1 /*
   2  * Copyright (c) 1997, 2026, Oracle and/or its affiliates. All rights reserved.
   3  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
   4  *
   5  * This code is free software; you can redistribute it and/or modify it
   6  * under the terms of the GNU General Public License version 2 only, as
   7  * published by the Free Software Foundation.
   8  *
   9  * This code is distributed in the hope that it will be useful, but WITHOUT
  10  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  11  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  12  * version 2 for more details (a copy is included in the LICENSE file that
  13  * accompanied this code).
  14  *
  15  * You should have received a copy of the GNU General Public License version
  16  * 2 along with this work; if not, write to the Free Software Foundation,
  17  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  18  *
  19  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  20  * or visit www.oracle.com if you need additional information or have any
  21  * questions.
  22  *
  23  */
  24 
  25 #include "ci/ciField.hpp"
  26 #include "ci/ciFlatArray.hpp"
  27 #include "ci/ciFlatArrayKlass.hpp"
  28 #include "ci/ciInlineKlass.hpp"
  29 #include "ci/ciInstanceKlass.hpp"
  30 #include "ci/ciMethodData.hpp"
  31 #include "ci/ciObjArrayKlass.hpp"
  32 #include "ci/ciTypeFlow.hpp"
  33 #include "classfile/javaClasses.hpp"
  34 #include "classfile/symbolTable.hpp"
  35 #include "classfile/vmSymbols.hpp"
  36 #include "compiler/compileLog.hpp"
  37 #include "libadt/dict.hpp"
  38 #include "memory/oopFactory.hpp"
  39 #include "memory/resourceArea.hpp"
  40 #include "oops/instanceKlass.hpp"
  41 #include "oops/instanceMirrorKlass.hpp"
  42 #include "oops/objArrayKlass.hpp"
  43 #include "oops/typeArrayKlass.hpp"
  44 #include "opto/arraycopynode.hpp"
  45 #include "opto/callnode.hpp"
  46 #include "opto/matcher.hpp"
  47 #include "opto/node.hpp"
  48 #include "opto/opcodes.hpp"
  49 #include "opto/rangeinference.hpp"
  50 #include "opto/runtime.hpp"
  51 #include "opto/type.hpp"
  52 #include "runtime/globals.hpp"
  53 #include "runtime/stubRoutines.hpp"
  54 #include "utilities/checkedCast.hpp"
  55 #include "utilities/debug.hpp"
  56 #include "utilities/globalDefinitions.hpp"
  57 #include "utilities/ostream.hpp"
  58 #include "utilities/powerOfTwo.hpp"
  59 #include "utilities/stringUtils.hpp"
  60 
  61 // Portions of code courtesy of Clifford Click
  62 
  63 // Optimization - Graph Style
  64 
  65 // Dictionary of types shared among compilations.
  66 Dict* Type::_shared_type_dict = nullptr;
  67 const Type::Offset Type::Offset::top(Type::OffsetTop);
  68 const Type::Offset Type::Offset::bottom(Type::OffsetBot);
  69 
  70 const Type::Offset Type::Offset::meet(const Type::Offset other) const {
  71   // Either is 'TOP' offset?  Return the other offset!
  72   if (_offset == OffsetTop) return other;
  73   if (other._offset == OffsetTop) return *this;
  74   // If either is different, return 'BOTTOM' offset
  75   if (_offset != other._offset) return bottom;
  76   return Offset(_offset);
  77 }
  78 
  79 const Type::Offset Type::Offset::dual() const {
  80   if (_offset == OffsetTop) return bottom;// Map 'TOP' into 'BOTTOM'
  81   if (_offset == OffsetBot) return top;// Map 'BOTTOM' into 'TOP'
  82   return Offset(_offset);               // Map everything else into self
  83 }
  84 
  85 const Type::Offset Type::Offset::add(intptr_t offset) const {
  86   // Adding to 'TOP' offset?  Return 'TOP'!
  87   if (_offset == OffsetTop || offset == OffsetTop) return top;
  88   // Adding to 'BOTTOM' offset?  Return 'BOTTOM'!
  89   if (_offset == OffsetBot || offset == OffsetBot) return bottom;
  90   // Addition overflows or "accidentally" equals to OffsetTop? Return 'BOTTOM'!
  91   offset += (intptr_t)_offset;
  92   if (offset != (int)offset || offset == OffsetTop) return bottom;
  93 
  94   // assert( _offset >= 0 && _offset+offset >= 0, "" );
  95   // It is possible to construct a negative offset during PhaseCCP
  96 
  97   return Offset((int)offset);        // Sum valid offsets
  98 }
  99 
 100 void Type::Offset::dump2(outputStream *st) const {
 101   if (_offset == 0) {
 102     return;
 103   } else if (_offset == OffsetTop) {
 104     st->print("+top");
 105   } else if (_offset == OffsetBot) {
 106     st->print("+bot");
 107   } else {
 108     st->print("+%d", _offset);
 109   }
 110 }
 111 
 112 // Array which maps compiler types to Basic Types
 113 const Type::TypeInfo Type::_type_info[Type::lastype] = {
 114   { Bad,             T_ILLEGAL,    "bad",           false, Node::NotAMachineReg},  // Bad
 115   { Control,         T_ILLEGAL,    "control",       false, 0                   },  // Control
 116   { Bottom,          T_VOID,       "top",           false, 0                   },  // Top
 117   { Bad,             T_INT,        "int:",          false, Op_RegI             },  // Int
 118   { Bad,             T_LONG,       "long:",         false, Op_RegL             },  // Long
 119   { Half,            T_VOID,       "half",          false, 0                   },  // Half
 120   { Bad,             T_NARROWOOP,  "narrowoop:",    false, Op_RegN             },  // NarrowOop
 121   { Bad,             T_NARROWKLASS,"narrowklass:",  false, Op_RegN             },  // NarrowKlass
 122   { Bad,             T_ILLEGAL,    "tuple:",        false, Node::NotAMachineReg},  // Tuple
 123   { Bad,             T_ARRAY,      "array:",        false, Node::NotAMachineReg},  // Array
 124   { Bad,             T_ARRAY,      "interfaces:",   false, Node::NotAMachineReg},  // Interfaces
 125 
 126 #if defined(PPC64)
 127   { Bad,             T_ILLEGAL,    "vectormask:",   false, Op_RegVectMask      },  // VectorMask.
 128   { Bad,             T_ILLEGAL,    "vectora:",      false, Op_VecA             },  // VectorA.
 129   { Bad,             T_ILLEGAL,    "vectors:",      false, 0                   },  // VectorS
 130   { Bad,             T_ILLEGAL,    "vectord:",      false, Op_RegL             },  // VectorD
 131   { Bad,             T_ILLEGAL,    "vectorx:",      false, Op_VecX             },  // VectorX
 132   { Bad,             T_ILLEGAL,    "vectory:",      false, 0                   },  // VectorY
 133   { Bad,             T_ILLEGAL,    "vectorz:",      false, 0                   },  // VectorZ
 134 #elif defined(S390)
 135   { Bad,             T_ILLEGAL,    "vectormask:",   false, Op_RegVectMask      },  // VectorMask.
 136   { Bad,             T_ILLEGAL,    "vectora:",      false, Op_VecA             },  // VectorA.
 137   { Bad,             T_ILLEGAL,    "vectors:",      false, 0                   },  // VectorS
 138   { Bad,             T_ILLEGAL,    "vectord:",      false, Op_RegL             },  // VectorD
 139   { Bad,             T_ILLEGAL,    "vectorx:",      false, Op_VecX             },  // VectorX
 140   { Bad,             T_ILLEGAL,    "vectory:",      false, 0                   },  // VectorY
 141   { Bad,             T_ILLEGAL,    "vectorz:",      false, 0                   },  // VectorZ
 142 #else // all other
 143   { Bad,             T_ILLEGAL,    "vectormask:",   false, Op_RegVectMask      },  // VectorMask.
 144   { Bad,             T_ILLEGAL,    "vectora:",      false, Op_VecA             },  // VectorA.
 145   { Bad,             T_ILLEGAL,    "vectors:",      false, Op_VecS             },  // VectorS
 146   { Bad,             T_ILLEGAL,    "vectord:",      false, Op_VecD             },  // VectorD
 147   { Bad,             T_ILLEGAL,    "vectorx:",      false, Op_VecX             },  // VectorX
 148   { Bad,             T_ILLEGAL,    "vectory:",      false, Op_VecY             },  // VectorY
 149   { Bad,             T_ILLEGAL,    "vectorz:",      false, Op_VecZ             },  // VectorZ
 150 #endif
 151   { Bad,             T_ADDRESS,    "anyptr:",       false, Op_RegP             },  // AnyPtr
 152   { Bad,             T_ADDRESS,    "rawptr:",       false, Op_RegP             },  // RawPtr
 153   { Bad,             T_OBJECT,     "oop:",          true,  Op_RegP             },  // OopPtr
 154   { Bad,             T_OBJECT,     "inst:",         true,  Op_RegP             },  // InstPtr
 155   { Bad,             T_OBJECT,     "ary:",          true,  Op_RegP             },  // AryPtr
 156   { Bad,             T_METADATA,   "metadata:",     false, Op_RegP             },  // MetadataPtr
 157   { Bad,             T_METADATA,   "klass:",        false, Op_RegP             },  // KlassPtr
 158   { Bad,             T_METADATA,   "instklass:",    false, Op_RegP             },  // InstKlassPtr
 159   { Bad,             T_METADATA,   "aryklass:",     false, Op_RegP             },  // AryKlassPtr
 160   { Bad,             T_OBJECT,     "func",          false, 0                   },  // Function
 161   { Abio,            T_ILLEGAL,    "abIO",          false, 0                   },  // Abio
 162   { Return_Address,  T_ADDRESS,    "return_address",false, Op_RegP             },  // Return_Address
 163   { Memory,          T_ILLEGAL,    "memory",        false, 0                   },  // Memory
 164   { HalfFloatBot,    T_SHORT,      "halffloat_top", false, Op_RegF             },  // HalfFloatTop
 165   { HalfFloatCon,    T_SHORT,      "hfcon:",        false, Op_RegF             },  // HalfFloatCon
 166   { HalfFloatTop,    T_SHORT,      "short",         false, Op_RegF             },  // HalfFloatBot
 167   { FloatBot,        T_FLOAT,      "float_top",     false, Op_RegF             },  // FloatTop
 168   { FloatCon,        T_FLOAT,      "ftcon:",        false, Op_RegF             },  // FloatCon
 169   { FloatTop,        T_FLOAT,      "float",         false, Op_RegF             },  // FloatBot
 170   { DoubleBot,       T_DOUBLE,     "double_top",    false, Op_RegD             },  // DoubleTop
 171   { DoubleCon,       T_DOUBLE,     "dblcon:",       false, Op_RegD             },  // DoubleCon
 172   { DoubleTop,       T_DOUBLE,     "double",        false, Op_RegD             },  // DoubleBot
 173   { Top,             T_ILLEGAL,    "bottom",        false, 0                   }   // Bottom
 174 };
 175 
 176 // Map ideal registers (machine types) to ideal types
 177 const Type *Type::mreg2type[_last_machine_leaf];
 178 
 179 // Map basic types to canonical Type* pointers.
 180 const Type* Type::     _const_basic_type[T_CONFLICT+1];
 181 
 182 // Map basic types to constant-zero Types.
 183 const Type* Type::            _zero_type[T_CONFLICT+1];
 184 
 185 // Map basic types to array-body alias types.
 186 const TypeAryPtr* TypeAryPtr::_array_body_type[T_CONFLICT+1];
 187 const TypeInterfaces* TypeAryPtr::_array_interfaces = nullptr;
 188 const TypeInterfaces* TypeAryKlassPtr::_array_interfaces = nullptr;
 189 
 190 //=============================================================================
 191 // Convenience common pre-built types.
 192 const Type *Type::ABIO;         // State-of-machine only
 193 const Type *Type::BOTTOM;       // All values
 194 const Type *Type::CONTROL;      // Control only
 195 const Type *Type::DOUBLE;       // All doubles
 196 const Type *Type::HALF_FLOAT;   // All half floats
 197 const Type *Type::FLOAT;        // All floats
 198 const Type *Type::HALF;         // Placeholder half of doublewide type
 199 const Type *Type::MEMORY;       // Abstract store only
 200 const Type *Type::RETURN_ADDRESS;
 201 const Type *Type::TOP;          // No values in set
 202 
 203 //------------------------------get_const_type---------------------------
 204 const Type* Type::get_const_type(ciType* type, InterfaceHandling interface_handling) {
 205   if (type == nullptr) {
 206     return nullptr;
 207   } else if (type->is_primitive_type()) {
 208     return get_const_basic_type(type->basic_type());
 209   } else {
 210     return TypeOopPtr::make_from_klass(type->as_klass(), interface_handling);
 211   }
 212 }
 213 
 214 //---------------------------array_element_basic_type---------------------------------
 215 // Mapping to the array element's basic type.
 216 BasicType Type::array_element_basic_type() const {
 217   BasicType bt = basic_type();
 218   if (bt == T_INT) {
 219     if (this == TypeInt::INT)   return T_INT;
 220     if (this == TypeInt::CHAR)  return T_CHAR;
 221     if (this == TypeInt::BYTE)  return T_BYTE;
 222     if (this == TypeInt::BOOL)  return T_BOOLEAN;
 223     if (this == TypeInt::SHORT) return T_SHORT;
 224     return T_VOID;
 225   }
 226   return bt;
 227 }
 228 
 229 // For two instance arrays of same dimension, return the base element types.
 230 // Otherwise or if the arrays have different dimensions, return null.
 231 void Type::get_arrays_base_elements(const Type *a1, const Type *a2,
 232                                     const TypeInstPtr **e1, const TypeInstPtr **e2) {
 233 
 234   if (e1) *e1 = nullptr;
 235   if (e2) *e2 = nullptr;
 236   const TypeAryPtr* a1tap = (a1 == nullptr) ? nullptr : a1->isa_aryptr();
 237   const TypeAryPtr* a2tap = (a2 == nullptr) ? nullptr : a2->isa_aryptr();
 238 
 239   if (a1tap != nullptr && a2tap != nullptr) {
 240     // Handle multidimensional arrays
 241     const TypePtr* a1tp = a1tap->elem()->make_ptr();
 242     const TypePtr* a2tp = a2tap->elem()->make_ptr();
 243     while (a1tp && a1tp->isa_aryptr() && a2tp && a2tp->isa_aryptr()) {
 244       a1tap = a1tp->is_aryptr();
 245       a2tap = a2tp->is_aryptr();
 246       a1tp = a1tap->elem()->make_ptr();
 247       a2tp = a2tap->elem()->make_ptr();
 248     }
 249     if (a1tp && a1tp->isa_instptr() && a2tp && a2tp->isa_instptr()) {
 250       if (e1) *e1 = a1tp->is_instptr();
 251       if (e2) *e2 = a2tp->is_instptr();
 252     }
 253   }
 254 }
 255 
 256 //---------------------------get_typeflow_type---------------------------------
 257 // Import a type produced by ciTypeFlow.
 258 const Type* Type::get_typeflow_type(ciType* type) {
 259   switch (type->basic_type()) {
 260 
 261   case ciTypeFlow::StateVector::T_BOTTOM:
 262     assert(type == ciTypeFlow::StateVector::bottom_type(), "");
 263     return Type::BOTTOM;
 264 
 265   case ciTypeFlow::StateVector::T_TOP:
 266     assert(type == ciTypeFlow::StateVector::top_type(), "");
 267     return Type::TOP;
 268 
 269   case ciTypeFlow::StateVector::T_NULL:
 270     assert(type == ciTypeFlow::StateVector::null_type(), "");
 271     return TypePtr::NULL_PTR;
 272 
 273   case ciTypeFlow::StateVector::T_LONG2:
 274     // The ciTypeFlow pass pushes a long, then the half.
 275     // We do the same.
 276     assert(type == ciTypeFlow::StateVector::long2_type(), "");
 277     return TypeInt::TOP;
 278 
 279   case ciTypeFlow::StateVector::T_DOUBLE2:
 280     // The ciTypeFlow pass pushes double, then the half.
 281     // Our convention is the same.
 282     assert(type == ciTypeFlow::StateVector::double2_type(), "");
 283     return Type::TOP;
 284 
 285   case T_ADDRESS:
 286     assert(type->is_return_address(), "");
 287     return TypeRawPtr::make((address)(intptr_t)type->as_return_address()->bci(), relocInfo::none);
 288 
 289   case T_OBJECT:
 290     return Type::get_const_type(type->unwrap())->join_speculative(type->is_null_free() ? TypePtr::NOTNULL : TypePtr::BOTTOM);
 291 
 292   default:
 293     // make sure we did not mix up the cases:
 294     assert(type != ciTypeFlow::StateVector::bottom_type(), "");
 295     assert(type != ciTypeFlow::StateVector::top_type(), "");
 296     assert(type != ciTypeFlow::StateVector::null_type(), "");
 297     assert(type != ciTypeFlow::StateVector::long2_type(), "");
 298     assert(type != ciTypeFlow::StateVector::double2_type(), "");
 299     assert(!type->is_return_address(), "");
 300 
 301     return Type::get_const_type(type);
 302   }
 303 }
 304 
 305 
 306 //-----------------------make_from_constant------------------------------------
 307 const Type* Type::make_from_constant(ciConstant constant, bool require_constant,
 308                                      int stable_dimension, bool is_narrow_oop,
 309                                      bool is_autobox_cache) {
 310   switch (constant.basic_type()) {
 311     case T_BOOLEAN:  return TypeInt::make(constant.as_boolean());
 312     case T_CHAR:     return TypeInt::make(constant.as_char());
 313     case T_BYTE:     return TypeInt::make(constant.as_byte());
 314     case T_SHORT:    return TypeInt::make(constant.as_short());
 315     case T_INT:      return TypeInt::make(constant.as_int());
 316     case T_LONG:     return TypeLong::make(constant.as_long());
 317     case T_FLOAT:    return TypeF::make(constant.as_float());
 318     case T_DOUBLE:   return TypeD::make(constant.as_double());
 319     case T_ARRAY:
 320     case T_OBJECT: {
 321         const Type* con_type = nullptr;
 322         ciObject* oop_constant = constant.as_object();
 323         if (oop_constant->is_null_object()) {
 324           con_type = Type::get_zero_type(T_OBJECT);
 325         } else {
 326           guarantee(require_constant || oop_constant->should_be_constant(), "con_type must get computed");
 327           con_type = TypeOopPtr::make_from_constant(oop_constant, require_constant);
 328           if (Compile::current()->eliminate_boxing() && is_autobox_cache) {
 329             con_type = con_type->is_aryptr()->cast_to_autobox_cache();
 330           }
 331           if (stable_dimension > 0) {
 332             assert(FoldStableValues, "sanity");
 333             assert(!con_type->is_zero_type(), "default value for stable field");
 334             con_type = con_type->is_aryptr()->cast_to_stable(true, stable_dimension);
 335           }
 336         }
 337         if (is_narrow_oop) {
 338           con_type = con_type->make_narrowoop();
 339         }
 340         return con_type;
 341       }
 342     case T_ILLEGAL:
 343       // Invalid ciConstant returned due to OutOfMemoryError in the CI
 344       assert(Compile::current()->env()->failing(), "otherwise should not see this");
 345       return nullptr;
 346     default:
 347       // Fall through to failure
 348       return nullptr;
 349   }
 350 }
 351 
 352 static ciConstant check_mismatched_access(ciConstant con, BasicType loadbt, bool is_unsigned) {
 353   BasicType conbt = con.basic_type();
 354   switch (conbt) {
 355     case T_BOOLEAN: conbt = T_BYTE;   break;
 356     case T_ARRAY:   conbt = T_OBJECT; break;
 357     default:                          break;
 358   }
 359   switch (loadbt) {
 360     case T_BOOLEAN:   loadbt = T_BYTE;   break;
 361     case T_NARROWOOP: loadbt = T_OBJECT; break;
 362     case T_ARRAY:     loadbt = T_OBJECT; break;
 363     case T_ADDRESS:   loadbt = T_OBJECT; break;
 364     default:                             break;
 365   }
 366   if (conbt == loadbt) {
 367     if (is_unsigned && conbt == T_BYTE) {
 368       // LoadB (T_BYTE) with a small mask (<=8-bit) is converted to LoadUB (T_BYTE).
 369       return ciConstant(T_INT, con.as_int() & 0xFF);
 370     } else {
 371       return con;
 372     }
 373   }
 374   if (conbt == T_SHORT && loadbt == T_CHAR) {
 375     // LoadS (T_SHORT) with a small mask (<=16-bit) is converted to LoadUS (T_CHAR).
 376     return ciConstant(T_INT, con.as_int() & 0xFFFF);
 377   }
 378   return ciConstant(); // T_ILLEGAL
 379 }
 380 
 381 static const Type* make_constant_from_non_flat_array_element(ciArray* array, int off, int stable_dimension,
 382                                                    BasicType loadbt, bool is_unsigned_load) {
 383   // Decode the results of GraphKit::array_element_address.
 384   ciConstant element_value = array->element_value_by_offset(off);
 385   if (element_value.basic_type() == T_ILLEGAL) {
 386     return nullptr; // wrong offset
 387   }
 388   ciConstant con = check_mismatched_access(element_value, loadbt, is_unsigned_load);
 389 
 390   assert(con.basic_type() != T_ILLEGAL, "elembt=%s; loadbt=%s; unsigned=%d",
 391          type2name(element_value.basic_type()), type2name(loadbt), is_unsigned_load);
 392 
 393   if (con.is_valid() &&          // not a mismatched access
 394       !con.is_null_or_zero()) {  // not a default value
 395     bool is_narrow_oop = (loadbt == T_NARROWOOP);
 396     return Type::make_from_constant(con, /*require_constant=*/true, stable_dimension, is_narrow_oop, /*is_autobox_cache=*/false);
 397   }
 398   return nullptr;
 399 }
 400 
 401 static const Type* make_constant_from_flat_array_element(ciFlatArray* array, int off, int field_offset, int stable_dimension,
 402                                                          BasicType loadbt, bool is_unsigned_load) {
 403   if (!array->is_null_free()) {
 404     ciConstant nm_value = array->null_marker_of_element_by_offset(off);
 405     if (!nm_value.is_valid() || !nm_value.as_boolean()) {
 406       return nullptr;
 407     }
 408   }
 409   ciConstant element_value = array->field_value_by_offset(off + field_offset);
 410   if (element_value.basic_type() == T_ILLEGAL) {
 411     return nullptr; // wrong offset
 412   }
 413   ciConstant con = check_mismatched_access(element_value, loadbt, is_unsigned_load);
 414 
 415   assert(con.basic_type() != T_ILLEGAL, "elembt=%s; loadbt=%s; unsigned=%d",
 416          type2name(element_value.basic_type()), type2name(loadbt), is_unsigned_load);
 417 
 418   if (con.is_valid()) { // not a mismatched access
 419     bool is_narrow_oop = (loadbt == T_NARROWOOP);
 420     return Type::make_from_constant(con, /*require_constant=*/true, stable_dimension, is_narrow_oop, /*is_autobox_cache=*/false);
 421   }
 422   return nullptr;
 423 }
 424 
 425 // Try to constant-fold a stable array element.
 426 const Type* Type::make_constant_from_array_element(ciArray* array, int off, int field_offset, int stable_dimension,
 427                                                    BasicType loadbt, bool is_unsigned_load) {
 428   if (array->is_flat()) {
 429     return make_constant_from_flat_array_element(array->as_flat_array(), off, field_offset, stable_dimension, loadbt, is_unsigned_load);
 430   }
 431   return make_constant_from_non_flat_array_element(array, off, stable_dimension, loadbt, is_unsigned_load);
 432 }
 433 
 434 const Type* Type::make_constant_from_field(ciInstance* holder, int off, bool is_unsigned_load, BasicType loadbt) {
 435   ciField* field;
 436   ciType* type = holder->java_mirror_type();
 437   if (type != nullptr && type->is_instance_klass() && off >= InstanceMirrorKlass::offset_of_static_fields()) {
 438     // Static field
 439     field = type->as_instance_klass()->get_field_by_offset(off, /*is_static=*/true);
 440   } else {
 441     // Instance field
 442     field = holder->klass()->as_instance_klass()->get_field_by_offset(off, /*is_static=*/false);
 443   }
 444   if (field == nullptr) {
 445     return nullptr; // Wrong offset
 446   }
 447   return Type::make_constant_from_field(field, holder, loadbt, is_unsigned_load);
 448 }
 449 
 450 const Type* Type::make_constant_from_field(ciField* field, ciInstance* holder,
 451                                            BasicType loadbt, bool is_unsigned_load) {
 452   if (!field->is_constant()) {
 453     return nullptr; // Non-constant field
 454   }
 455   ciConstant field_value;
 456   if (field->is_static()) {
 457     // final static field
 458     field_value = field->constant_value();
 459   } else if (holder != nullptr) {
 460     // final or stable non-static field
 461     // Treat final non-static fields of trusted classes (classes in
 462     // java.lang.invoke and sun.invoke packages and subpackages) as
 463     // compile time constants.
 464     field_value = field->constant_value_of(holder);
 465   }
 466   if (!field_value.is_valid()) {
 467     return nullptr; // Not a constant
 468   }
 469 
 470   ciConstant con = check_mismatched_access(field_value, loadbt, is_unsigned_load);
 471 
 472   assert(con.is_valid(), "elembt=%s; loadbt=%s; unsigned=%d",
 473          type2name(field_value.basic_type()), type2name(loadbt), is_unsigned_load);
 474 
 475   bool is_stable_array = FoldStableValues && field->is_stable() && field->type()->is_array_klass();
 476   int stable_dimension = (is_stable_array ? field->type()->as_array_klass()->dimension() : 0);
 477   bool is_narrow_oop = (loadbt == T_NARROWOOP);
 478 
 479   const Type* con_type = make_from_constant(con, /*require_constant=*/ true,
 480                                             stable_dimension, is_narrow_oop,
 481                                             field->is_autobox_cache());
 482   if (con_type != nullptr && field->is_call_site_target()) {
 483     ciCallSite* call_site = holder->as_call_site();
 484     if (!call_site->is_fully_initialized_constant_call_site()) {
 485       ciMethodHandle* target = con.as_object()->as_method_handle();
 486       Compile::current()->dependencies()->assert_call_site_target_value(call_site, target);
 487     }
 488   }
 489   return con_type;
 490 }
 491 
 492 //------------------------------make-------------------------------------------
 493 // Create a simple Type, with default empty symbol sets.  Then hashcons it
 494 // and look for an existing copy in the type dictionary.
 495 const Type *Type::make( enum TYPES t ) {
 496   return (new Type(t))->hashcons();
 497 }
 498 
 499 //------------------------------cmp--------------------------------------------
 500 bool Type::equals(const Type* t1, const Type* t2) {
 501   if (t1->_base != t2->_base) {
 502     return false; // Missed badly
 503   }
 504 
 505   assert(t1 != t2 || t1->eq(t2), "eq must be reflexive");
 506   return t1->eq(t2);
 507 }
 508 
 509 const Type* Type::maybe_remove_speculative(bool include_speculative) const {
 510   if (!include_speculative) {
 511     return remove_speculative();
 512   }
 513   return this;
 514 }
 515 
 516 //------------------------------hash-------------------------------------------
 517 int Type::uhash( const Type *const t ) {
 518   return (int)t->hash();
 519 }
 520 
 521 #define POSITIVE_INFINITE_F 0x7f800000 // hex representation for IEEE 754 single precision positive infinite
 522 #define POSITIVE_INFINITE_D 0x7ff0000000000000 // hex representation for IEEE 754 double precision positive infinite
 523 
 524 //--------------------------Initialize_shared----------------------------------
 525 void Type::Initialize_shared(Compile* current) {
 526   // This method does not need to be locked because the first system
 527   // compilations (stub compilations) occur serially.  If they are
 528   // changed to proceed in parallel, then this section will need
 529   // locking.
 530 
 531   Arena* save = current->type_arena();
 532   Arena* shared_type_arena = new (mtCompiler)Arena(mtCompiler, Arena::Tag::tag_type);
 533 
 534   current->set_type_arena(shared_type_arena);
 535 
 536   // Map the boolean result of Type::equals into a comparator result that CmpKey expects.
 537   CmpKey type_cmp = [](const void* t1, const void* t2) -> int32_t {
 538     return Type::equals((Type*) t1, (Type*) t2) ? 0 : 1;
 539   };
 540 
 541   _shared_type_dict = new (shared_type_arena) Dict(type_cmp, (Hash) Type::uhash, shared_type_arena, 128);
 542   current->set_type_dict(_shared_type_dict);
 543 
 544   // Make shared pre-built types.
 545   CONTROL = make(Control);      // Control only
 546   TOP     = make(Top);          // No values in set
 547   MEMORY  = make(Memory);       // Abstract store only
 548   ABIO    = make(Abio);         // State-of-machine only
 549   RETURN_ADDRESS=make(Return_Address);
 550   FLOAT   = make(FloatBot);     // All floats
 551   HALF_FLOAT = make(HalfFloatBot); // All half floats
 552   DOUBLE  = make(DoubleBot);    // All doubles
 553   BOTTOM  = make(Bottom);       // Everything
 554   HALF    = make(Half);         // Placeholder half of doublewide type
 555 
 556   TypeF::MAX = TypeF::make(max_jfloat); // Float MAX
 557   TypeF::MIN = TypeF::make(min_jfloat); // Float MIN
 558   TypeF::ZERO = TypeF::make(0.0); // Float 0 (positive zero)
 559   TypeF::ONE  = TypeF::make(1.0); // Float 1
 560   TypeF::POS_INF = TypeF::make(jfloat_cast(POSITIVE_INFINITE_F));
 561   TypeF::NEG_INF = TypeF::make(-jfloat_cast(POSITIVE_INFINITE_F));
 562 
 563   TypeH::MAX = TypeH::make(max_jfloat16); // HalfFloat MAX
 564   TypeH::MIN = TypeH::make(min_jfloat16); // HalfFloat MIN
 565   TypeH::ZERO = TypeH::make((jshort)0); // HalfFloat 0 (positive zero)
 566   TypeH::ONE  = TypeH::make(one_jfloat16); // HalfFloat 1
 567   TypeH::POS_INF = TypeH::make(pos_inf_jfloat16);
 568   TypeH::NEG_INF = TypeH::make(neg_inf_jfloat16);
 569 
 570   TypeD::MAX = TypeD::make(max_jdouble); // Double MAX
 571   TypeD::MIN = TypeD::make(min_jdouble); // Double MIN
 572   TypeD::ZERO = TypeD::make(0.0); // Double 0 (positive zero)
 573   TypeD::ONE  = TypeD::make(1.0); // Double 1
 574   TypeD::POS_INF = TypeD::make(jdouble_cast(POSITIVE_INFINITE_D));
 575   TypeD::NEG_INF = TypeD::make(-jdouble_cast(POSITIVE_INFINITE_D));
 576 
 577   TypeInt::MAX = TypeInt::make(max_jint); // Int MAX
 578   TypeInt::MIN = TypeInt::make(min_jint); // Int MIN
 579   TypeInt::MINUS_1  = TypeInt::make(-1);  // -1
 580   TypeInt::ZERO     = TypeInt::make( 0);  //  0
 581   TypeInt::ONE      = TypeInt::make( 1);  //  1
 582   TypeInt::BOOL     = TypeInt::make( 0, 1, WidenMin);  // 0 or 1, FALSE or TRUE.
 583   TypeInt::CC       = TypeInt::make(-1, 1, WidenMin);  // -1, 0 or 1, condition codes
 584   TypeInt::CC_LT    = TypeInt::make(-1,-1, WidenMin);  // == TypeInt::MINUS_1
 585   TypeInt::CC_GT    = TypeInt::make( 1, 1, WidenMin);  // == TypeInt::ONE
 586   TypeInt::CC_EQ    = TypeInt::make( 0, 0, WidenMin);  // == TypeInt::ZERO
 587   TypeInt::CC_NE    = TypeInt::make_or_top(TypeIntPrototype<jint, juint>{{-1, 1}, {1, max_juint}, {0, 1}}, WidenMin)->is_int();
 588   TypeInt::CC_LE    = TypeInt::make(-1, 0, WidenMin);
 589   TypeInt::CC_GE    = TypeInt::make( 0, 1, WidenMin);  // == TypeInt::BOOL
 590   TypeInt::BYTE     = TypeInt::make(-128, 127,     WidenMin); // Bytes
 591   TypeInt::UBYTE    = TypeInt::make(0, 255,        WidenMin); // Unsigned Bytes
 592   TypeInt::CHAR     = TypeInt::make(0, 65535,      WidenMin); // Java chars
 593   TypeInt::SHORT    = TypeInt::make(-32768, 32767, WidenMin); // Java shorts
 594   TypeInt::NON_ZERO = TypeInt::make_or_top(TypeIntPrototype<jint, juint>{{min_jint, max_jint}, {1, max_juint}, {0, 0}}, WidenMin)->is_int();
 595   TypeInt::POS      = TypeInt::make(0, max_jint,   WidenMin); // Non-neg values
 596   TypeInt::POS1     = TypeInt::make(1, max_jint,   WidenMin); // Positive values
 597   TypeInt::INT      = TypeInt::make(min_jint, max_jint, WidenMax); // 32-bit integers
 598   TypeInt::SYMINT   = TypeInt::make(-max_jint, max_jint, WidenMin); // symmetric range
 599   TypeInt::TYPE_DOMAIN = TypeInt::INT;
 600   // CmpL is overloaded both as the bytecode computation returning
 601   // a trinary (-1, 0, +1) integer result AND as an efficient long
 602   // compare returning optimizer ideal-type flags.
 603   assert(TypeInt::CC_LT == TypeInt::MINUS_1, "types must match for CmpL to work" );
 604   assert(TypeInt::CC_GT == TypeInt::ONE,     "types must match for CmpL to work" );
 605   assert(TypeInt::CC_EQ == TypeInt::ZERO,    "types must match for CmpL to work" );
 606   assert(TypeInt::CC_GE == TypeInt::BOOL,    "types must match for CmpL to work" );
 607 
 608   TypeLong::MAX = TypeLong::make(max_jlong); // Long MAX
 609   TypeLong::MIN = TypeLong::make(min_jlong); // Long MIN
 610   TypeLong::MINUS_1  = TypeLong::make(-1);   // -1
 611   TypeLong::ZERO     = TypeLong::make( 0);   //  0
 612   TypeLong::ONE      = TypeLong::make( 1);   //  1
 613   TypeLong::NON_ZERO = TypeLong::make_or_top(TypeIntPrototype<jlong, julong>{{min_jlong, max_jlong}, {1, max_julong}, {0, 0}}, WidenMin)->is_long();
 614   TypeLong::POS      = TypeLong::make(0, max_jlong, WidenMin); // Non-neg values
 615   TypeLong::NEG      = TypeLong::make(min_jlong, -1, WidenMin);
 616   TypeLong::LONG     = TypeLong::make(min_jlong, max_jlong, WidenMax); // 64-bit integers
 617   TypeLong::INT      = TypeLong::make((jlong)min_jint, (jlong)max_jint,WidenMin);
 618   TypeLong::UINT     = TypeLong::make(0, (jlong)max_juint, WidenMin);
 619   TypeLong::TYPE_DOMAIN = TypeLong::LONG;
 620 
 621   const Type **fboth =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 622   fboth[0] = Type::CONTROL;
 623   fboth[1] = Type::CONTROL;
 624   TypeTuple::IFBOTH = TypeTuple::make( 2, fboth );
 625 
 626   const Type **ffalse =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 627   ffalse[0] = Type::CONTROL;
 628   ffalse[1] = Type::TOP;
 629   TypeTuple::IFFALSE = TypeTuple::make( 2, ffalse );
 630 
 631   const Type **fneither =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 632   fneither[0] = Type::TOP;
 633   fneither[1] = Type::TOP;
 634   TypeTuple::IFNEITHER = TypeTuple::make( 2, fneither );
 635 
 636   const Type **ftrue =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 637   ftrue[0] = Type::TOP;
 638   ftrue[1] = Type::CONTROL;
 639   TypeTuple::IFTRUE = TypeTuple::make( 2, ftrue );
 640 
 641   const Type **floop =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 642   floop[0] = Type::CONTROL;
 643   floop[1] = TypeInt::INT;
 644   TypeTuple::LOOPBODY = TypeTuple::make( 2, floop );
 645 
 646   TypePtr::NULL_PTR= TypePtr::make(AnyPtr, TypePtr::Null, Offset(0));
 647   TypePtr::NOTNULL = TypePtr::make(AnyPtr, TypePtr::NotNull, Offset::bottom);
 648   TypePtr::BOTTOM  = TypePtr::make(AnyPtr, TypePtr::BotPTR, Offset::bottom);
 649 
 650   TypeRawPtr::BOTTOM = TypeRawPtr::make( TypePtr::BotPTR );
 651   TypeRawPtr::NOTNULL= TypeRawPtr::make( TypePtr::NotNull );
 652 
 653   const Type **fmembar = TypeTuple::fields(0);
 654   TypeTuple::MEMBAR = TypeTuple::make(TypeFunc::Parms+0, fmembar);
 655 
 656   const Type **fsc = (const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*));
 657   fsc[0] = TypeInt::CC;
 658   fsc[1] = Type::MEMORY;
 659   TypeTuple::STORECONDITIONAL = TypeTuple::make(2, fsc);
 660 
 661   TypeInstPtr::NOTNULL = TypeInstPtr::make(TypePtr::NotNull, current->env()->Object_klass());
 662   TypeInstPtr::BOTTOM  = TypeInstPtr::make(TypePtr::BotPTR,  current->env()->Object_klass());
 663   TypeInstPtr::MIRROR  = TypeInstPtr::make(TypePtr::NotNull, current->env()->Class_klass());
 664   TypeInstPtr::MARK    = TypeInstPtr::make(TypePtr::BotPTR,  current->env()->Object_klass(),
 665                                            false, nullptr, Offset(oopDesc::mark_offset_in_bytes()));
 666   TypeInstPtr::KLASS   = TypeInstPtr::make(TypePtr::BotPTR,  current->env()->Object_klass(),
 667                                            false, nullptr, Offset(oopDesc::klass_offset_in_bytes()));
 668   TypeOopPtr::BOTTOM  = TypeOopPtr::make(TypePtr::BotPTR, Offset::bottom, TypeOopPtr::InstanceBot);
 669 
 670   TypeMetadataPtr::BOTTOM = TypeMetadataPtr::make(TypePtr::BotPTR, nullptr, Offset::bottom);
 671 
 672   TypeNarrowOop::NULL_PTR = TypeNarrowOop::make( TypePtr::NULL_PTR );
 673   TypeNarrowOop::BOTTOM   = TypeNarrowOop::make( TypeInstPtr::BOTTOM );
 674 
 675   TypeNarrowKlass::NULL_PTR = TypeNarrowKlass::make( TypePtr::NULL_PTR );
 676 
 677   mreg2type[Op_Node] = Type::BOTTOM;
 678   mreg2type[Op_Set ] = nullptr;
 679   mreg2type[Op_RegN] = TypeNarrowOop::BOTTOM;
 680   mreg2type[Op_RegI] = TypeInt::INT;
 681   mreg2type[Op_RegP] = TypePtr::BOTTOM;
 682   mreg2type[Op_RegF] = Type::FLOAT;
 683   mreg2type[Op_RegD] = Type::DOUBLE;
 684   mreg2type[Op_RegL] = TypeLong::LONG;
 685   mreg2type[Op_RegFlags] = TypeInt::CC;
 686 
 687   GrowableArray<ciInstanceKlass*> array_interfaces;
 688   array_interfaces.push(current->env()->Cloneable_klass());
 689   array_interfaces.push(current->env()->Serializable_klass());
 690   TypeAryPtr::_array_interfaces = TypeInterfaces::make(&array_interfaces);
 691   TypeAryKlassPtr::_array_interfaces = TypeAryPtr::_array_interfaces;
 692 
 693   TypeAryPtr::BOTTOM = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::BOTTOM, TypeInt::POS, false, false, false, false, false), nullptr, false, Offset::bottom);
 694   TypeAryPtr::RANGE   = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::BOTTOM,TypeInt::POS, false, false, false, false, false), nullptr /* current->env()->Object_klass() */, false, Offset(arrayOopDesc::length_offset_in_bytes()));
 695 
 696   TypeAryPtr::NARROWOOPS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeNarrowOop::BOTTOM, TypeInt::POS, false, false, false, false, false), nullptr /*ciArrayKlass::make(o)*/,  false,  Offset::bottom);
 697 
 698 #ifdef _LP64
 699   if (UseCompressedOops) {
 700     assert(TypeAryPtr::NARROWOOPS->is_ptr_to_narrowoop(), "array of narrow oops must be ptr to narrow oop");
 701     TypeAryPtr::OOPS  = TypeAryPtr::NARROWOOPS;
 702   } else
 703 #endif
 704   {
 705     // There is no shared klass for Object[].  See note in TypeAryPtr::klass().
 706     TypeAryPtr::OOPS  = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInstPtr::BOTTOM,TypeInt::POS, false, false, false, false, false), nullptr /*ciArrayKlass::make(o)*/,  false,  Offset::bottom);
 707   }
 708   TypeAryPtr::BYTES   = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::BYTE      ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_BYTE),   true,  Offset::bottom);
 709   TypeAryPtr::SHORTS  = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::SHORT     ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_SHORT),  true,  Offset::bottom);
 710   TypeAryPtr::CHARS   = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::CHAR      ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_CHAR),   true,  Offset::bottom);
 711   TypeAryPtr::INTS    = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::INT       ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_INT),    true,  Offset::bottom);
 712   TypeAryPtr::LONGS   = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeLong::LONG     ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_LONG),   true,  Offset::bottom);
 713   TypeAryPtr::FLOATS  = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::FLOAT        ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_FLOAT),  true,  Offset::bottom);
 714   TypeAryPtr::DOUBLES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::DOUBLE       ,TypeInt::POS, false, false, true, true, true), ciTypeArrayKlass::make(T_DOUBLE), true,  Offset::bottom);
 715   TypeAryPtr::INLINES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInstPtr::BOTTOM,TypeInt::POS, /* stable= */ false, /* flat= */ true, false, false, false), nullptr, false, Offset::bottom);
 716 
 717   // Nobody should ask _array_body_type[T_NARROWOOP]. Use null as assert.
 718   TypeAryPtr::_array_body_type[T_NARROWOOP] = nullptr;
 719   TypeAryPtr::_array_body_type[T_OBJECT]  = TypeAryPtr::OOPS;
 720   TypeAryPtr::_array_body_type[T_FLAT_ELEMENT] = TypeAryPtr::OOPS;
 721   TypeAryPtr::_array_body_type[T_ARRAY]   = TypeAryPtr::OOPS; // arrays are stored in oop arrays
 722   TypeAryPtr::_array_body_type[T_BYTE]    = TypeAryPtr::BYTES;
 723   TypeAryPtr::_array_body_type[T_BOOLEAN] = TypeAryPtr::BYTES;  // boolean[] is a byte array
 724   TypeAryPtr::_array_body_type[T_SHORT]   = TypeAryPtr::SHORTS;
 725   TypeAryPtr::_array_body_type[T_CHAR]    = TypeAryPtr::CHARS;
 726   TypeAryPtr::_array_body_type[T_INT]     = TypeAryPtr::INTS;
 727   TypeAryPtr::_array_body_type[T_LONG]    = TypeAryPtr::LONGS;
 728   TypeAryPtr::_array_body_type[T_FLOAT]   = TypeAryPtr::FLOATS;
 729   TypeAryPtr::_array_body_type[T_DOUBLE]  = TypeAryPtr::DOUBLES;
 730 
 731   TypeInstKlassPtr::OBJECT = TypeInstKlassPtr::make(TypePtr::NotNull, current->env()->Object_klass(), Offset(0));
 732   TypeInstKlassPtr::OBJECT_OR_NULL = TypeInstKlassPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), Offset(0));
 733 
 734   const Type **fi2c = TypeTuple::fields(2);
 735   fi2c[TypeFunc::Parms+0] = TypeInstPtr::BOTTOM; // Method*
 736   fi2c[TypeFunc::Parms+1] = TypeRawPtr::BOTTOM; // argument pointer
 737   TypeTuple::START_I2C = TypeTuple::make(TypeFunc::Parms+2, fi2c);
 738 
 739   const Type **intpair = TypeTuple::fields(2);
 740   intpair[0] = TypeInt::INT;
 741   intpair[1] = TypeInt::INT;
 742   TypeTuple::INT_PAIR = TypeTuple::make(2, intpair);
 743 
 744   const Type **longpair = TypeTuple::fields(2);
 745   longpair[0] = TypeLong::LONG;
 746   longpair[1] = TypeLong::LONG;
 747   TypeTuple::LONG_PAIR = TypeTuple::make(2, longpair);
 748 
 749   const Type **intccpair = TypeTuple::fields(2);
 750   intccpair[0] = TypeInt::INT;
 751   intccpair[1] = TypeInt::CC;
 752   TypeTuple::INT_CC_PAIR = TypeTuple::make(2, intccpair);
 753 
 754   const Type **longccpair = TypeTuple::fields(2);
 755   longccpair[0] = TypeLong::LONG;
 756   longccpair[1] = TypeInt::CC;
 757   TypeTuple::LONG_CC_PAIR = TypeTuple::make(2, longccpair);
 758 
 759   _const_basic_type[T_NARROWOOP]   = TypeNarrowOop::BOTTOM;
 760   _const_basic_type[T_NARROWKLASS] = Type::BOTTOM;
 761   _const_basic_type[T_BOOLEAN]     = TypeInt::BOOL;
 762   _const_basic_type[T_CHAR]        = TypeInt::CHAR;
 763   _const_basic_type[T_BYTE]        = TypeInt::BYTE;
 764   _const_basic_type[T_SHORT]       = TypeInt::SHORT;
 765   _const_basic_type[T_INT]         = TypeInt::INT;
 766   _const_basic_type[T_LONG]        = TypeLong::LONG;
 767   _const_basic_type[T_FLOAT]       = Type::FLOAT;
 768   _const_basic_type[T_DOUBLE]      = Type::DOUBLE;
 769   _const_basic_type[T_OBJECT]      = TypeInstPtr::BOTTOM;
 770   _const_basic_type[T_ARRAY]       = TypeInstPtr::BOTTOM; // there is no separate bottom for arrays
 771   _const_basic_type[T_FLAT_ELEMENT] = TypeInstPtr::BOTTOM;
 772   _const_basic_type[T_VOID]        = TypePtr::NULL_PTR;   // reflection represents void this way
 773   _const_basic_type[T_ADDRESS]     = TypeRawPtr::BOTTOM;  // both interpreter return addresses & random raw ptrs
 774   _const_basic_type[T_CONFLICT]    = Type::BOTTOM;        // why not?
 775 
 776   _zero_type[T_NARROWOOP]   = TypeNarrowOop::NULL_PTR;
 777   _zero_type[T_NARROWKLASS] = TypeNarrowKlass::NULL_PTR;
 778   _zero_type[T_BOOLEAN]     = TypeInt::ZERO;     // false == 0
 779   _zero_type[T_CHAR]        = TypeInt::ZERO;     // '\0' == 0
 780   _zero_type[T_BYTE]        = TypeInt::ZERO;     // 0x00 == 0
 781   _zero_type[T_SHORT]       = TypeInt::ZERO;     // 0x0000 == 0
 782   _zero_type[T_INT]         = TypeInt::ZERO;
 783   _zero_type[T_LONG]        = TypeLong::ZERO;
 784   _zero_type[T_FLOAT]       = TypeF::ZERO;
 785   _zero_type[T_DOUBLE]      = TypeD::ZERO;
 786   _zero_type[T_OBJECT]      = TypePtr::NULL_PTR;
 787   _zero_type[T_ARRAY]       = TypePtr::NULL_PTR; // null array is null oop
 788   _zero_type[T_FLAT_ELEMENT] = TypePtr::NULL_PTR;
 789   _zero_type[T_ADDRESS]     = TypePtr::NULL_PTR; // raw pointers use the same null
 790   _zero_type[T_VOID]        = Type::TOP;         // the only void value is no value at all
 791 
 792   // get_zero_type() should not happen for T_CONFLICT
 793   _zero_type[T_CONFLICT]= nullptr;
 794 
 795   TypeVect::VECTMASK = (TypeVect*)(new TypePVectMask(T_BOOLEAN, MaxVectorSize))->hashcons();
 796   mreg2type[Op_RegVectMask] = TypeVect::VECTMASK;
 797 
 798   if (Matcher::supports_scalable_vector()) {
 799     TypeVect::VECTA = TypeVect::make(T_BYTE, Matcher::scalable_vector_reg_size(T_BYTE));
 800   }
 801 
 802   // Vector predefined types, it needs initialized _const_basic_type[].
 803   if (Matcher::vector_size_supported(T_BYTE, 4)) {
 804     TypeVect::VECTS = TypeVect::make(T_BYTE, 4);
 805   }
 806   if (Matcher::vector_size_supported(T_FLOAT, 2)) {
 807     TypeVect::VECTD = TypeVect::make(T_FLOAT, 2);
 808   }
 809   if (Matcher::vector_size_supported(T_FLOAT, 4)) {
 810     TypeVect::VECTX = TypeVect::make(T_FLOAT, 4);
 811   }
 812   if (Matcher::vector_size_supported(T_FLOAT, 8)) {
 813     TypeVect::VECTY = TypeVect::make(T_FLOAT, 8);
 814   }
 815   if (Matcher::vector_size_supported(T_FLOAT, 16)) {
 816     TypeVect::VECTZ = TypeVect::make(T_FLOAT, 16);
 817   }
 818 
 819   mreg2type[Op_VecA] = TypeVect::VECTA;
 820   mreg2type[Op_VecS] = TypeVect::VECTS;
 821   mreg2type[Op_VecD] = TypeVect::VECTD;
 822   mreg2type[Op_VecX] = TypeVect::VECTX;
 823   mreg2type[Op_VecY] = TypeVect::VECTY;
 824   mreg2type[Op_VecZ] = TypeVect::VECTZ;
 825 
 826   BarrierSetC2::make_clone_type();
 827   LockNode::initialize_lock_Type();
 828   ArrayCopyNode::initialize_arraycopy_Type();
 829   OptoRuntime::initialize_types();
 830 
 831   // Restore working type arena.
 832   current->set_type_arena(save);
 833   current->set_type_dict(nullptr);
 834 }
 835 
 836 //------------------------------Initialize-------------------------------------
 837 void Type::Initialize(Compile* current) {
 838   assert(current->type_arena() != nullptr, "must have created type arena");
 839 
 840   if (_shared_type_dict == nullptr) {
 841     Initialize_shared(current);
 842   }
 843 
 844   Arena* type_arena = current->type_arena();
 845 
 846   // Create the hash-cons'ing dictionary with top-level storage allocation
 847   Dict *tdic = new (type_arena) Dict(*_shared_type_dict, type_arena);
 848   current->set_type_dict(tdic);
 849 }
 850 
 851 //------------------------------hashcons---------------------------------------
 852 // Do the hash-cons trick.  If the Type already exists in the type table,
 853 // delete the current Type and return the existing Type.  Otherwise stick the
 854 // current Type in the Type table.
 855 const Type *Type::hashcons(void) {
 856   DEBUG_ONLY(base());           // Check the assertion in Type::base().
 857   // Look up the Type in the Type dictionary
 858   Dict *tdic = type_dict();
 859   Type* old = (Type*)(tdic->Insert(this, this, false));
 860   if( old ) {                   // Pre-existing Type?
 861     if( old != this )           // Yes, this guy is not the pre-existing?
 862       delete this;              // Yes, Nuke this guy
 863     assert( old->_dual, "" );
 864     return old;                 // Return pre-existing
 865   }
 866 
 867   // Every type has a dual (to make my lattice symmetric).
 868   // Since we just discovered a new Type, compute its dual right now.
 869   assert( !_dual, "" );         // No dual yet
 870   _dual = xdual();              // Compute the dual
 871   if (equals(this, _dual)) {    // Handle self-symmetric
 872     if (_dual != this) {
 873       delete _dual;
 874       _dual = this;
 875     }
 876     return this;
 877   }
 878   assert( !_dual->_dual, "" );  // No reverse dual yet
 879   assert( !(*tdic)[_dual], "" ); // Dual not in type system either
 880   // New Type, insert into Type table
 881   tdic->Insert((void*)_dual,(void*)_dual);
 882   ((Type*)_dual)->_dual = this; // Finish up being symmetric
 883 #ifdef ASSERT
 884   Type *dual_dual = (Type*)_dual->xdual();
 885   assert( eq(dual_dual), "xdual(xdual()) should be identity" );
 886   delete dual_dual;
 887 #endif
 888   return this;                  // Return new Type
 889 }
 890 
 891 //------------------------------eq---------------------------------------------
 892 // Structural equality check for Type representations
 893 bool Type::eq( const Type * ) const {
 894   return true;                  // Nothing else can go wrong
 895 }
 896 
 897 //------------------------------hash-------------------------------------------
 898 // Type-specific hashing function.
 899 uint Type::hash(void) const {
 900   return _base;
 901 }
 902 
 903 //------------------------------is_finite--------------------------------------
 904 // Has a finite value
 905 bool Type::is_finite() const {
 906   return false;
 907 }
 908 
 909 //------------------------------is_nan-----------------------------------------
 910 // Is not a number (NaN)
 911 bool Type::is_nan()    const {
 912   return false;
 913 }
 914 
 915 #ifdef ASSERT
 916 class VerifyMeet;
 917 class VerifyMeetResult : public ArenaObj {
 918   friend class VerifyMeet;
 919   friend class Type;
 920 private:
 921   class VerifyMeetResultEntry {
 922   private:
 923     const Type* _in1;
 924     const Type* _in2;
 925     const Type* _res;
 926   public:
 927     VerifyMeetResultEntry(const Type* in1, const Type* in2, const Type* res):
 928             _in1(in1), _in2(in2), _res(res) {
 929     }
 930     VerifyMeetResultEntry():
 931             _in1(nullptr), _in2(nullptr), _res(nullptr) {
 932     }
 933 
 934     bool operator==(const VerifyMeetResultEntry& rhs) const {
 935       return _in1 == rhs._in1 &&
 936              _in2 == rhs._in2 &&
 937              _res == rhs._res;
 938     }
 939 
 940     bool operator!=(const VerifyMeetResultEntry& rhs) const {
 941       return !(rhs == *this);
 942     }
 943 
 944     static int compare(const VerifyMeetResultEntry& v1, const VerifyMeetResultEntry& v2) {
 945       if ((intptr_t) v1._in1 < (intptr_t) v2._in1) {
 946         return -1;
 947       } else if (v1._in1 == v2._in1) {
 948         if ((intptr_t) v1._in2 < (intptr_t) v2._in2) {
 949           return -1;
 950         } else if (v1._in2 == v2._in2) {
 951           assert(v1._res == v2._res || v1._res == nullptr || v2._res == nullptr, "same inputs should lead to same result");
 952           return 0;
 953         }
 954         return 1;
 955       }
 956       return 1;
 957     }
 958     const Type* res() const { return _res; }
 959   };
 960   uint _depth;
 961   GrowableArray<VerifyMeetResultEntry> _cache;
 962 
 963   // With verification code, the meet of A and B causes the computation of:
 964   // 1- meet(A, B)
 965   // 2- meet(B, A)
 966   // 3- meet(dual(meet(A, B)), dual(A))
 967   // 4- meet(dual(meet(A, B)), dual(B))
 968   // 5- meet(dual(A), dual(B))
 969   // 6- meet(dual(B), dual(A))
 970   // 7- meet(dual(meet(dual(A), dual(B))), A)
 971   // 8- meet(dual(meet(dual(A), dual(B))), B)
 972   //
 973   // In addition the meet of A[] and B[] requires the computation of the meet of A and B.
 974   //
 975   // The meet of A[] and B[] triggers the computation of:
 976   // 1- meet(A[], B[][)
 977   //   1.1- meet(A, B)
 978   //   1.2- meet(B, A)
 979   //   1.3- meet(dual(meet(A, B)), dual(A))
 980   //   1.4- meet(dual(meet(A, B)), dual(B))
 981   //   1.5- meet(dual(A), dual(B))
 982   //   1.6- meet(dual(B), dual(A))
 983   //   1.7- meet(dual(meet(dual(A), dual(B))), A)
 984   //   1.8- meet(dual(meet(dual(A), dual(B))), B)
 985   // 2- meet(B[], A[])
 986   //   2.1- meet(B, A) = 1.2
 987   //   2.2- meet(A, B) = 1.1
 988   //   2.3- meet(dual(meet(B, A)), dual(B)) = 1.4
 989   //   2.4- meet(dual(meet(B, A)), dual(A)) = 1.3
 990   //   2.5- meet(dual(B), dual(A)) = 1.6
 991   //   2.6- meet(dual(A), dual(B)) = 1.5
 992   //   2.7- meet(dual(meet(dual(B), dual(A))), B) = 1.8
 993   //   2.8- meet(dual(meet(dual(B), dual(A))), B) = 1.7
 994   // etc.
 995   // The number of meet operations performed grows exponentially with the number of dimensions of the arrays but the number
 996   // of different meet operations is linear in the number of dimensions. The function below caches meet results for the
 997   // duration of the meet at the root of the recursive calls.
 998   //
 999   const Type* meet(const Type* t1, const Type* t2) {
1000     bool found = false;
1001     const VerifyMeetResultEntry meet(t1, t2, nullptr);
1002     int pos = _cache.find_sorted<VerifyMeetResultEntry, VerifyMeetResultEntry::compare>(meet, found);
1003     const Type* res = nullptr;
1004     if (found) {
1005       res = _cache.at(pos).res();
1006     } else {
1007       res = t1->xmeet(t2);
1008       _cache.insert_sorted<VerifyMeetResultEntry::compare>(VerifyMeetResultEntry(t1, t2, res));
1009       found = false;
1010       _cache.find_sorted<VerifyMeetResultEntry, VerifyMeetResultEntry::compare>(meet, found);
1011       assert(found, "should be in table after it's added");
1012     }
1013     return res;
1014   }
1015 
1016   void add(const Type* t1, const Type* t2, const Type* res) {
1017     _cache.insert_sorted<VerifyMeetResultEntry::compare>(VerifyMeetResultEntry(t1, t2, res));
1018   }
1019 
1020   bool empty_cache() const {
1021     return _cache.length() == 0;
1022   }
1023 public:
1024   VerifyMeetResult(Compile* C) :
1025           _depth(0), _cache(C->comp_arena(), 2, 0, VerifyMeetResultEntry()) {
1026   }
1027 };
1028 
1029 void Type::assert_type_verify_empty() const {
1030   assert(Compile::current()->_type_verify == nullptr || Compile::current()->_type_verify->empty_cache(), "cache should have been discarded");
1031 }
1032 
1033 class VerifyMeet {
1034 private:
1035   Compile* _C;
1036 public:
1037   VerifyMeet(Compile* C) : _C(C) {
1038     if (C->_type_verify == nullptr) {
1039       C->_type_verify = new (C->comp_arena())VerifyMeetResult(C);
1040     }
1041     _C->_type_verify->_depth++;
1042   }
1043 
1044   ~VerifyMeet() {
1045     assert(_C->_type_verify->_depth != 0, "");
1046     _C->_type_verify->_depth--;
1047     if (_C->_type_verify->_depth == 0) {
1048       _C->_type_verify->_cache.trunc_to(0);
1049     }
1050   }
1051 
1052   const Type* meet(const Type* t1, const Type* t2) const {
1053     return _C->_type_verify->meet(t1, t2);
1054   }
1055 
1056   void add(const Type* t1, const Type* t2, const Type* res) const {
1057     _C->_type_verify->add(t1, t2, res);
1058   }
1059 };
1060 
1061 void Type::check_symmetrical(const Type* t, const Type* mt, const VerifyMeet& verify) const {
1062   Compile* C = Compile::current();
1063   const Type* mt2 = verify.meet(t, this);
1064 
1065   // Verify that:
1066   //      this meet t == t meet this
1067   if (mt != mt2) {
1068     tty->print_cr("=== Meet Not Commutative ===");
1069     tty->print("t           = ");   t->dump(); tty->cr();
1070     tty->print("this        = ");      dump(); tty->cr();
1071     tty->print("t meet this = "); mt2->dump(); tty->cr();
1072     tty->print("this meet t = ");  mt->dump(); tty->cr();
1073     fatal("meet not commutative");
1074   }
1075   const Type* dual_join = mt->_dual;
1076   const Type* t2t    = verify.meet(dual_join,t->_dual);
1077   const Type* t2this = verify.meet(dual_join,this->_dual);
1078 
1079   // Interface meet Oop is Not Symmetric:
1080   // Interface:AnyNull meet Oop:AnyNull == Interface:AnyNull
1081   // Interface:NotNull meet Oop:NotNull == java/lang/Object:NotNull
1082 
1083   // Verify that:
1084   // 1)     mt_dual meet t_dual    == t_dual
1085   //    which corresponds to
1086   //       !(t meet this)  meet !t ==
1087   //       (!t join !this) meet !t == !t
1088   // 2)    mt_dual meet this_dual     == this_dual
1089   //    which corresponds to
1090   //       !(t meet this)  meet !this ==
1091   //       (!t join !this) meet !this == !this
1092   if (t2t != t->_dual || t2this != this->_dual) {
1093     tty->print_cr("=== Meet Not Symmetric ===");
1094     tty->print("t   =                   ");              t->dump(); tty->cr();
1095     tty->print("this=                   ");                 dump(); tty->cr();
1096     tty->print("mt=(t meet this)=       ");             mt->dump(); tty->cr();
1097 
1098     tty->print("t_dual=                 ");       t->_dual->dump(); tty->cr();
1099     tty->print("this_dual=              ");          _dual->dump(); tty->cr();
1100     tty->print("mt_dual=                ");      mt->_dual->dump(); tty->cr();
1101 
1102     // 1)
1103     tty->print("mt_dual meet t_dual=    "); t2t           ->dump(); tty->cr();
1104     // 2)
1105     tty->print("mt_dual meet this_dual= "); t2this        ->dump(); tty->cr();
1106     tty->cr();
1107     tty->print_cr("Fail: ");
1108     if (t2t != t->_dual) {
1109       tty->print_cr("- mt_dual meet t_dual != t_dual");
1110     }
1111     if (t2this != this->_dual) {
1112       tty->print_cr("- mt_dual meet this_dual != this_dual");
1113     }
1114     tty->cr();
1115 
1116     fatal("meet not symmetric");
1117   }
1118 }
1119 #endif
1120 
1121 //------------------------------meet-------------------------------------------
1122 // Compute the MEET of two types.  NOT virtual.  It enforces that meet is
1123 // commutative and the lattice is symmetric.
1124 const Type *Type::meet_helper(const Type *t, bool include_speculative) const {
1125   if (isa_narrowoop() && t->isa_narrowoop()) {
1126     const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative);
1127     return result->make_narrowoop();
1128   }
1129   if (isa_narrowklass() && t->isa_narrowklass()) {
1130     const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative);
1131     return result->make_narrowklass();
1132   }
1133 
1134 #ifdef ASSERT
1135   Compile* C = Compile::current();
1136   VerifyMeet verify(C);
1137 #endif
1138 
1139   const Type *this_t = maybe_remove_speculative(include_speculative);
1140   t = t->maybe_remove_speculative(include_speculative);
1141 
1142   const Type *mt = this_t->xmeet(t);
1143 #ifdef ASSERT
1144   verify.add(this_t, t, mt);
1145   if (isa_narrowoop() || t->isa_narrowoop()) {
1146     return mt;
1147   }
1148   if (isa_narrowklass() || t->isa_narrowklass()) {
1149     return mt;
1150   }
1151   // TODO 8387653 This currently triggers a verification failure, the code around "// Even though MyValue is final" needs adjustments
1152   if ((this_t->isa_ptr() && this_t->is_ptr()->is_not_flat()) ||
1153       (this_t->_dual->isa_ptr() && this_t->_dual->is_ptr()->is_not_flat())) return mt;
1154   this_t->check_symmetrical(t, mt, verify);
1155   const Type *mt_dual = verify.meet(this_t->_dual, t->_dual);
1156   this_t->_dual->check_symmetrical(t->_dual, mt_dual, verify);
1157 #endif
1158   return mt;
1159 }
1160 
1161 //------------------------------xmeet------------------------------------------
1162 // Compute the MEET of two types.  It returns a new Type object.
1163 const Type *Type::xmeet( const Type *t ) const {
1164   // Perform a fast test for common case; meeting the same types together.
1165   if( this == t ) return this;  // Meeting same type-rep?
1166 
1167   // Meeting TOP with anything?
1168   if( _base == Top ) return t;
1169 
1170   // Meeting BOTTOM with anything?
1171   if( _base == Bottom ) return BOTTOM;
1172 
1173   // Current "this->_base" is one of: Bad, Multi, Control, Top,
1174   // Abio, Abstore, Floatxxx, Doublexxx, Bottom, lastype.
1175   switch (t->base()) {  // Switch on original type
1176 
1177   // Cut in half the number of cases I must handle.  Only need cases for when
1178   // the given enum "t->type" is less than or equal to the local enum "type".
1179   case HalfFloatCon:
1180   case FloatCon:
1181   case DoubleCon:
1182   case Int:
1183   case Long:
1184     return t->xmeet(this);
1185 
1186   case OopPtr:
1187     return t->xmeet(this);
1188 
1189   case InstPtr:
1190     return t->xmeet(this);
1191 
1192   case MetadataPtr:
1193   case KlassPtr:
1194   case InstKlassPtr:
1195   case AryKlassPtr:
1196     return t->xmeet(this);
1197 
1198   case AryPtr:
1199     return t->xmeet(this);
1200 
1201   case NarrowOop:
1202     return t->xmeet(this);
1203 
1204   case NarrowKlass:
1205     return t->xmeet(this);
1206 
1207   case Bad:                     // Type check
1208   default:                      // Bogus type not in lattice
1209     typerr(t);
1210     return Type::BOTTOM;
1211 
1212   case Bottom:                  // Ye Olde Default
1213     return t;
1214 
1215   case HalfFloatTop:
1216     if (_base == HalfFloatTop) { return this; }
1217   case HalfFloatBot:            // Half Float
1218     if (_base == HalfFloatBot || _base == HalfFloatTop) { return HALF_FLOAT; }
1219     if (_base == FloatBot || _base == FloatTop) { return Type::BOTTOM; }
1220     if (_base == DoubleTop || _base == DoubleBot) { return Type::BOTTOM; }
1221     typerr(t);
1222     return Type::BOTTOM;
1223 
1224   case FloatTop:
1225     if (_base == FloatTop ) { return this; }
1226   case FloatBot:                // Float
1227     if (_base == FloatBot || _base == FloatTop) { return FLOAT; }
1228     if (_base == HalfFloatTop || _base == HalfFloatBot) { return Type::BOTTOM; }
1229     if (_base == DoubleTop || _base == DoubleBot) { return Type::BOTTOM; }
1230     typerr(t);
1231     return Type::BOTTOM;
1232 
1233   case DoubleTop:
1234     if (_base == DoubleTop) { return this; }
1235   case DoubleBot:               // Double
1236     if (_base == DoubleBot || _base == DoubleTop) { return DOUBLE; }
1237     if (_base == HalfFloatTop || _base == HalfFloatBot) { return Type::BOTTOM; }
1238     if (_base == FloatTop || _base == FloatBot) { return Type::BOTTOM; }
1239     typerr(t);
1240     return Type::BOTTOM;
1241 
1242   // These next few cases must match exactly or it is a compile-time error.
1243   case Control:                 // Control of code
1244   case Abio:                    // State of world outside of program
1245   case Memory:
1246     if (_base == t->_base)  { return this; }
1247     typerr(t);
1248     return Type::BOTTOM;
1249 
1250   case Top:                     // Top of the lattice
1251     return this;
1252   }
1253 
1254   // The type is unchanged
1255   return this;
1256 }
1257 
1258 //-----------------------------filter------------------------------------------
1259 const Type *Type::filter_helper(const Type *kills, bool include_speculative) const {
1260   const Type* ft = join_helper(kills, include_speculative);
1261   if (ft->empty())
1262     return Type::TOP;           // Canonical empty value
1263   return ft;
1264 }
1265 
1266 //------------------------------xdual------------------------------------------
1267 const Type *Type::xdual() const {
1268   // Note: the base() accessor asserts the sanity of _base.
1269   assert(_type_info[base()].dual_type != Bad, "implement with v-call");
1270   return new Type(_type_info[_base].dual_type);
1271 }
1272 
1273 //------------------------------has_memory-------------------------------------
1274 bool Type::has_memory() const {
1275   Type::TYPES tx = base();
1276   if (tx == Memory) return true;
1277   if (tx == Tuple) {
1278     const TypeTuple *t = is_tuple();
1279     for (uint i=0; i < t->cnt(); i++) {
1280       tx = t->field_at(i)->base();
1281       if (tx == Memory)  return true;
1282     }
1283   }
1284   return false;
1285 }
1286 
1287 #ifndef PRODUCT
1288 //------------------------------dump2------------------------------------------
1289 void Type::dump2( Dict &d, uint depth, outputStream *st ) const {
1290   st->print("%s", _type_info[_base].msg);
1291 }
1292 
1293 //------------------------------dump-------------------------------------------
1294 void Type::dump_on(outputStream *st) const {
1295   ResourceMark rm;
1296   Dict d(cmpkey,hashkey);       // Stop recursive type dumping
1297   dump2(d,1, st);
1298   if (is_ptr_to_narrowoop()) {
1299     st->print(" [narrow]");
1300   } else if (is_ptr_to_narrowklass()) {
1301     st->print(" [narrowklass]");
1302   }
1303 }
1304 
1305 //-----------------------------------------------------------------------------
1306 const char* Type::str(const Type* t) {
1307   stringStream ss;
1308   t->dump_on(&ss);
1309   return ss.as_string();
1310 }
1311 #endif
1312 
1313 //------------------------------singleton--------------------------------------
1314 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
1315 // constants (Ldi nodes).  Singletons are integer, float or double constants.
1316 bool Type::singleton(void) const {
1317   return _base == Top || _base == Half;
1318 }
1319 
1320 //------------------------------empty------------------------------------------
1321 // TRUE if Type is a type with no values, FALSE otherwise.
1322 bool Type::empty(void) const {
1323   switch (_base) {
1324   case DoubleTop:
1325   case FloatTop:
1326   case HalfFloatTop:
1327   case Top:
1328     return true;
1329 
1330   case Half:
1331   case Abio:
1332   case Return_Address:
1333   case Memory:
1334   case Bottom:
1335   case HalfFloatBot:
1336   case FloatBot:
1337   case DoubleBot:
1338     return false;  // never a singleton, therefore never empty
1339 
1340   default:
1341     ShouldNotReachHere();
1342     return false;
1343   }
1344 }
1345 
1346 //------------------------------dump_stats-------------------------------------
1347 // Dump collected statistics to stderr
1348 #ifndef PRODUCT
1349 void Type::dump_stats() {
1350   tty->print("Types made: %d\n", type_dict()->Size());
1351 }
1352 #endif
1353 
1354 //------------------------------category---------------------------------------
1355 #ifndef PRODUCT
1356 Type::Category Type::category() const {
1357   const TypeTuple* tuple;
1358   switch (base()) {
1359     case Type::Int:
1360     case Type::Long:
1361     case Type::Half:
1362     case Type::NarrowOop:
1363     case Type::NarrowKlass:
1364     case Type::Array:
1365     case Type::VectorA:
1366     case Type::VectorS:
1367     case Type::VectorD:
1368     case Type::VectorX:
1369     case Type::VectorY:
1370     case Type::VectorZ:
1371     case Type::VectorMask:
1372     case Type::AnyPtr:
1373     case Type::RawPtr:
1374     case Type::OopPtr:
1375     case Type::InstPtr:
1376     case Type::AryPtr:
1377     case Type::MetadataPtr:
1378     case Type::KlassPtr:
1379     case Type::InstKlassPtr:
1380     case Type::AryKlassPtr:
1381     case Type::Function:
1382     case Type::Return_Address:
1383     case Type::HalfFloatTop:
1384     case Type::HalfFloatCon:
1385     case Type::HalfFloatBot:
1386     case Type::FloatTop:
1387     case Type::FloatCon:
1388     case Type::FloatBot:
1389     case Type::DoubleTop:
1390     case Type::DoubleCon:
1391     case Type::DoubleBot:
1392       return Category::Data;
1393     case Type::Memory:
1394       return Category::Memory;
1395     case Type::Control:
1396       return Category::Control;
1397     case Type::Top:
1398     case Type::Abio:
1399     case Type::Bottom:
1400       return Category::Other;
1401     case Type::Bad:
1402     case Type::lastype:
1403       return Category::Undef;
1404     case Type::Tuple:
1405       // Recursive case. Return CatMixed if the tuple contains types of
1406       // different categories (e.g. CallStaticJavaNode's type), or the specific
1407       // category if all types are of the same category (e.g. IfNode's type).
1408       tuple = is_tuple();
1409       if (tuple->cnt() == 0) {
1410         return Category::Undef;
1411       } else {
1412         Category first = tuple->field_at(0)->category();
1413         for (uint i = 1; i < tuple->cnt(); i++) {
1414           if (tuple->field_at(i)->category() != first) {
1415             return Category::Mixed;
1416           }
1417         }
1418         return first;
1419       }
1420     default:
1421       assert(false, "unmatched base type: all base types must be categorized");
1422   }
1423   return Category::Undef;
1424 }
1425 
1426 bool Type::has_category(Type::Category cat) const {
1427   if (category() == cat) {
1428     return true;
1429   }
1430   if (category() == Category::Mixed) {
1431     const TypeTuple* tuple = is_tuple();
1432     for (uint i = 0; i < tuple->cnt(); i++) {
1433       if (tuple->field_at(i)->has_category(cat)) {
1434         return true;
1435       }
1436     }
1437   }
1438   return false;
1439 }
1440 #endif
1441 
1442 //------------------------------typerr-----------------------------------------
1443 void Type::typerr( const Type *t ) const {
1444 #ifndef PRODUCT
1445   tty->print("\nError mixing types: ");
1446   dump();
1447   tty->print(" and ");
1448   t->dump();
1449   tty->print("\n");
1450 #endif
1451   ShouldNotReachHere();
1452 }
1453 
1454 
1455 //=============================================================================
1456 // Convenience common pre-built types.
1457 const TypeF *TypeF::MAX;        // Floating point max
1458 const TypeF *TypeF::MIN;        // Floating point min
1459 const TypeF *TypeF::ZERO;       // Floating point zero
1460 const TypeF *TypeF::ONE;        // Floating point one
1461 const TypeF *TypeF::POS_INF;    // Floating point positive infinity
1462 const TypeF *TypeF::NEG_INF;    // Floating point negative infinity
1463 
1464 //------------------------------make-------------------------------------------
1465 // Create a float constant
1466 const TypeF *TypeF::make(float f) {
1467   return (TypeF*)(new TypeF(f))->hashcons();
1468 }
1469 
1470 //------------------------------meet-------------------------------------------
1471 // Compute the MEET of two types.  It returns a new Type object.
1472 const Type *TypeF::xmeet( const Type *t ) const {
1473   // Perform a fast test for common case; meeting the same types together.
1474   if( this == t ) return this;  // Meeting same type-rep?
1475 
1476   // Current "this->_base" is FloatCon
1477   switch (t->base()) {          // Switch on original type
1478   case AnyPtr:                  // Mixing with oops happens when javac
1479   case RawPtr:                  // reuses local variables
1480   case OopPtr:
1481   case InstPtr:
1482   case AryPtr:
1483   case MetadataPtr:
1484   case KlassPtr:
1485   case InstKlassPtr:
1486   case AryKlassPtr:
1487   case NarrowOop:
1488   case NarrowKlass:
1489   case Int:
1490   case Long:
1491   case HalfFloatTop:
1492   case HalfFloatCon:
1493   case HalfFloatBot:
1494   case DoubleTop:
1495   case DoubleCon:
1496   case DoubleBot:
1497   case Bottom:                  // Ye Olde Default
1498     return Type::BOTTOM;
1499 
1500   case FloatBot:
1501     return t;
1502 
1503   default:                      // All else is a mistake
1504     typerr(t);
1505 
1506   case FloatCon:                // Float-constant vs Float-constant?
1507     if( jint_cast(_f) != jint_cast(t->getf()) )         // unequal constants?
1508                                 // must compare bitwise as positive zero, negative zero and NaN have
1509                                 // all the same representation in C++
1510       return FLOAT;             // Return generic float
1511                                 // Equal constants
1512   case Top:
1513   case FloatTop:
1514     break;                      // Return the float constant
1515   }
1516   return this;                  // Return the float constant
1517 }
1518 
1519 //------------------------------xdual------------------------------------------
1520 // Dual: symmetric
1521 const Type *TypeF::xdual() const {
1522   return this;
1523 }
1524 
1525 //------------------------------eq---------------------------------------------
1526 // Structural equality check for Type representations
1527 bool TypeF::eq(const Type *t) const {
1528   // Bitwise comparison to distinguish between +/-0. These values must be treated
1529   // as different to be consistent with C1 and the interpreter.
1530   return (jint_cast(_f) == jint_cast(t->getf()));
1531 }
1532 
1533 //------------------------------hash-------------------------------------------
1534 // Type-specific hashing function.
1535 uint TypeF::hash(void) const {
1536   return *(uint*)(&_f);
1537 }
1538 
1539 //------------------------------is_finite--------------------------------------
1540 // Has a finite value
1541 bool TypeF::is_finite() const {
1542   return g_isfinite(getf()) != 0;
1543 }
1544 
1545 //------------------------------is_nan-----------------------------------------
1546 // Is not a number (NaN)
1547 bool TypeF::is_nan()    const {
1548   return g_isnan(getf()) != 0;
1549 }
1550 
1551 //------------------------------dump2------------------------------------------
1552 // Dump float constant Type
1553 #ifndef PRODUCT
1554 void TypeF::dump2( Dict &d, uint depth, outputStream *st ) const {
1555   Type::dump2(d,depth, st);
1556   st->print("%f", _f);
1557 }
1558 #endif
1559 
1560 //------------------------------singleton--------------------------------------
1561 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
1562 // constants (Ldi nodes).  Singletons are integer, float or double constants
1563 // or a single symbol.
1564 bool TypeF::singleton(void) const {
1565   return true;                  // Always a singleton
1566 }
1567 
1568 bool TypeF::empty(void) const {
1569   return false;                 // always exactly a singleton
1570 }
1571 
1572 //=============================================================================
1573 // Convenience common pre-built types.
1574 const TypeH* TypeH::MAX;        // Half float max
1575 const TypeH* TypeH::MIN;        // Half float min
1576 const TypeH* TypeH::ZERO;       // Half float zero
1577 const TypeH* TypeH::ONE;        // Half float one
1578 const TypeH* TypeH::POS_INF;    // Half float positive infinity
1579 const TypeH* TypeH::NEG_INF;    // Half float negative infinity
1580 
1581 //------------------------------make-------------------------------------------
1582 // Create a halffloat constant
1583 const TypeH* TypeH::make(short f) {
1584   return (TypeH*)(new TypeH(f))->hashcons();
1585 }
1586 
1587 const TypeH* TypeH::make(float f) {
1588   assert(StubRoutines::f2hf_adr() != nullptr, "");
1589   short hf = StubRoutines::f2hf(f);
1590   return (TypeH*)(new TypeH(hf))->hashcons();
1591 }
1592 
1593 //------------------------------xmeet-------------------------------------------
1594 // Compute the MEET of two types.  It returns a new Type object.
1595 const Type* TypeH::xmeet(const Type* t) const {
1596   // Perform a fast test for common case; meeting the same types together.
1597   if (this == t) return this;  // Meeting same type-rep?
1598 
1599   // Current "this->_base" is FloatCon
1600   switch (t->base()) {          // Switch on original type
1601   case AnyPtr:                  // Mixing with oops happens when javac
1602   case RawPtr:                  // reuses local variables
1603   case OopPtr:
1604   case InstPtr:
1605   case AryPtr:
1606   case MetadataPtr:
1607   case KlassPtr:
1608   case InstKlassPtr:
1609   case AryKlassPtr:
1610   case NarrowOop:
1611   case NarrowKlass:
1612   case Int:
1613   case Long:
1614   case FloatTop:
1615   case FloatCon:
1616   case FloatBot:
1617   case DoubleTop:
1618   case DoubleCon:
1619   case DoubleBot:
1620   case Bottom:                  // Ye Olde Default
1621     return Type::BOTTOM;
1622 
1623   case HalfFloatBot:
1624     return t;
1625 
1626   default:                      // All else is a mistake
1627     typerr(t);
1628 
1629   case HalfFloatCon:            // Half float-constant vs Half float-constant?
1630     if (_f != t->geth()) {      // unequal constants?
1631                                 // must compare bitwise as positive zero, negative zero and NaN have
1632                                 // all the same representation in C++
1633       return HALF_FLOAT;        // Return generic float
1634     }                           // Equal constants
1635   case Top:
1636   case HalfFloatTop:
1637     break;                      // Return the Half float constant
1638   }
1639   return this;                  // Return the Half float constant
1640 }
1641 
1642 //------------------------------xdual------------------------------------------
1643 // Dual: symmetric
1644 const Type* TypeH::xdual() const {
1645   return this;
1646 }
1647 
1648 //------------------------------eq---------------------------------------------
1649 // Structural equality check for Type representations
1650 bool TypeH::eq(const Type* t) const {
1651   // Bitwise comparison to distinguish between +/-0. These values must be treated
1652   // as different to be consistent with C1 and the interpreter.
1653   return (_f == t->geth());
1654 }
1655 
1656 //------------------------------hash-------------------------------------------
1657 // Type-specific hashing function.
1658 uint TypeH::hash(void) const {
1659   return *(jshort*)(&_f);
1660 }
1661 
1662 //------------------------------is_finite--------------------------------------
1663 // Has a finite value
1664 bool TypeH::is_finite() const {
1665   assert(StubRoutines::hf2f_adr() != nullptr, "");
1666   float f = StubRoutines::hf2f(geth());
1667   return g_isfinite(f) != 0;
1668 }
1669 
1670 float TypeH::getf() const {
1671   assert(StubRoutines::hf2f_adr() != nullptr, "");
1672   return StubRoutines::hf2f(geth());
1673 }
1674 
1675 //------------------------------is_nan-----------------------------------------
1676 // Is not a number (NaN)
1677 bool TypeH::is_nan() const {
1678   assert(StubRoutines::hf2f_adr() != nullptr, "");
1679   float f = StubRoutines::hf2f(geth());
1680   return g_isnan(f) != 0;
1681 }
1682 
1683 //------------------------------dump2------------------------------------------
1684 // Dump float constant Type
1685 #ifndef PRODUCT
1686 void TypeH::dump2(Dict &d, uint depth, outputStream* st) const {
1687   Type::dump2(d,depth, st);
1688   st->print("%f", getf());
1689 }
1690 #endif
1691 
1692 //------------------------------singleton--------------------------------------
1693 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
1694 // constants (Ldi nodes).  Singletons are integer, half float, float or double constants
1695 // or a single symbol.
1696 bool TypeH::singleton(void) const {
1697   return true;                  // Always a singleton
1698 }
1699 
1700 bool TypeH::empty(void) const {
1701   return false;                 // always exactly a singleton
1702 }
1703 
1704 //=============================================================================
1705 // Convenience common pre-built types.
1706 const TypeD *TypeD::MAX;        // Floating point max
1707 const TypeD *TypeD::MIN;        // Floating point min
1708 const TypeD *TypeD::ZERO;       // Floating point zero
1709 const TypeD *TypeD::ONE;        // Floating point one
1710 const TypeD *TypeD::POS_INF;    // Floating point positive infinity
1711 const TypeD *TypeD::NEG_INF;    // Floating point negative infinity
1712 
1713 //------------------------------make-------------------------------------------
1714 const TypeD *TypeD::make(double d) {
1715   return (TypeD*)(new TypeD(d))->hashcons();
1716 }
1717 
1718 //------------------------------meet-------------------------------------------
1719 // Compute the MEET of two types.  It returns a new Type object.
1720 const Type *TypeD::xmeet( const Type *t ) const {
1721   // Perform a fast test for common case; meeting the same types together.
1722   if( this == t ) return this;  // Meeting same type-rep?
1723 
1724   // Current "this->_base" is DoubleCon
1725   switch (t->base()) {          // Switch on original type
1726   case AnyPtr:                  // Mixing with oops happens when javac
1727   case RawPtr:                  // reuses local variables
1728   case OopPtr:
1729   case InstPtr:
1730   case AryPtr:
1731   case MetadataPtr:
1732   case KlassPtr:
1733   case InstKlassPtr:
1734   case AryKlassPtr:
1735   case NarrowOop:
1736   case NarrowKlass:
1737   case Int:
1738   case Long:
1739   case HalfFloatTop:
1740   case HalfFloatCon:
1741   case HalfFloatBot:
1742   case FloatTop:
1743   case FloatCon:
1744   case FloatBot:
1745   case Bottom:                  // Ye Olde Default
1746     return Type::BOTTOM;
1747 
1748   case DoubleBot:
1749     return t;
1750 
1751   default:                      // All else is a mistake
1752     typerr(t);
1753 
1754   case DoubleCon:               // Double-constant vs Double-constant?
1755     if( jlong_cast(_d) != jlong_cast(t->getd()) )       // unequal constants? (see comment in TypeF::xmeet)
1756       return DOUBLE;            // Return generic double
1757   case Top:
1758   case DoubleTop:
1759     break;
1760   }
1761   return this;                  // Return the double constant
1762 }
1763 
1764 //------------------------------xdual------------------------------------------
1765 // Dual: symmetric
1766 const Type *TypeD::xdual() const {
1767   return this;
1768 }
1769 
1770 //------------------------------eq---------------------------------------------
1771 // Structural equality check for Type representations
1772 bool TypeD::eq(const Type *t) const {
1773   // Bitwise comparison to distinguish between +/-0. These values must be treated
1774   // as different to be consistent with C1 and the interpreter.
1775   return (jlong_cast(_d) == jlong_cast(t->getd()));
1776 }
1777 
1778 //------------------------------hash-------------------------------------------
1779 // Type-specific hashing function.
1780 uint TypeD::hash(void) const {
1781   return *(uint*)(&_d);
1782 }
1783 
1784 //------------------------------is_finite--------------------------------------
1785 // Has a finite value
1786 bool TypeD::is_finite() const {
1787   return g_isfinite(getd()) != 0;
1788 }
1789 
1790 //------------------------------is_nan-----------------------------------------
1791 // Is not a number (NaN)
1792 bool TypeD::is_nan()    const {
1793   return g_isnan(getd()) != 0;
1794 }
1795 
1796 //------------------------------dump2------------------------------------------
1797 // Dump double constant Type
1798 #ifndef PRODUCT
1799 void TypeD::dump2( Dict &d, uint depth, outputStream *st ) const {
1800   Type::dump2(d,depth,st);
1801   st->print("%f", _d);
1802 }
1803 #endif
1804 
1805 //------------------------------singleton--------------------------------------
1806 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
1807 // constants (Ldi nodes).  Singletons are integer, float or double constants
1808 // or a single symbol.
1809 bool TypeD::singleton(void) const {
1810   return true;                  // Always a singleton
1811 }
1812 
1813 bool TypeD::empty(void) const {
1814   return false;                 // always exactly a singleton
1815 }
1816 
1817 const TypeInteger* TypeInteger::make(jlong lo, jlong hi, int w, BasicType bt) {
1818   if (bt == T_INT) {
1819     return TypeInt::make(checked_cast<jint>(lo), checked_cast<jint>(hi), w);
1820   }
1821   assert(bt == T_LONG, "basic type not an int or long");
1822   return TypeLong::make(lo, hi, w);
1823 }
1824 
1825 const TypeInteger* TypeInteger::make(jlong con, BasicType bt) {
1826   return make(con, con, WidenMin, bt);
1827 }
1828 
1829 jlong TypeInteger::get_con_as_long(BasicType bt) const {
1830   if (bt == T_INT) {
1831     return is_int()->get_con();
1832   }
1833   assert(bt == T_LONG, "basic type not an int or long");
1834   return is_long()->get_con();
1835 }
1836 
1837 const TypeInteger* TypeInteger::bottom(BasicType bt) {
1838   if (bt == T_INT) {
1839     return TypeInt::INT;
1840   }
1841   assert(bt == T_LONG, "basic type not an int or long");
1842   return TypeLong::LONG;
1843 }
1844 
1845 const TypeInteger* TypeInteger::zero(BasicType bt) {
1846   if (bt == T_INT) {
1847     return TypeInt::ZERO;
1848   }
1849   assert(bt == T_LONG, "basic type not an int or long");
1850   return TypeLong::ZERO;
1851 }
1852 
1853 const TypeInteger* TypeInteger::one(BasicType bt) {
1854   if (bt == T_INT) {
1855     return TypeInt::ONE;
1856   }
1857   assert(bt == T_LONG, "basic type not an int or long");
1858   return TypeLong::ONE;
1859 }
1860 
1861 const TypeInteger* TypeInteger::minus_1(BasicType bt) {
1862   if (bt == T_INT) {
1863     return TypeInt::MINUS_1;
1864   }
1865   assert(bt == T_LONG, "basic type not an int or long");
1866   return TypeLong::MINUS_1;
1867 }
1868 
1869 //=============================================================================
1870 // Convenience common pre-built types.
1871 const TypeInt* TypeInt::MAX;    // INT_MAX
1872 const TypeInt* TypeInt::MIN;    // INT_MIN
1873 const TypeInt* TypeInt::MINUS_1;// -1
1874 const TypeInt* TypeInt::ZERO;   // 0
1875 const TypeInt* TypeInt::ONE;    // 1
1876 const TypeInt* TypeInt::BOOL;   // 0 or 1, FALSE or TRUE.
1877 const TypeInt* TypeInt::CC;     // -1,0 or 1, condition codes
1878 const TypeInt* TypeInt::CC_LT;  // [-1]  == MINUS_1
1879 const TypeInt* TypeInt::CC_GT;  // [1]   == ONE
1880 const TypeInt* TypeInt::CC_EQ;  // [0]   == ZERO
1881 const TypeInt* TypeInt::CC_NE;
1882 const TypeInt* TypeInt::CC_LE;  // [-1,0]
1883 const TypeInt* TypeInt::CC_GE;  // [0,1] == BOOL (!)
1884 const TypeInt* TypeInt::BYTE;   // Bytes, -128 to 127
1885 const TypeInt* TypeInt::UBYTE;  // Unsigned Bytes, 0 to 255
1886 const TypeInt* TypeInt::CHAR;   // Java chars, 0-65535
1887 const TypeInt* TypeInt::SHORT;  // Java shorts, -32768-32767
1888 const TypeInt* TypeInt::NON_ZERO;
1889 const TypeInt* TypeInt::POS;    // Positive 32-bit integers or zero
1890 const TypeInt* TypeInt::POS1;   // Positive 32-bit integers
1891 const TypeInt* TypeInt::INT;    // 32-bit integers
1892 const TypeInt* TypeInt::SYMINT; // symmetric range [-max_jint..max_jint]
1893 const TypeInt* TypeInt::TYPE_DOMAIN; // alias for TypeInt::INT
1894 
1895 TypeInt::TypeInt(const TypeIntPrototype<jint, juint>& t, int widen, bool dual)
1896   : TypeInteger(Int, t.normalize_widen(widen), dual), _lo(t._srange._lo), _hi(t._srange._hi),
1897     _ulo(t._urange._lo), _uhi(t._urange._hi), _bits(t._bits) {
1898   DEBUG_ONLY(t.verify_constraints());
1899 }
1900 
1901 const Type* TypeInt::make_or_top(const TypeIntPrototype<jint, juint>& t, int widen, bool dual) {
1902   auto canonicalized_t = t.canonicalize_constraints();
1903   if (canonicalized_t.empty()) {
1904     return dual ? Type::BOTTOM : Type::TOP;
1905   }
1906   return (new TypeInt(canonicalized_t._data, widen, dual))->hashcons()->is_int();
1907 }
1908 
1909 const TypeInt* TypeInt::make(jint con) {
1910   juint ucon = con;
1911   return (new TypeInt(TypeIntPrototype<jint, juint>{{con, con}, {ucon, ucon}, {~ucon, ucon}},
1912                       WidenMin, false))->hashcons()->is_int();
1913 }
1914 
1915 const TypeInt* TypeInt::make(jint lo, jint hi, int widen) {
1916   assert(lo <= hi, "must be legal bounds");
1917   return make_or_top(TypeIntPrototype<jint, juint>{{lo, hi}, {0, max_juint}, {0, 0}}, widen)->is_int();
1918 }
1919 
1920 const TypeInt* TypeInt::make_unsigned(juint ulo, juint uhi, int widen) {
1921   assert(ulo <= uhi, "must be legal bounds");
1922   // By creating the TypeInt with the full signed range and the given unsigned range, the signed bounds are inferred from the unsigned bounds.
1923   return make_or_top(TypeIntPrototype<jint, juint>{{min_jint, max_jint}, {ulo, uhi}, {0, 0}}, widen)->is_int();
1924 }
1925 
1926 const Type* TypeInt::make_or_top(const TypeIntPrototype<jint, juint>& t, int widen) {
1927   return make_or_top(t, widen, false);
1928 }
1929 
1930 bool TypeInt::contains(jint i) const {
1931   assert(!_is_dual, "dual types should only be used for join calculation");
1932   juint u = i;
1933   return i >= _lo && i <= _hi &&
1934          u >= _ulo && u <= _uhi &&
1935          _bits.is_satisfied_by(u);
1936 }
1937 
1938 bool TypeInt::contains(const TypeInt* t) const {
1939   assert(!_is_dual && !t->_is_dual, "dual types should only be used for join calculation");
1940   return TypeIntHelper::int_type_is_subset(this, t);
1941 }
1942 
1943 #ifdef ASSERT
1944 bool TypeInt::strictly_contains(const TypeInt* t) const {
1945   assert(!_is_dual && !t->_is_dual, "dual types should only be used for join calculation");
1946   return TypeIntHelper::int_type_is_subset(this, t) && !TypeIntHelper::int_type_is_equal(this, t);
1947 }
1948 #endif // ASSERT
1949 
1950 const Type* TypeInt::xmeet(const Type* t) const {
1951   return TypeIntHelper::int_type_xmeet(this, t);
1952 }
1953 
1954 const Type* TypeInt::xdual() const {
1955   return new TypeInt(TypeIntPrototype<jint, juint>{{_lo, _hi}, {_ulo, _uhi}, _bits},
1956                      _widen, !_is_dual);
1957 }
1958 
1959 const Type* TypeInt::widen(const Type* old, const Type* limit) const {
1960   assert(!_is_dual, "dual types should only be used for join calculation");
1961   return TypeIntHelper::int_type_widen(this, old->isa_int(), limit->isa_int());
1962 }
1963 
1964 const Type* TypeInt::narrow(const Type* old) const {
1965   assert(!_is_dual, "dual types should only be used for join calculation");
1966   if (old == nullptr) {
1967     return this;
1968   }
1969 
1970   return TypeIntHelper::int_type_narrow(this, old->isa_int());
1971 }
1972 
1973 //-----------------------------filter------------------------------------------
1974 const Type* TypeInt::filter_helper(const Type* kills, bool include_speculative) const {
1975   assert(!_is_dual, "dual types should only be used for join calculation");
1976   const TypeInt* ft = join_helper(kills, include_speculative)->isa_int();
1977   if (ft == nullptr) {
1978     return Type::TOP;           // Canonical empty value
1979   }
1980   assert(!ft->_is_dual, "dual types should only be used for join calculation");
1981   if (ft->_widen < this->_widen) {
1982     // Do not allow the value of kill->_widen to affect the outcome.
1983     // The widen bits must be allowed to run freely through the graph.
1984     return (new TypeInt(TypeIntPrototype<jint, juint>{{ft->_lo, ft->_hi}, {ft->_ulo, ft->_uhi}, ft->_bits},
1985                         this->_widen, false))->hashcons();
1986   }
1987   return ft;
1988 }
1989 
1990 //------------------------------eq---------------------------------------------
1991 // Structural equality check for Type representations
1992 bool TypeInt::eq(const Type* t) const {
1993   const TypeInt* r = t->is_int();
1994   return TypeIntHelper::int_type_is_equal(this, r) && _widen == r->_widen && _is_dual == r->_is_dual;
1995 }
1996 
1997 //------------------------------hash-------------------------------------------
1998 // Type-specific hashing function.
1999 uint TypeInt::hash(void) const {
2000   return (uint)_lo + (uint)_hi + (uint)_ulo + (uint)_uhi +
2001          (uint)_bits._zeros + (uint)_bits._ones + (uint)_widen + (uint)_is_dual + (uint)Type::Int;
2002 }
2003 
2004 //------------------------------is_finite--------------------------------------
2005 // Has a finite value
2006 bool TypeInt::is_finite() const {
2007   return true;
2008 }
2009 
2010 //------------------------------singleton--------------------------------------
2011 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
2012 // constants.
2013 bool TypeInt::singleton(void) const {
2014   return _lo == _hi;
2015 }
2016 
2017 bool TypeInt::empty(void) const {
2018   return false;
2019 }
2020 
2021 //=============================================================================
2022 // Convenience common pre-built types.
2023 const TypeLong* TypeLong::MAX;
2024 const TypeLong* TypeLong::MIN;
2025 const TypeLong* TypeLong::MINUS_1;// -1
2026 const TypeLong* TypeLong::ZERO; // 0
2027 const TypeLong* TypeLong::ONE;  // 1
2028 const TypeLong* TypeLong::NON_ZERO;
2029 const TypeLong* TypeLong::POS;  // >=0
2030 const TypeLong* TypeLong::NEG;
2031 const TypeLong* TypeLong::LONG; // 64-bit integers
2032 const TypeLong* TypeLong::INT;  // 32-bit subrange
2033 const TypeLong* TypeLong::UINT; // 32-bit unsigned subrange
2034 const TypeLong* TypeLong::TYPE_DOMAIN; // alias for TypeLong::LONG
2035 
2036 TypeLong::TypeLong(const TypeIntPrototype<jlong, julong>& t, int widen, bool dual)
2037   : TypeInteger(Long, t.normalize_widen(widen), dual), _lo(t._srange._lo), _hi(t._srange._hi),
2038     _ulo(t._urange._lo), _uhi(t._urange._hi), _bits(t._bits) {
2039   DEBUG_ONLY(t.verify_constraints());
2040 }
2041 
2042 const Type* TypeLong::make_or_top(const TypeIntPrototype<jlong, julong>& t, int widen, bool dual) {
2043   auto canonicalized_t = t.canonicalize_constraints();
2044   if (canonicalized_t.empty()) {
2045     return dual ? Type::BOTTOM : Type::TOP;
2046   }
2047   return (new TypeLong(canonicalized_t._data, widen, dual))->hashcons()->is_long();
2048 }
2049 
2050 const TypeLong* TypeLong::make(jlong con) {
2051   julong ucon = con;
2052   return (new TypeLong(TypeIntPrototype<jlong, julong>{{con, con}, {ucon, ucon}, {~ucon, ucon}},
2053                        WidenMin, false))->hashcons()->is_long();
2054 }
2055 
2056 const TypeLong* TypeLong::make(jlong lo, jlong hi, int widen) {
2057   assert(lo <= hi, "must be legal bounds");
2058   return make_or_top(TypeIntPrototype<jlong, julong>{{lo, hi}, {0, max_julong}, {0, 0}}, widen)->is_long();
2059 }
2060 
2061 const TypeLong* TypeLong::make_unsigned(julong ulo, julong uhi, int widen) {
2062   assert(ulo <= uhi, "must be legal bounds");
2063   // By creating the TypeLong with the full signed range and the given unsigned range, the signed bounds are inferred from the unsigned bounds.
2064   return make_or_top(TypeIntPrototype<jlong, julong>{{min_jlong, max_jlong}, {ulo, uhi}, {0, 0}}, widen)->is_long();
2065 }
2066 
2067 const Type* TypeLong::make_or_top(const TypeIntPrototype<jlong, julong>& t, int widen) {
2068   return make_or_top(t, widen, false);
2069 }
2070 
2071 bool TypeLong::contains(jlong i) const {
2072   assert(!_is_dual, "dual types should only be used for join calculation");
2073   julong u = i;
2074   return i >= _lo && i <= _hi &&
2075          u >= _ulo && u <= _uhi &&
2076          _bits.is_satisfied_by(u);
2077 }
2078 
2079 bool TypeLong::contains(const TypeLong* t) const {
2080   assert(!_is_dual && !t->_is_dual, "dual types should only be used for join calculation");
2081   return TypeIntHelper::int_type_is_subset(this, t);
2082 }
2083 
2084 #ifdef ASSERT
2085 bool TypeLong::strictly_contains(const TypeLong* t) const {
2086   assert(!_is_dual && !t->_is_dual, "dual types should only be used for join calculation");
2087   return TypeIntHelper::int_type_is_subset(this, t) && !TypeIntHelper::int_type_is_equal(this, t);
2088 }
2089 #endif // ASSERT
2090 
2091 const Type* TypeLong::xmeet(const Type* t) const {
2092   return TypeIntHelper::int_type_xmeet(this, t);
2093 }
2094 
2095 const Type* TypeLong::xdual() const {
2096   return new TypeLong(TypeIntPrototype<jlong, julong>{{_lo, _hi}, {_ulo, _uhi}, _bits},
2097                       _widen, !_is_dual);
2098 }
2099 
2100 const Type* TypeLong::widen(const Type* old, const Type* limit) const {
2101   assert(!_is_dual, "dual types should only be used for join calculation");
2102   return TypeIntHelper::int_type_widen(this, old->isa_long(), limit->isa_long());
2103 }
2104 
2105 const Type* TypeLong::narrow(const Type* old) const {
2106   assert(!_is_dual, "dual types should only be used for join calculation");
2107   if (old == nullptr) {
2108     return this;
2109   }
2110 
2111   return TypeIntHelper::int_type_narrow(this, old->isa_long());
2112 }
2113 
2114 //-----------------------------filter------------------------------------------
2115 const Type* TypeLong::filter_helper(const Type* kills, bool include_speculative) const {
2116   assert(!_is_dual, "dual types should only be used for join calculation");
2117   const TypeLong* ft = join_helper(kills, include_speculative)->isa_long();
2118   if (ft == nullptr) {
2119     return Type::TOP;           // Canonical empty value
2120   }
2121   assert(!ft->_is_dual, "dual types should only be used for join calculation");
2122   if (ft->_widen < this->_widen) {
2123     // Do not allow the value of kill->_widen to affect the outcome.
2124     // The widen bits must be allowed to run freely through the graph.
2125     return (new TypeLong(TypeIntPrototype<jlong, julong>{{ft->_lo, ft->_hi}, {ft->_ulo, ft->_uhi}, ft->_bits},
2126                          this->_widen, false))->hashcons();
2127   }
2128   return ft;
2129 }
2130 
2131 //------------------------------eq---------------------------------------------
2132 // Structural equality check for Type representations
2133 bool TypeLong::eq(const Type* t) const {
2134   const TypeLong* r = t->is_long();
2135   return TypeIntHelper::int_type_is_equal(this, r) && _widen == r->_widen && _is_dual == r->_is_dual;
2136 }
2137 
2138 //------------------------------hash-------------------------------------------
2139 // Type-specific hashing function.
2140 uint TypeLong::hash(void) const {
2141   return (uint)_lo + (uint)_hi + (uint)_ulo + (uint)_uhi +
2142          (uint)_bits._zeros + (uint)_bits._ones + (uint)_widen + (uint)_is_dual + (uint)Type::Long;
2143 }
2144 
2145 //------------------------------is_finite--------------------------------------
2146 // Has a finite value
2147 bool TypeLong::is_finite() const {
2148   return true;
2149 }
2150 
2151 //------------------------------singleton--------------------------------------
2152 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
2153 // constants
2154 bool TypeLong::singleton(void) const {
2155   return _lo == _hi;
2156 }
2157 
2158 bool TypeLong::empty(void) const {
2159   return false;
2160 }
2161 
2162 //------------------------------dump2------------------------------------------
2163 #ifndef PRODUCT
2164 void TypeInt::dump2(Dict& d, uint depth, outputStream* st) const {
2165   TypeIntHelper::int_type_dump(this, st, false);
2166 }
2167 
2168 void TypeInt::dump_verbose() const {
2169   TypeIntHelper::int_type_dump(this, tty, true);
2170 }
2171 
2172 void TypeLong::dump2(Dict& d, uint depth, outputStream* st) const {
2173   TypeIntHelper::int_type_dump(this, st, false);
2174 }
2175 
2176 void TypeLong::dump_verbose() const {
2177   TypeIntHelper::int_type_dump(this, tty, true);
2178 }
2179 #endif
2180 
2181 //=============================================================================
2182 // Convenience common pre-built types.
2183 const TypeTuple *TypeTuple::IFBOTH;     // Return both arms of IF as reachable
2184 const TypeTuple *TypeTuple::IFFALSE;
2185 const TypeTuple *TypeTuple::IFTRUE;
2186 const TypeTuple *TypeTuple::IFNEITHER;
2187 const TypeTuple *TypeTuple::LOOPBODY;
2188 const TypeTuple *TypeTuple::MEMBAR;
2189 const TypeTuple *TypeTuple::STORECONDITIONAL;
2190 const TypeTuple *TypeTuple::START_I2C;
2191 const TypeTuple *TypeTuple::INT_PAIR;
2192 const TypeTuple *TypeTuple::LONG_PAIR;
2193 const TypeTuple *TypeTuple::INT_CC_PAIR;
2194 const TypeTuple *TypeTuple::LONG_CC_PAIR;
2195 
2196 static void collect_inline_fields(ciInlineKlass* vk, const Type** field_array, uint& pos) {
2197   for (int i = 0; i < vk->nof_declared_nonstatic_fields(); i++) {
2198     ciField* field = vk->declared_nonstatic_field_at(i);
2199     if (field->is_flat()) {
2200       collect_inline_fields(field->type()->as_inline_klass(), field_array, pos);
2201       if (!field->is_null_free()) {
2202         // Use T_INT instead of T_BOOLEAN here because the upper bits can contain garbage if the holder
2203         // is null and C2 will only zero them for T_INT assuming that T_BOOLEAN is already canonicalized.
2204         field_array[pos++] = Type::get_const_basic_type(T_INT);
2205       }
2206     } else {
2207       BasicType bt = field->type()->basic_type();
2208       const Type* ft = Type::get_const_type(field->type());
2209       field_array[pos++] = ft;
2210       if (type2size[bt] == 2) {
2211         field_array[pos++] = Type::HALF;
2212       }
2213     }
2214   }
2215 }
2216 
2217 //------------------------------make-------------------------------------------
2218 // Make a TypeTuple from the range of a method signature
2219 const TypeTuple* TypeTuple::make_range(ciSignature* sig, InterfaceHandling interface_handling, bool ret_vt_fields, bool is_call) {
2220   ciType* return_type = sig->return_type();
2221   uint arg_cnt = return_type->size();
2222   if (ret_vt_fields) {
2223     arg_cnt = return_type->as_inline_klass()->inline_arg_slots() + 1;
2224     if (is_call) {
2225       // InlineTypeNode::NullMarker field returned by scalarized calls
2226       arg_cnt++;
2227     }
2228   }
2229   const Type **field_array = fields(arg_cnt);
2230   switch (return_type->basic_type()) {
2231   case T_LONG:
2232     field_array[TypeFunc::Parms]   = TypeLong::LONG;
2233     field_array[TypeFunc::Parms+1] = Type::HALF;
2234     break;
2235   case T_DOUBLE:
2236     field_array[TypeFunc::Parms]   = Type::DOUBLE;
2237     field_array[TypeFunc::Parms+1] = Type::HALF;
2238     break;
2239   case T_OBJECT:
2240     if (ret_vt_fields) {
2241       uint pos = TypeFunc::Parms;
2242       field_array[pos++] = get_const_type(return_type); // Oop might be null when returning as fields
2243       collect_inline_fields(return_type->as_inline_klass(), field_array, pos);
2244       if (is_call) {
2245         // InlineTypeNode::NullMarker field returned by scalarized calls
2246         field_array[pos++] = get_const_basic_type(T_BOOLEAN);
2247       }
2248       assert(pos == (TypeFunc::Parms + arg_cnt), "out of bounds");
2249       break;
2250     } else {
2251       field_array[TypeFunc::Parms] = get_const_type(return_type, interface_handling)->join_speculative(TypePtr::BOTTOM);
2252     }
2253     break;
2254   case T_ARRAY:
2255   case T_BOOLEAN:
2256   case T_CHAR:
2257   case T_FLOAT:
2258   case T_BYTE:
2259   case T_SHORT:
2260   case T_INT:
2261     field_array[TypeFunc::Parms] = get_const_type(return_type, interface_handling);
2262     break;
2263   case T_VOID:
2264     break;
2265   default:
2266     ShouldNotReachHere();
2267   }
2268   return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons();
2269 }
2270 
2271 // Make a TypeTuple from the domain of a method signature
2272 const TypeTuple *TypeTuple::make_domain(ciMethod* method, InterfaceHandling interface_handling, bool vt_fields_as_args) {
2273   ciSignature* sig = method->signature();
2274   uint arg_cnt = sig->size() + (method->is_static() ? 0 : 1);
2275   if (vt_fields_as_args) {
2276     arg_cnt = 0;
2277     assert(method->get_sig_cc() != nullptr, "Should have scalarized signature");
2278     for (ExtendedSignature sig_cc = ExtendedSignature(method->get_sig_cc(), SigEntryFilter()); !sig_cc.at_end(); ++sig_cc) {
2279       arg_cnt += type2size[(*sig_cc)._bt];
2280     }
2281   }
2282 
2283   uint pos = TypeFunc::Parms;
2284   const Type** field_array = fields(arg_cnt);
2285   if (!method->is_static()) {
2286     ciInstanceKlass* recv = method->holder();
2287     if (vt_fields_as_args && recv->is_inlinetype() && recv->as_inline_klass()->can_be_passed_as_fields() && method->is_scalarized_arg(0)) {
2288       field_array[pos++] = get_const_type(recv, interface_handling); // buffer argument
2289       collect_inline_fields(recv->as_inline_klass(), field_array, pos);
2290     } else {
2291       field_array[pos++] = get_const_type(recv, interface_handling)->join_speculative(TypePtr::NOTNULL);
2292     }
2293   }
2294 
2295   int i = 0;
2296   while (pos < TypeFunc::Parms + arg_cnt) {
2297     ciType* type = sig->type_at(i);
2298     BasicType bt = type->basic_type();
2299 
2300     switch (bt) {
2301     case T_LONG:
2302       field_array[pos++] = TypeLong::LONG;
2303       field_array[pos++] = Type::HALF;
2304       break;
2305     case T_DOUBLE:
2306       field_array[pos++] = Type::DOUBLE;
2307       field_array[pos++] = Type::HALF;
2308       break;
2309     case T_OBJECT:
2310       if (type->is_inlinetype() && vt_fields_as_args && method->is_scalarized_arg(i + (method->is_static() ? 0 : 1))) {
2311         field_array[pos++] = get_const_type(type, interface_handling); // buffer argument
2312         // InlineTypeNode::NullMarker field used for null checking
2313         field_array[pos++] = get_const_basic_type(T_BOOLEAN);
2314         collect_inline_fields(type->as_inline_klass(), field_array, pos);
2315       } else {
2316         field_array[pos++] = get_const_type(type, interface_handling);
2317       }
2318       break;
2319     case T_ARRAY:
2320     case T_FLOAT:
2321     case T_INT:
2322       field_array[pos++] = get_const_type(type, interface_handling);
2323       break;
2324     case T_BOOLEAN:
2325     case T_CHAR:
2326     case T_BYTE:
2327     case T_SHORT:
2328       field_array[pos++] = TypeInt::INT;
2329       break;
2330     default:
2331       ShouldNotReachHere();
2332     }
2333     i++;
2334   }
2335   assert(pos == TypeFunc::Parms + arg_cnt, "wrong number of arguments");
2336 
2337   return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons();
2338 }
2339 
2340 const TypeTuple *TypeTuple::make( uint cnt, const Type **fields ) {
2341   return (TypeTuple*)(new TypeTuple(cnt,fields))->hashcons();
2342 }
2343 
2344 //------------------------------fields-----------------------------------------
2345 // Subroutine call type with space allocated for argument types
2346 // Memory for Control, I_O, Memory, FramePtr, and ReturnAdr is allocated implicitly
2347 const Type **TypeTuple::fields( uint arg_cnt ) {
2348   const Type **flds = (const Type **)(Compile::current()->type_arena()->AmallocWords((TypeFunc::Parms+arg_cnt)*sizeof(Type*) ));
2349   flds[TypeFunc::Control  ] = Type::CONTROL;
2350   flds[TypeFunc::I_O      ] = Type::ABIO;
2351   flds[TypeFunc::Memory   ] = Type::MEMORY;
2352   flds[TypeFunc::FramePtr ] = TypeRawPtr::BOTTOM;
2353   flds[TypeFunc::ReturnAdr] = Type::RETURN_ADDRESS;
2354 
2355   return flds;
2356 }
2357 
2358 //------------------------------meet-------------------------------------------
2359 // Compute the MEET of two types.  It returns a new Type object.
2360 const Type *TypeTuple::xmeet( const Type *t ) const {
2361   // Perform a fast test for common case; meeting the same types together.
2362   if( this == t ) return this;  // Meeting same type-rep?
2363 
2364   // Current "this->_base" is Tuple
2365   switch (t->base()) {          // switch on original type
2366 
2367   case Bottom:                  // Ye Olde Default
2368     return t;
2369 
2370   default:                      // All else is a mistake
2371     typerr(t);
2372 
2373   case Tuple: {                 // Meeting 2 signatures?
2374     const TypeTuple *x = t->is_tuple();
2375     assert( _cnt == x->_cnt, "" );
2376     const Type **fields = (const Type **)(Compile::current()->type_arena()->AmallocWords( _cnt*sizeof(Type*) ));
2377     for( uint i=0; i<_cnt; i++ )
2378       fields[i] = field_at(i)->xmeet( x->field_at(i) );
2379     return TypeTuple::make(_cnt,fields);
2380   }
2381   case Top:
2382     break;
2383   }
2384   return this;                  // Return the double constant
2385 }
2386 
2387 //------------------------------xdual------------------------------------------
2388 // Dual: compute field-by-field dual
2389 const Type *TypeTuple::xdual() const {
2390   const Type **fields = (const Type **)(Compile::current()->type_arena()->AmallocWords( _cnt*sizeof(Type*) ));
2391   for( uint i=0; i<_cnt; i++ )
2392     fields[i] = _fields[i]->dual();
2393   return new TypeTuple(_cnt,fields);
2394 }
2395 
2396 //------------------------------eq---------------------------------------------
2397 // Structural equality check for Type representations
2398 bool TypeTuple::eq( const Type *t ) const {
2399   const TypeTuple *s = (const TypeTuple *)t;
2400   if (_cnt != s->_cnt)  return false;  // Unequal field counts
2401   for (uint i = 0; i < _cnt; i++)
2402     if (field_at(i) != s->field_at(i)) // POINTER COMPARE!  NO RECURSION!
2403       return false;             // Missed
2404   return true;
2405 }
2406 
2407 //------------------------------hash-------------------------------------------
2408 // Type-specific hashing function.
2409 uint TypeTuple::hash(void) const {
2410   uintptr_t sum = _cnt;
2411   for( uint i=0; i<_cnt; i++ )
2412     sum += (uintptr_t)_fields[i];     // Hash on pointers directly
2413   return (uint)sum;
2414 }
2415 
2416 //------------------------------dump2------------------------------------------
2417 // Dump signature Type
2418 #ifndef PRODUCT
2419 void TypeTuple::dump2( Dict &d, uint depth, outputStream *st ) const {
2420   st->print("{");
2421   if( !depth || d[this] ) {     // Check for recursive print
2422     st->print("...}");
2423     return;
2424   }
2425   d.Insert((void*)this, (void*)this);   // Stop recursion
2426   if( _cnt ) {
2427     uint i;
2428     for( i=0; i<_cnt-1; i++ ) {
2429       st->print("%d:", i);
2430       _fields[i]->dump2(d, depth-1, st);
2431       st->print(", ");
2432     }
2433     st->print("%d:", i);
2434     _fields[i]->dump2(d, depth-1, st);
2435   }
2436   st->print("}");
2437 }
2438 #endif
2439 
2440 //------------------------------singleton--------------------------------------
2441 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
2442 // constants (Ldi nodes).  Singletons are integer, float or double constants
2443 // or a single symbol.
2444 bool TypeTuple::singleton(void) const {
2445   return false;                 // Never a singleton
2446 }
2447 
2448 bool TypeTuple::empty(void) const {
2449   for( uint i=0; i<_cnt; i++ ) {
2450     if (_fields[i]->empty())  return true;
2451   }
2452   return false;
2453 }
2454 
2455 //=============================================================================
2456 // Convenience common pre-built types.
2457 
2458 inline const TypeInt* normalize_array_size(const TypeInt* size) {
2459   // Certain normalizations keep us sane when comparing types.
2460   // We do not want arrayOop variables to differ only by the wideness
2461   // of their index types.  Pick minimum wideness, since that is the
2462   // forced wideness of small ranges anyway.
2463   if (size->_widen != Type::WidenMin)
2464     return TypeInt::make(size->_lo, size->_hi, Type::WidenMin);
2465   else
2466     return size;
2467 }
2468 
2469 //------------------------------make-------------------------------------------
2470 const TypeAry* TypeAry::make(const Type* elem, const TypeInt* size, bool stable,
2471                              bool flat, bool not_flat, bool not_null_free, bool atomic) {
2472   if (UseCompressedOops && elem->isa_oopptr()) {
2473     elem = elem->make_narrowoop();
2474   }
2475   size = normalize_array_size(size);
2476   return (TypeAry*)(new TypeAry(elem, size, stable, flat, not_flat, not_null_free, atomic))->hashcons();
2477 }
2478 
2479 //------------------------------meet-------------------------------------------
2480 // Compute the MEET of two types.  It returns a new Type object.
2481 const Type *TypeAry::xmeet( const Type *t ) const {
2482   // Perform a fast test for common case; meeting the same types together.
2483   if( this == t ) return this;  // Meeting same type-rep?
2484 
2485   // Current "this->_base" is Ary
2486   switch (t->base()) {          // switch on original type
2487 
2488   case Bottom:                  // Ye Olde Default
2489     return t;
2490 
2491   default:                      // All else is a mistake
2492     typerr(t);
2493 
2494   case Array: {                 // Meeting 2 arrays?
2495     const TypeAry* a = t->is_ary();
2496     const Type* size = _size->xmeet(a->_size);
2497     const TypeInt* isize = size->isa_int();
2498     if (isize == nullptr) {
2499       assert(size == Type::TOP || size == Type::BOTTOM, "");
2500       return size;
2501     }
2502     return TypeAry::make(_elem->meet_speculative(a->_elem),
2503                          isize, _stable && a->_stable,
2504                          _flat && a->_flat,
2505                          _not_flat && a->_not_flat,
2506                          _not_null_free && a->_not_null_free,
2507                          _atomic && a->_atomic);
2508   }
2509   case Top:
2510     break;
2511   }
2512   return this;                  // Return the double constant
2513 }
2514 
2515 //------------------------------xdual------------------------------------------
2516 // Dual: compute field-by-field dual
2517 const Type *TypeAry::xdual() const {
2518   const TypeInt* size_dual = _size->dual()->is_int();
2519   size_dual = normalize_array_size(size_dual);
2520   return new TypeAry(_elem->dual(), size_dual, !_stable, !_flat, !_not_flat, !_not_null_free, !_atomic);
2521 }
2522 
2523 //------------------------------eq---------------------------------------------
2524 // Structural equality check for Type representations
2525 bool TypeAry::eq( const Type *t ) const {
2526   const TypeAry *a = (const TypeAry*)t;
2527   return _elem == a->_elem &&
2528     _stable == a->_stable &&
2529     _size == a->_size &&
2530     _flat == a->_flat &&
2531     _not_flat == a->_not_flat &&
2532     _not_null_free == a->_not_null_free &&
2533     _atomic == a->_atomic;
2534 
2535 }
2536 
2537 //------------------------------hash-------------------------------------------
2538 // Type-specific hashing function.
2539 uint TypeAry::hash(void) const {
2540   return (uint)(uintptr_t)_elem + (uint)(uintptr_t)_size + (uint)(_stable ? 43 : 0) +
2541       (uint)(_flat ? 44 : 0) + (uint)(_not_flat ? 45 : 0) + (uint)(_not_null_free ? 46 : 0) + (uint)(_atomic ? 47 : 0);
2542 }
2543 
2544 /**
2545  * Return same type without a speculative part in the element
2546  */
2547 const TypeAry* TypeAry::remove_speculative() const {
2548   return make(_elem->remove_speculative(), _size, _stable, _flat, _not_flat, _not_null_free, _atomic);
2549 }
2550 
2551 /**
2552  * Return same type with cleaned up speculative part of element
2553  */
2554 const Type* TypeAry::cleanup_speculative() const {
2555   return make(_elem->cleanup_speculative(), _size, _stable, _flat, _not_flat, _not_null_free, _atomic);
2556 }
2557 
2558 /**
2559  * Return same type but with a different inline depth (used for speculation)
2560  *
2561  * @param depth  depth to meet with
2562  */
2563 const TypePtr* TypePtr::with_inline_depth(int depth) const {
2564   if (!UseInlineDepthForSpeculativeTypes) {
2565     return this;
2566   }
2567   return make(AnyPtr, _ptr, _offset, _speculative, depth, _reloc);
2568 }
2569 
2570 //------------------------------dump2------------------------------------------
2571 #ifndef PRODUCT
2572 void TypeAry::dump2( Dict &d, uint depth, outputStream *st ) const {
2573   if (_stable)  st->print("stable:");
2574   if (_flat) st->print("flat:");
2575   if (Verbose) {
2576     if (_not_flat) st->print("not flat:");
2577     if (_not_null_free) st->print("not null free:");
2578   }
2579   if (_atomic) st->print("atomic:");
2580   _elem->dump2(d, depth, st);
2581   st->print("[");
2582   _size->dump2(d, depth, st);
2583   st->print("]");
2584 }
2585 #endif
2586 
2587 //------------------------------singleton--------------------------------------
2588 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
2589 // constants (Ldi nodes).  Singletons are integer, float or double constants
2590 // or a single symbol.
2591 bool TypeAry::singleton(void) const {
2592   return false;                 // Never a singleton
2593 }
2594 
2595 bool TypeAry::empty(void) const {
2596   assert(!_size->empty(), "TypeInt is never empty");
2597   // TODO 8385426 This should be simplified at construction time once we get rid of dual
2598   // Doing it with the dual-based join is annoying. TypeAry::empty tests whether the
2599   // element type is empty. When computing the dual of an array that can be flat or not,
2600   // we will get an element type that is empty, and doesn't need more. We even shouldn't
2601   // do more otherwise, we can't make the dual involutive. But if we compute the
2602   // intersection of a flat and a non-flat array, we could change the element type to an
2603   // empty type to reduce the abstract value. And we must be careful not to do that in
2604   // the dual world.
2605   return _elem->empty() || (_flat && _not_flat);
2606 }
2607 
2608 //--------------------------ary_must_be_exact----------------------------------
2609 bool TypeAry::ary_must_be_exact() const {
2610   // This logic looks at the element type of an array, and returns true
2611   // if the element type is either a primitive or a final instance class.
2612   // In such cases, an array built on this ary must have no subclasses.
2613   if (_elem == BOTTOM)      return false;  // general array not exact
2614   if (_elem == TOP   )      return false;  // inverted general array not exact
2615   const TypeOopPtr*  toop = nullptr;
2616   if (UseCompressedOops && _elem->isa_narrowoop()) {
2617     toop = _elem->make_ptr()->isa_oopptr();
2618   } else {
2619     toop = _elem->isa_oopptr();
2620   }
2621   if (!toop)                return true;   // a primitive type, like int
2622   if (!toop->is_loaded())   return false;  // unloaded class
2623   const TypeInstPtr* tinst;
2624   if (_elem->isa_narrowoop())
2625     tinst = _elem->make_ptr()->isa_instptr();
2626   else
2627     tinst = _elem->isa_instptr();
2628   if (tinst) {
2629     if (tinst->instance_klass()->is_final()) {
2630       // Even though MyValue is final, [LMyValue is only exact if the array
2631       // is (not) null-free due to null-free [LMyValue <: null-able [LMyValue.
2632       // TODO 8387653 If we know that the array can't be null-free, it's allowed to be exact, right?
2633       // If so, we should add '&& !_not_null_free'
2634       if (tinst->is_inlinetypeptr() && (tinst->ptr() != TypePtr::NotNull)) {
2635         return false;
2636       }
2637       return true;
2638     }
2639     return false;
2640   }
2641   const TypeAryPtr*  tap;
2642   if (_elem->isa_narrowoop())
2643     tap = _elem->make_ptr()->isa_aryptr();
2644   else
2645     tap = _elem->isa_aryptr();
2646   if (tap)
2647     return tap->ary()->ary_must_be_exact();
2648   return false;
2649 }
2650 
2651 //==============================TypeVect=======================================
2652 // Convenience common pre-built types.
2653 const TypeVect* TypeVect::VECTA = nullptr; // vector length agnostic
2654 const TypeVect* TypeVect::VECTS = nullptr; //  32-bit vectors
2655 const TypeVect* TypeVect::VECTD = nullptr; //  64-bit vectors
2656 const TypeVect* TypeVect::VECTX = nullptr; // 128-bit vectors
2657 const TypeVect* TypeVect::VECTY = nullptr; // 256-bit vectors
2658 const TypeVect* TypeVect::VECTZ = nullptr; // 512-bit vectors
2659 const TypeVect* TypeVect::VECTMASK = nullptr; // predicate/mask vector
2660 
2661 //------------------------------make-------------------------------------------
2662 const TypeVect* TypeVect::make(BasicType elem_bt, uint length, bool is_mask) {
2663   if (is_mask) {
2664     return makemask(elem_bt, length);
2665   }
2666   assert(is_java_primitive(elem_bt), "only primitive types in vector");
2667   assert(Matcher::vector_size_supported(elem_bt, length), "length in range");
2668   int size = length * type2aelembytes(elem_bt);
2669   switch (Matcher::vector_ideal_reg(size)) {
2670   case Op_VecA:
2671     return (TypeVect*)(new TypeVectA(elem_bt, length))->hashcons();
2672   case Op_VecS:
2673     return (TypeVect*)(new TypeVectS(elem_bt, length))->hashcons();
2674   case Op_RegL:
2675   case Op_VecD:
2676   case Op_RegD:
2677     return (TypeVect*)(new TypeVectD(elem_bt, length))->hashcons();
2678   case Op_VecX:
2679     return (TypeVect*)(new TypeVectX(elem_bt, length))->hashcons();
2680   case Op_VecY:
2681     return (TypeVect*)(new TypeVectY(elem_bt, length))->hashcons();
2682   case Op_VecZ:
2683     return (TypeVect*)(new TypeVectZ(elem_bt, length))->hashcons();
2684   }
2685  ShouldNotReachHere();
2686   return nullptr;
2687 }
2688 
2689 // Create a vector mask type with the given element basic type and length.
2690 // - Returns "TypePVectMask" (PVectMask) for platforms that support the predicate
2691 //   feature and it is implemented properly in the backend, allowing the mask to
2692 //   be stored in a predicate/mask register.
2693 // - Returns a normal vector type "TypeVectA ~ TypeVectZ" (NVectMask) otherwise,
2694 //   where the vector mask is stored in a vector register.
2695 const TypeVect* TypeVect::makemask(BasicType elem_bt, uint length) {
2696   if (Matcher::has_predicated_vectors() &&
2697       Matcher::match_rule_supported_vector_masked(Op_VectorLoadMask, length, elem_bt)) {
2698     return TypePVectMask::make(elem_bt, length);
2699   } else {
2700     return make(elem_bt, length);
2701   }
2702 }
2703 
2704 //------------------------------meet-------------------------------------------
2705 // Compute the MEET of two types. Since each TypeVect is the only instance of
2706 // its species, meeting often returns itself
2707 const Type* TypeVect::xmeet(const Type* t) const {
2708   // Perform a fast test for common case; meeting the same types together.
2709   if (this == t) {
2710     return this;
2711   }
2712 
2713   // Current "this->_base" is Vector
2714   switch (t->base()) {          // switch on original type
2715 
2716   case Bottom:                  // Ye Olde Default
2717     return t;
2718 
2719   default:                      // All else is a mistake
2720     typerr(t);
2721   case VectorMask:
2722   case VectorA:
2723   case VectorS:
2724   case VectorD:
2725   case VectorX:
2726   case VectorY:
2727   case VectorZ: {                // Meeting 2 vectors?
2728     const TypeVect* v = t->is_vect();
2729     assert(base() == v->base(), "");
2730     assert(length() == v->length(), "");
2731     assert(element_basic_type() == v->element_basic_type(), "");
2732     return this;
2733   }
2734   case Top:
2735     break;
2736   }
2737   return this;
2738 }
2739 
2740 //------------------------------xdual------------------------------------------
2741 // Since each TypeVect is the only instance of its species, it is self-dual
2742 const Type* TypeVect::xdual() const {
2743   return this;
2744 }
2745 
2746 //------------------------------eq---------------------------------------------
2747 // Structural equality check for Type representations
2748 bool TypeVect::eq(const Type* t) const {
2749   const TypeVect* v = t->is_vect();
2750   return (element_basic_type() == v->element_basic_type()) && (length() == v->length());
2751 }
2752 
2753 //------------------------------hash-------------------------------------------
2754 // Type-specific hashing function.
2755 uint TypeVect::hash(void) const {
2756   return (uint)base() + (uint)(uintptr_t)_elem_bt + (uint)(uintptr_t)_length;
2757 }
2758 
2759 //------------------------------singleton--------------------------------------
2760 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple
2761 // constants (Ldi nodes).  Vector is singleton if all elements are the same
2762 // constant value (when vector is created with Replicate code).
2763 bool TypeVect::singleton(void) const {
2764 // There is no Con node for vectors yet.
2765 //  return _elem->singleton();
2766   return false;
2767 }
2768 
2769 bool TypeVect::empty(void) const {
2770   return false;
2771 }
2772 
2773 //------------------------------dump2------------------------------------------
2774 #ifndef PRODUCT
2775 void TypeVect::dump2(Dict& d, uint depth, outputStream* st) const {
2776   switch (base()) {
2777   case VectorA:
2778     st->print("vectora"); break;
2779   case VectorS:
2780     st->print("vectors"); break;
2781   case VectorD:
2782     st->print("vectord"); break;
2783   case VectorX:
2784     st->print("vectorx"); break;
2785   case VectorY:
2786     st->print("vectory"); break;
2787   case VectorZ:
2788     st->print("vectorz"); break;
2789   case VectorMask:
2790     st->print("vectormask"); break;
2791   default:
2792     ShouldNotReachHere();
2793   }
2794   st->print("<%c,%u>", type2char(element_basic_type()), length());
2795 }
2796 #endif
2797 
2798 const TypePVectMask* TypePVectMask::make(const BasicType elem_bt, uint length) {
2799   return (TypePVectMask*) (new TypePVectMask(elem_bt, length))->hashcons();
2800 }
2801 
2802 //=============================================================================
2803 // Convenience common pre-built types.
2804 const TypePtr *TypePtr::NULL_PTR;
2805 const TypePtr *TypePtr::NOTNULL;
2806 const TypePtr *TypePtr::BOTTOM;
2807 
2808 //------------------------------meet-------------------------------------------
2809 // Meet over the PTR enum
2810 const TypePtr::PTR TypePtr::ptr_meet[TypePtr::lastPTR][TypePtr::lastPTR] = {
2811   //              TopPTR,    AnyNull,   Constant, Null,   NotNull, BotPTR,
2812   { /* Top     */ TopPTR,    AnyNull,   Constant, Null,   NotNull, BotPTR,},
2813   { /* AnyNull */ AnyNull,   AnyNull,   Constant, BotPTR, NotNull, BotPTR,},
2814   { /* Constant*/ Constant,  Constant,  Constant, BotPTR, NotNull, BotPTR,},
2815   { /* Null    */ Null,      BotPTR,    BotPTR,   Null,   BotPTR,  BotPTR,},
2816   { /* NotNull */ NotNull,   NotNull,   NotNull,  BotPTR, NotNull, BotPTR,},
2817   { /* BotPTR  */ BotPTR,    BotPTR,    BotPTR,   BotPTR, BotPTR,  BotPTR,}
2818 };
2819 
2820 //------------------------------make-------------------------------------------
2821 const TypePtr* TypePtr::make(TYPES t, enum PTR ptr, Offset offset,
2822                              const TypePtr* speculative, int inline_depth,
2823                              relocInfo::relocType reloc) {
2824   return (TypePtr*)(new TypePtr(t, ptr, offset, reloc, speculative, inline_depth))->hashcons();
2825 }
2826 
2827 //------------------------------cast_to_ptr_type-------------------------------
2828 const TypePtr* TypePtr::cast_to_ptr_type(PTR ptr) const {
2829   assert(_base == AnyPtr, "subclass must override cast_to_ptr_type");
2830   if( ptr == _ptr ) return this;
2831   return make(_base, ptr, _offset, _speculative, _inline_depth, _reloc);
2832 }
2833 
2834 //------------------------------get_con----------------------------------------
2835 intptr_t TypePtr::get_con() const {
2836   assert( _ptr == Null, "" );
2837   return offset();
2838 }
2839 
2840 //------------------------------meet-------------------------------------------
2841 // Compute the MEET of two types.  It returns a new Type object.
2842 const Type *TypePtr::xmeet(const Type *t) const {
2843   const Type* res = xmeet_helper(t);
2844   if (res->isa_ptr() == nullptr) {
2845     return res;
2846   }
2847 
2848   const TypePtr* res_ptr = res->is_ptr();
2849   if (res_ptr->speculative() != nullptr) {
2850     // type->speculative() is null means that speculation is no better
2851     // than type, i.e. type->speculative() == type. So there are 2
2852     // ways to represent the fact that we have no useful speculative
2853     // data and we should use a single one to be able to test for
2854     // equality between types. Check whether type->speculative() ==
2855     // type and set speculative to null if it is the case.
2856     if (res_ptr->remove_speculative() == res_ptr->speculative()) {
2857       return res_ptr->remove_speculative();
2858     }
2859   }
2860 
2861   return res;
2862 }
2863 
2864 const Type *TypePtr::xmeet_helper(const Type *t) const {
2865   // Perform a fast test for common case; meeting the same types together.
2866   if( this == t ) return this;  // Meeting same type-rep?
2867 
2868   // Current "this->_base" is AnyPtr
2869   switch (t->base()) {          // switch on original type
2870   case Int:                     // Mixing ints & oops happens when javac
2871   case Long:                    // reuses local variables
2872   case HalfFloatTop:
2873   case HalfFloatCon:
2874   case HalfFloatBot:
2875   case FloatTop:
2876   case FloatCon:
2877   case FloatBot:
2878   case DoubleTop:
2879   case DoubleCon:
2880   case DoubleBot:
2881   case NarrowOop:
2882   case NarrowKlass:
2883   case Bottom:                  // Ye Olde Default
2884     return Type::BOTTOM;
2885   case Top:
2886     return this;
2887 
2888   case AnyPtr: {                // Meeting to AnyPtrs
2889     const TypePtr *tp = t->is_ptr();
2890     const TypePtr* speculative = xmeet_speculative(tp);
2891     int depth = meet_inline_depth(tp->inline_depth());
2892     return make(AnyPtr, meet_ptr(tp->ptr()), meet_offset(tp->offset()), speculative, depth);
2893   }
2894   case RawPtr:                  // For these, flip the call around to cut down
2895   case OopPtr:
2896   case InstPtr:                 // on the cases I have to handle.
2897   case AryPtr:
2898   case MetadataPtr:
2899   case KlassPtr:
2900   case InstKlassPtr:
2901   case AryKlassPtr:
2902     return t->xmeet(this);      // Call in reverse direction
2903   default:                      // All else is a mistake
2904     typerr(t);
2905 
2906   }
2907   return this;
2908 }
2909 
2910 //------------------------------meet_offset------------------------------------
2911 Type::Offset TypePtr::meet_offset(int offset) const {
2912   return _offset.meet(Offset(offset));
2913 }
2914 
2915 //------------------------------dual_offset------------------------------------
2916 Type::Offset TypePtr::dual_offset() const {
2917   return _offset.dual();
2918 }
2919 
2920 //------------------------------xdual------------------------------------------
2921 // Dual: compute field-by-field dual
2922 const TypePtr::PTR TypePtr::ptr_dual[TypePtr::lastPTR] = {
2923   BotPTR, NotNull, Constant, Null, AnyNull, TopPTR
2924 };
2925 
2926 const TypePtr::FlatInArray TypePtr::flat_in_array_dual[Uninitialized] = {
2927   /* TopFlat   -> */ MaybeFlat,
2928   /* Flat      -> */ NotFlat,
2929   /* NotFlat   -> */ Flat,
2930   /* MaybeFlat -> */ TopFlat
2931 };
2932 
2933 const char* const TypePtr::flat_in_array_msg[Uninitialized] = {
2934   "TOP flat in array", "flat in array", "not flat in array", "maybe flat in array"
2935 };
2936 
2937 const Type *TypePtr::xdual() const {
2938   return new TypePtr(AnyPtr, dual_ptr(), dual_offset(), relocInfo::none, dual_speculative(), dual_inline_depth());
2939 }
2940 
2941 //------------------------------xadd_offset------------------------------------
2942 Type::Offset TypePtr::xadd_offset(intptr_t offset) const {
2943   return _offset.add(offset);
2944 }
2945 
2946 //------------------------------add_offset-------------------------------------
2947 const TypePtr *TypePtr::add_offset( intptr_t offset ) const {
2948   return make(AnyPtr, _ptr, xadd_offset(offset), _speculative, _inline_depth, _reloc);
2949 }
2950 
2951 const TypePtr *TypePtr::with_offset(intptr_t offset) const {
2952   return make(AnyPtr, _ptr, Offset(offset), _speculative, _inline_depth, _reloc);
2953 }
2954 
2955 //------------------------------eq---------------------------------------------
2956 // Structural equality check for Type representations
2957 bool TypePtr::eq( const Type *t ) const {
2958   const TypePtr *a = (const TypePtr*)t;
2959   return _ptr == a->ptr() && offset() == a->offset() && _reloc == a->reloc() &&
2960          eq_speculative(a) && _inline_depth == a->_inline_depth;
2961 }
2962 
2963 //------------------------------hash-------------------------------------------
2964 // Type-specific hashing function.
2965 uint TypePtr::hash(void) const {
2966  return (uint)_ptr + (uint)offset() + (uint)_reloc + (uint)hash_speculative() + (uint)_inline_depth;
2967 }
2968 
2969 /**
2970  * Return same type without a speculative part
2971  */
2972 const TypePtr* TypePtr::remove_speculative() const {
2973   if (_speculative == nullptr) {
2974     return this;
2975   }
2976   assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth");
2977   return make(AnyPtr, _ptr, _offset, nullptr, _inline_depth, _reloc);
2978 }
2979 
2980 /**
2981  * Return same type but drop speculative part if we know we won't use
2982  * it
2983  */
2984 const Type* TypePtr::cleanup_speculative() const {
2985   if (speculative() == nullptr) {
2986     return this;
2987   }
2988   const Type* no_spec = remove_speculative();
2989   // If this is NULL_PTR then we don't need the speculative type
2990   // (with_inline_depth in case the current type inline depth is
2991   // InlineDepthTop)
2992   if (no_spec == NULL_PTR->with_inline_depth(inline_depth())) {
2993     return no_spec;
2994   }
2995   if (above_centerline(speculative()->ptr())) {
2996     return no_spec;
2997   }
2998   const TypeOopPtr* spec_oopptr = speculative()->isa_oopptr();
2999   // If the speculative may be null and is an inexact klass then it
3000   // doesn't help
3001   if (speculative() != TypePtr::NULL_PTR && speculative()->maybe_null() &&
3002       (spec_oopptr == nullptr || !spec_oopptr->klass_is_exact())) {
3003     return no_spec;
3004   }
3005   return this;
3006 }
3007 
3008 /**
3009  * dual of the speculative part of the type
3010  */
3011 const TypePtr* TypePtr::dual_speculative() const {
3012   if (_speculative == nullptr) {
3013     return nullptr;
3014   }
3015   return _speculative->dual()->is_ptr();
3016 }
3017 
3018 /**
3019  * meet of the speculative parts of 2 types
3020  *
3021  * @param other  type to meet with
3022  */
3023 const TypePtr* TypePtr::xmeet_speculative(const TypePtr* other) const {
3024   bool this_has_spec = (_speculative != nullptr);
3025   bool other_has_spec = (other->speculative() != nullptr);
3026 
3027   if (!this_has_spec && !other_has_spec) {
3028     return nullptr;
3029   }
3030 
3031   // If we are at a point where control flow meets and one branch has
3032   // a speculative type and the other has not, we meet the speculative
3033   // type of one branch with the actual type of the other. If the
3034   // actual type is exact and the speculative is as well, then the
3035   // result is a speculative type which is exact and we can continue
3036   // speculation further.
3037   const TypePtr* this_spec = _speculative;
3038   const TypePtr* other_spec = other->speculative();
3039 
3040   if (!this_has_spec) {
3041     this_spec = this;
3042   }
3043 
3044   if (!other_has_spec) {
3045     other_spec = other;
3046   }
3047 
3048   return this_spec->meet(other_spec)->is_ptr();
3049 }
3050 
3051 /**
3052  * dual of the inline depth for this type (used for speculation)
3053  */
3054 int TypePtr::dual_inline_depth() const {
3055   return -inline_depth();
3056 }
3057 
3058 /**
3059  * meet of 2 inline depths (used for speculation)
3060  *
3061  * @param depth  depth to meet with
3062  */
3063 int TypePtr::meet_inline_depth(int depth) const {
3064   return MAX2(inline_depth(), depth);
3065 }
3066 
3067 /**
3068  * Are the speculative parts of 2 types equal?
3069  *
3070  * @param other  type to compare this one to
3071  */
3072 bool TypePtr::eq_speculative(const TypePtr* other) const {
3073   if (_speculative == nullptr || other->speculative() == nullptr) {
3074     return _speculative == other->speculative();
3075   }
3076 
3077   if (_speculative->base() != other->speculative()->base()) {
3078     return false;
3079   }
3080 
3081   return _speculative->eq(other->speculative());
3082 }
3083 
3084 /**
3085  * Hash of the speculative part of the type
3086  */
3087 int TypePtr::hash_speculative() const {
3088   if (_speculative == nullptr) {
3089     return 0;
3090   }
3091 
3092   return _speculative->hash();
3093 }
3094 
3095 /**
3096  * add offset to the speculative part of the type
3097  *
3098  * @param offset  offset to add
3099  */
3100 const TypePtr* TypePtr::add_offset_speculative(intptr_t offset) const {
3101   if (_speculative == nullptr) {
3102     return nullptr;
3103   }
3104   return _speculative->add_offset(offset)->is_ptr();
3105 }
3106 
3107 const TypePtr* TypePtr::with_offset_speculative(intptr_t offset) const {
3108   if (_speculative == nullptr) {
3109     return nullptr;
3110   }
3111   return _speculative->with_offset(offset)->is_ptr();
3112 }
3113 
3114 /**
3115  * return exact klass from the speculative type if there's one
3116  */
3117 ciKlass* TypePtr::speculative_type() const {
3118   if (_speculative != nullptr && _speculative->isa_oopptr()) {
3119     const TypeOopPtr* speculative = _speculative->join(this)->is_oopptr();
3120     if (speculative->klass_is_exact()) {
3121       return speculative->exact_klass();
3122     }
3123   }
3124   return nullptr;
3125 }
3126 
3127 /**
3128  * return true if speculative type may be null
3129  */
3130 bool TypePtr::speculative_maybe_null() const {
3131   if (_speculative != nullptr) {
3132     const TypePtr* speculative = _speculative->join(this)->is_ptr();
3133     return speculative->maybe_null();
3134   }
3135   return true;
3136 }
3137 
3138 bool TypePtr::speculative_always_null() const {
3139   if (_speculative != nullptr) {
3140     const TypePtr* speculative = _speculative->join(this)->is_ptr();
3141     return speculative == TypePtr::NULL_PTR;
3142   }
3143   return false;
3144 }
3145 
3146 /**
3147  * Same as TypePtr::speculative_type() but return the klass only if
3148  * the speculative tells us is not null
3149  */
3150 ciKlass* TypePtr::speculative_type_not_null() const {
3151   if (speculative_maybe_null()) {
3152     return nullptr;
3153   }
3154   return speculative_type();
3155 }
3156 
3157 /**
3158  * Check whether new profiling would improve speculative type
3159  *
3160  * @param   exact_kls    class from profiling
3161  * @param   inline_depth inlining depth of profile point
3162  *
3163  * @return  true if type profile is valuable
3164  */
3165 bool TypePtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const {
3166   // no profiling?
3167   if (exact_kls == nullptr) {
3168     return false;
3169   }
3170   if (speculative() == TypePtr::NULL_PTR) {
3171     return false;
3172   }
3173   // no speculative type or non exact speculative type?
3174   if (speculative_type() == nullptr) {
3175     return true;
3176   }
3177   // If the node already has an exact speculative type keep it,
3178   // unless it was provided by profiling that is at a deeper
3179   // inlining level. Profiling at a higher inlining depth is
3180   // expected to be less accurate.
3181   if (_speculative->inline_depth() == InlineDepthBottom) {
3182     return false;
3183   }
3184   assert(_speculative->inline_depth() != InlineDepthTop, "can't do the comparison");
3185   return inline_depth < _speculative->inline_depth();
3186 }
3187 
3188 /**
3189  * Check whether new profiling would improve ptr (= tells us it is non
3190  * null)
3191  *
3192  * @param   ptr_kind always null or not null?
3193  *
3194  * @return  true if ptr profile is valuable
3195  */
3196 bool TypePtr::would_improve_ptr(ProfilePtrKind ptr_kind) const {
3197   // profiling doesn't tell us anything useful
3198   if (ptr_kind != ProfileAlwaysNull && ptr_kind != ProfileNeverNull) {
3199     return false;
3200   }
3201   // We already know this is not null
3202   if (!this->maybe_null()) {
3203     return false;
3204   }
3205   // We already know the speculative type cannot be null
3206   if (!speculative_maybe_null()) {
3207     return false;
3208   }
3209   // We already know this is always null
3210   if (this == TypePtr::NULL_PTR) {
3211     return false;
3212   }
3213   // We already know the speculative type is always null
3214   if (speculative_always_null()) {
3215     return false;
3216   }
3217   if (ptr_kind == ProfileAlwaysNull && speculative() != nullptr && speculative()->isa_oopptr()) {
3218     return false;
3219   }
3220   return true;
3221 }
3222 
3223 TypePtr::FlatInArray TypePtr::compute_flat_in_array(ciInstanceKlass* instance_klass, bool is_exact) {
3224   if (!instance_klass->can_be_inline_klass(is_exact) || !UseArrayFlattening) {
3225     // Definitely not a value class, or flattening is not even enabled, and thus never flat in an array.
3226     return NotFlat;
3227   }
3228   if (instance_klass->is_inlinetype()) {
3229     if (instance_klass->as_inline_klass()->is_always_flat_in_array()) {
3230       return Flat;
3231     }
3232     if (instance_klass->as_inline_klass()->maybe_flat_in_array()) {
3233       return MaybeFlat;
3234     }
3235     return NotFlat;
3236   }
3237   // It's not an inline class, but can still be, so we don't know.
3238   return MaybeFlat;
3239 }
3240 
3241 // Compute flat in array property if we don't know anything about it (i.e. old_flat_in_array == MaybeFlat).
3242 TypePtr::FlatInArray TypePtr::compute_flat_in_array_if_unknown(ciInstanceKlass* instance_klass, bool is_exact,
3243   FlatInArray old_flat_in_array) {
3244   // It is tempting to add verification code that "NotFlat == no value class" and "Flat == value class".
3245   // However, with type speculation, we could get contradicting flat in array properties that propagate through the
3246   // graph. We could try to stop the introduction of contradicting speculative types in terms of their flat in array
3247   // property. But this is hard because it is sometimes only recognized further down in the graph. Thus, we let an
3248   // inconsistent flat in array property propagating through the graph. This could lead to fold an actual live path
3249   // away. But in this case, the speculated type is wrong and we would trap earlier.
3250   if (old_flat_in_array == MaybeFlat) {
3251       return compute_flat_in_array(instance_klass, is_exact);
3252   }
3253   return old_flat_in_array;
3254 }
3255 
3256 //------------------------------dump2------------------------------------------
3257 const char *const TypePtr::ptr_msg[TypePtr::lastPTR] = {
3258   "TopPTR","AnyNull","Constant","null","NotNull","BotPTR"
3259 };
3260 
3261 #ifndef PRODUCT
3262 void TypePtr::dump2( Dict &d, uint depth, outputStream *st ) const {
3263   st->print("ptr:%s", ptr_msg[_ptr]);
3264   dump_offset(st);
3265   dump_inline_depth(st);
3266   dump_speculative(st);
3267 }
3268 
3269 void TypePtr::dump_offset(outputStream* st) const {
3270   _offset.dump2(st);
3271 }
3272 
3273 /**
3274  *dump the speculative part of the type
3275  */
3276 void TypePtr::dump_speculative(outputStream *st) const {
3277   if (_speculative != nullptr) {
3278     st->print(" (speculative=");
3279     _speculative->dump_on(st);
3280     st->print(")");
3281   }
3282 }
3283 
3284 /**
3285  *dump the inline depth of the type
3286  */
3287 void TypePtr::dump_inline_depth(outputStream *st) const {
3288   if (_inline_depth != InlineDepthBottom) {
3289     if (_inline_depth == InlineDepthTop) {
3290       st->print(" (inline_depth=InlineDepthTop)");
3291     } else {
3292       st->print(" (inline_depth=%d)", _inline_depth);
3293     }
3294   }
3295 }
3296 
3297 void TypePtr::dump_flat_in_array(FlatInArray flat_in_array, outputStream* st) {
3298   switch (flat_in_array) {
3299     case MaybeFlat:
3300     case NotFlat:
3301       if (!Verbose) {
3302         break;
3303       }
3304     case TopFlat:
3305     case Flat:
3306       st->print(" (%s)", flat_in_array_msg[flat_in_array]);
3307       break;
3308     default:
3309       ShouldNotReachHere();
3310   }
3311 }
3312 #endif
3313 
3314 //------------------------------singleton--------------------------------------
3315 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
3316 // constants
3317 bool TypePtr::singleton(void) const {
3318   // TopPTR, Null, AnyNull, Constant are all singletons
3319   return (_offset != Offset::bottom) && !below_centerline(_ptr);
3320 }
3321 
3322 bool TypePtr::empty(void) const {
3323   return (_offset == Offset::top) || above_centerline(_ptr);
3324 }
3325 
3326 //=============================================================================
3327 // Convenience common pre-built types.
3328 const TypeRawPtr *TypeRawPtr::BOTTOM;
3329 const TypeRawPtr *TypeRawPtr::NOTNULL;
3330 
3331 //------------------------------make-------------------------------------------
3332 const TypeRawPtr *TypeRawPtr::make( enum PTR ptr ) {
3333   assert( ptr != Constant, "what is the constant?" );
3334   assert( ptr != Null, "Use TypePtr for null" );
3335   return (TypeRawPtr*)(new TypeRawPtr(ptr, nullptr, relocInfo::none))->hashcons();
3336 }
3337 
3338 const TypeRawPtr* TypeRawPtr::make(address bits, relocInfo::relocType reloc) {
3339   assert(bits != nullptr, "Use TypePtr for null");
3340   return (TypeRawPtr*)(new TypeRawPtr(Constant, bits, reloc))->hashcons();
3341 }
3342 
3343 //------------------------------cast_to_ptr_type-------------------------------
3344 const TypeRawPtr* TypeRawPtr::cast_to_ptr_type(PTR ptr) const {
3345   assert( ptr != Constant, "what is the constant?" );
3346   assert( ptr != Null, "Use TypePtr for null" );
3347   assert( _bits == nullptr, "Why cast a constant address?");
3348   if( ptr == _ptr ) return this;
3349   return make(ptr);
3350 }
3351 
3352 //------------------------------get_con----------------------------------------
3353 intptr_t TypeRawPtr::get_con() const {
3354   assert( _ptr == Null || _ptr == Constant, "" );
3355   return (intptr_t)_bits;
3356 }
3357 
3358 //------------------------------meet-------------------------------------------
3359 // Compute the MEET of two types.  It returns a new Type object.
3360 const Type *TypeRawPtr::xmeet( const Type *t ) const {
3361   // Perform a fast test for common case; meeting the same types together.
3362   if( this == t ) return this;  // Meeting same type-rep?
3363 
3364   // Current "this->_base" is RawPtr
3365   switch( t->base() ) {         // switch on original type
3366   case Bottom:                  // Ye Olde Default
3367     return t;
3368   case Top:
3369     return this;
3370   case AnyPtr:                  // Meeting to AnyPtrs
3371     break;
3372   case RawPtr: {                // might be top, bot, any/not or constant
3373     enum PTR tptr = t->is_ptr()->ptr();
3374     enum PTR ptr = meet_ptr( tptr );
3375     if( ptr == Constant ) {     // Cannot be equal constants, so...
3376       if( tptr == Constant && _ptr != Constant)  return t;
3377       if( _ptr == Constant && tptr != Constant)  return this;
3378       ptr = NotNull;            // Fall down in lattice
3379     }
3380     return make( ptr );
3381   }
3382 
3383   case OopPtr:
3384   case InstPtr:
3385   case AryPtr:
3386   case MetadataPtr:
3387   case KlassPtr:
3388   case InstKlassPtr:
3389   case AryKlassPtr:
3390     return TypePtr::BOTTOM;     // Oop meet raw is not well defined
3391   default:                      // All else is a mistake
3392     typerr(t);
3393   }
3394 
3395   // Found an AnyPtr type vs self-RawPtr type
3396   const TypePtr *tp = t->is_ptr();
3397   switch (tp->ptr()) {
3398   case TypePtr::TopPTR:  return this;
3399   case TypePtr::BotPTR:  return t;
3400   case TypePtr::Null:
3401     if( _ptr == TypePtr::TopPTR ) return t;
3402     return TypeRawPtr::BOTTOM;
3403   case TypePtr::NotNull: return TypePtr::make(AnyPtr, meet_ptr(TypePtr::NotNull), tp->meet_offset(0), tp->speculative(), tp->inline_depth());
3404   case TypePtr::AnyNull:
3405     if( _ptr == TypePtr::Constant) return this;
3406     return make( meet_ptr(TypePtr::AnyNull) );
3407   default: ShouldNotReachHere();
3408   }
3409   return this;
3410 }
3411 
3412 //------------------------------xdual------------------------------------------
3413 // Dual: compute field-by-field dual
3414 const Type *TypeRawPtr::xdual() const {
3415   return new TypeRawPtr(dual_ptr(), _bits, _reloc);
3416 }
3417 
3418 //------------------------------add_offset-------------------------------------
3419 const TypePtr* TypeRawPtr::add_offset(intptr_t offset) const {
3420   if( offset == OffsetTop ) return BOTTOM; // Undefined offset-> undefined pointer
3421   if( offset == OffsetBot ) return BOTTOM; // Unknown offset-> unknown pointer
3422   if( offset == 0 ) return this; // No change
3423   switch (_ptr) {
3424   case TypePtr::TopPTR:
3425   case TypePtr::BotPTR:
3426   case TypePtr::NotNull:
3427     return this;
3428   case TypePtr::Constant: {
3429     uintptr_t bits = (uintptr_t)_bits;
3430     uintptr_t sum = bits + offset;
3431     if (( offset < 0 )
3432         ? ( sum > bits )        // Underflow?
3433         : ( sum < bits )) {     // Overflow?
3434       return BOTTOM;
3435     } else if ( sum == 0 ) {
3436       return TypePtr::NULL_PTR;
3437     } else {
3438       return make((address)sum, _reloc);
3439     }
3440   }
3441   default:  ShouldNotReachHere();
3442   }
3443 }
3444 
3445 //------------------------------eq---------------------------------------------
3446 // Structural equality check for Type representations
3447 bool TypeRawPtr::eq( const Type *t ) const {
3448   const TypeRawPtr *a = (const TypeRawPtr*)t;
3449   return _bits == a->_bits && TypePtr::eq(t);
3450 }
3451 
3452 //------------------------------hash-------------------------------------------
3453 // Type-specific hashing function.
3454 uint TypeRawPtr::hash(void) const {
3455   return (uint)(uintptr_t)_bits + (uint)TypePtr::hash();
3456 }
3457 
3458 //------------------------------dump2------------------------------------------
3459 #ifndef PRODUCT
3460 void TypeRawPtr::dump2(Dict& d, uint depth, outputStream* st) const {
3461   if (_ptr == Constant) {
3462     st->print("rawptr:Constant:" INTPTR_FORMAT, p2i(_bits));
3463   } else {
3464     st->print("rawptr:%s", ptr_msg[_ptr]);
3465   }
3466 }
3467 #endif
3468 
3469 //=============================================================================
3470 // Convenience common pre-built type.
3471 const TypeOopPtr *TypeOopPtr::BOTTOM;
3472 
3473 TypeInterfaces::TypeInterfaces(ciInstanceKlass** interfaces_base, int nb_interfaces)
3474         : Type(Interfaces), _interfaces(interfaces_base, nb_interfaces),
3475           _hash(0), _exact_klass(nullptr) {
3476   _interfaces.sort(compare);
3477   initialize();
3478 }
3479 
3480 const TypeInterfaces* TypeInterfaces::make(GrowableArray<ciInstanceKlass*>* interfaces) {
3481   // hashcons() can only delete the last thing that was allocated: to
3482   // make sure all memory for the newly created TypeInterfaces can be
3483   // freed if an identical one exists, allocate space for the array of
3484   // interfaces right after the TypeInterfaces object so that they
3485   // form a contiguous piece of memory.
3486   int nb_interfaces = interfaces == nullptr ? 0 : interfaces->length();
3487   size_t total_size = sizeof(TypeInterfaces) + nb_interfaces * sizeof(ciInstanceKlass*);
3488 
3489   void* allocated_mem = operator new(total_size);
3490   ciInstanceKlass** interfaces_base = (ciInstanceKlass**)((char*)allocated_mem + sizeof(TypeInterfaces));
3491   for (int i = 0; i < nb_interfaces; ++i) {
3492     interfaces_base[i] = interfaces->at(i);
3493   }
3494   TypeInterfaces* result = ::new (allocated_mem) TypeInterfaces(interfaces_base, nb_interfaces);
3495   return (const TypeInterfaces*)result->hashcons();
3496 }
3497 
3498 void TypeInterfaces::initialize() {
3499   compute_hash();
3500   compute_exact_klass();
3501   DEBUG_ONLY(_initialized = true;)
3502 }
3503 
3504 int TypeInterfaces::compare(ciInstanceKlass* const& k1, ciInstanceKlass* const& k2) {
3505   if ((intptr_t)k1 < (intptr_t)k2) {
3506     return -1;
3507   } else if ((intptr_t)k1 > (intptr_t)k2) {
3508     return 1;
3509   }
3510   return 0;
3511 }
3512 
3513 int TypeInterfaces::compare(ciInstanceKlass** k1, ciInstanceKlass** k2) {
3514   return compare(*k1, *k2);
3515 }
3516 
3517 bool TypeInterfaces::eq(const Type* t) const {
3518   const TypeInterfaces* other = (const TypeInterfaces*)t;
3519   if (_interfaces.length() != other->_interfaces.length()) {
3520     return false;
3521   }
3522   for (int i = 0; i < _interfaces.length(); i++) {
3523     ciKlass* k1 = _interfaces.at(i);
3524     ciKlass* k2 = other->_interfaces.at(i);
3525     if (!k1->equals(k2)) {
3526       return false;
3527     }
3528   }
3529   return true;
3530 }
3531 
3532 bool TypeInterfaces::eq(ciInstanceKlass* k) const {
3533   assert(k->is_loaded(), "should be loaded");
3534   GrowableArray<ciInstanceKlass *>* interfaces = k->transitive_interfaces();
3535   if (_interfaces.length() != interfaces->length()) {
3536     return false;
3537   }
3538   for (int i = 0; i < interfaces->length(); i++) {
3539     bool found = false;
3540     _interfaces.find_sorted<ciInstanceKlass*, compare>(interfaces->at(i), found);
3541     if (!found) {
3542       return false;
3543     }
3544   }
3545   return true;
3546 }
3547 
3548 // Check whether an instance of type k will satisfy this
3549 bool TypeInterfaces::is_subset(ciInstanceKlass* k) const {
3550   assert(k->is_loaded(), "should be loaded");
3551   GrowableArray<ciInstanceKlass*>* k_interfaces = k->transitive_interfaces();
3552   for (int i = 0; i < _interfaces.length(); i++) {
3553     if (!k_interfaces->contains(_interfaces.at(i))) {
3554       return false;
3555     }
3556   }
3557   return true;
3558 }
3559 
3560 uint TypeInterfaces::hash() const {
3561   assert(_initialized, "must be");
3562   return _hash;
3563 }
3564 
3565 const Type* TypeInterfaces::xdual() const {
3566   return this;
3567 }
3568 
3569 void TypeInterfaces::compute_hash() {
3570   uint hash = 0;
3571   for (int i = 0; i < _interfaces.length(); i++) {
3572     ciKlass* k = _interfaces.at(i);
3573     hash += k->hash();
3574   }
3575   _hash = hash;
3576 }
3577 
3578 static int compare_interfaces(ciInstanceKlass** k1, ciInstanceKlass** k2) {
3579   return (int)((*k1)->ident() - (*k2)->ident());
3580 }
3581 
3582 void TypeInterfaces::dump(outputStream* st) const {
3583   if (_interfaces.length() == 0) {
3584     return;
3585   }
3586   ResourceMark rm;
3587   st->print(" (");
3588   GrowableArray<ciInstanceKlass*> interfaces;
3589   interfaces.appendAll(&_interfaces);
3590   // Sort the interfaces so they are listed in the same order from one run to the other of the same compilation
3591   interfaces.sort(compare_interfaces);
3592   for (int i = 0; i < interfaces.length(); i++) {
3593     if (i > 0) {
3594       st->print(",");
3595     }
3596     ciKlass* k = interfaces.at(i);
3597     k->print_name_on(st);
3598   }
3599   st->print(")");
3600 }
3601 
3602 #ifdef ASSERT
3603 void TypeInterfaces::verify() const {
3604   for (int i = 1; i < _interfaces.length(); i++) {
3605     ciInstanceKlass* k1 = _interfaces.at(i-1);
3606     ciInstanceKlass* k2 = _interfaces.at(i);
3607     assert(compare(k2, k1) > 0, "should be ordered");
3608     assert(k1 != k2, "no duplicate");
3609   }
3610 }
3611 #endif
3612 
3613 const TypeInterfaces* TypeInterfaces::union_with(const TypeInterfaces* other) const {
3614   GrowableArray<ciInstanceKlass*> result_list;
3615   int i = 0;
3616   int j = 0;
3617   while (i < _interfaces.length() || j < other->_interfaces.length()) {
3618     while (i < _interfaces.length() &&
3619            (j >= other->_interfaces.length() ||
3620             compare(_interfaces.at(i), other->_interfaces.at(j)) < 0)) {
3621       result_list.push(_interfaces.at(i));
3622       i++;
3623     }
3624     while (j < other->_interfaces.length() &&
3625            (i >= _interfaces.length() ||
3626             compare(other->_interfaces.at(j), _interfaces.at(i)) < 0)) {
3627       result_list.push(other->_interfaces.at(j));
3628       j++;
3629     }
3630     if (i < _interfaces.length() &&
3631         j < other->_interfaces.length() &&
3632         _interfaces.at(i) == other->_interfaces.at(j)) {
3633       result_list.push(_interfaces.at(i));
3634       i++;
3635       j++;
3636     }
3637   }
3638   const TypeInterfaces* result = TypeInterfaces::make(&result_list);
3639 #ifdef ASSERT
3640   result->verify();
3641   for (int i = 0; i < _interfaces.length(); i++) {
3642     assert(result->_interfaces.contains(_interfaces.at(i)), "missing");
3643   }
3644   for (int i = 0; i < other->_interfaces.length(); i++) {
3645     assert(result->_interfaces.contains(other->_interfaces.at(i)), "missing");
3646   }
3647   for (int i = 0; i < result->_interfaces.length(); i++) {
3648     assert(_interfaces.contains(result->_interfaces.at(i)) || other->_interfaces.contains(result->_interfaces.at(i)), "missing");
3649   }
3650 #endif
3651   return result;
3652 }
3653 
3654 const TypeInterfaces* TypeInterfaces::intersection_with(const TypeInterfaces* other) const {
3655   GrowableArray<ciInstanceKlass*> result_list;
3656   int i = 0;
3657   int j = 0;
3658   while (i < _interfaces.length() || j < other->_interfaces.length()) {
3659     while (i < _interfaces.length() &&
3660            (j >= other->_interfaces.length() ||
3661             compare(_interfaces.at(i), other->_interfaces.at(j)) < 0)) {
3662       i++;
3663     }
3664     while (j < other->_interfaces.length() &&
3665            (i >= _interfaces.length() ||
3666             compare(other->_interfaces.at(j), _interfaces.at(i)) < 0)) {
3667       j++;
3668     }
3669     if (i < _interfaces.length() &&
3670         j < other->_interfaces.length() &&
3671         _interfaces.at(i) == other->_interfaces.at(j)) {
3672       result_list.push(_interfaces.at(i));
3673       i++;
3674       j++;
3675     }
3676   }
3677   const TypeInterfaces* result = TypeInterfaces::make(&result_list);
3678 #ifdef ASSERT
3679   result->verify();
3680   for (int i = 0; i < _interfaces.length(); i++) {
3681     assert(!other->_interfaces.contains(_interfaces.at(i)) || result->_interfaces.contains(_interfaces.at(i)), "missing");
3682   }
3683   for (int i = 0; i < other->_interfaces.length(); i++) {
3684     assert(!_interfaces.contains(other->_interfaces.at(i)) || result->_interfaces.contains(other->_interfaces.at(i)), "missing");
3685   }
3686   for (int i = 0; i < result->_interfaces.length(); i++) {
3687     assert(_interfaces.contains(result->_interfaces.at(i)) && other->_interfaces.contains(result->_interfaces.at(i)), "missing");
3688   }
3689 #endif
3690   return result;
3691 }
3692 
3693 // Is there a single ciKlass* that can represent the interface set?
3694 ciInstanceKlass* TypeInterfaces::exact_klass() const {
3695   assert(_initialized, "must be");
3696   return _exact_klass;
3697 }
3698 
3699 void TypeInterfaces::compute_exact_klass() {
3700   if (_interfaces.length() == 0) {
3701     _exact_klass = nullptr;
3702     return;
3703   }
3704   ciInstanceKlass* res = nullptr;
3705   for (int i = 0; i < _interfaces.length(); i++) {
3706     ciInstanceKlass* interface = _interfaces.at(i);
3707     if (eq(interface)) {
3708       assert(res == nullptr, "");
3709       res = interface;
3710     }
3711   }
3712   _exact_klass = res;
3713 }
3714 
3715 #ifdef ASSERT
3716 void TypeInterfaces::verify_is_loaded() const {
3717   for (int i = 0; i < _interfaces.length(); i++) {
3718     ciKlass* interface = _interfaces.at(i);
3719     assert(interface->is_loaded(), "Interface not loaded");
3720   }
3721 }
3722 #endif
3723 
3724 // Can't be implemented because there's no way to know if the type is above or below the center line.
3725 const Type* TypeInterfaces::xmeet(const Type* t) const {
3726   ShouldNotReachHere();
3727   return Type::xmeet(t);
3728 }
3729 
3730 bool TypeInterfaces::singleton(void) const {
3731   ShouldNotReachHere();
3732   return Type::singleton();
3733 }
3734 
3735 bool TypeInterfaces::has_non_array_interface() const {
3736   assert(TypeAryPtr::_array_interfaces != nullptr, "How come Type::Initialize_shared wasn't called yet?");
3737 
3738   return !TypeAryPtr::_array_interfaces->contains(this);
3739 }
3740 
3741 //------------------------------TypeOopPtr-------------------------------------
3742 TypeOopPtr::TypeOopPtr(TYPES t, PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, bool xk, ciObject* o, Offset offset, Offset field_offset,
3743                        int instance_id, const TypePtr* speculative, int inline_depth)
3744   : TypePtr(t, ptr, offset, relocInfo::oop_type, speculative, inline_depth),
3745     _const_oop(o), _klass(k),
3746     _interfaces(interfaces),
3747     _klass_is_exact(xk),
3748     _is_ptr_to_narrowoop(false),
3749     _is_ptr_to_narrowklass(false),
3750     _is_ptr_to_boxed_value(false),
3751     _is_ptr_to_strict_final_field(false),
3752     _instance_id(instance_id) {
3753 #ifdef ASSERT
3754   if (klass() != nullptr && klass()->is_loaded()) {
3755     interfaces->verify_is_loaded();
3756   }
3757 #endif
3758   if (Compile::current()->eliminate_boxing() && (t == InstPtr) &&
3759       (offset.get() > 0) && xk && (k != nullptr) && k->is_instance_klass()) {
3760     _is_ptr_to_boxed_value = k->as_instance_klass()->is_boxed_value_offset(offset.get());
3761     _is_ptr_to_strict_final_field = _is_ptr_to_boxed_value;
3762   }
3763 
3764   if (klass() != nullptr && klass()->is_instance_klass() && klass()->is_loaded() &&
3765       this->offset() != Type::OffsetBot && this->offset() != Type::OffsetTop) {
3766     ciField* field = klass()->as_instance_klass()->get_field_by_offset(this->offset(), false);
3767     if (field != nullptr && field->is_strict() && field->is_final()) {
3768       _is_ptr_to_strict_final_field = true;
3769     }
3770   }
3771 
3772 #ifdef _LP64
3773   if (this->offset() > 0 || this->offset() == Type::OffsetTop || this->offset() == Type::OffsetBot) {
3774     if (this->offset() == oopDesc::klass_offset_in_bytes()) {
3775       _is_ptr_to_narrowklass = true;
3776     } else if (klass() == nullptr) {
3777       // Array with unknown body type
3778       assert(this->isa_aryptr(), "only arrays without klass");
3779       _is_ptr_to_narrowoop = UseCompressedOops;
3780     } else if (UseCompressedOops && this->isa_aryptr() && this->offset() != arrayOopDesc::length_offset_in_bytes()) {
3781       if (klass()->is_flat_array_klass() && field_offset != Offset::top && field_offset != Offset::bottom) {
3782         // Check if the field of the inline type array element contains oops
3783         ciInlineKlass* vk = klass()->as_flat_array_klass()->element_klass()->as_inline_klass();
3784         int foffset = field_offset.get() + vk->payload_offset();
3785         BasicType field_bt;
3786         ciField* field = vk->get_field_by_offset(foffset, false);
3787         if (field != nullptr) {
3788           field_bt = field->layout_type();
3789         } else {
3790           assert(field_offset.get() == vk->null_marker_offset_in_payload(), "no field or null marker of %s at offset %d", vk->name()->as_utf8(), foffset);
3791           field_bt = T_BOOLEAN;
3792         }
3793         _is_ptr_to_narrowoop = ::is_reference_type(field_bt);
3794       } else if (klass()->is_obj_array_klass()) {
3795         _is_ptr_to_narrowoop = true;
3796       }
3797     } else if (klass()->is_instance_klass()) {
3798       if (this->isa_klassptr()) {
3799         // Perm objects don't use compressed references
3800       } else if (_offset == Offset::bottom || _offset == Offset::top) {
3801         // unsafe access
3802         _is_ptr_to_narrowoop = UseCompressedOops;
3803       } else {
3804         assert(this->isa_instptr(), "must be an instance ptr.");
3805         if (klass() == ciEnv::current()->Class_klass() &&
3806             (this->offset() == java_lang_Class::klass_offset() ||
3807              this->offset() == java_lang_Class::array_klass_offset())) {
3808           // Special hidden fields from the Class.
3809           assert(this->isa_instptr(), "must be an instance ptr.");
3810           _is_ptr_to_narrowoop = false;
3811         } else if (klass() == ciEnv::current()->Class_klass() &&
3812                    this->offset() >= InstanceMirrorKlass::offset_of_static_fields()) {
3813           // Static fields
3814           BasicType basic_elem_type = T_ILLEGAL;
3815           if (const_oop() != nullptr) {
3816             ciInstanceKlass* k = const_oop()->as_instance()->java_lang_Class_klass()->as_instance_klass();
3817             basic_elem_type = k->get_field_type_by_offset(this->offset(), true);
3818           }
3819           if (basic_elem_type != T_ILLEGAL) {
3820             _is_ptr_to_narrowoop = UseCompressedOops && ::is_reference_type(basic_elem_type);
3821           } else {
3822             // unsafe access
3823             _is_ptr_to_narrowoop = UseCompressedOops;
3824           }
3825         } else {
3826           // Instance fields which contains a compressed oop references.
3827           ciInstanceKlass* ik = klass()->as_instance_klass();
3828           BasicType basic_elem_type = ik->get_field_type_by_offset(this->offset(), false);
3829           if (basic_elem_type != T_ILLEGAL) {
3830             _is_ptr_to_narrowoop = UseCompressedOops && ::is_reference_type(basic_elem_type);
3831           } else if (klass()->equals(ciEnv::current()->Object_klass())) {
3832             // Compile::find_alias_type() cast exactness on all types to verify
3833             // that it does not affect alias type.
3834             _is_ptr_to_narrowoop = UseCompressedOops;
3835           } else {
3836             // Type for the copy start in LibraryCallKit::inline_native_clone().
3837             _is_ptr_to_narrowoop = UseCompressedOops;
3838           }
3839         }
3840       }
3841     }
3842   }
3843 #endif // _LP64
3844 }
3845 
3846 //------------------------------make-------------------------------------------
3847 const TypeOopPtr *TypeOopPtr::make(PTR ptr, Offset offset, int instance_id,
3848                                    const TypePtr* speculative, int inline_depth) {
3849   assert(ptr != Constant, "no constant generic pointers");
3850   ciKlass*  k = Compile::current()->env()->Object_klass();
3851   bool      xk = false;
3852   ciObject* o = nullptr;
3853   const TypeInterfaces* interfaces = TypeInterfaces::make();
3854   return (TypeOopPtr*)(new TypeOopPtr(OopPtr, ptr, k, interfaces, xk, o, offset, Offset::bottom, instance_id, speculative, inline_depth))->hashcons();
3855 }
3856 
3857 
3858 //------------------------------cast_to_ptr_type-------------------------------
3859 const TypeOopPtr* TypeOopPtr::cast_to_ptr_type(PTR ptr) const {
3860   assert(_base == OopPtr, "subclass must override cast_to_ptr_type");
3861   if( ptr == _ptr ) return this;
3862   return make(ptr, _offset, _instance_id, _speculative, _inline_depth);
3863 }
3864 
3865 //-----------------------------cast_to_instance_id----------------------------
3866 const TypeOopPtr *TypeOopPtr::cast_to_instance_id(int instance_id) const {
3867   // There are no instances of a general oop.
3868   // Return self unchanged.
3869   return this;
3870 }
3871 
3872 //-----------------------------cast_to_exactness-------------------------------
3873 const TypeOopPtr* TypeOopPtr::cast_to_exactness(bool klass_is_exact) const {
3874   // There is no such thing as an exact general oop.
3875   // Return self unchanged.
3876   return this;
3877 }
3878 
3879 //------------------------------as_klass_type----------------------------------
3880 // Return the klass type corresponding to this instance or array type.
3881 // It is the type that is loaded from an object of this type.
3882 const TypeKlassPtr* TypeOopPtr::as_klass_type(bool try_for_exact) const {
3883   ShouldNotReachHere();
3884   return nullptr;
3885 }
3886 
3887 //------------------------------meet-------------------------------------------
3888 // Compute the MEET of two types.  It returns a new Type object.
3889 const Type *TypeOopPtr::xmeet_helper(const Type *t) const {
3890   // Perform a fast test for common case; meeting the same types together.
3891   if( this == t ) return this;  // Meeting same type-rep?
3892 
3893   // Current "this->_base" is OopPtr
3894   switch (t->base()) {          // switch on original type
3895 
3896   case Int:                     // Mixing ints & oops happens when javac
3897   case Long:                    // reuses local variables
3898   case HalfFloatTop:
3899   case HalfFloatCon:
3900   case HalfFloatBot:
3901   case FloatTop:
3902   case FloatCon:
3903   case FloatBot:
3904   case DoubleTop:
3905   case DoubleCon:
3906   case DoubleBot:
3907   case NarrowOop:
3908   case NarrowKlass:
3909   case Bottom:                  // Ye Olde Default
3910     return Type::BOTTOM;
3911   case Top:
3912     return this;
3913 
3914   default:                      // All else is a mistake
3915     typerr(t);
3916 
3917   case RawPtr:
3918   case MetadataPtr:
3919   case KlassPtr:
3920   case InstKlassPtr:
3921   case AryKlassPtr:
3922     return TypePtr::BOTTOM;     // Oop meet raw is not well defined
3923 
3924   case AnyPtr: {
3925     // Found an AnyPtr type vs self-OopPtr type
3926     const TypePtr *tp = t->is_ptr();
3927     Offset offset = meet_offset(tp->offset());
3928     PTR ptr = meet_ptr(tp->ptr());
3929     const TypePtr* speculative = xmeet_speculative(tp);
3930     int depth = meet_inline_depth(tp->inline_depth());
3931     switch (tp->ptr()) {
3932     case Null:
3933       if (ptr == Null)  return TypePtr::make(AnyPtr, ptr, offset, speculative, depth);
3934       // else fall through:
3935     case TopPTR:
3936     case AnyNull: {
3937       int instance_id = meet_instance_id(InstanceTop);
3938       return make(ptr, offset, instance_id, speculative, depth);
3939     }
3940     case BotPTR:
3941     case NotNull:
3942       return TypePtr::make(AnyPtr, ptr, offset, speculative, depth);
3943     default: typerr(t);
3944     }
3945   }
3946 
3947   case OopPtr: {                 // Meeting to other OopPtrs
3948     const TypeOopPtr *tp = t->is_oopptr();
3949     int instance_id = meet_instance_id(tp->instance_id());
3950     const TypePtr* speculative = xmeet_speculative(tp);
3951     int depth = meet_inline_depth(tp->inline_depth());
3952     return make(meet_ptr(tp->ptr()), meet_offset(tp->offset()), instance_id, speculative, depth);
3953   }
3954 
3955   case InstPtr:                  // For these, flip the call around to cut down
3956   case AryPtr:
3957     return t->xmeet(this);      // Call in reverse direction
3958 
3959   } // End of switch
3960   return this;                  // Return the double constant
3961 }
3962 
3963 
3964 //------------------------------xdual------------------------------------------
3965 // Dual of a pure heap pointer.  No relevant klass or oop information.
3966 const Type *TypeOopPtr::xdual() const {
3967   assert(klass() == Compile::current()->env()->Object_klass(), "no klasses here");
3968   assert(const_oop() == nullptr,             "no constants here");
3969   return new TypeOopPtr(_base, dual_ptr(), klass(), _interfaces, klass_is_exact(), const_oop(), dual_offset(), Offset::bottom, dual_instance_id(), dual_speculative(), dual_inline_depth());
3970 }
3971 
3972 //--------------------------make_from_klass_common-----------------------------
3973 // Computes the element-type given a klass.
3974 const TypeOopPtr* TypeOopPtr::make_from_klass_common(ciKlass *klass, bool klass_change, bool try_for_exact, InterfaceHandling interface_handling) {
3975   if (klass->is_instance_klass() || klass->is_inlinetype()) {
3976     Compile* C = Compile::current();
3977     Dependencies* deps = C->dependencies();
3978     assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity");
3979     // Element is an instance
3980     bool klass_is_exact = false;
3981     ciInstanceKlass* ik = klass->as_instance_klass();
3982     if (klass->is_loaded()) {
3983       // Try to set klass_is_exact.
3984       klass_is_exact = ik->is_final();
3985       if (!klass_is_exact && klass_change
3986           && deps != nullptr && UseUniqueSubclasses) {
3987         ciInstanceKlass* sub = ik->unique_concrete_subklass();
3988         if (sub != nullptr) {
3989           deps->assert_abstract_with_unique_concrete_subtype(ik, sub);
3990           klass = ik = sub;
3991           klass_is_exact = sub->is_final();
3992         }
3993       }
3994       if (!klass_is_exact && try_for_exact && deps != nullptr &&
3995           !ik->is_interface() && !ik->has_subklass()) {
3996         // Add a dependence; if concrete subclass added we need to recompile
3997         deps->assert_leaf_type(ik);
3998         klass_is_exact = true;
3999       }
4000     }
4001     FlatInArray flat_in_array = compute_flat_in_array(ik, klass_is_exact);
4002     const TypeInterfaces* interfaces = TypePtr::interfaces(klass, true, true, false, interface_handling);
4003     return TypeInstPtr::make(TypePtr::BotPTR, klass, interfaces, klass_is_exact, nullptr, Offset(0), flat_in_array);
4004   } else if (klass->is_obj_array_klass()) {
4005     // Element is an object or inline type array. Recursively call ourself.
4006     ciObjArrayKlass* array_klass = klass->as_obj_array_klass();
4007     const TypeOopPtr* etype = TypeOopPtr::make_from_klass_common(array_klass->element_klass(), /* klass_change= */ false, try_for_exact, interface_handling);
4008     bool xk = array_klass->is_loaded() && array_klass->is_refined();
4009 
4010     // Determine null-free/flat properties
4011     bool flat;
4012     bool not_flat;
4013     bool not_null_free;
4014     bool atomic;
4015     if (xk) {
4016       flat = array_klass->is_flat_array_klass();
4017       not_flat = !flat;
4018       bool is_null_free = array_klass->is_elem_null_free();
4019       not_null_free = !is_null_free;
4020       atomic = array_klass->is_elem_atomic();
4021 
4022       if (is_null_free) {
4023         etype = etype->join_speculative(NOTNULL)->is_oopptr();
4024       }
4025     } else {
4026       const TypeOopPtr* exact_etype = etype;
4027       if (etype->can_be_inline_type()) {
4028         // Use exact type if element can be an inline type
4029         exact_etype = TypeOopPtr::make_from_klass_common(klass->as_array_klass()->element_klass(), /* klass_change= */ true, /* try_for_exact= */ true, interface_handling);
4030       }
4031 
4032       flat = false;
4033       bool not_inline = !exact_etype->can_be_inline_type();
4034       not_null_free = not_inline;
4035       not_flat = !UseArrayFlattening || not_inline || (exact_etype->is_inlinetypeptr() && !exact_etype->inline_klass()->maybe_flat_in_array());
4036       atomic = not_flat;
4037     }
4038 
4039     const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS, /* stable= */ false, flat, not_flat, not_null_free, atomic);
4040     // We used to pass NotNull in here, asserting that the sub-arrays
4041     // are all not-null.  This is not true in generally, as code can
4042     // slam nullptrs down in the subarrays.
4043     const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, nullptr, xk, Offset(0));
4044     return arr;
4045   } else if (klass->is_type_array_klass()) {
4046     // Element is an typeArray
4047     const Type* etype = get_const_basic_type(klass->as_type_array_klass()->element_type());
4048     const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS,
4049                                         /* stable= */ false, /* flat= */ false, /* not_flat= */ true, /* not_null_free= */ true, true);
4050     // We used to pass NotNull in here, asserting that the array pointer
4051     // is not-null. That was not true in general.
4052     const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, klass, true, Offset(0));
4053     return arr;
4054   } else {
4055     ShouldNotReachHere();
4056     return nullptr;
4057   }
4058 }
4059 
4060 //------------------------------make_from_constant-----------------------------
4061 // Make a java pointer from an oop constant
4062 const TypeOopPtr* TypeOopPtr::make_from_constant(ciObject* o, bool require_constant) {
4063   assert(!o->is_null_object(), "null object not yet handled here.");
4064 
4065   const bool make_constant = require_constant || o->should_be_constant();
4066 
4067   ciKlass* klass = o->klass();
4068   if (klass->is_instance_klass() || klass->is_inlinetype()) {
4069     // Element is an instance or inline type
4070     if (make_constant) {
4071       return TypeInstPtr::make(o);
4072     } else {
4073       return TypeInstPtr::make(TypePtr::NotNull, klass, true, nullptr, Offset(0));
4074     }
4075   } else if (klass->is_obj_array_klass()) {
4076     // Element is an object array. Recursively call ourself.
4077     const TypeOopPtr* etype = TypeOopPtr::make_from_klass_raw(klass->as_array_klass()->element_klass(), trust_interfaces);
4078     bool is_flat = o->as_array()->is_flat();
4079     bool is_null_free = o->as_array()->is_null_free();
4080     if (is_null_free) {
4081       etype = etype->join_speculative(TypePtr::NOTNULL)->is_oopptr();
4082     }
4083     bool is_atomic = o->as_array()->is_atomic();
4084     const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length()), /* stable= */ false, /* flat= */ is_flat,
4085                                         /* not_flat= */ !is_flat, /* not_null_free= */ !is_null_free, /* atomic= */ is_atomic);
4086     // We used to pass NotNull in here, asserting that the sub-arrays
4087     // are all not-null.  This is not true in generally, as code can
4088     // slam nulls down in the subarrays.
4089     if (make_constant) {
4090       return TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, Offset(0));
4091     } else {
4092       return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, Offset(0));
4093     }
4094   } else if (klass->is_type_array_klass()) {
4095     // Element is an typeArray
4096     const Type* etype = (Type*)get_const_basic_type(klass->as_type_array_klass()->element_type());
4097     const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length()), /* stable= */ false, /* flat= */ false,
4098                                         /* not_flat= */ true, /* not_null_free= */ true, true);
4099     // We used to pass NotNull in here, asserting that the array pointer
4100     // is not-null. That was not true in general.
4101     if (make_constant) {
4102       return TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, Offset(0));
4103     } else {
4104       return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, Offset(0));
4105     }
4106   }
4107 
4108   fatal("unhandled object type");
4109   return nullptr;
4110 }
4111 
4112 //------------------------------get_con----------------------------------------
4113 intptr_t TypeOopPtr::get_con() const {
4114   assert( _ptr == Null || _ptr == Constant, "" );
4115   assert(offset() >= 0, "");
4116 
4117   if (offset() != 0) {
4118     // After being ported to the compiler interface, the compiler no longer
4119     // directly manipulates the addresses of oops.  Rather, it only has a pointer
4120     // to a handle at compile time.  This handle is embedded in the generated
4121     // code and dereferenced at the time the nmethod is made.  Until that time,
4122     // it is not reasonable to do arithmetic with the addresses of oops (we don't
4123     // have access to the addresses!).  This does not seem to currently happen,
4124     // but this assertion here is to help prevent its occurrence.
4125     tty->print_cr("Found oop constant with non-zero offset");
4126     ShouldNotReachHere();
4127   }
4128 
4129   return (intptr_t)const_oop()->constant_encoding();
4130 }
4131 
4132 
4133 //-----------------------------filter------------------------------------------
4134 // Do not allow interface-vs.-noninterface joins to collapse to top.
4135 const Type *TypeOopPtr::filter_helper(const Type *kills, bool include_speculative) const {
4136 
4137   const Type* ft = join_helper(kills, include_speculative);
4138 
4139   if (ft->empty()) {
4140     return Type::TOP;           // Canonical empty value
4141   }
4142 
4143   return ft;
4144 }
4145 
4146 //------------------------------eq---------------------------------------------
4147 // Structural equality check for Type representations
4148 bool TypeOopPtr::eq( const Type *t ) const {
4149   const TypeOopPtr *a = (const TypeOopPtr*)t;
4150   if (_klass_is_exact != a->_klass_is_exact ||
4151       _instance_id != a->_instance_id)  return false;
4152   ciObject* one = const_oop();
4153   ciObject* two = a->const_oop();
4154   if (one == nullptr || two == nullptr) {
4155     return (one == two) && TypePtr::eq(t);
4156   } else {
4157     return one->equals(two) && TypePtr::eq(t);
4158   }
4159 }
4160 
4161 //------------------------------hash-------------------------------------------
4162 // Type-specific hashing function.
4163 uint TypeOopPtr::hash(void) const {
4164   return
4165     (uint)(const_oop() ? const_oop()->hash() : 0) +
4166     (uint)_klass_is_exact +
4167     (uint)_instance_id + TypePtr::hash();
4168 }
4169 
4170 //------------------------------dump2------------------------------------------
4171 #ifndef PRODUCT
4172 void TypeOopPtr::dump2(Dict& d, uint depth, outputStream* st) const {
4173   st->print("oopptr:%s", ptr_msg[_ptr]);
4174   if (_klass_is_exact) {
4175     st->print(":exact");
4176   }
4177   if (const_oop() != nullptr) {
4178     st->print(":" INTPTR_FORMAT, p2i(const_oop()));
4179   }
4180   dump_offset(st);
4181   dump_instance_id(st);
4182   dump_inline_depth(st);
4183   dump_speculative(st);
4184 }
4185 
4186 void TypeOopPtr::dump_instance_id(outputStream* st) const {
4187   if (_instance_id == InstanceTop) {
4188     st->print(",iid=top");
4189   } else if (_instance_id == InstanceBot) {
4190     st->print(",iid=bot");
4191   } else {
4192     st->print(",iid=%d", _instance_id);
4193   }
4194 }
4195 #endif
4196 
4197 //------------------------------singleton--------------------------------------
4198 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
4199 // constants
4200 bool TypeOopPtr::singleton(void) const {
4201   // detune optimizer to not generate constant oop + constant offset as a constant!
4202   // TopPTR, Null, AnyNull, Constant are all singletons
4203   return (offset() == 0) && !below_centerline(_ptr);
4204 }
4205 
4206 //------------------------------add_offset-------------------------------------
4207 const TypePtr* TypeOopPtr::add_offset(intptr_t offset) const {
4208   return make(_ptr, xadd_offset(offset), _instance_id, add_offset_speculative(offset), _inline_depth);
4209 }
4210 
4211 const TypeOopPtr* TypeOopPtr::with_offset(intptr_t offset) const {
4212   return make(_ptr, Offset(offset), _instance_id, with_offset_speculative(offset), _inline_depth);
4213 }
4214 
4215 /**
4216  * Return same type without a speculative part
4217  */
4218 const TypeOopPtr* TypeOopPtr::remove_speculative() const {
4219   if (_speculative == nullptr) {
4220     return this;
4221   }
4222   assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth");
4223   return make(_ptr, _offset, _instance_id, nullptr, _inline_depth);
4224 }
4225 
4226 /**
4227  * Return same type but drop speculative part if we know we won't use
4228  * it
4229  */
4230 const Type* TypeOopPtr::cleanup_speculative() const {
4231   // If the klass is exact and the ptr is not null then there's
4232   // nothing that the speculative type can help us with
4233   if (klass_is_exact() && !maybe_null()) {
4234     return remove_speculative();
4235   }
4236   return TypePtr::cleanup_speculative();
4237 }
4238 
4239 /**
4240  * Return same type but with a different inline depth (used for speculation)
4241  *
4242  * @param depth  depth to meet with
4243  */
4244 const TypePtr* TypeOopPtr::with_inline_depth(int depth) const {
4245   if (!UseInlineDepthForSpeculativeTypes) {
4246     return this;
4247   }
4248   return make(_ptr, _offset, _instance_id, _speculative, depth);
4249 }
4250 
4251 //------------------------------with_instance_id--------------------------------
4252 const TypePtr* TypeOopPtr::with_instance_id(int instance_id) const {
4253   assert(_instance_id != -1, "should be known");
4254   return make(_ptr, _offset, instance_id, _speculative, _inline_depth);
4255 }
4256 
4257 //------------------------------meet_instance_id--------------------------------
4258 int TypeOopPtr::meet_instance_id( int instance_id ) const {
4259   // Either is 'TOP' instance?  Return the other instance!
4260   if( _instance_id == InstanceTop ) return  instance_id;
4261   if(  instance_id == InstanceTop ) return _instance_id;
4262   // If either is different, return 'BOTTOM' instance
4263   if( _instance_id != instance_id ) return InstanceBot;
4264   return _instance_id;
4265 }
4266 
4267 //------------------------------dual_instance_id--------------------------------
4268 int TypeOopPtr::dual_instance_id( ) const {
4269   if( _instance_id == InstanceTop ) return InstanceBot; // Map TOP into BOTTOM
4270   if( _instance_id == InstanceBot ) return InstanceTop; // Map BOTTOM into TOP
4271   return _instance_id;              // Map everything else into self
4272 }
4273 
4274 
4275 const TypeInterfaces* TypeOopPtr::meet_interfaces(const TypeOopPtr* other) const {
4276   if (above_centerline(_ptr) && above_centerline(other->_ptr)) {
4277     return _interfaces->union_with(other->_interfaces);
4278   } else if (above_centerline(_ptr) && !above_centerline(other->_ptr)) {
4279     return other->_interfaces;
4280   } else if (above_centerline(other->_ptr) && !above_centerline(_ptr)) {
4281     return _interfaces;
4282   }
4283   return _interfaces->intersection_with(other->_interfaces);
4284 }
4285 
4286 /**
4287  * Check whether new profiling would improve speculative type
4288  *
4289  * @param   exact_kls    class from profiling
4290  * @param   inline_depth inlining depth of profile point
4291  *
4292  * @return  true if type profile is valuable
4293  */
4294 bool TypeOopPtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const {
4295   // no way to improve an already exact type
4296   if (klass_is_exact()) {
4297     return false;
4298   }
4299   return TypePtr::would_improve_type(exact_kls, inline_depth);
4300 }
4301 
4302 //=============================================================================
4303 // Convenience common pre-built types.
4304 const TypeInstPtr *TypeInstPtr::NOTNULL;
4305 const TypeInstPtr *TypeInstPtr::BOTTOM;
4306 const TypeInstPtr *TypeInstPtr::MIRROR;
4307 const TypeInstPtr *TypeInstPtr::MARK;
4308 const TypeInstPtr *TypeInstPtr::KLASS;
4309 
4310 // Is there a single ciKlass* that can represent that type?
4311 ciKlass* TypeInstPtr::exact_klass_helper() const {
4312   if (_interfaces->empty()) {
4313     return _klass;
4314   }
4315   if (_klass != ciEnv::current()->Object_klass()) {
4316     if (_interfaces->eq(_klass->as_instance_klass())) {
4317       return _klass;
4318     }
4319     return nullptr;
4320   }
4321   return _interfaces->exact_klass();
4322 }
4323 
4324 //------------------------------TypeInstPtr-------------------------------------
4325 TypeInstPtr::TypeInstPtr(PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, bool xk, ciObject* o, Offset off,
4326                          FlatInArray flat_in_array, int instance_id, const TypePtr* speculative, int inline_depth)
4327   : TypeOopPtr(InstPtr, ptr, k, interfaces, xk, o, off, Offset::bottom, instance_id, speculative, inline_depth),
4328     _flat_in_array(flat_in_array) {
4329 
4330   assert(flat_in_array != Uninitialized, "must be set now");
4331   assert(k == nullptr || !k->is_loaded() || !k->is_interface(), "no interface here");
4332   assert(k != nullptr &&
4333          (k->is_loaded() || o == nullptr),
4334          "cannot have constants with non-loaded klass");
4335 };
4336 
4337 //------------------------------make-------------------------------------------
4338 const TypeInstPtr *TypeInstPtr::make(PTR ptr,
4339                                      ciKlass* k,
4340                                      const TypeInterfaces* interfaces,
4341                                      bool xk,
4342                                      ciObject* o,
4343                                      Offset offset,
4344                                      FlatInArray flat_in_array,
4345                                      int instance_id,
4346                                      const TypePtr* speculative,
4347                                      int inline_depth) {
4348   assert( !k->is_loaded() || k->is_instance_klass(), "Must be for instance");
4349   // Either const_oop() is null or else ptr is Constant
4350   assert( (!o && ptr != Constant) || (o && ptr == Constant),
4351           "constant pointers must have a value supplied" );
4352   // Ptr is never Null
4353   assert( ptr != Null, "null pointers are not typed" );
4354 
4355   assert(instance_id <= 0 || xk, "instances are always exactly typed");
4356   ciInstanceKlass* ik = k->as_instance_klass();
4357   if (ptr == Constant) {
4358     // Note:  This case includes meta-object constants, such as methods.
4359     xk = true;
4360   } else if (k->is_loaded()) {
4361     if (!xk && ik->is_final())     xk = true;   // no inexact final klass
4362     assert(!ik->is_interface(), "no interface here");
4363     if (xk && ik->is_interface())  xk = false;  // no exact interface
4364   }
4365 
4366   if (flat_in_array == Uninitialized) {
4367     flat_in_array = compute_flat_in_array(ik, xk);
4368   }
4369   // Now hash this baby
4370   TypeInstPtr *result =
4371     (TypeInstPtr*)(new TypeInstPtr(ptr, k, interfaces, xk, o, offset, flat_in_array, instance_id, speculative, inline_depth))->hashcons();
4372 
4373   return result;
4374 }
4375 
4376 const TypeInterfaces* TypePtr::interfaces(ciKlass*& k, bool klass, bool interface, bool array, InterfaceHandling interface_handling) {
4377   if (k->is_instance_klass()) {
4378     if (k->is_loaded()) {
4379       if (k->is_interface() && interface_handling == ignore_interfaces) {
4380         assert(interface, "no interface expected");
4381         k = ciEnv::current()->Object_klass();
4382         const TypeInterfaces* interfaces = TypeInterfaces::make();
4383         return interfaces;
4384       }
4385       GrowableArray<ciInstanceKlass *>* k_interfaces = k->as_instance_klass()->transitive_interfaces();
4386       const TypeInterfaces* interfaces = TypeInterfaces::make(k_interfaces);
4387       if (k->is_interface()) {
4388         assert(interface, "no interface expected");
4389         k = ciEnv::current()->Object_klass();
4390       } else {
4391         assert(klass, "no instance klass expected");
4392       }
4393       return interfaces;
4394     }
4395     const TypeInterfaces* interfaces = TypeInterfaces::make();
4396     return interfaces;
4397   }
4398   assert(array, "no array expected");
4399   assert(k->is_array_klass(), "Not an array?");
4400   ciType* e = k->as_array_klass()->base_element_type();
4401   if (e->is_loaded() && e->is_instance_klass() && e->as_instance_klass()->is_interface()) {
4402     if (interface_handling == ignore_interfaces) {
4403       k = ciObjArrayKlass::make(ciEnv::current()->Object_klass(), k->as_array_klass()->dimension());
4404     }
4405   }
4406   return TypeAryPtr::_array_interfaces;
4407 }
4408 
4409 //------------------------------cast_to_ptr_type-------------------------------
4410 const TypeInstPtr* TypeInstPtr::cast_to_ptr_type(PTR ptr) const {
4411   if( ptr == _ptr ) return this;
4412   // Reconstruct _sig info here since not a problem with later lazy
4413   // construction, _sig will show up on demand.
4414   return make(ptr, klass(), _interfaces, klass_is_exact(), ptr == Constant ? const_oop() : nullptr, _offset, _flat_in_array, _instance_id, _speculative, _inline_depth);
4415 }
4416 
4417 
4418 //-----------------------------cast_to_exactness-------------------------------
4419 const TypeInstPtr* TypeInstPtr::cast_to_exactness(bool klass_is_exact) const {
4420   if( klass_is_exact == _klass_is_exact ) return this;
4421   if (!_klass->is_loaded())  return this;
4422   ciInstanceKlass* ik = _klass->as_instance_klass();
4423   if( (ik->is_final() || _const_oop) )  return this;  // cannot clear xk
4424   assert(!ik->is_interface(), "no interface here");
4425   FlatInArray flat_in_array = compute_flat_in_array(ik, klass_is_exact);
4426   return make(ptr(), klass(), _interfaces, klass_is_exact, const_oop(), _offset, flat_in_array, _instance_id, _speculative, _inline_depth);
4427 }
4428 
4429 //-----------------------------cast_to_instance_id----------------------------
4430 const TypeInstPtr* TypeInstPtr::cast_to_instance_id(int instance_id) const {
4431   if( instance_id == _instance_id ) return this;
4432   return make(_ptr, klass(), _interfaces, _klass_is_exact, const_oop(), _offset, _flat_in_array, instance_id, _speculative, _inline_depth);
4433 }
4434 
4435 //------------------------------xmeet_unloaded---------------------------------
4436 // Compute the MEET of two InstPtrs when at least one is unloaded.
4437 // Assume classes are different since called after check for same name/class-loader
4438 const TypeInstPtr *TypeInstPtr::xmeet_unloaded(const TypeInstPtr *tinst, const TypeInterfaces* interfaces) const {
4439   Offset off = meet_offset(tinst->offset());
4440   PTR ptr = meet_ptr(tinst->ptr());
4441   int instance_id = meet_instance_id(tinst->instance_id());
4442   const TypePtr* speculative = xmeet_speculative(tinst);
4443   int depth = meet_inline_depth(tinst->inline_depth());
4444 
4445   const TypeInstPtr *loaded    = is_loaded() ? this  : tinst;
4446   const TypeInstPtr *unloaded  = is_loaded() ? tinst : this;
4447   if( loaded->klass()->equals(ciEnv::current()->Object_klass()) ) {
4448     //
4449     // Meet unloaded class with java/lang/Object
4450     //
4451     // Meet
4452     //          |                     Unloaded Class
4453     //  Object  |   TOP    |   AnyNull | Constant |   NotNull |  BOTTOM   |
4454     //  ===================================================================
4455     //   TOP    | ..........................Unloaded......................|
4456     //  AnyNull |  U-AN    |................Unloaded......................|
4457     // Constant | ... O-NN .................................. |   O-BOT   |
4458     //  NotNull | ... O-NN .................................. |   O-BOT   |
4459     //  BOTTOM  | ........................Object-BOTTOM ..................|
4460     //
4461     assert(loaded->ptr() != TypePtr::Null, "insanity check");
4462     //
4463     if (loaded->ptr() == TypePtr::TopPTR)        { return unloaded->with_speculative(speculative); }
4464     else if (loaded->ptr() == TypePtr::AnyNull)  {
4465       FlatInArray flat_in_array = meet_flat_in_array(_flat_in_array, tinst->flat_in_array());
4466       return make(ptr, unloaded->klass(), interfaces, false, nullptr, off, flat_in_array, instance_id,
4467                   speculative, depth);
4468     }
4469     else if (loaded->ptr() == TypePtr::BotPTR)   { return TypeInstPtr::BOTTOM->with_speculative(speculative); }
4470     else if (loaded->ptr() == TypePtr::Constant || loaded->ptr() == TypePtr::NotNull) {
4471       if (unloaded->ptr() == TypePtr::BotPTR)    { return TypeInstPtr::BOTTOM->with_speculative(speculative);  }
4472       else                                       { return TypeInstPtr::NOTNULL->with_speculative(speculative); }
4473     }
4474     else if (unloaded->ptr() == TypePtr::TopPTR) { return unloaded->with_speculative(speculative); }
4475 
4476     return unloaded->cast_to_ptr_type(TypePtr::AnyNull)->is_instptr()->with_speculative(speculative);
4477   }
4478 
4479   // Both are unloaded, not the same class, not Object
4480   // Or meet unloaded with a different loaded class, not java/lang/Object
4481   if (ptr != TypePtr::BotPTR) {
4482     return TypeInstPtr::NOTNULL->with_speculative(speculative);
4483   }
4484   return TypeInstPtr::BOTTOM->with_speculative(speculative);
4485 }
4486 
4487 
4488 //------------------------------meet-------------------------------------------
4489 // Compute the MEET of two types.  It returns a new Type object.
4490 const Type *TypeInstPtr::xmeet_helper(const Type *t) const {
4491   // Perform a fast test for common case; meeting the same types together.
4492   if( this == t ) return this;  // Meeting same type-rep?
4493 
4494   // Current "this->_base" is Pointer
4495   switch (t->base()) {          // switch on original type
4496 
4497   case Int:                     // Mixing ints & oops happens when javac
4498   case Long:                    // reuses local variables
4499   case HalfFloatTop:
4500   case HalfFloatCon:
4501   case HalfFloatBot:
4502   case FloatTop:
4503   case FloatCon:
4504   case FloatBot:
4505   case DoubleTop:
4506   case DoubleCon:
4507   case DoubleBot:
4508   case NarrowOop:
4509   case NarrowKlass:
4510   case Bottom:                  // Ye Olde Default
4511     return Type::BOTTOM;
4512   case Top:
4513     return this;
4514 
4515   default:                      // All else is a mistake
4516     typerr(t);
4517 
4518   case MetadataPtr:
4519   case KlassPtr:
4520   case InstKlassPtr:
4521   case AryKlassPtr:
4522   case RawPtr: return TypePtr::BOTTOM;
4523 
4524   case AryPtr: {                // All arrays inherit from Object class
4525     // Call in reverse direction to avoid duplication
4526     return t->is_aryptr()->xmeet_helper(this);
4527   }
4528 
4529   case OopPtr: {                // Meeting to OopPtrs
4530     // Found a OopPtr type vs self-InstPtr type
4531     const TypeOopPtr *tp = t->is_oopptr();
4532     Offset offset = meet_offset(tp->offset());
4533     PTR ptr = meet_ptr(tp->ptr());
4534     switch (tp->ptr()) {
4535     case TopPTR:
4536     case AnyNull: {
4537       int instance_id = meet_instance_id(InstanceTop);
4538       const TypePtr* speculative = xmeet_speculative(tp);
4539       int depth = meet_inline_depth(tp->inline_depth());
4540       return make(ptr, klass(), _interfaces, klass_is_exact(),
4541                   (ptr == Constant ? const_oop() : nullptr), offset, flat_in_array(), instance_id, speculative, depth);
4542     }
4543     case NotNull:
4544     case BotPTR: {
4545       int instance_id = meet_instance_id(tp->instance_id());
4546       const TypePtr* speculative = xmeet_speculative(tp);
4547       int depth = meet_inline_depth(tp->inline_depth());
4548       return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth);
4549     }
4550     default: typerr(t);
4551     }
4552   }
4553 
4554   case AnyPtr: {                // Meeting to AnyPtrs
4555     // Found an AnyPtr type vs self-InstPtr type
4556     const TypePtr *tp = t->is_ptr();
4557     Offset offset = meet_offset(tp->offset());
4558     PTR ptr = meet_ptr(tp->ptr());
4559     int instance_id = meet_instance_id(InstanceTop);
4560     const TypePtr* speculative = xmeet_speculative(tp);
4561     int depth = meet_inline_depth(tp->inline_depth());
4562     switch (tp->ptr()) {
4563     case Null:
4564       if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth);
4565       // else fall through to AnyNull
4566     case TopPTR:
4567     case AnyNull: {
4568       return make(ptr, klass(), _interfaces, klass_is_exact(),
4569                   (ptr == Constant ? const_oop() : nullptr), offset, flat_in_array(), instance_id, speculative, depth);
4570     }
4571     case NotNull:
4572     case BotPTR:
4573       return TypePtr::make(AnyPtr, ptr, offset, speculative,depth);
4574     default: typerr(t);
4575     }
4576   }
4577 
4578   /*
4579                  A-top         }
4580                /   |   \       }  Tops
4581            B-top A-any C-top   }
4582               | /  |  \ |      }  Any-nulls
4583            B-any   |   C-any   }
4584               |    |    |
4585            B-con A-con C-con   } constants; not comparable across classes
4586               |    |    |
4587            B-not   |   C-not   }
4588               | \  |  / |      }  not-nulls
4589            B-bot A-not C-bot   }
4590                \   |   /       }  Bottoms
4591                  A-bot         }
4592   */
4593 
4594   case InstPtr: {                // Meeting 2 Oops?
4595     // Found an InstPtr sub-type vs self-InstPtr type
4596     const TypeInstPtr *tinst = t->is_instptr();
4597     Offset off = meet_offset(tinst->offset());
4598     PTR ptr = meet_ptr(tinst->ptr());
4599     int instance_id = meet_instance_id(tinst->instance_id());
4600     const TypePtr* speculative = xmeet_speculative(tinst);
4601     int depth = meet_inline_depth(tinst->inline_depth());
4602     const TypeInterfaces* interfaces = meet_interfaces(tinst);
4603 
4604     ciKlass* tinst_klass = tinst->klass();
4605     ciKlass* this_klass  = klass();
4606 
4607     ciKlass* res_klass = nullptr;
4608     bool res_xk = false;
4609     const Type* res;
4610     MeetResult kind = meet_instptr(ptr, interfaces, this, tinst, res_klass, res_xk);
4611 
4612     if (kind == UNLOADED) {
4613       // One of these classes has not been loaded
4614       const TypeInstPtr* unloaded_meet = xmeet_unloaded(tinst, interfaces);
4615 #ifndef PRODUCT
4616       if (PrintOpto && Verbose) {
4617         tty->print("meet of unloaded classes resulted in: ");
4618         unloaded_meet->dump();
4619         tty->cr();
4620         tty->print("  this == ");
4621         dump();
4622         tty->cr();
4623         tty->print(" tinst == ");
4624         tinst->dump();
4625         tty->cr();
4626       }
4627 #endif
4628       res = unloaded_meet;
4629     } else {
4630       FlatInArray flat_in_array = meet_flat_in_array(_flat_in_array, tinst->flat_in_array());
4631       if (kind == NOT_SUBTYPE && instance_id > 0) {
4632         instance_id = InstanceBot;
4633       } else if (kind == LCA) {
4634         instance_id = InstanceBot;
4635       }
4636       ciObject* o = nullptr;             // Assume not constant when done
4637       ciObject* this_oop = const_oop();
4638       ciObject* tinst_oop = tinst->const_oop();
4639       if (ptr == Constant) {
4640         if (this_oop != nullptr && tinst_oop != nullptr &&
4641             this_oop->equals(tinst_oop))
4642           o = this_oop;
4643         else if (above_centerline(_ptr)) {
4644           assert(!tinst_klass->is_interface(), "");
4645           o = tinst_oop;
4646         } else if (above_centerline(tinst->_ptr)) {
4647           assert(!this_klass->is_interface(), "");
4648           o = this_oop;
4649         } else
4650           ptr = NotNull;
4651       }
4652       res = make(ptr, res_klass, interfaces, res_xk, o, off, flat_in_array, instance_id, speculative, depth);
4653     }
4654 
4655     return res;
4656 
4657   } // End of case InstPtr
4658 
4659   } // End of switch
4660   return this;                  // Return the double constant
4661 }
4662 
4663 template<class T> TypePtr::MeetResult TypePtr::meet_instptr(PTR& ptr, const TypeInterfaces*& interfaces, const T* this_type, const T* other_type,
4664                                                             ciKlass*& res_klass, bool& res_xk) {
4665   ciKlass* this_klass = this_type->klass();
4666   ciKlass* other_klass = other_type->klass();
4667 
4668   bool this_xk = this_type->klass_is_exact();
4669   bool other_xk = other_type->klass_is_exact();
4670   PTR this_ptr = this_type->ptr();
4671   PTR other_ptr = other_type->ptr();
4672   const TypeInterfaces* this_interfaces = this_type->interfaces();
4673   const TypeInterfaces* other_interfaces = other_type->interfaces();
4674   // Check for easy case; klasses are equal (and perhaps not loaded!)
4675   // If we have constants, then we created oops so classes are loaded
4676   // and we can handle the constants further down.  This case handles
4677   // both-not-loaded or both-loaded classes
4678   if (ptr != Constant && this_klass->equals(other_klass) && this_xk == other_xk) {
4679     res_klass = this_klass;
4680     res_xk = this_xk;
4681     return QUICK;
4682   }
4683 
4684   // Classes require inspection in the Java klass hierarchy.  Must be loaded.
4685   if (!other_klass->is_loaded() || !this_klass->is_loaded()) {
4686     return UNLOADED;
4687   }
4688 
4689   // !!! Here's how the symmetry requirement breaks down into invariants:
4690   // If we split one up & one down AND they subtype, take the down man.
4691   // If we split one up & one down AND they do NOT subtype, "fall hard".
4692   // If both are up and they subtype, take the subtype class.
4693   // If both are up and they do NOT subtype, "fall hard".
4694   // If both are down and they subtype, take the supertype class.
4695   // If both are down and they do NOT subtype, "fall hard".
4696   // Constants treated as down.
4697 
4698   // Now, reorder the above list; observe that both-down+subtype is also
4699   // "fall hard"; "fall hard" becomes the default case:
4700   // If we split one up & one down AND they subtype, take the down man.
4701   // If both are up and they subtype, take the subtype class.
4702 
4703   // If both are down and they subtype, "fall hard".
4704   // If both are down and they do NOT subtype, "fall hard".
4705   // If both are up and they do NOT subtype, "fall hard".
4706   // If we split one up & one down AND they do NOT subtype, "fall hard".
4707 
4708   // If a proper subtype is exact, and we return it, we return it exactly.
4709   // If a proper supertype is exact, there can be no subtyping relationship!
4710   // If both types are equal to the subtype, exactness is and-ed below the
4711   // centerline and or-ed above it.  (N.B. Constants are always exact.)
4712 
4713   const T* subtype = nullptr;
4714   bool subtype_exact = false;
4715   if (this_type->is_same_java_type_as(other_type)) {
4716     // Same klass
4717     subtype = this_type;
4718     subtype_exact = below_centerline(ptr) ? (this_xk && other_xk) : (this_xk || other_xk);
4719   } else if (!other_xk && this_type->is_meet_subtype_of(other_type)) {
4720     subtype = this_type;     // Pick subtyping class
4721     subtype_exact = this_xk;
4722   } else if (!this_xk && other_type->is_meet_subtype_of(this_type)) {
4723     subtype = other_type;    // Pick subtyping class
4724     subtype_exact = other_xk;
4725   }
4726 
4727   if (subtype != nullptr) {
4728     if (above_centerline(ptr)) {
4729       // Both types are empty.
4730       this_type = other_type = subtype;
4731       this_xk = other_xk = subtype_exact;
4732     } else if (above_centerline(this_ptr) && !above_centerline(other_ptr)) {
4733       // this_type is empty while other_type is not. Take other_type.
4734       this_type = other_type;
4735       this_xk = other_xk;
4736     } else if (above_centerline(other_ptr) && !above_centerline(this_ptr)) {
4737       // other_type is empty while this_type is not. Take this_type.
4738       other_type = this_type; // this is down; keep down man
4739     } else {
4740       // this_type and other_type are both non-empty.
4741       this_xk = subtype_exact;  // either they are equal, or we'll do an LCA
4742     }
4743   }
4744 
4745   // Check for classes now being equal
4746   if (this_type->is_same_java_type_as(other_type)) {
4747     // If the klasses are equal, the constants may still differ.  Fall to
4748     // NotNull if they do (neither constant is null; that is a special case
4749     // handled elsewhere).
4750     res_klass = this_type->klass();
4751     res_xk = this_xk;
4752     return SUBTYPE;
4753   } // Else classes are not equal
4754 
4755   // Since klasses are different, we require a LCA in the Java
4756   // class hierarchy - which means we have to fall to at least NotNull.
4757   if (ptr == TopPTR || ptr == AnyNull || ptr == Constant) {
4758     ptr = NotNull;
4759   }
4760 
4761   interfaces = this_interfaces->intersection_with(other_interfaces);
4762 
4763   // Now we find the LCA of Java classes
4764   ciKlass* k = this_klass->least_common_ancestor(other_klass);
4765 
4766   res_klass = k;
4767   res_xk = false;
4768   return LCA;
4769 }
4770 
4771 //                Top-Flat    Flat        Not-Flat    Maybe-Flat
4772 // -------------------------------------------------------------
4773 //    Top-Flat    Top-Flat    Flat        Not-Flat    Maybe-Flat
4774 //        Flat    Flat        Flat        Maybe-Flat  Maybe-Flat
4775 //    Not-Flat    Not-Flat    Maybe-Flat  Not-Flat    Maybe-Flat
4776 //  Maybe-Flat    Maybe-Flat  Maybe-Flat  Maybe-Flat  Maybe-flat
4777 TypePtr::FlatInArray TypePtr::meet_flat_in_array(const FlatInArray left, const FlatInArray right) {
4778   if (left == TopFlat) {
4779     return right;
4780   }
4781   if (right == TopFlat) {
4782     return left;
4783   }
4784   if (left == MaybeFlat || right == MaybeFlat) {
4785     return MaybeFlat;
4786   }
4787 
4788   switch (left) {
4789     case Flat:
4790       if (right == Flat) {
4791         return Flat;
4792       }
4793       return MaybeFlat;
4794     case NotFlat:
4795       if (right == NotFlat) {
4796         return NotFlat;
4797       }
4798       return MaybeFlat;
4799     default:
4800       ShouldNotReachHere();
4801       return Uninitialized;
4802   }
4803 }
4804 
4805 //------------------------java_mirror_type--------------------------------------
4806 ciType* TypeInstPtr::java_mirror_type() const {
4807   // must be a singleton type
4808   if( const_oop() == nullptr )  return nullptr;
4809 
4810   // must be of type java.lang.Class
4811   if( klass() != ciEnv::current()->Class_klass() )  return nullptr;
4812   return const_oop()->as_instance()->java_mirror_type();
4813 }
4814 
4815 
4816 //------------------------------xdual------------------------------------------
4817 // Dual: do NOT dual on klasses.  This means I do NOT understand the Java
4818 // inheritance mechanism.
4819 const Type* TypeInstPtr::xdual() const {
4820   return new TypeInstPtr(dual_ptr(), klass(), _interfaces, klass_is_exact(), const_oop(), dual_offset(),
4821                          dual_flat_in_array(), dual_instance_id(), dual_speculative(), dual_inline_depth());
4822 }
4823 
4824 //------------------------------eq---------------------------------------------
4825 // Structural equality check for Type representations
4826 bool TypeInstPtr::eq( const Type *t ) const {
4827   const TypeInstPtr *p = t->is_instptr();
4828   return
4829     klass()->equals(p->klass()) &&
4830     _flat_in_array == p->_flat_in_array &&
4831     _interfaces->eq(p->_interfaces) &&
4832     TypeOopPtr::eq(p);          // Check sub-type stuff
4833 }
4834 
4835 //------------------------------hash-------------------------------------------
4836 // Type-specific hashing function.
4837 uint TypeInstPtr::hash() const {
4838   return klass()->hash() + TypeOopPtr::hash() + _interfaces->hash() + static_cast<uint>(_flat_in_array);
4839 }
4840 
4841 bool TypeInstPtr::is_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const {
4842   return TypePtr::is_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact);
4843 }
4844 
4845 
4846 bool TypeInstPtr::is_same_java_type_as_helper(const TypeOopPtr* other) const {
4847   return TypePtr::is_same_java_type_as_helper_for_instance(this, other);
4848 }
4849 
4850 bool TypeInstPtr::maybe_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const {
4851   return TypePtr::maybe_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact);
4852 }
4853 
4854 
4855 //------------------------------dump2------------------------------------------
4856 // Dump oop Type
4857 #ifndef PRODUCT
4858 void TypeInstPtr::dump2(Dict &d, uint depth, outputStream* st) const {
4859   // Print the name of the klass.
4860   st->print("instptr:");
4861   klass()->print_name_on(st);
4862   _interfaces->dump(st);
4863 
4864   if (_ptr == Constant && (WizardMode || Verbose)) {
4865     ResourceMark rm;
4866     stringStream ss;
4867 
4868     st->print(" ");
4869     const_oop()->print_oop(&ss);
4870     // 'const_oop->print_oop()' may emit newlines('\n') into ss.
4871     // suppress newlines from it so -XX:+Verbose -XX:+PrintIdeal dumps one-liner for each node.
4872     char* buf = ss.as_string(/* c_heap= */false);
4873     StringUtils::replace_no_expand(buf, "\n", "");
4874     st->print_raw(buf);
4875   }
4876 
4877   st->print(":%s", ptr_msg[_ptr]);
4878   if (_klass_is_exact) {
4879     st->print(":exact");
4880   }
4881 
4882   st->print(" *");
4883 
4884   dump_offset(st);
4885   dump_instance_id(st);
4886   dump_inline_depth(st);
4887   dump_speculative(st);
4888   dump_flat_in_array(_flat_in_array, st);
4889 }
4890 #endif
4891 
4892 bool TypeInstPtr::empty() const {
4893   if (_flat_in_array == TopFlat) {
4894     return true;
4895   }
4896   return TypeOopPtr::empty();
4897 }
4898 
4899 //------------------------------add_offset-------------------------------------
4900 const TypePtr* TypeInstPtr::add_offset(intptr_t offset) const {
4901   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), xadd_offset(offset), _flat_in_array,
4902               _instance_id, add_offset_speculative(offset), _inline_depth);
4903 }
4904 
4905 const TypeInstPtr* TypeInstPtr::with_offset(intptr_t offset) const {
4906   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), Offset(offset), _flat_in_array,
4907               _instance_id, with_offset_speculative(offset), _inline_depth);
4908 }
4909 
4910 const TypeInstPtr* TypeInstPtr::remove_speculative() const {
4911   if (_speculative == nullptr) {
4912     return this;
4913   }
4914   assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth");
4915   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, _flat_in_array,
4916               _instance_id, nullptr, _inline_depth);
4917 }
4918 
4919 const TypeInstPtr* TypeInstPtr::with_speculative(const TypePtr* speculative) const {
4920   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, _flat_in_array, _instance_id, speculative, _inline_depth);
4921 }
4922 
4923 const TypePtr* TypeInstPtr::with_inline_depth(int depth) const {
4924   if (!UseInlineDepthForSpeculativeTypes) {
4925     return this;
4926   }
4927   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, _flat_in_array, _instance_id, _speculative, depth);
4928 }
4929 
4930 const TypePtr* TypeInstPtr::with_instance_id(int instance_id) const {
4931   assert(is_known_instance(), "should be known");
4932   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, _flat_in_array, instance_id, _speculative, _inline_depth);
4933 }
4934 
4935 const TypeInstPtr *TypeInstPtr::cast_to_flat_in_array() const {
4936   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, Flat, _instance_id, _speculative, _inline_depth);
4937 }
4938 
4939 const TypeInstPtr *TypeInstPtr::cast_to_maybe_flat_in_array() const {
4940   return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, MaybeFlat, _instance_id, _speculative, _inline_depth);
4941 }
4942 
4943 const TypeKlassPtr* TypeInstPtr::as_klass_type(bool try_for_exact) const {
4944   bool xk = klass_is_exact();
4945   ciInstanceKlass* ik = klass()->as_instance_klass();
4946   if (try_for_exact && !xk && !ik->has_subklass() && !ik->is_final()) {
4947     if (_interfaces->eq(ik)) {
4948       Compile* C = Compile::current();
4949       Dependencies* deps = C->dependencies();
4950       deps->assert_leaf_type(ik);
4951       xk = true;
4952     }
4953   }
4954   FlatInArray flat_in_array = compute_flat_in_array_if_unknown(ik, xk, _flat_in_array);
4955   return TypeInstKlassPtr::make(xk ? TypePtr::Constant : TypePtr::NotNull, klass(), _interfaces, Offset(0), flat_in_array);
4956 }
4957 
4958 template <class T1, class T2> bool TypePtr::is_meet_subtype_of_helper_for_instance(const T1* this_one, const T2* other, bool this_xk, bool other_xk) {
4959   static_assert(std::is_base_of<T2, T1>::value, "");
4960 
4961   if (!this_one->is_instance_type(other)) {
4962     return false;
4963   }
4964 
4965   if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty()) {
4966     return true;
4967   }
4968 
4969   return this_one->klass()->is_subtype_of(other->klass()) &&
4970          (!this_xk || this_one->_interfaces->contains(other->_interfaces));
4971 }
4972 
4973 
4974 bool TypeInstPtr::is_meet_subtype_of_helper(const TypeOopPtr *other, bool this_xk, bool other_xk) const {
4975   return TypePtr::is_meet_subtype_of_helper_for_instance(this, other, this_xk, other_xk);
4976 }
4977 
4978 template <class T1, class T2>  bool TypePtr::is_meet_subtype_of_helper_for_array(const T1* this_one, const T2* other, bool this_xk, bool other_xk) {
4979   static_assert(std::is_base_of<T2, T1>::value, "");
4980   if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty()) {
4981     return true;
4982   }
4983 
4984   if (this_one->is_instance_type(other)) {
4985     return other->klass() == ciEnv::current()->Object_klass() && this_one->_interfaces->contains(other->_interfaces);
4986   }
4987 
4988   int dummy;
4989   bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM);
4990   if (this_top_or_bottom) {
4991     return false;
4992   }
4993 
4994   const T1* other_ary = this_one->is_array_type(other);
4995   const TypePtr* other_elem = other_ary->elem()->make_ptr();
4996   const TypePtr* this_elem = this_one->elem()->make_ptr();
4997   if (other_elem != nullptr && this_elem != nullptr) {
4998     return this_one->is_reference_type(this_elem)->is_meet_subtype_of_helper(this_one->is_reference_type(other_elem), this_xk, other_xk);
4999   }
5000   if (other_elem == nullptr && this_elem == nullptr) {
5001     return this_one->klass()->is_subtype_of(other->klass());
5002   }
5003 
5004   return false;
5005 }
5006 
5007 bool TypeAryPtr::is_meet_subtype_of_helper(const TypeOopPtr *other, bool this_xk, bool other_xk) const {
5008   return TypePtr::is_meet_subtype_of_helper_for_array(this, other, this_xk, other_xk);
5009 }
5010 
5011 bool TypeInstKlassPtr::is_meet_subtype_of_helper(const TypeKlassPtr *other, bool this_xk, bool other_xk) const {
5012   return TypePtr::is_meet_subtype_of_helper_for_instance(this, other, this_xk, other_xk);
5013 }
5014 
5015 bool TypeAryKlassPtr::is_meet_subtype_of_helper(const TypeKlassPtr *other, bool this_xk, bool other_xk) const {
5016   return TypePtr::is_meet_subtype_of_helper_for_array(this, other, this_xk, other_xk);
5017 }
5018 
5019 //=============================================================================
5020 // Convenience common pre-built types.
5021 const TypeAryPtr* TypeAryPtr::BOTTOM;
5022 const TypeAryPtr *TypeAryPtr::RANGE;
5023 const TypeAryPtr *TypeAryPtr::OOPS;
5024 const TypeAryPtr *TypeAryPtr::NARROWOOPS;
5025 const TypeAryPtr *TypeAryPtr::BYTES;
5026 const TypeAryPtr *TypeAryPtr::SHORTS;
5027 const TypeAryPtr *TypeAryPtr::CHARS;
5028 const TypeAryPtr *TypeAryPtr::INTS;
5029 const TypeAryPtr *TypeAryPtr::LONGS;
5030 const TypeAryPtr *TypeAryPtr::FLOATS;
5031 const TypeAryPtr *TypeAryPtr::DOUBLES;
5032 const TypeAryPtr *TypeAryPtr::INLINES;
5033 
5034 //------------------------------make-------------------------------------------
5035 const TypeAryPtr* TypeAryPtr::make(PTR ptr, const TypeAry *ary, ciKlass* k, bool xk, Offset offset, Offset field_offset,
5036                                    int instance_id, const TypePtr* speculative, int inline_depth) {
5037   assert(!(k == nullptr && ary->_elem->isa_int()),
5038          "integral arrays must be pre-equipped with a class");
5039   if (!xk)  xk = ary->ary_must_be_exact();
5040   assert(instance_id <= 0 || xk, "instances are always exactly typed");
5041   if (k != nullptr && k->is_loaded() && k->is_obj_array_klass() &&
5042       k->as_obj_array_klass()->base_element_klass()->is_interface()) {
5043     k = nullptr;
5044   }
5045   return (TypeAryPtr*)(new TypeAryPtr(ptr, nullptr, ary, k, xk, offset, field_offset, instance_id, false, speculative, inline_depth))->hashcons();
5046 }
5047 
5048 //------------------------------make-------------------------------------------
5049 const TypeAryPtr* TypeAryPtr::make(PTR ptr, ciObject* o, const TypeAry *ary, ciKlass* k, bool xk, Offset offset, Offset field_offset,
5050                                    int instance_id, const TypePtr* speculative, int inline_depth,
5051                                    bool is_autobox_cache) {
5052   assert(!(k == nullptr && ary->_elem->isa_int()),
5053          "integral arrays must be pre-equipped with a class");
5054   assert( (ptr==Constant && o) || (ptr!=Constant && !o), "" );
5055   if (!xk)  xk = (o != nullptr) || ary->ary_must_be_exact();
5056   assert(instance_id <= 0 || xk, "instances are always exactly typed");
5057   if (k != nullptr && k->is_loaded() && k->is_obj_array_klass() &&
5058       k->as_obj_array_klass()->base_element_klass()->is_interface()) {
5059     k = nullptr;
5060   }
5061   return (TypeAryPtr*)(new TypeAryPtr(ptr, o, ary, k, xk, offset, field_offset, instance_id, is_autobox_cache, speculative, inline_depth))->hashcons();
5062 }
5063 
5064 //------------------------------cast_to_ptr_type-------------------------------
5065 const TypeAryPtr* TypeAryPtr::cast_to_ptr_type(PTR ptr) const {
5066   if( ptr == _ptr ) return this;
5067   return make(ptr, ptr == Constant ? const_oop() : nullptr, _ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5068 }
5069 
5070 
5071 //-----------------------------cast_to_exactness-------------------------------
5072 const TypeAryPtr* TypeAryPtr::cast_to_exactness(bool klass_is_exact) const {
5073   if( klass_is_exact == _klass_is_exact ) return this;
5074   if (_ary->ary_must_be_exact())  return this;  // cannot clear xk
5075   return make(ptr(), const_oop(), _ary, klass(), klass_is_exact, _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5076 }
5077 
5078 //-----------------------------cast_to_instance_id----------------------------
5079 const TypeAryPtr* TypeAryPtr::cast_to_instance_id(int instance_id) const {
5080   if( instance_id == _instance_id ) return this;
5081   return make(_ptr, const_oop(), _ary, klass(), _klass_is_exact, _offset, _field_offset, instance_id, _speculative, _inline_depth, _is_autobox_cache);
5082 }
5083 
5084 
5085 //-----------------------------max_array_length-------------------------------
5086 // A wrapper around arrayOopDesc::max_array_length(etype) with some input normalization.
5087 jint TypeAryPtr::max_array_length(BasicType etype) {
5088   if (!is_java_primitive(etype) && !::is_reference_type(etype)) {
5089     if (etype == T_NARROWOOP) {
5090       etype = T_OBJECT;
5091     } else if (etype == T_ILLEGAL) { // bottom[]
5092       etype = T_BYTE; // will produce conservatively high value
5093     } else {
5094       fatal("not an element type: %s", type2name(etype));
5095     }
5096   }
5097   return arrayOopDesc::max_array_length(etype);
5098 }
5099 
5100 //-----------------------------narrow_size_type-------------------------------
5101 // Narrow the given size type to the index range for the given array base type.
5102 // Return null if the resulting int type becomes empty.
5103 const TypeInt* TypeAryPtr::narrow_size_type(const TypeInt* size) const {
5104   jint hi = size->_hi;
5105   jint lo = size->_lo;
5106   jint min_lo = 0;
5107   jint max_hi = max_array_length(elem()->array_element_basic_type());
5108   //if (index_not_size)  --max_hi;     // type of a valid array index, FTR
5109   bool chg = false;
5110   if (lo < min_lo) {
5111     lo = min_lo;
5112     if (size->is_con()) {
5113       hi = lo;
5114     }
5115     chg = true;
5116   }
5117   if (hi > max_hi) {
5118     hi = max_hi;
5119     if (size->is_con()) {
5120       lo = hi;
5121     }
5122     chg = true;
5123   }
5124   // Negative length arrays will produce weird intermediate dead fast-path code
5125   if (lo > hi) {
5126     return TypeInt::ZERO;
5127   }
5128   if (!chg) {
5129     return size;
5130   }
5131   return TypeInt::make(lo, hi, Type::WidenMin);
5132 }
5133 
5134 //-------------------------------cast_to_size----------------------------------
5135 const TypeAryPtr* TypeAryPtr::cast_to_size(const TypeInt* new_size) const {
5136   assert(new_size != nullptr, "");
5137   new_size = narrow_size_type(new_size);
5138   if (new_size == size())  return this;
5139   const TypeAry* new_ary = TypeAry::make(elem(), new_size, is_stable(), is_flat(), is_not_flat(), is_not_null_free(), is_atomic());
5140   return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5141 }
5142 
5143 const TypeAryPtr* TypeAryPtr::cast_to_flat(bool flat) const {
5144   if (flat == is_flat()) {
5145     return this;
5146   }
5147   assert(!flat || !is_not_flat(), "inconsistency");
5148   const TypeAry* new_ary = TypeAry::make(elem(), size(), is_stable(), flat, is_not_flat(), is_not_null_free(), is_atomic());
5149   const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5150   if (res->speculative() == res->remove_speculative()) {
5151     return res->remove_speculative();
5152   }
5153   return res;
5154 }
5155 
5156 //-------------------------------cast_to_not_flat------------------------------
5157 const TypeAryPtr* TypeAryPtr::cast_to_not_flat(bool not_flat) const {
5158   if (not_flat == is_not_flat()) {
5159     return this;
5160   }
5161   assert(!not_flat || !is_flat(), "inconsistency");
5162   const TypeAry* new_ary = TypeAry::make(elem(), size(), is_stable(), is_flat(), not_flat, is_not_null_free(), is_atomic());
5163   const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5164   // We keep the speculative part if it contains information about flat-/nullability.
5165   // Make sure it's removed if it's not better than the non-speculative type anymore.
5166   if (res->speculative() == res->remove_speculative()) {
5167     return res->remove_speculative();
5168   }
5169   return res;
5170 }
5171 
5172 const TypeAryPtr* TypeAryPtr::cast_to_null_free(bool null_free) const {
5173   if (null_free == is_null_free()) {
5174     return this;
5175   }
5176   assert(!null_free || !is_not_null_free(), "inconsistency");
5177   const Type* elem = this->elem();
5178   const Type* new_elem = elem->make_ptr();
5179   if (null_free) {
5180     new_elem = new_elem->join_speculative(TypePtr::NOTNULL);
5181   } else {
5182     new_elem = new_elem->meet_speculative(TypePtr::NULL_PTR);
5183   }
5184   new_elem = elem->isa_narrowoop() ? new_elem->make_narrowoop() : new_elem;
5185   const TypeAry* new_ary = TypeAry::make(new_elem, size(), is_stable(), is_flat(), is_not_flat(), is_not_null_free(), is_atomic());
5186   const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5187   if (res->speculative() == res->remove_speculative()) {
5188     return res->remove_speculative();
5189   }
5190   assert(res->speculative() == nullptr || res->speculative()->with_inline_depth(res->inline_depth())->higher_equal(res->remove_speculative()),
5191            "speculative type must not be narrower than non-speculative type");
5192   return res;
5193 }
5194 
5195 //-------------------------------cast_to_not_null_free-------------------------
5196 const TypeAryPtr* TypeAryPtr::cast_to_not_null_free(bool not_null_free) const {
5197   if (not_null_free == is_not_null_free()) {
5198     return this;
5199   }
5200   assert(!not_null_free || !is_null_free(), "inconsistency");
5201   const TypeAry* new_ary = TypeAry::make(elem(), size(), is_stable(), is_flat(), is_not_flat(), not_null_free, is_atomic());
5202   const TypePtr* new_spec = _speculative;
5203   if (new_spec != nullptr) {
5204     // Could be 'null free' from profiling, which would contradict the cast.
5205     new_spec = new_spec->is_aryptr()->cast_to_null_free(false)->cast_to_not_null_free();
5206   }
5207   const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset,
5208                                _instance_id, new_spec, _inline_depth, _is_autobox_cache);
5209   // We keep the speculative part if it contains information about flat-/nullability.
5210   // Make sure it's removed if it's not better than the non-speculative type anymore.
5211   if (res->speculative() == res->remove_speculative()) {
5212     return res->remove_speculative();
5213   }
5214   assert(res->speculative() == nullptr || res->speculative()->with_inline_depth(res->inline_depth())->higher_equal(res->remove_speculative()),
5215            "speculative type must not be narrower than non-speculative type");
5216   return res;
5217 }
5218 
5219 //---------------------------------update_properties---------------------------
5220 const TypeAryPtr* TypeAryPtr::update_properties(const TypeAryPtr* from) const {
5221   if ((from->is_flat()          && is_not_flat()) ||
5222       (from->is_not_flat()      && is_flat()) ||
5223       (from->is_null_free()     && is_not_null_free()) ||
5224       (from->is_not_null_free() && is_null_free())) {
5225     return nullptr; // Inconsistent properties
5226   }
5227   const TypeAryPtr* res = this;
5228   if (from->is_not_null_free()) {
5229     res = res->cast_to_not_null_free();
5230   }
5231   if (from->is_not_flat()) {
5232     res = res->cast_to_not_flat();
5233   }
5234   return res;
5235 }
5236 
5237 jint TypeAryPtr::flat_layout_helper() const {
5238   return exact_klass()->as_flat_array_klass()->layout_helper();
5239 }
5240 
5241 int TypeAryPtr::flat_elem_size() const {
5242   return exact_klass()->as_flat_array_klass()->element_byte_size();
5243 }
5244 
5245 int TypeAryPtr::flat_log_elem_size() const {
5246   return exact_klass()->as_flat_array_klass()->log2_element_size();
5247 }
5248 
5249 jint TypeAryPtr::max_flat_elements() const {
5250   return exact_klass()->as_flat_array_klass()->max_elements();
5251 }
5252 
5253 //------------------------------cast_to_stable---------------------------------
5254 const TypeAryPtr* TypeAryPtr::cast_to_stable(bool stable, int stable_dimension) const {
5255   if (stable_dimension <= 0 || (stable_dimension == 1 && stable == this->is_stable()))
5256     return this;
5257 
5258   const Type* elem = this->elem();
5259   const TypePtr* elem_ptr = elem->make_ptr();
5260 
5261   if (stable_dimension > 1 && elem_ptr != nullptr && elem_ptr->isa_aryptr()) {
5262     // If this is widened from a narrow oop, TypeAry::make will re-narrow it.
5263     elem = elem_ptr = elem_ptr->is_aryptr()->cast_to_stable(stable, stable_dimension - 1);
5264   }
5265 
5266   const TypeAry* new_ary = TypeAry::make(elem, size(), stable, is_flat(), is_not_flat(), is_not_null_free(), is_atomic());
5267 
5268   return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5269 }
5270 
5271 //-----------------------------stable_dimension--------------------------------
5272 int TypeAryPtr::stable_dimension() const {
5273   if (!is_stable())  return 0;
5274   int dim = 1;
5275   const TypePtr* elem_ptr = elem()->make_ptr();
5276   if (elem_ptr != nullptr && elem_ptr->isa_aryptr())
5277     dim += elem_ptr->is_aryptr()->stable_dimension();
5278   return dim;
5279 }
5280 
5281 //----------------------cast_to_autobox_cache-----------------------------------
5282 const TypeAryPtr* TypeAryPtr::cast_to_autobox_cache() const {
5283   if (is_autobox_cache())  return this;
5284   const TypeOopPtr* etype = elem()->make_oopptr();
5285   if (etype == nullptr)  return this;
5286   // The pointers in the autobox arrays are always non-null.
5287   etype = etype->cast_to_ptr_type(TypePtr::NotNull)->is_oopptr();
5288   const TypeAry* new_ary = TypeAry::make(etype, size(), is_stable(), is_flat(), is_not_flat(), is_not_null_free(), is_atomic());
5289   return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, /*is_autobox_cache=*/true);
5290 }
5291 
5292 //------------------------------eq---------------------------------------------
5293 // Structural equality check for Type representations
5294 bool TypeAryPtr::eq( const Type *t ) const {
5295   const TypeAryPtr *p = t->is_aryptr();
5296   return
5297     _ary == p->_ary &&  // Check array
5298     TypeOopPtr::eq(p) &&// Check sub-parts
5299     _field_offset == p->_field_offset;
5300 }
5301 
5302 //------------------------------hash-------------------------------------------
5303 // Type-specific hashing function.
5304 uint TypeAryPtr::hash(void) const {
5305   return (uint)(uintptr_t)_ary + TypeOopPtr::hash() + _field_offset.get();
5306 }
5307 
5308 bool TypeAryPtr::is_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const {
5309   return TypePtr::is_java_subtype_of_helper_for_array(this, other, this_exact, other_exact);
5310 }
5311 
5312 bool TypeAryPtr::is_same_java_type_as_helper(const TypeOopPtr* other) const {
5313   return TypePtr::is_same_java_type_as_helper_for_array(this, other);
5314 }
5315 
5316 bool TypeAryPtr::maybe_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const {
5317   return TypePtr::maybe_java_subtype_of_helper_for_array(this, other, this_exact, other_exact);
5318 }
5319 //------------------------------meet-------------------------------------------
5320 // Compute the MEET of two types.  It returns a new Type object.
5321 const Type *TypeAryPtr::xmeet_helper(const Type *t) const {
5322   // Perform a fast test for common case; meeting the same types together.
5323   if( this == t ) return this;  // Meeting same type-rep?
5324   // Current "this->_base" is Pointer
5325   switch (t->base()) {          // switch on original type
5326 
5327   // Mixing ints & oops happens when javac reuses local variables
5328   case Int:
5329   case Long:
5330   case HalfFloatTop:
5331   case HalfFloatCon:
5332   case HalfFloatBot:
5333   case FloatTop:
5334   case FloatCon:
5335   case FloatBot:
5336   case DoubleTop:
5337   case DoubleCon:
5338   case DoubleBot:
5339   case NarrowOop:
5340   case NarrowKlass:
5341   case Bottom:                  // Ye Olde Default
5342     return Type::BOTTOM;
5343   case Top:
5344     return this;
5345 
5346   default:                      // All else is a mistake
5347     typerr(t);
5348 
5349   case OopPtr: {                // Meeting to OopPtrs
5350     // Found a OopPtr type vs self-AryPtr type
5351     const TypeOopPtr *tp = t->is_oopptr();
5352     Offset offset = meet_offset(tp->offset());
5353     PTR ptr = meet_ptr(tp->ptr());
5354     int depth = meet_inline_depth(tp->inline_depth());
5355     const TypePtr* speculative = xmeet_speculative(tp);
5356     switch (tp->ptr()) {
5357     case TopPTR:
5358     case AnyNull: {
5359       int instance_id = meet_instance_id(InstanceTop);
5360       return make(ptr, (ptr == Constant ? const_oop() : nullptr),
5361                   _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth);
5362     }
5363     case BotPTR:
5364     case NotNull: {
5365       int instance_id = meet_instance_id(tp->instance_id());
5366       return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth);
5367     }
5368     default: ShouldNotReachHere();
5369     }
5370   }
5371 
5372   case AnyPtr: {                // Meeting two AnyPtrs
5373     // Found an AnyPtr type vs self-AryPtr type
5374     const TypePtr *tp = t->is_ptr();
5375     Offset offset = meet_offset(tp->offset());
5376     PTR ptr = meet_ptr(tp->ptr());
5377     const TypePtr* speculative = xmeet_speculative(tp);
5378     int depth = meet_inline_depth(tp->inline_depth());
5379     switch (tp->ptr()) {
5380     case TopPTR:
5381       return this;
5382     case BotPTR:
5383     case NotNull:
5384       return TypePtr::make(AnyPtr, ptr, offset, speculative, depth);
5385     case Null:
5386       if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth);
5387       // else fall through to AnyNull
5388     case AnyNull: {
5389       int instance_id = meet_instance_id(InstanceTop);
5390       return make(ptr, (ptr == Constant ? const_oop() : nullptr),
5391                   _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth);
5392     }
5393     default: ShouldNotReachHere();
5394     }
5395   }
5396 
5397   case MetadataPtr:
5398   case KlassPtr:
5399   case InstKlassPtr:
5400   case AryKlassPtr:
5401   case RawPtr: return TypePtr::BOTTOM;
5402 
5403   case AryPtr: {                // Meeting 2 references?
5404     const TypeAryPtr *tap = t->is_aryptr();
5405     Offset off = meet_offset(tap->offset());
5406     Offset field_off = meet_field_offset(tap->field_offset());
5407     const Type* tm = _ary->meet_speculative(tap->_ary);
5408     const TypeAry* tary = tm->isa_ary();
5409     if (tary == nullptr) {
5410       assert(tm == Type::TOP || tm == Type::BOTTOM, "");
5411       return tm;
5412     }
5413     PTR ptr = meet_ptr(tap->ptr());
5414     int instance_id = meet_instance_id(tap->instance_id());
5415     const TypePtr* speculative = xmeet_speculative(tap);
5416     int depth = meet_inline_depth(tap->inline_depth());
5417 
5418     ciKlass* res_klass = nullptr;
5419     bool res_xk = false;
5420     bool res_flat = false;
5421     bool res_not_flat = false;
5422     bool res_not_null_free = false;
5423     bool res_atomic = false;
5424     const Type* elem = tary->_elem;
5425     if (meet_aryptr(ptr, elem, this, tap, res_klass, res_xk, res_flat, res_not_flat, res_not_null_free, res_atomic) == NOT_SUBTYPE) {
5426       instance_id = InstanceBot;
5427     } else if (this->is_flat() != tap->is_flat()) {
5428       // Meeting flat inline type array with non-flat array. Adjust (field) offset accordingly.
5429       if (tary->_flat) {
5430         // Result is in a flat representation
5431         off = Offset(is_flat() ? offset() : tap->offset());
5432         field_off = is_flat() ? field_offset() : tap->field_offset();
5433       } else if (below_centerline(ptr)) {
5434         // Result is in a non-flat representation
5435         off = Offset(flat_offset()).meet(Offset(tap->flat_offset()));
5436         field_off = (field_off == Offset::top) ? Offset::top : Offset::bottom;
5437       } else if (flat_offset() == tap->flat_offset()) {
5438         off = Offset(!is_flat() ? offset() : tap->offset());
5439         field_off = !is_flat() ? field_offset() : tap->field_offset();
5440       }
5441     }
5442 
5443     ciObject* o = nullptr;             // Assume not constant when done
5444     ciObject* this_oop = const_oop();
5445     ciObject* tap_oop = tap->const_oop();
5446     if (ptr == Constant) {
5447       if (this_oop != nullptr && tap_oop != nullptr &&
5448           this_oop->equals(tap_oop)) {
5449         o = tap_oop;
5450       } else if (above_centerline(_ptr)) {
5451         o = tap_oop;
5452       } else if (above_centerline(tap->_ptr)) {
5453         o = this_oop;
5454       } else {
5455         ptr = NotNull;
5456       }
5457     }
5458     return make(ptr, o, TypeAry::make(elem, tary->_size, tary->_stable, res_flat, res_not_flat, res_not_null_free, res_atomic), res_klass, res_xk, off, field_off, instance_id, speculative, depth);
5459   }
5460 
5461   // All arrays inherit from Object class
5462   case InstPtr: {
5463     const TypeInstPtr *tp = t->is_instptr();
5464     Offset offset = meet_offset(tp->offset());
5465     PTR ptr = meet_ptr(tp->ptr());
5466     int instance_id = meet_instance_id(tp->instance_id());
5467     const TypePtr* speculative = xmeet_speculative(tp);
5468     int depth = meet_inline_depth(tp->inline_depth());
5469     const TypeInterfaces* interfaces = meet_interfaces(tp);
5470     const TypeInterfaces* tp_interfaces = tp->_interfaces;
5471     const TypeInterfaces* this_interfaces = _interfaces;
5472 
5473     switch (ptr) {
5474     case TopPTR:
5475     case AnyNull:                // Fall 'down' to dual of object klass
5476       // For instances when a subclass meets a superclass we fall
5477       // below the centerline when the superclass is exact. We need to
5478       // do the same here.
5479       //
5480       // Flat in array:
5481       // We do
5482       //   dual(TypeAryPtr) MEET dual(TypeInstPtr)
5483       // If TypeInstPtr is anything else than Object, then the result of the meet is bottom Object (i.e. we could have
5484       // instances or arrays).
5485       // If TypeInstPtr is an Object and either
5486       // - exact
5487       // - inexact AND flat in array == dual(not flat in array) (i.e. not an array type)
5488       // then the result of the meet is bottom Object (i.e. we could have instances or arrays).
5489       // Otherwise, we meet two array pointers and create a new TypeAryPtr.
5490       if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) &&
5491           !tp->klass_is_exact() && !tp->is_not_flat_in_array()) {
5492         return TypeAryPtr::make(ptr, _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth);
5493       } else {
5494         // cannot subclass, so the meet has to fall badly below the centerline
5495         ptr = NotNull;
5496         instance_id = InstanceBot;
5497         interfaces = this_interfaces->intersection_with(tp_interfaces);
5498         FlatInArray flat_in_array = meet_flat_in_array(NotFlat, tp->flat_in_array());
5499         return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, false, nullptr, offset, flat_in_array, instance_id, speculative, depth);
5500       }
5501     case Constant:
5502     case NotNull:
5503     case BotPTR: { // Fall down to object klass
5504       // LCA is object_klass, but if we subclass from the top we can do better
5505       if (above_centerline(tp->ptr())) {
5506         // If 'tp'  is above the centerline and it is Object class
5507         // then we can subclass in the Java class hierarchy.
5508         // For instances when a subclass meets a superclass we fall
5509         // below the centerline when the superclass is exact. We need
5510         // to do the same here.
5511 
5512         // Flat in array: We do TypeAryPtr MEET dual(TypeInstPtr), same applies as above in TopPTR/AnyNull case.
5513         if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) &&
5514             !tp->klass_is_exact() && !tp->is_not_flat_in_array()) {
5515           // that is, my array type is a subtype of 'tp' klass
5516           return make(ptr, (ptr == Constant ? const_oop() : nullptr),
5517                       _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth);
5518         }
5519       }
5520       // The other case cannot happen, since t cannot be a subtype of an array.
5521       // The meet falls down to Object class below centerline.
5522       if (ptr == Constant) {
5523         ptr = NotNull;
5524       }
5525       if (instance_id > 0) {
5526         instance_id = InstanceBot;
5527       }
5528 
5529       FlatInArray flat_in_array = meet_flat_in_array(NotFlat, tp->flat_in_array());
5530       interfaces = this_interfaces->intersection_with(tp_interfaces);
5531       return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, false, nullptr, offset,
5532                                flat_in_array, instance_id, speculative, depth);
5533     }
5534     default: typerr(t);
5535     }
5536   }
5537   }
5538   return this;                  // Lint noise
5539 }
5540 
5541 
5542 template<class T> TypePtr::MeetResult TypePtr::meet_aryptr(PTR& ptr, const Type*& elem, const T* this_ary, const T* other_ary,
5543                                                            ciKlass*& res_klass, bool& res_xk, bool &res_flat, bool& res_not_flat, bool& res_not_null_free, bool &res_atomic) {
5544   int dummy;
5545   bool this_top_or_bottom = (this_ary->base_element_type(dummy) == Type::TOP || this_ary->base_element_type(dummy) == Type::BOTTOM);
5546   bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM);
5547   ciKlass* this_klass = this_ary->klass();
5548   ciKlass* other_klass = other_ary->klass();
5549   bool this_xk = this_ary->klass_is_exact();
5550   bool other_xk = other_ary->klass_is_exact();
5551   PTR this_ptr = this_ary->ptr();
5552   PTR other_ptr = other_ary->ptr();
5553   bool this_flat = this_ary->is_flat();
5554   bool this_not_flat = this_ary->is_not_flat();
5555   bool other_flat = other_ary->is_flat();
5556   bool other_not_flat = other_ary->is_not_flat();
5557   bool this_not_null_free = this_ary->is_not_null_free();
5558   bool other_not_null_free = other_ary->is_not_null_free();
5559   bool this_atomic = this_ary->is_atomic();
5560   bool other_atomic = other_ary->is_atomic();
5561   const bool same_nullness = this_ary->is_null_free() == other_ary->is_null_free();
5562   res_klass = nullptr;
5563   MeetResult result = SUBTYPE;
5564   res_flat = this_flat && other_flat;
5565   bool res_null_free = this_ary->is_null_free() && other_ary->is_null_free();
5566   res_not_flat = this_not_flat && other_not_flat;
5567   res_not_null_free = this_not_null_free && other_not_null_free;
5568   res_atomic = this_atomic && other_atomic;
5569 
5570   if (elem->isa_int()) {
5571     // Integral array element types have irrelevant lattice relations.
5572     // It is the klass that determines array layout, not the element type.
5573       if (this_top_or_bottom) {
5574         res_klass = other_klass;
5575       } else if (other_top_or_bottom || other_klass == this_klass) {
5576       res_klass = this_klass;
5577     } else {
5578       // Something like byte[int+] meets char[int+].
5579       // This must fall to bottom, not (int[-128..65535])[int+].
5580       // instance_id = InstanceBot;
5581       elem = Type::BOTTOM;
5582       result = NOT_SUBTYPE;
5583       if (above_centerline(ptr) || ptr == Constant) {
5584         ptr = NotNull;
5585         res_xk = false;
5586         return NOT_SUBTYPE;
5587       }
5588     }
5589   } else {// Non integral arrays.
5590     // Must fall to bottom if exact klasses in upper lattice
5591     // are not equal or super klass is exact.
5592     if ((above_centerline(ptr) || ptr == Constant) && !this_ary->is_same_java_type_as(other_ary) &&
5593         // meet with top[] and bottom[] are processed further down:
5594         !this_top_or_bottom && !other_top_or_bottom &&
5595         // both are exact and not equal:
5596         ((other_xk && this_xk) ||
5597          // 'tap'  is exact and super or unrelated:
5598          (other_xk && !other_ary->is_meet_subtype_of(this_ary)) ||
5599          // 'this' is exact and super or unrelated:
5600          (this_xk && !this_ary->is_meet_subtype_of(other_ary)))) {
5601       if (above_centerline(ptr) || (elem->make_ptr() && above_centerline(elem->make_ptr()->_ptr))) {
5602         elem = Type::BOTTOM;
5603       }
5604       ptr = NotNull;
5605       res_xk = false;
5606       return NOT_SUBTYPE;
5607     }
5608   }
5609 
5610   res_xk = false;
5611   switch (other_ptr) {
5612     case AnyNull:
5613     case TopPTR:
5614       // Compute new klass on demand, do not use tap->_klass
5615       if (below_centerline(this_ptr)) {
5616         res_xk = this_xk;
5617         if (this_ary->is_flat()) {
5618           elem = this_ary->elem();
5619         }
5620       } else {
5621         res_xk = (other_xk || this_xk);
5622       }
5623       break;
5624     case Constant: {
5625       if (this_ptr == Constant && same_nullness) {
5626         // Only exact if same nullness since:
5627         //     null-free [LMyValue <: nullable [LMyValue.
5628         res_xk = true;
5629       } else if (above_centerline(this_ptr)) {
5630         res_xk = true;
5631       } else {
5632         // Only precise for identical arrays
5633         res_xk = this_xk && (this_ary->is_same_java_type_as(other_ary) || (this_top_or_bottom && other_top_or_bottom));
5634         // Even though MyValue is final, [LMyValue is only exact if the array
5635         // is (not) null-free due to null-free [LMyValue <: null-able [LMyValue.
5636         if (res_xk && !res_null_free && !res_not_null_free) {
5637           ptr = NotNull;
5638           res_xk = false;
5639         }
5640       }
5641       break;
5642     }
5643     case NotNull:
5644     case BotPTR:
5645       // Compute new klass on demand, do not use tap->_klass
5646       if (above_centerline(this_ptr)) {
5647         res_xk = other_xk;
5648         if (other_ary->is_flat()) {
5649           elem = other_ary->elem();
5650         }
5651       } else {
5652         res_xk = (other_xk && this_xk) &&
5653                  (this_ary->is_same_java_type_as(other_ary) || (this_top_or_bottom && other_top_or_bottom)); // Only precise for identical arrays
5654         // Even though MyValue is final, [LMyValue is only exact if the array
5655         // is (not) null-free due to null-free [LMyValue <: null-able [LMyValue.
5656         if (res_xk && !res_null_free && !res_not_null_free) {
5657           res_xk = false;
5658         }
5659       }
5660       break;
5661     default:  {
5662       ShouldNotReachHere();
5663       return result;
5664     }
5665   }
5666   return result;
5667 }
5668 
5669 
5670 //------------------------------xdual------------------------------------------
5671 // Dual: compute field-by-field dual
5672 const Type *TypeAryPtr::xdual() const {
5673   bool xk = _klass_is_exact;
5674   return new TypeAryPtr(dual_ptr(), _const_oop, _ary->dual()->is_ary(), _klass, xk, dual_offset(), dual_field_offset(), dual_instance_id(), is_autobox_cache(), dual_speculative(), dual_inline_depth());
5675 }
5676 
5677 Type::Offset TypeAryPtr::meet_field_offset(const Type::Offset offset) const {
5678   return _field_offset.meet(offset);
5679 }
5680 
5681 //------------------------------dual_offset------------------------------------
5682 Type::Offset TypeAryPtr::dual_field_offset() const {
5683   return _field_offset.dual();
5684 }
5685 
5686 //------------------------------dump2------------------------------------------
5687 #ifndef PRODUCT
5688 void TypeAryPtr::dump2( Dict &d, uint depth, outputStream *st ) const {
5689   st->print("aryptr:");
5690   _ary->dump2(d, depth, st);
5691   _interfaces->dump(st);
5692 
5693   if (_ptr == Constant) {
5694     const_oop()->print(st);
5695   }
5696 
5697   st->print(":%s", ptr_msg[_ptr]);
5698   if (_klass_is_exact) {
5699     st->print(":exact");
5700   }
5701 
5702   if (is_flat()) {
5703     st->print(":flat");
5704     st->print("(");
5705     _field_offset.dump2(st);
5706     st->print(")");
5707   } else if (is_not_flat()) {
5708     st->print(":not_flat");
5709   }
5710   if (is_null_free()) {
5711     st->print(":null free");
5712   }
5713   if (is_atomic()) {
5714     st->print(":atomic");
5715   }
5716   if (Verbose) {
5717     if (is_not_flat()) {
5718       st->print(":not flat");
5719     }
5720     if (is_not_null_free()) {
5721       st->print(":nullable");
5722     }
5723   }
5724   if (offset() != 0) {
5725     BasicType basic_elem_type = elem()->basic_type();
5726     int header_size = arrayOopDesc::base_offset_in_bytes(basic_elem_type);
5727     if( _offset == Offset::top )       st->print("+undefined");
5728     else if( _offset == Offset::bottom )  st->print("+any");
5729     else if( offset() < header_size ) st->print("+%d", offset());
5730     else {
5731       if (basic_elem_type == T_ILLEGAL) {
5732         st->print("+any");
5733       } else {
5734         int elem_size = type2aelembytes(basic_elem_type);
5735         st->print("[%d]", (offset() - header_size)/elem_size);
5736       }
5737     }
5738   }
5739 
5740   dump_instance_id(st);
5741   dump_inline_depth(st);
5742   dump_speculative(st);
5743 }
5744 #endif
5745 
5746 bool TypeAryPtr::empty(void) const {
5747   if (_ary->empty()) {
5748     return true;
5749   }
5750 
5751   // Reference array is always possible. Only flat array with non-flattenable content can be an issue.
5752   if (const TypeOopPtr* elem_ptr = elem()->make_oopptr(); _ary->_flat && elem_ptr != nullptr && elem_ptr->is_inlinetypeptr()) {
5753     auto impossible_layout_with_null_freeness = [this](bool null_free, bool atomic) -> bool {
5754       ArrayDescription description = elem()->inline_klass()->array_description_of_array_properties(ArrayProperties::Default().with_null_restricted(null_free).with_non_atomic(!atomic));
5755       return !LayoutKindHelper::is_flat(description._layout_kind);  // We get a contradiction between _ary->_flat and array_layout_selection
5756     };
5757     auto impossible_layout = [&](bool atomic) -> bool {
5758       if (is_null_free()) {
5759         // Surely null-free
5760         if (impossible_layout_with_null_freeness(true, atomic)) {
5761           return true;
5762         }
5763       } else if (is_not_null_free()) {
5764         // Surely nullable
5765         if (impossible_layout_with_null_freeness(false, atomic)) {
5766           return true;
5767         }
5768       } else {
5769         // Not sure...
5770         if (impossible_layout_with_null_freeness(false, atomic) && impossible_layout_with_null_freeness(true, atomic)) {
5771           return true;
5772         }
5773       }
5774       return false;
5775     };
5776     if (_ary->_atomic) {
5777       // Surely atomic
5778       if (impossible_layout(true)) {
5779         return true;
5780       }
5781     } else if (klass_is_exact()) {
5782       // Surely non-atomic
5783       if (impossible_layout(false)) {
5784         return true;
5785       }
5786     } else {
5787       // Not sure...
5788       if (impossible_layout(true) && impossible_layout(false)) {
5789         return true;
5790       }
5791     }
5792   }
5793 
5794   return TypeOopPtr::empty();
5795 }
5796 
5797 //------------------------------add_offset-------------------------------------
5798 const TypePtr* TypeAryPtr::add_offset(intptr_t offset) const {
5799   return make(_ptr, _const_oop, _ary, _klass, _klass_is_exact, xadd_offset(offset), _field_offset, _instance_id, add_offset_speculative(offset), _inline_depth, _is_autobox_cache);
5800 }
5801 
5802 const TypeAryPtr* TypeAryPtr::with_offset(intptr_t offset) const {
5803   return make(_ptr, _const_oop, _ary, _klass, _klass_is_exact, Offset(offset), _field_offset, _instance_id, with_offset_speculative(offset), _inline_depth, _is_autobox_cache);
5804 }
5805 
5806 const TypeAryPtr* TypeAryPtr::with_ary(const TypeAry* ary) const {
5807   return make(_ptr, _const_oop, ary, _klass, _klass_is_exact, _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5808 }
5809 
5810 const TypeAryPtr* TypeAryPtr::remove_speculative() const {
5811   if (_speculative == nullptr) {
5812     return this;
5813   }
5814   assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth");
5815   return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _field_offset, _instance_id, nullptr, _inline_depth, _is_autobox_cache);
5816 }
5817 
5818 const Type* TypeAryPtr::cleanup_speculative() const {
5819   if (speculative() == nullptr) {
5820     return this;
5821   }
5822   // Keep speculative part if it contains information about flat-/nullability
5823   const TypeAryPtr* spec_aryptr = speculative()->isa_aryptr();
5824   if (spec_aryptr != nullptr && !above_centerline(spec_aryptr->ptr()) &&
5825       (spec_aryptr->is_not_flat() || spec_aryptr->is_not_null_free())) {
5826     return this;
5827   }
5828   return TypeOopPtr::cleanup_speculative();
5829 }
5830 
5831 const TypePtr* TypeAryPtr::with_inline_depth(int depth) const {
5832   if (!UseInlineDepthForSpeculativeTypes) {
5833     return this;
5834   }
5835   return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _field_offset, _instance_id, _speculative, depth, _is_autobox_cache);
5836 }
5837 
5838 const TypeAryPtr* TypeAryPtr::with_field_offset(int offset) const {
5839   return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, Offset(offset), _instance_id, _speculative, _inline_depth, _is_autobox_cache);
5840 }
5841 
5842 const TypePtr* TypeAryPtr::add_field_offset_and_offset(intptr_t offset) const {
5843   if (!is_flat() || !klass_is_exact() || offset == OffsetBot || offset == OffsetTop) {
5844     return add_offset(offset);
5845   }
5846 
5847   // Handle flat concrete value class array with known 'offset' which could refer to an actual field in the flat storage.
5848   int adj = 0;
5849   if (_offset != Offset::bottom && _offset != Offset::top) {
5850     adj = _offset.get();
5851     offset += _offset.get();
5852   }
5853   uint header = arrayOopDesc::base_offset_in_bytes(T_FLAT_ELEMENT);
5854   if (_field_offset != Offset::bottom && _field_offset != Offset::top) {
5855     offset += _field_offset.get();
5856     if (_offset == Offset::bottom || _offset == Offset::top) {
5857       offset += header;
5858     }
5859   }
5860   if (elem()->make_oopptr()->is_inlinetypeptr() && (offset >= (intptr_t)header || offset < 0)) {
5861     // Try to get the field of the inline type array element we are pointing to
5862     ciInlineKlass* vk = elem()->inline_klass();
5863     int shift = flat_log_elem_size();
5864     int mask = (1 << shift) - 1;
5865     int field_offset = static_cast<int>((offset - header) & mask);
5866     ciField* field = vk->get_field_by_offset(field_offset + vk->payload_offset(), false);
5867     if (field != nullptr || field_offset == vk->null_marker_offset_in_payload()) {
5868       return with_field_offset(field_offset)->add_offset(offset - field_offset - adj);
5869     }
5870   }
5871   return add_offset(offset - adj);
5872 }
5873 
5874 // Return offset incremented by field_offset for flat inline type arrays
5875 int TypeAryPtr::flat_offset() const {
5876   int offset = _offset.get();
5877   if (offset != OffsetBot && offset != OffsetTop &&
5878       _field_offset != Offset::bottom && _field_offset != Offset::top) {
5879     offset += _field_offset.get();
5880   }
5881   return offset;
5882 }
5883 
5884 const TypePtr* TypeAryPtr::with_instance_id(int instance_id) const {
5885   assert(is_known_instance(), "should be known");
5886   return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _field_offset, instance_id, _speculative, _inline_depth);
5887 }
5888 
5889 //=============================================================================
5890 
5891 
5892 //------------------------------hash-------------------------------------------
5893 // Type-specific hashing function.
5894 uint TypeNarrowPtr::hash(void) const {
5895   return _ptrtype->hash() + 7;
5896 }
5897 
5898 bool TypeNarrowPtr::singleton(void) const {    // TRUE if type is a singleton
5899   return _ptrtype->singleton();
5900 }
5901 
5902 bool TypeNarrowPtr::empty(void) const {
5903   return _ptrtype->empty();
5904 }
5905 
5906 intptr_t TypeNarrowPtr::get_con() const {
5907   return _ptrtype->get_con();
5908 }
5909 
5910 bool TypeNarrowPtr::eq( const Type *t ) const {
5911   const TypeNarrowPtr* tc = isa_same_narrowptr(t);
5912   if (tc != nullptr) {
5913     if (_ptrtype->base() != tc->_ptrtype->base()) {
5914       return false;
5915     }
5916     return tc->_ptrtype->eq(_ptrtype);
5917   }
5918   return false;
5919 }
5920 
5921 const Type *TypeNarrowPtr::xdual() const {    // Compute dual right now.
5922   const TypePtr* odual = _ptrtype->dual()->is_ptr();
5923   return make_same_narrowptr(odual);
5924 }
5925 
5926 
5927 const Type *TypeNarrowPtr::filter_helper(const Type *kills, bool include_speculative) const {
5928   if (isa_same_narrowptr(kills)) {
5929     const Type* ft =_ptrtype->filter_helper(is_same_narrowptr(kills)->_ptrtype, include_speculative);
5930     if (ft->empty())
5931       return Type::TOP;           // Canonical empty value
5932     if (ft->isa_ptr()) {
5933       return make_hash_same_narrowptr(ft->isa_ptr());
5934     }
5935     return ft;
5936   } else if (kills->isa_ptr()) {
5937     const Type* ft = _ptrtype->join_helper(kills, include_speculative);
5938     if (ft->empty())
5939       return Type::TOP;           // Canonical empty value
5940     return ft;
5941   } else {
5942     return Type::TOP;
5943   }
5944 }
5945 
5946 //------------------------------xmeet------------------------------------------
5947 // Compute the MEET of two types.  It returns a new Type object.
5948 const Type *TypeNarrowPtr::xmeet( const Type *t ) const {
5949   // Perform a fast test for common case; meeting the same types together.
5950   if( this == t ) return this;  // Meeting same type-rep?
5951 
5952   if (t->base() == base()) {
5953     const Type* result = _ptrtype->xmeet(t->make_ptr());
5954     if (result->isa_ptr()) {
5955       return make_hash_same_narrowptr(result->is_ptr());
5956     }
5957     return result;
5958   }
5959 
5960   // Current "this->_base" is NarrowKlass or NarrowOop
5961   switch (t->base()) {          // switch on original type
5962 
5963   case Int:                     // Mixing ints & oops happens when javac
5964   case Long:                    // reuses local variables
5965   case HalfFloatTop:
5966   case HalfFloatCon:
5967   case HalfFloatBot:
5968   case FloatTop:
5969   case FloatCon:
5970   case FloatBot:
5971   case DoubleTop:
5972   case DoubleCon:
5973   case DoubleBot:
5974   case AnyPtr:
5975   case RawPtr:
5976   case OopPtr:
5977   case InstPtr:
5978   case AryPtr:
5979   case MetadataPtr:
5980   case KlassPtr:
5981   case InstKlassPtr:
5982   case AryKlassPtr:
5983   case NarrowOop:
5984   case NarrowKlass:
5985   case Bottom:                  // Ye Olde Default
5986     return Type::BOTTOM;
5987   case Top:
5988     return this;
5989 
5990   default:                      // All else is a mistake
5991     typerr(t);
5992 
5993   } // End of switch
5994 
5995   return this;
5996 }
5997 
5998 #ifndef PRODUCT
5999 void TypeNarrowPtr::dump2( Dict & d, uint depth, outputStream *st ) const {
6000   _ptrtype->dump2(d, depth, st);
6001 }
6002 #endif
6003 
6004 const TypeNarrowOop *TypeNarrowOop::BOTTOM;
6005 const TypeNarrowOop *TypeNarrowOop::NULL_PTR;
6006 
6007 
6008 const TypeNarrowOop* TypeNarrowOop::make(const TypePtr* type) {
6009   return (const TypeNarrowOop*)(new TypeNarrowOop(type))->hashcons();
6010 }
6011 
6012 const TypeNarrowOop* TypeNarrowOop::remove_speculative() const {
6013   return make(_ptrtype->remove_speculative()->is_ptr());
6014 }
6015 
6016 const Type* TypeNarrowOop::cleanup_speculative() const {
6017   return make(_ptrtype->cleanup_speculative()->is_ptr());
6018 }
6019 
6020 #ifndef PRODUCT
6021 void TypeNarrowOop::dump2( Dict & d, uint depth, outputStream *st ) const {
6022   st->print("narrowoop: ");
6023   TypeNarrowPtr::dump2(d, depth, st);
6024 }
6025 #endif
6026 
6027 const TypeNarrowKlass *TypeNarrowKlass::NULL_PTR;
6028 
6029 const TypeNarrowKlass* TypeNarrowKlass::make(const TypePtr* type) {
6030   return (const TypeNarrowKlass*)(new TypeNarrowKlass(type))->hashcons();
6031 }
6032 
6033 #ifndef PRODUCT
6034 void TypeNarrowKlass::dump2( Dict & d, uint depth, outputStream *st ) const {
6035   st->print("narrowklass: ");
6036   TypeNarrowPtr::dump2(d, depth, st);
6037 }
6038 #endif
6039 
6040 
6041 //------------------------------eq---------------------------------------------
6042 // Structural equality check for Type representations
6043 bool TypeMetadataPtr::eq( const Type *t ) const {
6044   const TypeMetadataPtr *a = (const TypeMetadataPtr*)t;
6045   ciMetadata* one = metadata();
6046   ciMetadata* two = a->metadata();
6047   if (one == nullptr || two == nullptr) {
6048     return (one == two) && TypePtr::eq(t);
6049   } else {
6050     return one->equals(two) && TypePtr::eq(t);
6051   }
6052 }
6053 
6054 //------------------------------hash-------------------------------------------
6055 // Type-specific hashing function.
6056 uint TypeMetadataPtr::hash(void) const {
6057   return
6058     (metadata() ? metadata()->hash() : 0) +
6059     TypePtr::hash();
6060 }
6061 
6062 //------------------------------singleton--------------------------------------
6063 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
6064 // constants
6065 bool TypeMetadataPtr::singleton(void) const {
6066   // detune optimizer to not generate constant metadata + constant offset as a constant!
6067   // TopPTR, Null, AnyNull, Constant are all singletons
6068   return (offset() == 0) && !below_centerline(_ptr);
6069 }
6070 
6071 //------------------------------add_offset-------------------------------------
6072 const TypePtr* TypeMetadataPtr::add_offset( intptr_t offset ) const {
6073   return make( _ptr, _metadata, xadd_offset(offset));
6074 }
6075 
6076 //-----------------------------filter------------------------------------------
6077 // Do not allow interface-vs.-noninterface joins to collapse to top.
6078 const Type *TypeMetadataPtr::filter_helper(const Type *kills, bool include_speculative) const {
6079   const TypeMetadataPtr* ft = join_helper(kills, include_speculative)->isa_metadataptr();
6080   if (ft == nullptr || ft->empty())
6081     return Type::TOP;           // Canonical empty value
6082   return ft;
6083 }
6084 
6085  //------------------------------get_con----------------------------------------
6086 intptr_t TypeMetadataPtr::get_con() const {
6087   assert( _ptr == Null || _ptr == Constant, "" );
6088   assert(offset() >= 0, "");
6089 
6090   if (offset() != 0) {
6091     // After being ported to the compiler interface, the compiler no longer
6092     // directly manipulates the addresses of oops.  Rather, it only has a pointer
6093     // to a handle at compile time.  This handle is embedded in the generated
6094     // code and dereferenced at the time the nmethod is made.  Until that time,
6095     // it is not reasonable to do arithmetic with the addresses of oops (we don't
6096     // have access to the addresses!).  This does not seem to currently happen,
6097     // but this assertion here is to help prevent its occurrence.
6098     tty->print_cr("Found oop constant with non-zero offset");
6099     ShouldNotReachHere();
6100   }
6101 
6102   return (intptr_t)metadata()->constant_encoding();
6103 }
6104 
6105 //------------------------------cast_to_ptr_type-------------------------------
6106 const TypeMetadataPtr* TypeMetadataPtr::cast_to_ptr_type(PTR ptr) const {
6107   if( ptr == _ptr ) return this;
6108   return make(ptr, metadata(), _offset);
6109 }
6110 
6111 //------------------------------meet-------------------------------------------
6112 // Compute the MEET of two types.  It returns a new Type object.
6113 const Type *TypeMetadataPtr::xmeet( const Type *t ) const {
6114   // Perform a fast test for common case; meeting the same types together.
6115   if( this == t ) return this;  // Meeting same type-rep?
6116 
6117   // Current "this->_base" is OopPtr
6118   switch (t->base()) {          // switch on original type
6119 
6120   case Int:                     // Mixing ints & oops happens when javac
6121   case Long:                    // reuses local variables
6122   case HalfFloatTop:
6123   case HalfFloatCon:
6124   case HalfFloatBot:
6125   case FloatTop:
6126   case FloatCon:
6127   case FloatBot:
6128   case DoubleTop:
6129   case DoubleCon:
6130   case DoubleBot:
6131   case NarrowOop:
6132   case NarrowKlass:
6133   case Bottom:                  // Ye Olde Default
6134     return Type::BOTTOM;
6135   case Top:
6136     return this;
6137 
6138   default:                      // All else is a mistake
6139     typerr(t);
6140 
6141   case AnyPtr: {
6142     // Found an AnyPtr type vs self-OopPtr type
6143     const TypePtr *tp = t->is_ptr();
6144     Offset offset = meet_offset(tp->offset());
6145     PTR ptr = meet_ptr(tp->ptr());
6146     switch (tp->ptr()) {
6147     case Null:
6148       if (ptr == Null)  return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
6149       // else fall through:
6150     case TopPTR:
6151     case AnyNull: {
6152       return make(ptr, _metadata, offset);
6153     }
6154     case BotPTR:
6155     case NotNull:
6156       return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
6157     default: typerr(t);
6158     }
6159   }
6160 
6161   case RawPtr:
6162   case KlassPtr:
6163   case InstKlassPtr:
6164   case AryKlassPtr:
6165   case OopPtr:
6166   case InstPtr:
6167   case AryPtr:
6168     return TypePtr::BOTTOM;     // Oop meet raw is not well defined
6169 
6170   case MetadataPtr: {
6171     const TypeMetadataPtr *tp = t->is_metadataptr();
6172     Offset offset = meet_offset(tp->offset());
6173     PTR tptr = tp->ptr();
6174     PTR ptr = meet_ptr(tptr);
6175     ciMetadata* md = (tptr == TopPTR) ? metadata() : tp->metadata();
6176     if (tptr == TopPTR || _ptr == TopPTR ||
6177         metadata()->equals(tp->metadata())) {
6178       return make(ptr, md, offset);
6179     }
6180     // metadata is different
6181     if( ptr == Constant ) {  // Cannot be equal constants, so...
6182       if( tptr == Constant && _ptr != Constant)  return t;
6183       if( _ptr == Constant && tptr != Constant)  return this;
6184       ptr = NotNull;            // Fall down in lattice
6185     }
6186     return make(ptr, nullptr, offset);
6187     break;
6188   }
6189   } // End of switch
6190   return this;                  // Return the double constant
6191 }
6192 
6193 
6194 //------------------------------xdual------------------------------------------
6195 // Dual of a pure metadata pointer.
6196 const Type *TypeMetadataPtr::xdual() const {
6197   return new TypeMetadataPtr(dual_ptr(), metadata(), dual_offset());
6198 }
6199 
6200 //------------------------------dump2------------------------------------------
6201 #ifndef PRODUCT
6202 void TypeMetadataPtr::dump2( Dict &d, uint depth, outputStream *st ) const {
6203   st->print("metadataptr:%s", ptr_msg[_ptr]);
6204   if (metadata() != nullptr) {
6205     st->print(":" INTPTR_FORMAT, p2i(metadata()));
6206   }
6207   dump_offset(st);
6208 }
6209 #endif
6210 
6211 
6212 //=============================================================================
6213 // Convenience common pre-built type.
6214 const TypeMetadataPtr *TypeMetadataPtr::BOTTOM;
6215 
6216 TypeMetadataPtr::TypeMetadataPtr(PTR ptr, ciMetadata* metadata, Offset offset):
6217   TypePtr(MetadataPtr, ptr, offset, relocInfo::metadata_type), _metadata(metadata) {
6218 }
6219 
6220 const TypeMetadataPtr* TypeMetadataPtr::make(ciMethod* m) {
6221   return make(Constant, m, Offset(0));
6222 }
6223 const TypeMetadataPtr* TypeMetadataPtr::make(ciMethodData* m) {
6224   return make(Constant, m, Offset(0));
6225 }
6226 
6227 //------------------------------make-------------------------------------------
6228 // Create a meta data constant
6229 const TypeMetadataPtr* TypeMetadataPtr::make(PTR ptr, ciMetadata* m, Offset offset) {
6230   assert(m == nullptr || !m->is_klass(), "wrong type");
6231   return (TypeMetadataPtr*)(new TypeMetadataPtr(ptr, m, offset))->hashcons();
6232 }
6233 
6234 
6235 const TypeKlassPtr* TypeAryPtr::as_klass_type(bool try_for_exact) const {
6236   const Type* elem = _ary->_elem;
6237   bool xk = klass_is_exact();
6238   bool is_refined = false;
6239   if (elem->make_oopptr() != nullptr) {
6240     is_refined = true;
6241     elem = elem->make_oopptr()->as_klass_type(try_for_exact);
6242     if (elem->isa_aryklassptr()) {
6243       const TypeAryKlassPtr* elem_klass = elem->is_aryklassptr();
6244       if (elem_klass->is_refined_type()) {
6245         elem = elem_klass->cast_to_non_refined();
6246       }
6247     } else {
6248       const TypeInstKlassPtr* elem_klass = elem->is_instklassptr();
6249       if (try_for_exact && !xk && elem_klass->klass_is_exact() &&
6250           !elem_klass->exact_klass()->as_instance_klass()->can_be_inline_klass()) {
6251         xk = true;
6252       }
6253     }
6254   }
6255   return TypeAryKlassPtr::make(xk ? TypePtr::Constant : TypePtr::NotNull, elem, klass(), Offset(0), is_not_flat(), is_not_null_free(), is_flat(), is_null_free(), is_atomic(), is_refined);
6256 }
6257 
6258 const TypeKlassPtr* TypeKlassPtr::make(ciKlass* klass, InterfaceHandling interface_handling) {
6259   if (klass->is_instance_klass()) {
6260     return TypeInstKlassPtr::make(klass, interface_handling);
6261   }
6262   return TypeAryKlassPtr::make(klass, interface_handling);
6263 }
6264 
6265 TypeKlassPtr::TypeKlassPtr(TYPES t, PTR ptr, ciKlass* klass, const TypeInterfaces* interfaces, Offset offset)
6266   : TypePtr(t, ptr, offset, relocInfo::metadata_type), _klass(klass), _interfaces(interfaces) {
6267   assert(klass == nullptr || !klass->is_loaded() || (klass->is_instance_klass() && !klass->is_interface()) ||
6268          klass->is_type_array_klass() || klass->is_flat_array_klass() || !klass->as_obj_array_klass()->base_element_klass()->is_interface(), "no interface here");
6269 }
6270 
6271 // Is there a single ciKlass* that can represent that type?
6272 ciKlass* TypeKlassPtr::exact_klass_helper() const {
6273   assert(_klass->is_instance_klass() && !_klass->is_interface(), "No interface");
6274   if (_interfaces->empty()) {
6275     return _klass;
6276   }
6277   if (_klass != ciEnv::current()->Object_klass()) {
6278     if (_interfaces->eq(_klass->as_instance_klass())) {
6279       return _klass;
6280     }
6281     return nullptr;
6282   }
6283   return _interfaces->exact_klass();
6284 }
6285 
6286 //------------------------------eq---------------------------------------------
6287 // Structural equality check for Type representations
6288 bool TypeKlassPtr::eq(const Type *t) const {
6289   const TypeKlassPtr *p = t->is_klassptr();
6290   return
6291     _interfaces->eq(p->_interfaces) &&
6292     TypePtr::eq(p);
6293 }
6294 
6295 //------------------------------hash-------------------------------------------
6296 // Type-specific hashing function.
6297 uint TypeKlassPtr::hash(void) const {
6298   return TypePtr::hash() + _interfaces->hash();
6299 }
6300 
6301 //------------------------------singleton--------------------------------------
6302 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
6303 // constants
6304 bool TypeKlassPtr::singleton(void) const {
6305   // detune optimizer to not generate constant klass + constant offset as a constant!
6306   // TopPTR, Null, AnyNull, Constant are all singletons
6307   return (offset() == 0) && !below_centerline(_ptr);
6308 }
6309 
6310 // Do not allow interface-vs.-noninterface joins to collapse to top.
6311 const Type *TypeKlassPtr::filter_helper(const Type *kills, bool include_speculative) const {
6312   // logic here mirrors the one from TypeOopPtr::filter. See comments
6313   // there.
6314   const Type* ft = join_helper(kills, include_speculative);
6315 
6316   if (ft->empty()) {
6317     return Type::TOP;           // Canonical empty value
6318   }
6319 
6320   return ft;
6321 }
6322 
6323 const TypeInterfaces* TypeKlassPtr::meet_interfaces(const TypeKlassPtr* other) const {
6324   if (above_centerline(_ptr) && above_centerline(other->_ptr)) {
6325     return _interfaces->union_with(other->_interfaces);
6326   } else if (above_centerline(_ptr) && !above_centerline(other->_ptr)) {
6327     return other->_interfaces;
6328   } else if (above_centerline(other->_ptr) && !above_centerline(_ptr)) {
6329     return _interfaces;
6330   }
6331   return _interfaces->intersection_with(other->_interfaces);
6332 }
6333 
6334 //------------------------------get_con----------------------------------------
6335 intptr_t TypeKlassPtr::get_con() const {
6336   assert( _ptr == Null || _ptr == Constant, "" );
6337   assert( offset() >= 0, "" );
6338 
6339   if (offset() != 0) {
6340     // After being ported to the compiler interface, the compiler no longer
6341     // directly manipulates the addresses of oops.  Rather, it only has a pointer
6342     // to a handle at compile time.  This handle is embedded in the generated
6343     // code and dereferenced at the time the nmethod is made.  Until that time,
6344     // it is not reasonable to do arithmetic with the addresses of oops (we don't
6345     // have access to the addresses!).  This does not seem to currently happen,
6346     // but this assertion here is to help prevent its occurrence.
6347     tty->print_cr("Found oop constant with non-zero offset");
6348     ShouldNotReachHere();
6349   }
6350 
6351   ciKlass* k = exact_klass();
6352 
6353   return (intptr_t)k->constant_encoding();
6354 }
6355 
6356 //=============================================================================
6357 // Convenience common pre-built types.
6358 
6359 // Not-null object klass or below
6360 const TypeInstKlassPtr *TypeInstKlassPtr::OBJECT;
6361 const TypeInstKlassPtr *TypeInstKlassPtr::OBJECT_OR_NULL;
6362 
6363 bool TypeInstKlassPtr::eq(const Type *t) const {
6364   const TypeInstKlassPtr* p = t->is_instklassptr();
6365   return
6366     klass()->equals(p->klass()) &&
6367     _flat_in_array == p->_flat_in_array &&
6368     TypeKlassPtr::eq(p);
6369 }
6370 
6371 uint TypeInstKlassPtr::hash() const {
6372   return klass()->hash() + TypeKlassPtr::hash() + static_cast<uint>(_flat_in_array);
6373 }
6374 
6375 const TypeInstKlassPtr *TypeInstKlassPtr::make(PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, Offset offset, FlatInArray flat_in_array) {
6376   if (flat_in_array == Uninitialized) {
6377     flat_in_array = compute_flat_in_array(k->as_instance_klass(), ptr == Constant);
6378   }
6379   TypeInstKlassPtr *r =
6380     (TypeInstKlassPtr*)(new TypeInstKlassPtr(ptr, k, interfaces, offset, flat_in_array))->hashcons();
6381 
6382   return r;
6383 }
6384 
6385 bool TypeInstKlassPtr::empty() const {
6386   if (_flat_in_array == TopFlat) {
6387     return true;
6388   }
6389   return TypeKlassPtr::empty();
6390 }
6391 
6392 //------------------------------add_offset-------------------------------------
6393 // Access internals of klass object
6394 const TypePtr *TypeInstKlassPtr::add_offset( intptr_t offset ) const {
6395   return make(_ptr, klass(), _interfaces, xadd_offset(offset), _flat_in_array);
6396 }
6397 
6398 const TypeInstKlassPtr* TypeInstKlassPtr::with_offset(intptr_t offset) const {
6399   return make(_ptr, klass(), _interfaces, Offset(offset), _flat_in_array);
6400 }
6401 
6402 //------------------------------cast_to_ptr_type-------------------------------
6403 const TypeInstKlassPtr* TypeInstKlassPtr::cast_to_ptr_type(PTR ptr) const {
6404   assert(_base == InstKlassPtr, "subclass must override cast_to_ptr_type");
6405   if( ptr == _ptr ) return this;
6406   return make(ptr, _klass, _interfaces, _offset, _flat_in_array);
6407 }
6408 
6409 
6410 bool TypeInstKlassPtr::must_be_exact() const {
6411   if (!_klass->is_loaded())  return false;
6412   ciInstanceKlass* ik = _klass->as_instance_klass();
6413   if (ik->is_final())  return true;  // cannot clear xk
6414   return false;
6415 }
6416 
6417 //-----------------------------cast_to_exactness-------------------------------
6418 const TypeInstKlassPtr* TypeInstKlassPtr::cast_to_exactness(bool klass_is_exact) const {
6419   if (klass_is_exact == (_ptr == Constant)) return this;
6420   if (must_be_exact()) return this;
6421   ciKlass* k = klass();
6422   FlatInArray flat_in_array = compute_flat_in_array(k->as_instance_klass(), klass_is_exact);
6423   return make(klass_is_exact ? Constant : NotNull, k, _interfaces, _offset, flat_in_array);
6424 }
6425 
6426 
6427 //-----------------------------as_instance_type--------------------------------
6428 // Corresponding type for an instance of the given class.
6429 // It will be NotNull, and exact if and only if the klass type is exact.
6430 const TypeInstPtr* TypeInstKlassPtr::as_exact_instance_type(bool klass_change) const {
6431   ciKlass* k = klass();
6432   bool xk = klass_is_exact();
6433   Compile* C = Compile::current();
6434   Dependencies* deps = C->dependencies();
6435   assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity");
6436   // Element is an instance
6437   bool klass_is_exact = false;
6438   const TypeInterfaces* interfaces = _interfaces;
6439   ciInstanceKlass* ik = k->as_instance_klass();
6440   if (k->is_loaded()) {
6441     // Try to set klass_is_exact.
6442     klass_is_exact = ik->is_final();
6443     if (!klass_is_exact && klass_change
6444         && deps != nullptr && UseUniqueSubclasses) {
6445       ciInstanceKlass* sub = ik->unique_concrete_subklass();
6446       if (sub != nullptr) {
6447         if (_interfaces->eq(sub)) {
6448           deps->assert_abstract_with_unique_concrete_subtype(ik, sub);
6449           k = ik = sub;
6450           xk = sub->is_final();
6451         }
6452       }
6453     }
6454   }
6455 
6456   FlatInArray flat_in_array = compute_flat_in_array_if_unknown(ik, xk, _flat_in_array);
6457   return TypeInstPtr::make(TypePtr::BotPTR, k, interfaces, xk, nullptr, Offset(0), flat_in_array);
6458 }
6459 
6460 const TypeInstPtr* TypeInstKlassPtr::as_subtype_instance_type(bool klass_change) const {
6461   return cast_to_exactness(false)->as_exact_instance_type(klass_change);
6462 }
6463 
6464 //------------------------------xmeet------------------------------------------
6465 // Compute the MEET of two types, return a new Type object.
6466 const Type    *TypeInstKlassPtr::xmeet( const Type *t ) const {
6467   // Perform a fast test for common case; meeting the same types together.
6468   if( this == t ) return this;  // Meeting same type-rep?
6469 
6470   // Current "this->_base" is Pointer
6471   switch (t->base()) {          // switch on original type
6472 
6473   case Int:                     // Mixing ints & oops happens when javac
6474   case Long:                    // reuses local variables
6475   case HalfFloatTop:
6476   case HalfFloatCon:
6477   case HalfFloatBot:
6478   case FloatTop:
6479   case FloatCon:
6480   case FloatBot:
6481   case DoubleTop:
6482   case DoubleCon:
6483   case DoubleBot:
6484   case NarrowOop:
6485   case NarrowKlass:
6486   case Bottom:                  // Ye Olde Default
6487     return Type::BOTTOM;
6488   case Top:
6489     return this;
6490 
6491   default:                      // All else is a mistake
6492     typerr(t);
6493 
6494   case AnyPtr: {                // Meeting to AnyPtrs
6495     // Found an AnyPtr type vs self-KlassPtr type
6496     const TypePtr *tp = t->is_ptr();
6497     Offset offset = meet_offset(tp->offset());
6498     PTR ptr = meet_ptr(tp->ptr());
6499     switch (tp->ptr()) {
6500     case TopPTR:
6501       return this;
6502     case Null:
6503       if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
6504     case AnyNull:
6505       return make(ptr, klass(), _interfaces, offset, _flat_in_array);
6506     case BotPTR:
6507     case NotNull:
6508       return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
6509     default: typerr(t);
6510     }
6511   }
6512 
6513   case RawPtr:
6514   case MetadataPtr:
6515   case OopPtr:
6516   case AryPtr:                  // Meet with AryPtr
6517   case InstPtr:                 // Meet with InstPtr
6518       return TypePtr::BOTTOM;
6519 
6520   //
6521   //             A-top         }
6522   //           /   |   \       }  Tops
6523   //       B-top A-any C-top   }
6524   //          | /  |  \ |      }  Any-nulls
6525   //       B-any   |   C-any   }
6526   //          |    |    |
6527   //       B-con A-con C-con   } constants; not comparable across classes
6528   //          |    |    |
6529   //       B-not   |   C-not   }
6530   //          | \  |  / |      }  not-nulls
6531   //       B-bot A-not C-bot   }
6532   //           \   |   /       }  Bottoms
6533   //             A-bot         }
6534   //
6535 
6536   case InstKlassPtr: {  // Meet two KlassPtr types
6537     const TypeInstKlassPtr *tkls = t->is_instklassptr();
6538     Offset  off     = meet_offset(tkls->offset());
6539     PTR  ptr     = meet_ptr(tkls->ptr());
6540     const TypeInterfaces* interfaces = meet_interfaces(tkls);
6541 
6542     ciKlass* res_klass = nullptr;
6543     bool res_xk = false;
6544     const FlatInArray flat_in_array = meet_flat_in_array(_flat_in_array, tkls->flat_in_array());
6545     switch (meet_instptr(ptr, interfaces, this, tkls, res_klass, res_xk)) {
6546       case UNLOADED:
6547         ShouldNotReachHere();
6548       case SUBTYPE:
6549       case NOT_SUBTYPE:
6550       case LCA:
6551       case QUICK: {
6552         assert(res_xk == (ptr == Constant), "");
6553         const Type* res = make(ptr, res_klass, interfaces, off, flat_in_array);
6554         return res;
6555       }
6556       default:
6557         ShouldNotReachHere();
6558     }
6559   } // End of case KlassPtr
6560   case AryKlassPtr: {                // All arrays inherit from Object class
6561     const TypeAryKlassPtr *tp = t->is_aryklassptr();
6562     Offset offset = meet_offset(tp->offset());
6563     PTR ptr = meet_ptr(tp->ptr());
6564     const TypeInterfaces* interfaces = meet_interfaces(tp);
6565     const TypeInterfaces* tp_interfaces = tp->_interfaces;
6566     const TypeInterfaces* this_interfaces = _interfaces;
6567 
6568     switch (ptr) {
6569     case TopPTR:
6570     case AnyNull:                // Fall 'down' to dual of object klass
6571       // For instances when a subclass meets a superclass we fall
6572       // below the centerline when the superclass is exact. We need to
6573       // do the same here.
6574       //
6575       // Flat in array: See explanation for meet with TypeInstPtr in TypeAryPtr::xmeet_helper().
6576       if (klass()->equals(ciEnv::current()->Object_klass()) && tp_interfaces->contains(this_interfaces) &&
6577           !klass_is_exact() && !is_not_flat_in_array()) {
6578         return TypeAryKlassPtr::make(ptr, tp->elem(), tp->klass(), offset, tp->is_not_flat(), tp->is_not_null_free(), tp->is_flat(), tp->is_null_free(), tp->is_atomic(), tp->is_refined_type());
6579       } else {
6580         // cannot subclass, so the meet has to fall badly below the centerline
6581         ptr = NotNull;
6582         interfaces = _interfaces->intersection_with(tp->_interfaces);
6583         FlatInArray flat_in_array = meet_flat_in_array(_flat_in_array, NotFlat);
6584         return make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, flat_in_array);
6585       }
6586     case Constant:
6587     case NotNull:
6588     case BotPTR: { // Fall down to object klass
6589       // LCA is object_klass, but if we subclass from the top we can do better
6590       if( above_centerline(_ptr) ) { // if( _ptr == TopPTR || _ptr == AnyNull )
6591         // If 'this' (InstPtr) is above the centerline and it is Object class
6592         // then we can subclass in the Java class hierarchy.
6593         // For instances when a subclass meets a superclass we fall
6594         // below the centerline when the superclass is exact. We need
6595         // to do the same here.
6596         //
6597         // Flat in array: See explanation for meet with TypeInstPtr in TypeAryPtr::xmeet_helper().
6598         if (klass()->equals(ciEnv::current()->Object_klass()) && tp_interfaces->contains(this_interfaces) &&
6599             !klass_is_exact() && !is_not_flat_in_array()) {
6600           // that is, tp's array type is a subtype of my klass
6601           return TypeAryKlassPtr::make(ptr, tp->elem(), tp->klass(), offset, tp->is_not_flat(), tp->is_not_null_free(), tp->is_flat(), tp->is_null_free(), tp->is_atomic(), tp->is_refined_type());
6602         }
6603       }
6604       // The other case cannot happen, since I cannot be a subtype of an array.
6605       // The meet falls down to Object class below centerline.
6606       if( ptr == Constant )
6607         ptr = NotNull;
6608       interfaces = this_interfaces->intersection_with(tp_interfaces);
6609       FlatInArray flat_in_array = meet_flat_in_array(_flat_in_array, NotFlat);
6610       return make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, flat_in_array);
6611     }
6612     default: typerr(t);
6613     }
6614   }
6615 
6616   } // End of switch
6617   return this;                  // Return the double constant
6618 }
6619 
6620 //------------------------------xdual------------------------------------------
6621 // Dual: compute field-by-field dual
6622 const Type* TypeInstKlassPtr::xdual() const {
6623   return new TypeInstKlassPtr(dual_ptr(), klass(), _interfaces, dual_offset(), dual_flat_in_array());
6624 }
6625 
6626 template <class T1, class T2> bool TypePtr::is_java_subtype_of_helper_for_instance(const T1* this_one, const T2* other, bool this_exact, bool other_exact) {
6627   static_assert(std::is_base_of<T2, T1>::value, "");
6628   if (!this_one->is_loaded() || !other->is_loaded()) {
6629     return false;
6630   }
6631   if (!this_one->is_instance_type(other)) {
6632     return false;
6633   }
6634 
6635   if (!other_exact) {
6636     return false;
6637   }
6638 
6639   if (other->klass()->equals(ciEnv::current()->Object_klass()) && other->_interfaces->empty()) {
6640     return true;
6641   }
6642 
6643   return this_one->klass()->is_subtype_of(other->klass()) && this_one->_interfaces->contains(other->_interfaces);
6644 }
6645 
6646 bool TypeInstKlassPtr::might_be_an_array() const {
6647   if (!instance_klass()->is_java_lang_Object()) {
6648     // TypeInstKlassPtr can be an array only if it is java.lang.Object: the only supertype of array types.
6649     return false;
6650   }
6651   if (interfaces()->has_non_array_interface()) {
6652     // Arrays only implement Cloneable and Serializable. If we see any other interface, [this] cannot be an array.
6653     return false;
6654   }
6655   // Cannot prove it's not an array.
6656   return true;
6657 }
6658 
6659 bool TypeInstKlassPtr::is_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const {
6660   return TypePtr::is_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact);
6661 }
6662 
6663 template <class T1, class T2> bool TypePtr::is_same_java_type_as_helper_for_instance(const T1* this_one, const T2* other) {
6664   static_assert(std::is_base_of<T2, T1>::value, "");
6665   if (!this_one->is_loaded() || !other->is_loaded()) {
6666     return false;
6667   }
6668   if (!this_one->is_instance_type(other)) {
6669     return false;
6670   }
6671   return this_one->klass()->equals(other->klass()) && this_one->_interfaces->eq(other->_interfaces);
6672 }
6673 
6674 bool TypeInstKlassPtr::is_same_java_type_as_helper(const TypeKlassPtr* other) const {
6675   return TypePtr::is_same_java_type_as_helper_for_instance(this, other);
6676 }
6677 
6678 template <class T1, class T2> bool TypePtr::maybe_java_subtype_of_helper_for_instance(const T1* this_one, const T2* other, bool this_exact, bool other_exact) {
6679   static_assert(std::is_base_of<T2, T1>::value, "");
6680   if (!this_one->is_loaded() || !other->is_loaded()) {
6681     return true;
6682   }
6683 
6684   if (this_one->is_array_type(other)) {
6685     return !this_exact && this_one->klass()->equals(ciEnv::current()->Object_klass())  && other->_interfaces->contains(this_one->_interfaces);
6686   }
6687 
6688   assert(this_one->is_instance_type(other), "unsupported");
6689 
6690   if (this_exact && other_exact) {
6691     return this_one->is_java_subtype_of(other);
6692   }
6693 
6694   if (!this_one->klass()->is_subtype_of(other->klass()) && !other->klass()->is_subtype_of(this_one->klass())) {
6695     return false;
6696   }
6697 
6698   if (this_exact) {
6699     return this_one->klass()->is_subtype_of(other->klass()) && this_one->_interfaces->contains(other->_interfaces);
6700   }
6701 
6702   return true;
6703 }
6704 
6705 bool TypeInstKlassPtr::maybe_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const {
6706   return TypePtr::maybe_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact);
6707 }
6708 
6709 const TypeKlassPtr* TypeInstKlassPtr::try_improve() const {
6710   if (!UseUniqueSubclasses) {
6711     return this;
6712   }
6713   ciKlass* k = klass();
6714   Compile* C = Compile::current();
6715   Dependencies* deps = C->dependencies();
6716   assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity");
6717   if (k->is_loaded()) {
6718     ciInstanceKlass* ik = k->as_instance_klass();
6719     if (deps != nullptr) {
6720       ciInstanceKlass* sub = ik->unique_concrete_subklass();
6721       if (sub != nullptr) {
6722         bool improve_to_exact = sub->is_final() && _ptr == NotNull;
6723         const TypeInstKlassPtr* improved = TypeInstKlassPtr::make(improve_to_exact ? Constant : _ptr, sub, _offset);
6724         if (_interfaces->is_subset(sub)) {
6725           deps->assert_abstract_with_unique_concrete_subtype(ik, sub);
6726           return improved;
6727         }
6728       }
6729     }
6730   }
6731   return this;
6732 }
6733 
6734 bool TypeInstKlassPtr::can_be_inline_array() const {
6735   return _klass->equals(ciEnv::current()->Object_klass()) && TypeAryKlassPtr::_array_interfaces->contains(_interfaces);
6736 }
6737 
6738 #ifndef PRODUCT
6739 void TypeInstKlassPtr::dump2(Dict& d, uint depth, outputStream* st) const {
6740   st->print("instklassptr:");
6741   klass()->print_name_on(st);
6742   _interfaces->dump(st);
6743   st->print(":%s", ptr_msg[_ptr]);
6744   dump_offset(st);
6745   dump_flat_in_array(_flat_in_array, st);
6746 }
6747 #endif // PRODUCT
6748 
6749 bool TypeAryKlassPtr::can_be_inline_array() const {
6750   return _elem->isa_instklassptr() && _elem->is_instklassptr()->_klass->can_be_inline_klass();
6751 }
6752 
6753 bool TypeInstPtr::can_be_inline_array() const {
6754   return _klass->equals(ciEnv::current()->Object_klass()) && TypeAryPtr::_array_interfaces->contains(_interfaces);
6755 }
6756 
6757 bool TypeAryPtr::can_be_inline_array() const {
6758   return elem()->make_ptr() && elem()->make_ptr()->isa_instptr() && elem()->make_ptr()->is_instptr()->_klass->can_be_inline_klass();
6759 }
6760 
6761 const TypeAryKlassPtr *TypeAryKlassPtr::make(PTR ptr, const Type* elem, ciKlass* k, Offset offset, bool not_flat, bool not_null_free, bool flat, bool null_free, bool atomic, bool refined_type) {
6762   return (TypeAryKlassPtr*)(new TypeAryKlassPtr(ptr, elem, k, offset, not_flat, not_null_free, flat, null_free, atomic, refined_type))->hashcons();
6763 }
6764 
6765 const TypeAryKlassPtr* TypeAryKlassPtr::make(PTR ptr, ciKlass* k, Offset offset, InterfaceHandling interface_handling, bool not_flat, bool not_null_free, bool flat, bool null_free, bool atomic, bool refined_type) {
6766   const Type* etype;
6767   if (k->is_obj_array_klass()) {
6768     // Element is an object array. Recursively call ourself.
6769     ciKlass* eklass = k->as_obj_array_klass()->element_klass();
6770     etype = TypeKlassPtr::make(eklass, interface_handling)->cast_to_exactness(false);
6771     k = nullptr;
6772   } else if (k->is_type_array_klass()) {
6773     // Element is an typeArray
6774     etype = get_const_basic_type(k->as_type_array_klass()->element_type());
6775   } else {
6776     ShouldNotReachHere();
6777   }
6778 
6779   return TypeAryKlassPtr::make(ptr, etype, k, offset, not_flat, not_null_free, flat, null_free, atomic, refined_type);
6780 }
6781 
6782 const TypeAryKlassPtr* TypeAryKlassPtr::make(ciKlass* klass, InterfaceHandling interface_handling) {
6783   ciArrayKlass* k = klass->as_array_klass();
6784   if (k->is_refined()) {
6785     return TypeAryKlassPtr::make(Constant, k, Offset(0), interface_handling, !k->is_flat_array_klass(), !k->is_elem_null_free(),
6786                                  k->is_flat_array_klass(), k->is_elem_null_free(), k->is_elem_atomic(), true);
6787   } else {
6788     // Use the default combination to canonicalize all non-refined klass pointers
6789     return TypeAryKlassPtr::make(Constant, k, Offset(0), interface_handling, true, true, false, false, true, false);
6790   }
6791 }
6792 
6793 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_non_refined() const {
6794   assert(is_refined_type(), "must be a refined type");
6795   PTR ptr = _ptr;
6796   // There can be multiple refined array types corresponding to a single unrefined type
6797   if (ptr == NotNull && elem()->is_klassptr()->klass_is_exact()) {
6798     ptr = Constant;
6799   }
6800   return make(ptr, elem(), nullptr, _offset, true, true, false, false, true, false);
6801 }
6802 
6803 // Get the (non-)refined array klass ptr
6804 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_refined_array_klass_ptr(bool refined) const {
6805   if ((refined == is_refined_type()) || !klass_is_exact() || !exact_klass()->is_obj_array_klass()) {
6806     return this;
6807   }
6808   ciArrayKlass* k = exact_klass()->as_array_klass();
6809   k = ciObjArrayKlass::make(k->element_klass(), refined);
6810   return make(k, trust_interfaces);
6811 }
6812 
6813 //------------------------------eq---------------------------------------------
6814 // Structural equality check for Type representations
6815 bool TypeAryKlassPtr::eq(const Type *t) const {
6816   const TypeAryKlassPtr *p = t->is_aryklassptr();
6817   return
6818     _elem == p->_elem &&  // Check array
6819     _flat == p->_flat &&
6820     _not_flat == p->_not_flat &&
6821     _null_free == p->_null_free &&
6822     _not_null_free == p->_not_null_free &&
6823     _atomic == p->_atomic &&
6824     _refined_type == p->_refined_type &&
6825     TypeKlassPtr::eq(p);  // Check sub-parts
6826 }
6827 
6828 //------------------------------hash-------------------------------------------
6829 // Type-specific hashing function.
6830 uint TypeAryKlassPtr::hash(void) const {
6831   return (uint)(uintptr_t)_elem + TypeKlassPtr::hash() + (uint)(_not_flat ? 43 : 0) +
6832       (uint)(_not_null_free ? 44 : 0) + (uint)(_flat ? 45 : 0) + (uint)(_null_free ? 46 : 0)  + (uint)(_atomic ? 47 : 0) + (uint)(_refined_type ? 48 : 0);
6833 }
6834 
6835 //----------------------compute_klass------------------------------------------
6836 // Compute the defining klass for this class
6837 ciKlass* TypeAryPtr::compute_klass() const {
6838   // Compute _klass based on element type.
6839   ciKlass* k_ary = nullptr;
6840   const TypeInstPtr *tinst;
6841   const TypeAryPtr *tary;
6842   const Type* el = elem();
6843   if (el->isa_narrowoop()) {
6844     el = el->make_ptr();
6845   }
6846 
6847   // Get element klass
6848   if ((tinst = el->isa_instptr()) != nullptr) {
6849     // Leave k_ary at nullptr.
6850   } else if ((tary = el->isa_aryptr()) != nullptr) {
6851     // Leave k_ary at nullptr.
6852   } else if ((el->base() == Type::Top) ||
6853              (el->base() == Type::Bottom)) {
6854     // element type of Bottom occurs from meet of basic type
6855     // and object; Top occurs when doing join on Bottom.
6856     // Leave k_ary at null.
6857   } else {
6858     assert(!el->isa_int(), "integral arrays must be pre-equipped with a class");
6859     // Compute array klass directly from basic type
6860     k_ary = ciTypeArrayKlass::make(el->basic_type());
6861   }
6862   return k_ary;
6863 }
6864 
6865 //------------------------------klass------------------------------------------
6866 // Return the defining klass for this class
6867 ciKlass* TypeAryPtr::klass() const {
6868   if( _klass ) return _klass;   // Return cached value, if possible
6869 
6870   // Oops, need to compute _klass and cache it
6871   ciKlass* k_ary = compute_klass();
6872 
6873   if( this != TypeAryPtr::OOPS && this->dual() != TypeAryPtr::OOPS ) {
6874     // The _klass field acts as a cache of the underlying
6875     // ciKlass for this array type.  In order to set the field,
6876     // we need to cast away const-ness.
6877     //
6878     // IMPORTANT NOTE: we *never* set the _klass field for the
6879     // type TypeAryPtr::OOPS.  This Type is shared between all
6880     // active compilations.  However, the ciKlass which represents
6881     // this Type is *not* shared between compilations, so caching
6882     // this value would result in fetching a dangling pointer.
6883     //
6884     // Recomputing the underlying ciKlass for each request is
6885     // a bit less efficient than caching, but calls to
6886     // TypeAryPtr::OOPS->klass() are not common enough to matter.
6887     ((TypeAryPtr*)this)->_klass = k_ary;
6888   }
6889   return k_ary;
6890 }
6891 
6892 // Is there a single ciKlass* that can represent that type?
6893 ciKlass* TypeAryPtr::exact_klass_helper() const {
6894   if (_ary->_elem->make_ptr() && _ary->_elem->make_ptr()->isa_oopptr()) {
6895     ciKlass* k = _ary->_elem->make_ptr()->is_oopptr()->exact_klass_helper();
6896     if (k == nullptr) {
6897       return nullptr;
6898     }
6899     if (k->is_array_klass() && k->as_array_klass()->is_refined()) {
6900       // We have no mechanism to create an array of refined arrays
6901       k = ciObjArrayKlass::make(k->as_array_klass()->element_klass(), false);
6902     }
6903     if (klass_is_exact()) {
6904       return ciObjArrayKlass::make(k, true, is_null_free(), is_atomic());
6905     } else {
6906       // We may reach here if called recursively, must be an unrefined type then
6907       return ciObjArrayKlass::make(k, false);
6908     }
6909   }
6910 
6911   return klass();
6912 }
6913 
6914 const Type* TypeAryPtr::base_element_type(int& dims) const {
6915   const Type* elem = this->elem();
6916   dims = 1;
6917   while (elem->make_ptr() && elem->make_ptr()->isa_aryptr()) {
6918     elem = elem->make_ptr()->is_aryptr()->elem();
6919     dims++;
6920   }
6921   return elem;
6922 }
6923 
6924 //------------------------------add_offset-------------------------------------
6925 // Access internals of klass object
6926 const TypePtr* TypeAryKlassPtr::add_offset(intptr_t offset) const {
6927   return make(_ptr, elem(), klass(), xadd_offset(offset), is_not_flat(), is_not_null_free(), _flat, _null_free, _atomic, _refined_type);
6928 }
6929 
6930 const TypeAryKlassPtr* TypeAryKlassPtr::with_offset(intptr_t offset) const {
6931   return make(_ptr, elem(), klass(), Offset(offset), is_not_flat(), is_not_null_free(), _flat, _null_free, _atomic, _refined_type);
6932 }
6933 
6934 //------------------------------cast_to_ptr_type-------------------------------
6935 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_ptr_type(PTR ptr) const {
6936   assert(_base == AryKlassPtr, "subclass must override cast_to_ptr_type");
6937   if (ptr == _ptr) return this;
6938   return make(ptr, elem(), _klass, _offset, is_not_flat(), is_not_null_free(), _flat, _null_free, _atomic, _refined_type);
6939 }
6940 
6941 bool TypeAryKlassPtr::must_be_exact() const {
6942   assert(klass_is_exact(), "precondition");
6943   if (_elem == Type::BOTTOM || _elem == Type::TOP) {
6944     return false;
6945   }
6946   const TypeKlassPtr* elem = _elem->isa_klassptr();
6947   if (elem == nullptr) {
6948     // primitive arrays
6949     return true;
6950   }
6951 
6952   // refined types are final
6953   return _refined_type;
6954 }
6955 
6956 //-----------------------------cast_to_exactness-------------------------------
6957 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_exactness(bool klass_is_exact) const {
6958   if (klass_is_exact == this->klass_is_exact()) {
6959     return this;
6960   }
6961   if (!klass_is_exact && must_be_exact()) {
6962     return this;
6963   }
6964   const Type* elem = this->elem();
6965   if (elem->isa_klassptr() && !klass_is_exact) {
6966     elem = elem->is_klassptr()->cast_to_exactness(klass_is_exact);
6967   }
6968 
6969   if (klass_is_exact) {
6970     // cast_to_exactness(true) really means get the LCA of all values represented by this
6971     // TypeAryKlassPtr. As a result, it must be an unrefined klass pointer.
6972     return make(Constant, elem, nullptr, _offset, true, true, false, false, true, false);
6973   } else {
6974     // cast_to_exactness(false) means get the TypeAryKlassPtr representing all values that subtype
6975     // this value
6976     bool not_inline = !_elem->isa_instklassptr() || !_elem->is_instklassptr()->instance_klass()->can_be_inline_klass();
6977     bool not_flat = !UseArrayFlattening || not_inline ||
6978                     (_elem->isa_instklassptr() && _elem->is_instklassptr()->instance_klass()->is_inlinetype() && !_elem->is_instklassptr()->instance_klass()->maybe_flat_in_array());
6979     bool not_null_free = not_inline;
6980     bool atomic = not_flat;
6981     return make(NotNull, elem, nullptr, _offset, not_flat, not_null_free, false, false, atomic, false);
6982   }
6983 }
6984 
6985 //-----------------------------as_instance_type--------------------------------
6986 // Corresponding type for an instance of the given class.
6987 // It will be NotNull, and exact if and only if the klass type is exact.
6988 const TypeAryPtr* TypeAryKlassPtr::as_exact_instance_type(bool klass_change) const {
6989   ciKlass* k = klass();
6990   bool    xk = klass_is_exact();
6991   const Type* el = nullptr;
6992   if (elem()->isa_klassptr()) {
6993     el = elem()->is_klassptr()->as_subtype_instance_type(false);
6994     k = nullptr;
6995   } else {
6996     el = elem();
6997   }
6998   bool flat, not_flat, not_null_free, atomic;
6999   if (_refined_type) {
7000     if (_null_free && el->isa_ptr()) {
7001       el = el->is_ptr()->join_speculative(TypePtr::NOTNULL);
7002     }
7003     flat = is_flat();
7004     not_flat = is_not_flat();
7005     not_null_free = is_not_null_free();
7006     atomic = is_atomic();
7007   } else {  // Unrefined types aren't trustworthy! Let's not mistake their ignorance for information.
7008     // We can always have arrays of references. Flatness is not guaranteed.
7009     flat = false;
7010     // There are asserts that expect us to not be entirely naive about properties.
7011     // Only arrays of value classes can be null free. Otherwise, not_null_free == true. That is if the element type
7012     // is not an instance class, or this instance class cannot be an inline type, it's surely not null-restricted.
7013     not_null_free = !elem()->isa_instklassptr() || !elem()->is_instklassptr()->can_be_inline_type();
7014     bool array_can_be_flat;
7015     if (elem()->isa_instklassptr()) {
7016       FlatInArray elem_flat_in_array = elem()->is_instklassptr()->flat_in_array();
7017       array_can_be_flat = elem_flat_in_array == MaybeFlat || elem_flat_in_array == Flat;
7018     } else {
7019       array_can_be_flat = false;
7020     }
7021     not_flat = !array_can_be_flat;
7022     atomic = !array_can_be_flat;
7023   }
7024   return TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(el, TypeInt::POS, false, flat, not_flat, not_null_free, atomic), k, xk, Offset(0));
7025 }
7026 
7027 // Corresponding type for instances that subtype the given class
7028 const TypeAryPtr* TypeAryKlassPtr::as_subtype_instance_type(bool klass_change) const {
7029   return cast_to_exactness(false)->as_exact_instance_type(klass_change);
7030 }
7031 
7032 //------------------------------xmeet------------------------------------------
7033 // Compute the MEET of two types, return a new Type object.
7034 const Type    *TypeAryKlassPtr::xmeet( const Type *t ) const {
7035   // Perform a fast test for common case; meeting the same types together.
7036   if( this == t ) return this;  // Meeting same type-rep?
7037 
7038   // Current "this->_base" is Pointer
7039   switch (t->base()) {          // switch on original type
7040 
7041   case Int:                     // Mixing ints & oops happens when javac
7042   case Long:                    // reuses local variables
7043   case HalfFloatTop:
7044   case HalfFloatCon:
7045   case HalfFloatBot:
7046   case FloatTop:
7047   case FloatCon:
7048   case FloatBot:
7049   case DoubleTop:
7050   case DoubleCon:
7051   case DoubleBot:
7052   case NarrowOop:
7053   case NarrowKlass:
7054   case Bottom:                  // Ye Olde Default
7055     return Type::BOTTOM;
7056   case Top:
7057     return this;
7058 
7059   default:                      // All else is a mistake
7060     typerr(t);
7061 
7062   case AnyPtr: {                // Meeting to AnyPtrs
7063     // Found an AnyPtr type vs self-KlassPtr type
7064     const TypePtr *tp = t->is_ptr();
7065     Offset offset = meet_offset(tp->offset());
7066     PTR ptr = meet_ptr(tp->ptr());
7067     switch (tp->ptr()) {
7068     case TopPTR:
7069       return this;
7070     case Null:
7071       if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
7072     case AnyNull:
7073       return make(ptr, _elem, klass(), offset, is_not_flat(), is_not_null_free(), is_flat(), is_null_free(), is_atomic(), is_refined_type());
7074     case BotPTR:
7075     case NotNull:
7076       return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth());
7077     default: typerr(t);
7078     }
7079   }
7080 
7081   case RawPtr:
7082   case MetadataPtr:
7083   case OopPtr:
7084   case AryPtr:                  // Meet with AryPtr
7085   case InstPtr:                 // Meet with InstPtr
7086     return TypePtr::BOTTOM;
7087 
7088   //
7089   //             A-top         }
7090   //           /   |   \       }  Tops
7091   //       B-top A-any C-top   }
7092   //          | /  |  \ |      }  Any-nulls
7093   //       B-any   |   C-any   }
7094   //          |    |    |
7095   //       B-con A-con C-con   } constants; not comparable across classes
7096   //          |    |    |
7097   //       B-not   |   C-not   }
7098   //          | \  |  / |      }  not-nulls
7099   //       B-bot A-not C-bot   }
7100   //           \   |   /       }  Bottoms
7101   //             A-bot         }
7102   //
7103 
7104   case AryKlassPtr: {  // Meet two KlassPtr types
7105     const TypeAryKlassPtr *tap = t->is_aryklassptr();
7106     Offset off = meet_offset(tap->offset());
7107     const Type* elem = _elem->meet(tap->_elem);
7108     PTR ptr = meet_ptr(tap->ptr());
7109     ciKlass* res_klass = nullptr;
7110     bool res_xk = false;
7111     bool res_flat = false;
7112     bool res_not_flat = false;
7113     bool res_not_null_free = false;
7114     bool res_atomic = false;
7115     MeetResult res = meet_aryptr(ptr, elem, this, tap,
7116                                  res_klass, res_xk, res_flat, res_not_flat, res_not_null_free, res_atomic);
7117     assert(res_xk == (ptr == Constant), "");
7118     bool flat = meet_flat(tap->_flat);
7119     bool null_free = meet_null_free(tap->_null_free);
7120     bool atomic = meet_atomic(tap->_atomic);
7121     bool refined_type = _refined_type && tap->_refined_type;
7122     if (res == NOT_SUBTYPE) {
7123       flat = false;
7124       null_free = false;
7125       atomic = false;
7126       refined_type = false;
7127     } else if (res == SUBTYPE) {
7128       if (above_centerline(tap->ptr()) && !above_centerline(this->ptr())) {
7129         flat = _flat;
7130         null_free = _null_free;
7131         atomic = _atomic;
7132         refined_type = _refined_type;
7133       } else if (above_centerline(this->ptr()) && !above_centerline(tap->ptr())) {
7134         flat = tap->_flat;
7135         null_free = tap->_null_free;
7136         atomic = tap->_atomic;
7137         refined_type = tap->_refined_type;
7138       } else if (above_centerline(this->ptr()) && above_centerline(tap->ptr())) {
7139         flat = _flat || tap->_flat;
7140         null_free = _null_free || tap->_null_free;
7141         atomic = _atomic || tap->_atomic;
7142         refined_type = _refined_type || tap->_refined_type;
7143       } else if (res_xk && _refined_type != tap->_refined_type) {
7144         // This can happen if the phi emitted by LibraryCallKit::load_default_refined_array_klass/load_non_refined_array_klass
7145         // is processed before the typeArray guard is folded. Both inputs are constant but the input corresponding to the
7146         // typeArray will go away. Don't constant fold it yet but wait for the control input to collapse.
7147         ptr = PTR::NotNull;
7148       }
7149     }
7150     return make(ptr, elem, res_klass, off, res_not_flat, res_not_null_free, flat, null_free, atomic, refined_type);
7151   } // End of case KlassPtr
7152   case InstKlassPtr: {
7153     const TypeInstKlassPtr *tp = t->is_instklassptr();
7154     Offset offset = meet_offset(tp->offset());
7155     PTR ptr = meet_ptr(tp->ptr());
7156     const TypeInterfaces* interfaces = meet_interfaces(tp);
7157     const TypeInterfaces* tp_interfaces = tp->_interfaces;
7158     const TypeInterfaces* this_interfaces = _interfaces;
7159 
7160     switch (ptr) {
7161     case TopPTR:
7162     case AnyNull:                // Fall 'down' to dual of object klass
7163       // For instances when a subclass meets a superclass we fall
7164       // below the centerline when the superclass is exact. We need to
7165       // do the same here.
7166       //
7167       // Flat in array: See explanation for meet with TypeInstPtr in TypeAryPtr::xmeet_helper().
7168       if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) &&
7169           !tp->klass_is_exact() && !tp->is_not_flat_in_array()) {
7170         return TypeAryKlassPtr::make(ptr, _elem, _klass, offset, is_not_flat(), is_not_null_free(), is_flat(), is_null_free(), is_atomic(), is_refined_type());
7171       } else {
7172         // cannot subclass, so the meet has to fall badly below the centerline
7173         ptr = NotNull;
7174         interfaces = this_interfaces->intersection_with(tp->_interfaces);
7175         FlatInArray flat_in_array = meet_flat_in_array(NotFlat, tp->flat_in_array());
7176         return TypeInstKlassPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, flat_in_array);
7177       }
7178     case Constant:
7179     case NotNull:
7180     case BotPTR: { // Fall down to object klass
7181       // LCA is object_klass, but if we subclass from the top we can do better
7182       if (above_centerline(tp->ptr())) {
7183         // If 'tp'  is above the centerline and it is Object class
7184         // then we can subclass in the Java class hierarchy.
7185         // For instances when a subclass meets a superclass we fall
7186         // below the centerline when the superclass is exact. We need
7187         // to do the same here.
7188         //
7189         // Flat in array: See explanation for meet with TypeInstPtr in TypeAryPtr::xmeet_helper().
7190         if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) &&
7191             !tp->klass_is_exact() && !tp->is_not_flat_in_array()) {
7192           // that is, my array type is a subtype of 'tp' klass
7193           return make(ptr, _elem, _klass, offset, is_not_flat(), is_not_null_free(), is_flat(), is_null_free(), is_atomic(), is_refined_type());
7194         }
7195       }
7196       // The other case cannot happen, since t cannot be a subtype of an array.
7197       // The meet falls down to Object class below centerline.
7198       if (ptr == Constant)
7199         ptr = NotNull;
7200       interfaces = this_interfaces->intersection_with(tp_interfaces);
7201       FlatInArray flat_in_array = meet_flat_in_array(NotFlat, tp->flat_in_array());
7202       return TypeInstKlassPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, flat_in_array);
7203     }
7204     default: typerr(t);
7205     }
7206   }
7207 
7208   } // End of switch
7209   return this;                  // Return the double constant
7210 }
7211 
7212 template <class T1, class T2> bool TypePtr::is_java_subtype_of_helper_for_array(const T1* this_one, const T2* other, bool this_exact, bool other_exact) {
7213   static_assert(std::is_base_of<T2, T1>::value, "");
7214 
7215   if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty() && other_exact) {
7216     return true;
7217   }
7218 
7219   int dummy;
7220   bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM);
7221 
7222   if (!this_one->is_loaded() || !other->is_loaded() || this_top_or_bottom) {
7223     return false;
7224   }
7225 
7226   if (this_one->is_instance_type(other)) {
7227     return other->klass() == ciEnv::current()->Object_klass() && this_one->_interfaces->contains(other->_interfaces) &&
7228            other_exact;
7229   }
7230 
7231   assert(this_one->is_array_type(other), "");
7232   const T1* other_ary = this_one->is_array_type(other);
7233   bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM);
7234   if (other_top_or_bottom) {
7235     return false;
7236   }
7237 
7238   const TypePtr* other_elem = other_ary->elem()->make_ptr();
7239   const TypePtr* this_elem = this_one->elem()->make_ptr();
7240   if (this_elem != nullptr && other_elem != nullptr) {
7241     if (other->is_null_free() && !this_one->is_null_free()) {
7242       return false; // A nullable array can't be a subtype of a null-free array
7243     }
7244     return this_one->is_reference_type(this_elem)->is_java_subtype_of_helper(this_one->is_reference_type(other_elem), this_exact, other_exact);
7245   }
7246   if (this_elem == nullptr && other_elem == nullptr) {
7247     return this_one->klass()->is_subtype_of(other->klass());
7248   }
7249   return false;
7250 }
7251 
7252 bool TypeAryKlassPtr::is_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const {
7253   return TypePtr::is_java_subtype_of_helper_for_array(this, other, this_exact, other_exact);
7254 }
7255 
7256 template <class T1, class T2> bool TypePtr::is_same_java_type_as_helper_for_array(const T1* this_one, const T2* other) {
7257   static_assert(std::is_base_of<T2, T1>::value, "");
7258 
7259   int dummy;
7260   bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM);
7261 
7262   if (!this_one->is_array_type(other) ||
7263       !this_one->is_loaded() || !other->is_loaded() || this_top_or_bottom) {
7264     return false;
7265   }
7266   const T1* other_ary = this_one->is_array_type(other);
7267   bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM);
7268 
7269   if (other_top_or_bottom) {
7270     return false;
7271   }
7272 
7273   const TypePtr* other_elem = other_ary->elem()->make_ptr();
7274   const TypePtr* this_elem = this_one->elem()->make_ptr();
7275   if (other_elem != nullptr && this_elem != nullptr) {
7276     return this_one->is_reference_type(this_elem)->is_same_java_type_as(this_one->is_reference_type(other_elem));
7277   }
7278   if (other_elem == nullptr && this_elem == nullptr) {
7279     return this_one->klass()->equals(other->klass());
7280   }
7281   return false;
7282 }
7283 
7284 bool TypeAryKlassPtr::is_same_java_type_as_helper(const TypeKlassPtr* other) const {
7285   return TypePtr::is_same_java_type_as_helper_for_array(this, other);
7286 }
7287 
7288 template <class T1, class T2> bool TypePtr::maybe_java_subtype_of_helper_for_array(const T1* this_one, const T2* other, bool this_exact, bool other_exact) {
7289   static_assert(std::is_base_of<T2, T1>::value, "");
7290   if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty() && other_exact) {
7291     return true;
7292   }
7293   if (!this_one->is_loaded() || !other->is_loaded()) {
7294     return true;
7295   }
7296   if (this_one->is_instance_type(other)) {
7297     return other->klass()->equals(ciEnv::current()->Object_klass()) &&
7298            this_one->_interfaces->contains(other->_interfaces);
7299   }
7300 
7301   int dummy;
7302   bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM);
7303   if (this_top_or_bottom) {
7304     return true;
7305   }
7306 
7307   assert(this_one->is_array_type(other), "");
7308 
7309   const T1* other_ary = this_one->is_array_type(other);
7310   bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM);
7311   if (other_top_or_bottom) {
7312     return true;
7313   }
7314   if (this_exact && other_exact) {
7315     return this_one->is_java_subtype_of(other);
7316   }
7317 
7318   const TypePtr* this_elem = this_one->elem()->make_ptr();
7319   const TypePtr* other_elem = other_ary->elem()->make_ptr();
7320   if (other_elem != nullptr && this_elem != nullptr) {
7321     return this_one->is_reference_type(this_elem)->maybe_java_subtype_of_helper(this_one->is_reference_type(other_elem), this_exact, other_exact);
7322   }
7323   if (other_elem == nullptr && this_elem == nullptr) {
7324     return this_one->klass()->is_subtype_of(other->klass());
7325   }
7326   return false;
7327 }
7328 
7329 bool TypeAryKlassPtr::maybe_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const {
7330   return TypePtr::maybe_java_subtype_of_helper_for_array(this, other, this_exact, other_exact);
7331 }
7332 
7333 //------------------------------xdual------------------------------------------
7334 // Dual: compute field-by-field dual
7335 const Type    *TypeAryKlassPtr::xdual() const {
7336   return new TypeAryKlassPtr(dual_ptr(), elem()->dual(), klass(), dual_offset(), !is_not_flat(), !is_not_null_free(), dual_flat(), dual_null_free(), dual_atomic(), _refined_type);
7337 }
7338 
7339 // Is there a single ciKlass* that can represent that type?
7340 ciKlass* TypeAryKlassPtr::exact_klass_helper() const {
7341   if (elem()->isa_klassptr()) {
7342     ciKlass* k = elem()->is_klassptr()->exact_klass_helper();
7343     if (k == nullptr) {
7344       return nullptr;
7345     }
7346     assert(!k->is_array_klass() || !k->as_array_klass()->is_refined(), "no mechanism to create an array of refined arrays %s", k->name()->as_utf8());
7347     k = ciArrayKlass::make(k, is_null_free(), is_atomic(), _refined_type);
7348     return k;
7349   }
7350 
7351   return klass();
7352 }
7353 
7354 ciKlass* TypeAryKlassPtr::klass() const {
7355   if (_klass != nullptr) {
7356     return _klass;
7357   }
7358   ciKlass* k = nullptr;
7359   if (elem()->isa_klassptr()) {
7360     // leave null
7361   } else if ((elem()->base() == Type::Top) ||
7362              (elem()->base() == Type::Bottom)) {
7363   } else {
7364     k = ciTypeArrayKlass::make(elem()->basic_type());
7365     ((TypeAryKlassPtr*)this)->_klass = k;
7366   }
7367   return k;
7368 }
7369 
7370 //------------------------------dump2------------------------------------------
7371 // Dump Klass Type
7372 #ifndef PRODUCT
7373 void TypeAryKlassPtr::dump2( Dict & d, uint depth, outputStream *st ) const {
7374   st->print("aryklassptr:[");
7375   _elem->dump2(d, depth, st);
7376   _interfaces->dump(st);
7377   st->print(":%s", ptr_msg[_ptr]);
7378   if (_flat) st->print(":flat");
7379   if (_null_free) st->print(":null free");
7380   if (_atomic) st->print(":atomic");
7381   if (_refined_type) st->print(":refined_type");
7382   if (Verbose) {
7383     if (_not_flat) st->print(":not flat");
7384     if (_not_null_free) st->print(":nullable");
7385   }
7386   dump_offset(st);
7387 }
7388 #endif
7389 
7390 const Type* TypeAryKlassPtr::base_element_type(int& dims) const {
7391   const Type* elem = this->elem();
7392   dims = 1;
7393   while (elem->isa_aryklassptr()) {
7394     elem = elem->is_aryklassptr()->elem();
7395     dims++;
7396   }
7397   return elem;
7398 }
7399 
7400 //=============================================================================
7401 // Convenience common pre-built types.
7402 
7403 //------------------------------make-------------------------------------------
7404 const TypeFunc *TypeFunc::make(const TypeTuple *domain_sig, const TypeTuple* domain_cc,
7405                                const TypeTuple* range_sig, const TypeTuple* range_cc,
7406                                bool scalarized_return) {
7407   return (TypeFunc*)(new TypeFunc(domain_sig, domain_cc, range_sig, range_cc, scalarized_return))->hashcons();
7408 }
7409 
7410 const TypeFunc *TypeFunc::make(const TypeTuple *domain, const TypeTuple *range) {
7411   return make(domain, domain, range, range);
7412 }
7413 
7414 //------------------------------osr_domain-----------------------------
7415 const TypeTuple* osr_domain() {
7416   const Type **fields = TypeTuple::fields(2);
7417   fields[TypeFunc::Parms+0] = TypeRawPtr::BOTTOM;  // address of osr buffer
7418   return TypeTuple::make(TypeFunc::Parms+1, fields);
7419 }
7420 
7421 // Build a TypeFunc with both the Java-signature view ('sig') and the actual calling-
7422 // convention view ('cc') of inline types. In the signature, an inline type is a single
7423 // oop slot. In the scalarized calling convention, it is expanded to its field
7424 // values (plus null marker and optional oop to the heap buffer).
7425 // The 'is_call' argument distinguishes between the return signature of a method at calls
7426 // vs. at compilation of that method because at calls we return an additional null marker field.
7427 // For OSR and mismatching calls, we fall back to the non-scalarized argument view.
7428 const TypeFunc* TypeFunc::make(ciMethod* method, bool is_call, bool is_osr_compilation) {
7429   Compile* C = Compile::current();
7430   const TypeFunc* tf = nullptr;
7431   // Inline types are not passed/returned by reference, instead each field of
7432   // the inline type is passed/returned as an argument. We maintain two views of
7433   // the argument/return list here: one based on the signature (with an inline
7434   // type argument/return as a single slot), one based on the actual calling
7435   // convention (with an inline type argument/return as a list of its fields).
7436   bool has_scalar_args = method->has_scalarized_args() && !is_osr_compilation;
7437   // Fall back to the non-scalarized calling convention when compiling a call via a mismatching method
7438   if (is_call && method->mismatch()) {
7439     has_scalar_args = false;
7440   }
7441   ciSignature* sig = method->signature();
7442   bool has_scalar_ret = !method->is_native() && sig->return_type()->is_inlinetype() && sig->return_type()->as_inline_klass()->can_be_returned_as_fields();
7443   // Don't cache on scalarized return because the range depends on 'is_call'
7444   if (!is_osr_compilation && !has_scalar_ret) {
7445     tf = C->last_tf(method); // check cache
7446     if (tf != nullptr)  return tf;  // The hit rate here is almost 50%.
7447   }
7448   const TypeTuple* domain_sig = is_osr_compilation ? osr_domain() : TypeTuple::make_domain(method, ignore_interfaces, false);
7449   const TypeTuple* domain_cc = has_scalar_args ? TypeTuple::make_domain(method, ignore_interfaces, true) : domain_sig;
7450   const TypeTuple* range_sig = TypeTuple::make_range(sig, ignore_interfaces);
7451   const TypeTuple* range_cc = has_scalar_ret ? TypeTuple::make_range(sig, ignore_interfaces, true, is_call) : range_sig;
7452   tf = TypeFunc::make(domain_sig, domain_cc, range_sig, range_cc, has_scalar_ret);
7453   if (!is_osr_compilation && !has_scalar_ret) {
7454     C->set_last_tf(method, tf);  // fill cache
7455   }
7456   return tf;
7457 }
7458 
7459 //------------------------------meet-------------------------------------------
7460 // Compute the MEET of two types.  It returns a new Type object.
7461 const Type *TypeFunc::xmeet( const Type *t ) const {
7462   // Perform a fast test for common case; meeting the same types together.
7463   if( this == t ) return this;  // Meeting same type-rep?
7464 
7465   // Current "this->_base" is Func
7466   switch (t->base()) {          // switch on original type
7467 
7468   case Bottom:                  // Ye Olde Default
7469     return t;
7470 
7471   default:                      // All else is a mistake
7472     typerr(t);
7473 
7474   case Top:
7475     break;
7476   }
7477   return this;                  // Return the double constant
7478 }
7479 
7480 //------------------------------xdual------------------------------------------
7481 // Dual: compute field-by-field dual
7482 const Type *TypeFunc::xdual() const {
7483   return this;
7484 }
7485 
7486 //------------------------------eq---------------------------------------------
7487 // Structural equality check for Type representations
7488 bool TypeFunc::eq( const Type *t ) const {
7489   const TypeFunc *a = (const TypeFunc*)t;
7490   return _domain_sig == a->_domain_sig &&
7491     _domain_cc == a->_domain_cc &&
7492     _range_sig == a->_range_sig &&
7493     _range_cc == a->_range_cc &&
7494     _scalarized_return == a->_scalarized_return;
7495 }
7496 
7497 //------------------------------hash-------------------------------------------
7498 // Type-specific hashing function.
7499 uint TypeFunc::hash(void) const {
7500   return (uint)(intptr_t)_domain_sig + (uint)(intptr_t)_domain_cc + (uint)(intptr_t)_range_sig + (uint)(intptr_t)_range_cc + (uint)(intptr_t)_scalarized_return;
7501 }
7502 
7503 //------------------------------dump2------------------------------------------
7504 // Dump Function Type
7505 #ifndef PRODUCT
7506 void TypeFunc::dump2( Dict &d, uint depth, outputStream *st ) const {
7507   if( _range_sig->cnt() <= Parms )
7508     st->print("void");
7509   else {
7510     uint i;
7511     for (i = Parms; i < _range_sig->cnt()-1; i++) {
7512       _range_sig->field_at(i)->dump2(d,depth,st);
7513       st->print("/");
7514     }
7515     _range_sig->field_at(i)->dump2(d,depth,st);
7516   }
7517   st->print(" ");
7518   st->print("( ");
7519   if( !depth || d[this] ) {     // Check for recursive dump
7520     st->print("...)");
7521     return;
7522   }
7523   d.Insert((void*)this,(void*)this);    // Stop recursion
7524   if (Parms < _domain_sig->cnt())
7525     _domain_sig->field_at(Parms)->dump2(d,depth-1,st);
7526   for (uint i = Parms+1; i < _domain_sig->cnt(); i++) {
7527     st->print(", ");
7528     _domain_sig->field_at(i)->dump2(d,depth-1,st);
7529   }
7530   st->print(" )");
7531 }
7532 #endif
7533 
7534 //------------------------------singleton--------------------------------------
7535 // TRUE if Type is a singleton type, FALSE otherwise.   Singletons are simple
7536 // constants (Ldi nodes).  Singletons are integer, float or double constants
7537 // or a single symbol.
7538 bool TypeFunc::singleton(void) const {
7539   return false;                 // Never a singleton
7540 }
7541 
7542 bool TypeFunc::empty(void) const {
7543   return false;                 // Never empty
7544 }
7545 
7546 
7547 BasicType TypeFunc::return_type() const{
7548   if (range_sig()->cnt() == TypeFunc::Parms) {
7549     return T_VOID;
7550   }
7551   return range_sig()->field_at(TypeFunc::Parms)->basic_type();
7552 }