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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 "reg_type.h"
#include <set>
#include "base/bit_vector.h"
#include "base/casts.h"
#include "base/scoped_arena_allocator.h"
#include "common_runtime_test.h"
#include "compiler_callbacks.h"
#include "reg_type-inl.h"
#include "reg_type_cache-inl.h"
#include "scoped_thread_state_change-inl.h"
#include "thread-current-inl.h"
namespace art {
namespace verifier {
class RegTypeTest : public CommonRuntimeTest {};
TEST_F(RegTypeTest, ConstLoHi) {
// Tests creating primitive types types.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& ref_type_const_0 = cache.FromCat1Const(10, true);
const RegType& ref_type_const_1 = cache.FromCat1Const(10, true);
const RegType& ref_type_const_2 = cache.FromCat1Const(30, true);
const RegType& ref_type_const_3 = cache.FromCat1Const(30, false);
EXPECT_TRUE(ref_type_const_0.Equals(ref_type_const_1));
EXPECT_FALSE(ref_type_const_0.Equals(ref_type_const_2));
EXPECT_FALSE(ref_type_const_0.Equals(ref_type_const_3));
const RegType& ref_type_const_wide_0 = cache.FromCat2ConstHi(50, true);
const RegType& ref_type_const_wide_1 = cache.FromCat2ConstHi(50, true);
EXPECT_TRUE(ref_type_const_wide_0.Equals(ref_type_const_wide_1));
const RegType& ref_type_const_wide_2 = cache.FromCat2ConstLo(50, true);
const RegType& ref_type_const_wide_3 = cache.FromCat2ConstLo(50, true);
const RegType& ref_type_const_wide_4 = cache.FromCat2ConstLo(55, true);
EXPECT_TRUE(ref_type_const_wide_2.Equals(ref_type_const_wide_3));
EXPECT_FALSE(ref_type_const_wide_2.Equals(ref_type_const_wide_4));
}
TEST_F(RegTypeTest, Pairs) {
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
int64_t val = static_cast<int32_t>(1234);
const RegType& precise_lo = cache.FromCat2ConstLo(static_cast<int32_t>(val), true);
const RegType& precise_hi = cache.FromCat2ConstHi(static_cast<int32_t>(val >> 32), true);
const RegType& precise_const = cache.FromCat1Const(static_cast<int32_t>(val >> 32), true);
const RegType& long_lo = cache.LongLo();
const RegType& long_hi = cache.LongHi();
// Check sanity of types.
EXPECT_TRUE(precise_lo.IsLowHalf());
EXPECT_FALSE(precise_hi.IsLowHalf());
EXPECT_FALSE(precise_lo.IsHighHalf());
EXPECT_TRUE(precise_hi.IsHighHalf());
EXPECT_TRUE(long_hi.IsLongHighTypes());
EXPECT_TRUE(precise_hi.IsLongHighTypes());
// Check Pairing.
EXPECT_FALSE(precise_lo.CheckWidePair(precise_const));
EXPECT_TRUE(precise_lo.CheckWidePair(precise_hi));
// Test Merging.
EXPECT_TRUE((long_lo.Merge(precise_lo, &cache, /* verifier */ nullptr)).IsLongTypes());
EXPECT_TRUE((long_hi.Merge(precise_hi, &cache, /* verifier */ nullptr)).IsLongHighTypes());
}
TEST_F(RegTypeTest, Primitives) {
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& bool_reg_type = cache.Boolean();
EXPECT_FALSE(bool_reg_type.IsUndefined());
EXPECT_FALSE(bool_reg_type.IsConflict());
EXPECT_FALSE(bool_reg_type.IsZero());
EXPECT_FALSE(bool_reg_type.IsOne());
EXPECT_FALSE(bool_reg_type.IsLongConstant());
EXPECT_TRUE(bool_reg_type.IsBoolean());
EXPECT_FALSE(bool_reg_type.IsByte());
EXPECT_FALSE(bool_reg_type.IsChar());
EXPECT_FALSE(bool_reg_type.IsShort());
EXPECT_FALSE(bool_reg_type.IsInteger());
EXPECT_FALSE(bool_reg_type.IsLong());
EXPECT_FALSE(bool_reg_type.IsFloat());
EXPECT_FALSE(bool_reg_type.IsDouble());
EXPECT_FALSE(bool_reg_type.IsReference());
EXPECT_FALSE(bool_reg_type.IsLowHalf());
EXPECT_FALSE(bool_reg_type.IsHighHalf());
EXPECT_FALSE(bool_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(bool_reg_type.IsReferenceTypes());
EXPECT_TRUE(bool_reg_type.IsCategory1Types());
EXPECT_FALSE(bool_reg_type.IsCategory2Types());
EXPECT_TRUE(bool_reg_type.IsBooleanTypes());
EXPECT_TRUE(bool_reg_type.IsByteTypes());
EXPECT_TRUE(bool_reg_type.IsShortTypes());
EXPECT_TRUE(bool_reg_type.IsCharTypes());
EXPECT_TRUE(bool_reg_type.IsIntegralTypes());
EXPECT_FALSE(bool_reg_type.IsFloatTypes());
EXPECT_FALSE(bool_reg_type.IsLongTypes());
EXPECT_FALSE(bool_reg_type.IsDoubleTypes());
EXPECT_TRUE(bool_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(bool_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(bool_reg_type.HasClass());
const RegType& byte_reg_type = cache.Byte();
EXPECT_FALSE(byte_reg_type.IsUndefined());
EXPECT_FALSE(byte_reg_type.IsConflict());
EXPECT_FALSE(byte_reg_type.IsZero());
EXPECT_FALSE(byte_reg_type.IsOne());
EXPECT_FALSE(byte_reg_type.IsLongConstant());
EXPECT_FALSE(byte_reg_type.IsBoolean());
EXPECT_TRUE(byte_reg_type.IsByte());
EXPECT_FALSE(byte_reg_type.IsChar());
EXPECT_FALSE(byte_reg_type.IsShort());
EXPECT_FALSE(byte_reg_type.IsInteger());
EXPECT_FALSE(byte_reg_type.IsLong());
EXPECT_FALSE(byte_reg_type.IsFloat());
EXPECT_FALSE(byte_reg_type.IsDouble());
EXPECT_FALSE(byte_reg_type.IsReference());
EXPECT_FALSE(byte_reg_type.IsLowHalf());
EXPECT_FALSE(byte_reg_type.IsHighHalf());
EXPECT_FALSE(byte_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(byte_reg_type.IsReferenceTypes());
EXPECT_TRUE(byte_reg_type.IsCategory1Types());
EXPECT_FALSE(byte_reg_type.IsCategory2Types());
EXPECT_FALSE(byte_reg_type.IsBooleanTypes());
EXPECT_TRUE(byte_reg_type.IsByteTypes());
EXPECT_TRUE(byte_reg_type.IsShortTypes());
EXPECT_FALSE(byte_reg_type.IsCharTypes());
EXPECT_TRUE(byte_reg_type.IsIntegralTypes());
EXPECT_FALSE(byte_reg_type.IsFloatTypes());
EXPECT_FALSE(byte_reg_type.IsLongTypes());
EXPECT_FALSE(byte_reg_type.IsDoubleTypes());
EXPECT_TRUE(byte_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(byte_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(byte_reg_type.HasClass());
const RegType& char_reg_type = cache.Char();
EXPECT_FALSE(char_reg_type.IsUndefined());
EXPECT_FALSE(char_reg_type.IsConflict());
EXPECT_FALSE(char_reg_type.IsZero());
EXPECT_FALSE(char_reg_type.IsOne());
EXPECT_FALSE(char_reg_type.IsLongConstant());
EXPECT_FALSE(char_reg_type.IsBoolean());
EXPECT_FALSE(char_reg_type.IsByte());
EXPECT_TRUE(char_reg_type.IsChar());
EXPECT_FALSE(char_reg_type.IsShort());
EXPECT_FALSE(char_reg_type.IsInteger());
EXPECT_FALSE(char_reg_type.IsLong());
EXPECT_FALSE(char_reg_type.IsFloat());
EXPECT_FALSE(char_reg_type.IsDouble());
EXPECT_FALSE(char_reg_type.IsReference());
EXPECT_FALSE(char_reg_type.IsLowHalf());
EXPECT_FALSE(char_reg_type.IsHighHalf());
EXPECT_FALSE(char_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(char_reg_type.IsReferenceTypes());
EXPECT_TRUE(char_reg_type.IsCategory1Types());
EXPECT_FALSE(char_reg_type.IsCategory2Types());
EXPECT_FALSE(char_reg_type.IsBooleanTypes());
EXPECT_FALSE(char_reg_type.IsByteTypes());
EXPECT_FALSE(char_reg_type.IsShortTypes());
EXPECT_TRUE(char_reg_type.IsCharTypes());
EXPECT_TRUE(char_reg_type.IsIntegralTypes());
EXPECT_FALSE(char_reg_type.IsFloatTypes());
EXPECT_FALSE(char_reg_type.IsLongTypes());
EXPECT_FALSE(char_reg_type.IsDoubleTypes());
EXPECT_TRUE(char_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(char_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(char_reg_type.HasClass());
const RegType& short_reg_type = cache.Short();
EXPECT_FALSE(short_reg_type.IsUndefined());
EXPECT_FALSE(short_reg_type.IsConflict());
EXPECT_FALSE(short_reg_type.IsZero());
EXPECT_FALSE(short_reg_type.IsOne());
EXPECT_FALSE(short_reg_type.IsLongConstant());
EXPECT_FALSE(short_reg_type.IsBoolean());
EXPECT_FALSE(short_reg_type.IsByte());
EXPECT_FALSE(short_reg_type.IsChar());
EXPECT_TRUE(short_reg_type.IsShort());
EXPECT_FALSE(short_reg_type.IsInteger());
EXPECT_FALSE(short_reg_type.IsLong());
EXPECT_FALSE(short_reg_type.IsFloat());
EXPECT_FALSE(short_reg_type.IsDouble());
EXPECT_FALSE(short_reg_type.IsReference());
EXPECT_FALSE(short_reg_type.IsLowHalf());
EXPECT_FALSE(short_reg_type.IsHighHalf());
EXPECT_FALSE(short_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(short_reg_type.IsReferenceTypes());
EXPECT_TRUE(short_reg_type.IsCategory1Types());
EXPECT_FALSE(short_reg_type.IsCategory2Types());
EXPECT_FALSE(short_reg_type.IsBooleanTypes());
EXPECT_FALSE(short_reg_type.IsByteTypes());
EXPECT_TRUE(short_reg_type.IsShortTypes());
EXPECT_FALSE(short_reg_type.IsCharTypes());
EXPECT_TRUE(short_reg_type.IsIntegralTypes());
EXPECT_FALSE(short_reg_type.IsFloatTypes());
EXPECT_FALSE(short_reg_type.IsLongTypes());
EXPECT_FALSE(short_reg_type.IsDoubleTypes());
EXPECT_TRUE(short_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(short_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(short_reg_type.HasClass());
const RegType& int_reg_type = cache.Integer();
EXPECT_FALSE(int_reg_type.IsUndefined());
EXPECT_FALSE(int_reg_type.IsConflict());
EXPECT_FALSE(int_reg_type.IsZero());
EXPECT_FALSE(int_reg_type.IsOne());
EXPECT_FALSE(int_reg_type.IsLongConstant());
EXPECT_FALSE(int_reg_type.IsBoolean());
EXPECT_FALSE(int_reg_type.IsByte());
EXPECT_FALSE(int_reg_type.IsChar());
EXPECT_FALSE(int_reg_type.IsShort());
EXPECT_TRUE(int_reg_type.IsInteger());
EXPECT_FALSE(int_reg_type.IsLong());
EXPECT_FALSE(int_reg_type.IsFloat());
EXPECT_FALSE(int_reg_type.IsDouble());
EXPECT_FALSE(int_reg_type.IsReference());
EXPECT_FALSE(int_reg_type.IsLowHalf());
EXPECT_FALSE(int_reg_type.IsHighHalf());
EXPECT_FALSE(int_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(int_reg_type.IsReferenceTypes());
EXPECT_TRUE(int_reg_type.IsCategory1Types());
EXPECT_FALSE(int_reg_type.IsCategory2Types());
EXPECT_FALSE(int_reg_type.IsBooleanTypes());
EXPECT_FALSE(int_reg_type.IsByteTypes());
EXPECT_FALSE(int_reg_type.IsShortTypes());
EXPECT_FALSE(int_reg_type.IsCharTypes());
EXPECT_TRUE(int_reg_type.IsIntegralTypes());
EXPECT_FALSE(int_reg_type.IsFloatTypes());
EXPECT_FALSE(int_reg_type.IsLongTypes());
EXPECT_FALSE(int_reg_type.IsDoubleTypes());
EXPECT_TRUE(int_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(int_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(int_reg_type.HasClass());
const RegType& long_reg_type = cache.LongLo();
EXPECT_FALSE(long_reg_type.IsUndefined());
EXPECT_FALSE(long_reg_type.IsConflict());
EXPECT_FALSE(long_reg_type.IsZero());
EXPECT_FALSE(long_reg_type.IsOne());
EXPECT_FALSE(long_reg_type.IsLongConstant());
EXPECT_FALSE(long_reg_type.IsBoolean());
EXPECT_FALSE(long_reg_type.IsByte());
EXPECT_FALSE(long_reg_type.IsChar());
EXPECT_FALSE(long_reg_type.IsShort());
EXPECT_FALSE(long_reg_type.IsInteger());
EXPECT_TRUE(long_reg_type.IsLong());
EXPECT_FALSE(long_reg_type.IsFloat());
EXPECT_FALSE(long_reg_type.IsDouble());
EXPECT_FALSE(long_reg_type.IsReference());
EXPECT_TRUE(long_reg_type.IsLowHalf());
EXPECT_FALSE(long_reg_type.IsHighHalf());
EXPECT_TRUE(long_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(long_reg_type.IsReferenceTypes());
EXPECT_FALSE(long_reg_type.IsCategory1Types());
EXPECT_TRUE(long_reg_type.IsCategory2Types());
EXPECT_FALSE(long_reg_type.IsBooleanTypes());
EXPECT_FALSE(long_reg_type.IsByteTypes());
EXPECT_FALSE(long_reg_type.IsShortTypes());
EXPECT_FALSE(long_reg_type.IsCharTypes());
EXPECT_FALSE(long_reg_type.IsIntegralTypes());
EXPECT_FALSE(long_reg_type.IsFloatTypes());
EXPECT_TRUE(long_reg_type.IsLongTypes());
EXPECT_FALSE(long_reg_type.IsDoubleTypes());
EXPECT_FALSE(long_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(long_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(long_reg_type.HasClass());
const RegType& float_reg_type = cache.Float();
EXPECT_FALSE(float_reg_type.IsUndefined());
EXPECT_FALSE(float_reg_type.IsConflict());
EXPECT_FALSE(float_reg_type.IsZero());
EXPECT_FALSE(float_reg_type.IsOne());
EXPECT_FALSE(float_reg_type.IsLongConstant());
EXPECT_FALSE(float_reg_type.IsBoolean());
EXPECT_FALSE(float_reg_type.IsByte());
EXPECT_FALSE(float_reg_type.IsChar());
EXPECT_FALSE(float_reg_type.IsShort());
EXPECT_FALSE(float_reg_type.IsInteger());
EXPECT_FALSE(float_reg_type.IsLong());
EXPECT_TRUE(float_reg_type.IsFloat());
EXPECT_FALSE(float_reg_type.IsDouble());
EXPECT_FALSE(float_reg_type.IsReference());
EXPECT_FALSE(float_reg_type.IsLowHalf());
EXPECT_FALSE(float_reg_type.IsHighHalf());
EXPECT_FALSE(float_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(float_reg_type.IsReferenceTypes());
EXPECT_TRUE(float_reg_type.IsCategory1Types());
EXPECT_FALSE(float_reg_type.IsCategory2Types());
EXPECT_FALSE(float_reg_type.IsBooleanTypes());
EXPECT_FALSE(float_reg_type.IsByteTypes());
EXPECT_FALSE(float_reg_type.IsShortTypes());
EXPECT_FALSE(float_reg_type.IsCharTypes());
EXPECT_FALSE(float_reg_type.IsIntegralTypes());
EXPECT_TRUE(float_reg_type.IsFloatTypes());
EXPECT_FALSE(float_reg_type.IsLongTypes());
EXPECT_FALSE(float_reg_type.IsDoubleTypes());
EXPECT_FALSE(float_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(float_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(float_reg_type.HasClass());
const RegType& double_reg_type = cache.DoubleLo();
EXPECT_FALSE(double_reg_type.IsUndefined());
EXPECT_FALSE(double_reg_type.IsConflict());
EXPECT_FALSE(double_reg_type.IsZero());
EXPECT_FALSE(double_reg_type.IsOne());
EXPECT_FALSE(double_reg_type.IsLongConstant());
EXPECT_FALSE(double_reg_type.IsBoolean());
EXPECT_FALSE(double_reg_type.IsByte());
EXPECT_FALSE(double_reg_type.IsChar());
EXPECT_FALSE(double_reg_type.IsShort());
EXPECT_FALSE(double_reg_type.IsInteger());
EXPECT_FALSE(double_reg_type.IsLong());
EXPECT_FALSE(double_reg_type.IsFloat());
EXPECT_TRUE(double_reg_type.IsDouble());
EXPECT_FALSE(double_reg_type.IsReference());
EXPECT_TRUE(double_reg_type.IsLowHalf());
EXPECT_FALSE(double_reg_type.IsHighHalf());
EXPECT_TRUE(double_reg_type.IsLongOrDoubleTypes());
EXPECT_FALSE(double_reg_type.IsReferenceTypes());
EXPECT_FALSE(double_reg_type.IsCategory1Types());
EXPECT_TRUE(double_reg_type.IsCategory2Types());
EXPECT_FALSE(double_reg_type.IsBooleanTypes());
EXPECT_FALSE(double_reg_type.IsByteTypes());
EXPECT_FALSE(double_reg_type.IsShortTypes());
EXPECT_FALSE(double_reg_type.IsCharTypes());
EXPECT_FALSE(double_reg_type.IsIntegralTypes());
EXPECT_FALSE(double_reg_type.IsFloatTypes());
EXPECT_FALSE(double_reg_type.IsLongTypes());
EXPECT_TRUE(double_reg_type.IsDoubleTypes());
EXPECT_FALSE(double_reg_type.IsArrayIndexTypes());
EXPECT_FALSE(double_reg_type.IsNonZeroReferenceTypes());
EXPECT_TRUE(double_reg_type.HasClass());
}
class RegTypeReferenceTest : public CommonRuntimeTest {};
TEST_F(RegTypeReferenceTest, JavalangObjectImprecise) {
// Tests matching precisions. A reference type that was created precise doesn't
// match the one that is imprecise.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& imprecise_obj = cache.JavaLangObject(false);
const RegType& precise_obj = cache.JavaLangObject(true);
const RegType& precise_obj_2 = cache.FromDescriptor(nullptr, "Ljava/lang/Object;", true);
EXPECT_TRUE(precise_obj.Equals(precise_obj_2));
EXPECT_FALSE(imprecise_obj.Equals(precise_obj));
EXPECT_FALSE(imprecise_obj.Equals(precise_obj));
EXPECT_FALSE(imprecise_obj.Equals(precise_obj_2));
}
TEST_F(RegTypeReferenceTest, UnresolvedType) {
// Tests creating unresolved types. Miss for the first time asking the cache and
// a hit second time.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& ref_type_0 = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
EXPECT_TRUE(ref_type_0.IsUnresolvedReference());
EXPECT_TRUE(ref_type_0.IsNonZeroReferenceTypes());
const RegType& ref_type_1 = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
EXPECT_TRUE(ref_type_0.Equals(ref_type_1));
const RegType& unresolved_super_class = cache.FromUnresolvedSuperClass(ref_type_0);
EXPECT_TRUE(unresolved_super_class.IsUnresolvedSuperClass());
EXPECT_TRUE(unresolved_super_class.IsNonZeroReferenceTypes());
}
TEST_F(RegTypeReferenceTest, UnresolvedUnintializedType) {
// Tests creating types uninitialized types from unresolved types.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& ref_type_0 = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
EXPECT_TRUE(ref_type_0.IsUnresolvedReference());
const RegType& ref_type = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
EXPECT_TRUE(ref_type_0.Equals(ref_type));
// Create an uninitialized type of this unresolved type
const RegType& unresolved_unintialised = cache.Uninitialized(ref_type, 1101ull);
EXPECT_TRUE(unresolved_unintialised.IsUnresolvedAndUninitializedReference());
EXPECT_TRUE(unresolved_unintialised.IsUninitializedTypes());
EXPECT_TRUE(unresolved_unintialised.IsNonZeroReferenceTypes());
// Create an uninitialized type of this unresolved type with different PC
const RegType& ref_type_unresolved_unintialised_1 = cache.Uninitialized(ref_type, 1102ull);
EXPECT_TRUE(unresolved_unintialised.IsUnresolvedAndUninitializedReference());
EXPECT_FALSE(unresolved_unintialised.Equals(ref_type_unresolved_unintialised_1));
// Create an uninitialized type of this unresolved type with the same PC
const RegType& unresolved_unintialised_2 = cache.Uninitialized(ref_type, 1101ull);
EXPECT_TRUE(unresolved_unintialised.Equals(unresolved_unintialised_2));
}
TEST_F(RegTypeReferenceTest, Dump) {
// Tests types for proper Dump messages.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& unresolved_ref = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
const RegType& unresolved_ref_another = cache.FromDescriptor(nullptr, "Ljava/lang/DoesNotExistEither;", true);
const RegType& resolved_ref = cache.JavaLangString();
const RegType& resolved_unintialiesd = cache.Uninitialized(resolved_ref, 10);
const RegType& unresolved_unintialized = cache.Uninitialized(unresolved_ref, 12);
const RegType& unresolved_merged = cache.FromUnresolvedMerge(
unresolved_ref, unresolved_ref_another, /* verifier */ nullptr);
std::string expected = "Unresolved Reference: java.lang.DoesNotExist";
EXPECT_EQ(expected, unresolved_ref.Dump());
expected = "Precise Reference: java.lang.String";
EXPECT_EQ(expected, resolved_ref.Dump());
expected ="Uninitialized Reference: java.lang.String Allocation PC: 10";
EXPECT_EQ(expected, resolved_unintialiesd.Dump());
expected = "Unresolved And Uninitialized Reference: java.lang.DoesNotExist Allocation PC: 12";
EXPECT_EQ(expected, unresolved_unintialized.Dump());
expected = "UnresolvedMergedReferences(Zero/null | Unresolved Reference: java.lang.DoesNotExist, Unresolved Reference: java.lang.DoesNotExistEither)";
EXPECT_EQ(expected, unresolved_merged.Dump());
}
TEST_F(RegTypeReferenceTest, JavalangString) {
// Add a class to the cache then look for the same class and make sure it is a
// Hit the second time. Then check for the same effect when using
// The JavaLangObject method instead of FromDescriptor. String class is final.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& ref_type = cache.JavaLangString();
const RegType& ref_type_2 = cache.JavaLangString();
const RegType& ref_type_3 = cache.FromDescriptor(nullptr, "Ljava/lang/String;", true);
EXPECT_TRUE(ref_type.Equals(ref_type_2));
EXPECT_TRUE(ref_type_2.Equals(ref_type_3));
EXPECT_TRUE(ref_type.IsPreciseReference());
// Create an uninitialized type out of this:
const RegType& ref_type_unintialized = cache.Uninitialized(ref_type, 0110ull);
EXPECT_TRUE(ref_type_unintialized.IsUninitializedReference());
EXPECT_FALSE(ref_type_unintialized.IsUnresolvedAndUninitializedReference());
}
TEST_F(RegTypeReferenceTest, JavalangObject) {
// Add a class to the cache then look for the same class and make sure it is a
// Hit the second time. Then I am checking for the same effect when using
// The JavaLangObject method instead of FromDescriptor. Object Class in not final.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache(true, allocator);
const RegType& ref_type = cache.JavaLangObject(true);
const RegType& ref_type_2 = cache.JavaLangObject(true);
const RegType& ref_type_3 = cache.FromDescriptor(nullptr, "Ljava/lang/Object;", true);
EXPECT_TRUE(ref_type.Equals(ref_type_2));
EXPECT_TRUE(ref_type_3.Equals(ref_type_2));
EXPECT_EQ(ref_type.GetId(), ref_type_3.GetId());
}
TEST_F(RegTypeReferenceTest, Merging) {
// Tests merging logic
// String and object , LUB is object.
ScopedObjectAccess soa(Thread::Current());
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
RegTypeCache cache_new(true, allocator);
const RegType& string = cache_new.JavaLangString();
const RegType& Object = cache_new.JavaLangObject(true);
EXPECT_TRUE(string.Merge(Object, &cache_new, /* verifier */ nullptr).IsJavaLangObject());
// Merge two unresolved types.
const RegType& ref_type_0 = cache_new.FromDescriptor(nullptr, "Ljava/lang/DoesNotExist;", true);
EXPECT_TRUE(ref_type_0.IsUnresolvedReference());
const RegType& ref_type_1 = cache_new.FromDescriptor(nullptr, "Ljava/lang/DoesNotExistToo;", true);
EXPECT_FALSE(ref_type_0.Equals(ref_type_1));
const RegType& merged = ref_type_1.Merge(ref_type_0, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsUnresolvedMergedReference());
RegType& merged_nonconst = const_cast<RegType&>(merged);
const BitVector& unresolved_parts =
down_cast<UnresolvedMergedType*>(&merged_nonconst)->GetUnresolvedTypes();
EXPECT_TRUE(unresolved_parts.IsBitSet(ref_type_0.GetId()));
EXPECT_TRUE(unresolved_parts.IsBitSet(ref_type_1.GetId()));
}
TEST_F(RegTypeTest, MergingFloat) {
// Testing merging logic with float and float constants.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache_new(true, allocator);
constexpr int32_t kTestConstantValue = 10;
const RegType& float_type = cache_new.Float();
const RegType& precise_cst = cache_new.FromCat1Const(kTestConstantValue, true);
const RegType& imprecise_cst = cache_new.FromCat1Const(kTestConstantValue, false);
{
// float MERGE precise cst => float.
const RegType& merged = float_type.Merge(precise_cst, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsFloat());
}
{
// precise cst MERGE float => float.
const RegType& merged = precise_cst.Merge(float_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsFloat());
}
{
// float MERGE imprecise cst => float.
const RegType& merged = float_type.Merge(imprecise_cst, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsFloat());
}
{
// imprecise cst MERGE float => float.
const RegType& merged = imprecise_cst.Merge(float_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsFloat());
}
}
TEST_F(RegTypeTest, MergingLong) {
// Testing merging logic with long and long constants.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache_new(true, allocator);
constexpr int32_t kTestConstantValue = 10;
const RegType& long_lo_type = cache_new.LongLo();
const RegType& long_hi_type = cache_new.LongHi();
const RegType& precise_cst_lo = cache_new.FromCat2ConstLo(kTestConstantValue, true);
const RegType& imprecise_cst_lo = cache_new.FromCat2ConstLo(kTestConstantValue, false);
const RegType& precise_cst_hi = cache_new.FromCat2ConstHi(kTestConstantValue, true);
const RegType& imprecise_cst_hi = cache_new.FromCat2ConstHi(kTestConstantValue, false);
{
// lo MERGE precise cst lo => lo.
const RegType& merged = long_lo_type.Merge(precise_cst_lo, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongLo());
}
{
// precise cst lo MERGE lo => lo.
const RegType& merged = precise_cst_lo.Merge(long_lo_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongLo());
}
{
// lo MERGE imprecise cst lo => lo.
const RegType& merged = long_lo_type.Merge(
imprecise_cst_lo, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongLo());
}
{
// imprecise cst lo MERGE lo => lo.
const RegType& merged = imprecise_cst_lo.Merge(
long_lo_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongLo());
}
{
// hi MERGE precise cst hi => hi.
const RegType& merged = long_hi_type.Merge(precise_cst_hi, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongHi());
}
{
// precise cst hi MERGE hi => hi.
const RegType& merged = precise_cst_hi.Merge(long_hi_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongHi());
}
{
// hi MERGE imprecise cst hi => hi.
const RegType& merged = long_hi_type.Merge(
imprecise_cst_hi, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongHi());
}
{
// imprecise cst hi MERGE hi => hi.
const RegType& merged = imprecise_cst_hi.Merge(
long_hi_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsLongHi());
}
}
TEST_F(RegTypeTest, MergingDouble) {
// Testing merging logic with double and double constants.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache_new(true, allocator);
constexpr int32_t kTestConstantValue = 10;
const RegType& double_lo_type = cache_new.DoubleLo();
const RegType& double_hi_type = cache_new.DoubleHi();
const RegType& precise_cst_lo = cache_new.FromCat2ConstLo(kTestConstantValue, true);
const RegType& imprecise_cst_lo = cache_new.FromCat2ConstLo(kTestConstantValue, false);
const RegType& precise_cst_hi = cache_new.FromCat2ConstHi(kTestConstantValue, true);
const RegType& imprecise_cst_hi = cache_new.FromCat2ConstHi(kTestConstantValue, false);
{
// lo MERGE precise cst lo => lo.
const RegType& merged = double_lo_type.Merge(
precise_cst_lo, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleLo());
}
{
// precise cst lo MERGE lo => lo.
const RegType& merged = precise_cst_lo.Merge(
double_lo_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleLo());
}
{
// lo MERGE imprecise cst lo => lo.
const RegType& merged = double_lo_type.Merge(
imprecise_cst_lo, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleLo());
}
{
// imprecise cst lo MERGE lo => lo.
const RegType& merged = imprecise_cst_lo.Merge(
double_lo_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleLo());
}
{
// hi MERGE precise cst hi => hi.
const RegType& merged = double_hi_type.Merge(
precise_cst_hi, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleHi());
}
{
// precise cst hi MERGE hi => hi.
const RegType& merged = precise_cst_hi.Merge(
double_hi_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleHi());
}
{
// hi MERGE imprecise cst hi => hi.
const RegType& merged = double_hi_type.Merge(
imprecise_cst_hi, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleHi());
}
{
// imprecise cst hi MERGE hi => hi.
const RegType& merged = imprecise_cst_hi.Merge(
double_hi_type, &cache_new, /* verifier */ nullptr);
EXPECT_TRUE(merged.IsDoubleHi());
}
}
TEST_F(RegTypeTest, MergeSemiLatticeRef) {
// (Incomplete) semilattice:
//
// Excluded for now: * category-2 types
// * interfaces
// * all of category-1 primitive types, including constants.
// This is to demonstrate/codify the reference side, mostly.
//
// Note: It is not a real semilattice because int = float makes this wonky. :-(
//
// Conflict
// |
// #---------#--------------------------#-----------------------------#
// | | |
// | | Object
// | | |
// int uninit types #---------------#--------#------------------#---------#
// | | | | | |
// | unresolved-merge-types | Object[] char[] byte[]
// | | | | | | | |
// | unresolved-types | #------Number #---------# | |
// | | | | | | | |
// | | #--------Integer Number[] Number[][] | |
// | | | | | | |
// | #---------------#--------#---------#--------#---------#
// | |
// | null
// | |
// #--------------------------#----------------------------#
// |
// 0
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
// We cannot allow moving GC. Otherwise we'd have to ensure the reg types are updated (reference
// reg types store a class pointer in a GCRoot, which is normally updated through active verifiers
// being registered with their thread), which is unnecessarily complex.
Runtime::Current()->GetHeap()->IncrementDisableMovingGC(soa.Self());
RegTypeCache cache(true, allocator);
const RegType& conflict = cache.Conflict();
const RegType& zero = cache.Zero();
const RegType& null = cache.Null();
const RegType& int_type = cache.Integer();
const RegType& obj = cache.JavaLangObject(false);
const RegType& obj_arr = cache.From(nullptr, "[Ljava/lang/Object;", false);
ASSERT_FALSE(obj_arr.IsUnresolvedReference());
const RegType& unresolved_a = cache.From(nullptr, "Ldoes/not/resolve/A;", false);
ASSERT_TRUE(unresolved_a.IsUnresolvedReference());
const RegType& unresolved_b = cache.From(nullptr, "Ldoes/not/resolve/B;", false);
ASSERT_TRUE(unresolved_b.IsUnresolvedReference());
const RegType& unresolved_ab = cache.FromUnresolvedMerge(unresolved_a, unresolved_b, nullptr);
ASSERT_TRUE(unresolved_ab.IsUnresolvedMergedReference());
const RegType& uninit_this = cache.UninitializedThisArgument(obj);
const RegType& uninit_obj_0 = cache.Uninitialized(obj, 0u);
const RegType& uninit_obj_1 = cache.Uninitialized(obj, 1u);
const RegType& uninit_unres_this = cache.UninitializedThisArgument(unresolved_a);
const RegType& uninit_unres_a_0 = cache.Uninitialized(unresolved_a, 0);
const RegType& uninit_unres_b_0 = cache.Uninitialized(unresolved_b, 0);
const RegType& number = cache.From(nullptr, "Ljava/lang/Number;", false);
ASSERT_FALSE(number.IsUnresolvedReference());
const RegType& integer = cache.From(nullptr, "Ljava/lang/Integer;", false);
ASSERT_FALSE(integer.IsUnresolvedReference());
const RegType& uninit_number_0 = cache.Uninitialized(number, 0u);
const RegType& uninit_integer_0 = cache.Uninitialized(integer, 0u);
const RegType& number_arr = cache.From(nullptr, "[Ljava/lang/Number;", false);
ASSERT_FALSE(number_arr.IsUnresolvedReference());
const RegType& integer_arr = cache.From(nullptr, "[Ljava/lang/Integer;", false);
ASSERT_FALSE(integer_arr.IsUnresolvedReference());
const RegType& number_arr_arr = cache.From(nullptr, "[[Ljava/lang/Number;", false);
ASSERT_FALSE(number_arr_arr.IsUnresolvedReference());
const RegType& char_arr = cache.From(nullptr, "[C", false);
ASSERT_FALSE(char_arr.IsUnresolvedReference());
const RegType& byte_arr = cache.From(nullptr, "[B", false);
ASSERT_FALSE(byte_arr.IsUnresolvedReference());
const RegType& unresolved_a_num = cache.FromUnresolvedMerge(unresolved_a, number, nullptr);
ASSERT_TRUE(unresolved_a_num.IsUnresolvedMergedReference());
const RegType& unresolved_b_num = cache.FromUnresolvedMerge(unresolved_b, number, nullptr);
ASSERT_TRUE(unresolved_b_num.IsUnresolvedMergedReference());
const RegType& unresolved_ab_num = cache.FromUnresolvedMerge(unresolved_ab, number, nullptr);
ASSERT_TRUE(unresolved_ab_num.IsUnresolvedMergedReference());
const RegType& unresolved_a_int = cache.FromUnresolvedMerge(unresolved_a, integer, nullptr);
ASSERT_TRUE(unresolved_a_int.IsUnresolvedMergedReference());
const RegType& unresolved_b_int = cache.FromUnresolvedMerge(unresolved_b, integer, nullptr);
ASSERT_TRUE(unresolved_b_int.IsUnresolvedMergedReference());
const RegType& unresolved_ab_int = cache.FromUnresolvedMerge(unresolved_ab, integer, nullptr);
ASSERT_TRUE(unresolved_ab_int.IsUnresolvedMergedReference());
std::vector<const RegType*> uninitialized_types = {
&uninit_this, &uninit_obj_0, &uninit_obj_1, &uninit_number_0, &uninit_integer_0
};
std::vector<const RegType*> unresolved_types = {
&unresolved_a,
&unresolved_b,
&unresolved_ab,
&unresolved_a_num,
&unresolved_b_num,
&unresolved_ab_num,
&unresolved_a_int,
&unresolved_b_int,
&unresolved_ab_int
};
std::vector<const RegType*> uninit_unresolved_types = {
&uninit_unres_this, &uninit_unres_a_0, &uninit_unres_b_0
};
std::vector<const RegType*> plain_nonobj_classes = { &number, &integer };
std::vector<const RegType*> plain_nonobj_arr_classes = {
&number_arr,
&number_arr_arr,
&integer_arr,
&char_arr,
};
// std::vector<const RegType*> others = { &conflict, &zero, &null, &obj, &int_type };
std::vector<const RegType*> all_minus_uninit_conflict;
all_minus_uninit_conflict.insert(all_minus_uninit_conflict.end(),
unresolved_types.begin(),
unresolved_types.end());
all_minus_uninit_conflict.insert(all_minus_uninit_conflict.end(),
plain_nonobj_classes.begin(),
plain_nonobj_classes.end());
all_minus_uninit_conflict.insert(all_minus_uninit_conflict.end(),
plain_nonobj_arr_classes.begin(),
plain_nonobj_arr_classes.end());
all_minus_uninit_conflict.push_back(&zero);
all_minus_uninit_conflict.push_back(&null);
all_minus_uninit_conflict.push_back(&obj);
std::vector<const RegType*> all_minus_uninit;
all_minus_uninit.insert(all_minus_uninit.end(),
all_minus_uninit_conflict.begin(),
all_minus_uninit_conflict.end());
all_minus_uninit.push_back(&conflict);
std::vector<const RegType*> all;
all.insert(all.end(), uninitialized_types.begin(), uninitialized_types.end());
all.insert(all.end(), uninit_unresolved_types.begin(), uninit_unresolved_types.end());
all.insert(all.end(), all_minus_uninit.begin(), all_minus_uninit.end());
all.push_back(&int_type);
auto check = [&](const RegType& in1, const RegType& in2, const RegType& expected_out)
REQUIRES_SHARED(Locks::mutator_lock_) {
const RegType& merge_result = in1.SafeMerge(in2, &cache, nullptr);
EXPECT_EQ(&expected_out, &merge_result)
<< in1.Dump() << " x " << in2.Dump() << " = " << merge_result.Dump()
<< " != " << expected_out.Dump();
};
// Identity.
{
for (auto r : all) {
check(*r, *r, *r);
}
}
// Define a covering relation through a list of Edges. We'll then derive LUBs from this and
// create checks for every pair of types.
struct Edge {
const RegType& from;
const RegType& to;
Edge(const RegType& from_, const RegType& to_) : from(from_), to(to_) {}
};
std::vector<Edge> edges;
#define ADD_EDGE(from, to) edges.emplace_back((from), (to))
// To Conflict.
{
for (auto r : uninitialized_types) {
ADD_EDGE(*r, conflict);
}
for (auto r : uninit_unresolved_types) {
ADD_EDGE(*r, conflict);
}
ADD_EDGE(obj, conflict);
ADD_EDGE(int_type, conflict);
}
ADD_EDGE(zero, null);
// Unresolved.
{
ADD_EDGE(null, unresolved_a);
ADD_EDGE(null, unresolved_b);
ADD_EDGE(unresolved_a, unresolved_ab);
ADD_EDGE(unresolved_b, unresolved_ab);
ADD_EDGE(number, unresolved_a_num);
ADD_EDGE(unresolved_a, unresolved_a_num);
ADD_EDGE(number, unresolved_b_num);
ADD_EDGE(unresolved_b, unresolved_b_num);
ADD_EDGE(number, unresolved_ab_num);
ADD_EDGE(unresolved_a_num, unresolved_ab_num);
ADD_EDGE(unresolved_b_num, unresolved_ab_num);
ADD_EDGE(unresolved_ab, unresolved_ab_num);
ADD_EDGE(integer, unresolved_a_int);
ADD_EDGE(unresolved_a, unresolved_a_int);
ADD_EDGE(integer, unresolved_b_int);
ADD_EDGE(unresolved_b, unresolved_b_int);
ADD_EDGE(integer, unresolved_ab_int);
ADD_EDGE(unresolved_a_int, unresolved_ab_int);
ADD_EDGE(unresolved_b_int, unresolved_ab_int);
ADD_EDGE(unresolved_ab, unresolved_ab_int);
ADD_EDGE(unresolved_a_int, unresolved_a_num);
ADD_EDGE(unresolved_b_int, unresolved_b_num);
ADD_EDGE(unresolved_ab_int, unresolved_ab_num);
ADD_EDGE(unresolved_ab_num, obj);
}
// Classes.
{
ADD_EDGE(null, integer);
ADD_EDGE(integer, number);
ADD_EDGE(number, obj);
}
// Arrays.
{
ADD_EDGE(integer_arr, number_arr);
ADD_EDGE(number_arr, obj_arr);
ADD_EDGE(obj_arr, obj);
ADD_EDGE(number_arr_arr, obj_arr);
ADD_EDGE(char_arr, obj);
ADD_EDGE(byte_arr, obj);
ADD_EDGE(null, integer_arr);
ADD_EDGE(null, number_arr_arr);
ADD_EDGE(null, char_arr);
ADD_EDGE(null, byte_arr);
}
// Primitive.
{
ADD_EDGE(zero, int_type);
}
#undef ADD_EDGE
// Create merge triples by using the covering relation established by edges to derive the
// expected merge for any pair of types.
// Expect merge(in1, in2) == out.
struct MergeExpectation {
const RegType& in1;
const RegType& in2;
const RegType& out;
MergeExpectation(const RegType& in1_, const RegType& in2_, const RegType& out_)
: in1(in1_), in2(in2_), out(out_) {}
};
std::vector<MergeExpectation> expectations;
for (auto r1 : all) {
for (auto r2 : all) {
if (r1 == r2) {
continue;
}
// Very simple algorithm here that is usually used with adjacency lists. Our graph is
// small, it didn't make sense to have lists per node. Thus, the regular guarantees
// of O(n + |e|) don't apply, but that is acceptable.
//
// To compute r1 lub r2 = merge(r1, r2):
// 1) Generate the reachable set of r1, name it grey.
// 2) Mark all grey reachable nodes of r2 as black.
// 3) Find black nodes with no in-edges from other black nodes.
// 4) If |3)| == 1, that's the lub.
// Generic BFS of the graph induced by edges, starting at start. new_node will be called
// with any discovered node, in order.
auto bfs = [&](auto new_node, const RegType* start) {
std::unordered_set<const RegType*> seen;
std::queue<const RegType*> work_list;
work_list.push(start);
while (!work_list.empty()) {
const RegType* cur = work_list.front();
work_list.pop();
auto it = seen.find(cur);
if (it != seen.end()) {
continue;
}
seen.insert(cur);
new_node(cur);
for (const Edge& edge : edges) {
if (&edge.from == cur) {
work_list.push(&edge.to);
}
}
}
};
std::unordered_set<const RegType*> grey;
auto compute_grey = [&](const RegType* cur) {
grey.insert(cur); // Mark discovered node as grey.
};
bfs(compute_grey, r1);
std::set<const RegType*> black;
auto compute_black = [&](const RegType* cur) {
// Mark discovered grey node as black.
if (grey.find(cur) != grey.end()) {
black.insert(cur);
}
};
bfs(compute_black, r2);
std::set<const RegType*> no_in_edge(black); // Copy of black, remove nodes with in-edges.
for (auto r : black) {
for (Edge& e : edges) {
if (&e.from == r) {
no_in_edge.erase(&e.to); // It doesn't matter whether "to" is black or not, just
// attempt to remove it.
}
}
}
// Helper to print sets when something went wrong.
auto print_set = [](auto& container) REQUIRES_SHARED(Locks::mutator_lock_) {
std::string result;
for (auto r : container) {
result.append(" + ");
result.append(r->Dump());
}
return result;
};
ASSERT_EQ(no_in_edge.size(), 1u) << r1->Dump() << " u " << r2->Dump()
<< " grey=" << print_set(grey)
<< " black=" << print_set(black)
<< " no-in-edge=" << print_set(no_in_edge);
expectations.emplace_back(*r1, *r2, **no_in_edge.begin());
}
}
// Evaluate merge expectations. The merge is expected to be commutative.
for (auto& triple : expectations) {
check(triple.in1, triple.in2, triple.out);
check(triple.in2, triple.in1, triple.out);
}
Runtime::Current()->GetHeap()->DecrementDisableMovingGC(soa.Self());
}
TEST_F(RegTypeTest, ConstPrecision) {
// Tests creating primitive types types.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
RegTypeCache cache_new(true, allocator);
const RegType& imprecise_const = cache_new.FromCat1Const(10, false);
const RegType& precise_const = cache_new.FromCat1Const(10, true);
EXPECT_TRUE(imprecise_const.IsImpreciseConstant());
EXPECT_TRUE(precise_const.IsPreciseConstant());
EXPECT_FALSE(imprecise_const.Equals(precise_const));
}
class RegTypeOOMTest : public RegTypeTest {
protected:
void SetUpRuntimeOptions(RuntimeOptions *options) OVERRIDE {
SetUpRuntimeOptionsForFillHeap(options);
// We must not appear to be a compiler, or we'll abort on the host.
callbacks_.reset();
}
};
TEST_F(RegTypeOOMTest, ClassJoinOOM) {
// TODO: Figure out why FillHeap isn't good enough under CMS.
TEST_DISABLED_WITHOUT_BAKER_READ_BARRIERS();
// Tests that we don't abort with OOMs.
ArenaStack stack(Runtime::Current()->GetArenaPool());
ScopedArenaAllocator allocator(&stack);
ScopedObjectAccess soa(Thread::Current());
// We cannot allow moving GC. Otherwise we'd have to ensure the reg types are updated (reference
// reg types store a class pointer in a GCRoot, which is normally updated through active verifiers
// being registered with their thread), which is unnecessarily complex.
Runtime::Current()->GetHeap()->IncrementDisableMovingGC(soa.Self());
// We merge nested array of primitive wrappers. These have a join type of an array of Number of
// the same depth. We start with depth five, as we want at least two newly created classes to
// test recursion (it's just more likely that nobody uses such deep arrays in runtime bringup).
constexpr const char* kIntArrayFive = "[[[[[Ljava/lang/Integer;";
constexpr const char* kFloatArrayFive = "[[[[[Ljava/lang/Float;";
constexpr const char* kNumberArrayFour = "[[[[Ljava/lang/Number;";
constexpr const char* kNumberArrayFive = "[[[[[Ljava/lang/Number;";
RegTypeCache cache(true, allocator);
const RegType& int_array_array = cache.From(nullptr, kIntArrayFive, false);
ASSERT_TRUE(int_array_array.HasClass());
const RegType& float_array_array = cache.From(nullptr, kFloatArrayFive, false);
ASSERT_TRUE(float_array_array.HasClass());
// Check assumptions: the joined classes don't exist, yet.
ClassLinker* class_linker = Runtime::Current()->GetClassLinker();
ASSERT_TRUE(class_linker->LookupClass(soa.Self(), kNumberArrayFour, nullptr) == nullptr);
ASSERT_TRUE(class_linker->LookupClass(soa.Self(), kNumberArrayFive, nullptr) == nullptr);
// Fill the heap.
VariableSizedHandleScope hs(soa.Self());
FillHeap(soa.Self(), class_linker, &hs);
const RegType& join_type = int_array_array.Merge(float_array_array, &cache, nullptr);
ASSERT_TRUE(join_type.IsUnresolvedReference());
Runtime::Current()->GetHeap()->DecrementDisableMovingGC(soa.Self());
}
} // namespace verifier
} // namespace art