invalidate ObjPtr<>s. DCHECK(GetClass() != nullptr && !GetClass()->IsPrimitive()); DCHECK(incoming_type.GetClass() != nullptr && !incoming_type.GetClass()->IsPrimitive()); ObjPtr join_class = ClassJoin(GetClass(), incoming_type.GetClass(), reg_types->GetClassLinker()); if (UNLIKELY(join_class == nullptr)) { // Internal error joining the classes (e.g., OOME). Report an unresolved reference type. // We cannot report an unresolved merge type, as that will attempt to merge the resolved // components, leaving us in an infinite loop. // We do not want to report the originating exception, as that would require a fast path // out all the way to VerifyClass. Instead attempt to continue on without a detailed type. Thread* self = Thread::Current(); self->AssertPendingException(); self->ClearException(); // When compiling on the host, we rather want to abort to ensure determinism for preopting. // (In that case, it is likely a misconfiguration of dex2oat.) if (!kIsTargetBuild && (verifier != nullptr && verifier->IsAotMode())) { LOG(FATAL) << "Could not create class join of " << GetClass()->PrettyClass() << " & " << incoming_type.GetClass()->PrettyClass(); UNREACHABLE(); } return reg_types->MakeUnresolvedReference(); } // Record the dependency that both `GetClass()` and `incoming_type.GetClass()` // are assignable to `join_class`. The `verifier` is null during unit tests. if (verifier != nullptr) { VerifierDeps::MaybeRecordAssignability(verifier->GetVerifierDeps(), verifier->GetDexFile(), verifier->GetClassDef(), join_class, GetClass()); VerifierDeps::MaybeRecordAssignability(verifier->GetVerifierDeps(), verifier->GetDexFile(), verifier->GetClassDef(), join_class, incoming_type.GetClass()); } if (GetClass() == join_class && !IsPreciseReference()) { return *this; } else if (incoming_type.GetClass() == join_class && !incoming_type.IsPreciseReference()) { return incoming_type; } else { std::string temp; const char* descriptor = join_class->GetDescriptor(&temp); return reg_types->FromClass(descriptor, join_class, /* precise= */ false); } } } else { return conflict; // Unexpected types => Conflict } } void RegType::CheckInvariants() const { if (IsConstant() || IsConstantLo() || IsConstantHi()) { CHECK(descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; } if (!klass_.IsNull()) { CHECK(!descriptor_.empty()) << *this; std::string temp; CHECK_EQ(descriptor_, klass_.Read()->GetDescriptor(&temp)) << *this; } } void RegType::VisitRoots(RootVisitor* visitor, const RootInfo& root_info) const { klass_.VisitRootIfNonNull(visitor, root_info); } void UninitializedThisReferenceType::CheckInvariants() const { CHECK_EQ(GetAllocationPc(), 0U) << *this; } void UnresolvedUninitializedThisRefType::CheckInvariants() const { CHECK_EQ(GetAllocationPc(), 0U) << *this; CHECK(!descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; } void UnresolvedUninitializedRefType::CheckInvariants() const { CHECK(!descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; } UnresolvedMergedType::UnresolvedMergedType(const RegType& resolved, const BitVector& unresolved, const RegTypeCache* reg_type_cache, uint16_t cache_id) : UnresolvedType("", cache_id), reg_type_cache_(reg_type_cache), resolved_part_(resolved), unresolved_types_(unresolved, false, unresolved.GetAllocator()) { CheckConstructorInvariants(this); } void UnresolvedMergedType::CheckInvariants() const { CHECK(reg_type_cache_ != nullptr); // Unresolved merged types: merged types should be defined. CHECK(descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; CHECK(!resolved_part_.IsConflict()); CHECK(resolved_part_.IsReferenceTypes()); CHECK(!resolved_part_.IsUnresolvedTypes()); CHECK(resolved_part_.IsZero() || !(resolved_part_.IsArrayTypes() && !resolved_part_.IsObjectArrayTypes())); CHECK_GT(unresolved_types_.NumSetBits(), 0U); bool unresolved_is_array = reg_type_cache_->GetFromId(unresolved_types_.GetHighestBitSet()).IsArrayTypes(); for (uint32_t idx : unresolved_types_.Indexes()) { const RegType& t = reg_type_cache_->GetFromId(idx); CHECK_EQ(unresolved_is_array, t.IsArrayTypes()); } if (!resolved_part_.IsZero()) { CHECK_EQ(resolved_part_.IsArrayTypes(), unresolved_is_array); } } bool UnresolvedMergedType::IsArrayTypes() const { // For a merge to be an array, both the resolved and the unresolved part need to be object // arrays. // (Note: we encode a missing resolved part [which doesn't need to be an array] as zero.) if (!resolved_part_.IsZero() && !resolved_part_.IsArrayTypes()) { return false; } // It is enough to check just one of the merged types. Otherwise the merge should have been // collapsed (checked in CheckInvariants on construction). uint32_t idx = unresolved_types_.GetHighestBitSet(); const RegType& unresolved = reg_type_cache_->GetFromId(idx); return unresolved.IsArrayTypes(); } bool UnresolvedMergedType::IsObjectArrayTypes() const { // Same as IsArrayTypes, as primitive arrays are always resolved. return IsArrayTypes(); } void UnresolvedReferenceType::CheckInvariants() const { CHECK(!descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; } void UnresolvedSuperClass::CheckInvariants() const { // Unresolved merged types: merged types should be defined. CHECK(descriptor_.empty()) << *this; CHECK(klass_.IsNull()) << *this; CHECK_NE(unresolved_child_id_, 0U) << *this; } std::ostream& operator<<(std::ostream& os, const RegType& rhs) { os << rhs.Dump(); return os; } bool RegType::CanAssignArray(const RegType& src, RegTypeCache& reg_types, Handle class_loader, MethodVerifier* verifier, bool* soft_error) const { if (!IsArrayTypes() || !src.IsArrayTypes()) { *soft_error = false; return false; } if (IsUnresolvedMergedReference() || src.IsUnresolvedMergedReference()) { // An unresolved array type means that it's an array of some reference type. Reference arrays // can never be assigned to primitive-type arrays, and vice versa. So it is a soft error if // both arrays are reference arrays, otherwise a hard error. *soft_error = IsObjectArrayTypes() && src.IsObjectArrayTypes(); return false; } const RegType& cmp1 = reg_types.GetComponentType(*this, class_loader.Get()); const RegType& cmp2 = reg_types.GetComponentType(src, class_loader.Get()); if (cmp1.IsAssignableFrom(cmp2, verifier)) { return true; } if (cmp1.IsUnresolvedTypes()) { if (cmp2.IsIntegralTypes() || cmp2.IsFloatTypes() || cmp2.IsArrayTypes()) { *soft_error = false; return false; } *soft_error = true; return false; } if (cmp2.IsUnresolvedTypes()) { if (cmp1.IsIntegralTypes() || cmp1.IsFloatTypes() || cmp1.IsArrayTypes()) { *soft_error = false; return false; } *soft_error = true; return false; } if (!cmp1.IsArrayTypes() || !cmp2.IsArrayTypes()) { *soft_error = false; return false; } return cmp1.CanAssignArray(cmp2, reg_types, class_loader, verifier, soft_error); } const NullType* NullType::CreateInstance(ObjPtr klass, const std::string_view& descriptor, uint16_t cache_id) { CHECK(instance_ == nullptr); instance_ = new NullType(klass, descriptor, cache_id); return instance_; } void NullType::Destroy() { if (NullType::instance_ != nullptr) { delete instance_; instance_ = nullptr; } } } // namespace verifier } // namespace art