| /* |
| * Copyright (c) 1997, 2015, Oracle and/or its affiliates. All rights reserved. |
| * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
| * |
| * This code is free software; you can redistribute it and/or modify it |
| * under the terms of the GNU General Public License version 2 only, as |
| * published by the Free Software Foundation. |
| * |
| * This code is distributed in the hope that it will be useful, but WITHOUT |
| * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
| * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
| * version 2 for more details (a copy is included in the LICENSE file that |
| * accompanied this code). |
| * |
| * You should have received a copy of the GNU General Public License version |
| * 2 along with this work; if not, write to the Free Software Foundation, |
| * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
| * |
| * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
| * or visit www.oracle.com if you need additional information or have any |
| * questions. |
| * |
| */ |
| |
| #include "precompiled.hpp" |
| #include "ci/ciMethodData.hpp" |
| #include "ci/ciTypeFlow.hpp" |
| #include "classfile/symbolTable.hpp" |
| #include "classfile/systemDictionary.hpp" |
| #include "compiler/compileLog.hpp" |
| #include "gc/shared/gcLocker.hpp" |
| #include "libadt/dict.hpp" |
| #include "memory/oopFactory.hpp" |
| #include "memory/resourceArea.hpp" |
| #include "oops/instanceKlass.hpp" |
| #include "oops/instanceMirrorKlass.hpp" |
| #include "oops/objArrayKlass.hpp" |
| #include "oops/typeArrayKlass.hpp" |
| #include "opto/matcher.hpp" |
| #include "opto/node.hpp" |
| #include "opto/opcodes.hpp" |
| #include "opto/type.hpp" |
| |
| // Portions of code courtesy of Clifford Click |
| |
| // Optimization - Graph Style |
| |
| // Dictionary of types shared among compilations. |
| Dict* Type::_shared_type_dict = NULL; |
| |
| // Array which maps compiler types to Basic Types |
| Type::TypeInfo Type::_type_info[Type::lastype] = { |
| { Bad, T_ILLEGAL, "bad", false, Node::NotAMachineReg, relocInfo::none }, // Bad |
| { Control, T_ILLEGAL, "control", false, 0, relocInfo::none }, // Control |
| { Bottom, T_VOID, "top", false, 0, relocInfo::none }, // Top |
| { Bad, T_INT, "int:", false, Op_RegI, relocInfo::none }, // Int |
| { Bad, T_LONG, "long:", false, Op_RegL, relocInfo::none }, // Long |
| { Half, T_VOID, "half", false, 0, relocInfo::none }, // Half |
| { Bad, T_NARROWOOP, "narrowoop:", false, Op_RegN, relocInfo::none }, // NarrowOop |
| { Bad, T_NARROWKLASS,"narrowklass:", false, Op_RegN, relocInfo::none }, // NarrowKlass |
| { Bad, T_ILLEGAL, "tuple:", false, Node::NotAMachineReg, relocInfo::none }, // Tuple |
| { Bad, T_ARRAY, "array:", false, Node::NotAMachineReg, relocInfo::none }, // Array |
| |
| #ifdef SPARC |
| { Bad, T_ILLEGAL, "vectors:", false, 0, relocInfo::none }, // VectorS |
| { Bad, T_ILLEGAL, "vectord:", false, Op_RegD, relocInfo::none }, // VectorD |
| { Bad, T_ILLEGAL, "vectorx:", false, 0, relocInfo::none }, // VectorX |
| { Bad, T_ILLEGAL, "vectory:", false, 0, relocInfo::none }, // VectorY |
| { Bad, T_ILLEGAL, "vectorz:", false, 0, relocInfo::none }, // VectorZ |
| #elif defined(PPC64) |
| { Bad, T_ILLEGAL, "vectors:", false, 0, relocInfo::none }, // VectorS |
| { Bad, T_ILLEGAL, "vectord:", false, Op_RegL, relocInfo::none }, // VectorD |
| { Bad, T_ILLEGAL, "vectorx:", false, 0, relocInfo::none }, // VectorX |
| { Bad, T_ILLEGAL, "vectory:", false, 0, relocInfo::none }, // VectorY |
| { Bad, T_ILLEGAL, "vectorz:", false, 0, relocInfo::none }, // VectorZ |
| #else // all other |
| { Bad, T_ILLEGAL, "vectors:", false, Op_VecS, relocInfo::none }, // VectorS |
| { Bad, T_ILLEGAL, "vectord:", false, Op_VecD, relocInfo::none }, // VectorD |
| { Bad, T_ILLEGAL, "vectorx:", false, Op_VecX, relocInfo::none }, // VectorX |
| { Bad, T_ILLEGAL, "vectory:", false, Op_VecY, relocInfo::none }, // VectorY |
| { Bad, T_ILLEGAL, "vectorz:", false, Op_VecZ, relocInfo::none }, // VectorZ |
| #endif |
| { Bad, T_ADDRESS, "anyptr:", false, Op_RegP, relocInfo::none }, // AnyPtr |
| { Bad, T_ADDRESS, "rawptr:", false, Op_RegP, relocInfo::none }, // RawPtr |
| { Bad, T_OBJECT, "oop:", true, Op_RegP, relocInfo::oop_type }, // OopPtr |
| { Bad, T_OBJECT, "inst:", true, Op_RegP, relocInfo::oop_type }, // InstPtr |
| { Bad, T_OBJECT, "ary:", true, Op_RegP, relocInfo::oop_type }, // AryPtr |
| { Bad, T_METADATA, "metadata:", false, Op_RegP, relocInfo::metadata_type }, // MetadataPtr |
| { Bad, T_METADATA, "klass:", false, Op_RegP, relocInfo::metadata_type }, // KlassPtr |
| { Bad, T_OBJECT, "func", false, 0, relocInfo::none }, // Function |
| { Abio, T_ILLEGAL, "abIO", false, 0, relocInfo::none }, // Abio |
| { Return_Address, T_ADDRESS, "return_address",false, Op_RegP, relocInfo::none }, // Return_Address |
| { Memory, T_ILLEGAL, "memory", false, 0, relocInfo::none }, // Memory |
| { FloatBot, T_FLOAT, "float_top", false, Op_RegF, relocInfo::none }, // FloatTop |
| { FloatCon, T_FLOAT, "ftcon:", false, Op_RegF, relocInfo::none }, // FloatCon |
| { FloatTop, T_FLOAT, "float", false, Op_RegF, relocInfo::none }, // FloatBot |
| { DoubleBot, T_DOUBLE, "double_top", false, Op_RegD, relocInfo::none }, // DoubleTop |
| { DoubleCon, T_DOUBLE, "dblcon:", false, Op_RegD, relocInfo::none }, // DoubleCon |
| { DoubleTop, T_DOUBLE, "double", false, Op_RegD, relocInfo::none }, // DoubleBot |
| { Top, T_ILLEGAL, "bottom", false, 0, relocInfo::none } // Bottom |
| }; |
| |
| // Map ideal registers (machine types) to ideal types |
| const Type *Type::mreg2type[_last_machine_leaf]; |
| |
| // Map basic types to canonical Type* pointers. |
| const Type* Type:: _const_basic_type[T_CONFLICT+1]; |
| |
| // Map basic types to constant-zero Types. |
| const Type* Type:: _zero_type[T_CONFLICT+1]; |
| |
| // Map basic types to array-body alias types. |
| const TypeAryPtr* TypeAryPtr::_array_body_type[T_CONFLICT+1]; |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const Type *Type::ABIO; // State-of-machine only |
| const Type *Type::BOTTOM; // All values |
| const Type *Type::CONTROL; // Control only |
| const Type *Type::DOUBLE; // All doubles |
| const Type *Type::FLOAT; // All floats |
| const Type *Type::HALF; // Placeholder half of doublewide type |
| const Type *Type::MEMORY; // Abstract store only |
| const Type *Type::RETURN_ADDRESS; |
| const Type *Type::TOP; // No values in set |
| |
| //------------------------------get_const_type--------------------------- |
| const Type* Type::get_const_type(ciType* type) { |
| if (type == NULL) { |
| return NULL; |
| } else if (type->is_primitive_type()) { |
| return get_const_basic_type(type->basic_type()); |
| } else { |
| return TypeOopPtr::make_from_klass(type->as_klass()); |
| } |
| } |
| |
| //---------------------------array_element_basic_type--------------------------------- |
| // Mapping to the array element's basic type. |
| BasicType Type::array_element_basic_type() const { |
| BasicType bt = basic_type(); |
| if (bt == T_INT) { |
| if (this == TypeInt::INT) return T_INT; |
| if (this == TypeInt::CHAR) return T_CHAR; |
| if (this == TypeInt::BYTE) return T_BYTE; |
| if (this == TypeInt::BOOL) return T_BOOLEAN; |
| if (this == TypeInt::SHORT) return T_SHORT; |
| return T_VOID; |
| } |
| return bt; |
| } |
| |
| // For two instance arrays of same dimension, return the base element types. |
| // Otherwise or if the arrays have different dimensions, return NULL. |
| void Type::get_arrays_base_elements(const Type *a1, const Type *a2, |
| const TypeInstPtr **e1, const TypeInstPtr **e2) { |
| |
| if (e1) *e1 = NULL; |
| if (e2) *e2 = NULL; |
| const TypeAryPtr* a1tap = (a1 == NULL) ? NULL : a1->isa_aryptr(); |
| const TypeAryPtr* a2tap = (a2 == NULL) ? NULL : a2->isa_aryptr(); |
| |
| if (a1tap != NULL && a2tap != NULL) { |
| // Handle multidimensional arrays |
| const TypePtr* a1tp = a1tap->elem()->make_ptr(); |
| const TypePtr* a2tp = a2tap->elem()->make_ptr(); |
| while (a1tp && a1tp->isa_aryptr() && a2tp && a2tp->isa_aryptr()) { |
| a1tap = a1tp->is_aryptr(); |
| a2tap = a2tp->is_aryptr(); |
| a1tp = a1tap->elem()->make_ptr(); |
| a2tp = a2tap->elem()->make_ptr(); |
| } |
| if (a1tp && a1tp->isa_instptr() && a2tp && a2tp->isa_instptr()) { |
| if (e1) *e1 = a1tp->is_instptr(); |
| if (e2) *e2 = a2tp->is_instptr(); |
| } |
| } |
| } |
| |
| //---------------------------get_typeflow_type--------------------------------- |
| // Import a type produced by ciTypeFlow. |
| const Type* Type::get_typeflow_type(ciType* type) { |
| switch (type->basic_type()) { |
| |
| case ciTypeFlow::StateVector::T_BOTTOM: |
| assert(type == ciTypeFlow::StateVector::bottom_type(), ""); |
| return Type::BOTTOM; |
| |
| case ciTypeFlow::StateVector::T_TOP: |
| assert(type == ciTypeFlow::StateVector::top_type(), ""); |
| return Type::TOP; |
| |
| case ciTypeFlow::StateVector::T_NULL: |
| assert(type == ciTypeFlow::StateVector::null_type(), ""); |
| return TypePtr::NULL_PTR; |
| |
| case ciTypeFlow::StateVector::T_LONG2: |
| // The ciTypeFlow pass pushes a long, then the half. |
| // We do the same. |
| assert(type == ciTypeFlow::StateVector::long2_type(), ""); |
| return TypeInt::TOP; |
| |
| case ciTypeFlow::StateVector::T_DOUBLE2: |
| // The ciTypeFlow pass pushes double, then the half. |
| // Our convention is the same. |
| assert(type == ciTypeFlow::StateVector::double2_type(), ""); |
| return Type::TOP; |
| |
| case T_ADDRESS: |
| assert(type->is_return_address(), ""); |
| return TypeRawPtr::make((address)(intptr_t)type->as_return_address()->bci()); |
| |
| default: |
| // make sure we did not mix up the cases: |
| assert(type != ciTypeFlow::StateVector::bottom_type(), ""); |
| assert(type != ciTypeFlow::StateVector::top_type(), ""); |
| assert(type != ciTypeFlow::StateVector::null_type(), ""); |
| assert(type != ciTypeFlow::StateVector::long2_type(), ""); |
| assert(type != ciTypeFlow::StateVector::double2_type(), ""); |
| assert(!type->is_return_address(), ""); |
| |
| return Type::get_const_type(type); |
| } |
| } |
| |
| |
| //-----------------------make_from_constant------------------------------------ |
| const Type* Type::make_from_constant(ciConstant constant, bool require_constant) { |
| switch (constant.basic_type()) { |
| case T_BOOLEAN: return TypeInt::make(constant.as_boolean()); |
| case T_CHAR: return TypeInt::make(constant.as_char()); |
| case T_BYTE: return TypeInt::make(constant.as_byte()); |
| case T_SHORT: return TypeInt::make(constant.as_short()); |
| case T_INT: return TypeInt::make(constant.as_int()); |
| case T_LONG: return TypeLong::make(constant.as_long()); |
| case T_FLOAT: return TypeF::make(constant.as_float()); |
| case T_DOUBLE: return TypeD::make(constant.as_double()); |
| case T_ARRAY: |
| case T_OBJECT: |
| { |
| // cases: |
| // can_be_constant = (oop not scavengable || ScavengeRootsInCode != 0) |
| // should_be_constant = (oop not scavengable || ScavengeRootsInCode >= 2) |
| // An oop is not scavengable if it is in the perm gen. |
| ciObject* oop_constant = constant.as_object(); |
| if (oop_constant->is_null_object()) { |
| return Type::get_zero_type(T_OBJECT); |
| } else if (require_constant || oop_constant->should_be_constant()) { |
| return TypeOopPtr::make_from_constant(oop_constant, require_constant); |
| } |
| } |
| case T_ILLEGAL: |
| // Invalid ciConstant returned due to OutOfMemoryError in the CI |
| assert(Compile::current()->env()->failing(), "otherwise should not see this"); |
| return NULL; |
| } |
| // Fall through to failure |
| return NULL; |
| } |
| |
| |
| const Type* Type::make_constant(ciField* field, Node* obj) { |
| if (!field->is_constant()) return NULL; |
| |
| const Type* con_type = NULL; |
| if (field->is_static()) { |
| // final static field |
| con_type = Type::make_from_constant(field->constant_value(), /*require_const=*/true); |
| if (Compile::current()->eliminate_boxing() && field->is_autobox_cache() && con_type != NULL) { |
| con_type = con_type->is_aryptr()->cast_to_autobox_cache(true); |
| } |
| } else { |
| // final or stable non-static field |
| // Treat final non-static fields of trusted classes (classes in |
| // java.lang.invoke and sun.invoke packages and subpackages) as |
| // compile time constants. |
| if (obj->is_Con()) { |
| const TypeOopPtr* oop_ptr = obj->bottom_type()->isa_oopptr(); |
| ciObject* constant_oop = oop_ptr->const_oop(); |
| ciConstant constant = field->constant_value_of(constant_oop); |
| con_type = Type::make_from_constant(constant, /*require_const=*/true); |
| } |
| } |
| if (FoldStableValues && field->is_stable() && con_type != NULL) { |
| if (con_type->is_zero_type()) { |
| return NULL; // the field hasn't been initialized yet |
| } else if (con_type->isa_oopptr()) { |
| const Type* stable_type = Type::get_const_type(field->type()); |
| if (field->type()->is_array_klass()) { |
| int stable_dimension = field->type()->as_array_klass()->dimension(); |
| stable_type = stable_type->is_aryptr()->cast_to_stable(true, stable_dimension); |
| } |
| if (stable_type != NULL) { |
| con_type = con_type->join_speculative(stable_type); |
| } |
| } |
| } |
| return con_type; |
| } |
| |
| //------------------------------make------------------------------------------- |
| // Create a simple Type, with default empty symbol sets. Then hashcons it |
| // and look for an existing copy in the type dictionary. |
| const Type *Type::make( enum TYPES t ) { |
| return (new Type(t))->hashcons(); |
| } |
| |
| //------------------------------cmp-------------------------------------------- |
| int Type::cmp( const Type *const t1, const Type *const t2 ) { |
| if( t1->_base != t2->_base ) |
| return 1; // Missed badly |
| assert(t1 != t2 || t1->eq(t2), "eq must be reflexive"); |
| return !t1->eq(t2); // Return ZERO if equal |
| } |
| |
| const Type* Type::maybe_remove_speculative(bool include_speculative) const { |
| if (!include_speculative) { |
| return remove_speculative(); |
| } |
| return this; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| int Type::uhash( const Type *const t ) { |
| return t->hash(); |
| } |
| |
| #define SMALLINT ((juint)3) // a value too insignificant to consider widening |
| |
| //--------------------------Initialize_shared---------------------------------- |
| void Type::Initialize_shared(Compile* current) { |
| // This method does not need to be locked because the first system |
| // compilations (stub compilations) occur serially. If they are |
| // changed to proceed in parallel, then this section will need |
| // locking. |
| |
| Arena* save = current->type_arena(); |
| Arena* shared_type_arena = new (mtCompiler)Arena(mtCompiler); |
| |
| current->set_type_arena(shared_type_arena); |
| _shared_type_dict = |
| new (shared_type_arena) Dict( (CmpKey)Type::cmp, (Hash)Type::uhash, |
| shared_type_arena, 128 ); |
| current->set_type_dict(_shared_type_dict); |
| |
| // Make shared pre-built types. |
| CONTROL = make(Control); // Control only |
| TOP = make(Top); // No values in set |
| MEMORY = make(Memory); // Abstract store only |
| ABIO = make(Abio); // State-of-machine only |
| RETURN_ADDRESS=make(Return_Address); |
| FLOAT = make(FloatBot); // All floats |
| DOUBLE = make(DoubleBot); // All doubles |
| BOTTOM = make(Bottom); // Everything |
| HALF = make(Half); // Placeholder half of doublewide type |
| |
| TypeF::ZERO = TypeF::make(0.0); // Float 0 (positive zero) |
| TypeF::ONE = TypeF::make(1.0); // Float 1 |
| |
| TypeD::ZERO = TypeD::make(0.0); // Double 0 (positive zero) |
| TypeD::ONE = TypeD::make(1.0); // Double 1 |
| |
| TypeInt::MINUS_1 = TypeInt::make(-1); // -1 |
| TypeInt::ZERO = TypeInt::make( 0); // 0 |
| TypeInt::ONE = TypeInt::make( 1); // 1 |
| TypeInt::BOOL = TypeInt::make(0,1, WidenMin); // 0 or 1, FALSE or TRUE. |
| TypeInt::CC = TypeInt::make(-1, 1, WidenMin); // -1, 0 or 1, condition codes |
| TypeInt::CC_LT = TypeInt::make(-1,-1, WidenMin); // == TypeInt::MINUS_1 |
| TypeInt::CC_GT = TypeInt::make( 1, 1, WidenMin); // == TypeInt::ONE |
| TypeInt::CC_EQ = TypeInt::make( 0, 0, WidenMin); // == TypeInt::ZERO |
| TypeInt::CC_LE = TypeInt::make(-1, 0, WidenMin); |
| TypeInt::CC_GE = TypeInt::make( 0, 1, WidenMin); // == TypeInt::BOOL |
| TypeInt::BYTE = TypeInt::make(-128,127, WidenMin); // Bytes |
| TypeInt::UBYTE = TypeInt::make(0, 255, WidenMin); // Unsigned Bytes |
| TypeInt::CHAR = TypeInt::make(0,65535, WidenMin); // Java chars |
| TypeInt::SHORT = TypeInt::make(-32768,32767, WidenMin); // Java shorts |
| TypeInt::POS = TypeInt::make(0,max_jint, WidenMin); // Non-neg values |
| TypeInt::POS1 = TypeInt::make(1,max_jint, WidenMin); // Positive values |
| TypeInt::INT = TypeInt::make(min_jint,max_jint, WidenMax); // 32-bit integers |
| TypeInt::SYMINT = TypeInt::make(-max_jint,max_jint,WidenMin); // symmetric range |
| TypeInt::TYPE_DOMAIN = TypeInt::INT; |
| // CmpL is overloaded both as the bytecode computation returning |
| // a trinary (-1,0,+1) integer result AND as an efficient long |
| // compare returning optimizer ideal-type flags. |
| assert( TypeInt::CC_LT == TypeInt::MINUS_1, "types must match for CmpL to work" ); |
| assert( TypeInt::CC_GT == TypeInt::ONE, "types must match for CmpL to work" ); |
| assert( TypeInt::CC_EQ == TypeInt::ZERO, "types must match for CmpL to work" ); |
| assert( TypeInt::CC_GE == TypeInt::BOOL, "types must match for CmpL to work" ); |
| assert( (juint)(TypeInt::CC->_hi - TypeInt::CC->_lo) <= SMALLINT, "CC is truly small"); |
| |
| TypeLong::MINUS_1 = TypeLong::make(-1); // -1 |
| TypeLong::ZERO = TypeLong::make( 0); // 0 |
| TypeLong::ONE = TypeLong::make( 1); // 1 |
| TypeLong::POS = TypeLong::make(0,max_jlong, WidenMin); // Non-neg values |
| TypeLong::LONG = TypeLong::make(min_jlong,max_jlong,WidenMax); // 64-bit integers |
| TypeLong::INT = TypeLong::make((jlong)min_jint,(jlong)max_jint,WidenMin); |
| TypeLong::UINT = TypeLong::make(0,(jlong)max_juint,WidenMin); |
| TypeLong::TYPE_DOMAIN = TypeLong::LONG; |
| |
| const Type **fboth =(const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| fboth[0] = Type::CONTROL; |
| fboth[1] = Type::CONTROL; |
| TypeTuple::IFBOTH = TypeTuple::make( 2, fboth ); |
| |
| const Type **ffalse =(const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| ffalse[0] = Type::CONTROL; |
| ffalse[1] = Type::TOP; |
| TypeTuple::IFFALSE = TypeTuple::make( 2, ffalse ); |
| |
| const Type **fneither =(const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| fneither[0] = Type::TOP; |
| fneither[1] = Type::TOP; |
| TypeTuple::IFNEITHER = TypeTuple::make( 2, fneither ); |
| |
| const Type **ftrue =(const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| ftrue[0] = Type::TOP; |
| ftrue[1] = Type::CONTROL; |
| TypeTuple::IFTRUE = TypeTuple::make( 2, ftrue ); |
| |
| const Type **floop =(const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| floop[0] = Type::CONTROL; |
| floop[1] = TypeInt::INT; |
| TypeTuple::LOOPBODY = TypeTuple::make( 2, floop ); |
| |
| TypePtr::NULL_PTR= TypePtr::make(AnyPtr, TypePtr::Null, 0); |
| TypePtr::NOTNULL = TypePtr::make(AnyPtr, TypePtr::NotNull, OffsetBot); |
| TypePtr::BOTTOM = TypePtr::make(AnyPtr, TypePtr::BotPTR, OffsetBot); |
| |
| TypeRawPtr::BOTTOM = TypeRawPtr::make( TypePtr::BotPTR ); |
| TypeRawPtr::NOTNULL= TypeRawPtr::make( TypePtr::NotNull ); |
| |
| const Type **fmembar = TypeTuple::fields(0); |
| TypeTuple::MEMBAR = TypeTuple::make(TypeFunc::Parms+0, fmembar); |
| |
| const Type **fsc = (const Type**)shared_type_arena->Amalloc_4(2*sizeof(Type*)); |
| fsc[0] = TypeInt::CC; |
| fsc[1] = Type::MEMORY; |
| TypeTuple::STORECONDITIONAL = TypeTuple::make(2, fsc); |
| |
| TypeInstPtr::NOTNULL = TypeInstPtr::make(TypePtr::NotNull, current->env()->Object_klass()); |
| TypeInstPtr::BOTTOM = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass()); |
| TypeInstPtr::MIRROR = TypeInstPtr::make(TypePtr::NotNull, current->env()->Class_klass()); |
| TypeInstPtr::MARK = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), |
| false, 0, oopDesc::mark_offset_in_bytes()); |
| TypeInstPtr::KLASS = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), |
| false, 0, oopDesc::klass_offset_in_bytes()); |
| TypeOopPtr::BOTTOM = TypeOopPtr::make(TypePtr::BotPTR, OffsetBot, TypeOopPtr::InstanceBot); |
| |
| TypeMetadataPtr::BOTTOM = TypeMetadataPtr::make(TypePtr::BotPTR, NULL, OffsetBot); |
| |
| TypeNarrowOop::NULL_PTR = TypeNarrowOop::make( TypePtr::NULL_PTR ); |
| TypeNarrowOop::BOTTOM = TypeNarrowOop::make( TypeInstPtr::BOTTOM ); |
| |
| TypeNarrowKlass::NULL_PTR = TypeNarrowKlass::make( TypePtr::NULL_PTR ); |
| |
| mreg2type[Op_Node] = Type::BOTTOM; |
| mreg2type[Op_Set ] = 0; |
| mreg2type[Op_RegN] = TypeNarrowOop::BOTTOM; |
| mreg2type[Op_RegI] = TypeInt::INT; |
| mreg2type[Op_RegP] = TypePtr::BOTTOM; |
| mreg2type[Op_RegF] = Type::FLOAT; |
| mreg2type[Op_RegD] = Type::DOUBLE; |
| mreg2type[Op_RegL] = TypeLong::LONG; |
| mreg2type[Op_RegFlags] = TypeInt::CC; |
| |
| TypeAryPtr::RANGE = TypeAryPtr::make( TypePtr::BotPTR, TypeAry::make(Type::BOTTOM,TypeInt::POS), NULL /* current->env()->Object_klass() */, false, arrayOopDesc::length_offset_in_bytes()); |
| |
| TypeAryPtr::NARROWOOPS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeNarrowOop::BOTTOM, TypeInt::POS), NULL /*ciArrayKlass::make(o)*/, false, Type::OffsetBot); |
| |
| #ifdef _LP64 |
| if (UseCompressedOops) { |
| assert(TypeAryPtr::NARROWOOPS->is_ptr_to_narrowoop(), "array of narrow oops must be ptr to narrow oop"); |
| TypeAryPtr::OOPS = TypeAryPtr::NARROWOOPS; |
| } else |
| #endif |
| { |
| // There is no shared klass for Object[]. See note in TypeAryPtr::klass(). |
| TypeAryPtr::OOPS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInstPtr::BOTTOM,TypeInt::POS), NULL /*ciArrayKlass::make(o)*/, false, Type::OffsetBot); |
| } |
| TypeAryPtr::BYTES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::BYTE ,TypeInt::POS), ciTypeArrayKlass::make(T_BYTE), true, Type::OffsetBot); |
| TypeAryPtr::SHORTS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::SHORT ,TypeInt::POS), ciTypeArrayKlass::make(T_SHORT), true, Type::OffsetBot); |
| TypeAryPtr::CHARS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::CHAR ,TypeInt::POS), ciTypeArrayKlass::make(T_CHAR), true, Type::OffsetBot); |
| TypeAryPtr::INTS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::INT ,TypeInt::POS), ciTypeArrayKlass::make(T_INT), true, Type::OffsetBot); |
| TypeAryPtr::LONGS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeLong::LONG ,TypeInt::POS), ciTypeArrayKlass::make(T_LONG), true, Type::OffsetBot); |
| TypeAryPtr::FLOATS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::FLOAT ,TypeInt::POS), ciTypeArrayKlass::make(T_FLOAT), true, Type::OffsetBot); |
| TypeAryPtr::DOUBLES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::DOUBLE ,TypeInt::POS), ciTypeArrayKlass::make(T_DOUBLE), true, Type::OffsetBot); |
| |
| // Nobody should ask _array_body_type[T_NARROWOOP]. Use NULL as assert. |
| TypeAryPtr::_array_body_type[T_NARROWOOP] = NULL; |
| TypeAryPtr::_array_body_type[T_OBJECT] = TypeAryPtr::OOPS; |
| TypeAryPtr::_array_body_type[T_ARRAY] = TypeAryPtr::OOPS; // arrays are stored in oop arrays |
| TypeAryPtr::_array_body_type[T_BYTE] = TypeAryPtr::BYTES; |
| TypeAryPtr::_array_body_type[T_BOOLEAN] = TypeAryPtr::BYTES; // boolean[] is a byte array |
| TypeAryPtr::_array_body_type[T_SHORT] = TypeAryPtr::SHORTS; |
| TypeAryPtr::_array_body_type[T_CHAR] = TypeAryPtr::CHARS; |
| TypeAryPtr::_array_body_type[T_INT] = TypeAryPtr::INTS; |
| TypeAryPtr::_array_body_type[T_LONG] = TypeAryPtr::LONGS; |
| TypeAryPtr::_array_body_type[T_FLOAT] = TypeAryPtr::FLOATS; |
| TypeAryPtr::_array_body_type[T_DOUBLE] = TypeAryPtr::DOUBLES; |
| |
| TypeKlassPtr::OBJECT = TypeKlassPtr::make( TypePtr::NotNull, current->env()->Object_klass(), 0 ); |
| TypeKlassPtr::OBJECT_OR_NULL = TypeKlassPtr::make( TypePtr::BotPTR, current->env()->Object_klass(), 0 ); |
| |
| const Type **fi2c = TypeTuple::fields(2); |
| fi2c[TypeFunc::Parms+0] = TypeInstPtr::BOTTOM; // Method* |
| fi2c[TypeFunc::Parms+1] = TypeRawPtr::BOTTOM; // argument pointer |
| TypeTuple::START_I2C = TypeTuple::make(TypeFunc::Parms+2, fi2c); |
| |
| const Type **intpair = TypeTuple::fields(2); |
| intpair[0] = TypeInt::INT; |
| intpair[1] = TypeInt::INT; |
| TypeTuple::INT_PAIR = TypeTuple::make(2, intpair); |
| |
| const Type **longpair = TypeTuple::fields(2); |
| longpair[0] = TypeLong::LONG; |
| longpair[1] = TypeLong::LONG; |
| TypeTuple::LONG_PAIR = TypeTuple::make(2, longpair); |
| |
| const Type **intccpair = TypeTuple::fields(2); |
| intccpair[0] = TypeInt::INT; |
| intccpair[1] = TypeInt::CC; |
| TypeTuple::INT_CC_PAIR = TypeTuple::make(2, intccpair); |
| |
| const Type **longccpair = TypeTuple::fields(2); |
| longccpair[0] = TypeLong::LONG; |
| longccpair[1] = TypeInt::CC; |
| TypeTuple::LONG_CC_PAIR = TypeTuple::make(2, longccpair); |
| |
| _const_basic_type[T_NARROWOOP] = TypeNarrowOop::BOTTOM; |
| _const_basic_type[T_NARROWKLASS] = Type::BOTTOM; |
| _const_basic_type[T_BOOLEAN] = TypeInt::BOOL; |
| _const_basic_type[T_CHAR] = TypeInt::CHAR; |
| _const_basic_type[T_BYTE] = TypeInt::BYTE; |
| _const_basic_type[T_SHORT] = TypeInt::SHORT; |
| _const_basic_type[T_INT] = TypeInt::INT; |
| _const_basic_type[T_LONG] = TypeLong::LONG; |
| _const_basic_type[T_FLOAT] = Type::FLOAT; |
| _const_basic_type[T_DOUBLE] = Type::DOUBLE; |
| _const_basic_type[T_OBJECT] = TypeInstPtr::BOTTOM; |
| _const_basic_type[T_ARRAY] = TypeInstPtr::BOTTOM; // there is no separate bottom for arrays |
| _const_basic_type[T_VOID] = TypePtr::NULL_PTR; // reflection represents void this way |
| _const_basic_type[T_ADDRESS] = TypeRawPtr::BOTTOM; // both interpreter return addresses & random raw ptrs |
| _const_basic_type[T_CONFLICT] = Type::BOTTOM; // why not? |
| |
| _zero_type[T_NARROWOOP] = TypeNarrowOop::NULL_PTR; |
| _zero_type[T_NARROWKLASS] = TypeNarrowKlass::NULL_PTR; |
| _zero_type[T_BOOLEAN] = TypeInt::ZERO; // false == 0 |
| _zero_type[T_CHAR] = TypeInt::ZERO; // '\0' == 0 |
| _zero_type[T_BYTE] = TypeInt::ZERO; // 0x00 == 0 |
| _zero_type[T_SHORT] = TypeInt::ZERO; // 0x0000 == 0 |
| _zero_type[T_INT] = TypeInt::ZERO; |
| _zero_type[T_LONG] = TypeLong::ZERO; |
| _zero_type[T_FLOAT] = TypeF::ZERO; |
| _zero_type[T_DOUBLE] = TypeD::ZERO; |
| _zero_type[T_OBJECT] = TypePtr::NULL_PTR; |
| _zero_type[T_ARRAY] = TypePtr::NULL_PTR; // null array is null oop |
| _zero_type[T_ADDRESS] = TypePtr::NULL_PTR; // raw pointers use the same null |
| _zero_type[T_VOID] = Type::TOP; // the only void value is no value at all |
| |
| // get_zero_type() should not happen for T_CONFLICT |
| _zero_type[T_CONFLICT]= NULL; |
| |
| // Vector predefined types, it needs initialized _const_basic_type[]. |
| if (Matcher::vector_size_supported(T_BYTE,4)) { |
| TypeVect::VECTS = TypeVect::make(T_BYTE,4); |
| } |
| if (Matcher::vector_size_supported(T_FLOAT,2)) { |
| TypeVect::VECTD = TypeVect::make(T_FLOAT,2); |
| } |
| if (Matcher::vector_size_supported(T_FLOAT,4)) { |
| TypeVect::VECTX = TypeVect::make(T_FLOAT,4); |
| } |
| if (Matcher::vector_size_supported(T_FLOAT,8)) { |
| TypeVect::VECTY = TypeVect::make(T_FLOAT,8); |
| } |
| if (Matcher::vector_size_supported(T_FLOAT,16)) { |
| TypeVect::VECTZ = TypeVect::make(T_FLOAT,16); |
| } |
| mreg2type[Op_VecS] = TypeVect::VECTS; |
| mreg2type[Op_VecD] = TypeVect::VECTD; |
| mreg2type[Op_VecX] = TypeVect::VECTX; |
| mreg2type[Op_VecY] = TypeVect::VECTY; |
| mreg2type[Op_VecZ] = TypeVect::VECTZ; |
| |
| // Restore working type arena. |
| current->set_type_arena(save); |
| current->set_type_dict(NULL); |
| } |
| |
| //------------------------------Initialize------------------------------------- |
| void Type::Initialize(Compile* current) { |
| assert(current->type_arena() != NULL, "must have created type arena"); |
| |
| if (_shared_type_dict == NULL) { |
| Initialize_shared(current); |
| } |
| |
| Arena* type_arena = current->type_arena(); |
| |
| // Create the hash-cons'ing dictionary with top-level storage allocation |
| Dict *tdic = new (type_arena) Dict( (CmpKey)Type::cmp,(Hash)Type::uhash, type_arena, 128 ); |
| current->set_type_dict(tdic); |
| |
| // Transfer the shared types. |
| DictI i(_shared_type_dict); |
| for( ; i.test(); ++i ) { |
| Type* t = (Type*)i._value; |
| tdic->Insert(t,t); // New Type, insert into Type table |
| } |
| } |
| |
| //------------------------------hashcons--------------------------------------- |
| // Do the hash-cons trick. If the Type already exists in the type table, |
| // delete the current Type and return the existing Type. Otherwise stick the |
| // current Type in the Type table. |
| const Type *Type::hashcons(void) { |
| debug_only(base()); // Check the assertion in Type::base(). |
| // Look up the Type in the Type dictionary |
| Dict *tdic = type_dict(); |
| Type* old = (Type*)(tdic->Insert(this, this, false)); |
| if( old ) { // Pre-existing Type? |
| if( old != this ) // Yes, this guy is not the pre-existing? |
| delete this; // Yes, Nuke this guy |
| assert( old->_dual, "" ); |
| return old; // Return pre-existing |
| } |
| |
| // Every type has a dual (to make my lattice symmetric). |
| // Since we just discovered a new Type, compute its dual right now. |
| assert( !_dual, "" ); // No dual yet |
| _dual = xdual(); // Compute the dual |
| if( cmp(this,_dual)==0 ) { // Handle self-symmetric |
| _dual = this; |
| return this; |
| } |
| assert( !_dual->_dual, "" ); // No reverse dual yet |
| assert( !(*tdic)[_dual], "" ); // Dual not in type system either |
| // New Type, insert into Type table |
| tdic->Insert((void*)_dual,(void*)_dual); |
| ((Type*)_dual)->_dual = this; // Finish up being symmetric |
| #ifdef ASSERT |
| Type *dual_dual = (Type*)_dual->xdual(); |
| assert( eq(dual_dual), "xdual(xdual()) should be identity" ); |
| delete dual_dual; |
| #endif |
| return this; // Return new Type |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool Type::eq( const Type * ) const { |
| return true; // Nothing else can go wrong |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int Type::hash(void) const { |
| return _base; |
| } |
| |
| //------------------------------is_finite-------------------------------------- |
| // Has a finite value |
| bool Type::is_finite() const { |
| return false; |
| } |
| |
| //------------------------------is_nan----------------------------------------- |
| // Is not a number (NaN) |
| bool Type::is_nan() const { |
| return false; |
| } |
| |
| //----------------------interface_vs_oop--------------------------------------- |
| #ifdef ASSERT |
| bool Type::interface_vs_oop_helper(const Type *t) const { |
| bool result = false; |
| |
| const TypePtr* this_ptr = this->make_ptr(); // In case it is narrow_oop |
| const TypePtr* t_ptr = t->make_ptr(); |
| if( this_ptr == NULL || t_ptr == NULL ) |
| return result; |
| |
| const TypeInstPtr* this_inst = this_ptr->isa_instptr(); |
| const TypeInstPtr* t_inst = t_ptr->isa_instptr(); |
| if( this_inst && this_inst->is_loaded() && t_inst && t_inst->is_loaded() ) { |
| bool this_interface = this_inst->klass()->is_interface(); |
| bool t_interface = t_inst->klass()->is_interface(); |
| result = this_interface ^ t_interface; |
| } |
| |
| return result; |
| } |
| |
| bool Type::interface_vs_oop(const Type *t) const { |
| if (interface_vs_oop_helper(t)) { |
| return true; |
| } |
| // Now check the speculative parts as well |
| const TypePtr* this_spec = isa_ptr() != NULL ? is_ptr()->speculative() : NULL; |
| const TypePtr* t_spec = t->isa_ptr() != NULL ? t->is_ptr()->speculative() : NULL; |
| if (this_spec != NULL && t_spec != NULL) { |
| if (this_spec->interface_vs_oop_helper(t_spec)) { |
| return true; |
| } |
| return false; |
| } |
| if (this_spec != NULL && this_spec->interface_vs_oop_helper(t)) { |
| return true; |
| } |
| if (t_spec != NULL && interface_vs_oop_helper(t_spec)) { |
| return true; |
| } |
| return false; |
| } |
| |
| #endif |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. NOT virtual. It enforces that meet is |
| // commutative and the lattice is symmetric. |
| const Type *Type::meet_helper(const Type *t, bool include_speculative) const { |
| if (isa_narrowoop() && t->isa_narrowoop()) { |
| const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative); |
| return result->make_narrowoop(); |
| } |
| if (isa_narrowklass() && t->isa_narrowklass()) { |
| const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative); |
| return result->make_narrowklass(); |
| } |
| |
| const Type *this_t = maybe_remove_speculative(include_speculative); |
| t = t->maybe_remove_speculative(include_speculative); |
| |
| const Type *mt = this_t->xmeet(t); |
| if (isa_narrowoop() || t->isa_narrowoop()) return mt; |
| if (isa_narrowklass() || t->isa_narrowklass()) return mt; |
| #ifdef ASSERT |
| assert(mt == t->xmeet(this_t), "meet not commutative"); |
| const Type* dual_join = mt->_dual; |
| const Type *t2t = dual_join->xmeet(t->_dual); |
| const Type *t2this = dual_join->xmeet(this_t->_dual); |
| |
| // Interface meet Oop is Not Symmetric: |
| // Interface:AnyNull meet Oop:AnyNull == Interface:AnyNull |
| // Interface:NotNull meet Oop:NotNull == java/lang/Object:NotNull |
| |
| if( !interface_vs_oop(t) && (t2t != t->_dual || t2this != this_t->_dual) ) { |
| tty->print_cr("=== Meet Not Symmetric ==="); |
| tty->print("t = "); t->dump(); tty->cr(); |
| tty->print("this= "); this_t->dump(); tty->cr(); |
| tty->print("mt=(t meet this)= "); mt->dump(); tty->cr(); |
| |
| tty->print("t_dual= "); t->_dual->dump(); tty->cr(); |
| tty->print("this_dual= "); this_t->_dual->dump(); tty->cr(); |
| tty->print("mt_dual= "); mt->_dual->dump(); tty->cr(); |
| |
| tty->print("mt_dual meet t_dual= "); t2t ->dump(); tty->cr(); |
| tty->print("mt_dual meet this_dual= "); t2this ->dump(); tty->cr(); |
| |
| fatal("meet not symmetric" ); |
| } |
| #endif |
| return mt; |
| } |
| |
| //------------------------------xmeet------------------------------------------ |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *Type::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Meeting TOP with anything? |
| if( _base == Top ) return t; |
| |
| // Meeting BOTTOM with anything? |
| if( _base == Bottom ) return BOTTOM; |
| |
| // Current "this->_base" is one of: Bad, Multi, Control, Top, |
| // Abio, Abstore, Floatxxx, Doublexxx, Bottom, lastype. |
| switch (t->base()) { // Switch on original type |
| |
| // Cut in half the number of cases I must handle. Only need cases for when |
| // the given enum "t->type" is less than or equal to the local enum "type". |
| case FloatCon: |
| case DoubleCon: |
| case Int: |
| case Long: |
| return t->xmeet(this); |
| |
| case OopPtr: |
| return t->xmeet(this); |
| |
| case InstPtr: |
| return t->xmeet(this); |
| |
| case MetadataPtr: |
| case KlassPtr: |
| return t->xmeet(this); |
| |
| case AryPtr: |
| return t->xmeet(this); |
| |
| case NarrowOop: |
| return t->xmeet(this); |
| |
| case NarrowKlass: |
| return t->xmeet(this); |
| |
| case Bad: // Type check |
| default: // Bogus type not in lattice |
| typerr(t); |
| return Type::BOTTOM; |
| |
| case Bottom: // Ye Olde Default |
| return t; |
| |
| case FloatTop: |
| if( _base == FloatTop ) return this; |
| case FloatBot: // Float |
| if( _base == FloatBot || _base == FloatTop ) return FLOAT; |
| if( _base == DoubleTop || _base == DoubleBot ) return Type::BOTTOM; |
| typerr(t); |
| return Type::BOTTOM; |
| |
| case DoubleTop: |
| if( _base == DoubleTop ) return this; |
| case DoubleBot: // Double |
| if( _base == DoubleBot || _base == DoubleTop ) return DOUBLE; |
| if( _base == FloatTop || _base == FloatBot ) return Type::BOTTOM; |
| typerr(t); |
| return Type::BOTTOM; |
| |
| // These next few cases must match exactly or it is a compile-time error. |
| case Control: // Control of code |
| case Abio: // State of world outside of program |
| case Memory: |
| if( _base == t->_base ) return this; |
| typerr(t); |
| return Type::BOTTOM; |
| |
| case Top: // Top of the lattice |
| return this; |
| } |
| |
| // The type is unchanged |
| return this; |
| } |
| |
| //-----------------------------filter------------------------------------------ |
| const Type *Type::filter_helper(const Type *kills, bool include_speculative) const { |
| const Type* ft = join_helper(kills, include_speculative); |
| if (ft->empty()) |
| return Type::TOP; // Canonical empty value |
| return ft; |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Compute dual right now. |
| const Type::TYPES Type::dual_type[Type::lastype] = { |
| Bad, // Bad |
| Control, // Control |
| Bottom, // Top |
| Bad, // Int - handled in v-call |
| Bad, // Long - handled in v-call |
| Half, // Half |
| Bad, // NarrowOop - handled in v-call |
| Bad, // NarrowKlass - handled in v-call |
| |
| Bad, // Tuple - handled in v-call |
| Bad, // Array - handled in v-call |
| Bad, // VectorS - handled in v-call |
| Bad, // VectorD - handled in v-call |
| Bad, // VectorX - handled in v-call |
| Bad, // VectorY - handled in v-call |
| Bad, // VectorZ - handled in v-call |
| |
| Bad, // AnyPtr - handled in v-call |
| Bad, // RawPtr - handled in v-call |
| Bad, // OopPtr - handled in v-call |
| Bad, // InstPtr - handled in v-call |
| Bad, // AryPtr - handled in v-call |
| |
| Bad, // MetadataPtr - handled in v-call |
| Bad, // KlassPtr - handled in v-call |
| |
| Bad, // Function - handled in v-call |
| Abio, // Abio |
| Return_Address,// Return_Address |
| Memory, // Memory |
| FloatBot, // FloatTop |
| FloatCon, // FloatCon |
| FloatTop, // FloatBot |
| DoubleBot, // DoubleTop |
| DoubleCon, // DoubleCon |
| DoubleTop, // DoubleBot |
| Top // Bottom |
| }; |
| |
| const Type *Type::xdual() const { |
| // Note: the base() accessor asserts the sanity of _base. |
| assert(_type_info[base()].dual_type != Bad, "implement with v-call"); |
| return new Type(_type_info[_base].dual_type); |
| } |
| |
| //------------------------------has_memory------------------------------------- |
| bool Type::has_memory() const { |
| Type::TYPES tx = base(); |
| if (tx == Memory) return true; |
| if (tx == Tuple) { |
| const TypeTuple *t = is_tuple(); |
| for (uint i=0; i < t->cnt(); i++) { |
| tx = t->field_at(i)->base(); |
| if (tx == Memory) return true; |
| } |
| } |
| return false; |
| } |
| |
| #ifndef PRODUCT |
| //------------------------------dump2------------------------------------------ |
| void Type::dump2( Dict &d, uint depth, outputStream *st ) const { |
| st->print("%s", _type_info[_base].msg); |
| } |
| |
| //------------------------------dump------------------------------------------- |
| void Type::dump_on(outputStream *st) const { |
| ResourceMark rm; |
| Dict d(cmpkey,hashkey); // Stop recursive type dumping |
| dump2(d,1, st); |
| if (is_ptr_to_narrowoop()) { |
| st->print(" [narrow]"); |
| } else if (is_ptr_to_narrowklass()) { |
| st->print(" [narrowklass]"); |
| } |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants. |
| bool Type::singleton(void) const { |
| return _base == Top || _base == Half; |
| } |
| |
| //------------------------------empty------------------------------------------ |
| // TRUE if Type is a type with no values, FALSE otherwise. |
| bool Type::empty(void) const { |
| switch (_base) { |
| case DoubleTop: |
| case FloatTop: |
| case Top: |
| return true; |
| |
| case Half: |
| case Abio: |
| case Return_Address: |
| case Memory: |
| case Bottom: |
| case FloatBot: |
| case DoubleBot: |
| return false; // never a singleton, therefore never empty |
| } |
| |
| ShouldNotReachHere(); |
| return false; |
| } |
| |
| //------------------------------dump_stats------------------------------------- |
| // Dump collected statistics to stderr |
| #ifndef PRODUCT |
| void Type::dump_stats() { |
| tty->print("Types made: %d\n", type_dict()->Size()); |
| } |
| #endif |
| |
| //------------------------------typerr----------------------------------------- |
| void Type::typerr( const Type *t ) const { |
| #ifndef PRODUCT |
| tty->print("\nError mixing types: "); |
| dump(); |
| tty->print(" and "); |
| t->dump(); |
| tty->print("\n"); |
| #endif |
| ShouldNotReachHere(); |
| } |
| |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeF *TypeF::ZERO; // Floating point zero |
| const TypeF *TypeF::ONE; // Floating point one |
| |
| //------------------------------make------------------------------------------- |
| // Create a float constant |
| const TypeF *TypeF::make(float f) { |
| return (TypeF*)(new TypeF(f))->hashcons(); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeF::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is FloatCon |
| switch (t->base()) { // Switch on original type |
| case AnyPtr: // Mixing with oops happens when javac |
| case RawPtr: // reuses local variables |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| case NarrowOop: |
| case NarrowKlass: |
| case Int: |
| case Long: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| |
| case FloatBot: |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case FloatCon: // Float-constant vs Float-constant? |
| if( jint_cast(_f) != jint_cast(t->getf()) ) // unequal constants? |
| // must compare bitwise as positive zero, negative zero and NaN have |
| // all the same representation in C++ |
| return FLOAT; // Return generic float |
| // Equal constants |
| case Top: |
| case FloatTop: |
| break; // Return the float constant |
| } |
| return this; // Return the float constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: symmetric |
| const Type *TypeF::xdual() const { |
| return this; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeF::eq(const Type *t) const { |
| // Bitwise comparison to distinguish between +/-0. These values must be treated |
| // as different to be consistent with C1 and the interpreter. |
| return (jint_cast(_f) == jint_cast(t->getf())); |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeF::hash(void) const { |
| return *(int*)(&_f); |
| } |
| |
| //------------------------------is_finite-------------------------------------- |
| // Has a finite value |
| bool TypeF::is_finite() const { |
| return g_isfinite(getf()) != 0; |
| } |
| |
| //------------------------------is_nan----------------------------------------- |
| // Is not a number (NaN) |
| bool TypeF::is_nan() const { |
| return g_isnan(getf()) != 0; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump float constant Type |
| #ifndef PRODUCT |
| void TypeF::dump2( Dict &d, uint depth, outputStream *st ) const { |
| Type::dump2(d,depth, st); |
| st->print("%f", _f); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants |
| // or a single symbol. |
| bool TypeF::singleton(void) const { |
| return true; // Always a singleton |
| } |
| |
| bool TypeF::empty(void) const { |
| return false; // always exactly a singleton |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeD *TypeD::ZERO; // Floating point zero |
| const TypeD *TypeD::ONE; // Floating point one |
| |
| //------------------------------make------------------------------------------- |
| const TypeD *TypeD::make(double d) { |
| return (TypeD*)(new TypeD(d))->hashcons(); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeD::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is DoubleCon |
| switch (t->base()) { // Switch on original type |
| case AnyPtr: // Mixing with oops happens when javac |
| case RawPtr: // reuses local variables |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| case NarrowOop: |
| case NarrowKlass: |
| case Int: |
| case Long: |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| |
| case DoubleBot: |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case DoubleCon: // Double-constant vs Double-constant? |
| if( jlong_cast(_d) != jlong_cast(t->getd()) ) // unequal constants? (see comment in TypeF::xmeet) |
| return DOUBLE; // Return generic double |
| case Top: |
| case DoubleTop: |
| break; |
| } |
| return this; // Return the double constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: symmetric |
| const Type *TypeD::xdual() const { |
| return this; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeD::eq(const Type *t) const { |
| // Bitwise comparison to distinguish between +/-0. These values must be treated |
| // as different to be consistent with C1 and the interpreter. |
| return (jlong_cast(_d) == jlong_cast(t->getd())); |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeD::hash(void) const { |
| return *(int*)(&_d); |
| } |
| |
| //------------------------------is_finite-------------------------------------- |
| // Has a finite value |
| bool TypeD::is_finite() const { |
| return g_isfinite(getd()) != 0; |
| } |
| |
| //------------------------------is_nan----------------------------------------- |
| // Is not a number (NaN) |
| bool TypeD::is_nan() const { |
| return g_isnan(getd()) != 0; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump double constant Type |
| #ifndef PRODUCT |
| void TypeD::dump2( Dict &d, uint depth, outputStream *st ) const { |
| Type::dump2(d,depth,st); |
| st->print("%f", _d); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants |
| // or a single symbol. |
| bool TypeD::singleton(void) const { |
| return true; // Always a singleton |
| } |
| |
| bool TypeD::empty(void) const { |
| return false; // always exactly a singleton |
| } |
| |
| //============================================================================= |
| // Convience common pre-built types. |
| const TypeInt *TypeInt::MINUS_1;// -1 |
| const TypeInt *TypeInt::ZERO; // 0 |
| const TypeInt *TypeInt::ONE; // 1 |
| const TypeInt *TypeInt::BOOL; // 0 or 1, FALSE or TRUE. |
| const TypeInt *TypeInt::CC; // -1,0 or 1, condition codes |
| const TypeInt *TypeInt::CC_LT; // [-1] == MINUS_1 |
| const TypeInt *TypeInt::CC_GT; // [1] == ONE |
| const TypeInt *TypeInt::CC_EQ; // [0] == ZERO |
| const TypeInt *TypeInt::CC_LE; // [-1,0] |
| const TypeInt *TypeInt::CC_GE; // [0,1] == BOOL (!) |
| const TypeInt *TypeInt::BYTE; // Bytes, -128 to 127 |
| const TypeInt *TypeInt::UBYTE; // Unsigned Bytes, 0 to 255 |
| const TypeInt *TypeInt::CHAR; // Java chars, 0-65535 |
| const TypeInt *TypeInt::SHORT; // Java shorts, -32768-32767 |
| const TypeInt *TypeInt::POS; // Positive 32-bit integers or zero |
| const TypeInt *TypeInt::POS1; // Positive 32-bit integers |
| const TypeInt *TypeInt::INT; // 32-bit integers |
| const TypeInt *TypeInt::SYMINT; // symmetric range [-max_jint..max_jint] |
| const TypeInt *TypeInt::TYPE_DOMAIN; // alias for TypeInt::INT |
| |
| //------------------------------TypeInt---------------------------------------- |
| TypeInt::TypeInt( jint lo, jint hi, int w ) : Type(Int), _lo(lo), _hi(hi), _widen(w) { |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeInt *TypeInt::make( jint lo ) { |
| return (TypeInt*)(new TypeInt(lo,lo,WidenMin))->hashcons(); |
| } |
| |
| static int normalize_int_widen( jint lo, jint hi, int w ) { |
| // Certain normalizations keep us sane when comparing types. |
| // The 'SMALLINT' covers constants and also CC and its relatives. |
| if (lo <= hi) { |
| if (((juint)hi - lo) <= SMALLINT) w = Type::WidenMin; |
| if (((juint)hi - lo) >= max_juint) w = Type::WidenMax; // TypeInt::INT |
| } else { |
| if (((juint)lo - hi) <= SMALLINT) w = Type::WidenMin; |
| if (((juint)lo - hi) >= max_juint) w = Type::WidenMin; // dual TypeInt::INT |
| } |
| return w; |
| } |
| |
| const TypeInt *TypeInt::make( jint lo, jint hi, int w ) { |
| w = normalize_int_widen(lo, hi, w); |
| return (TypeInt*)(new TypeInt(lo,hi,w))->hashcons(); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type representation object |
| // with reference count equal to the number of Types pointing at it. |
| // Caller should wrap a Types around it. |
| const Type *TypeInt::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type? |
| |
| // Currently "this->_base" is a TypeInt |
| switch (t->base()) { // Switch on original type |
| case AnyPtr: // Mixing with oops happens when javac |
| case RawPtr: // reuses local variables |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| case NarrowOop: |
| case NarrowKlass: |
| case Long: |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| default: // All else is a mistake |
| typerr(t); |
| case Top: // No change |
| return this; |
| case Int: // Int vs Int? |
| break; |
| } |
| |
| // Expand covered set |
| const TypeInt *r = t->is_int(); |
| return make( MIN2(_lo,r->_lo), MAX2(_hi,r->_hi), MAX2(_widen,r->_widen) ); |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: reverse hi & lo; flip widen |
| const Type *TypeInt::xdual() const { |
| int w = normalize_int_widen(_hi,_lo, WidenMax-_widen); |
| return new TypeInt(_hi,_lo,w); |
| } |
| |
| //------------------------------widen------------------------------------------ |
| // Only happens for optimistic top-down optimizations. |
| const Type *TypeInt::widen( const Type *old, const Type* limit ) const { |
| // Coming from TOP or such; no widening |
| if( old->base() != Int ) return this; |
| const TypeInt *ot = old->is_int(); |
| |
| // If new guy is equal to old guy, no widening |
| if( _lo == ot->_lo && _hi == ot->_hi ) |
| return old; |
| |
| // If new guy contains old, then we widened |
| if( _lo <= ot->_lo && _hi >= ot->_hi ) { |
| // New contains old |
| // If new guy is already wider than old, no widening |
| if( _widen > ot->_widen ) return this; |
| // If old guy was a constant, do not bother |
| if (ot->_lo == ot->_hi) return this; |
| // Now widen new guy. |
| // Check for widening too far |
| if (_widen == WidenMax) { |
| int max = max_jint; |
| int min = min_jint; |
| if (limit->isa_int()) { |
| max = limit->is_int()->_hi; |
| min = limit->is_int()->_lo; |
| } |
| if (min < _lo && _hi < max) { |
| // If neither endpoint is extremal yet, push out the endpoint |
| // which is closer to its respective limit. |
| if (_lo >= 0 || // easy common case |
| (juint)(_lo - min) >= (juint)(max - _hi)) { |
| // Try to widen to an unsigned range type of 31 bits: |
| return make(_lo, max, WidenMax); |
| } else { |
| return make(min, _hi, WidenMax); |
| } |
| } |
| return TypeInt::INT; |
| } |
| // Returned widened new guy |
| return make(_lo,_hi,_widen+1); |
| } |
| |
| // If old guy contains new, then we probably widened too far & dropped to |
| // bottom. Return the wider fellow. |
| if ( ot->_lo <= _lo && ot->_hi >= _hi ) |
| return old; |
| |
| //fatal("Integer value range is not subset"); |
| //return this; |
| return TypeInt::INT; |
| } |
| |
| //------------------------------narrow--------------------------------------- |
| // Only happens for pessimistic optimizations. |
| const Type *TypeInt::narrow( const Type *old ) const { |
| if (_lo >= _hi) return this; // already narrow enough |
| if (old == NULL) return this; |
| const TypeInt* ot = old->isa_int(); |
| if (ot == NULL) return this; |
| jint olo = ot->_lo; |
| jint ohi = ot->_hi; |
| |
| // If new guy is equal to old guy, no narrowing |
| if (_lo == olo && _hi == ohi) return old; |
| |
| // If old guy was maximum range, allow the narrowing |
| if (olo == min_jint && ohi == max_jint) return this; |
| |
| if (_lo < olo || _hi > ohi) |
| return this; // doesn't narrow; pretty wierd |
| |
| // The new type narrows the old type, so look for a "death march". |
| // See comments on PhaseTransform::saturate. |
| juint nrange = (juint)_hi - _lo; |
| juint orange = (juint)ohi - olo; |
| if (nrange < max_juint - 1 && nrange > (orange >> 1) + (SMALLINT*2)) { |
| // Use the new type only if the range shrinks a lot. |
| // We do not want the optimizer computing 2^31 point by point. |
| return old; |
| } |
| |
| return this; |
| } |
| |
| //-----------------------------filter------------------------------------------ |
| const Type *TypeInt::filter_helper(const Type *kills, bool include_speculative) const { |
| const TypeInt* ft = join_helper(kills, include_speculative)->isa_int(); |
| if (ft == NULL || ft->empty()) |
| return Type::TOP; // Canonical empty value |
| if (ft->_widen < this->_widen) { |
| // Do not allow the value of kill->_widen to affect the outcome. |
| // The widen bits must be allowed to run freely through the graph. |
| ft = TypeInt::make(ft->_lo, ft->_hi, this->_widen); |
| } |
| return ft; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeInt::eq( const Type *t ) const { |
| const TypeInt *r = t->is_int(); // Handy access |
| return r->_lo == _lo && r->_hi == _hi && r->_widen == _widen; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeInt::hash(void) const { |
| return java_add(java_add(_lo, _hi), java_add(_widen, (int)Type::Int)); |
| } |
| |
| //------------------------------is_finite-------------------------------------- |
| // Has a finite value |
| bool TypeInt::is_finite() const { |
| return true; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump TypeInt |
| #ifndef PRODUCT |
| static const char* intname(char* buf, jint n) { |
| if (n == min_jint) |
| return "min"; |
| else if (n < min_jint + 10000) |
| sprintf(buf, "min+" INT32_FORMAT, n - min_jint); |
| else if (n == max_jint) |
| return "max"; |
| else if (n > max_jint - 10000) |
| sprintf(buf, "max-" INT32_FORMAT, max_jint - n); |
| else |
| sprintf(buf, INT32_FORMAT, n); |
| return buf; |
| } |
| |
| void TypeInt::dump2( Dict &d, uint depth, outputStream *st ) const { |
| char buf[40], buf2[40]; |
| if (_lo == min_jint && _hi == max_jint) |
| st->print("int"); |
| else if (is_con()) |
| st->print("int:%s", intname(buf, get_con())); |
| else if (_lo == BOOL->_lo && _hi == BOOL->_hi) |
| st->print("bool"); |
| else if (_lo == BYTE->_lo && _hi == BYTE->_hi) |
| st->print("byte"); |
| else if (_lo == CHAR->_lo && _hi == CHAR->_hi) |
| st->print("char"); |
| else if (_lo == SHORT->_lo && _hi == SHORT->_hi) |
| st->print("short"); |
| else if (_hi == max_jint) |
| st->print("int:>=%s", intname(buf, _lo)); |
| else if (_lo == min_jint) |
| st->print("int:<=%s", intname(buf, _hi)); |
| else |
| st->print("int:%s..%s", intname(buf, _lo), intname(buf2, _hi)); |
| |
| if (_widen != 0 && this != TypeInt::INT) |
| st->print(":%.*s", _widen, "wwww"); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants. |
| bool TypeInt::singleton(void) const { |
| return _lo >= _hi; |
| } |
| |
| bool TypeInt::empty(void) const { |
| return _lo > _hi; |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeLong *TypeLong::MINUS_1;// -1 |
| const TypeLong *TypeLong::ZERO; // 0 |
| const TypeLong *TypeLong::ONE; // 1 |
| const TypeLong *TypeLong::POS; // >=0 |
| const TypeLong *TypeLong::LONG; // 64-bit integers |
| const TypeLong *TypeLong::INT; // 32-bit subrange |
| const TypeLong *TypeLong::UINT; // 32-bit unsigned subrange |
| const TypeLong *TypeLong::TYPE_DOMAIN; // alias for TypeLong::LONG |
| |
| //------------------------------TypeLong--------------------------------------- |
| TypeLong::TypeLong( jlong lo, jlong hi, int w ) : Type(Long), _lo(lo), _hi(hi), _widen(w) { |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeLong *TypeLong::make( jlong lo ) { |
| return (TypeLong*)(new TypeLong(lo,lo,WidenMin))->hashcons(); |
| } |
| |
| static int normalize_long_widen( jlong lo, jlong hi, int w ) { |
| // Certain normalizations keep us sane when comparing types. |
| // The 'SMALLINT' covers constants. |
| if (lo <= hi) { |
| if (((julong)hi - lo) <= SMALLINT) w = Type::WidenMin; |
| if (((julong)hi - lo) >= max_julong) w = Type::WidenMax; // TypeLong::LONG |
| } else { |
| if (((julong)lo - hi) <= SMALLINT) w = Type::WidenMin; |
| if (((julong)lo - hi) >= max_julong) w = Type::WidenMin; // dual TypeLong::LONG |
| } |
| return w; |
| } |
| |
| const TypeLong *TypeLong::make( jlong lo, jlong hi, int w ) { |
| w = normalize_long_widen(lo, hi, w); |
| return (TypeLong*)(new TypeLong(lo,hi,w))->hashcons(); |
| } |
| |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type representation object |
| // with reference count equal to the number of Types pointing at it. |
| // Caller should wrap a Types around it. |
| const Type *TypeLong::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type? |
| |
| // Currently "this->_base" is a TypeLong |
| switch (t->base()) { // Switch on original type |
| case AnyPtr: // Mixing with oops happens when javac |
| case RawPtr: // reuses local variables |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| case NarrowOop: |
| case NarrowKlass: |
| case Int: |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| default: // All else is a mistake |
| typerr(t); |
| case Top: // No change |
| return this; |
| case Long: // Long vs Long? |
| break; |
| } |
| |
| // Expand covered set |
| const TypeLong *r = t->is_long(); // Turn into a TypeLong |
| return make( MIN2(_lo,r->_lo), MAX2(_hi,r->_hi), MAX2(_widen,r->_widen) ); |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: reverse hi & lo; flip widen |
| const Type *TypeLong::xdual() const { |
| int w = normalize_long_widen(_hi,_lo, WidenMax-_widen); |
| return new TypeLong(_hi,_lo,w); |
| } |
| |
| //------------------------------widen------------------------------------------ |
| // Only happens for optimistic top-down optimizations. |
| const Type *TypeLong::widen( const Type *old, const Type* limit ) const { |
| // Coming from TOP or such; no widening |
| if( old->base() != Long ) return this; |
| const TypeLong *ot = old->is_long(); |
| |
| // If new guy is equal to old guy, no widening |
| if( _lo == ot->_lo && _hi == ot->_hi ) |
| return old; |
| |
| // If new guy contains old, then we widened |
| if( _lo <= ot->_lo && _hi >= ot->_hi ) { |
| // New contains old |
| // If new guy is already wider than old, no widening |
| if( _widen > ot->_widen ) return this; |
| // If old guy was a constant, do not bother |
| if (ot->_lo == ot->_hi) return this; |
| // Now widen new guy. |
| // Check for widening too far |
| if (_widen == WidenMax) { |
| jlong max = max_jlong; |
| jlong min = min_jlong; |
| if (limit->isa_long()) { |
| max = limit->is_long()->_hi; |
| min = limit->is_long()->_lo; |
| } |
| if (min < _lo && _hi < max) { |
| // If neither endpoint is extremal yet, push out the endpoint |
| // which is closer to its respective limit. |
| if (_lo >= 0 || // easy common case |
| ((julong)_lo - min) >= ((julong)max - _hi)) { |
| // Try to widen to an unsigned range type of 32/63 bits: |
| if (max >= max_juint && _hi < max_juint) |
| return make(_lo, max_juint, WidenMax); |
| else |
| return make(_lo, max, WidenMax); |
| } else { |
| return make(min, _hi, WidenMax); |
| } |
| } |
| return TypeLong::LONG; |
| } |
| // Returned widened new guy |
| return make(_lo,_hi,_widen+1); |
| } |
| |
| // If old guy contains new, then we probably widened too far & dropped to |
| // bottom. Return the wider fellow. |
| if ( ot->_lo <= _lo && ot->_hi >= _hi ) |
| return old; |
| |
| // fatal("Long value range is not subset"); |
| // return this; |
| return TypeLong::LONG; |
| } |
| |
| //------------------------------narrow---------------------------------------- |
| // Only happens for pessimistic optimizations. |
| const Type *TypeLong::narrow( const Type *old ) const { |
| if (_lo >= _hi) return this; // already narrow enough |
| if (old == NULL) return this; |
| const TypeLong* ot = old->isa_long(); |
| if (ot == NULL) return this; |
| jlong olo = ot->_lo; |
| jlong ohi = ot->_hi; |
| |
| // If new guy is equal to old guy, no narrowing |
| if (_lo == olo && _hi == ohi) return old; |
| |
| // If old guy was maximum range, allow the narrowing |
| if (olo == min_jlong && ohi == max_jlong) return this; |
| |
| if (_lo < olo || _hi > ohi) |
| return this; // doesn't narrow; pretty wierd |
| |
| // The new type narrows the old type, so look for a "death march". |
| // See comments on PhaseTransform::saturate. |
| julong nrange = _hi - _lo; |
| julong orange = ohi - olo; |
| if (nrange < max_julong - 1 && nrange > (orange >> 1) + (SMALLINT*2)) { |
| // Use the new type only if the range shrinks a lot. |
| // We do not want the optimizer computing 2^31 point by point. |
| return old; |
| } |
| |
| return this; |
| } |
| |
| //-----------------------------filter------------------------------------------ |
| const Type *TypeLong::filter_helper(const Type *kills, bool include_speculative) const { |
| const TypeLong* ft = join_helper(kills, include_speculative)->isa_long(); |
| if (ft == NULL || ft->empty()) |
| return Type::TOP; // Canonical empty value |
| if (ft->_widen < this->_widen) { |
| // Do not allow the value of kill->_widen to affect the outcome. |
| // The widen bits must be allowed to run freely through the graph. |
| ft = TypeLong::make(ft->_lo, ft->_hi, this->_widen); |
| } |
| return ft; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeLong::eq( const Type *t ) const { |
| const TypeLong *r = t->is_long(); // Handy access |
| return r->_lo == _lo && r->_hi == _hi && r->_widen == _widen; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeLong::hash(void) const { |
| return (int)(_lo+_hi+_widen+(int)Type::Long); |
| } |
| |
| //------------------------------is_finite-------------------------------------- |
| // Has a finite value |
| bool TypeLong::is_finite() const { |
| return true; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump TypeLong |
| #ifndef PRODUCT |
| static const char* longnamenear(jlong x, const char* xname, char* buf, jlong n) { |
| if (n > x) { |
| if (n >= x + 10000) return NULL; |
| sprintf(buf, "%s+" JLONG_FORMAT, xname, n - x); |
| } else if (n < x) { |
| if (n <= x - 10000) return NULL; |
| sprintf(buf, "%s-" JLONG_FORMAT, xname, x - n); |
| } else { |
| return xname; |
| } |
| return buf; |
| } |
| |
| static const char* longname(char* buf, jlong n) { |
| const char* str; |
| if (n == min_jlong) |
| return "min"; |
| else if (n < min_jlong + 10000) |
| sprintf(buf, "min+" JLONG_FORMAT, n - min_jlong); |
| else if (n == max_jlong) |
| return "max"; |
| else if (n > max_jlong - 10000) |
| sprintf(buf, "max-" JLONG_FORMAT, max_jlong - n); |
| else if ((str = longnamenear(max_juint, "maxuint", buf, n)) != NULL) |
| return str; |
| else if ((str = longnamenear(max_jint, "maxint", buf, n)) != NULL) |
| return str; |
| else if ((str = longnamenear(min_jint, "minint", buf, n)) != NULL) |
| return str; |
| else |
| sprintf(buf, JLONG_FORMAT, n); |
| return buf; |
| } |
| |
| void TypeLong::dump2( Dict &d, uint depth, outputStream *st ) const { |
| char buf[80], buf2[80]; |
| if (_lo == min_jlong && _hi == max_jlong) |
| st->print("long"); |
| else if (is_con()) |
| st->print("long:%s", longname(buf, get_con())); |
| else if (_hi == max_jlong) |
| st->print("long:>=%s", longname(buf, _lo)); |
| else if (_lo == min_jlong) |
| st->print("long:<=%s", longname(buf, _hi)); |
| else |
| st->print("long:%s..%s", longname(buf, _lo), longname(buf2, _hi)); |
| |
| if (_widen != 0 && this != TypeLong::LONG) |
| st->print(":%.*s", _widen, "wwww"); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants |
| bool TypeLong::singleton(void) const { |
| return _lo >= _hi; |
| } |
| |
| bool TypeLong::empty(void) const { |
| return _lo > _hi; |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeTuple *TypeTuple::IFBOTH; // Return both arms of IF as reachable |
| const TypeTuple *TypeTuple::IFFALSE; |
| const TypeTuple *TypeTuple::IFTRUE; |
| const TypeTuple *TypeTuple::IFNEITHER; |
| const TypeTuple *TypeTuple::LOOPBODY; |
| const TypeTuple *TypeTuple::MEMBAR; |
| const TypeTuple *TypeTuple::STORECONDITIONAL; |
| const TypeTuple *TypeTuple::START_I2C; |
| const TypeTuple *TypeTuple::INT_PAIR; |
| const TypeTuple *TypeTuple::LONG_PAIR; |
| const TypeTuple *TypeTuple::INT_CC_PAIR; |
| const TypeTuple *TypeTuple::LONG_CC_PAIR; |
| |
| |
| //------------------------------make------------------------------------------- |
| // Make a TypeTuple from the range of a method signature |
| const TypeTuple *TypeTuple::make_range(ciSignature* sig) { |
| ciType* return_type = sig->return_type(); |
| uint arg_cnt = return_type->size(); |
| const Type **field_array = fields(arg_cnt); |
| switch (return_type->basic_type()) { |
| case T_LONG: |
| field_array[TypeFunc::Parms] = TypeLong::LONG; |
| field_array[TypeFunc::Parms+1] = Type::HALF; |
| break; |
| case T_DOUBLE: |
| field_array[TypeFunc::Parms] = Type::DOUBLE; |
| field_array[TypeFunc::Parms+1] = Type::HALF; |
| break; |
| case T_OBJECT: |
| case T_ARRAY: |
| case T_BOOLEAN: |
| case T_CHAR: |
| case T_FLOAT: |
| case T_BYTE: |
| case T_SHORT: |
| case T_INT: |
| field_array[TypeFunc::Parms] = get_const_type(return_type); |
| break; |
| case T_VOID: |
| break; |
| default: |
| ShouldNotReachHere(); |
| } |
| return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons(); |
| } |
| |
| // Make a TypeTuple from the domain of a method signature |
| const TypeTuple *TypeTuple::make_domain(ciInstanceKlass* recv, ciSignature* sig) { |
| uint arg_cnt = sig->size(); |
| |
| uint pos = TypeFunc::Parms; |
| const Type **field_array; |
| if (recv != NULL) { |
| arg_cnt++; |
| field_array = fields(arg_cnt); |
| // Use get_const_type here because it respects UseUniqueSubclasses: |
| field_array[pos++] = get_const_type(recv)->join_speculative(TypePtr::NOTNULL); |
| } else { |
| field_array = fields(arg_cnt); |
| } |
| |
| int i = 0; |
| while (pos < TypeFunc::Parms + arg_cnt) { |
| ciType* type = sig->type_at(i); |
| |
| switch (type->basic_type()) { |
| case T_LONG: |
| field_array[pos++] = TypeLong::LONG; |
| field_array[pos++] = Type::HALF; |
| break; |
| case T_DOUBLE: |
| field_array[pos++] = Type::DOUBLE; |
| field_array[pos++] = Type::HALF; |
| break; |
| case T_OBJECT: |
| case T_ARRAY: |
| case T_BOOLEAN: |
| case T_CHAR: |
| case T_FLOAT: |
| case T_BYTE: |
| case T_SHORT: |
| case T_INT: |
| field_array[pos++] = get_const_type(type); |
| break; |
| default: |
| ShouldNotReachHere(); |
| } |
| i++; |
| } |
| |
| return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons(); |
| } |
| |
| const TypeTuple *TypeTuple::make( uint cnt, const Type **fields ) { |
| return (TypeTuple*)(new TypeTuple(cnt,fields))->hashcons(); |
| } |
| |
| //------------------------------fields----------------------------------------- |
| // Subroutine call type with space allocated for argument types |
| // Memory for Control, I_O, Memory, FramePtr, and ReturnAdr is allocated implicitly |
| const Type **TypeTuple::fields( uint arg_cnt ) { |
| const Type **flds = (const Type **)(Compile::current()->type_arena()->Amalloc_4((TypeFunc::Parms+arg_cnt)*sizeof(Type*) )); |
| flds[TypeFunc::Control ] = Type::CONTROL; |
| flds[TypeFunc::I_O ] = Type::ABIO; |
| flds[TypeFunc::Memory ] = Type::MEMORY; |
| flds[TypeFunc::FramePtr ] = TypeRawPtr::BOTTOM; |
| flds[TypeFunc::ReturnAdr] = Type::RETURN_ADDRESS; |
| |
| return flds; |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeTuple::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Tuple |
| switch (t->base()) { // switch on original type |
| |
| case Bottom: // Ye Olde Default |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case Tuple: { // Meeting 2 signatures? |
| const TypeTuple *x = t->is_tuple(); |
| assert( _cnt == x->_cnt, "" ); |
| const Type **fields = (const Type **)(Compile::current()->type_arena()->Amalloc_4( _cnt*sizeof(Type*) )); |
| for( uint i=0; i<_cnt; i++ ) |
| fields[i] = field_at(i)->xmeet( x->field_at(i) ); |
| return TypeTuple::make(_cnt,fields); |
| } |
| case Top: |
| break; |
| } |
| return this; // Return the double constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeTuple::xdual() const { |
| const Type **fields = (const Type **)(Compile::current()->type_arena()->Amalloc_4( _cnt*sizeof(Type*) )); |
| for( uint i=0; i<_cnt; i++ ) |
| fields[i] = _fields[i]->dual(); |
| return new TypeTuple(_cnt,fields); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeTuple::eq( const Type *t ) const { |
| const TypeTuple *s = (const TypeTuple *)t; |
| if (_cnt != s->_cnt) return false; // Unequal field counts |
| for (uint i = 0; i < _cnt; i++) |
| if (field_at(i) != s->field_at(i)) // POINTER COMPARE! NO RECURSION! |
| return false; // Missed |
| return true; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeTuple::hash(void) const { |
| intptr_t sum = _cnt; |
| for( uint i=0; i<_cnt; i++ ) |
| sum += (intptr_t)_fields[i]; // Hash on pointers directly |
| return sum; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump signature Type |
| #ifndef PRODUCT |
| void TypeTuple::dump2( Dict &d, uint depth, outputStream *st ) const { |
| st->print("{"); |
| if( !depth || d[this] ) { // Check for recursive print |
| st->print("...}"); |
| return; |
| } |
| d.Insert((void*)this, (void*)this); // Stop recursion |
| if( _cnt ) { |
| uint i; |
| for( i=0; i<_cnt-1; i++ ) { |
| st->print("%d:", i); |
| _fields[i]->dump2(d, depth-1, st); |
| st->print(", "); |
| } |
| st->print("%d:", i); |
| _fields[i]->dump2(d, depth-1, st); |
| } |
| st->print("}"); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants |
| // or a single symbol. |
| bool TypeTuple::singleton(void) const { |
| return false; // Never a singleton |
| } |
| |
| bool TypeTuple::empty(void) const { |
| for( uint i=0; i<_cnt; i++ ) { |
| if (_fields[i]->empty()) return true; |
| } |
| return false; |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| |
| inline const TypeInt* normalize_array_size(const TypeInt* size) { |
| // Certain normalizations keep us sane when comparing types. |
| // We do not want arrayOop variables to differ only by the wideness |
| // of their index types. Pick minimum wideness, since that is the |
| // forced wideness of small ranges anyway. |
| if (size->_widen != Type::WidenMin) |
| return TypeInt::make(size->_lo, size->_hi, Type::WidenMin); |
| else |
| return size; |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeAry* TypeAry::make(const Type* elem, const TypeInt* size, bool stable) { |
| if (UseCompressedOops && elem->isa_oopptr()) { |
| elem = elem->make_narrowoop(); |
| } |
| size = normalize_array_size(size); |
| return (TypeAry*)(new TypeAry(elem,size,stable))->hashcons(); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeAry::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Ary |
| switch (t->base()) { // switch on original type |
| |
| case Bottom: // Ye Olde Default |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case Array: { // Meeting 2 arrays? |
| const TypeAry *a = t->is_ary(); |
| return TypeAry::make(_elem->meet_speculative(a->_elem), |
| _size->xmeet(a->_size)->is_int(), |
| _stable & a->_stable); |
| } |
| case Top: |
| break; |
| } |
| return this; // Return the double constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeAry::xdual() const { |
| const TypeInt* size_dual = _size->dual()->is_int(); |
| size_dual = normalize_array_size(size_dual); |
| return new TypeAry(_elem->dual(), size_dual, !_stable); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeAry::eq( const Type *t ) const { |
| const TypeAry *a = (const TypeAry*)t; |
| return _elem == a->_elem && |
| _stable == a->_stable && |
| _size == a->_size; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeAry::hash(void) const { |
| return (intptr_t)_elem + (intptr_t)_size + (_stable ? 43 : 0); |
| } |
| |
| /** |
| * Return same type without a speculative part in the element |
| */ |
| const Type* TypeAry::remove_speculative() const { |
| return make(_elem->remove_speculative(), _size, _stable); |
| } |
| |
| /** |
| * Return same type with cleaned up speculative part of element |
| */ |
| const Type* TypeAry::cleanup_speculative() const { |
| return make(_elem->cleanup_speculative(), _size, _stable); |
| } |
| |
| /** |
| * Return same type but with a different inline depth (used for speculation) |
| * |
| * @param depth depth to meet with |
| */ |
| const TypePtr* TypePtr::with_inline_depth(int depth) const { |
| if (!UseInlineDepthForSpeculativeTypes) { |
| return this; |
| } |
| return make(AnyPtr, _ptr, _offset, _speculative, depth); |
| } |
| |
| //----------------------interface_vs_oop--------------------------------------- |
| #ifdef ASSERT |
| bool TypeAry::interface_vs_oop(const Type *t) const { |
| const TypeAry* t_ary = t->is_ary(); |
| if (t_ary) { |
| const TypePtr* this_ptr = _elem->make_ptr(); // In case we have narrow_oops |
| const TypePtr* t_ptr = t_ary->_elem->make_ptr(); |
| if(this_ptr != NULL && t_ptr != NULL) { |
| return this_ptr->interface_vs_oop(t_ptr); |
| } |
| } |
| return false; |
| } |
| #endif |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeAry::dump2( Dict &d, uint depth, outputStream *st ) const { |
| if (_stable) st->print("stable:"); |
| _elem->dump2(d, depth, st); |
| st->print("["); |
| _size->dump2(d, depth, st); |
| st->print("]"); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants |
| // or a single symbol. |
| bool TypeAry::singleton(void) const { |
| return false; // Never a singleton |
| } |
| |
| bool TypeAry::empty(void) const { |
| return _elem->empty() || _size->empty(); |
| } |
| |
| //--------------------------ary_must_be_exact---------------------------------- |
| bool TypeAry::ary_must_be_exact() const { |
| if (!UseExactTypes) return false; |
| // This logic looks at the element type of an array, and returns true |
| // if the element type is either a primitive or a final instance class. |
| // In such cases, an array built on this ary must have no subclasses. |
| if (_elem == BOTTOM) return false; // general array not exact |
| if (_elem == TOP ) return false; // inverted general array not exact |
| const TypeOopPtr* toop = NULL; |
| if (UseCompressedOops && _elem->isa_narrowoop()) { |
| toop = _elem->make_ptr()->isa_oopptr(); |
| } else { |
| toop = _elem->isa_oopptr(); |
| } |
| if (!toop) return true; // a primitive type, like int |
| ciKlass* tklass = toop->klass(); |
| if (tklass == NULL) return false; // unloaded class |
| if (!tklass->is_loaded()) return false; // unloaded class |
| const TypeInstPtr* tinst; |
| if (_elem->isa_narrowoop()) |
| tinst = _elem->make_ptr()->isa_instptr(); |
| else |
| tinst = _elem->isa_instptr(); |
| if (tinst) |
| return tklass->as_instance_klass()->is_final(); |
| const TypeAryPtr* tap; |
| if (_elem->isa_narrowoop()) |
| tap = _elem->make_ptr()->isa_aryptr(); |
| else |
| tap = _elem->isa_aryptr(); |
| if (tap) |
| return tap->ary()->ary_must_be_exact(); |
| return false; |
| } |
| |
| //==============================TypeVect======================================= |
| // Convenience common pre-built types. |
| const TypeVect *TypeVect::VECTS = NULL; // 32-bit vectors |
| const TypeVect *TypeVect::VECTD = NULL; // 64-bit vectors |
| const TypeVect *TypeVect::VECTX = NULL; // 128-bit vectors |
| const TypeVect *TypeVect::VECTY = NULL; // 256-bit vectors |
| const TypeVect *TypeVect::VECTZ = NULL; // 512-bit vectors |
| |
| //------------------------------make------------------------------------------- |
| const TypeVect* TypeVect::make(const Type *elem, uint length) { |
| BasicType elem_bt = elem->array_element_basic_type(); |
| assert(is_java_primitive(elem_bt), "only primitive types in vector"); |
| assert(length > 1 && is_power_of_2(length), "vector length is power of 2"); |
| assert(Matcher::vector_size_supported(elem_bt, length), "length in range"); |
| int size = length * type2aelembytes(elem_bt); |
| switch (Matcher::vector_ideal_reg(size)) { |
| case Op_VecS: |
| return (TypeVect*)(new TypeVectS(elem, length))->hashcons(); |
| case Op_RegL: |
| case Op_VecD: |
| case Op_RegD: |
| return (TypeVect*)(new TypeVectD(elem, length))->hashcons(); |
| case Op_VecX: |
| return (TypeVect*)(new TypeVectX(elem, length))->hashcons(); |
| case Op_VecY: |
| return (TypeVect*)(new TypeVectY(elem, length))->hashcons(); |
| case Op_VecZ: |
| return (TypeVect*)(new TypeVectZ(elem, length))->hashcons(); |
| } |
| ShouldNotReachHere(); |
| return NULL; |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeVect::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Vector |
| switch (t->base()) { // switch on original type |
| |
| case Bottom: // Ye Olde Default |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case VectorS: |
| case VectorD: |
| case VectorX: |
| case VectorY: |
| case VectorZ: { // Meeting 2 vectors? |
| const TypeVect* v = t->is_vect(); |
| assert( base() == v->base(), ""); |
| assert(length() == v->length(), ""); |
| assert(element_basic_type() == v->element_basic_type(), ""); |
| return TypeVect::make(_elem->xmeet(v->_elem), _length); |
| } |
| case Top: |
| break; |
| } |
| return this; |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeVect::xdual() const { |
| return new TypeVect(base(), _elem->dual(), _length); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeVect::eq(const Type *t) const { |
| const TypeVect *v = t->is_vect(); |
| return (_elem == v->_elem) && (_length == v->_length); |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeVect::hash(void) const { |
| return (intptr_t)_elem + (intptr_t)_length; |
| } |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Vector is singleton if all elements are the same |
| // constant value (when vector is created with Replicate code). |
| bool TypeVect::singleton(void) const { |
| // There is no Con node for vectors yet. |
| // return _elem->singleton(); |
| return false; |
| } |
| |
| bool TypeVect::empty(void) const { |
| return _elem->empty(); |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeVect::dump2(Dict &d, uint depth, outputStream *st) const { |
| switch (base()) { |
| case VectorS: |
| st->print("vectors["); break; |
| case VectorD: |
| st->print("vectord["); break; |
| case VectorX: |
| st->print("vectorx["); break; |
| case VectorY: |
| st->print("vectory["); break; |
| case VectorZ: |
| st->print("vectorz["); break; |
| default: |
| ShouldNotReachHere(); |
| } |
| st->print("%d]:{", _length); |
| _elem->dump2(d, depth, st); |
| st->print("}"); |
| } |
| #endif |
| |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypePtr *TypePtr::NULL_PTR; |
| const TypePtr *TypePtr::NOTNULL; |
| const TypePtr *TypePtr::BOTTOM; |
| |
| //------------------------------meet------------------------------------------- |
| // Meet over the PTR enum |
| const TypePtr::PTR TypePtr::ptr_meet[TypePtr::lastPTR][TypePtr::lastPTR] = { |
| // TopPTR, AnyNull, Constant, Null, NotNull, BotPTR, |
| { /* Top */ TopPTR, AnyNull, Constant, Null, NotNull, BotPTR,}, |
| { /* AnyNull */ AnyNull, AnyNull, Constant, BotPTR, NotNull, BotPTR,}, |
| { /* Constant*/ Constant, Constant, Constant, BotPTR, NotNull, BotPTR,}, |
| { /* Null */ Null, BotPTR, BotPTR, Null, BotPTR, BotPTR,}, |
| { /* NotNull */ NotNull, NotNull, NotNull, BotPTR, NotNull, BotPTR,}, |
| { /* BotPTR */ BotPTR, BotPTR, BotPTR, BotPTR, BotPTR, BotPTR,} |
| }; |
| |
| //------------------------------make------------------------------------------- |
| const TypePtr *TypePtr::make(TYPES t, enum PTR ptr, int offset, const TypePtr* speculative, int inline_depth) { |
| return (TypePtr*)(new TypePtr(t,ptr,offset, speculative, inline_depth))->hashcons(); |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypePtr::cast_to_ptr_type(PTR ptr) const { |
| assert(_base == AnyPtr, "subclass must override cast_to_ptr_type"); |
| if( ptr == _ptr ) return this; |
| return make(_base, ptr, _offset, _speculative, _inline_depth); |
| } |
| |
| //------------------------------get_con---------------------------------------- |
| intptr_t TypePtr::get_con() const { |
| assert( _ptr == Null, "" ); |
| return _offset; |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypePtr::xmeet(const Type *t) const { |
| const Type* res = xmeet_helper(t); |
| if (res->isa_ptr() == NULL) { |
| return res; |
| } |
| |
| const TypePtr* res_ptr = res->is_ptr(); |
| if (res_ptr->speculative() != NULL) { |
| // type->speculative() == NULL means that speculation is no better |
| // than type, i.e. type->speculative() == type. So there are 2 |
| // ways to represent the fact that we have no useful speculative |
| // data and we should use a single one to be able to test for |
| // equality between types. Check whether type->speculative() == |
| // type and set speculative to NULL if it is the case. |
| if (res_ptr->remove_speculative() == res_ptr->speculative()) { |
| return res_ptr->remove_speculative(); |
| } |
| } |
| |
| return res; |
| } |
| |
| const Type *TypePtr::xmeet_helper(const Type *t) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is AnyPtr |
| switch (t->base()) { // switch on original type |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| case AnyPtr: { // Meeting to AnyPtrs |
| const TypePtr *tp = t->is_ptr(); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| return make(AnyPtr, meet_ptr(tp->ptr()), meet_offset(tp->offset()), speculative, depth); |
| } |
| case RawPtr: // For these, flip the call around to cut down |
| case OopPtr: |
| case InstPtr: // on the cases I have to handle. |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| return t->xmeet(this); // Call in reverse direction |
| default: // All else is a mistake |
| typerr(t); |
| |
| } |
| return this; |
| } |
| |
| //------------------------------meet_offset------------------------------------ |
| int TypePtr::meet_offset( int offset ) const { |
| // Either is 'TOP' offset? Return the other offset! |
| if( _offset == OffsetTop ) return offset; |
| if( offset == OffsetTop ) return _offset; |
| // If either is different, return 'BOTTOM' offset |
| if( _offset != offset ) return OffsetBot; |
| return _offset; |
| } |
| |
| //------------------------------dual_offset------------------------------------ |
| int TypePtr::dual_offset( ) const { |
| if( _offset == OffsetTop ) return OffsetBot;// Map 'TOP' into 'BOTTOM' |
| if( _offset == OffsetBot ) return OffsetTop;// Map 'BOTTOM' into 'TOP' |
| return _offset; // Map everything else into self |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const TypePtr::PTR TypePtr::ptr_dual[TypePtr::lastPTR] = { |
| BotPTR, NotNull, Constant, Null, AnyNull, TopPTR |
| }; |
| const Type *TypePtr::xdual() const { |
| return new TypePtr(AnyPtr, dual_ptr(), dual_offset(), dual_speculative(), dual_inline_depth()); |
| } |
| |
| //------------------------------xadd_offset------------------------------------ |
| int TypePtr::xadd_offset( intptr_t offset ) const { |
| // Adding to 'TOP' offset? Return 'TOP'! |
| if( _offset == OffsetTop || offset == OffsetTop ) return OffsetTop; |
| // Adding to 'BOTTOM' offset? Return 'BOTTOM'! |
| if( _offset == OffsetBot || offset == OffsetBot ) return OffsetBot; |
| // Addition overflows or "accidentally" equals to OffsetTop? Return 'BOTTOM'! |
| offset += (intptr_t)_offset; |
| if (offset != (int)offset || offset == OffsetTop) return OffsetBot; |
| |
| // assert( _offset >= 0 && _offset+offset >= 0, "" ); |
| // It is possible to construct a negative offset during PhaseCCP |
| |
| return (int)offset; // Sum valid offsets |
| } |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypePtr::add_offset( intptr_t offset ) const { |
| return make(AnyPtr, _ptr, xadd_offset(offset), _speculative, _inline_depth); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypePtr::eq( const Type *t ) const { |
| const TypePtr *a = (const TypePtr*)t; |
| return _ptr == a->ptr() && _offset == a->offset() && eq_speculative(a) && _inline_depth == a->_inline_depth; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypePtr::hash(void) const { |
| return java_add(java_add(_ptr, _offset), java_add( hash_speculative(), _inline_depth)); |
| ; |
| } |
| |
| /** |
| * Return same type without a speculative part |
| */ |
| const Type* TypePtr::remove_speculative() const { |
| if (_speculative == NULL) { |
| return this; |
| } |
| assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); |
| return make(AnyPtr, _ptr, _offset, NULL, _inline_depth); |
| } |
| |
| /** |
| * Return same type but drop speculative part if we know we won't use |
| * it |
| */ |
| const Type* TypePtr::cleanup_speculative() const { |
| if (speculative() == NULL) { |
| return this; |
| } |
| const Type* no_spec = remove_speculative(); |
| // If this is NULL_PTR then we don't need the speculative type |
| // (with_inline_depth in case the current type inline depth is |
| // InlineDepthTop) |
| if (no_spec == NULL_PTR->with_inline_depth(inline_depth())) { |
| return no_spec; |
| } |
| if (above_centerline(speculative()->ptr())) { |
| return no_spec; |
| } |
| const TypeOopPtr* spec_oopptr = speculative()->isa_oopptr(); |
| // If the speculative may be null and is an inexact klass then it |
| // doesn't help |
| if (speculative()->maybe_null() && (spec_oopptr == NULL || !spec_oopptr->klass_is_exact())) { |
| return no_spec; |
| } |
| return this; |
| } |
| |
| /** |
| * dual of the speculative part of the type |
| */ |
| const TypePtr* TypePtr::dual_speculative() const { |
| if (_speculative == NULL) { |
| return NULL; |
| } |
| return _speculative->dual()->is_ptr(); |
| } |
| |
| /** |
| * meet of the speculative parts of 2 types |
| * |
| * @param other type to meet with |
| */ |
| const TypePtr* TypePtr::xmeet_speculative(const TypePtr* other) const { |
| bool this_has_spec = (_speculative != NULL); |
| bool other_has_spec = (other->speculative() != NULL); |
| |
| if (!this_has_spec && !other_has_spec) { |
| return NULL; |
| } |
| |
| // If we are at a point where control flow meets and one branch has |
| // a speculative type and the other has not, we meet the speculative |
| // type of one branch with the actual type of the other. If the |
| // actual type is exact and the speculative is as well, then the |
| // result is a speculative type which is exact and we can continue |
| // speculation further. |
| const TypePtr* this_spec = _speculative; |
| const TypePtr* other_spec = other->speculative(); |
| |
| if (!this_has_spec) { |
| this_spec = this; |
| } |
| |
| if (!other_has_spec) { |
| other_spec = other; |
| } |
| |
| return this_spec->meet(other_spec)->is_ptr(); |
| } |
| |
| /** |
| * dual of the inline depth for this type (used for speculation) |
| */ |
| int TypePtr::dual_inline_depth() const { |
| return -inline_depth(); |
| } |
| |
| /** |
| * meet of 2 inline depths (used for speculation) |
| * |
| * @param depth depth to meet with |
| */ |
| int TypePtr::meet_inline_depth(int depth) const { |
| return MAX2(inline_depth(), depth); |
| } |
| |
| /** |
| * Are the speculative parts of 2 types equal? |
| * |
| * @param other type to compare this one to |
| */ |
| bool TypePtr::eq_speculative(const TypePtr* other) const { |
| if (_speculative == NULL || other->speculative() == NULL) { |
| return _speculative == other->speculative(); |
| } |
| |
| if (_speculative->base() != other->speculative()->base()) { |
| return false; |
| } |
| |
| return _speculative->eq(other->speculative()); |
| } |
| |
| /** |
| * Hash of the speculative part of the type |
| */ |
| int TypePtr::hash_speculative() const { |
| if (_speculative == NULL) { |
| return 0; |
| } |
| |
| return _speculative->hash(); |
| } |
| |
| /** |
| * add offset to the speculative part of the type |
| * |
| * @param offset offset to add |
| */ |
| const TypePtr* TypePtr::add_offset_speculative(intptr_t offset) const { |
| if (_speculative == NULL) { |
| return NULL; |
| } |
| return _speculative->add_offset(offset)->is_ptr(); |
| } |
| |
| /** |
| * return exact klass from the speculative type if there's one |
| */ |
| ciKlass* TypePtr::speculative_type() const { |
| if (_speculative != NULL && _speculative->isa_oopptr()) { |
| const TypeOopPtr* speculative = _speculative->join(this)->is_oopptr(); |
| if (speculative->klass_is_exact()) { |
| return speculative->klass(); |
| } |
| } |
| return NULL; |
| } |
| |
| /** |
| * return true if speculative type may be null |
| */ |
| bool TypePtr::speculative_maybe_null() const { |
| if (_speculative != NULL) { |
| const TypePtr* speculative = _speculative->join(this)->is_ptr(); |
| return speculative->maybe_null(); |
| } |
| return true; |
| } |
| |
| /** |
| * Same as TypePtr::speculative_type() but return the klass only if |
| * the speculative tells us is not null |
| */ |
| ciKlass* TypePtr::speculative_type_not_null() const { |
| if (speculative_maybe_null()) { |
| return NULL; |
| } |
| return speculative_type(); |
| } |
| |
| /** |
| * Check whether new profiling would improve speculative type |
| * |
| * @param exact_kls class from profiling |
| * @param inline_depth inlining depth of profile point |
| * |
| * @return true if type profile is valuable |
| */ |
| bool TypePtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const { |
| // no profiling? |
| if (exact_kls == NULL) { |
| return false; |
| } |
| // no speculative type or non exact speculative type? |
| if (speculative_type() == NULL) { |
| return true; |
| } |
| // If the node already has an exact speculative type keep it, |
| // unless it was provided by profiling that is at a deeper |
| // inlining level. Profiling at a higher inlining depth is |
| // expected to be less accurate. |
| if (_speculative->inline_depth() == InlineDepthBottom) { |
| return false; |
| } |
| assert(_speculative->inline_depth() != InlineDepthTop, "can't do the comparison"); |
| return inline_depth < _speculative->inline_depth(); |
| } |
| |
| /** |
| * Check whether new profiling would improve ptr (= tells us it is non |
| * null) |
| * |
| * @param maybe_null true if profiling tells the ptr may be null |
| * |
| * @return true if ptr profile is valuable |
| */ |
| bool TypePtr::would_improve_ptr(bool maybe_null) const { |
| // profiling doesn't tell us anything useful |
| if (maybe_null) { |
| return false; |
| } |
| // We already know this is not be null |
| if (!this->maybe_null()) { |
| return false; |
| } |
| // We already know the speculative type cannot be null |
| if (!speculative_maybe_null()) { |
| return false; |
| } |
| return true; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| const char *const TypePtr::ptr_msg[TypePtr::lastPTR] = { |
| "TopPTR","AnyNull","Constant","NULL","NotNull","BotPTR" |
| }; |
| |
| #ifndef PRODUCT |
| void TypePtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| if( _ptr == Null ) st->print("NULL"); |
| else st->print("%s *", ptr_msg[_ptr]); |
| if( _offset == OffsetTop ) st->print("+top"); |
| else if( _offset == OffsetBot ) st->print("+bot"); |
| else if( _offset ) st->print("+%d", _offset); |
| dump_inline_depth(st); |
| dump_speculative(st); |
| } |
| |
| /** |
| *dump the speculative part of the type |
| */ |
| void TypePtr::dump_speculative(outputStream *st) const { |
| if (_speculative != NULL) { |
| st->print(" (speculative="); |
| _speculative->dump_on(st); |
| st->print(")"); |
| } |
| } |
| |
| /** |
| *dump the inline depth of the type |
| */ |
| void TypePtr::dump_inline_depth(outputStream *st) const { |
| if (_inline_depth != InlineDepthBottom) { |
| if (_inline_depth == InlineDepthTop) { |
| st->print(" (inline_depth=InlineDepthTop)"); |
| } else { |
| st->print(" (inline_depth=%d)", _inline_depth); |
| } |
| } |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants |
| bool TypePtr::singleton(void) const { |
| // TopPTR, Null, AnyNull, Constant are all singletons |
| return (_offset != OffsetBot) && !below_centerline(_ptr); |
| } |
| |
| bool TypePtr::empty(void) const { |
| return (_offset == OffsetTop) || above_centerline(_ptr); |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeRawPtr *TypeRawPtr::BOTTOM; |
| const TypeRawPtr *TypeRawPtr::NOTNULL; |
| |
| //------------------------------make------------------------------------------- |
| const TypeRawPtr *TypeRawPtr::make( enum PTR ptr ) { |
| assert( ptr != Constant, "what is the constant?" ); |
| assert( ptr != Null, "Use TypePtr for NULL" ); |
| return (TypeRawPtr*)(new TypeRawPtr(ptr,0))->hashcons(); |
| } |
| |
| const TypeRawPtr *TypeRawPtr::make( address bits ) { |
| assert( bits, "Use TypePtr for NULL" ); |
| return (TypeRawPtr*)(new TypeRawPtr(Constant,bits))->hashcons(); |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeRawPtr::cast_to_ptr_type(PTR ptr) const { |
| assert( ptr != Constant, "what is the constant?" ); |
| assert( ptr != Null, "Use TypePtr for NULL" ); |
| assert( _bits==0, "Why cast a constant address?"); |
| if( ptr == _ptr ) return this; |
| return make(ptr); |
| } |
| |
| //------------------------------get_con---------------------------------------- |
| intptr_t TypeRawPtr::get_con() const { |
| assert( _ptr == Null || _ptr == Constant, "" ); |
| return (intptr_t)_bits; |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeRawPtr::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is RawPtr |
| switch( t->base() ) { // switch on original type |
| case Bottom: // Ye Olde Default |
| return t; |
| case Top: |
| return this; |
| case AnyPtr: // Meeting to AnyPtrs |
| break; |
| case RawPtr: { // might be top, bot, any/not or constant |
| enum PTR tptr = t->is_ptr()->ptr(); |
| enum PTR ptr = meet_ptr( tptr ); |
| if( ptr == Constant ) { // Cannot be equal constants, so... |
| if( tptr == Constant && _ptr != Constant) return t; |
| if( _ptr == Constant && tptr != Constant) return this; |
| ptr = NotNull; // Fall down in lattice |
| } |
| return make( ptr ); |
| } |
| |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| return TypePtr::BOTTOM; // Oop meet raw is not well defined |
| default: // All else is a mistake |
| typerr(t); |
| } |
| |
| // Found an AnyPtr type vs self-RawPtr type |
| const TypePtr *tp = t->is_ptr(); |
| switch (tp->ptr()) { |
| case TypePtr::TopPTR: return this; |
| case TypePtr::BotPTR: return t; |
| case TypePtr::Null: |
| if( _ptr == TypePtr::TopPTR ) return t; |
| return TypeRawPtr::BOTTOM; |
| case TypePtr::NotNull: return TypePtr::make(AnyPtr, meet_ptr(TypePtr::NotNull), tp->meet_offset(0), tp->speculative(), tp->inline_depth()); |
| case TypePtr::AnyNull: |
| if( _ptr == TypePtr::Constant) return this; |
| return make( meet_ptr(TypePtr::AnyNull) ); |
| default: ShouldNotReachHere(); |
| } |
| return this; |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeRawPtr::xdual() const { |
| return new TypeRawPtr( dual_ptr(), _bits ); |
| } |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypeRawPtr::add_offset( intptr_t offset ) const { |
| if( offset == OffsetTop ) return BOTTOM; // Undefined offset-> undefined pointer |
| if( offset == OffsetBot ) return BOTTOM; // Unknown offset-> unknown pointer |
| if( offset == 0 ) return this; // No change |
| switch (_ptr) { |
| case TypePtr::TopPTR: |
| case TypePtr::BotPTR: |
| case TypePtr::NotNull: |
| return this; |
| case TypePtr::Null: |
| case TypePtr::Constant: { |
| address bits = _bits+offset; |
| if ( bits == 0 ) return TypePtr::NULL_PTR; |
| return make( bits ); |
| } |
| default: ShouldNotReachHere(); |
| } |
| return NULL; // Lint noise |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeRawPtr::eq( const Type *t ) const { |
| const TypeRawPtr *a = (const TypeRawPtr*)t; |
| return _bits == a->_bits && TypePtr::eq(t); |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeRawPtr::hash(void) const { |
| return (intptr_t)_bits + TypePtr::hash(); |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeRawPtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| if( _ptr == Constant ) |
| st->print(INTPTR_FORMAT, p2i(_bits)); |
| else |
| st->print("rawptr:%s", ptr_msg[_ptr]); |
| } |
| #endif |
| |
| //============================================================================= |
| // Convenience common pre-built type. |
| const TypeOopPtr *TypeOopPtr::BOTTOM; |
| |
| //------------------------------TypeOopPtr------------------------------------- |
| TypeOopPtr::TypeOopPtr(TYPES t, PTR ptr, ciKlass* k, bool xk, ciObject* o, int offset, |
| int instance_id, const TypePtr* speculative, int inline_depth) |
| : TypePtr(t, ptr, offset, speculative, inline_depth), |
| _const_oop(o), _klass(k), |
| _klass_is_exact(xk), |
| _is_ptr_to_narrowoop(false), |
| _is_ptr_to_narrowklass(false), |
| _is_ptr_to_boxed_value(false), |
| _instance_id(instance_id) { |
| if (Compile::current()->eliminate_boxing() && (t == InstPtr) && |
| (offset > 0) && xk && (k != 0) && k->is_instance_klass()) { |
| _is_ptr_to_boxed_value = k->as_instance_klass()->is_boxed_value_offset(offset); |
| } |
| #ifdef _LP64 |
| if (_offset != 0) { |
| if (_offset == oopDesc::klass_offset_in_bytes()) { |
| _is_ptr_to_narrowklass = UseCompressedClassPointers; |
| } else if (klass() == NULL) { |
| // Array with unknown body type |
| assert(this->isa_aryptr(), "only arrays without klass"); |
| _is_ptr_to_narrowoop = UseCompressedOops; |
| } else if (this->isa_aryptr()) { |
| _is_ptr_to_narrowoop = (UseCompressedOops && klass()->is_obj_array_klass() && |
| _offset != arrayOopDesc::length_offset_in_bytes()); |
| } else if (klass()->is_instance_klass()) { |
| ciInstanceKlass* ik = klass()->as_instance_klass(); |
| ciField* field = NULL; |
| if (this->isa_klassptr()) { |
| // Perm objects don't use compressed references |
| } else if (_offset == OffsetBot || _offset == OffsetTop) { |
| // unsafe access |
| _is_ptr_to_narrowoop = UseCompressedOops; |
| } else { // exclude unsafe ops |
| assert(this->isa_instptr(), "must be an instance ptr."); |
| |
| if (klass() == ciEnv::current()->Class_klass() && |
| (_offset == java_lang_Class::klass_offset_in_bytes() || |
| _offset == java_lang_Class::array_klass_offset_in_bytes())) { |
| // Special hidden fields from the Class. |
| assert(this->isa_instptr(), "must be an instance ptr."); |
| _is_ptr_to_narrowoop = false; |
| } else if (klass() == ciEnv::current()->Class_klass() && |
| _offset >= InstanceMirrorKlass::offset_of_static_fields()) { |
| // Static fields |
| assert(o != NULL, "must be constant"); |
| ciInstanceKlass* k = o->as_instance()->java_lang_Class_klass()->as_instance_klass(); |
| ciField* field = k->get_field_by_offset(_offset, true); |
| assert(field != NULL, "missing field"); |
| BasicType basic_elem_type = field->layout_type(); |
| _is_ptr_to_narrowoop = UseCompressedOops && (basic_elem_type == T_OBJECT || |
| basic_elem_type == T_ARRAY); |
| } else { |
| // Instance fields which contains a compressed oop references. |
| field = ik->get_field_by_offset(_offset, false); |
| if (field != NULL) { |
| BasicType basic_elem_type = field->layout_type(); |
| _is_ptr_to_narrowoop = UseCompressedOops && (basic_elem_type == T_OBJECT || |
| basic_elem_type == T_ARRAY); |
| } else if (klass()->equals(ciEnv::current()->Object_klass())) { |
| // Compile::find_alias_type() cast exactness on all types to verify |
| // that it does not affect alias type. |
| _is_ptr_to_narrowoop = UseCompressedOops; |
| } else { |
| // Type for the copy start in LibraryCallKit::inline_native_clone(). |
| _is_ptr_to_narrowoop = UseCompressedOops; |
| } |
| } |
| } |
| } |
| } |
| #endif |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeOopPtr *TypeOopPtr::make(PTR ptr, int offset, int instance_id, |
| const TypePtr* speculative, int inline_depth) { |
| assert(ptr != Constant, "no constant generic pointers"); |
| ciKlass* k = Compile::current()->env()->Object_klass(); |
| bool xk = false; |
| ciObject* o = NULL; |
| return (TypeOopPtr*)(new TypeOopPtr(OopPtr, ptr, k, xk, o, offset, instance_id, speculative, inline_depth))->hashcons(); |
| } |
| |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeOopPtr::cast_to_ptr_type(PTR ptr) const { |
| assert(_base == OopPtr, "subclass must override cast_to_ptr_type"); |
| if( ptr == _ptr ) return this; |
| return make(ptr, _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| //-----------------------------cast_to_instance_id---------------------------- |
| const TypeOopPtr *TypeOopPtr::cast_to_instance_id(int instance_id) const { |
| // There are no instances of a general oop. |
| // Return self unchanged. |
| return this; |
| } |
| |
| //-----------------------------cast_to_exactness------------------------------- |
| const Type *TypeOopPtr::cast_to_exactness(bool klass_is_exact) const { |
| // There is no such thing as an exact general oop. |
| // Return self unchanged. |
| return this; |
| } |
| |
| |
| //------------------------------as_klass_type---------------------------------- |
| // Return the klass type corresponding to this instance or array type. |
| // It is the type that is loaded from an object of this type. |
| const TypeKlassPtr* TypeOopPtr::as_klass_type() const { |
| ciKlass* k = klass(); |
| bool xk = klass_is_exact(); |
| if (k == NULL) |
| return TypeKlassPtr::OBJECT; |
| else |
| return TypeKlassPtr::make(xk? Constant: NotNull, k, 0); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeOopPtr::xmeet_helper(const Type *t) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is OopPtr |
| switch (t->base()) { // switch on original type |
| |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case RawPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| return TypePtr::BOTTOM; // Oop meet raw is not well defined |
| |
| case AnyPtr: { |
| // Found an AnyPtr type vs self-OopPtr type |
| const TypePtr *tp = t->is_ptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| switch (tp->ptr()) { |
| case Null: |
| if (ptr == Null) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); |
| // else fall through: |
| case TopPTR: |
| case AnyNull: { |
| int instance_id = meet_instance_id(InstanceTop); |
| return make(ptr, offset, instance_id, speculative, depth); |
| } |
| case BotPTR: |
| case NotNull: |
| return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); |
| default: typerr(t); |
| } |
| } |
| |
| case OopPtr: { // Meeting to other OopPtrs |
| const TypeOopPtr *tp = t->is_oopptr(); |
| int instance_id = meet_instance_id(tp->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| return make(meet_ptr(tp->ptr()), meet_offset(tp->offset()), instance_id, speculative, depth); |
| } |
| |
| case InstPtr: // For these, flip the call around to cut down |
| case AryPtr: |
| return t->xmeet(this); // Call in reverse direction |
| |
| } // End of switch |
| return this; // Return the double constant |
| } |
| |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual of a pure heap pointer. No relevant klass or oop information. |
| const Type *TypeOopPtr::xdual() const { |
| assert(klass() == Compile::current()->env()->Object_klass(), "no klasses here"); |
| assert(const_oop() == NULL, "no constants here"); |
| return new TypeOopPtr(_base, dual_ptr(), klass(), klass_is_exact(), const_oop(), dual_offset(), dual_instance_id(), dual_speculative(), dual_inline_depth()); |
| } |
| |
| //--------------------------make_from_klass_common----------------------------- |
| // Computes the element-type given a klass. |
| const TypeOopPtr* TypeOopPtr::make_from_klass_common(ciKlass *klass, bool klass_change, bool try_for_exact) { |
| if (klass->is_instance_klass()) { |
| Compile* C = Compile::current(); |
| Dependencies* deps = C->dependencies(); |
| assert((deps != NULL) == (C->method() != NULL && C->method()->code_size() > 0), "sanity"); |
| // Element is an instance |
| bool klass_is_exact = false; |
| if (klass->is_loaded()) { |
| // Try to set klass_is_exact. |
| ciInstanceKlass* ik = klass->as_instance_klass(); |
| klass_is_exact = ik->is_final(); |
| if (!klass_is_exact && klass_change |
| && deps != NULL && UseUniqueSubclasses) { |
| ciInstanceKlass* sub = ik->unique_concrete_subklass(); |
| if (sub != NULL) { |
| deps->assert_abstract_with_unique_concrete_subtype(ik, sub); |
| klass = ik = sub; |
| klass_is_exact = sub->is_final(); |
| } |
| } |
| if (!klass_is_exact && try_for_exact |
| && deps != NULL && UseExactTypes) { |
| if (!ik->is_interface() && !ik->has_subklass()) { |
| // Add a dependence; if concrete subclass added we need to recompile |
| deps->assert_leaf_type(ik); |
| klass_is_exact = true; |
| } |
| } |
| } |
| return TypeInstPtr::make(TypePtr::BotPTR, klass, klass_is_exact, NULL, 0); |
| } else if (klass->is_obj_array_klass()) { |
| // Element is an object array. Recursively call ourself. |
| const TypeOopPtr *etype = TypeOopPtr::make_from_klass_common(klass->as_obj_array_klass()->element_klass(), false, try_for_exact); |
| bool xk = etype->klass_is_exact(); |
| const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS); |
| // We used to pass NotNull in here, asserting that the sub-arrays |
| // are all not-null. This is not true in generally, as code can |
| // slam NULLs down in the subarrays. |
| const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, klass, xk, 0); |
| return arr; |
| } else if (klass->is_type_array_klass()) { |
| // Element is an typeArray |
| const Type* etype = get_const_basic_type(klass->as_type_array_klass()->element_type()); |
| const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS); |
| // We used to pass NotNull in here, asserting that the array pointer |
| // is not-null. That was not true in general. |
| const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, klass, true, 0); |
| return arr; |
| } else { |
| ShouldNotReachHere(); |
| return NULL; |
| } |
| } |
| |
| //------------------------------make_from_constant----------------------------- |
| // Make a java pointer from an oop constant |
| const TypeOopPtr* TypeOopPtr::make_from_constant(ciObject* o, bool require_constant) { |
| assert(!o->is_null_object(), "null object not yet handled here."); |
| ciKlass* klass = o->klass(); |
| if (klass->is_instance_klass()) { |
| // Element is an instance |
| if (require_constant) { |
| if (!o->can_be_constant()) return NULL; |
| } else if (!o->should_be_constant()) { |
| return TypeInstPtr::make(TypePtr::NotNull, klass, true, NULL, 0); |
| } |
| return TypeInstPtr::make(o); |
| } else if (klass->is_obj_array_klass()) { |
| // Element is an object array. Recursively call ourself. |
| const TypeOopPtr *etype = |
| TypeOopPtr::make_from_klass_raw(klass->as_obj_array_klass()->element_klass()); |
| const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length())); |
| // We used to pass NotNull in here, asserting that the sub-arrays |
| // are all not-null. This is not true in generally, as code can |
| // slam NULLs down in the subarrays. |
| if (require_constant) { |
| if (!o->can_be_constant()) return NULL; |
| } else if (!o->should_be_constant()) { |
| return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, 0); |
| } |
| const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, 0); |
| return arr; |
| } else if (klass->is_type_array_klass()) { |
| // Element is an typeArray |
| const Type* etype = |
| (Type*)get_const_basic_type(klass->as_type_array_klass()->element_type()); |
| const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length())); |
| // We used to pass NotNull in here, asserting that the array pointer |
| // is not-null. That was not true in general. |
| if (require_constant) { |
| if (!o->can_be_constant()) return NULL; |
| } else if (!o->should_be_constant()) { |
| return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, 0); |
| } |
| const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, 0); |
| return arr; |
| } |
| |
| fatal("unhandled object type"); |
| return NULL; |
| } |
| |
| //------------------------------get_con---------------------------------------- |
| intptr_t TypeOopPtr::get_con() const { |
| assert( _ptr == Null || _ptr == Constant, "" ); |
| assert( _offset >= 0, "" ); |
| |
| if (_offset != 0) { |
| // After being ported to the compiler interface, the compiler no longer |
| // directly manipulates the addresses of oops. Rather, it only has a pointer |
| // to a handle at compile time. This handle is embedded in the generated |
| // code and dereferenced at the time the nmethod is made. Until that time, |
| // it is not reasonable to do arithmetic with the addresses of oops (we don't |
| // have access to the addresses!). This does not seem to currently happen, |
| // but this assertion here is to help prevent its occurence. |
| tty->print_cr("Found oop constant with non-zero offset"); |
| ShouldNotReachHere(); |
| } |
| |
| return (intptr_t)const_oop()->constant_encoding(); |
| } |
| |
| |
| //-----------------------------filter------------------------------------------ |
| // Do not allow interface-vs.-noninterface joins to collapse to top. |
| const Type *TypeOopPtr::filter_helper(const Type *kills, bool include_speculative) const { |
| |
| const Type* ft = join_helper(kills, include_speculative); |
| const TypeInstPtr* ftip = ft->isa_instptr(); |
| const TypeInstPtr* ktip = kills->isa_instptr(); |
| |
| if (ft->empty()) { |
| // Check for evil case of 'this' being a class and 'kills' expecting an |
| // interface. This can happen because the bytecodes do not contain |
| // enough type info to distinguish a Java-level interface variable |
| // from a Java-level object variable. If we meet 2 classes which |
| // both implement interface I, but their meet is at 'j/l/O' which |
| // doesn't implement I, we have no way to tell if the result should |
| // be 'I' or 'j/l/O'. Thus we'll pick 'j/l/O'. If this then flows |
| // into a Phi which "knows" it's an Interface type we'll have to |
| // uplift the type. |
| if (!empty()) { |
| if (ktip != NULL && ktip->is_loaded() && ktip->klass()->is_interface()) { |
| return kills; // Uplift to interface |
| } |
| // Also check for evil cases of 'this' being a class array |
| // and 'kills' expecting an array of interfaces. |
| Type::get_arrays_base_elements(ft, kills, NULL, &ktip); |
| if (ktip != NULL && ktip->is_loaded() && ktip->klass()->is_interface()) { |
| return kills; // Uplift to array of interface |
| } |
| } |
| |
| return Type::TOP; // Canonical empty value |
| } |
| |
| // If we have an interface-typed Phi or cast and we narrow to a class type, |
| // the join should report back the class. However, if we have a J/L/Object |
| // class-typed Phi and an interface flows in, it's possible that the meet & |
| // join report an interface back out. This isn't possible but happens |
| // because the type system doesn't interact well with interfaces. |
| if (ftip != NULL && ktip != NULL && |
| ftip->is_loaded() && ftip->klass()->is_interface() && |
| ktip->is_loaded() && !ktip->klass()->is_interface()) { |
| assert(!ftip->klass_is_exact(), "interface could not be exact"); |
| return ktip->cast_to_ptr_type(ftip->ptr()); |
| } |
| |
| return ft; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeOopPtr::eq( const Type *t ) const { |
| const TypeOopPtr *a = (const TypeOopPtr*)t; |
| if (_klass_is_exact != a->_klass_is_exact || |
| _instance_id != a->_instance_id) return false; |
| ciObject* one = const_oop(); |
| ciObject* two = a->const_oop(); |
| if (one == NULL || two == NULL) { |
| return (one == two) && TypePtr::eq(t); |
| } else { |
| return one->equals(two) && TypePtr::eq(t); |
| } |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeOopPtr::hash(void) const { |
| return |
| java_add(java_add(const_oop() ? const_oop()->hash() : 0, _klass_is_exact), |
| java_add(_instance_id, TypePtr::hash())); |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeOopPtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| st->print("oopptr:%s", ptr_msg[_ptr]); |
| if( _klass_is_exact ) st->print(":exact"); |
| if( const_oop() ) st->print(INTPTR_FORMAT, p2i(const_oop())); |
| switch( _offset ) { |
| case OffsetTop: st->print("+top"); break; |
| case OffsetBot: st->print("+any"); break; |
| case 0: break; |
| default: st->print("+%d",_offset); break; |
| } |
| if (_instance_id == InstanceTop) |
| st->print(",iid=top"); |
| else if (_instance_id != InstanceBot) |
| st->print(",iid=%d",_instance_id); |
| |
| dump_inline_depth(st); |
| dump_speculative(st); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants |
| bool TypeOopPtr::singleton(void) const { |
| // detune optimizer to not generate constant oop + constant offset as a constant! |
| // TopPTR, Null, AnyNull, Constant are all singletons |
| return (_offset == 0) && !below_centerline(_ptr); |
| } |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypeOopPtr::add_offset(intptr_t offset) const { |
| return make(_ptr, xadd_offset(offset), _instance_id, add_offset_speculative(offset), _inline_depth); |
| } |
| |
| /** |
| * Return same type without a speculative part |
| */ |
| const Type* TypeOopPtr::remove_speculative() const { |
| if (_speculative == NULL) { |
| return this; |
| } |
| assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); |
| return make(_ptr, _offset, _instance_id, NULL, _inline_depth); |
| } |
| |
| /** |
| * Return same type but drop speculative part if we know we won't use |
| * it |
| */ |
| const Type* TypeOopPtr::cleanup_speculative() const { |
| // If the klass is exact and the ptr is not null then there's |
| // nothing that the speculative type can help us with |
| if (klass_is_exact() && !maybe_null()) { |
| return remove_speculative(); |
| } |
| return TypePtr::cleanup_speculative(); |
| } |
| |
| /** |
| * Return same type but with a different inline depth (used for speculation) |
| * |
| * @param depth depth to meet with |
| */ |
| const TypePtr* TypeOopPtr::with_inline_depth(int depth) const { |
| if (!UseInlineDepthForSpeculativeTypes) { |
| return this; |
| } |
| return make(_ptr, _offset, _instance_id, _speculative, depth); |
| } |
| |
| //------------------------------meet_instance_id-------------------------------- |
| int TypeOopPtr::meet_instance_id( int instance_id ) const { |
| // Either is 'TOP' instance? Return the other instance! |
| if( _instance_id == InstanceTop ) return instance_id; |
| if( instance_id == InstanceTop ) return _instance_id; |
| // If either is different, return 'BOTTOM' instance |
| if( _instance_id != instance_id ) return InstanceBot; |
| return _instance_id; |
| } |
| |
| //------------------------------dual_instance_id-------------------------------- |
| int TypeOopPtr::dual_instance_id( ) const { |
| if( _instance_id == InstanceTop ) return InstanceBot; // Map TOP into BOTTOM |
| if( _instance_id == InstanceBot ) return InstanceTop; // Map BOTTOM into TOP |
| return _instance_id; // Map everything else into self |
| } |
| |
| /** |
| * Check whether new profiling would improve speculative type |
| * |
| * @param exact_kls class from profiling |
| * @param inline_depth inlining depth of profile point |
| * |
| * @return true if type profile is valuable |
| */ |
| bool TypeOopPtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const { |
| // no way to improve an already exact type |
| if (klass_is_exact()) { |
| return false; |
| } |
| return TypePtr::would_improve_type(exact_kls, inline_depth); |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeInstPtr *TypeInstPtr::NOTNULL; |
| const TypeInstPtr *TypeInstPtr::BOTTOM; |
| const TypeInstPtr *TypeInstPtr::MIRROR; |
| const TypeInstPtr *TypeInstPtr::MARK; |
| const TypeInstPtr *TypeInstPtr::KLASS; |
| |
| //------------------------------TypeInstPtr------------------------------------- |
| TypeInstPtr::TypeInstPtr(PTR ptr, ciKlass* k, bool xk, ciObject* o, int off, |
| int instance_id, const TypePtr* speculative, int inline_depth) |
| : TypeOopPtr(InstPtr, ptr, k, xk, o, off, instance_id, speculative, inline_depth), |
| _name(k->name()) { |
| assert(k != NULL && |
| (k->is_loaded() || o == NULL), |
| "cannot have constants with non-loaded klass"); |
| }; |
| |
| //------------------------------make------------------------------------------- |
| const TypeInstPtr *TypeInstPtr::make(PTR ptr, |
| ciKlass* k, |
| bool xk, |
| ciObject* o, |
| int offset, |
| int instance_id, |
| const TypePtr* speculative, |
| int inline_depth) { |
| assert( !k->is_loaded() || k->is_instance_klass(), "Must be for instance"); |
| // Either const_oop() is NULL or else ptr is Constant |
| assert( (!o && ptr != Constant) || (o && ptr == Constant), |
| "constant pointers must have a value supplied" ); |
| // Ptr is never Null |
| assert( ptr != Null, "NULL pointers are not typed" ); |
| |
| assert(instance_id <= 0 || xk || !UseExactTypes, "instances are always exactly typed"); |
| if (!UseExactTypes) xk = false; |
| if (ptr == Constant) { |
| // Note: This case includes meta-object constants, such as methods. |
| xk = true; |
| } else if (k->is_loaded()) { |
| ciInstanceKlass* ik = k->as_instance_klass(); |
| if (!xk && ik->is_final()) xk = true; // no inexact final klass |
| if (xk && ik->is_interface()) xk = false; // no exact interface |
| } |
| |
| // Now hash this baby |
| TypeInstPtr *result = |
| (TypeInstPtr*)(new TypeInstPtr(ptr, k, xk, o ,offset, instance_id, speculative, inline_depth))->hashcons(); |
| |
| return result; |
| } |
| |
| /** |
| * Create constant type for a constant boxed value |
| */ |
| const Type* TypeInstPtr::get_const_boxed_value() const { |
| assert(is_ptr_to_boxed_value(), "should be called only for boxed value"); |
| assert((const_oop() != NULL), "should be called only for constant object"); |
| ciConstant constant = const_oop()->as_instance()->field_value_by_offset(offset()); |
| BasicType bt = constant.basic_type(); |
| switch (bt) { |
| case T_BOOLEAN: return TypeInt::make(constant.as_boolean()); |
| case T_INT: return TypeInt::make(constant.as_int()); |
| case T_CHAR: return TypeInt::make(constant.as_char()); |
| case T_BYTE: return TypeInt::make(constant.as_byte()); |
| case T_SHORT: return TypeInt::make(constant.as_short()); |
| case T_FLOAT: return TypeF::make(constant.as_float()); |
| case T_DOUBLE: return TypeD::make(constant.as_double()); |
| case T_LONG: return TypeLong::make(constant.as_long()); |
| default: break; |
| } |
| fatal("Invalid boxed value type '%s'", type2name(bt)); |
| return NULL; |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeInstPtr::cast_to_ptr_type(PTR ptr) const { |
| if( ptr == _ptr ) return this; |
| // Reconstruct _sig info here since not a problem with later lazy |
| // construction, _sig will show up on demand. |
| return make(ptr, klass(), klass_is_exact(), const_oop(), _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| |
| //-----------------------------cast_to_exactness------------------------------- |
| const Type *TypeInstPtr::cast_to_exactness(bool klass_is_exact) const { |
| if( klass_is_exact == _klass_is_exact ) return this; |
| if (!UseExactTypes) return this; |
| if (!_klass->is_loaded()) return this; |
| ciInstanceKlass* ik = _klass->as_instance_klass(); |
| if( (ik->is_final() || _const_oop) ) return this; // cannot clear xk |
| if( ik->is_interface() ) return this; // cannot set xk |
| return make(ptr(), klass(), klass_is_exact, const_oop(), _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| //-----------------------------cast_to_instance_id---------------------------- |
| const TypeOopPtr *TypeInstPtr::cast_to_instance_id(int instance_id) const { |
| if( instance_id == _instance_id ) return this; |
| return make(_ptr, klass(), _klass_is_exact, const_oop(), _offset, instance_id, _speculative, _inline_depth); |
| } |
| |
| //------------------------------xmeet_unloaded--------------------------------- |
| // Compute the MEET of two InstPtrs when at least one is unloaded. |
| // Assume classes are different since called after check for same name/class-loader |
| const TypeInstPtr *TypeInstPtr::xmeet_unloaded(const TypeInstPtr *tinst) const { |
| int off = meet_offset(tinst->offset()); |
| PTR ptr = meet_ptr(tinst->ptr()); |
| int instance_id = meet_instance_id(tinst->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tinst); |
| int depth = meet_inline_depth(tinst->inline_depth()); |
| |
| const TypeInstPtr *loaded = is_loaded() ? this : tinst; |
| const TypeInstPtr *unloaded = is_loaded() ? tinst : this; |
| if( loaded->klass()->equals(ciEnv::current()->Object_klass()) ) { |
| // |
| // Meet unloaded class with java/lang/Object |
| // |
| // Meet |
| // | Unloaded Class |
| // Object | TOP | AnyNull | Constant | NotNull | BOTTOM | |
| // =================================================================== |
| // TOP | ..........................Unloaded......................| |
| // AnyNull | U-AN |................Unloaded......................| |
| // Constant | ... O-NN .................................. | O-BOT | |
| // NotNull | ... O-NN .................................. | O-BOT | |
| // BOTTOM | ........................Object-BOTTOM ..................| |
| // |
| assert(loaded->ptr() != TypePtr::Null, "insanity check"); |
| // |
| if( loaded->ptr() == TypePtr::TopPTR ) { return unloaded; } |
| else if (loaded->ptr() == TypePtr::AnyNull) { return TypeInstPtr::make(ptr, unloaded->klass(), false, NULL, off, instance_id, speculative, depth); } |
| else if (loaded->ptr() == TypePtr::BotPTR ) { return TypeInstPtr::BOTTOM; } |
| else if (loaded->ptr() == TypePtr::Constant || loaded->ptr() == TypePtr::NotNull) { |
| if (unloaded->ptr() == TypePtr::BotPTR ) { return TypeInstPtr::BOTTOM; } |
| else { return TypeInstPtr::NOTNULL; } |
| } |
| else if( unloaded->ptr() == TypePtr::TopPTR ) { return unloaded; } |
| |
| return unloaded->cast_to_ptr_type(TypePtr::AnyNull)->is_instptr(); |
| } |
| |
| // Both are unloaded, not the same class, not Object |
| // Or meet unloaded with a different loaded class, not java/lang/Object |
| if( ptr != TypePtr::BotPTR ) { |
| return TypeInstPtr::NOTNULL; |
| } |
| return TypeInstPtr::BOTTOM; |
| } |
| |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeInstPtr::xmeet_helper(const Type *t) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Pointer |
| switch (t->base()) { // switch on original type |
| |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case MetadataPtr: |
| case KlassPtr: |
| case RawPtr: return TypePtr::BOTTOM; |
| |
| case AryPtr: { // All arrays inherit from Object class |
| const TypeAryPtr *tp = t->is_aryptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| int instance_id = meet_instance_id(tp->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| switch (ptr) { |
| case TopPTR: |
| case AnyNull: // Fall 'down' to dual of object klass |
| // For instances when a subclass meets a superclass we fall |
| // below the centerline when the superclass is exact. We need to |
| // do the same here. |
| if (klass()->equals(ciEnv::current()->Object_klass()) && !klass_is_exact()) { |
| return TypeAryPtr::make(ptr, tp->ary(), tp->klass(), tp->klass_is_exact(), offset, instance_id, speculative, depth); |
| } else { |
| // cannot subclass, so the meet has to fall badly below the centerline |
| ptr = NotNull; |
| instance_id = InstanceBot; |
| return TypeInstPtr::make( ptr, ciEnv::current()->Object_klass(), false, NULL, offset, instance_id, speculative, depth); |
| } |
| case Constant: |
| case NotNull: |
| case BotPTR: // Fall down to object klass |
| // LCA is object_klass, but if we subclass from the top we can do better |
| if( above_centerline(_ptr) ) { // if( _ptr == TopPTR || _ptr == AnyNull ) |
| // If 'this' (InstPtr) is above the centerline and it is Object class |
| // then we can subclass in the Java class hierarchy. |
| // For instances when a subclass meets a superclass we fall |
| // below the centerline when the superclass is exact. We need |
| // to do the same here. |
| if (klass()->equals(ciEnv::current()->Object_klass()) && !klass_is_exact()) { |
| // that is, tp's array type is a subtype of my klass |
| return TypeAryPtr::make(ptr, (ptr == Constant ? tp->const_oop() : NULL), |
| tp->ary(), tp->klass(), tp->klass_is_exact(), offset, instance_id, speculative, depth); |
| } |
| } |
| // The other case cannot happen, since I cannot be a subtype of an array. |
| // The meet falls down to Object class below centerline. |
| if( ptr == Constant ) |
| ptr = NotNull; |
| instance_id = InstanceBot; |
| return make(ptr, ciEnv::current()->Object_klass(), false, NULL, offset, instance_id, speculative, depth); |
| default: typerr(t); |
| } |
| } |
| |
| case OopPtr: { // Meeting to OopPtrs |
| // Found a OopPtr type vs self-InstPtr type |
| const TypeOopPtr *tp = t->is_oopptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| switch (tp->ptr()) { |
| case TopPTR: |
| case AnyNull: { |
| int instance_id = meet_instance_id(InstanceTop); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| return make(ptr, klass(), klass_is_exact(), |
| (ptr == Constant ? const_oop() : NULL), offset, instance_id, speculative, depth); |
| } |
| case NotNull: |
| case BotPTR: { |
| int instance_id = meet_instance_id(tp->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth); |
| } |
| default: typerr(t); |
| } |
| } |
| |
| case AnyPtr: { // Meeting to AnyPtrs |
| // Found an AnyPtr type vs self-InstPtr type |
| const TypePtr *tp = t->is_ptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| int instance_id = meet_instance_id(InstanceTop); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| switch (tp->ptr()) { |
| case Null: |
| if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); |
| // else fall through to AnyNull |
| case TopPTR: |
| case AnyNull: { |
| return make(ptr, klass(), klass_is_exact(), |
| (ptr == Constant ? const_oop() : NULL), offset, instance_id, speculative, depth); |
| } |
| case NotNull: |
| case BotPTR: |
| return TypePtr::make(AnyPtr, ptr, offset, speculative,depth); |
| default: typerr(t); |
| } |
| } |
| |
| /* |
| A-top } |
| / | \ } Tops |
| B-top A-any C-top } |
| | / | \ | } Any-nulls |
| B-any | C-any } |
| | | | |
| B-con A-con C-con } constants; not comparable across classes |
| | | | |
| B-not | C-not } |
| | \ | / | } not-nulls |
| B-bot A-not C-bot } |
| \ | / } Bottoms |
| A-bot } |
| */ |
| |
| case InstPtr: { // Meeting 2 Oops? |
| // Found an InstPtr sub-type vs self-InstPtr type |
| const TypeInstPtr *tinst = t->is_instptr(); |
| int off = meet_offset( tinst->offset() ); |
| PTR ptr = meet_ptr( tinst->ptr() ); |
| int instance_id = meet_instance_id(tinst->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tinst); |
| int depth = meet_inline_depth(tinst->inline_depth()); |
| |
| // Check for easy case; klasses are equal (and perhaps not loaded!) |
| // If we have constants, then we created oops so classes are loaded |
| // and we can handle the constants further down. This case handles |
| // both-not-loaded or both-loaded classes |
| if (ptr != Constant && klass()->equals(tinst->klass()) && klass_is_exact() == tinst->klass_is_exact()) { |
| return make(ptr, klass(), klass_is_exact(), NULL, off, instance_id, speculative, depth); |
| } |
| |
| // Classes require inspection in the Java klass hierarchy. Must be loaded. |
| ciKlass* tinst_klass = tinst->klass(); |
| ciKlass* this_klass = this->klass(); |
| bool tinst_xk = tinst->klass_is_exact(); |
| bool this_xk = this->klass_is_exact(); |
| if (!tinst_klass->is_loaded() || !this_klass->is_loaded() ) { |
| // One of these classes has not been loaded |
| const TypeInstPtr *unloaded_meet = xmeet_unloaded(tinst); |
| #ifndef PRODUCT |
| if( PrintOpto && Verbose ) { |
| tty->print("meet of unloaded classes resulted in: "); unloaded_meet->dump(); tty->cr(); |
| tty->print(" this == "); this->dump(); tty->cr(); |
| tty->print(" tinst == "); tinst->dump(); tty->cr(); |
| } |
| #endif |
| return unloaded_meet; |
| } |
| |
| // Handle mixing oops and interfaces first. |
| if( this_klass->is_interface() && !(tinst_klass->is_interface() || |
| tinst_klass == ciEnv::current()->Object_klass())) { |
| ciKlass *tmp = tinst_klass; // Swap interface around |
| tinst_klass = this_klass; |
| this_klass = tmp; |
| bool tmp2 = tinst_xk; |
| tinst_xk = this_xk; |
| this_xk = tmp2; |
| } |
| if (tinst_klass->is_interface() && |
| !(this_klass->is_interface() || |
| // Treat java/lang/Object as an honorary interface, |
| // because we need a bottom for the interface hierarchy. |
| this_klass == ciEnv::current()->Object_klass())) { |
| // Oop meets interface! |
| |
| // See if the oop subtypes (implements) interface. |
| ciKlass *k; |
| bool xk; |
| if( this_klass->is_subtype_of( tinst_klass ) ) { |
| // Oop indeed subtypes. Now keep oop or interface depending |
| // on whether we are both above the centerline or either is |
| // below the centerline. If we are on the centerline |
| // (e.g., Constant vs. AnyNull interface), use the constant. |
| k = below_centerline(ptr) ? tinst_klass : this_klass; |
| // If we are keeping this_klass, keep its exactness too. |
| xk = below_centerline(ptr) ? tinst_xk : this_xk; |
| } else { // Does not implement, fall to Object |
| // Oop does not implement interface, so mixing falls to Object |
| // just like the verifier does (if both are above the |
| // centerline fall to interface) |
| k = above_centerline(ptr) ? tinst_klass : ciEnv::current()->Object_klass(); |
| xk = above_centerline(ptr) ? tinst_xk : false; |
| // Watch out for Constant vs. AnyNull interface. |
| if (ptr == Constant) ptr = NotNull; // forget it was a constant |
| instance_id = InstanceBot; |
| } |
| ciObject* o = NULL; // the Constant value, if any |
| if (ptr == Constant) { |
| // Find out which constant. |
| o = (this_klass == klass()) ? const_oop() : tinst->const_oop(); |
| } |
| return make(ptr, k, xk, o, off, instance_id, speculative, depth); |
| } |
| |
| // Either oop vs oop or interface vs interface or interface vs Object |
| |
| // !!! Here's how the symmetry requirement breaks down into invariants: |
| // If we split one up & one down AND they subtype, take the down man. |
| // If we split one up & one down AND they do NOT subtype, "fall hard". |
| // If both are up and they subtype, take the subtype class. |
| // If both are up and they do NOT subtype, "fall hard". |
| // If both are down and they subtype, take the supertype class. |
| // If both are down and they do NOT subtype, "fall hard". |
| // Constants treated as down. |
| |
| // Now, reorder the above list; observe that both-down+subtype is also |
| // "fall hard"; "fall hard" becomes the default case: |
| // If we split one up & one down AND they subtype, take the down man. |
| // If both are up and they subtype, take the subtype class. |
| |
| // If both are down and they subtype, "fall hard". |
| // If both are down and they do NOT subtype, "fall hard". |
| // If both are up and they do NOT subtype, "fall hard". |
| // If we split one up & one down AND they do NOT subtype, "fall hard". |
| |
| // If a proper subtype is exact, and we return it, we return it exactly. |
| // If a proper supertype is exact, there can be no subtyping relationship! |
| // If both types are equal to the subtype, exactness is and-ed below the |
| // centerline and or-ed above it. (N.B. Constants are always exact.) |
| |
| // Check for subtyping: |
| ciKlass *subtype = NULL; |
| bool subtype_exact = false; |
| if( tinst_klass->equals(this_klass) ) { |
| subtype = this_klass; |
| subtype_exact = below_centerline(ptr) ? (this_xk & tinst_xk) : (this_xk | tinst_xk); |
| } else if( !tinst_xk && this_klass->is_subtype_of( tinst_klass ) ) { |
| subtype = this_klass; // Pick subtyping class |
| subtype_exact = this_xk; |
| } else if( !this_xk && tinst_klass->is_subtype_of( this_klass ) ) { |
| subtype = tinst_klass; // Pick subtyping class |
| subtype_exact = tinst_xk; |
| } |
| |
| if( subtype ) { |
| if( above_centerline(ptr) ) { // both are up? |
| this_klass = tinst_klass = subtype; |
| this_xk = tinst_xk = subtype_exact; |
| } else if( above_centerline(this ->_ptr) && !above_centerline(tinst->_ptr) ) { |
| this_klass = tinst_klass; // tinst is down; keep down man |
| this_xk = tinst_xk; |
| } else if( above_centerline(tinst->_ptr) && !above_centerline(this ->_ptr) ) { |
| tinst_klass = this_klass; // this is down; keep down man |
| tinst_xk = this_xk; |
| } else { |
| this_xk = subtype_exact; // either they are equal, or we'll do an LCA |
| } |
| } |
| |
| // Check for classes now being equal |
| if (tinst_klass->equals(this_klass)) { |
| // If the klasses are equal, the constants may still differ. Fall to |
| // NotNull if they do (neither constant is NULL; that is a special case |
| // handled elsewhere). |
| ciObject* o = NULL; // Assume not constant when done |
| ciObject* this_oop = const_oop(); |
| ciObject* tinst_oop = tinst->const_oop(); |
| if( ptr == Constant ) { |
| if (this_oop != NULL && tinst_oop != NULL && |
| this_oop->equals(tinst_oop) ) |
| o = this_oop; |
| else if (above_centerline(this ->_ptr)) |
| o = tinst_oop; |
| else if (above_centerline(tinst ->_ptr)) |
| o = this_oop; |
| else |
| ptr = NotNull; |
| } |
| return make(ptr, this_klass, this_xk, o, off, instance_id, speculative, depth); |
| } // Else classes are not equal |
| |
| // Since klasses are different, we require a LCA in the Java |
| // class hierarchy - which means we have to fall to at least NotNull. |
| if( ptr == TopPTR || ptr == AnyNull || ptr == Constant ) |
| ptr = NotNull; |
| |
| instance_id = InstanceBot; |
| |
| // Now we find the LCA of Java classes |
| ciKlass* k = this_klass->least_common_ancestor(tinst_klass); |
| return make(ptr, k, false, NULL, off, instance_id, speculative, depth); |
| } // End of case InstPtr |
| |
| } // End of switch |
| return this; // Return the double constant |
| } |
| |
| |
| //------------------------java_mirror_type-------------------------------------- |
| ciType* TypeInstPtr::java_mirror_type() const { |
| // must be a singleton type |
| if( const_oop() == NULL ) return NULL; |
| |
| // must be of type java.lang.Class |
| if( klass() != ciEnv::current()->Class_klass() ) return NULL; |
| |
| return const_oop()->as_instance()->java_mirror_type(); |
| } |
| |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: do NOT dual on klasses. This means I do NOT understand the Java |
| // inheritance mechanism. |
| const Type *TypeInstPtr::xdual() const { |
| return new TypeInstPtr(dual_ptr(), klass(), klass_is_exact(), const_oop(), dual_offset(), dual_instance_id(), dual_speculative(), dual_inline_depth()); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeInstPtr::eq( const Type *t ) const { |
| const TypeInstPtr *p = t->is_instptr(); |
| return |
| klass()->equals(p->klass()) && |
| TypeOopPtr::eq(p); // Check sub-type stuff |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeInstPtr::hash(void) const { |
| int hash = java_add(klass()->hash(), TypeOopPtr::hash()); |
| return hash; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump oop Type |
| #ifndef PRODUCT |
| void TypeInstPtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| // Print the name of the klass. |
| klass()->print_name_on(st); |
| |
| switch( _ptr ) { |
| case Constant: |
| // TO DO: Make CI print the hex address of the underlying oop. |
| if (WizardMode || Verbose) { |
| const_oop()->print_oop(st); |
| } |
| case BotPTR: |
| if (!WizardMode && !Verbose) { |
| if( _klass_is_exact ) st->print(":exact"); |
| break; |
| } |
| case TopPTR: |
| case AnyNull: |
| case NotNull: |
| st->print(":%s", ptr_msg[_ptr]); |
| if( _klass_is_exact ) st->print(":exact"); |
| break; |
| } |
| |
| if( _offset ) { // Dump offset, if any |
| if( _offset == OffsetBot ) st->print("+any"); |
| else if( _offset == OffsetTop ) st->print("+unknown"); |
| else st->print("+%d", _offset); |
| } |
| |
| st->print(" *"); |
| if (_instance_id == InstanceTop) |
| st->print(",iid=top"); |
| else if (_instance_id != InstanceBot) |
| st->print(",iid=%d",_instance_id); |
| |
| dump_inline_depth(st); |
| dump_speculative(st); |
| } |
| #endif |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypeInstPtr::add_offset(intptr_t offset) const { |
| return make(_ptr, klass(), klass_is_exact(), const_oop(), xadd_offset(offset), |
| _instance_id, add_offset_speculative(offset), _inline_depth); |
| } |
| |
| const Type *TypeInstPtr::remove_speculative() const { |
| if (_speculative == NULL) { |
| return this; |
| } |
| assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); |
| return make(_ptr, klass(), klass_is_exact(), const_oop(), _offset, |
| _instance_id, NULL, _inline_depth); |
| } |
| |
| const TypePtr *TypeInstPtr::with_inline_depth(int depth) const { |
| if (!UseInlineDepthForSpeculativeTypes) { |
| return this; |
| } |
| return make(_ptr, klass(), klass_is_exact(), const_oop(), _offset, _instance_id, _speculative, depth); |
| } |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| const TypeAryPtr *TypeAryPtr::RANGE; |
| const TypeAryPtr *TypeAryPtr::OOPS; |
| const TypeAryPtr *TypeAryPtr::NARROWOOPS; |
| const TypeAryPtr *TypeAryPtr::BYTES; |
| const TypeAryPtr *TypeAryPtr::SHORTS; |
| const TypeAryPtr *TypeAryPtr::CHARS; |
| const TypeAryPtr *TypeAryPtr::INTS; |
| const TypeAryPtr *TypeAryPtr::LONGS; |
| const TypeAryPtr *TypeAryPtr::FLOATS; |
| const TypeAryPtr *TypeAryPtr::DOUBLES; |
| |
| //------------------------------make------------------------------------------- |
| const TypeAryPtr *TypeAryPtr::make(PTR ptr, const TypeAry *ary, ciKlass* k, bool xk, int offset, |
| int instance_id, const TypePtr* speculative, int inline_depth) { |
| assert(!(k == NULL && ary->_elem->isa_int()), |
| "integral arrays must be pre-equipped with a class"); |
| if (!xk) xk = ary->ary_must_be_exact(); |
| assert(instance_id <= 0 || xk || !UseExactTypes, "instances are always exactly typed"); |
| if (!UseExactTypes) xk = (ptr == Constant); |
| return (TypeAryPtr*)(new TypeAryPtr(ptr, NULL, ary, k, xk, offset, instance_id, false, speculative, inline_depth))->hashcons(); |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeAryPtr *TypeAryPtr::make(PTR ptr, ciObject* o, const TypeAry *ary, ciKlass* k, bool xk, int offset, |
| int instance_id, const TypePtr* speculative, int inline_depth, |
| bool is_autobox_cache) { |
| assert(!(k == NULL && ary->_elem->isa_int()), |
| "integral arrays must be pre-equipped with a class"); |
| assert( (ptr==Constant && o) || (ptr!=Constant && !o), "" ); |
| if (!xk) xk = (o != NULL) || ary->ary_must_be_exact(); |
| assert(instance_id <= 0 || xk || !UseExactTypes, "instances are always exactly typed"); |
| if (!UseExactTypes) xk = (ptr == Constant); |
| return (TypeAryPtr*)(new TypeAryPtr(ptr, o, ary, k, xk, offset, instance_id, is_autobox_cache, speculative, inline_depth))->hashcons(); |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeAryPtr::cast_to_ptr_type(PTR ptr) const { |
| if( ptr == _ptr ) return this; |
| return make(ptr, const_oop(), _ary, klass(), klass_is_exact(), _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| |
| //-----------------------------cast_to_exactness------------------------------- |
| const Type *TypeAryPtr::cast_to_exactness(bool klass_is_exact) const { |
| if( klass_is_exact == _klass_is_exact ) return this; |
| if (!UseExactTypes) return this; |
| if (_ary->ary_must_be_exact()) return this; // cannot clear xk |
| return make(ptr(), const_oop(), _ary, klass(), klass_is_exact, _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| //-----------------------------cast_to_instance_id---------------------------- |
| const TypeOopPtr *TypeAryPtr::cast_to_instance_id(int instance_id) const { |
| if( instance_id == _instance_id ) return this; |
| return make(_ptr, const_oop(), _ary, klass(), _klass_is_exact, _offset, instance_id, _speculative, _inline_depth); |
| } |
| |
| //-----------------------------narrow_size_type------------------------------- |
| // Local cache for arrayOopDesc::max_array_length(etype), |
| // which is kind of slow (and cached elsewhere by other users). |
| static jint max_array_length_cache[T_CONFLICT+1]; |
| static jint max_array_length(BasicType etype) { |
| jint& cache = max_array_length_cache[etype]; |
| jint res = cache; |
| if (res == 0) { |
| switch (etype) { |
| case T_NARROWOOP: |
| etype = T_OBJECT; |
| break; |
| case T_NARROWKLASS: |
| case T_CONFLICT: |
| case T_ILLEGAL: |
| case T_VOID: |
| etype = T_BYTE; // will produce conservatively high value |
| } |
| cache = res = arrayOopDesc::max_array_length(etype); |
| } |
| return res; |
| } |
| |
| // Narrow the given size type to the index range for the given array base type. |
| // Return NULL if the resulting int type becomes empty. |
| const TypeInt* TypeAryPtr::narrow_size_type(const TypeInt* size) const { |
| jint hi = size->_hi; |
| jint lo = size->_lo; |
| jint min_lo = 0; |
| jint max_hi = max_array_length(elem()->basic_type()); |
| //if (index_not_size) --max_hi; // type of a valid array index, FTR |
| bool chg = false; |
| if (lo < min_lo) { |
| lo = min_lo; |
| if (size->is_con()) { |
| hi = lo; |
| } |
| chg = true; |
| } |
| if (hi > max_hi) { |
| hi = max_hi; |
| if (size->is_con()) { |
| lo = hi; |
| } |
| chg = true; |
| } |
| // Negative length arrays will produce weird intermediate dead fast-path code |
| if (lo > hi) |
| return TypeInt::ZERO; |
| if (!chg) |
| return size; |
| return TypeInt::make(lo, hi, Type::WidenMin); |
| } |
| |
| //-------------------------------cast_to_size---------------------------------- |
| const TypeAryPtr* TypeAryPtr::cast_to_size(const TypeInt* new_size) const { |
| assert(new_size != NULL, ""); |
| new_size = narrow_size_type(new_size); |
| if (new_size == size()) return this; |
| const TypeAry* new_ary = TypeAry::make(elem(), new_size, is_stable()); |
| return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| //------------------------------cast_to_stable--------------------------------- |
| const TypeAryPtr* TypeAryPtr::cast_to_stable(bool stable, int stable_dimension) const { |
| if (stable_dimension <= 0 || (stable_dimension == 1 && stable == this->is_stable())) |
| return this; |
| |
| const Type* elem = this->elem(); |
| const TypePtr* elem_ptr = elem->make_ptr(); |
| |
| if (stable_dimension > 1 && elem_ptr != NULL && elem_ptr->isa_aryptr()) { |
| // If this is widened from a narrow oop, TypeAry::make will re-narrow it. |
| elem = elem_ptr = elem_ptr->is_aryptr()->cast_to_stable(stable, stable_dimension - 1); |
| } |
| |
| const TypeAry* new_ary = TypeAry::make(elem, size(), stable); |
| |
| return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _instance_id, _speculative, _inline_depth); |
| } |
| |
| //-----------------------------stable_dimension-------------------------------- |
| int TypeAryPtr::stable_dimension() const { |
| if (!is_stable()) return 0; |
| int dim = 1; |
| const TypePtr* elem_ptr = elem()->make_ptr(); |
| if (elem_ptr != NULL && elem_ptr->isa_aryptr()) |
| dim += elem_ptr->is_aryptr()->stable_dimension(); |
| return dim; |
| } |
| |
| //----------------------cast_to_autobox_cache----------------------------------- |
| const TypeAryPtr* TypeAryPtr::cast_to_autobox_cache(bool cache) const { |
| if (is_autobox_cache() == cache) return this; |
| const TypeOopPtr* etype = elem()->make_oopptr(); |
| if (etype == NULL) return this; |
| // The pointers in the autobox arrays are always non-null. |
| TypePtr::PTR ptr_type = cache ? TypePtr::NotNull : TypePtr::AnyNull; |
| etype = etype->cast_to_ptr_type(TypePtr::NotNull)->is_oopptr(); |
| const TypeAry* new_ary = TypeAry::make(etype, size(), is_stable()); |
| return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _instance_id, _speculative, _inline_depth, cache); |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeAryPtr::eq( const Type *t ) const { |
| const TypeAryPtr *p = t->is_aryptr(); |
| return |
| _ary == p->_ary && // Check array |
| TypeOopPtr::eq(p); // Check sub-parts |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeAryPtr::hash(void) const { |
| return (intptr_t)_ary + TypeOopPtr::hash(); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeAryPtr::xmeet_helper(const Type *t) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| // Current "this->_base" is Pointer |
| switch (t->base()) { // switch on original type |
| |
| // Mixing ints & oops happens when javac reuses local variables |
| case Int: |
| case Long: |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case OopPtr: { // Meeting to OopPtrs |
| // Found a OopPtr type vs self-AryPtr type |
| const TypeOopPtr *tp = t->is_oopptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| switch (tp->ptr()) { |
| case TopPTR: |
| case AnyNull: { |
| int instance_id = meet_instance_id(InstanceTop); |
| return make(ptr, (ptr == Constant ? const_oop() : NULL), |
| _ary, _klass, _klass_is_exact, offset, instance_id, speculative, depth); |
| } |
| case BotPTR: |
| case NotNull: { |
| int instance_id = meet_instance_id(tp->instance_id()); |
| return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth); |
| } |
| default: ShouldNotReachHere(); |
| } |
| } |
| |
| case AnyPtr: { // Meeting two AnyPtrs |
| // Found an AnyPtr type vs self-AryPtr type |
| const TypePtr *tp = t->is_ptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| switch (tp->ptr()) { |
| case TopPTR: |
| return this; |
| case BotPTR: |
| case NotNull: |
| return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); |
| case Null: |
| if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); |
| // else fall through to AnyNull |
| case AnyNull: { |
| int instance_id = meet_instance_id(InstanceTop); |
| return make(ptr, (ptr == Constant ? const_oop() : NULL), |
| _ary, _klass, _klass_is_exact, offset, instance_id, speculative, depth); |
| } |
| default: ShouldNotReachHere(); |
| } |
| } |
| |
| case MetadataPtr: |
| case KlassPtr: |
| case RawPtr: return TypePtr::BOTTOM; |
| |
| case AryPtr: { // Meeting 2 references? |
| const TypeAryPtr *tap = t->is_aryptr(); |
| int off = meet_offset(tap->offset()); |
| const TypeAry *tary = _ary->meet_speculative(tap->_ary)->is_ary(); |
| PTR ptr = meet_ptr(tap->ptr()); |
| int instance_id = meet_instance_id(tap->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tap); |
| int depth = meet_inline_depth(tap->inline_depth()); |
| ciKlass* lazy_klass = NULL; |
| if (tary->_elem->isa_int()) { |
| // Integral array element types have irrelevant lattice relations. |
| // It is the klass that determines array layout, not the element type. |
| if (_klass == NULL) |
| lazy_klass = tap->_klass; |
| else if (tap->_klass == NULL || tap->_klass == _klass) { |
| lazy_klass = _klass; |
| } else { |
| // Something like byte[int+] meets char[int+]. |
| // This must fall to bottom, not (int[-128..65535])[int+]. |
| instance_id = InstanceBot; |
| tary = TypeAry::make(Type::BOTTOM, tary->_size, tary->_stable); |
| } |
| } else // Non integral arrays. |
| // Must fall to bottom if exact klasses in upper lattice |
| // are not equal or super klass is exact. |
| if ((above_centerline(ptr) || ptr == Constant) && klass() != tap->klass() && |
| // meet with top[] and bottom[] are processed further down: |
| tap->_klass != NULL && this->_klass != NULL && |
| // both are exact and not equal: |
| ((tap->_klass_is_exact && this->_klass_is_exact) || |
| // 'tap' is exact and super or unrelated: |
| (tap->_klass_is_exact && !tap->klass()->is_subtype_of(klass())) || |
| // 'this' is exact and super or unrelated: |
| (this->_klass_is_exact && !klass()->is_subtype_of(tap->klass())))) { |
| if (above_centerline(ptr)) { |
| tary = TypeAry::make(Type::BOTTOM, tary->_size, tary->_stable); |
| } |
| return make(NotNull, NULL, tary, lazy_klass, false, off, InstanceBot, speculative, depth); |
| } |
| |
| bool xk = false; |
| switch (tap->ptr()) { |
| case AnyNull: |
| case TopPTR: |
| // Compute new klass on demand, do not use tap->_klass |
| if (below_centerline(this->_ptr)) { |
| xk = this->_klass_is_exact; |
| } else { |
| xk = (tap->_klass_is_exact | this->_klass_is_exact); |
| } |
| return make(ptr, const_oop(), tary, lazy_klass, xk, off, instance_id, speculative, depth); |
| case Constant: { |
| ciObject* o = const_oop(); |
| if( _ptr == Constant ) { |
| if( tap->const_oop() != NULL && !o->equals(tap->const_oop()) ) { |
| xk = (klass() == tap->klass()); |
| ptr = NotNull; |
| o = NULL; |
| instance_id = InstanceBot; |
| } else { |
| xk = true; |
| } |
| } else if(above_centerline(_ptr)) { |
| o = tap->const_oop(); |
| xk = true; |
| } else { |
| // Only precise for identical arrays |
| xk = this->_klass_is_exact && (klass() == tap->klass()); |
| } |
| return TypeAryPtr::make(ptr, o, tary, lazy_klass, xk, off, instance_id, speculative, depth); |
| } |
| case NotNull: |
| case BotPTR: |
| // Compute new klass on demand, do not use tap->_klass |
| if (above_centerline(this->_ptr)) |
| xk = tap->_klass_is_exact; |
| else xk = (tap->_klass_is_exact & this->_klass_is_exact) && |
| (klass() == tap->klass()); // Only precise for identical arrays |
| return TypeAryPtr::make(ptr, NULL, tary, lazy_klass, xk, off, instance_id, speculative, depth); |
| default: ShouldNotReachHere(); |
| } |
| } |
| |
| // All arrays inherit from Object class |
| case InstPtr: { |
| const TypeInstPtr *tp = t->is_instptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| int instance_id = meet_instance_id(tp->instance_id()); |
| const TypePtr* speculative = xmeet_speculative(tp); |
| int depth = meet_inline_depth(tp->inline_depth()); |
| switch (ptr) { |
| case TopPTR: |
| case AnyNull: // Fall 'down' to dual of object klass |
| // For instances when a subclass meets a superclass we fall |
| // below the centerline when the superclass is exact. We need to |
| // do the same here. |
| if (tp->klass()->equals(ciEnv::current()->Object_klass()) && !tp->klass_is_exact()) { |
| return TypeAryPtr::make(ptr, _ary, _klass, _klass_is_exact, offset, instance_id, speculative, depth); |
| } else { |
| // cannot subclass, so the meet has to fall badly below the centerline |
| ptr = NotNull; |
| instance_id = InstanceBot; |
| return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), false, NULL,offset, instance_id, speculative, depth); |
| } |
| case Constant: |
| case NotNull: |
| case BotPTR: // Fall down to object klass |
| // LCA is object_klass, but if we subclass from the top we can do better |
| if (above_centerline(tp->ptr())) { |
| // If 'tp' is above the centerline and it is Object class |
| // then we can subclass in the Java class hierarchy. |
| // For instances when a subclass meets a superclass we fall |
| // below the centerline when the superclass is exact. We need |
| // to do the same here. |
| if (tp->klass()->equals(ciEnv::current()->Object_klass()) && !tp->klass_is_exact()) { |
| // that is, my array type is a subtype of 'tp' klass |
| return make(ptr, (ptr == Constant ? const_oop() : NULL), |
| _ary, _klass, _klass_is_exact, offset, instance_id, speculative, depth); |
| } |
| } |
| // The other case cannot happen, since t cannot be a subtype of an array. |
| // The meet falls down to Object class below centerline. |
| if( ptr == Constant ) |
| ptr = NotNull; |
| instance_id = InstanceBot; |
| return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), false, NULL,offset, instance_id, speculative, depth); |
| default: typerr(t); |
| } |
| } |
| } |
| return this; // Lint noise |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeAryPtr::xdual() const { |
| return new TypeAryPtr(dual_ptr(), _const_oop, _ary->dual()->is_ary(),_klass, _klass_is_exact, dual_offset(), dual_instance_id(), is_autobox_cache(), dual_speculative(), dual_inline_depth()); |
| } |
| |
| //----------------------interface_vs_oop--------------------------------------- |
| #ifdef ASSERT |
| bool TypeAryPtr::interface_vs_oop(const Type *t) const { |
| const TypeAryPtr* t_aryptr = t->isa_aryptr(); |
| if (t_aryptr) { |
| return _ary->interface_vs_oop(t_aryptr->_ary); |
| } |
| return false; |
| } |
| #endif |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeAryPtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| _ary->dump2(d,depth,st); |
| switch( _ptr ) { |
| case Constant: |
| const_oop()->print(st); |
| break; |
| case BotPTR: |
| if (!WizardMode && !Verbose) { |
| if( _klass_is_exact ) st->print(":exact"); |
| break; |
| } |
| case TopPTR: |
| case AnyNull: |
| case NotNull: |
| st->print(":%s", ptr_msg[_ptr]); |
| if( _klass_is_exact ) st->print(":exact"); |
| break; |
| } |
| |
| if( _offset != 0 ) { |
| int header_size = objArrayOopDesc::header_size() * wordSize; |
| if( _offset == OffsetTop ) st->print("+undefined"); |
| else if( _offset == OffsetBot ) st->print("+any"); |
| else if( _offset < header_size ) st->print("+%d", _offset); |
| else { |
| BasicType basic_elem_type = elem()->basic_type(); |
| int array_base = arrayOopDesc::base_offset_in_bytes(basic_elem_type); |
| int elem_size = type2aelembytes(basic_elem_type); |
| st->print("[%d]", (_offset - array_base)/elem_size); |
| } |
| } |
| st->print(" *"); |
| if (_instance_id == InstanceTop) |
| st->print(",iid=top"); |
| else if (_instance_id != InstanceBot) |
| st->print(",iid=%d",_instance_id); |
| |
| dump_inline_depth(st); |
| dump_speculative(st); |
| } |
| #endif |
| |
| bool TypeAryPtr::empty(void) const { |
| if (_ary->empty()) return true; |
| return TypeOopPtr::empty(); |
| } |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypeAryPtr::add_offset(intptr_t offset) const { |
| return make(_ptr, _const_oop, _ary, _klass, _klass_is_exact, xadd_offset(offset), _instance_id, add_offset_speculative(offset), _inline_depth); |
| } |
| |
| const Type *TypeAryPtr::remove_speculative() const { |
| if (_speculative == NULL) { |
| return this; |
| } |
| assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); |
| return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _instance_id, NULL, _inline_depth); |
| } |
| |
| const TypePtr *TypeAryPtr::with_inline_depth(int depth) const { |
| if (!UseInlineDepthForSpeculativeTypes) { |
| return this; |
| } |
| return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _instance_id, _speculative, depth); |
| } |
| |
| //============================================================================= |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeNarrowPtr::hash(void) const { |
| return _ptrtype->hash() + 7; |
| } |
| |
| bool TypeNarrowPtr::singleton(void) const { // TRUE if type is a singleton |
| return _ptrtype->singleton(); |
| } |
| |
| bool TypeNarrowPtr::empty(void) const { |
| return _ptrtype->empty(); |
| } |
| |
| intptr_t TypeNarrowPtr::get_con() const { |
| return _ptrtype->get_con(); |
| } |
| |
| bool TypeNarrowPtr::eq( const Type *t ) const { |
| const TypeNarrowPtr* tc = isa_same_narrowptr(t); |
| if (tc != NULL) { |
| if (_ptrtype->base() != tc->_ptrtype->base()) { |
| return false; |
| } |
| return tc->_ptrtype->eq(_ptrtype); |
| } |
| return false; |
| } |
| |
| const Type *TypeNarrowPtr::xdual() const { // Compute dual right now. |
| const TypePtr* odual = _ptrtype->dual()->is_ptr(); |
| return make_same_narrowptr(odual); |
| } |
| |
| |
| const Type *TypeNarrowPtr::filter_helper(const Type *kills, bool include_speculative) const { |
| if (isa_same_narrowptr(kills)) { |
| const Type* ft =_ptrtype->filter_helper(is_same_narrowptr(kills)->_ptrtype, include_speculative); |
| if (ft->empty()) |
| return Type::TOP; // Canonical empty value |
| if (ft->isa_ptr()) { |
| return make_hash_same_narrowptr(ft->isa_ptr()); |
| } |
| return ft; |
| } else if (kills->isa_ptr()) { |
| const Type* ft = _ptrtype->join_helper(kills, include_speculative); |
| if (ft->empty()) |
| return Type::TOP; // Canonical empty value |
| return ft; |
| } else { |
| return Type::TOP; |
| } |
| } |
| |
| //------------------------------xmeet------------------------------------------ |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeNarrowPtr::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| if (t->base() == base()) { |
| const Type* result = _ptrtype->xmeet(t->make_ptr()); |
| if (result->isa_ptr()) { |
| return make_hash_same_narrowptr(result->is_ptr()); |
| } |
| return result; |
| } |
| |
| // Current "this->_base" is NarrowKlass or NarrowOop |
| switch (t->base()) { // switch on original type |
| |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case AnyPtr: |
| case RawPtr: |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| case MetadataPtr: |
| case KlassPtr: |
| case NarrowOop: |
| case NarrowKlass: |
| |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| } // End of switch |
| |
| return this; |
| } |
| |
| #ifndef PRODUCT |
| void TypeNarrowPtr::dump2( Dict & d, uint depth, outputStream *st ) const { |
| _ptrtype->dump2(d, depth, st); |
| } |
| #endif |
| |
| const TypeNarrowOop *TypeNarrowOop::BOTTOM; |
| const TypeNarrowOop *TypeNarrowOop::NULL_PTR; |
| |
| |
| const TypeNarrowOop* TypeNarrowOop::make(const TypePtr* type) { |
| return (const TypeNarrowOop*)(new TypeNarrowOop(type))->hashcons(); |
| } |
| |
| const Type* TypeNarrowOop::remove_speculative() const { |
| return make(_ptrtype->remove_speculative()->is_ptr()); |
| } |
| |
| const Type* TypeNarrowOop::cleanup_speculative() const { |
| return make(_ptrtype->cleanup_speculative()->is_ptr()); |
| } |
| |
| #ifndef PRODUCT |
| void TypeNarrowOop::dump2( Dict & d, uint depth, outputStream *st ) const { |
| st->print("narrowoop: "); |
| TypeNarrowPtr::dump2(d, depth, st); |
| } |
| #endif |
| |
| const TypeNarrowKlass *TypeNarrowKlass::NULL_PTR; |
| |
| const TypeNarrowKlass* TypeNarrowKlass::make(const TypePtr* type) { |
| return (const TypeNarrowKlass*)(new TypeNarrowKlass(type))->hashcons(); |
| } |
| |
| #ifndef PRODUCT |
| void TypeNarrowKlass::dump2( Dict & d, uint depth, outputStream *st ) const { |
| st->print("narrowklass: "); |
| TypeNarrowPtr::dump2(d, depth, st); |
| } |
| #endif |
| |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeMetadataPtr::eq( const Type *t ) const { |
| const TypeMetadataPtr *a = (const TypeMetadataPtr*)t; |
| ciMetadata* one = metadata(); |
| ciMetadata* two = a->metadata(); |
| if (one == NULL || two == NULL) { |
| return (one == two) && TypePtr::eq(t); |
| } else { |
| return one->equals(two) && TypePtr::eq(t); |
| } |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeMetadataPtr::hash(void) const { |
| return |
| (metadata() ? metadata()->hash() : 0) + |
| TypePtr::hash(); |
| } |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants |
| bool TypeMetadataPtr::singleton(void) const { |
| // detune optimizer to not generate constant metadata + constant offset as a constant! |
| // TopPTR, Null, AnyNull, Constant are all singletons |
| return (_offset == 0) && !below_centerline(_ptr); |
| } |
| |
| //------------------------------add_offset------------------------------------- |
| const TypePtr *TypeMetadataPtr::add_offset( intptr_t offset ) const { |
| return make( _ptr, _metadata, xadd_offset(offset)); |
| } |
| |
| //-----------------------------filter------------------------------------------ |
| // Do not allow interface-vs.-noninterface joins to collapse to top. |
| const Type *TypeMetadataPtr::filter_helper(const Type *kills, bool include_speculative) const { |
| const TypeMetadataPtr* ft = join_helper(kills, include_speculative)->isa_metadataptr(); |
| if (ft == NULL || ft->empty()) |
| return Type::TOP; // Canonical empty value |
| return ft; |
| } |
| |
| //------------------------------get_con---------------------------------------- |
| intptr_t TypeMetadataPtr::get_con() const { |
| assert( _ptr == Null || _ptr == Constant, "" ); |
| assert( _offset >= 0, "" ); |
| |
| if (_offset != 0) { |
| // After being ported to the compiler interface, the compiler no longer |
| // directly manipulates the addresses of oops. Rather, it only has a pointer |
| // to a handle at compile time. This handle is embedded in the generated |
| // code and dereferenced at the time the nmethod is made. Until that time, |
| // it is not reasonable to do arithmetic with the addresses of oops (we don't |
| // have access to the addresses!). This does not seem to currently happen, |
| // but this assertion here is to help prevent its occurence. |
| tty->print_cr("Found oop constant with non-zero offset"); |
| ShouldNotReachHere(); |
| } |
| |
| return (intptr_t)metadata()->constant_encoding(); |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeMetadataPtr::cast_to_ptr_type(PTR ptr) const { |
| if( ptr == _ptr ) return this; |
| return make(ptr, metadata(), _offset); |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeMetadataPtr::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is OopPtr |
| switch (t->base()) { // switch on original type |
| |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case AnyPtr: { |
| // Found an AnyPtr type vs self-OopPtr type |
| const TypePtr *tp = t->is_ptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| switch (tp->ptr()) { |
| case Null: |
| if (ptr == Null) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); |
| // else fall through: |
| case TopPTR: |
| case AnyNull: { |
| return make(ptr, _metadata, offset); |
| } |
| case BotPTR: |
| case NotNull: |
| return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); |
| default: typerr(t); |
| } |
| } |
| |
| case RawPtr: |
| case KlassPtr: |
| case OopPtr: |
| case InstPtr: |
| case AryPtr: |
| return TypePtr::BOTTOM; // Oop meet raw is not well defined |
| |
| case MetadataPtr: { |
| const TypeMetadataPtr *tp = t->is_metadataptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR tptr = tp->ptr(); |
| PTR ptr = meet_ptr(tptr); |
| ciMetadata* md = (tptr == TopPTR) ? metadata() : tp->metadata(); |
| if (tptr == TopPTR || _ptr == TopPTR || |
| metadata()->equals(tp->metadata())) { |
| return make(ptr, md, offset); |
| } |
| // metadata is different |
| if( ptr == Constant ) { // Cannot be equal constants, so... |
| if( tptr == Constant && _ptr != Constant) return t; |
| if( _ptr == Constant && tptr != Constant) return this; |
| ptr = NotNull; // Fall down in lattice |
| } |
| return make(ptr, NULL, offset); |
| break; |
| } |
| } // End of switch |
| return this; // Return the double constant |
| } |
| |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual of a pure metadata pointer. |
| const Type *TypeMetadataPtr::xdual() const { |
| return new TypeMetadataPtr(dual_ptr(), metadata(), dual_offset()); |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| #ifndef PRODUCT |
| void TypeMetadataPtr::dump2( Dict &d, uint depth, outputStream *st ) const { |
| st->print("metadataptr:%s", ptr_msg[_ptr]); |
| if( metadata() ) st->print(INTPTR_FORMAT, p2i(metadata())); |
| switch( _offset ) { |
| case OffsetTop: st->print("+top"); break; |
| case OffsetBot: st->print("+any"); break; |
| case 0: break; |
| default: st->print("+%d",_offset); break; |
| } |
| } |
| #endif |
| |
| |
| //============================================================================= |
| // Convenience common pre-built type. |
| const TypeMetadataPtr *TypeMetadataPtr::BOTTOM; |
| |
| TypeMetadataPtr::TypeMetadataPtr(PTR ptr, ciMetadata* metadata, int offset): |
| TypePtr(MetadataPtr, ptr, offset), _metadata(metadata) { |
| } |
| |
| const TypeMetadataPtr* TypeMetadataPtr::make(ciMethod* m) { |
| return make(Constant, m, 0); |
| } |
| const TypeMetadataPtr* TypeMetadataPtr::make(ciMethodData* m) { |
| return make(Constant, m, 0); |
| } |
| |
| //------------------------------make------------------------------------------- |
| // Create a meta data constant |
| const TypeMetadataPtr *TypeMetadataPtr::make(PTR ptr, ciMetadata* m, int offset) { |
| assert(m == NULL || !m->is_klass(), "wrong type"); |
| return (TypeMetadataPtr*)(new TypeMetadataPtr(ptr, m, offset))->hashcons(); |
| } |
| |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| |
| // Not-null object klass or below |
| const TypeKlassPtr *TypeKlassPtr::OBJECT; |
| const TypeKlassPtr *TypeKlassPtr::OBJECT_OR_NULL; |
| |
| //------------------------------TypeKlassPtr----------------------------------- |
| TypeKlassPtr::TypeKlassPtr( PTR ptr, ciKlass* klass, int offset ) |
| : TypePtr(KlassPtr, ptr, offset), _klass(klass), _klass_is_exact(ptr == Constant) { |
| } |
| |
| //------------------------------make------------------------------------------- |
| // ptr to klass 'k', if Constant, or possibly to a sub-klass if not a Constant |
| const TypeKlassPtr *TypeKlassPtr::make( PTR ptr, ciKlass* k, int offset ) { |
| assert( k != NULL, "Expect a non-NULL klass"); |
| assert(k->is_instance_klass() || k->is_array_klass(), "Incorrect type of klass oop"); |
| TypeKlassPtr *r = |
| (TypeKlassPtr*)(new TypeKlassPtr(ptr, k, offset))->hashcons(); |
| |
| return r; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeKlassPtr::eq( const Type *t ) const { |
| const TypeKlassPtr *p = t->is_klassptr(); |
| return |
| klass()->equals(p->klass()) && |
| TypePtr::eq(p); |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeKlassPtr::hash(void) const { |
| return java_add(klass()->hash(), TypePtr::hash()); |
| } |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants |
| bool TypeKlassPtr::singleton(void) const { |
| // detune optimizer to not generate constant klass + constant offset as a constant! |
| // TopPTR, Null, AnyNull, Constant are all singletons |
| return (_offset == 0) && !below_centerline(_ptr); |
| } |
| |
| // Do not allow interface-vs.-noninterface joins to collapse to top. |
| const Type *TypeKlassPtr::filter_helper(const Type *kills, bool include_speculative) const { |
| // logic here mirrors the one from TypeOopPtr::filter. See comments |
| // there. |
| const Type* ft = join_helper(kills, include_speculative); |
| const TypeKlassPtr* ftkp = ft->isa_klassptr(); |
| const TypeKlassPtr* ktkp = kills->isa_klassptr(); |
| |
| if (ft->empty()) { |
| if (!empty() && ktkp != NULL && ktkp->klass()->is_loaded() && ktkp->klass()->is_interface()) |
| return kills; // Uplift to interface |
| |
| return Type::TOP; // Canonical empty value |
| } |
| |
| // Interface klass type could be exact in opposite to interface type, |
| // return it here instead of incorrect Constant ptr J/L/Object (6894807). |
| if (ftkp != NULL && ktkp != NULL && |
| ftkp->is_loaded() && ftkp->klass()->is_interface() && |
| !ftkp->klass_is_exact() && // Keep exact interface klass |
| ktkp->is_loaded() && !ktkp->klass()->is_interface()) { |
| return ktkp->cast_to_ptr_type(ftkp->ptr()); |
| } |
| |
| return ft; |
| } |
| |
| //----------------------compute_klass------------------------------------------ |
| // Compute the defining klass for this class |
| ciKlass* TypeAryPtr::compute_klass(DEBUG_ONLY(bool verify)) const { |
| // Compute _klass based on element type. |
| ciKlass* k_ary = NULL; |
| const TypeInstPtr *tinst; |
| const TypeAryPtr *tary; |
| const Type* el = elem(); |
| if (el->isa_narrowoop()) { |
| el = el->make_ptr(); |
| } |
| |
| // Get element klass |
| if ((tinst = el->isa_instptr()) != NULL) { |
| // Compute array klass from element klass |
| k_ary = ciObjArrayKlass::make(tinst->klass()); |
| } else if ((tary = el->isa_aryptr()) != NULL) { |
| // Compute array klass from element klass |
| ciKlass* k_elem = tary->klass(); |
| // If element type is something like bottom[], k_elem will be null. |
| if (k_elem != NULL) |
| k_ary = ciObjArrayKlass::make(k_elem); |
| } else if ((el->base() == Type::Top) || |
| (el->base() == Type::Bottom)) { |
| // element type of Bottom occurs from meet of basic type |
| // and object; Top occurs when doing join on Bottom. |
| // Leave k_ary at NULL. |
| } else { |
| // Cannot compute array klass directly from basic type, |
| // since subtypes of TypeInt all have basic type T_INT. |
| #ifdef ASSERT |
| if (verify && el->isa_int()) { |
| // Check simple cases when verifying klass. |
| BasicType bt = T_ILLEGAL; |
| if (el == TypeInt::BYTE) { |
| bt = T_BYTE; |
| } else if (el == TypeInt::SHORT) { |
| bt = T_SHORT; |
| } else if (el == TypeInt::CHAR) { |
| bt = T_CHAR; |
| } else if (el == TypeInt::INT) { |
| bt = T_INT; |
| } else { |
| return _klass; // just return specified klass |
| } |
| return ciTypeArrayKlass::make(bt); |
| } |
| #endif |
| assert(!el->isa_int(), |
| "integral arrays must be pre-equipped with a class"); |
| // Compute array klass directly from basic type |
| k_ary = ciTypeArrayKlass::make(el->basic_type()); |
| } |
| return k_ary; |
| } |
| |
| //------------------------------klass------------------------------------------ |
| // Return the defining klass for this class |
| ciKlass* TypeAryPtr::klass() const { |
| if( _klass ) return _klass; // Return cached value, if possible |
| |
| // Oops, need to compute _klass and cache it |
| ciKlass* k_ary = compute_klass(); |
| |
| if( this != TypeAryPtr::OOPS && this->dual() != TypeAryPtr::OOPS ) { |
| // The _klass field acts as a cache of the underlying |
| // ciKlass for this array type. In order to set the field, |
| // we need to cast away const-ness. |
| // |
| // IMPORTANT NOTE: we *never* set the _klass field for the |
| // type TypeAryPtr::OOPS. This Type is shared between all |
| // active compilations. However, the ciKlass which represents |
| // this Type is *not* shared between compilations, so caching |
| // this value would result in fetching a dangling pointer. |
| // |
| // Recomputing the underlying ciKlass for each request is |
| // a bit less efficient than caching, but calls to |
| // TypeAryPtr::OOPS->klass() are not common enough to matter. |
| ((TypeAryPtr*)this)->_klass = k_ary; |
| if (UseCompressedOops && k_ary != NULL && k_ary->is_obj_array_klass() && |
| _offset != 0 && _offset != arrayOopDesc::length_offset_in_bytes()) { |
| ((TypeAryPtr*)this)->_is_ptr_to_narrowoop = true; |
| } |
| } |
| return k_ary; |
| } |
| |
| |
| //------------------------------add_offset------------------------------------- |
| // Access internals of klass object |
| const TypePtr *TypeKlassPtr::add_offset( intptr_t offset ) const { |
| return make( _ptr, klass(), xadd_offset(offset) ); |
| } |
| |
| //------------------------------cast_to_ptr_type------------------------------- |
| const Type *TypeKlassPtr::cast_to_ptr_type(PTR ptr) const { |
| assert(_base == KlassPtr, "subclass must override cast_to_ptr_type"); |
| if( ptr == _ptr ) return this; |
| return make(ptr, _klass, _offset); |
| } |
| |
| |
| //-----------------------------cast_to_exactness------------------------------- |
| const Type *TypeKlassPtr::cast_to_exactness(bool klass_is_exact) const { |
| if( klass_is_exact == _klass_is_exact ) return this; |
| if (!UseExactTypes) return this; |
| return make(klass_is_exact ? Constant : NotNull, _klass, _offset); |
| } |
| |
| |
| //-----------------------------as_instance_type-------------------------------- |
| // Corresponding type for an instance of the given class. |
| // It will be NotNull, and exact if and only if the klass type is exact. |
| const TypeOopPtr* TypeKlassPtr::as_instance_type() const { |
| ciKlass* k = klass(); |
| bool xk = klass_is_exact(); |
| //return TypeInstPtr::make(TypePtr::NotNull, k, xk, NULL, 0); |
| const TypeOopPtr* toop = TypeOopPtr::make_from_klass_raw(k); |
| guarantee(toop != NULL, "need type for given klass"); |
| toop = toop->cast_to_ptr_type(TypePtr::NotNull)->is_oopptr(); |
| return toop->cast_to_exactness(xk)->is_oopptr(); |
| } |
| |
| |
| //------------------------------xmeet------------------------------------------ |
| // Compute the MEET of two types, return a new Type object. |
| const Type *TypeKlassPtr::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Pointer |
| switch (t->base()) { // switch on original type |
| |
| case Int: // Mixing ints & oops happens when javac |
| case Long: // reuses local variables |
| case FloatTop: |
| case FloatCon: |
| case FloatBot: |
| case DoubleTop: |
| case DoubleCon: |
| case DoubleBot: |
| case NarrowOop: |
| case NarrowKlass: |
| case Bottom: // Ye Olde Default |
| return Type::BOTTOM; |
| case Top: |
| return this; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case AnyPtr: { // Meeting to AnyPtrs |
| // Found an AnyPtr type vs self-KlassPtr type |
| const TypePtr *tp = t->is_ptr(); |
| int offset = meet_offset(tp->offset()); |
| PTR ptr = meet_ptr(tp->ptr()); |
| switch (tp->ptr()) { |
| case TopPTR: |
| return this; |
| case Null: |
| if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); |
| case AnyNull: |
| return make( ptr, klass(), offset ); |
| case BotPTR: |
| case NotNull: |
| return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); |
| default: typerr(t); |
| } |
| } |
| |
| case RawPtr: |
| case MetadataPtr: |
| case OopPtr: |
| case AryPtr: // Meet with AryPtr |
| case InstPtr: // Meet with InstPtr |
| return TypePtr::BOTTOM; |
| |
| // |
| // A-top } |
| // / | \ } Tops |
| // B-top A-any C-top } |
| // | / | \ | } Any-nulls |
| // B-any | C-any } |
| // | | | |
| // B-con A-con C-con } constants; not comparable across classes |
| // | | | |
| // B-not | C-not } |
| // | \ | / | } not-nulls |
| // B-bot A-not C-bot } |
| // \ | / } Bottoms |
| // A-bot } |
| // |
| |
| case KlassPtr: { // Meet two KlassPtr types |
| const TypeKlassPtr *tkls = t->is_klassptr(); |
| int off = meet_offset(tkls->offset()); |
| PTR ptr = meet_ptr(tkls->ptr()); |
| |
| // Check for easy case; klasses are equal (and perhaps not loaded!) |
| // If we have constants, then we created oops so classes are loaded |
| // and we can handle the constants further down. This case handles |
| // not-loaded classes |
| if( ptr != Constant && tkls->klass()->equals(klass()) ) { |
| return make( ptr, klass(), off ); |
| } |
| |
| // Classes require inspection in the Java klass hierarchy. Must be loaded. |
| ciKlass* tkls_klass = tkls->klass(); |
| ciKlass* this_klass = this->klass(); |
| assert( tkls_klass->is_loaded(), "This class should have been loaded."); |
| assert( this_klass->is_loaded(), "This class should have been loaded."); |
| |
| // If 'this' type is above the centerline and is a superclass of the |
| // other, we can treat 'this' as having the same type as the other. |
| if ((above_centerline(this->ptr())) && |
| tkls_klass->is_subtype_of(this_klass)) { |
| this_klass = tkls_klass; |
| } |
| // If 'tinst' type is above the centerline and is a superclass of the |
| // other, we can treat 'tinst' as having the same type as the other. |
| if ((above_centerline(tkls->ptr())) && |
| this_klass->is_subtype_of(tkls_klass)) { |
| tkls_klass = this_klass; |
| } |
| |
| // Check for classes now being equal |
| if (tkls_klass->equals(this_klass)) { |
| // If the klasses are equal, the constants may still differ. Fall to |
| // NotNull if they do (neither constant is NULL; that is a special case |
| // handled elsewhere). |
| if( ptr == Constant ) { |
| if (this->_ptr == Constant && tkls->_ptr == Constant && |
| this->klass()->equals(tkls->klass())); |
| else if (above_centerline(this->ptr())); |
| else if (above_centerline(tkls->ptr())); |
| else |
| ptr = NotNull; |
| } |
| return make( ptr, this_klass, off ); |
| } // Else classes are not equal |
| |
| // Since klasses are different, we require the LCA in the Java |
| // class hierarchy - which means we have to fall to at least NotNull. |
| if( ptr == TopPTR || ptr == AnyNull || ptr == Constant ) |
| ptr = NotNull; |
| // Now we find the LCA of Java classes |
| ciKlass* k = this_klass->least_common_ancestor(tkls_klass); |
| return make( ptr, k, off ); |
| } // End of case KlassPtr |
| |
| } // End of switch |
| return this; // Return the double constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeKlassPtr::xdual() const { |
| return new TypeKlassPtr( dual_ptr(), klass(), dual_offset() ); |
| } |
| |
| //------------------------------get_con---------------------------------------- |
| intptr_t TypeKlassPtr::get_con() const { |
| assert( _ptr == Null || _ptr == Constant, "" ); |
| assert( _offset >= 0, "" ); |
| |
| if (_offset != 0) { |
| // After being ported to the compiler interface, the compiler no longer |
| // directly manipulates the addresses of oops. Rather, it only has a pointer |
| // to a handle at compile time. This handle is embedded in the generated |
| // code and dereferenced at the time the nmethod is made. Until that time, |
| // it is not reasonable to do arithmetic with the addresses of oops (we don't |
| // have access to the addresses!). This does not seem to currently happen, |
| // but this assertion here is to help prevent its occurence. |
| tty->print_cr("Found oop constant with non-zero offset"); |
| ShouldNotReachHere(); |
| } |
| |
| return (intptr_t)klass()->constant_encoding(); |
| } |
| //------------------------------dump2------------------------------------------ |
| // Dump Klass Type |
| #ifndef PRODUCT |
| void TypeKlassPtr::dump2( Dict & d, uint depth, outputStream *st ) const { |
| switch( _ptr ) { |
| case Constant: |
| st->print("precise "); |
| case NotNull: |
| { |
| const char *name = klass()->name()->as_utf8(); |
| if( name ) { |
| st->print("klass %s: " INTPTR_FORMAT, name, p2i(klass())); |
| } else { |
| ShouldNotReachHere(); |
| } |
| } |
| case BotPTR: |
| if( !WizardMode && !Verbose && !_klass_is_exact ) break; |
| case TopPTR: |
| case AnyNull: |
| st->print(":%s", ptr_msg[_ptr]); |
| if( _klass_is_exact ) st->print(":exact"); |
| break; |
| } |
| |
| if( _offset ) { // Dump offset, if any |
| if( _offset == OffsetBot ) { st->print("+any"); } |
| else if( _offset == OffsetTop ) { st->print("+unknown"); } |
| else { st->print("+%d", _offset); } |
| } |
| |
| st->print(" *"); |
| } |
| #endif |
| |
| |
| |
| //============================================================================= |
| // Convenience common pre-built types. |
| |
| //------------------------------make------------------------------------------- |
| const TypeFunc *TypeFunc::make( const TypeTuple *domain, const TypeTuple *range ) { |
| return (TypeFunc*)(new TypeFunc(domain,range))->hashcons(); |
| } |
| |
| //------------------------------make------------------------------------------- |
| const TypeFunc *TypeFunc::make(ciMethod* method) { |
| Compile* C = Compile::current(); |
| const TypeFunc* tf = C->last_tf(method); // check cache |
| if (tf != NULL) return tf; // The hit rate here is almost 50%. |
| const TypeTuple *domain; |
| if (method->is_static()) { |
| domain = TypeTuple::make_domain(NULL, method->signature()); |
| } else { |
| domain = TypeTuple::make_domain(method->holder(), method->signature()); |
| } |
| const TypeTuple *range = TypeTuple::make_range(method->signature()); |
| tf = TypeFunc::make(domain, range); |
| C->set_last_tf(method, tf); // fill cache |
| return tf; |
| } |
| |
| //------------------------------meet------------------------------------------- |
| // Compute the MEET of two types. It returns a new Type object. |
| const Type *TypeFunc::xmeet( const Type *t ) const { |
| // Perform a fast test for common case; meeting the same types together. |
| if( this == t ) return this; // Meeting same type-rep? |
| |
| // Current "this->_base" is Func |
| switch (t->base()) { // switch on original type |
| |
| case Bottom: // Ye Olde Default |
| return t; |
| |
| default: // All else is a mistake |
| typerr(t); |
| |
| case Top: |
| break; |
| } |
| return this; // Return the double constant |
| } |
| |
| //------------------------------xdual------------------------------------------ |
| // Dual: compute field-by-field dual |
| const Type *TypeFunc::xdual() const { |
| return this; |
| } |
| |
| //------------------------------eq--------------------------------------------- |
| // Structural equality check for Type representations |
| bool TypeFunc::eq( const Type *t ) const { |
| const TypeFunc *a = (const TypeFunc*)t; |
| return _domain == a->_domain && |
| _range == a->_range; |
| } |
| |
| //------------------------------hash------------------------------------------- |
| // Type-specific hashing function. |
| int TypeFunc::hash(void) const { |
| return (intptr_t)_domain + (intptr_t)_range; |
| } |
| |
| //------------------------------dump2------------------------------------------ |
| // Dump Function Type |
| #ifndef PRODUCT |
| void TypeFunc::dump2( Dict &d, uint depth, outputStream *st ) const { |
| if( _range->cnt() <= Parms ) |
| st->print("void"); |
| else { |
| uint i; |
| for (i = Parms; i < _range->cnt()-1; i++) { |
| _range->field_at(i)->dump2(d,depth,st); |
| st->print("/"); |
| } |
| _range->field_at(i)->dump2(d,depth,st); |
| } |
| st->print(" "); |
| st->print("( "); |
| if( !depth || d[this] ) { // Check for recursive dump |
| st->print("...)"); |
| return; |
| } |
| d.Insert((void*)this,(void*)this); // Stop recursion |
| if (Parms < _domain->cnt()) |
| _domain->field_at(Parms)->dump2(d,depth-1,st); |
| for (uint i = Parms+1; i < _domain->cnt(); i++) { |
| st->print(", "); |
| _domain->field_at(i)->dump2(d,depth-1,st); |
| } |
| st->print(" )"); |
| } |
| #endif |
| |
| //------------------------------singleton-------------------------------------- |
| // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple |
| // constants (Ldi nodes). Singletons are integer, float or double constants |
| // or a single symbol. |
| bool TypeFunc::singleton(void) const { |
| return false; // Never a singleton |
| } |
| |
| bool TypeFunc::empty(void) const { |
| return false; // Never empty |
| } |
| |
| |
| BasicType TypeFunc::return_type() const{ |
| if (range()->cnt() == TypeFunc::Parms) { |
| return T_VOID; |
| } |
| return range()->field_at(TypeFunc::Parms)->basic_type(); |
| } |