src/verifier/reg_type.cc - platform/art - Git at Google

 /*
  * 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.h"

 #include "object_utils.h"
 #include "reg_type_cache.h"

 namespace art {
 namespace verifier {

 static const char* type_strings[] = {
     "Undefined",
     "Conflict",
     "Boolean",
     "Byte",
     "Short",
     "Char",
     "Integer",
     "Float",
     "Long (Low Half)",
     "Long (High Half)",
     "Double (Low Half)",
     "Double (High Half)",
     "64-bit Constant (Low Half)",
     "64-bit Constant (High Half)",
     "32-bit Constant",
     "Unresolved Reference",
     "Uninitialized Reference",
     "Uninitialized This Reference",
     "Unresolved And Uninitialized Reference",
     "Unresolved And Uninitialized This Reference",
     "Unresolved Merged References",
     "Unresolved Super Class",
     "Reference",
 };

 std::string RegType::Dump(const RegTypeCache* reg_types) const {
   DCHECK(type_ >=  kRegTypeUndefined && type_ <= kRegTypeReference);
   DCHECK(arraysize(type_strings) == (kRegTypeReference + 1));
   std::string result;
   if (IsUnresolvedMergedReference()) {
     if (reg_types == NULL) {
       std::pair<uint16_t, uint16_t> refs = GetTopMergedTypes();
       result += StringPrintf("UnresolvedMergedReferences(%d, %d)", refs.first, refs.second);
     } else {
       std::set<uint16_t> types = GetMergedTypes(reg_types);
       result += "UnresolvedMergedReferences(";
       typedef std::set<uint16_t>::const_iterator It;  // TODO: C++0x auto
       It it = types.begin();
       result += reg_types->GetFromId(*it).Dump(reg_types);
       for(++it; it != types.end(); ++it) {
         result += ", ";
         result += reg_types->GetFromId(*it).Dump(reg_types);
       }
       result += ")";
     }
   } else if (IsUnresolvedSuperClass()) {
     uint16_t super_type_id = GetUnresolvedSuperClassChildId();
     if (reg_types == NULL) {
       result += StringPrintf("UnresolvedSuperClass(%d)", super_type_id);
     } else {
       result += "UnresolvedSuperClass(";
       result += reg_types->GetFromId(super_type_id).Dump(reg_types);
       result += ")";
     }
   } else if (IsConstant()) {
     uint32_t val = ConstantValue();
     if (val == 0) {
       result = "Zero";
     } else {
       if (IsConstantShort()) {
         result = StringPrintf("32-bit Constant: %d", val);
       } else {
         result = StringPrintf("32-bit Constant: 0x%x", val);
       }
     }
   } else {
     result = type_strings[type_];
     if (IsReferenceTypes()) {
       result += ": ";
       if (IsUnresolvedTypes()) {
         result += PrettyDescriptor(GetDescriptor());
       } else {
         result += PrettyDescriptor(GetClass());
       }
     }
   }
   return result;
 }

 const RegType& RegType::HighHalf(RegTypeCache* cache) const {
   CHECK(IsLowHalf());
   if (type_ == kRegTypeLongLo) {
     return cache->FromType(kRegTypeLongHi);
   } else if (type_ == kRegTypeDoubleLo) {
     return cache->FromType(kRegTypeDoubleHi);
   } else {
     return cache->FromType(kRegTypeConstHi);
   }
 }

 std::set<uint16_t> RegType::GetMergedTypes(const RegTypeCache* cache) const {
   std::pair<uint16_t, uint16_t> refs = GetTopMergedTypes();
   const RegType& left = cache->GetFromId(refs.first);
   const RegType& right = cache->GetFromId(refs.second);
   std::set<uint16_t> types;
   if (left.IsUnresolvedMergedReference()) {
     types = left.GetMergedTypes(cache);
   } else {
     types.insert(refs.first);
   }
   if (right.IsUnresolvedMergedReference()) {
     std::set<uint16_t> right_types = right.GetMergedTypes(cache);
     types.insert(right_types.begin(), right_types.end());
   } else {
     types.insert(refs.second);
   }
 #ifndef NDEBUG
   typedef std::set<uint16_t>::const_iterator It;  // TODO: C++0x auto
   for(It it = types.begin(); it != types.end(); ++it) {
     CHECK(!cache->GetFromId(*it).IsUnresolvedMergedReference());
   }
 #endif
   return types;
 }

 const RegType& RegType::GetSuperClass(RegTypeCache* cache) const {
   if (!IsUnresolvedTypes()) {
     Class* super_klass = GetClass()->GetSuperClass();
     if (super_klass != NULL) {
       return cache->FromClass(super_klass);
     } else {
       return cache->Zero();
     }
   } else {
     if (!IsUnresolvedMergedReference() && !IsUnresolvedSuperClass() &&
         GetDescriptor()->CharAt(0) == '[') {
       // Super class of all arrays is Object.
       return cache->JavaLangObject();
     } else {
       return cache->FromUnresolvedSuperClass(*this);
     }
   }
 }

 bool RegType::CanAccess(const RegType& other) const {
   if (Equals(other)) {
     return true;  // Trivial accessibility.
   } else {
     bool this_unresolved = IsUnresolvedTypes();
     bool other_unresolved = other.IsUnresolvedTypes();
     if (!this_unresolved && !other_unresolved) {
       return GetClass()->CanAccess(other.GetClass());
     } else if (!other_unresolved) {
       return other.GetClass()->IsPublic();  // Be conservative, only allow if other is public.
     } else {
       return false; // More complicated test not possible on unresolved types, be conservative.
     }
   }
 }

 bool RegType::CanAccessMember(Class* klass, uint32_t access_flags) const {
   if (access_flags & kAccPublic) {
     return true;
   }
   if (!IsUnresolvedTypes()) {
     return GetClass()->CanAccessMember(klass, access_flags);
   } else {
     return false;  // More complicated test not possible on unresolved types, be conservative.
   }
 }

 bool RegType::IsAssignableFrom(const RegType& src) const {
   if (Equals(src)) {
     return true;
   } else {
     switch (GetType()) {
       case RegType::kRegTypeBoolean:  return src.IsBooleanTypes();
       case RegType::kRegTypeByte:     return src.IsByteTypes();
       case RegType::kRegTypeShort:    return src.IsShortTypes();
       case RegType::kRegTypeChar:     return src.IsCharTypes();
       case RegType::kRegTypeInteger:  return src.IsIntegralTypes();
       case RegType::kRegTypeFloat:    return src.IsFloatTypes();
       case RegType::kRegTypeLongLo:   return src.IsLongTypes();
       case RegType::kRegTypeDoubleLo: return src.IsDoubleTypes();
       default:
         if (!IsReferenceTypes()) {
           LOG(FATAL) << "Unexpected register type in IsAssignableFrom: '" << src << "'";
         }
         if (src.IsZero()) {
           return true;  // all reference types can be assigned null
         } else if (!src.IsReferenceTypes()) {
           return false;  // expect src to be a reference type
         } else if (IsJavaLangObject()) {
           return true;  // all reference types can be assigned to Object
         } else if (!IsUnresolvedTypes() && GetClass()->IsInterface()) {
           return true;  // We allow assignment to any interface, see comment in ClassJoin
         } else if (IsJavaLangObjectArray()) {
           return src.IsObjectArrayTypes();  // All reference arrays may be assigned to Object[]
         } else if (!IsUnresolvedTypes() && !src.IsUnresolvedTypes() &&
                    GetClass()->IsAssignableFrom(src.GetClass())) {
           // We're assignable from the Class point-of-view
           return true;
         } else {
           // TODO: unresolved types are only assignable for null, Object and equality currently.
           return false;
         }
     }
   }
 }

 static const RegType& SelectNonConstant(const RegType& a, const RegType& b) {
   return a.IsConstant() ? b : a;
 }

 const RegType& RegType::Merge(const RegType& incoming_type, RegTypeCache* reg_types) const {
   DCHECK(!Equals(incoming_type));  // Trivial equality handled by caller
   if (IsUndefined() && incoming_type.IsUndefined()) {
     return *this;  // Undefined MERGE Undefined => Undefined
   } else if (IsConflict()) {
     return *this;  // Conflict MERGE * => Conflict
   } else if (incoming_type.IsConflict()) {
     return incoming_type;  // * MERGE Conflict => Conflict
   } else if (IsUndefined() || incoming_type.IsUndefined()) {
     return reg_types->Conflict();  // Unknown MERGE * => Conflict
   } else if (IsConstant() && incoming_type.IsConstant()) {
     int32_t val1 = ConstantValue();
     int32_t val2 = incoming_type.ConstantValue();
     if (val1 >= 0 && val2 >= 0) {
       // +ve1 MERGE +ve2 => MAX(+ve1, +ve2)
       if (val1 >= val2) {
         return *this;
       } else {
         return incoming_type;
       }
     } else if (val1 < 0 && val2 < 0) {
       // -ve1 MERGE -ve2 => MIN(-ve1, -ve2)
       if (val1 <= val2) {
         return *this;
       } else {
         return incoming_type;
       }
     } else {
       // Values are +ve and -ve, choose smallest signed type in which they both fit
       if (IsConstantByte()) {
         if (incoming_type.IsConstantByte()) {
           return reg_types->ByteConstant();
         } else if (incoming_type.IsConstantShort()) {
           return reg_types->ShortConstant();
         } else {
           return reg_types->IntConstant();
         }
       } else if (IsConstantShort()) {
         if (incoming_type.IsConstantShort()) {
           return reg_types->ShortConstant();
         } else {
           return reg_types->IntConstant();
         }
       } else {
         return reg_types->IntConstant();
       }
     }
   } 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 (IsZero() || incoming_type.IsZero()) {
       return SelectNonConstant(*this, incoming_type);  // 0 MERGE ref => ref
     } else if (IsJavaLangObject() || incoming_type.IsJavaLangObject()) {
       return reg_types->JavaLangObject();  // 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);
     } else if (IsUninitializedTypes() || incoming_type.IsUninitializedTypes()) {
       // Something that is uninitialized hasn't had its constructor called. Mark any merge
       // of this type with something that is initialized as conflicting. The cases of a merge
       // with itself, 0 or Object are handled above.
       return reg_types->Conflict();
     } else {  // Two reference types, compute Join
       Class* c1 = GetClass();
       Class* c2 = incoming_type.GetClass();
       DCHECK(c1 != NULL && !c1->IsPrimitive());
       DCHECK(c2 != NULL && !c2->IsPrimitive());
       Class* join_class = ClassJoin(c1, c2);
       if (c1 == join_class) {
         return *this;
       } else if (c2 == join_class) {
         return incoming_type;
       } else {
         return reg_types->FromClass(join_class);
       }
     }
   } else {
     return reg_types->Conflict();  // Unexpected types => Conflict
   }
 }

 // See comment in reg_type.h
 Class* RegType::ClassJoin(Class* s, Class* t) {
   DCHECK(!s->IsPrimitive()) << PrettyClass(s);
   DCHECK(!t->IsPrimitive()) << PrettyClass(t);
   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()) {
     Class* s_ct = s->GetComponentType();
     Class* 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
       Class* result = s->GetSuperClass();  // short-cut to java.lang.Object
       DCHECK(result->IsObjectClass());
       return result;
     }
     Class* common_elem = ClassJoin(s_ct, t_ct);
     ClassLinker* class_linker = Runtime::Current()->GetClassLinker();
     ClassLoader* class_loader = s->GetClassLoader();
     std::string descriptor("[");
     descriptor += ClassHelper(common_elem).GetDescriptor();
     Class* array_class = class_linker->FindClass(descriptor.c_str(), class_loader);
     DCHECK(array_class != NULL);
     return array_class;
   } 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;
   }
 }

 std::ostream& operator<<(std::ostream& os, const RegType& rhs)
     SHARED_LOCKS_REQUIRED(GlobalSynchronization::mutator_lock_) {
   os << rhs.Dump();
   return os;
 }

 }  // namespace verifier
 }  // namespace art
	/*
	* 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.h"

	#include "object_utils.h"
	#include "reg_type_cache.h"

	namespace art {
	namespace verifier {

	static const char* type_strings[] = {
	"Undefined",
	"Conflict",
	"Boolean",
	"Byte",
	"Short",
	"Char",
	"Integer",
	"Float",
	"Long (Low Half)",
	"Long (High Half)",
	"Double (Low Half)",
	"Double (High Half)",
	"64-bit Constant (Low Half)",
	"64-bit Constant (High Half)",
	"32-bit Constant",
	"Unresolved Reference",
	"Uninitialized Reference",
	"Uninitialized This Reference",
	"Unresolved And Uninitialized Reference",
	"Unresolved And Uninitialized This Reference",
	"Unresolved Merged References",
	"Unresolved Super Class",
	"Reference",
	};

	std::string RegType::Dump(const RegTypeCache* reg_types) const {
	DCHECK(type_ >= kRegTypeUndefined && type_ <= kRegTypeReference);
	DCHECK(arraysize(type_strings) == (kRegTypeReference + 1));
	std::string result;
	if (IsUnresolvedMergedReference()) {
	if (reg_types == NULL) {
	std::pair<uint16_t, uint16_t> refs = GetTopMergedTypes();
	result += StringPrintf("UnresolvedMergedReferences(%d, %d)", refs.first, refs.second);
	} else {
	std::set<uint16_t> types = GetMergedTypes(reg_types);
	result += "UnresolvedMergedReferences(";
	typedef std::set<uint16_t>::const_iterator It; // TODO: C++0x auto
	It it = types.begin();
	result += reg_types->GetFromId(*it).Dump(reg_types);
	for(++it; it != types.end(); ++it) {
	result += ", ";
	result += reg_types->GetFromId(*it).Dump(reg_types);
	}
	result += ")";
	}
	} else if (IsUnresolvedSuperClass()) {
	uint16_t super_type_id = GetUnresolvedSuperClassChildId();
	if (reg_types == NULL) {
	result += StringPrintf("UnresolvedSuperClass(%d)", super_type_id);
	} else {
	result += "UnresolvedSuperClass(";
	result += reg_types->GetFromId(super_type_id).Dump(reg_types);
	result += ")";
	}
	} else if (IsConstant()) {
	uint32_t val = ConstantValue();
	if (val == 0) {
	result = "Zero";
	} else {
	if (IsConstantShort()) {
	result = StringPrintf("32-bit Constant: %d", val);
	} else {
	result = StringPrintf("32-bit Constant: 0x%x", val);
	}
	}
	} else {
	result = type_strings[type_];
	if (IsReferenceTypes()) {
	result += ": ";
	if (IsUnresolvedTypes()) {
	result += PrettyDescriptor(GetDescriptor());
	} else {
	result += PrettyDescriptor(GetClass());
	}
	}
	}
	return result;
	}

	const RegType& RegType::HighHalf(RegTypeCache* cache) const {
	CHECK(IsLowHalf());
	if (type_ == kRegTypeLongLo) {
	return cache->FromType(kRegTypeLongHi);
	} else if (type_ == kRegTypeDoubleLo) {
	return cache->FromType(kRegTypeDoubleHi);
	} else {
	return cache->FromType(kRegTypeConstHi);
	}
	}

	std::set<uint16_t> RegType::GetMergedTypes(const RegTypeCache* cache) const {
	std::pair<uint16_t, uint16_t> refs = GetTopMergedTypes();
	const RegType& left = cache->GetFromId(refs.first);
	const RegType& right = cache->GetFromId(refs.second);
	std::set<uint16_t> types;
	if (left.IsUnresolvedMergedReference()) {
	types = left.GetMergedTypes(cache);
	} else {
	types.insert(refs.first);
	}
	if (right.IsUnresolvedMergedReference()) {
	std::set<uint16_t> right_types = right.GetMergedTypes(cache);
	types.insert(right_types.begin(), right_types.end());
	} else {
	types.insert(refs.second);
	}
	#ifndef NDEBUG
	typedef std::set<uint16_t>::const_iterator It; // TODO: C++0x auto
	for(It it = types.begin(); it != types.end(); ++it) {
	CHECK(!cache->GetFromId(*it).IsUnresolvedMergedReference());
	}
	#endif
	return types;
	}

	const RegType& RegType::GetSuperClass(RegTypeCache* cache) const {
	if (!IsUnresolvedTypes()) {
	Class* super_klass = GetClass()->GetSuperClass();
	if (super_klass != NULL) {
	return cache->FromClass(super_klass);
	} else {
	return cache->Zero();
	}
	} else {
	if (!IsUnresolvedMergedReference() && !IsUnresolvedSuperClass() &&
	GetDescriptor()->CharAt(0) == '[') {
	// Super class of all arrays is Object.
	return cache->JavaLangObject();
	} else {
	return cache->FromUnresolvedSuperClass(*this);
	}
	}
	}

	bool RegType::CanAccess(const RegType& other) const {
	if (Equals(other)) {
	return true; // Trivial accessibility.
	} else {
	bool this_unresolved = IsUnresolvedTypes();
	bool other_unresolved = other.IsUnresolvedTypes();
	if (!this_unresolved && !other_unresolved) {
	return GetClass()->CanAccess(other.GetClass());
	} else if (!other_unresolved) {
	return other.GetClass()->IsPublic(); // Be conservative, only allow if other is public.
	} else {
	return false; // More complicated test not possible on unresolved types, be conservative.
	}
	}
	}

	bool RegType::CanAccessMember(Class* klass, uint32_t access_flags) const {
	if (access_flags & kAccPublic) {
	return true;
	}
	if (!IsUnresolvedTypes()) {
	return GetClass()->CanAccessMember(klass, access_flags);
	} else {
	return false; // More complicated test not possible on unresolved types, be conservative.
	}
	}

	bool RegType::IsAssignableFrom(const RegType& src) const {
	if (Equals(src)) {
	return true;
	} else {
	switch (GetType()) {
	case RegType::kRegTypeBoolean: return src.IsBooleanTypes();
	case RegType::kRegTypeByte: return src.IsByteTypes();
	case RegType::kRegTypeShort: return src.IsShortTypes();
	case RegType::kRegTypeChar: return src.IsCharTypes();
	case RegType::kRegTypeInteger: return src.IsIntegralTypes();
	case RegType::kRegTypeFloat: return src.IsFloatTypes();
	case RegType::kRegTypeLongLo: return src.IsLongTypes();
	case RegType::kRegTypeDoubleLo: return src.IsDoubleTypes();
	default:
	if (!IsReferenceTypes()) {
	LOG(FATAL) << "Unexpected register type in IsAssignableFrom: '" << src << "'";
	}
	if (src.IsZero()) {
	return true; // all reference types can be assigned null
	} else if (!src.IsReferenceTypes()) {
	return false; // expect src to be a reference type
	} else if (IsJavaLangObject()) {
	return true; // all reference types can be assigned to Object
	} else if (!IsUnresolvedTypes() && GetClass()->IsInterface()) {
	return true; // We allow assignment to any interface, see comment in ClassJoin
	} else if (IsJavaLangObjectArray()) {
	return src.IsObjectArrayTypes(); // All reference arrays may be assigned to Object[]
	} else if (!IsUnresolvedTypes() && !src.IsUnresolvedTypes() &&
	GetClass()->IsAssignableFrom(src.GetClass())) {
	// We're assignable from the Class point-of-view
	return true;
	} else {
	// TODO: unresolved types are only assignable for null, Object and equality currently.
	return false;
	}
	}
	}
	}

	static const RegType& SelectNonConstant(const RegType& a, const RegType& b) {
	return a.IsConstant() ? b : a;
	}

	const RegType& RegType::Merge(const RegType& incoming_type, RegTypeCache* reg_types) const {
	DCHECK(!Equals(incoming_type)); // Trivial equality handled by caller
	if (IsUndefined() && incoming_type.IsUndefined()) {
	return *this; // Undefined MERGE Undefined => Undefined
	} else if (IsConflict()) {
	return this; // Conflict MERGE => Conflict
	} else if (incoming_type.IsConflict()) {
	return incoming_type; // * MERGE Conflict => Conflict
	} else if (IsUndefined() \|\| incoming_type.IsUndefined()) {
	return reg_types->Conflict(); // Unknown MERGE * => Conflict
	} else if (IsConstant() && incoming_type.IsConstant()) {
	int32_t val1 = ConstantValue();
	int32_t val2 = incoming_type.ConstantValue();
	if (val1 >= 0 && val2 >= 0) {
	// +ve1 MERGE +ve2 => MAX(+ve1, +ve2)
	if (val1 >= val2) {
	return *this;
	} else {
	return incoming_type;
	}
	} else if (val1 < 0 && val2 < 0) {
	// -ve1 MERGE -ve2 => MIN(-ve1, -ve2)
	if (val1 <= val2) {
	return *this;
	} else {
	return incoming_type;
	}
	} else {
	// Values are +ve and -ve, choose smallest signed type in which they both fit
	if (IsConstantByte()) {
	if (incoming_type.IsConstantByte()) {
	return reg_types->ByteConstant();
	} else if (incoming_type.IsConstantShort()) {
	return reg_types->ShortConstant();
	} else {
	return reg_types->IntConstant();
	}
	} else if (IsConstantShort()) {
	if (incoming_type.IsConstantShort()) {
	return reg_types->ShortConstant();
	} else {
	return reg_types->IntConstant();
	}
	} else {
	return reg_types->IntConstant();
	}
	}
	} 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 (IsZero() \|\| incoming_type.IsZero()) {
	return SelectNonConstant(*this, incoming_type); // 0 MERGE ref => ref
	} else if (IsJavaLangObject() \|\| incoming_type.IsJavaLangObject()) {
	return reg_types->JavaLangObject(); // 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);
	} else if (IsUninitializedTypes() \|\| incoming_type.IsUninitializedTypes()) {
	// Something that is uninitialized hasn't had its constructor called. Mark any merge
	// of this type with something that is initialized as conflicting. The cases of a merge
	// with itself, 0 or Object are handled above.
	return reg_types->Conflict();
	} else { // Two reference types, compute Join
	Class* c1 = GetClass();
	Class* c2 = incoming_type.GetClass();
	DCHECK(c1 != NULL && !c1->IsPrimitive());
	DCHECK(c2 != NULL && !c2->IsPrimitive());
	Class* join_class = ClassJoin(c1, c2);
	if (c1 == join_class) {
	return *this;
	} else if (c2 == join_class) {
	return incoming_type;
	} else {
	return reg_types->FromClass(join_class);
	}
	}
	} else {
	return reg_types->Conflict(); // Unexpected types => Conflict
	}
	}

	// See comment in reg_type.h
	Class* RegType::ClassJoin(Class* s, Class* t) {
	DCHECK(!s->IsPrimitive()) << PrettyClass(s);
	DCHECK(!t->IsPrimitive()) << PrettyClass(t);
	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()) {
	Class* s_ct = s->GetComponentType();
	Class* 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
	Class* result = s->GetSuperClass(); // short-cut to java.lang.Object
	DCHECK(result->IsObjectClass());
	return result;
	}
	Class* common_elem = ClassJoin(s_ct, t_ct);
	ClassLinker* class_linker = Runtime::Current()->GetClassLinker();
	ClassLoader* class_loader = s->GetClassLoader();
	std::string descriptor("[");
	descriptor += ClassHelper(common_elem).GetDescriptor();
	Class* array_class = class_linker->FindClass(descriptor.c_str(), class_loader);
	DCHECK(array_class != NULL);
	return array_class;
	} 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;
	}
	}

	std::ostream& operator<<(std::ostream& os, const RegType& rhs)
	SHARED_LOCKS_REQUIRED(GlobalSynchronization::mutator_lock_) {
	os << rhs.Dump();
	return os;
	}

	} // namespace verifier
	} // namespace art