1 /* 2 * Copyright (c) 1997, 2023, 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 "precompiled.hpp" 26 #include "ci/ciFlatArrayKlass.hpp" 27 #include "ci/ciField.hpp" 28 #include "ci/ciInlineKlass.hpp" 29 #include "ci/ciMethodData.hpp" 30 #include "ci/ciTypeFlow.hpp" 31 #include "classfile/javaClasses.hpp" 32 #include "classfile/symbolTable.hpp" 33 #include "compiler/compileLog.hpp" 34 #include "libadt/dict.hpp" 35 #include "memory/oopFactory.hpp" 36 #include "memory/resourceArea.hpp" 37 #include "oops/instanceKlass.hpp" 38 #include "oops/instanceMirrorKlass.hpp" 39 #include "oops/objArrayKlass.hpp" 40 #include "oops/typeArrayKlass.hpp" 41 #include "opto/matcher.hpp" 42 #include "opto/node.hpp" 43 #include "opto/opcodes.hpp" 44 #include "opto/type.hpp" 45 #include "utilities/checkedCast.hpp" 46 #include "utilities/powerOfTwo.hpp" 47 #include "utilities/stringUtils.hpp" 48 49 // Portions of code courtesy of Clifford Click 50 51 // Optimization - Graph Style 52 53 // Dictionary of types shared among compilations. 54 Dict* Type::_shared_type_dict = nullptr; 55 const Type::Offset Type::Offset::top(Type::OffsetTop); 56 const Type::Offset Type::Offset::bottom(Type::OffsetBot); 57 58 const Type::Offset Type::Offset::meet(const Type::Offset other) const { 59 // Either is 'TOP' offset? Return the other offset! 60 if (_offset == OffsetTop) return other; 61 if (other._offset == OffsetTop) return *this; 62 // If either is different, return 'BOTTOM' offset 63 if (_offset != other._offset) return bottom; 64 return Offset(_offset); 65 } 66 67 const Type::Offset Type::Offset::dual() const { 68 if (_offset == OffsetTop) return bottom;// Map 'TOP' into 'BOTTOM' 69 if (_offset == OffsetBot) return top;// Map 'BOTTOM' into 'TOP' 70 return Offset(_offset); // Map everything else into self 71 } 72 73 const Type::Offset Type::Offset::add(intptr_t offset) const { 74 // Adding to 'TOP' offset? Return 'TOP'! 75 if (_offset == OffsetTop || offset == OffsetTop) return top; 76 // Adding to 'BOTTOM' offset? Return 'BOTTOM'! 77 if (_offset == OffsetBot || offset == OffsetBot) return bottom; 78 // Addition overflows or "accidentally" equals to OffsetTop? Return 'BOTTOM'! 79 offset += (intptr_t)_offset; 80 if (offset != (int)offset || offset == OffsetTop) return bottom; 81 82 // assert( _offset >= 0 && _offset+offset >= 0, "" ); 83 // It is possible to construct a negative offset during PhaseCCP 84 85 return Offset((int)offset); // Sum valid offsets 86 } 87 88 void Type::Offset::dump2(outputStream *st) const { 89 if (_offset == 0) { 90 return; 91 } else if (_offset == OffsetTop) { 92 st->print("+top"); 93 } 94 else if (_offset == OffsetBot) { 95 st->print("+bot"); 96 } else if (_offset) { 97 st->print("+%d", _offset); 98 } 99 } 100 101 // Array which maps compiler types to Basic Types 102 const Type::TypeInfo Type::_type_info[Type::lastype] = { 103 { Bad, T_ILLEGAL, "bad", false, Node::NotAMachineReg, relocInfo::none }, // Bad 104 { Control, T_ILLEGAL, "control", false, 0, relocInfo::none }, // Control 105 { Bottom, T_VOID, "top", false, 0, relocInfo::none }, // Top 106 { Bad, T_INT, "int:", false, Op_RegI, relocInfo::none }, // Int 107 { Bad, T_LONG, "long:", false, Op_RegL, relocInfo::none }, // Long 108 { Half, T_VOID, "half", false, 0, relocInfo::none }, // Half 109 { Bad, T_NARROWOOP, "narrowoop:", false, Op_RegN, relocInfo::none }, // NarrowOop 110 { Bad, T_NARROWKLASS,"narrowklass:", false, Op_RegN, relocInfo::none }, // NarrowKlass 111 { Bad, T_ILLEGAL, "tuple:", false, Node::NotAMachineReg, relocInfo::none }, // Tuple 112 { Bad, T_ARRAY, "array:", false, Node::NotAMachineReg, relocInfo::none }, // Array 113 { Bad, T_ARRAY, "interfaces:", false, Node::NotAMachineReg, relocInfo::none }, // Interfaces 114 115 #if defined(PPC64) 116 { Bad, T_ILLEGAL, "vectormask:", false, Op_RegVectMask, relocInfo::none }, // VectorMask. 117 { Bad, T_ILLEGAL, "vectora:", false, Op_VecA, relocInfo::none }, // VectorA. 118 { Bad, T_ILLEGAL, "vectors:", false, 0, relocInfo::none }, // VectorS 119 { Bad, T_ILLEGAL, "vectord:", false, Op_RegL, relocInfo::none }, // VectorD 120 { Bad, T_ILLEGAL, "vectorx:", false, Op_VecX, relocInfo::none }, // VectorX 121 { Bad, T_ILLEGAL, "vectory:", false, 0, relocInfo::none }, // VectorY 122 { Bad, T_ILLEGAL, "vectorz:", false, 0, relocInfo::none }, // VectorZ 123 #elif defined(S390) 124 { Bad, T_ILLEGAL, "vectormask:", false, Op_RegVectMask, relocInfo::none }, // VectorMask. 125 { Bad, T_ILLEGAL, "vectora:", false, Op_VecA, relocInfo::none }, // VectorA. 126 { Bad, T_ILLEGAL, "vectors:", false, 0, relocInfo::none }, // VectorS 127 { Bad, T_ILLEGAL, "vectord:", false, Op_RegL, relocInfo::none }, // VectorD 128 { Bad, T_ILLEGAL, "vectorx:", false, 0, relocInfo::none }, // VectorX 129 { Bad, T_ILLEGAL, "vectory:", false, 0, relocInfo::none }, // VectorY 130 { Bad, T_ILLEGAL, "vectorz:", false, 0, relocInfo::none }, // VectorZ 131 #else // all other 132 { Bad, T_ILLEGAL, "vectormask:", false, Op_RegVectMask, relocInfo::none }, // VectorMask. 133 { Bad, T_ILLEGAL, "vectora:", false, Op_VecA, relocInfo::none }, // VectorA. 134 { Bad, T_ILLEGAL, "vectors:", false, Op_VecS, relocInfo::none }, // VectorS 135 { Bad, T_ILLEGAL, "vectord:", false, Op_VecD, relocInfo::none }, // VectorD 136 { Bad, T_ILLEGAL, "vectorx:", false, Op_VecX, relocInfo::none }, // VectorX 137 { Bad, T_ILLEGAL, "vectory:", false, Op_VecY, relocInfo::none }, // VectorY 138 { Bad, T_ILLEGAL, "vectorz:", false, Op_VecZ, relocInfo::none }, // VectorZ 139 #endif 140 { Bad, T_ADDRESS, "anyptr:", false, Op_RegP, relocInfo::none }, // AnyPtr 141 { Bad, T_ADDRESS, "rawptr:", false, Op_RegP, relocInfo::none }, // RawPtr 142 { Bad, T_OBJECT, "oop:", true, Op_RegP, relocInfo::oop_type }, // OopPtr 143 { Bad, T_OBJECT, "inst:", true, Op_RegP, relocInfo::oop_type }, // InstPtr 144 { Bad, T_OBJECT, "ary:", true, Op_RegP, relocInfo::oop_type }, // AryPtr 145 { Bad, T_METADATA, "metadata:", false, Op_RegP, relocInfo::metadata_type }, // MetadataPtr 146 { Bad, T_METADATA, "klass:", false, Op_RegP, relocInfo::metadata_type }, // KlassPtr 147 { Bad, T_METADATA, "instklass:", false, Op_RegP, relocInfo::metadata_type }, // InstKlassPtr 148 { Bad, T_METADATA, "aryklass:", false, Op_RegP, relocInfo::metadata_type }, // AryKlassPtr 149 { Bad, T_OBJECT, "func", false, 0, relocInfo::none }, // Function 150 { Abio, T_ILLEGAL, "abIO", false, 0, relocInfo::none }, // Abio 151 { Return_Address, T_ADDRESS, "return_address",false, Op_RegP, relocInfo::none }, // Return_Address 152 { Memory, T_ILLEGAL, "memory", false, 0, relocInfo::none }, // Memory 153 { FloatBot, T_FLOAT, "float_top", false, Op_RegF, relocInfo::none }, // FloatTop 154 { FloatCon, T_FLOAT, "ftcon:", false, Op_RegF, relocInfo::none }, // FloatCon 155 { FloatTop, T_FLOAT, "float", false, Op_RegF, relocInfo::none }, // FloatBot 156 { DoubleBot, T_DOUBLE, "double_top", false, Op_RegD, relocInfo::none }, // DoubleTop 157 { DoubleCon, T_DOUBLE, "dblcon:", false, Op_RegD, relocInfo::none }, // DoubleCon 158 { DoubleTop, T_DOUBLE, "double", false, Op_RegD, relocInfo::none }, // DoubleBot 159 { Top, T_ILLEGAL, "bottom", false, 0, relocInfo::none } // Bottom 160 }; 161 162 // Map ideal registers (machine types) to ideal types 163 const Type *Type::mreg2type[_last_machine_leaf]; 164 165 // Map basic types to canonical Type* pointers. 166 const Type* Type:: _const_basic_type[T_CONFLICT+1]; 167 168 // Map basic types to constant-zero Types. 169 const Type* Type:: _zero_type[T_CONFLICT+1]; 170 171 // Map basic types to array-body alias types. 172 const TypeAryPtr* TypeAryPtr::_array_body_type[T_CONFLICT+1]; 173 const TypeInterfaces* TypeAryPtr::_array_interfaces = nullptr; 174 const TypeInterfaces* TypeAryKlassPtr::_array_interfaces = nullptr; 175 176 //============================================================================= 177 // Convenience common pre-built types. 178 const Type *Type::ABIO; // State-of-machine only 179 const Type *Type::BOTTOM; // All values 180 const Type *Type::CONTROL; // Control only 181 const Type *Type::DOUBLE; // All doubles 182 const Type *Type::FLOAT; // All floats 183 const Type *Type::HALF; // Placeholder half of doublewide type 184 const Type *Type::MEMORY; // Abstract store only 185 const Type *Type::RETURN_ADDRESS; 186 const Type *Type::TOP; // No values in set 187 188 //------------------------------get_const_type--------------------------- 189 const Type* Type::get_const_type(ciType* type, InterfaceHandling interface_handling) { 190 if (type == nullptr) { 191 return nullptr; 192 } else if (type->is_primitive_type()) { 193 return get_const_basic_type(type->basic_type()); 194 } else { 195 return TypeOopPtr::make_from_klass(type->as_klass(), interface_handling); 196 } 197 } 198 199 //---------------------------array_element_basic_type--------------------------------- 200 // Mapping to the array element's basic type. 201 BasicType Type::array_element_basic_type() const { 202 BasicType bt = basic_type(); 203 if (bt == T_INT) { 204 if (this == TypeInt::INT) return T_INT; 205 if (this == TypeInt::CHAR) return T_CHAR; 206 if (this == TypeInt::BYTE) return T_BYTE; 207 if (this == TypeInt::BOOL) return T_BOOLEAN; 208 if (this == TypeInt::SHORT) return T_SHORT; 209 return T_VOID; 210 } 211 return bt; 212 } 213 214 // For two instance arrays of same dimension, return the base element types. 215 // Otherwise or if the arrays have different dimensions, return null. 216 void Type::get_arrays_base_elements(const Type *a1, const Type *a2, 217 const TypeInstPtr **e1, const TypeInstPtr **e2) { 218 219 if (e1) *e1 = nullptr; 220 if (e2) *e2 = nullptr; 221 const TypeAryPtr* a1tap = (a1 == nullptr) ? nullptr : a1->isa_aryptr(); 222 const TypeAryPtr* a2tap = (a2 == nullptr) ? nullptr : a2->isa_aryptr(); 223 224 if (a1tap != nullptr && a2tap != nullptr) { 225 // Handle multidimensional arrays 226 const TypePtr* a1tp = a1tap->elem()->make_ptr(); 227 const TypePtr* a2tp = a2tap->elem()->make_ptr(); 228 while (a1tp && a1tp->isa_aryptr() && a2tp && a2tp->isa_aryptr()) { 229 a1tap = a1tp->is_aryptr(); 230 a2tap = a2tp->is_aryptr(); 231 a1tp = a1tap->elem()->make_ptr(); 232 a2tp = a2tap->elem()->make_ptr(); 233 } 234 if (a1tp && a1tp->isa_instptr() && a2tp && a2tp->isa_instptr()) { 235 if (e1) *e1 = a1tp->is_instptr(); 236 if (e2) *e2 = a2tp->is_instptr(); 237 } 238 } 239 } 240 241 //---------------------------get_typeflow_type--------------------------------- 242 // Import a type produced by ciTypeFlow. 243 const Type* Type::get_typeflow_type(ciType* type) { 244 switch (type->basic_type()) { 245 246 case ciTypeFlow::StateVector::T_BOTTOM: 247 assert(type == ciTypeFlow::StateVector::bottom_type(), ""); 248 return Type::BOTTOM; 249 250 case ciTypeFlow::StateVector::T_TOP: 251 assert(type == ciTypeFlow::StateVector::top_type(), ""); 252 return Type::TOP; 253 254 case ciTypeFlow::StateVector::T_NULL: 255 assert(type == ciTypeFlow::StateVector::null_type(), ""); 256 return TypePtr::NULL_PTR; 257 258 case ciTypeFlow::StateVector::T_LONG2: 259 // The ciTypeFlow pass pushes a long, then the half. 260 // We do the same. 261 assert(type == ciTypeFlow::StateVector::long2_type(), ""); 262 return TypeInt::TOP; 263 264 case ciTypeFlow::StateVector::T_DOUBLE2: 265 // The ciTypeFlow pass pushes double, then the half. 266 // Our convention is the same. 267 assert(type == ciTypeFlow::StateVector::double2_type(), ""); 268 return Type::TOP; 269 270 case T_ADDRESS: 271 assert(type->is_return_address(), ""); 272 return TypeRawPtr::make((address)(intptr_t)type->as_return_address()->bci()); 273 274 case T_OBJECT: 275 return Type::get_const_type(type->unwrap())->join_speculative(type->is_null_free() ? TypePtr::NOTNULL : TypePtr::BOTTOM); 276 277 default: 278 // make sure we did not mix up the cases: 279 assert(type != ciTypeFlow::StateVector::bottom_type(), ""); 280 assert(type != ciTypeFlow::StateVector::top_type(), ""); 281 assert(type != ciTypeFlow::StateVector::null_type(), ""); 282 assert(type != ciTypeFlow::StateVector::long2_type(), ""); 283 assert(type != ciTypeFlow::StateVector::double2_type(), ""); 284 assert(!type->is_return_address(), ""); 285 286 return Type::get_const_type(type); 287 } 288 } 289 290 291 //-----------------------make_from_constant------------------------------------ 292 const Type* Type::make_from_constant(ciConstant constant, bool require_constant, 293 int stable_dimension, bool is_narrow_oop, 294 bool is_autobox_cache) { 295 switch (constant.basic_type()) { 296 case T_BOOLEAN: return TypeInt::make(constant.as_boolean()); 297 case T_CHAR: return TypeInt::make(constant.as_char()); 298 case T_BYTE: return TypeInt::make(constant.as_byte()); 299 case T_SHORT: return TypeInt::make(constant.as_short()); 300 case T_INT: return TypeInt::make(constant.as_int()); 301 case T_LONG: return TypeLong::make(constant.as_long()); 302 case T_FLOAT: return TypeF::make(constant.as_float()); 303 case T_DOUBLE: return TypeD::make(constant.as_double()); 304 case T_ARRAY: 305 case T_OBJECT: { 306 const Type* con_type = nullptr; 307 ciObject* oop_constant = constant.as_object(); 308 if (oop_constant->is_null_object()) { 309 con_type = Type::get_zero_type(T_OBJECT); 310 } else { 311 guarantee(require_constant || oop_constant->should_be_constant(), "con_type must get computed"); 312 con_type = TypeOopPtr::make_from_constant(oop_constant, require_constant); 313 if (Compile::current()->eliminate_boxing() && is_autobox_cache) { 314 con_type = con_type->is_aryptr()->cast_to_autobox_cache(); 315 } 316 if (stable_dimension > 0) { 317 assert(FoldStableValues, "sanity"); 318 assert(!con_type->is_zero_type(), "default value for stable field"); 319 con_type = con_type->is_aryptr()->cast_to_stable(true, stable_dimension); 320 } 321 } 322 if (is_narrow_oop) { 323 con_type = con_type->make_narrowoop(); 324 } 325 return con_type; 326 } 327 case T_ILLEGAL: 328 // Invalid ciConstant returned due to OutOfMemoryError in the CI 329 assert(Compile::current()->env()->failing(), "otherwise should not see this"); 330 return nullptr; 331 default: 332 // Fall through to failure 333 return nullptr; 334 } 335 } 336 337 static ciConstant check_mismatched_access(ciConstant con, BasicType loadbt, bool is_unsigned) { 338 BasicType conbt = con.basic_type(); 339 switch (conbt) { 340 case T_BOOLEAN: conbt = T_BYTE; break; 341 case T_ARRAY: conbt = T_OBJECT; break; 342 default: break; 343 } 344 switch (loadbt) { 345 case T_BOOLEAN: loadbt = T_BYTE; break; 346 case T_NARROWOOP: loadbt = T_OBJECT; break; 347 case T_ARRAY: loadbt = T_OBJECT; break; 348 case T_ADDRESS: loadbt = T_OBJECT; break; 349 default: break; 350 } 351 if (conbt == loadbt) { 352 if (is_unsigned && conbt == T_BYTE) { 353 // LoadB (T_BYTE) with a small mask (<=8-bit) is converted to LoadUB (T_BYTE). 354 return ciConstant(T_INT, con.as_int() & 0xFF); 355 } else { 356 return con; 357 } 358 } 359 if (conbt == T_SHORT && loadbt == T_CHAR) { 360 // LoadS (T_SHORT) with a small mask (<=16-bit) is converted to LoadUS (T_CHAR). 361 return ciConstant(T_INT, con.as_int() & 0xFFFF); 362 } 363 return ciConstant(); // T_ILLEGAL 364 } 365 366 // Try to constant-fold a stable array element. 367 const Type* Type::make_constant_from_array_element(ciArray* array, int off, int stable_dimension, 368 BasicType loadbt, bool is_unsigned_load) { 369 // Decode the results of GraphKit::array_element_address. 370 ciConstant element_value = array->element_value_by_offset(off); 371 if (element_value.basic_type() == T_ILLEGAL) { 372 return nullptr; // wrong offset 373 } 374 ciConstant con = check_mismatched_access(element_value, loadbt, is_unsigned_load); 375 376 assert(con.basic_type() != T_ILLEGAL, "elembt=%s; loadbt=%s; unsigned=%d", 377 type2name(element_value.basic_type()), type2name(loadbt), is_unsigned_load); 378 379 if (con.is_valid() && // not a mismatched access 380 !con.is_null_or_zero()) { // not a default value 381 bool is_narrow_oop = (loadbt == T_NARROWOOP); 382 return Type::make_from_constant(con, /*require_constant=*/true, stable_dimension, is_narrow_oop, /*is_autobox_cache=*/false); 383 } 384 return nullptr; 385 } 386 387 const Type* Type::make_constant_from_field(ciInstance* holder, int off, bool is_unsigned_load, BasicType loadbt) { 388 ciField* field; 389 ciType* type = holder->java_mirror_type(); 390 if (type != nullptr && type->is_instance_klass() && off >= InstanceMirrorKlass::offset_of_static_fields()) { 391 // Static field 392 field = type->as_instance_klass()->get_field_by_offset(off, /*is_static=*/true); 393 } else { 394 // Instance field 395 field = holder->klass()->as_instance_klass()->get_field_by_offset(off, /*is_static=*/false); 396 } 397 if (field == nullptr) { 398 return nullptr; // Wrong offset 399 } 400 return Type::make_constant_from_field(field, holder, loadbt, is_unsigned_load); 401 } 402 403 const Type* Type::make_constant_from_field(ciField* field, ciInstance* holder, 404 BasicType loadbt, bool is_unsigned_load) { 405 if (!field->is_constant()) { 406 return nullptr; // Non-constant field 407 } 408 ciConstant field_value; 409 if (field->is_static()) { 410 // final static field 411 field_value = field->constant_value(); 412 } else if (holder != nullptr) { 413 // final or stable non-static field 414 // Treat final non-static fields of trusted classes (classes in 415 // java.lang.invoke and sun.invoke packages and subpackages) as 416 // compile time constants. 417 field_value = field->constant_value_of(holder); 418 } 419 if (!field_value.is_valid()) { 420 return nullptr; // Not a constant 421 } 422 423 ciConstant con = check_mismatched_access(field_value, loadbt, is_unsigned_load); 424 425 assert(con.is_valid(), "elembt=%s; loadbt=%s; unsigned=%d", 426 type2name(field_value.basic_type()), type2name(loadbt), is_unsigned_load); 427 428 bool is_stable_array = FoldStableValues && field->is_stable() && field->type()->is_array_klass(); 429 int stable_dimension = (is_stable_array ? field->type()->as_array_klass()->dimension() : 0); 430 bool is_narrow_oop = (loadbt == T_NARROWOOP); 431 432 const Type* con_type = make_from_constant(con, /*require_constant=*/ true, 433 stable_dimension, is_narrow_oop, 434 field->is_autobox_cache()); 435 if (con_type != nullptr && field->is_call_site_target()) { 436 ciCallSite* call_site = holder->as_call_site(); 437 if (!call_site->is_fully_initialized_constant_call_site()) { 438 ciMethodHandle* target = con.as_object()->as_method_handle(); 439 Compile::current()->dependencies()->assert_call_site_target_value(call_site, target); 440 } 441 } 442 return con_type; 443 } 444 445 //------------------------------make------------------------------------------- 446 // Create a simple Type, with default empty symbol sets. Then hashcons it 447 // and look for an existing copy in the type dictionary. 448 const Type *Type::make( enum TYPES t ) { 449 return (new Type(t))->hashcons(); 450 } 451 452 //------------------------------cmp-------------------------------------------- 453 int Type::cmp( const Type *const t1, const Type *const t2 ) { 454 if( t1->_base != t2->_base ) 455 return 1; // Missed badly 456 assert(t1 != t2 || t1->eq(t2), "eq must be reflexive"); 457 return !t1->eq(t2); // Return ZERO if equal 458 } 459 460 const Type* Type::maybe_remove_speculative(bool include_speculative) const { 461 if (!include_speculative) { 462 return remove_speculative(); 463 } 464 return this; 465 } 466 467 //------------------------------hash------------------------------------------- 468 int Type::uhash( const Type *const t ) { 469 return (int)t->hash(); 470 } 471 472 #define SMALLINT ((juint)3) // a value too insignificant to consider widening 473 #define POSITIVE_INFINITE_F 0x7f800000 // hex representation for IEEE 754 single precision positive infinite 474 #define POSITIVE_INFINITE_D 0x7ff0000000000000 // hex representation for IEEE 754 double precision positive infinite 475 476 //--------------------------Initialize_shared---------------------------------- 477 void Type::Initialize_shared(Compile* current) { 478 // This method does not need to be locked because the first system 479 // compilations (stub compilations) occur serially. If they are 480 // changed to proceed in parallel, then this section will need 481 // locking. 482 483 Arena* save = current->type_arena(); 484 Arena* shared_type_arena = new (mtCompiler)Arena(mtCompiler); 485 486 current->set_type_arena(shared_type_arena); 487 _shared_type_dict = 488 new (shared_type_arena) Dict( (CmpKey)Type::cmp, (Hash)Type::uhash, 489 shared_type_arena, 128 ); 490 current->set_type_dict(_shared_type_dict); 491 492 // Make shared pre-built types. 493 CONTROL = make(Control); // Control only 494 TOP = make(Top); // No values in set 495 MEMORY = make(Memory); // Abstract store only 496 ABIO = make(Abio); // State-of-machine only 497 RETURN_ADDRESS=make(Return_Address); 498 FLOAT = make(FloatBot); // All floats 499 DOUBLE = make(DoubleBot); // All doubles 500 BOTTOM = make(Bottom); // Everything 501 HALF = make(Half); // Placeholder half of doublewide type 502 503 TypeF::MAX = TypeF::make(max_jfloat); // Float MAX 504 TypeF::MIN = TypeF::make(min_jfloat); // Float MIN 505 TypeF::ZERO = TypeF::make(0.0); // Float 0 (positive zero) 506 TypeF::ONE = TypeF::make(1.0); // Float 1 507 TypeF::POS_INF = TypeF::make(jfloat_cast(POSITIVE_INFINITE_F)); 508 TypeF::NEG_INF = TypeF::make(-jfloat_cast(POSITIVE_INFINITE_F)); 509 510 TypeD::MAX = TypeD::make(max_jdouble); // Double MAX 511 TypeD::MIN = TypeD::make(min_jdouble); // Double MIN 512 TypeD::ZERO = TypeD::make(0.0); // Double 0 (positive zero) 513 TypeD::ONE = TypeD::make(1.0); // Double 1 514 TypeD::POS_INF = TypeD::make(jdouble_cast(POSITIVE_INFINITE_D)); 515 TypeD::NEG_INF = TypeD::make(-jdouble_cast(POSITIVE_INFINITE_D)); 516 517 TypeInt::MAX = TypeInt::make(max_jint); // Int MAX 518 TypeInt::MIN = TypeInt::make(min_jint); // Int MIN 519 TypeInt::MINUS_1 = TypeInt::make(-1); // -1 520 TypeInt::ZERO = TypeInt::make( 0); // 0 521 TypeInt::ONE = TypeInt::make( 1); // 1 522 TypeInt::BOOL = TypeInt::make(0,1, WidenMin); // 0 or 1, FALSE or TRUE. 523 TypeInt::CC = TypeInt::make(-1, 1, WidenMin); // -1, 0 or 1, condition codes 524 TypeInt::CC_LT = TypeInt::make(-1,-1, WidenMin); // == TypeInt::MINUS_1 525 TypeInt::CC_GT = TypeInt::make( 1, 1, WidenMin); // == TypeInt::ONE 526 TypeInt::CC_EQ = TypeInt::make( 0, 0, WidenMin); // == TypeInt::ZERO 527 TypeInt::CC_LE = TypeInt::make(-1, 0, WidenMin); 528 TypeInt::CC_GE = TypeInt::make( 0, 1, WidenMin); // == TypeInt::BOOL 529 TypeInt::BYTE = TypeInt::make(-128,127, WidenMin); // Bytes 530 TypeInt::UBYTE = TypeInt::make(0, 255, WidenMin); // Unsigned Bytes 531 TypeInt::CHAR = TypeInt::make(0,65535, WidenMin); // Java chars 532 TypeInt::SHORT = TypeInt::make(-32768,32767, WidenMin); // Java shorts 533 TypeInt::POS = TypeInt::make(0,max_jint, WidenMin); // Non-neg values 534 TypeInt::POS1 = TypeInt::make(1,max_jint, WidenMin); // Positive values 535 TypeInt::INT = TypeInt::make(min_jint,max_jint, WidenMax); // 32-bit integers 536 TypeInt::SYMINT = TypeInt::make(-max_jint,max_jint,WidenMin); // symmetric range 537 TypeInt::TYPE_DOMAIN = TypeInt::INT; 538 // CmpL is overloaded both as the bytecode computation returning 539 // a trinary (-1,0,+1) integer result AND as an efficient long 540 // compare returning optimizer ideal-type flags. 541 assert( TypeInt::CC_LT == TypeInt::MINUS_1, "types must match for CmpL to work" ); 542 assert( TypeInt::CC_GT == TypeInt::ONE, "types must match for CmpL to work" ); 543 assert( TypeInt::CC_EQ == TypeInt::ZERO, "types must match for CmpL to work" ); 544 assert( TypeInt::CC_GE == TypeInt::BOOL, "types must match for CmpL to work" ); 545 assert( (juint)(TypeInt::CC->_hi - TypeInt::CC->_lo) <= SMALLINT, "CC is truly small"); 546 547 TypeLong::MAX = TypeLong::make(max_jlong); // Long MAX 548 TypeLong::MIN = TypeLong::make(min_jlong); // Long MIN 549 TypeLong::MINUS_1 = TypeLong::make(-1); // -1 550 TypeLong::ZERO = TypeLong::make( 0); // 0 551 TypeLong::ONE = TypeLong::make( 1); // 1 552 TypeLong::POS = TypeLong::make(0,max_jlong, WidenMin); // Non-neg values 553 TypeLong::LONG = TypeLong::make(min_jlong,max_jlong,WidenMax); // 64-bit integers 554 TypeLong::INT = TypeLong::make((jlong)min_jint,(jlong)max_jint,WidenMin); 555 TypeLong::UINT = TypeLong::make(0,(jlong)max_juint,WidenMin); 556 TypeLong::TYPE_DOMAIN = TypeLong::LONG; 557 558 const Type **fboth =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 559 fboth[0] = Type::CONTROL; 560 fboth[1] = Type::CONTROL; 561 TypeTuple::IFBOTH = TypeTuple::make( 2, fboth ); 562 563 const Type **ffalse =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 564 ffalse[0] = Type::CONTROL; 565 ffalse[1] = Type::TOP; 566 TypeTuple::IFFALSE = TypeTuple::make( 2, ffalse ); 567 568 const Type **fneither =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 569 fneither[0] = Type::TOP; 570 fneither[1] = Type::TOP; 571 TypeTuple::IFNEITHER = TypeTuple::make( 2, fneither ); 572 573 const Type **ftrue =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 574 ftrue[0] = Type::TOP; 575 ftrue[1] = Type::CONTROL; 576 TypeTuple::IFTRUE = TypeTuple::make( 2, ftrue ); 577 578 const Type **floop =(const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 579 floop[0] = Type::CONTROL; 580 floop[1] = TypeInt::INT; 581 TypeTuple::LOOPBODY = TypeTuple::make( 2, floop ); 582 583 TypePtr::NULL_PTR= TypePtr::make(AnyPtr, TypePtr::Null, Offset(0)); 584 TypePtr::NOTNULL = TypePtr::make(AnyPtr, TypePtr::NotNull, Offset::bottom); 585 TypePtr::BOTTOM = TypePtr::make(AnyPtr, TypePtr::BotPTR, Offset::bottom); 586 587 TypeRawPtr::BOTTOM = TypeRawPtr::make( TypePtr::BotPTR ); 588 TypeRawPtr::NOTNULL= TypeRawPtr::make( TypePtr::NotNull ); 589 590 const Type **fmembar = TypeTuple::fields(0); 591 TypeTuple::MEMBAR = TypeTuple::make(TypeFunc::Parms+0, fmembar); 592 593 const Type **fsc = (const Type**)shared_type_arena->AmallocWords(2*sizeof(Type*)); 594 fsc[0] = TypeInt::CC; 595 fsc[1] = Type::MEMORY; 596 TypeTuple::STORECONDITIONAL = TypeTuple::make(2, fsc); 597 598 TypeInstPtr::NOTNULL = TypeInstPtr::make(TypePtr::NotNull, current->env()->Object_klass()); 599 TypeInstPtr::BOTTOM = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass()); 600 TypeInstPtr::MIRROR = TypeInstPtr::make(TypePtr::NotNull, current->env()->Class_klass()); 601 TypeInstPtr::MARK = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), 602 false, 0, Offset(oopDesc::mark_offset_in_bytes())); 603 TypeInstPtr::KLASS = TypeInstPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), 604 false, 0, Offset(oopDesc::klass_offset_in_bytes())); 605 TypeOopPtr::BOTTOM = TypeOopPtr::make(TypePtr::BotPTR, Offset::bottom, TypeOopPtr::InstanceBot); 606 607 TypeMetadataPtr::BOTTOM = TypeMetadataPtr::make(TypePtr::BotPTR, nullptr, Offset::bottom); 608 609 TypeNarrowOop::NULL_PTR = TypeNarrowOop::make( TypePtr::NULL_PTR ); 610 TypeNarrowOop::BOTTOM = TypeNarrowOop::make( TypeInstPtr::BOTTOM ); 611 612 TypeNarrowKlass::NULL_PTR = TypeNarrowKlass::make( TypePtr::NULL_PTR ); 613 614 mreg2type[Op_Node] = Type::BOTTOM; 615 mreg2type[Op_Set ] = 0; 616 mreg2type[Op_RegN] = TypeNarrowOop::BOTTOM; 617 mreg2type[Op_RegI] = TypeInt::INT; 618 mreg2type[Op_RegP] = TypePtr::BOTTOM; 619 mreg2type[Op_RegF] = Type::FLOAT; 620 mreg2type[Op_RegD] = Type::DOUBLE; 621 mreg2type[Op_RegL] = TypeLong::LONG; 622 mreg2type[Op_RegFlags] = TypeInt::CC; 623 624 GrowableArray<ciInstanceKlass*> array_interfaces; 625 array_interfaces.push(current->env()->Cloneable_klass()); 626 array_interfaces.push(current->env()->Serializable_klass()); 627 TypeAryPtr::_array_interfaces = TypeInterfaces::make(&array_interfaces); 628 TypeAryKlassPtr::_array_interfaces = TypeAryPtr::_array_interfaces; 629 630 TypeAryPtr::RANGE = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::BOTTOM,TypeInt::POS), nullptr /* current->env()->Object_klass() */, false, Offset(arrayOopDesc::length_offset_in_bytes())); 631 632 TypeAryPtr::NARROWOOPS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeNarrowOop::BOTTOM, TypeInt::POS), nullptr /*ciArrayKlass::make(o)*/, false, Offset::bottom); 633 634 #ifdef _LP64 635 if (UseCompressedOops) { 636 assert(TypeAryPtr::NARROWOOPS->is_ptr_to_narrowoop(), "array of narrow oops must be ptr to narrow oop"); 637 TypeAryPtr::OOPS = TypeAryPtr::NARROWOOPS; 638 } else 639 #endif 640 { 641 // There is no shared klass for Object[]. See note in TypeAryPtr::klass(). 642 TypeAryPtr::OOPS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInstPtr::BOTTOM,TypeInt::POS), nullptr /*ciArrayKlass::make(o)*/, false, Offset::bottom); 643 } 644 TypeAryPtr::BYTES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::BYTE ,TypeInt::POS), ciTypeArrayKlass::make(T_BYTE), true, Offset::bottom); 645 TypeAryPtr::SHORTS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::SHORT ,TypeInt::POS), ciTypeArrayKlass::make(T_SHORT), true, Offset::bottom); 646 TypeAryPtr::CHARS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::CHAR ,TypeInt::POS), ciTypeArrayKlass::make(T_CHAR), true, Offset::bottom); 647 TypeAryPtr::INTS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInt::INT ,TypeInt::POS), ciTypeArrayKlass::make(T_INT), true, Offset::bottom); 648 TypeAryPtr::LONGS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeLong::LONG ,TypeInt::POS), ciTypeArrayKlass::make(T_LONG), true, Offset::bottom); 649 TypeAryPtr::FLOATS = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::FLOAT ,TypeInt::POS), ciTypeArrayKlass::make(T_FLOAT), true, Offset::bottom); 650 TypeAryPtr::DOUBLES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(Type::DOUBLE ,TypeInt::POS), ciTypeArrayKlass::make(T_DOUBLE), true, Offset::bottom); 651 TypeAryPtr::INLINES = TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(TypeInstPtr::BOTTOM,TypeInt::POS, /* stable= */ false, /* flat= */ true), nullptr, false, Offset::bottom); 652 653 // Nobody should ask _array_body_type[T_NARROWOOP]. Use null as assert. 654 TypeAryPtr::_array_body_type[T_NARROWOOP] = nullptr; 655 TypeAryPtr::_array_body_type[T_OBJECT] = TypeAryPtr::OOPS; 656 TypeAryPtr::_array_body_type[T_PRIMITIVE_OBJECT] = TypeAryPtr::OOPS; 657 TypeAryPtr::_array_body_type[T_ARRAY] = TypeAryPtr::OOPS; // arrays are stored in oop arrays 658 TypeAryPtr::_array_body_type[T_BYTE] = TypeAryPtr::BYTES; 659 TypeAryPtr::_array_body_type[T_BOOLEAN] = TypeAryPtr::BYTES; // boolean[] is a byte array 660 TypeAryPtr::_array_body_type[T_SHORT] = TypeAryPtr::SHORTS; 661 TypeAryPtr::_array_body_type[T_CHAR] = TypeAryPtr::CHARS; 662 TypeAryPtr::_array_body_type[T_INT] = TypeAryPtr::INTS; 663 TypeAryPtr::_array_body_type[T_LONG] = TypeAryPtr::LONGS; 664 TypeAryPtr::_array_body_type[T_FLOAT] = TypeAryPtr::FLOATS; 665 TypeAryPtr::_array_body_type[T_DOUBLE] = TypeAryPtr::DOUBLES; 666 667 TypeInstKlassPtr::OBJECT = TypeInstKlassPtr::make(TypePtr::NotNull, current->env()->Object_klass(), Offset(0)); 668 TypeInstKlassPtr::OBJECT_OR_NULL = TypeInstKlassPtr::make(TypePtr::BotPTR, current->env()->Object_klass(), Offset(0)); 669 670 const Type **fi2c = TypeTuple::fields(2); 671 fi2c[TypeFunc::Parms+0] = TypeInstPtr::BOTTOM; // Method* 672 fi2c[TypeFunc::Parms+1] = TypeRawPtr::BOTTOM; // argument pointer 673 TypeTuple::START_I2C = TypeTuple::make(TypeFunc::Parms+2, fi2c); 674 675 const Type **intpair = TypeTuple::fields(2); 676 intpair[0] = TypeInt::INT; 677 intpair[1] = TypeInt::INT; 678 TypeTuple::INT_PAIR = TypeTuple::make(2, intpair); 679 680 const Type **longpair = TypeTuple::fields(2); 681 longpair[0] = TypeLong::LONG; 682 longpair[1] = TypeLong::LONG; 683 TypeTuple::LONG_PAIR = TypeTuple::make(2, longpair); 684 685 const Type **intccpair = TypeTuple::fields(2); 686 intccpair[0] = TypeInt::INT; 687 intccpair[1] = TypeInt::CC; 688 TypeTuple::INT_CC_PAIR = TypeTuple::make(2, intccpair); 689 690 const Type **longccpair = TypeTuple::fields(2); 691 longccpair[0] = TypeLong::LONG; 692 longccpair[1] = TypeInt::CC; 693 TypeTuple::LONG_CC_PAIR = TypeTuple::make(2, longccpair); 694 695 _const_basic_type[T_NARROWOOP] = TypeNarrowOop::BOTTOM; 696 _const_basic_type[T_NARROWKLASS] = Type::BOTTOM; 697 _const_basic_type[T_BOOLEAN] = TypeInt::BOOL; 698 _const_basic_type[T_CHAR] = TypeInt::CHAR; 699 _const_basic_type[T_BYTE] = TypeInt::BYTE; 700 _const_basic_type[T_SHORT] = TypeInt::SHORT; 701 _const_basic_type[T_INT] = TypeInt::INT; 702 _const_basic_type[T_LONG] = TypeLong::LONG; 703 _const_basic_type[T_FLOAT] = Type::FLOAT; 704 _const_basic_type[T_DOUBLE] = Type::DOUBLE; 705 _const_basic_type[T_OBJECT] = TypeInstPtr::BOTTOM; 706 _const_basic_type[T_ARRAY] = TypeInstPtr::BOTTOM; // there is no separate bottom for arrays 707 _const_basic_type[T_PRIMITIVE_OBJECT] = TypeInstPtr::BOTTOM; 708 _const_basic_type[T_VOID] = TypePtr::NULL_PTR; // reflection represents void this way 709 _const_basic_type[T_ADDRESS] = TypeRawPtr::BOTTOM; // both interpreter return addresses & random raw ptrs 710 _const_basic_type[T_CONFLICT] = Type::BOTTOM; // why not? 711 712 _zero_type[T_NARROWOOP] = TypeNarrowOop::NULL_PTR; 713 _zero_type[T_NARROWKLASS] = TypeNarrowKlass::NULL_PTR; 714 _zero_type[T_BOOLEAN] = TypeInt::ZERO; // false == 0 715 _zero_type[T_CHAR] = TypeInt::ZERO; // '\0' == 0 716 _zero_type[T_BYTE] = TypeInt::ZERO; // 0x00 == 0 717 _zero_type[T_SHORT] = TypeInt::ZERO; // 0x0000 == 0 718 _zero_type[T_INT] = TypeInt::ZERO; 719 _zero_type[T_LONG] = TypeLong::ZERO; 720 _zero_type[T_FLOAT] = TypeF::ZERO; 721 _zero_type[T_DOUBLE] = TypeD::ZERO; 722 _zero_type[T_OBJECT] = TypePtr::NULL_PTR; 723 _zero_type[T_ARRAY] = TypePtr::NULL_PTR; // null array is null oop 724 _zero_type[T_PRIMITIVE_OBJECT] = TypePtr::NULL_PTR; 725 _zero_type[T_ADDRESS] = TypePtr::NULL_PTR; // raw pointers use the same null 726 _zero_type[T_VOID] = Type::TOP; // the only void value is no value at all 727 728 // get_zero_type() should not happen for T_CONFLICT 729 _zero_type[T_CONFLICT]= nullptr; 730 731 TypeVect::VECTMASK = (TypeVect*)(new TypeVectMask(TypeInt::BOOL, MaxVectorSize))->hashcons(); 732 mreg2type[Op_RegVectMask] = TypeVect::VECTMASK; 733 734 if (Matcher::supports_scalable_vector()) { 735 TypeVect::VECTA = TypeVect::make(T_BYTE, Matcher::scalable_vector_reg_size(T_BYTE)); 736 } 737 738 // Vector predefined types, it needs initialized _const_basic_type[]. 739 if (Matcher::vector_size_supported(T_BYTE,4)) { 740 TypeVect::VECTS = TypeVect::make(T_BYTE,4); 741 } 742 if (Matcher::vector_size_supported(T_FLOAT,2)) { 743 TypeVect::VECTD = TypeVect::make(T_FLOAT,2); 744 } 745 if (Matcher::vector_size_supported(T_FLOAT,4)) { 746 TypeVect::VECTX = TypeVect::make(T_FLOAT,4); 747 } 748 if (Matcher::vector_size_supported(T_FLOAT,8)) { 749 TypeVect::VECTY = TypeVect::make(T_FLOAT,8); 750 } 751 if (Matcher::vector_size_supported(T_FLOAT,16)) { 752 TypeVect::VECTZ = TypeVect::make(T_FLOAT,16); 753 } 754 755 mreg2type[Op_VecA] = TypeVect::VECTA; 756 mreg2type[Op_VecS] = TypeVect::VECTS; 757 mreg2type[Op_VecD] = TypeVect::VECTD; 758 mreg2type[Op_VecX] = TypeVect::VECTX; 759 mreg2type[Op_VecY] = TypeVect::VECTY; 760 mreg2type[Op_VecZ] = TypeVect::VECTZ; 761 762 // Restore working type arena. 763 current->set_type_arena(save); 764 current->set_type_dict(nullptr); 765 } 766 767 //------------------------------Initialize------------------------------------- 768 void Type::Initialize(Compile* current) { 769 assert(current->type_arena() != nullptr, "must have created type arena"); 770 771 if (_shared_type_dict == nullptr) { 772 Initialize_shared(current); 773 } 774 775 Arena* type_arena = current->type_arena(); 776 777 // Create the hash-cons'ing dictionary with top-level storage allocation 778 Dict *tdic = new (type_arena) Dict(*_shared_type_dict, type_arena); 779 current->set_type_dict(tdic); 780 } 781 782 //------------------------------hashcons--------------------------------------- 783 // Do the hash-cons trick. If the Type already exists in the type table, 784 // delete the current Type and return the existing Type. Otherwise stick the 785 // current Type in the Type table. 786 const Type *Type::hashcons(void) { 787 debug_only(base()); // Check the assertion in Type::base(). 788 // Look up the Type in the Type dictionary 789 Dict *tdic = type_dict(); 790 Type* old = (Type*)(tdic->Insert(this, this, false)); 791 if( old ) { // Pre-existing Type? 792 if( old != this ) // Yes, this guy is not the pre-existing? 793 delete this; // Yes, Nuke this guy 794 assert( old->_dual, "" ); 795 return old; // Return pre-existing 796 } 797 798 // Every type has a dual (to make my lattice symmetric). 799 // Since we just discovered a new Type, compute its dual right now. 800 assert( !_dual, "" ); // No dual yet 801 _dual = xdual(); // Compute the dual 802 if (cmp(this, _dual) == 0) { // Handle self-symmetric 803 if (_dual != this) { 804 delete _dual; 805 _dual = this; 806 } 807 return this; 808 } 809 assert( !_dual->_dual, "" ); // No reverse dual yet 810 assert( !(*tdic)[_dual], "" ); // Dual not in type system either 811 // New Type, insert into Type table 812 tdic->Insert((void*)_dual,(void*)_dual); 813 ((Type*)_dual)->_dual = this; // Finish up being symmetric 814 #ifdef ASSERT 815 Type *dual_dual = (Type*)_dual->xdual(); 816 assert( eq(dual_dual), "xdual(xdual()) should be identity" ); 817 delete dual_dual; 818 #endif 819 return this; // Return new Type 820 } 821 822 //------------------------------eq--------------------------------------------- 823 // Structural equality check for Type representations 824 bool Type::eq( const Type * ) const { 825 return true; // Nothing else can go wrong 826 } 827 828 //------------------------------hash------------------------------------------- 829 // Type-specific hashing function. 830 uint Type::hash(void) const { 831 return _base; 832 } 833 834 //------------------------------is_finite-------------------------------------- 835 // Has a finite value 836 bool Type::is_finite() const { 837 return false; 838 } 839 840 //------------------------------is_nan----------------------------------------- 841 // Is not a number (NaN) 842 bool Type::is_nan() const { 843 return false; 844 } 845 846 #ifdef ASSERT 847 class VerifyMeet; 848 class VerifyMeetResult : public ArenaObj { 849 friend class VerifyMeet; 850 friend class Type; 851 private: 852 class VerifyMeetResultEntry { 853 private: 854 const Type* _in1; 855 const Type* _in2; 856 const Type* _res; 857 public: 858 VerifyMeetResultEntry(const Type* in1, const Type* in2, const Type* res): 859 _in1(in1), _in2(in2), _res(res) { 860 } 861 VerifyMeetResultEntry(): 862 _in1(nullptr), _in2(nullptr), _res(nullptr) { 863 } 864 865 bool operator==(const VerifyMeetResultEntry& rhs) const { 866 return _in1 == rhs._in1 && 867 _in2 == rhs._in2 && 868 _res == rhs._res; 869 } 870 871 bool operator!=(const VerifyMeetResultEntry& rhs) const { 872 return !(rhs == *this); 873 } 874 875 static int compare(const VerifyMeetResultEntry& v1, const VerifyMeetResultEntry& v2) { 876 if ((intptr_t) v1._in1 < (intptr_t) v2._in1) { 877 return -1; 878 } else if (v1._in1 == v2._in1) { 879 if ((intptr_t) v1._in2 < (intptr_t) v2._in2) { 880 return -1; 881 } else if (v1._in2 == v2._in2) { 882 assert(v1._res == v2._res || v1._res == nullptr || v2._res == nullptr, "same inputs should lead to same result"); 883 return 0; 884 } 885 return 1; 886 } 887 return 1; 888 } 889 const Type* res() const { return _res; } 890 }; 891 uint _depth; 892 GrowableArray<VerifyMeetResultEntry> _cache; 893 894 // With verification code, the meet of A and B causes the computation of: 895 // 1- meet(A, B) 896 // 2- meet(B, A) 897 // 3- meet(dual(meet(A, B)), dual(A)) 898 // 4- meet(dual(meet(A, B)), dual(B)) 899 // 5- meet(dual(A), dual(B)) 900 // 6- meet(dual(B), dual(A)) 901 // 7- meet(dual(meet(dual(A), dual(B))), A) 902 // 8- meet(dual(meet(dual(A), dual(B))), B) 903 // 904 // In addition the meet of A[] and B[] requires the computation of the meet of A and B. 905 // 906 // The meet of A[] and B[] triggers the computation of: 907 // 1- meet(A[], B[][) 908 // 1.1- meet(A, B) 909 // 1.2- meet(B, A) 910 // 1.3- meet(dual(meet(A, B)), dual(A)) 911 // 1.4- meet(dual(meet(A, B)), dual(B)) 912 // 1.5- meet(dual(A), dual(B)) 913 // 1.6- meet(dual(B), dual(A)) 914 // 1.7- meet(dual(meet(dual(A), dual(B))), A) 915 // 1.8- meet(dual(meet(dual(A), dual(B))), B) 916 // 2- meet(B[], A[]) 917 // 2.1- meet(B, A) = 1.2 918 // 2.2- meet(A, B) = 1.1 919 // 2.3- meet(dual(meet(B, A)), dual(B)) = 1.4 920 // 2.4- meet(dual(meet(B, A)), dual(A)) = 1.3 921 // 2.5- meet(dual(B), dual(A)) = 1.6 922 // 2.6- meet(dual(A), dual(B)) = 1.5 923 // 2.7- meet(dual(meet(dual(B), dual(A))), B) = 1.8 924 // 2.8- meet(dual(meet(dual(B), dual(A))), B) = 1.7 925 // etc. 926 // The number of meet operations performed grows exponentially with the number of dimensions of the arrays but the number 927 // of different meet operations is linear in the number of dimensions. The function below caches meet results for the 928 // duration of the meet at the root of the recursive calls. 929 // 930 const Type* meet(const Type* t1, const Type* t2) { 931 bool found = false; 932 const VerifyMeetResultEntry meet(t1, t2, nullptr); 933 int pos = _cache.find_sorted<VerifyMeetResultEntry, VerifyMeetResultEntry::compare>(meet, found); 934 const Type* res = nullptr; 935 if (found) { 936 res = _cache.at(pos).res(); 937 } else { 938 res = t1->xmeet(t2); 939 _cache.insert_sorted<VerifyMeetResultEntry::compare>(VerifyMeetResultEntry(t1, t2, res)); 940 found = false; 941 _cache.find_sorted<VerifyMeetResultEntry, VerifyMeetResultEntry::compare>(meet, found); 942 assert(found, "should be in table after it's added"); 943 } 944 return res; 945 } 946 947 void add(const Type* t1, const Type* t2, const Type* res) { 948 _cache.insert_sorted<VerifyMeetResultEntry::compare>(VerifyMeetResultEntry(t1, t2, res)); 949 } 950 951 bool empty_cache() const { 952 return _cache.length() == 0; 953 } 954 public: 955 VerifyMeetResult(Compile* C) : 956 _depth(0), _cache(C->comp_arena(), 2, 0, VerifyMeetResultEntry()) { 957 } 958 }; 959 960 void Type::assert_type_verify_empty() const { 961 assert(Compile::current()->_type_verify == nullptr || Compile::current()->_type_verify->empty_cache(), "cache should have been discarded"); 962 } 963 964 class VerifyMeet { 965 private: 966 Compile* _C; 967 public: 968 VerifyMeet(Compile* C) : _C(C) { 969 if (C->_type_verify == nullptr) { 970 C->_type_verify = new (C->comp_arena())VerifyMeetResult(C); 971 } 972 _C->_type_verify->_depth++; 973 } 974 975 ~VerifyMeet() { 976 assert(_C->_type_verify->_depth != 0, ""); 977 _C->_type_verify->_depth--; 978 if (_C->_type_verify->_depth == 0) { 979 _C->_type_verify->_cache.trunc_to(0); 980 } 981 } 982 983 const Type* meet(const Type* t1, const Type* t2) const { 984 return _C->_type_verify->meet(t1, t2); 985 } 986 987 void add(const Type* t1, const Type* t2, const Type* res) const { 988 _C->_type_verify->add(t1, t2, res); 989 } 990 }; 991 992 void Type::check_symmetrical(const Type* t, const Type* mt, const VerifyMeet& verify) const { 993 Compile* C = Compile::current(); 994 const Type* mt2 = verify.meet(t, this); 995 996 // Verify that: 997 // this meet t == t meet this 998 if (mt != mt2) { 999 tty->print_cr("=== Meet Not Commutative ==="); 1000 tty->print("t = "); t->dump(); tty->cr(); 1001 tty->print("this = "); dump(); tty->cr(); 1002 tty->print("t meet this = "); mt2->dump(); tty->cr(); 1003 tty->print("this meet t = "); mt->dump(); tty->cr(); 1004 fatal("meet not commutative"); 1005 } 1006 const Type* dual_join = mt->_dual; 1007 const Type* t2t = verify.meet(dual_join,t->_dual); 1008 const Type* t2this = verify.meet(dual_join,this->_dual); 1009 1010 // Interface meet Oop is Not Symmetric: 1011 // Interface:AnyNull meet Oop:AnyNull == Interface:AnyNull 1012 // Interface:NotNull meet Oop:NotNull == java/lang/Object:NotNull 1013 1014 // Verify that: 1015 // !(t meet this) meet !t == 1016 // (!t join !this) meet !t == !t 1017 // and 1018 // !(t meet this) meet !this == 1019 // (!t join !this) meet !this == !this 1020 if (t2t != t->_dual || t2this != this->_dual) { 1021 tty->print_cr("=== Meet Not Symmetric ==="); 1022 tty->print("t = "); t->dump(); tty->cr(); 1023 tty->print("this= "); dump(); tty->cr(); 1024 tty->print("mt=(t meet this)= "); mt->dump(); tty->cr(); 1025 1026 tty->print("t_dual= "); t->_dual->dump(); tty->cr(); 1027 tty->print("this_dual= "); _dual->dump(); tty->cr(); 1028 tty->print("mt_dual= "); mt->_dual->dump(); tty->cr(); 1029 1030 tty->print("mt_dual meet t_dual= "); t2t ->dump(); tty->cr(); 1031 tty->print("mt_dual meet this_dual= "); t2this ->dump(); tty->cr(); 1032 1033 fatal("meet not symmetric"); 1034 } 1035 } 1036 #endif 1037 1038 //------------------------------meet------------------------------------------- 1039 // Compute the MEET of two types. NOT virtual. It enforces that meet is 1040 // commutative and the lattice is symmetric. 1041 const Type *Type::meet_helper(const Type *t, bool include_speculative) const { 1042 if (isa_narrowoop() && t->isa_narrowoop()) { 1043 const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative); 1044 return result->make_narrowoop(); 1045 } 1046 if (isa_narrowklass() && t->isa_narrowklass()) { 1047 const Type* result = make_ptr()->meet_helper(t->make_ptr(), include_speculative); 1048 return result->make_narrowklass(); 1049 } 1050 1051 #ifdef ASSERT 1052 Compile* C = Compile::current(); 1053 VerifyMeet verify(C); 1054 #endif 1055 1056 const Type *this_t = maybe_remove_speculative(include_speculative); 1057 t = t->maybe_remove_speculative(include_speculative); 1058 1059 const Type *mt = this_t->xmeet(t); 1060 #ifdef ASSERT 1061 verify.add(this_t, t, mt); 1062 if (isa_narrowoop() || t->isa_narrowoop()) { 1063 return mt; 1064 } 1065 if (isa_narrowklass() || t->isa_narrowklass()) { 1066 return mt; 1067 } 1068 this_t->check_symmetrical(t, mt, verify); 1069 const Type *mt_dual = verify.meet(this_t->_dual, t->_dual); 1070 this_t->_dual->check_symmetrical(t->_dual, mt_dual, verify); 1071 #endif 1072 return mt; 1073 } 1074 1075 //------------------------------xmeet------------------------------------------ 1076 // Compute the MEET of two types. It returns a new Type object. 1077 const Type *Type::xmeet( const Type *t ) const { 1078 // Perform a fast test for common case; meeting the same types together. 1079 if( this == t ) return this; // Meeting same type-rep? 1080 1081 // Meeting TOP with anything? 1082 if( _base == Top ) return t; 1083 1084 // Meeting BOTTOM with anything? 1085 if( _base == Bottom ) return BOTTOM; 1086 1087 // Current "this->_base" is one of: Bad, Multi, Control, Top, 1088 // Abio, Abstore, Floatxxx, Doublexxx, Bottom, lastype. 1089 switch (t->base()) { // Switch on original type 1090 1091 // Cut in half the number of cases I must handle. Only need cases for when 1092 // the given enum "t->type" is less than or equal to the local enum "type". 1093 case FloatCon: 1094 case DoubleCon: 1095 case Int: 1096 case Long: 1097 return t->xmeet(this); 1098 1099 case OopPtr: 1100 return t->xmeet(this); 1101 1102 case InstPtr: 1103 return t->xmeet(this); 1104 1105 case MetadataPtr: 1106 case KlassPtr: 1107 case InstKlassPtr: 1108 case AryKlassPtr: 1109 return t->xmeet(this); 1110 1111 case AryPtr: 1112 return t->xmeet(this); 1113 1114 case NarrowOop: 1115 return t->xmeet(this); 1116 1117 case NarrowKlass: 1118 return t->xmeet(this); 1119 1120 case Bad: // Type check 1121 default: // Bogus type not in lattice 1122 typerr(t); 1123 return Type::BOTTOM; 1124 1125 case Bottom: // Ye Olde Default 1126 return t; 1127 1128 case FloatTop: 1129 if( _base == FloatTop ) return this; 1130 case FloatBot: // Float 1131 if( _base == FloatBot || _base == FloatTop ) return FLOAT; 1132 if( _base == DoubleTop || _base == DoubleBot ) return Type::BOTTOM; 1133 typerr(t); 1134 return Type::BOTTOM; 1135 1136 case DoubleTop: 1137 if( _base == DoubleTop ) return this; 1138 case DoubleBot: // Double 1139 if( _base == DoubleBot || _base == DoubleTop ) return DOUBLE; 1140 if( _base == FloatTop || _base == FloatBot ) return Type::BOTTOM; 1141 typerr(t); 1142 return Type::BOTTOM; 1143 1144 // These next few cases must match exactly or it is a compile-time error. 1145 case Control: // Control of code 1146 case Abio: // State of world outside of program 1147 case Memory: 1148 if( _base == t->_base ) return this; 1149 typerr(t); 1150 return Type::BOTTOM; 1151 1152 case Top: // Top of the lattice 1153 return this; 1154 } 1155 1156 // The type is unchanged 1157 return this; 1158 } 1159 1160 //-----------------------------filter------------------------------------------ 1161 const Type *Type::filter_helper(const Type *kills, bool include_speculative) const { 1162 const Type* ft = join_helper(kills, include_speculative); 1163 if (ft->empty()) 1164 return Type::TOP; // Canonical empty value 1165 return ft; 1166 } 1167 1168 //------------------------------xdual------------------------------------------ 1169 const Type *Type::xdual() const { 1170 // Note: the base() accessor asserts the sanity of _base. 1171 assert(_type_info[base()].dual_type != Bad, "implement with v-call"); 1172 return new Type(_type_info[_base].dual_type); 1173 } 1174 1175 //------------------------------has_memory------------------------------------- 1176 bool Type::has_memory() const { 1177 Type::TYPES tx = base(); 1178 if (tx == Memory) return true; 1179 if (tx == Tuple) { 1180 const TypeTuple *t = is_tuple(); 1181 for (uint i=0; i < t->cnt(); i++) { 1182 tx = t->field_at(i)->base(); 1183 if (tx == Memory) return true; 1184 } 1185 } 1186 return false; 1187 } 1188 1189 #ifndef PRODUCT 1190 //------------------------------dump2------------------------------------------ 1191 void Type::dump2( Dict &d, uint depth, outputStream *st ) const { 1192 st->print("%s", _type_info[_base].msg); 1193 } 1194 1195 //------------------------------dump------------------------------------------- 1196 void Type::dump_on(outputStream *st) const { 1197 ResourceMark rm; 1198 Dict d(cmpkey,hashkey); // Stop recursive type dumping 1199 dump2(d,1, st); 1200 if (is_ptr_to_narrowoop()) { 1201 st->print(" [narrow]"); 1202 } else if (is_ptr_to_narrowklass()) { 1203 st->print(" [narrowklass]"); 1204 } 1205 } 1206 1207 //----------------------------------------------------------------------------- 1208 const char* Type::str(const Type* t) { 1209 stringStream ss; 1210 t->dump_on(&ss); 1211 return ss.as_string(); 1212 } 1213 #endif 1214 1215 //------------------------------singleton-------------------------------------- 1216 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 1217 // constants (Ldi nodes). Singletons are integer, float or double constants. 1218 bool Type::singleton(void) const { 1219 return _base == Top || _base == Half; 1220 } 1221 1222 //------------------------------empty------------------------------------------ 1223 // TRUE if Type is a type with no values, FALSE otherwise. 1224 bool Type::empty(void) const { 1225 switch (_base) { 1226 case DoubleTop: 1227 case FloatTop: 1228 case Top: 1229 return true; 1230 1231 case Half: 1232 case Abio: 1233 case Return_Address: 1234 case Memory: 1235 case Bottom: 1236 case FloatBot: 1237 case DoubleBot: 1238 return false; // never a singleton, therefore never empty 1239 1240 default: 1241 ShouldNotReachHere(); 1242 return false; 1243 } 1244 } 1245 1246 //------------------------------dump_stats------------------------------------- 1247 // Dump collected statistics to stderr 1248 #ifndef PRODUCT 1249 void Type::dump_stats() { 1250 tty->print("Types made: %d\n", type_dict()->Size()); 1251 } 1252 #endif 1253 1254 //------------------------------category--------------------------------------- 1255 #ifndef PRODUCT 1256 Type::Category Type::category() const { 1257 const TypeTuple* tuple; 1258 switch (base()) { 1259 case Type::Int: 1260 case Type::Long: 1261 case Type::Half: 1262 case Type::NarrowOop: 1263 case Type::NarrowKlass: 1264 case Type::Array: 1265 case Type::VectorA: 1266 case Type::VectorS: 1267 case Type::VectorD: 1268 case Type::VectorX: 1269 case Type::VectorY: 1270 case Type::VectorZ: 1271 case Type::VectorMask: 1272 case Type::AnyPtr: 1273 case Type::RawPtr: 1274 case Type::OopPtr: 1275 case Type::InstPtr: 1276 case Type::AryPtr: 1277 case Type::MetadataPtr: 1278 case Type::KlassPtr: 1279 case Type::InstKlassPtr: 1280 case Type::AryKlassPtr: 1281 case Type::Function: 1282 case Type::Return_Address: 1283 case Type::FloatTop: 1284 case Type::FloatCon: 1285 case Type::FloatBot: 1286 case Type::DoubleTop: 1287 case Type::DoubleCon: 1288 case Type::DoubleBot: 1289 return Category::Data; 1290 case Type::Memory: 1291 return Category::Memory; 1292 case Type::Control: 1293 return Category::Control; 1294 case Type::Top: 1295 case Type::Abio: 1296 case Type::Bottom: 1297 return Category::Other; 1298 case Type::Bad: 1299 case Type::lastype: 1300 return Category::Undef; 1301 case Type::Tuple: 1302 // Recursive case. Return CatMixed if the tuple contains types of 1303 // different categories (e.g. CallStaticJavaNode's type), or the specific 1304 // category if all types are of the same category (e.g. IfNode's type). 1305 tuple = is_tuple(); 1306 if (tuple->cnt() == 0) { 1307 return Category::Undef; 1308 } else { 1309 Category first = tuple->field_at(0)->category(); 1310 for (uint i = 1; i < tuple->cnt(); i++) { 1311 if (tuple->field_at(i)->category() != first) { 1312 return Category::Mixed; 1313 } 1314 } 1315 return first; 1316 } 1317 default: 1318 assert(false, "unmatched base type: all base types must be categorized"); 1319 } 1320 return Category::Undef; 1321 } 1322 1323 bool Type::has_category(Type::Category cat) const { 1324 if (category() == cat) { 1325 return true; 1326 } 1327 if (category() == Category::Mixed) { 1328 const TypeTuple* tuple = is_tuple(); 1329 for (uint i = 0; i < tuple->cnt(); i++) { 1330 if (tuple->field_at(i)->has_category(cat)) { 1331 return true; 1332 } 1333 } 1334 } 1335 return false; 1336 } 1337 #endif 1338 1339 //------------------------------typerr----------------------------------------- 1340 void Type::typerr( const Type *t ) const { 1341 #ifndef PRODUCT 1342 tty->print("\nError mixing types: "); 1343 dump(); 1344 tty->print(" and "); 1345 t->dump(); 1346 tty->print("\n"); 1347 #endif 1348 ShouldNotReachHere(); 1349 } 1350 1351 1352 //============================================================================= 1353 // Convenience common pre-built types. 1354 const TypeF *TypeF::MAX; // Floating point max 1355 const TypeF *TypeF::MIN; // Floating point min 1356 const TypeF *TypeF::ZERO; // Floating point zero 1357 const TypeF *TypeF::ONE; // Floating point one 1358 const TypeF *TypeF::POS_INF; // Floating point positive infinity 1359 const TypeF *TypeF::NEG_INF; // Floating point negative infinity 1360 1361 //------------------------------make------------------------------------------- 1362 // Create a float constant 1363 const TypeF *TypeF::make(float f) { 1364 return (TypeF*)(new TypeF(f))->hashcons(); 1365 } 1366 1367 //------------------------------meet------------------------------------------- 1368 // Compute the MEET of two types. It returns a new Type object. 1369 const Type *TypeF::xmeet( const Type *t ) const { 1370 // Perform a fast test for common case; meeting the same types together. 1371 if( this == t ) return this; // Meeting same type-rep? 1372 1373 // Current "this->_base" is FloatCon 1374 switch (t->base()) { // Switch on original type 1375 case AnyPtr: // Mixing with oops happens when javac 1376 case RawPtr: // reuses local variables 1377 case OopPtr: 1378 case InstPtr: 1379 case AryPtr: 1380 case MetadataPtr: 1381 case KlassPtr: 1382 case InstKlassPtr: 1383 case AryKlassPtr: 1384 case NarrowOop: 1385 case NarrowKlass: 1386 case Int: 1387 case Long: 1388 case DoubleTop: 1389 case DoubleCon: 1390 case DoubleBot: 1391 case Bottom: // Ye Olde Default 1392 return Type::BOTTOM; 1393 1394 case FloatBot: 1395 return t; 1396 1397 default: // All else is a mistake 1398 typerr(t); 1399 1400 case FloatCon: // Float-constant vs Float-constant? 1401 if( jint_cast(_f) != jint_cast(t->getf()) ) // unequal constants? 1402 // must compare bitwise as positive zero, negative zero and NaN have 1403 // all the same representation in C++ 1404 return FLOAT; // Return generic float 1405 // Equal constants 1406 case Top: 1407 case FloatTop: 1408 break; // Return the float constant 1409 } 1410 return this; // Return the float constant 1411 } 1412 1413 //------------------------------xdual------------------------------------------ 1414 // Dual: symmetric 1415 const Type *TypeF::xdual() const { 1416 return this; 1417 } 1418 1419 //------------------------------eq--------------------------------------------- 1420 // Structural equality check for Type representations 1421 bool TypeF::eq(const Type *t) const { 1422 // Bitwise comparison to distinguish between +/-0. These values must be treated 1423 // as different to be consistent with C1 and the interpreter. 1424 return (jint_cast(_f) == jint_cast(t->getf())); 1425 } 1426 1427 //------------------------------hash------------------------------------------- 1428 // Type-specific hashing function. 1429 uint TypeF::hash(void) const { 1430 return *(uint*)(&_f); 1431 } 1432 1433 //------------------------------is_finite-------------------------------------- 1434 // Has a finite value 1435 bool TypeF::is_finite() const { 1436 return g_isfinite(getf()) != 0; 1437 } 1438 1439 //------------------------------is_nan----------------------------------------- 1440 // Is not a number (NaN) 1441 bool TypeF::is_nan() const { 1442 return g_isnan(getf()) != 0; 1443 } 1444 1445 //------------------------------dump2------------------------------------------ 1446 // Dump float constant Type 1447 #ifndef PRODUCT 1448 void TypeF::dump2( Dict &d, uint depth, outputStream *st ) const { 1449 Type::dump2(d,depth, st); 1450 st->print("%f", _f); 1451 } 1452 #endif 1453 1454 //------------------------------singleton-------------------------------------- 1455 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 1456 // constants (Ldi nodes). Singletons are integer, float or double constants 1457 // or a single symbol. 1458 bool TypeF::singleton(void) const { 1459 return true; // Always a singleton 1460 } 1461 1462 bool TypeF::empty(void) const { 1463 return false; // always exactly a singleton 1464 } 1465 1466 //============================================================================= 1467 // Convenience common pre-built types. 1468 const TypeD *TypeD::MAX; // Floating point max 1469 const TypeD *TypeD::MIN; // Floating point min 1470 const TypeD *TypeD::ZERO; // Floating point zero 1471 const TypeD *TypeD::ONE; // Floating point one 1472 const TypeD *TypeD::POS_INF; // Floating point positive infinity 1473 const TypeD *TypeD::NEG_INF; // Floating point negative infinity 1474 1475 //------------------------------make------------------------------------------- 1476 const TypeD *TypeD::make(double d) { 1477 return (TypeD*)(new TypeD(d))->hashcons(); 1478 } 1479 1480 //------------------------------meet------------------------------------------- 1481 // Compute the MEET of two types. It returns a new Type object. 1482 const Type *TypeD::xmeet( const Type *t ) const { 1483 // Perform a fast test for common case; meeting the same types together. 1484 if( this == t ) return this; // Meeting same type-rep? 1485 1486 // Current "this->_base" is DoubleCon 1487 switch (t->base()) { // Switch on original type 1488 case AnyPtr: // Mixing with oops happens when javac 1489 case RawPtr: // reuses local variables 1490 case OopPtr: 1491 case InstPtr: 1492 case AryPtr: 1493 case MetadataPtr: 1494 case KlassPtr: 1495 case InstKlassPtr: 1496 case AryKlassPtr: 1497 case NarrowOop: 1498 case NarrowKlass: 1499 case Int: 1500 case Long: 1501 case FloatTop: 1502 case FloatCon: 1503 case FloatBot: 1504 case Bottom: // Ye Olde Default 1505 return Type::BOTTOM; 1506 1507 case DoubleBot: 1508 return t; 1509 1510 default: // All else is a mistake 1511 typerr(t); 1512 1513 case DoubleCon: // Double-constant vs Double-constant? 1514 if( jlong_cast(_d) != jlong_cast(t->getd()) ) // unequal constants? (see comment in TypeF::xmeet) 1515 return DOUBLE; // Return generic double 1516 case Top: 1517 case DoubleTop: 1518 break; 1519 } 1520 return this; // Return the double constant 1521 } 1522 1523 //------------------------------xdual------------------------------------------ 1524 // Dual: symmetric 1525 const Type *TypeD::xdual() const { 1526 return this; 1527 } 1528 1529 //------------------------------eq--------------------------------------------- 1530 // Structural equality check for Type representations 1531 bool TypeD::eq(const Type *t) const { 1532 // Bitwise comparison to distinguish between +/-0. These values must be treated 1533 // as different to be consistent with C1 and the interpreter. 1534 return (jlong_cast(_d) == jlong_cast(t->getd())); 1535 } 1536 1537 //------------------------------hash------------------------------------------- 1538 // Type-specific hashing function. 1539 uint TypeD::hash(void) const { 1540 return *(uint*)(&_d); 1541 } 1542 1543 //------------------------------is_finite-------------------------------------- 1544 // Has a finite value 1545 bool TypeD::is_finite() const { 1546 return g_isfinite(getd()) != 0; 1547 } 1548 1549 //------------------------------is_nan----------------------------------------- 1550 // Is not a number (NaN) 1551 bool TypeD::is_nan() const { 1552 return g_isnan(getd()) != 0; 1553 } 1554 1555 //------------------------------dump2------------------------------------------ 1556 // Dump double constant Type 1557 #ifndef PRODUCT 1558 void TypeD::dump2( Dict &d, uint depth, outputStream *st ) const { 1559 Type::dump2(d,depth,st); 1560 st->print("%f", _d); 1561 } 1562 #endif 1563 1564 //------------------------------singleton-------------------------------------- 1565 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 1566 // constants (Ldi nodes). Singletons are integer, float or double constants 1567 // or a single symbol. 1568 bool TypeD::singleton(void) const { 1569 return true; // Always a singleton 1570 } 1571 1572 bool TypeD::empty(void) const { 1573 return false; // always exactly a singleton 1574 } 1575 1576 const TypeInteger* TypeInteger::make(jlong lo, jlong hi, int w, BasicType bt) { 1577 if (bt == T_INT) { 1578 return TypeInt::make(checked_cast<jint>(lo), checked_cast<jint>(hi), w); 1579 } 1580 assert(bt == T_LONG, "basic type not an int or long"); 1581 return TypeLong::make(lo, hi, w); 1582 } 1583 1584 jlong TypeInteger::get_con_as_long(BasicType bt) const { 1585 if (bt == T_INT) { 1586 return is_int()->get_con(); 1587 } 1588 assert(bt == T_LONG, "basic type not an int or long"); 1589 return is_long()->get_con(); 1590 } 1591 1592 const TypeInteger* TypeInteger::bottom(BasicType bt) { 1593 if (bt == T_INT) { 1594 return TypeInt::INT; 1595 } 1596 assert(bt == T_LONG, "basic type not an int or long"); 1597 return TypeLong::LONG; 1598 } 1599 1600 const TypeInteger* TypeInteger::zero(BasicType bt) { 1601 if (bt == T_INT) { 1602 return TypeInt::ZERO; 1603 } 1604 assert(bt == T_LONG, "basic type not an int or long"); 1605 return TypeLong::ZERO; 1606 } 1607 1608 const TypeInteger* TypeInteger::one(BasicType bt) { 1609 if (bt == T_INT) { 1610 return TypeInt::ONE; 1611 } 1612 assert(bt == T_LONG, "basic type not an int or long"); 1613 return TypeLong::ONE; 1614 } 1615 1616 const TypeInteger* TypeInteger::minus_1(BasicType bt) { 1617 if (bt == T_INT) { 1618 return TypeInt::MINUS_1; 1619 } 1620 assert(bt == T_LONG, "basic type not an int or long"); 1621 return TypeLong::MINUS_1; 1622 } 1623 1624 //============================================================================= 1625 // Convenience common pre-built types. 1626 const TypeInt *TypeInt::MAX; // INT_MAX 1627 const TypeInt *TypeInt::MIN; // INT_MIN 1628 const TypeInt *TypeInt::MINUS_1;// -1 1629 const TypeInt *TypeInt::ZERO; // 0 1630 const TypeInt *TypeInt::ONE; // 1 1631 const TypeInt *TypeInt::BOOL; // 0 or 1, FALSE or TRUE. 1632 const TypeInt *TypeInt::CC; // -1,0 or 1, condition codes 1633 const TypeInt *TypeInt::CC_LT; // [-1] == MINUS_1 1634 const TypeInt *TypeInt::CC_GT; // [1] == ONE 1635 const TypeInt *TypeInt::CC_EQ; // [0] == ZERO 1636 const TypeInt *TypeInt::CC_LE; // [-1,0] 1637 const TypeInt *TypeInt::CC_GE; // [0,1] == BOOL (!) 1638 const TypeInt *TypeInt::BYTE; // Bytes, -128 to 127 1639 const TypeInt *TypeInt::UBYTE; // Unsigned Bytes, 0 to 255 1640 const TypeInt *TypeInt::CHAR; // Java chars, 0-65535 1641 const TypeInt *TypeInt::SHORT; // Java shorts, -32768-32767 1642 const TypeInt *TypeInt::POS; // Positive 32-bit integers or zero 1643 const TypeInt *TypeInt::POS1; // Positive 32-bit integers 1644 const TypeInt *TypeInt::INT; // 32-bit integers 1645 const TypeInt *TypeInt::SYMINT; // symmetric range [-max_jint..max_jint] 1646 const TypeInt *TypeInt::TYPE_DOMAIN; // alias for TypeInt::INT 1647 1648 //------------------------------TypeInt---------------------------------------- 1649 TypeInt::TypeInt( jint lo, jint hi, int w ) : TypeInteger(Int, w), _lo(lo), _hi(hi) { 1650 } 1651 1652 //------------------------------make------------------------------------------- 1653 const TypeInt *TypeInt::make( jint lo ) { 1654 return (TypeInt*)(new TypeInt(lo,lo,WidenMin))->hashcons(); 1655 } 1656 1657 static int normalize_int_widen( jint lo, jint hi, int w ) { 1658 // Certain normalizations keep us sane when comparing types. 1659 // The 'SMALLINT' covers constants and also CC and its relatives. 1660 if (lo <= hi) { 1661 if (((juint)hi - lo) <= SMALLINT) w = Type::WidenMin; 1662 if (((juint)hi - lo) >= max_juint) w = Type::WidenMax; // TypeInt::INT 1663 } else { 1664 if (((juint)lo - hi) <= SMALLINT) w = Type::WidenMin; 1665 if (((juint)lo - hi) >= max_juint) w = Type::WidenMin; // dual TypeInt::INT 1666 } 1667 return w; 1668 } 1669 1670 const TypeInt *TypeInt::make( jint lo, jint hi, int w ) { 1671 w = normalize_int_widen(lo, hi, w); 1672 return (TypeInt*)(new TypeInt(lo,hi,w))->hashcons(); 1673 } 1674 1675 //------------------------------meet------------------------------------------- 1676 // Compute the MEET of two types. It returns a new Type representation object 1677 // with reference count equal to the number of Types pointing at it. 1678 // Caller should wrap a Types around it. 1679 const Type *TypeInt::xmeet( const Type *t ) const { 1680 // Perform a fast test for common case; meeting the same types together. 1681 if( this == t ) return this; // Meeting same type? 1682 1683 // Currently "this->_base" is a TypeInt 1684 switch (t->base()) { // Switch on original type 1685 case AnyPtr: // Mixing with oops happens when javac 1686 case RawPtr: // reuses local variables 1687 case OopPtr: 1688 case InstPtr: 1689 case AryPtr: 1690 case MetadataPtr: 1691 case KlassPtr: 1692 case InstKlassPtr: 1693 case AryKlassPtr: 1694 case NarrowOop: 1695 case NarrowKlass: 1696 case Long: 1697 case FloatTop: 1698 case FloatCon: 1699 case FloatBot: 1700 case DoubleTop: 1701 case DoubleCon: 1702 case DoubleBot: 1703 case Bottom: // Ye Olde Default 1704 return Type::BOTTOM; 1705 default: // All else is a mistake 1706 typerr(t); 1707 case Top: // No change 1708 return this; 1709 case Int: // Int vs Int? 1710 break; 1711 } 1712 1713 // Expand covered set 1714 const TypeInt *r = t->is_int(); 1715 return make( MIN2(_lo,r->_lo), MAX2(_hi,r->_hi), MAX2(_widen,r->_widen) ); 1716 } 1717 1718 //------------------------------xdual------------------------------------------ 1719 // Dual: reverse hi & lo; flip widen 1720 const Type *TypeInt::xdual() const { 1721 int w = normalize_int_widen(_hi,_lo, WidenMax-_widen); 1722 return new TypeInt(_hi,_lo,w); 1723 } 1724 1725 //------------------------------widen------------------------------------------ 1726 // Only happens for optimistic top-down optimizations. 1727 const Type *TypeInt::widen( const Type *old, const Type* limit ) const { 1728 // Coming from TOP or such; no widening 1729 if( old->base() != Int ) return this; 1730 const TypeInt *ot = old->is_int(); 1731 1732 // If new guy is equal to old guy, no widening 1733 if( _lo == ot->_lo && _hi == ot->_hi ) 1734 return old; 1735 1736 // If new guy contains old, then we widened 1737 if( _lo <= ot->_lo && _hi >= ot->_hi ) { 1738 // New contains old 1739 // If new guy is already wider than old, no widening 1740 if( _widen > ot->_widen ) return this; 1741 // If old guy was a constant, do not bother 1742 if (ot->_lo == ot->_hi) return this; 1743 // Now widen new guy. 1744 // Check for widening too far 1745 if (_widen == WidenMax) { 1746 int max = max_jint; 1747 int min = min_jint; 1748 if (limit->isa_int()) { 1749 max = limit->is_int()->_hi; 1750 min = limit->is_int()->_lo; 1751 } 1752 if (min < _lo && _hi < max) { 1753 // If neither endpoint is extremal yet, push out the endpoint 1754 // which is closer to its respective limit. 1755 if (_lo >= 0 || // easy common case 1756 ((juint)_lo - min) >= ((juint)max - _hi)) { 1757 // Try to widen to an unsigned range type of 31 bits: 1758 return make(_lo, max, WidenMax); 1759 } else { 1760 return make(min, _hi, WidenMax); 1761 } 1762 } 1763 return TypeInt::INT; 1764 } 1765 // Returned widened new guy 1766 return make(_lo,_hi,_widen+1); 1767 } 1768 1769 // If old guy contains new, then we probably widened too far & dropped to 1770 // bottom. Return the wider fellow. 1771 if ( ot->_lo <= _lo && ot->_hi >= _hi ) 1772 return old; 1773 1774 //fatal("Integer value range is not subset"); 1775 //return this; 1776 return TypeInt::INT; 1777 } 1778 1779 //------------------------------narrow--------------------------------------- 1780 // Only happens for pessimistic optimizations. 1781 const Type *TypeInt::narrow( const Type *old ) const { 1782 if (_lo >= _hi) return this; // already narrow enough 1783 if (old == nullptr) return this; 1784 const TypeInt* ot = old->isa_int(); 1785 if (ot == nullptr) return this; 1786 jint olo = ot->_lo; 1787 jint ohi = ot->_hi; 1788 1789 // If new guy is equal to old guy, no narrowing 1790 if (_lo == olo && _hi == ohi) return old; 1791 1792 // If old guy was maximum range, allow the narrowing 1793 if (olo == min_jint && ohi == max_jint) return this; 1794 1795 if (_lo < olo || _hi > ohi) 1796 return this; // doesn't narrow; pretty weird 1797 1798 // The new type narrows the old type, so look for a "death march". 1799 // See comments on PhaseTransform::saturate. 1800 juint nrange = (juint)_hi - _lo; 1801 juint orange = (juint)ohi - olo; 1802 if (nrange < max_juint - 1 && nrange > (orange >> 1) + (SMALLINT*2)) { 1803 // Use the new type only if the range shrinks a lot. 1804 // We do not want the optimizer computing 2^31 point by point. 1805 return old; 1806 } 1807 1808 return this; 1809 } 1810 1811 //-----------------------------filter------------------------------------------ 1812 const Type *TypeInt::filter_helper(const Type *kills, bool include_speculative) const { 1813 const TypeInt* ft = join_helper(kills, include_speculative)->isa_int(); 1814 if (ft == nullptr || ft->empty()) 1815 return Type::TOP; // Canonical empty value 1816 if (ft->_widen < this->_widen) { 1817 // Do not allow the value of kill->_widen to affect the outcome. 1818 // The widen bits must be allowed to run freely through the graph. 1819 ft = TypeInt::make(ft->_lo, ft->_hi, this->_widen); 1820 } 1821 return ft; 1822 } 1823 1824 //------------------------------eq--------------------------------------------- 1825 // Structural equality check for Type representations 1826 bool TypeInt::eq( const Type *t ) const { 1827 const TypeInt *r = t->is_int(); // Handy access 1828 return r->_lo == _lo && r->_hi == _hi && r->_widen == _widen; 1829 } 1830 1831 //------------------------------hash------------------------------------------- 1832 // Type-specific hashing function. 1833 uint TypeInt::hash(void) const { 1834 return (uint)_lo + (uint)_hi + (uint)_widen + (uint)Type::Int; 1835 } 1836 1837 //------------------------------is_finite-------------------------------------- 1838 // Has a finite value 1839 bool TypeInt::is_finite() const { 1840 return true; 1841 } 1842 1843 //------------------------------dump2------------------------------------------ 1844 // Dump TypeInt 1845 #ifndef PRODUCT 1846 static const char* intname(char* buf, size_t buf_size, jint n) { 1847 if (n == min_jint) 1848 return "min"; 1849 else if (n < min_jint + 10000) 1850 os::snprintf_checked(buf, buf_size, "min+" INT32_FORMAT, n - min_jint); 1851 else if (n == max_jint) 1852 return "max"; 1853 else if (n > max_jint - 10000) 1854 os::snprintf_checked(buf, buf_size, "max-" INT32_FORMAT, max_jint - n); 1855 else 1856 os::snprintf_checked(buf, buf_size, INT32_FORMAT, n); 1857 return buf; 1858 } 1859 1860 void TypeInt::dump2( Dict &d, uint depth, outputStream *st ) const { 1861 char buf[40], buf2[40]; 1862 if (_lo == min_jint && _hi == max_jint) 1863 st->print("int"); 1864 else if (is_con()) 1865 st->print("int:%s", intname(buf, sizeof(buf), get_con())); 1866 else if (_lo == BOOL->_lo && _hi == BOOL->_hi) 1867 st->print("bool"); 1868 else if (_lo == BYTE->_lo && _hi == BYTE->_hi) 1869 st->print("byte"); 1870 else if (_lo == CHAR->_lo && _hi == CHAR->_hi) 1871 st->print("char"); 1872 else if (_lo == SHORT->_lo && _hi == SHORT->_hi) 1873 st->print("short"); 1874 else if (_hi == max_jint) 1875 st->print("int:>=%s", intname(buf, sizeof(buf), _lo)); 1876 else if (_lo == min_jint) 1877 st->print("int:<=%s", intname(buf, sizeof(buf), _hi)); 1878 else 1879 st->print("int:%s..%s", intname(buf, sizeof(buf), _lo), intname(buf2, sizeof(buf2), _hi)); 1880 1881 if (_widen != 0 && this != TypeInt::INT) 1882 st->print(":%.*s", _widen, "wwww"); 1883 } 1884 #endif 1885 1886 //------------------------------singleton-------------------------------------- 1887 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 1888 // constants. 1889 bool TypeInt::singleton(void) const { 1890 return _lo >= _hi; 1891 } 1892 1893 bool TypeInt::empty(void) const { 1894 return _lo > _hi; 1895 } 1896 1897 //============================================================================= 1898 // Convenience common pre-built types. 1899 const TypeLong *TypeLong::MAX; 1900 const TypeLong *TypeLong::MIN; 1901 const TypeLong *TypeLong::MINUS_1;// -1 1902 const TypeLong *TypeLong::ZERO; // 0 1903 const TypeLong *TypeLong::ONE; // 1 1904 const TypeLong *TypeLong::POS; // >=0 1905 const TypeLong *TypeLong::LONG; // 64-bit integers 1906 const TypeLong *TypeLong::INT; // 32-bit subrange 1907 const TypeLong *TypeLong::UINT; // 32-bit unsigned subrange 1908 const TypeLong *TypeLong::TYPE_DOMAIN; // alias for TypeLong::LONG 1909 1910 //------------------------------TypeLong--------------------------------------- 1911 TypeLong::TypeLong(jlong lo, jlong hi, int w) : TypeInteger(Long, w), _lo(lo), _hi(hi) { 1912 } 1913 1914 //------------------------------make------------------------------------------- 1915 const TypeLong *TypeLong::make( jlong lo ) { 1916 return (TypeLong*)(new TypeLong(lo,lo,WidenMin))->hashcons(); 1917 } 1918 1919 static int normalize_long_widen( jlong lo, jlong hi, int w ) { 1920 // Certain normalizations keep us sane when comparing types. 1921 // The 'SMALLINT' covers constants. 1922 if (lo <= hi) { 1923 if (((julong)hi - lo) <= SMALLINT) w = Type::WidenMin; 1924 if (((julong)hi - lo) >= max_julong) w = Type::WidenMax; // TypeLong::LONG 1925 } else { 1926 if (((julong)lo - hi) <= SMALLINT) w = Type::WidenMin; 1927 if (((julong)lo - hi) >= max_julong) w = Type::WidenMin; // dual TypeLong::LONG 1928 } 1929 return w; 1930 } 1931 1932 const TypeLong *TypeLong::make( jlong lo, jlong hi, int w ) { 1933 w = normalize_long_widen(lo, hi, w); 1934 return (TypeLong*)(new TypeLong(lo,hi,w))->hashcons(); 1935 } 1936 1937 1938 //------------------------------meet------------------------------------------- 1939 // Compute the MEET of two types. It returns a new Type representation object 1940 // with reference count equal to the number of Types pointing at it. 1941 // Caller should wrap a Types around it. 1942 const Type *TypeLong::xmeet( const Type *t ) const { 1943 // Perform a fast test for common case; meeting the same types together. 1944 if( this == t ) return this; // Meeting same type? 1945 1946 // Currently "this->_base" is a TypeLong 1947 switch (t->base()) { // Switch on original type 1948 case AnyPtr: // Mixing with oops happens when javac 1949 case RawPtr: // reuses local variables 1950 case OopPtr: 1951 case InstPtr: 1952 case AryPtr: 1953 case MetadataPtr: 1954 case KlassPtr: 1955 case InstKlassPtr: 1956 case AryKlassPtr: 1957 case NarrowOop: 1958 case NarrowKlass: 1959 case Int: 1960 case FloatTop: 1961 case FloatCon: 1962 case FloatBot: 1963 case DoubleTop: 1964 case DoubleCon: 1965 case DoubleBot: 1966 case Bottom: // Ye Olde Default 1967 return Type::BOTTOM; 1968 default: // All else is a mistake 1969 typerr(t); 1970 case Top: // No change 1971 return this; 1972 case Long: // Long vs Long? 1973 break; 1974 } 1975 1976 // Expand covered set 1977 const TypeLong *r = t->is_long(); // Turn into a TypeLong 1978 return make( MIN2(_lo,r->_lo), MAX2(_hi,r->_hi), MAX2(_widen,r->_widen) ); 1979 } 1980 1981 //------------------------------xdual------------------------------------------ 1982 // Dual: reverse hi & lo; flip widen 1983 const Type *TypeLong::xdual() const { 1984 int w = normalize_long_widen(_hi,_lo, WidenMax-_widen); 1985 return new TypeLong(_hi,_lo,w); 1986 } 1987 1988 //------------------------------widen------------------------------------------ 1989 // Only happens for optimistic top-down optimizations. 1990 const Type *TypeLong::widen( const Type *old, const Type* limit ) const { 1991 // Coming from TOP or such; no widening 1992 if( old->base() != Long ) return this; 1993 const TypeLong *ot = old->is_long(); 1994 1995 // If new guy is equal to old guy, no widening 1996 if( _lo == ot->_lo && _hi == ot->_hi ) 1997 return old; 1998 1999 // If new guy contains old, then we widened 2000 if( _lo <= ot->_lo && _hi >= ot->_hi ) { 2001 // New contains old 2002 // If new guy is already wider than old, no widening 2003 if( _widen > ot->_widen ) return this; 2004 // If old guy was a constant, do not bother 2005 if (ot->_lo == ot->_hi) return this; 2006 // Now widen new guy. 2007 // Check for widening too far 2008 if (_widen == WidenMax) { 2009 jlong max = max_jlong; 2010 jlong min = min_jlong; 2011 if (limit->isa_long()) { 2012 max = limit->is_long()->_hi; 2013 min = limit->is_long()->_lo; 2014 } 2015 if (min < _lo && _hi < max) { 2016 // If neither endpoint is extremal yet, push out the endpoint 2017 // which is closer to its respective limit. 2018 if (_lo >= 0 || // easy common case 2019 ((julong)_lo - min) >= ((julong)max - _hi)) { 2020 // Try to widen to an unsigned range type of 32/63 bits: 2021 if (max >= max_juint && _hi < max_juint) 2022 return make(_lo, max_juint, WidenMax); 2023 else 2024 return make(_lo, max, WidenMax); 2025 } else { 2026 return make(min, _hi, WidenMax); 2027 } 2028 } 2029 return TypeLong::LONG; 2030 } 2031 // Returned widened new guy 2032 return make(_lo,_hi,_widen+1); 2033 } 2034 2035 // If old guy contains new, then we probably widened too far & dropped to 2036 // bottom. Return the wider fellow. 2037 if ( ot->_lo <= _lo && ot->_hi >= _hi ) 2038 return old; 2039 2040 // fatal("Long value range is not subset"); 2041 // return this; 2042 return TypeLong::LONG; 2043 } 2044 2045 //------------------------------narrow---------------------------------------- 2046 // Only happens for pessimistic optimizations. 2047 const Type *TypeLong::narrow( const Type *old ) const { 2048 if (_lo >= _hi) return this; // already narrow enough 2049 if (old == nullptr) return this; 2050 const TypeLong* ot = old->isa_long(); 2051 if (ot == nullptr) return this; 2052 jlong olo = ot->_lo; 2053 jlong ohi = ot->_hi; 2054 2055 // If new guy is equal to old guy, no narrowing 2056 if (_lo == olo && _hi == ohi) return old; 2057 2058 // If old guy was maximum range, allow the narrowing 2059 if (olo == min_jlong && ohi == max_jlong) return this; 2060 2061 if (_lo < olo || _hi > ohi) 2062 return this; // doesn't narrow; pretty weird 2063 2064 // The new type narrows the old type, so look for a "death march". 2065 // See comments on PhaseTransform::saturate. 2066 julong nrange = (julong)_hi - _lo; 2067 julong orange = (julong)ohi - olo; 2068 if (nrange < max_julong - 1 && nrange > (orange >> 1) + (SMALLINT*2)) { 2069 // Use the new type only if the range shrinks a lot. 2070 // We do not want the optimizer computing 2^31 point by point. 2071 return old; 2072 } 2073 2074 return this; 2075 } 2076 2077 //-----------------------------filter------------------------------------------ 2078 const Type *TypeLong::filter_helper(const Type *kills, bool include_speculative) const { 2079 const TypeLong* ft = join_helper(kills, include_speculative)->isa_long(); 2080 if (ft == nullptr || ft->empty()) 2081 return Type::TOP; // Canonical empty value 2082 if (ft->_widen < this->_widen) { 2083 // Do not allow the value of kill->_widen to affect the outcome. 2084 // The widen bits must be allowed to run freely through the graph. 2085 ft = TypeLong::make(ft->_lo, ft->_hi, this->_widen); 2086 } 2087 return ft; 2088 } 2089 2090 //------------------------------eq--------------------------------------------- 2091 // Structural equality check for Type representations 2092 bool TypeLong::eq( const Type *t ) const { 2093 const TypeLong *r = t->is_long(); // Handy access 2094 return r->_lo == _lo && r->_hi == _hi && r->_widen == _widen; 2095 } 2096 2097 //------------------------------hash------------------------------------------- 2098 // Type-specific hashing function. 2099 uint TypeLong::hash(void) const { 2100 return (uint)_lo + (uint)_hi + (uint)_widen + (uint)Type::Long; 2101 } 2102 2103 //------------------------------is_finite-------------------------------------- 2104 // Has a finite value 2105 bool TypeLong::is_finite() const { 2106 return true; 2107 } 2108 2109 //------------------------------dump2------------------------------------------ 2110 // Dump TypeLong 2111 #ifndef PRODUCT 2112 static const char* longnamenear(jlong x, const char* xname, char* buf, size_t buf_size, jlong n) { 2113 if (n > x) { 2114 if (n >= x + 10000) return nullptr; 2115 os::snprintf_checked(buf, buf_size, "%s+" JLONG_FORMAT, xname, n - x); 2116 } else if (n < x) { 2117 if (n <= x - 10000) return nullptr; 2118 os::snprintf_checked(buf, buf_size, "%s-" JLONG_FORMAT, xname, x - n); 2119 } else { 2120 return xname; 2121 } 2122 return buf; 2123 } 2124 2125 static const char* longname(char* buf, size_t buf_size, jlong n) { 2126 const char* str; 2127 if (n == min_jlong) 2128 return "min"; 2129 else if (n < min_jlong + 10000) 2130 os::snprintf_checked(buf, buf_size, "min+" JLONG_FORMAT, n - min_jlong); 2131 else if (n == max_jlong) 2132 return "max"; 2133 else if (n > max_jlong - 10000) 2134 os::snprintf_checked(buf, buf_size, "max-" JLONG_FORMAT, max_jlong - n); 2135 else if ((str = longnamenear(max_juint, "maxuint", buf, buf_size, n)) != nullptr) 2136 return str; 2137 else if ((str = longnamenear(max_jint, "maxint", buf, buf_size, n)) != nullptr) 2138 return str; 2139 else if ((str = longnamenear(min_jint, "minint", buf, buf_size, n)) != nullptr) 2140 return str; 2141 else 2142 os::snprintf_checked(buf, buf_size, JLONG_FORMAT, n); 2143 return buf; 2144 } 2145 2146 void TypeLong::dump2( Dict &d, uint depth, outputStream *st ) const { 2147 char buf[80], buf2[80]; 2148 if (_lo == min_jlong && _hi == max_jlong) 2149 st->print("long"); 2150 else if (is_con()) 2151 st->print("long:%s", longname(buf, sizeof(buf), get_con())); 2152 else if (_hi == max_jlong) 2153 st->print("long:>=%s", longname(buf, sizeof(buf), _lo)); 2154 else if (_lo == min_jlong) 2155 st->print("long:<=%s", longname(buf, sizeof(buf), _hi)); 2156 else 2157 st->print("long:%s..%s", longname(buf, sizeof(buf), _lo), longname(buf2,sizeof(buf2), _hi)); 2158 2159 if (_widen != 0 && this != TypeLong::LONG) 2160 st->print(":%.*s", _widen, "wwww"); 2161 } 2162 #endif 2163 2164 //------------------------------singleton-------------------------------------- 2165 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 2166 // constants 2167 bool TypeLong::singleton(void) const { 2168 return _lo >= _hi; 2169 } 2170 2171 bool TypeLong::empty(void) const { 2172 return _lo > _hi; 2173 } 2174 2175 //============================================================================= 2176 // Convenience common pre-built types. 2177 const TypeTuple *TypeTuple::IFBOTH; // Return both arms of IF as reachable 2178 const TypeTuple *TypeTuple::IFFALSE; 2179 const TypeTuple *TypeTuple::IFTRUE; 2180 const TypeTuple *TypeTuple::IFNEITHER; 2181 const TypeTuple *TypeTuple::LOOPBODY; 2182 const TypeTuple *TypeTuple::MEMBAR; 2183 const TypeTuple *TypeTuple::STORECONDITIONAL; 2184 const TypeTuple *TypeTuple::START_I2C; 2185 const TypeTuple *TypeTuple::INT_PAIR; 2186 const TypeTuple *TypeTuple::LONG_PAIR; 2187 const TypeTuple *TypeTuple::INT_CC_PAIR; 2188 const TypeTuple *TypeTuple::LONG_CC_PAIR; 2189 2190 static void collect_inline_fields(ciInlineKlass* vk, const Type** field_array, uint& pos) { 2191 for (int j = 0; j < vk->nof_nonstatic_fields(); j++) { 2192 ciField* field = vk->nonstatic_field_at(j); 2193 // TODO 8325106 The field could be null free, right? Shouldn't we set the type to null-free here? 2194 BasicType bt = field->type()->basic_type(); 2195 const Type* ft = Type::get_const_type(field->type()); 2196 field_array[pos++] = ft; 2197 if (type2size[bt] == 2) { 2198 field_array[pos++] = Type::HALF; 2199 } 2200 } 2201 } 2202 2203 //------------------------------make------------------------------------------- 2204 // Make a TypeTuple from the range of a method signature 2205 const TypeTuple *TypeTuple::make_range(ciSignature* sig, InterfaceHandling interface_handling, bool ret_vt_fields) { 2206 ciType* return_type = sig->return_type(); 2207 uint arg_cnt = return_type->size(); 2208 if (ret_vt_fields) { 2209 arg_cnt = return_type->as_inline_klass()->inline_arg_slots() + 1; 2210 // InlineTypeNode::IsInit field used for null checking 2211 arg_cnt++; 2212 } 2213 const Type **field_array = fields(arg_cnt); 2214 switch (return_type->basic_type()) { 2215 case T_LONG: 2216 field_array[TypeFunc::Parms] = TypeLong::LONG; 2217 field_array[TypeFunc::Parms+1] = Type::HALF; 2218 break; 2219 case T_DOUBLE: 2220 field_array[TypeFunc::Parms] = Type::DOUBLE; 2221 field_array[TypeFunc::Parms+1] = Type::HALF; 2222 break; 2223 case T_OBJECT: 2224 if (return_type->is_inlinetype() && ret_vt_fields) { 2225 uint pos = TypeFunc::Parms; 2226 field_array[pos++] = get_const_type(return_type); // Oop might be null when returning as fields 2227 collect_inline_fields(return_type->as_inline_klass(), field_array, pos); 2228 // InlineTypeNode::IsInit field used for null checking 2229 field_array[pos++] = get_const_basic_type(T_BOOLEAN); 2230 break; 2231 } else { 2232 field_array[TypeFunc::Parms] = get_const_type(return_type, interface_handling)->join_speculative(TypePtr::BOTTOM); 2233 } 2234 break; 2235 case T_ARRAY: 2236 case T_BOOLEAN: 2237 case T_CHAR: 2238 case T_FLOAT: 2239 case T_BYTE: 2240 case T_SHORT: 2241 case T_INT: 2242 field_array[TypeFunc::Parms] = get_const_type(return_type, interface_handling); 2243 break; 2244 case T_VOID: 2245 break; 2246 default: 2247 ShouldNotReachHere(); 2248 } 2249 return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons(); 2250 } 2251 2252 // Make a TypeTuple from the domain of a method signature 2253 const TypeTuple *TypeTuple::make_domain(ciMethod* method, InterfaceHandling interface_handling, bool vt_fields_as_args) { 2254 ciSignature* sig = method->signature(); 2255 uint arg_cnt = sig->size() + (method->is_static() ? 0 : 1); 2256 if (vt_fields_as_args) { 2257 arg_cnt = 0; 2258 assert(method->get_sig_cc() != nullptr, "Should have scalarized signature"); 2259 for (ExtendedSignature sig_cc = ExtendedSignature(method->get_sig_cc(), SigEntryFilter()); !sig_cc.at_end(); ++sig_cc) { 2260 arg_cnt += type2size[(*sig_cc)._bt]; 2261 } 2262 } 2263 2264 uint pos = TypeFunc::Parms; 2265 const Type** field_array = fields(arg_cnt); 2266 if (!method->is_static()) { 2267 ciInstanceKlass* recv = method->holder(); 2268 if (vt_fields_as_args && recv->is_inlinetype() && recv->as_inline_klass()->can_be_passed_as_fields() && method->is_scalarized_arg(0)) { 2269 collect_inline_fields(recv->as_inline_klass(), field_array, pos); 2270 } else { 2271 field_array[pos++] = get_const_type(recv, interface_handling)->join_speculative(TypePtr::NOTNULL); 2272 } 2273 } 2274 2275 int i = 0; 2276 while (pos < TypeFunc::Parms + arg_cnt) { 2277 ciType* type = sig->type_at(i); 2278 BasicType bt = type->basic_type(); 2279 2280 switch (bt) { 2281 case T_LONG: 2282 field_array[pos++] = TypeLong::LONG; 2283 field_array[pos++] = Type::HALF; 2284 break; 2285 case T_DOUBLE: 2286 field_array[pos++] = Type::DOUBLE; 2287 field_array[pos++] = Type::HALF; 2288 break; 2289 case T_OBJECT: 2290 if (type->is_inlinetype() && vt_fields_as_args && method->is_scalarized_arg(i + (method->is_static() ? 0 : 1))) { 2291 // InlineTypeNode::IsInit field used for null checking 2292 field_array[pos++] = get_const_basic_type(T_BOOLEAN); 2293 collect_inline_fields(type->as_inline_klass(), field_array, pos); 2294 } else { 2295 field_array[pos++] = get_const_type(type, interface_handling); 2296 } 2297 break; 2298 case T_ARRAY: 2299 case T_FLOAT: 2300 case T_INT: 2301 field_array[pos++] = get_const_type(type, interface_handling); 2302 break; 2303 case T_BOOLEAN: 2304 case T_CHAR: 2305 case T_BYTE: 2306 case T_SHORT: 2307 field_array[pos++] = TypeInt::INT; 2308 break; 2309 default: 2310 ShouldNotReachHere(); 2311 } 2312 i++; 2313 } 2314 assert(pos == TypeFunc::Parms + arg_cnt, "wrong number of arguments"); 2315 2316 return (TypeTuple*)(new TypeTuple(TypeFunc::Parms + arg_cnt, field_array))->hashcons(); 2317 } 2318 2319 const TypeTuple *TypeTuple::make( uint cnt, const Type **fields ) { 2320 return (TypeTuple*)(new TypeTuple(cnt,fields))->hashcons(); 2321 } 2322 2323 //------------------------------fields----------------------------------------- 2324 // Subroutine call type with space allocated for argument types 2325 // Memory for Control, I_O, Memory, FramePtr, and ReturnAdr is allocated implicitly 2326 const Type **TypeTuple::fields( uint arg_cnt ) { 2327 const Type **flds = (const Type **)(Compile::current()->type_arena()->AmallocWords((TypeFunc::Parms+arg_cnt)*sizeof(Type*) )); 2328 flds[TypeFunc::Control ] = Type::CONTROL; 2329 flds[TypeFunc::I_O ] = Type::ABIO; 2330 flds[TypeFunc::Memory ] = Type::MEMORY; 2331 flds[TypeFunc::FramePtr ] = TypeRawPtr::BOTTOM; 2332 flds[TypeFunc::ReturnAdr] = Type::RETURN_ADDRESS; 2333 2334 return flds; 2335 } 2336 2337 //------------------------------meet------------------------------------------- 2338 // Compute the MEET of two types. It returns a new Type object. 2339 const Type *TypeTuple::xmeet( const Type *t ) const { 2340 // Perform a fast test for common case; meeting the same types together. 2341 if( this == t ) return this; // Meeting same type-rep? 2342 2343 // Current "this->_base" is Tuple 2344 switch (t->base()) { // switch on original type 2345 2346 case Bottom: // Ye Olde Default 2347 return t; 2348 2349 default: // All else is a mistake 2350 typerr(t); 2351 2352 case Tuple: { // Meeting 2 signatures? 2353 const TypeTuple *x = t->is_tuple(); 2354 assert( _cnt == x->_cnt, "" ); 2355 const Type **fields = (const Type **)(Compile::current()->type_arena()->AmallocWords( _cnt*sizeof(Type*) )); 2356 for( uint i=0; i<_cnt; i++ ) 2357 fields[i] = field_at(i)->xmeet( x->field_at(i) ); 2358 return TypeTuple::make(_cnt,fields); 2359 } 2360 case Top: 2361 break; 2362 } 2363 return this; // Return the double constant 2364 } 2365 2366 //------------------------------xdual------------------------------------------ 2367 // Dual: compute field-by-field dual 2368 const Type *TypeTuple::xdual() const { 2369 const Type **fields = (const Type **)(Compile::current()->type_arena()->AmallocWords( _cnt*sizeof(Type*) )); 2370 for( uint i=0; i<_cnt; i++ ) 2371 fields[i] = _fields[i]->dual(); 2372 return new TypeTuple(_cnt,fields); 2373 } 2374 2375 //------------------------------eq--------------------------------------------- 2376 // Structural equality check for Type representations 2377 bool TypeTuple::eq( const Type *t ) const { 2378 const TypeTuple *s = (const TypeTuple *)t; 2379 if (_cnt != s->_cnt) return false; // Unequal field counts 2380 for (uint i = 0; i < _cnt; i++) 2381 if (field_at(i) != s->field_at(i)) // POINTER COMPARE! NO RECURSION! 2382 return false; // Missed 2383 return true; 2384 } 2385 2386 //------------------------------hash------------------------------------------- 2387 // Type-specific hashing function. 2388 uint TypeTuple::hash(void) const { 2389 uintptr_t sum = _cnt; 2390 for( uint i=0; i<_cnt; i++ ) 2391 sum += (uintptr_t)_fields[i]; // Hash on pointers directly 2392 return (uint)sum; 2393 } 2394 2395 //------------------------------dump2------------------------------------------ 2396 // Dump signature Type 2397 #ifndef PRODUCT 2398 void TypeTuple::dump2( Dict &d, uint depth, outputStream *st ) const { 2399 st->print("{"); 2400 if( !depth || d[this] ) { // Check for recursive print 2401 st->print("...}"); 2402 return; 2403 } 2404 d.Insert((void*)this, (void*)this); // Stop recursion 2405 if( _cnt ) { 2406 uint i; 2407 for( i=0; i<_cnt-1; i++ ) { 2408 st->print("%d:", i); 2409 _fields[i]->dump2(d, depth-1, st); 2410 st->print(", "); 2411 } 2412 st->print("%d:", i); 2413 _fields[i]->dump2(d, depth-1, st); 2414 } 2415 st->print("}"); 2416 } 2417 #endif 2418 2419 //------------------------------singleton-------------------------------------- 2420 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 2421 // constants (Ldi nodes). Singletons are integer, float or double constants 2422 // or a single symbol. 2423 bool TypeTuple::singleton(void) const { 2424 return false; // Never a singleton 2425 } 2426 2427 bool TypeTuple::empty(void) const { 2428 for( uint i=0; i<_cnt; i++ ) { 2429 if (_fields[i]->empty()) return true; 2430 } 2431 return false; 2432 } 2433 2434 //============================================================================= 2435 // Convenience common pre-built types. 2436 2437 inline const TypeInt* normalize_array_size(const TypeInt* size) { 2438 // Certain normalizations keep us sane when comparing types. 2439 // We do not want arrayOop variables to differ only by the wideness 2440 // of their index types. Pick minimum wideness, since that is the 2441 // forced wideness of small ranges anyway. 2442 if (size->_widen != Type::WidenMin) 2443 return TypeInt::make(size->_lo, size->_hi, Type::WidenMin); 2444 else 2445 return size; 2446 } 2447 2448 //------------------------------make------------------------------------------- 2449 const TypeAry* TypeAry::make(const Type* elem, const TypeInt* size, bool stable, 2450 bool flat, bool not_flat, bool not_null_free) { 2451 if (UseCompressedOops && elem->isa_oopptr()) { 2452 elem = elem->make_narrowoop(); 2453 } 2454 size = normalize_array_size(size); 2455 return (TypeAry*)(new TypeAry(elem, size, stable, flat, not_flat, not_null_free))->hashcons(); 2456 } 2457 2458 //------------------------------meet------------------------------------------- 2459 // Compute the MEET of two types. It returns a new Type object. 2460 const Type *TypeAry::xmeet( const Type *t ) const { 2461 // Perform a fast test for common case; meeting the same types together. 2462 if( this == t ) return this; // Meeting same type-rep? 2463 2464 // Current "this->_base" is Ary 2465 switch (t->base()) { // switch on original type 2466 2467 case Bottom: // Ye Olde Default 2468 return t; 2469 2470 default: // All else is a mistake 2471 typerr(t); 2472 2473 case Array: { // Meeting 2 arrays? 2474 const TypeAry *a = t->is_ary(); 2475 return TypeAry::make(_elem->meet_speculative(a->_elem), 2476 _size->xmeet(a->_size)->is_int(), 2477 _stable && a->_stable, 2478 _flat && a->_flat, 2479 _not_flat && a->_not_flat, 2480 _not_null_free && a->_not_null_free); 2481 } 2482 case Top: 2483 break; 2484 } 2485 return this; // Return the double constant 2486 } 2487 2488 //------------------------------xdual------------------------------------------ 2489 // Dual: compute field-by-field dual 2490 const Type *TypeAry::xdual() const { 2491 const TypeInt* size_dual = _size->dual()->is_int(); 2492 size_dual = normalize_array_size(size_dual); 2493 return new TypeAry(_elem->dual(), size_dual, !_stable, !_flat, !_not_flat, !_not_null_free); 2494 } 2495 2496 //------------------------------eq--------------------------------------------- 2497 // Structural equality check for Type representations 2498 bool TypeAry::eq( const Type *t ) const { 2499 const TypeAry *a = (const TypeAry*)t; 2500 return _elem == a->_elem && 2501 _stable == a->_stable && 2502 _size == a->_size && 2503 _flat == a->_flat && 2504 _not_flat == a->_not_flat && 2505 _not_null_free == a->_not_null_free; 2506 2507 } 2508 2509 //------------------------------hash------------------------------------------- 2510 // Type-specific hashing function. 2511 uint TypeAry::hash(void) const { 2512 return (uint)(uintptr_t)_elem + (uint)(uintptr_t)_size + (uint)(_stable ? 43 : 0) + 2513 (uint)(_flat ? 44 : 0) + (uint)(_not_flat ? 45 : 0) + (uint)(_not_null_free ? 46 : 0); 2514 } 2515 2516 /** 2517 * Return same type without a speculative part in the element 2518 */ 2519 const TypeAry* TypeAry::remove_speculative() const { 2520 return make(_elem->remove_speculative(), _size, _stable, _flat, _not_flat, _not_null_free); 2521 } 2522 2523 /** 2524 * Return same type with cleaned up speculative part of element 2525 */ 2526 const Type* TypeAry::cleanup_speculative() const { 2527 return make(_elem->cleanup_speculative(), _size, _stable, _flat, _not_flat, _not_null_free); 2528 } 2529 2530 /** 2531 * Return same type but with a different inline depth (used for speculation) 2532 * 2533 * @param depth depth to meet with 2534 */ 2535 const TypePtr* TypePtr::with_inline_depth(int depth) const { 2536 if (!UseInlineDepthForSpeculativeTypes) { 2537 return this; 2538 } 2539 return make(AnyPtr, _ptr, _offset, _speculative, depth); 2540 } 2541 2542 //------------------------------dump2------------------------------------------ 2543 #ifndef PRODUCT 2544 void TypeAry::dump2( Dict &d, uint depth, outputStream *st ) const { 2545 if (_stable) st->print("stable:"); 2546 if (_flat) st->print("flat:"); 2547 if (Verbose) { 2548 if (_not_flat) st->print("not flat:"); 2549 if (_not_null_free) st->print("not null free:"); 2550 } 2551 _elem->dump2(d, depth, st); 2552 st->print("["); 2553 _size->dump2(d, depth, st); 2554 st->print("]"); 2555 } 2556 #endif 2557 2558 //------------------------------singleton-------------------------------------- 2559 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 2560 // constants (Ldi nodes). Singletons are integer, float or double constants 2561 // or a single symbol. 2562 bool TypeAry::singleton(void) const { 2563 return false; // Never a singleton 2564 } 2565 2566 bool TypeAry::empty(void) const { 2567 return _elem->empty() || _size->empty(); 2568 } 2569 2570 //--------------------------ary_must_be_exact---------------------------------- 2571 bool TypeAry::ary_must_be_exact() const { 2572 // This logic looks at the element type of an array, and returns true 2573 // if the element type is either a primitive or a final instance class. 2574 // In such cases, an array built on this ary must have no subclasses. 2575 if (_elem == BOTTOM) return false; // general array not exact 2576 if (_elem == TOP ) return false; // inverted general array not exact 2577 const TypeOopPtr* toop = nullptr; 2578 if (UseCompressedOops && _elem->isa_narrowoop()) { 2579 toop = _elem->make_ptr()->isa_oopptr(); 2580 } else { 2581 toop = _elem->isa_oopptr(); 2582 } 2583 if (!toop) return true; // a primitive type, like int 2584 if (!toop->is_loaded()) return false; // unloaded class 2585 const TypeInstPtr* tinst; 2586 if (_elem->isa_narrowoop()) 2587 tinst = _elem->make_ptr()->isa_instptr(); 2588 else 2589 tinst = _elem->isa_instptr(); 2590 if (tinst) { 2591 if (tinst->instance_klass()->is_final()) { 2592 // TODO 8325106 Fix comment 2593 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 2594 if (tinst->is_inlinetypeptr() && (tinst->ptr() == TypePtr::BotPTR || tinst->ptr() == TypePtr::TopPTR)) { 2595 return false; 2596 } 2597 return true; 2598 } 2599 return false; 2600 } 2601 const TypeAryPtr* tap; 2602 if (_elem->isa_narrowoop()) 2603 tap = _elem->make_ptr()->isa_aryptr(); 2604 else 2605 tap = _elem->isa_aryptr(); 2606 if (tap) 2607 return tap->ary()->ary_must_be_exact(); 2608 return false; 2609 } 2610 2611 //==============================TypeVect======================================= 2612 // Convenience common pre-built types. 2613 const TypeVect *TypeVect::VECTA = nullptr; // vector length agnostic 2614 const TypeVect *TypeVect::VECTS = nullptr; // 32-bit vectors 2615 const TypeVect *TypeVect::VECTD = nullptr; // 64-bit vectors 2616 const TypeVect *TypeVect::VECTX = nullptr; // 128-bit vectors 2617 const TypeVect *TypeVect::VECTY = nullptr; // 256-bit vectors 2618 const TypeVect *TypeVect::VECTZ = nullptr; // 512-bit vectors 2619 const TypeVect *TypeVect::VECTMASK = nullptr; // predicate/mask vector 2620 2621 //------------------------------make------------------------------------------- 2622 const TypeVect* TypeVect::make(const Type *elem, uint length, bool is_mask) { 2623 if (is_mask) { 2624 return makemask(elem, length); 2625 } 2626 BasicType elem_bt = elem->array_element_basic_type(); 2627 assert(is_java_primitive(elem_bt), "only primitive types in vector"); 2628 assert(Matcher::vector_size_supported(elem_bt, length), "length in range"); 2629 int size = length * type2aelembytes(elem_bt); 2630 switch (Matcher::vector_ideal_reg(size)) { 2631 case Op_VecA: 2632 return (TypeVect*)(new TypeVectA(elem, length))->hashcons(); 2633 case Op_VecS: 2634 return (TypeVect*)(new TypeVectS(elem, length))->hashcons(); 2635 case Op_RegL: 2636 case Op_VecD: 2637 case Op_RegD: 2638 return (TypeVect*)(new TypeVectD(elem, length))->hashcons(); 2639 case Op_VecX: 2640 return (TypeVect*)(new TypeVectX(elem, length))->hashcons(); 2641 case Op_VecY: 2642 return (TypeVect*)(new TypeVectY(elem, length))->hashcons(); 2643 case Op_VecZ: 2644 return (TypeVect*)(new TypeVectZ(elem, length))->hashcons(); 2645 } 2646 ShouldNotReachHere(); 2647 return nullptr; 2648 } 2649 2650 const TypeVect *TypeVect::makemask(const Type* elem, uint length) { 2651 BasicType elem_bt = elem->array_element_basic_type(); 2652 if (Matcher::has_predicated_vectors() && 2653 Matcher::match_rule_supported_vector_masked(Op_VectorLoadMask, length, elem_bt)) { 2654 return TypeVectMask::make(elem, length); 2655 } else { 2656 return make(elem, length); 2657 } 2658 } 2659 2660 //------------------------------meet------------------------------------------- 2661 // Compute the MEET of two types. It returns a new Type object. 2662 const Type *TypeVect::xmeet( const Type *t ) const { 2663 // Perform a fast test for common case; meeting the same types together. 2664 if( this == t ) return this; // Meeting same type-rep? 2665 2666 // Current "this->_base" is Vector 2667 switch (t->base()) { // switch on original type 2668 2669 case Bottom: // Ye Olde Default 2670 return t; 2671 2672 default: // All else is a mistake 2673 typerr(t); 2674 case VectorMask: { 2675 const TypeVectMask* v = t->is_vectmask(); 2676 assert( base() == v->base(), ""); 2677 assert(length() == v->length(), ""); 2678 assert(element_basic_type() == v->element_basic_type(), ""); 2679 return TypeVect::makemask(_elem->xmeet(v->_elem), _length); 2680 } 2681 case VectorA: 2682 case VectorS: 2683 case VectorD: 2684 case VectorX: 2685 case VectorY: 2686 case VectorZ: { // Meeting 2 vectors? 2687 const TypeVect* v = t->is_vect(); 2688 assert( base() == v->base(), ""); 2689 assert(length() == v->length(), ""); 2690 assert(element_basic_type() == v->element_basic_type(), ""); 2691 return TypeVect::make(_elem->xmeet(v->_elem), _length); 2692 } 2693 case Top: 2694 break; 2695 } 2696 return this; 2697 } 2698 2699 //------------------------------xdual------------------------------------------ 2700 // Dual: compute field-by-field dual 2701 const Type *TypeVect::xdual() const { 2702 return new TypeVect(base(), _elem->dual(), _length); 2703 } 2704 2705 //------------------------------eq--------------------------------------------- 2706 // Structural equality check for Type representations 2707 bool TypeVect::eq(const Type *t) const { 2708 const TypeVect *v = t->is_vect(); 2709 return (_elem == v->_elem) && (_length == v->_length); 2710 } 2711 2712 //------------------------------hash------------------------------------------- 2713 // Type-specific hashing function. 2714 uint TypeVect::hash(void) const { 2715 return (uint)(uintptr_t)_elem + (uint)(uintptr_t)_length; 2716 } 2717 2718 //------------------------------singleton-------------------------------------- 2719 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 2720 // constants (Ldi nodes). Vector is singleton if all elements are the same 2721 // constant value (when vector is created with Replicate code). 2722 bool TypeVect::singleton(void) const { 2723 // There is no Con node for vectors yet. 2724 // return _elem->singleton(); 2725 return false; 2726 } 2727 2728 bool TypeVect::empty(void) const { 2729 return _elem->empty(); 2730 } 2731 2732 //------------------------------dump2------------------------------------------ 2733 #ifndef PRODUCT 2734 void TypeVect::dump2(Dict &d, uint depth, outputStream *st) const { 2735 switch (base()) { 2736 case VectorA: 2737 st->print("vectora["); break; 2738 case VectorS: 2739 st->print("vectors["); break; 2740 case VectorD: 2741 st->print("vectord["); break; 2742 case VectorX: 2743 st->print("vectorx["); break; 2744 case VectorY: 2745 st->print("vectory["); break; 2746 case VectorZ: 2747 st->print("vectorz["); break; 2748 case VectorMask: 2749 st->print("vectormask["); break; 2750 default: 2751 ShouldNotReachHere(); 2752 } 2753 st->print("%d]:{", _length); 2754 _elem->dump2(d, depth, st); 2755 st->print("}"); 2756 } 2757 #endif 2758 2759 bool TypeVectMask::eq(const Type *t) const { 2760 const TypeVectMask *v = t->is_vectmask(); 2761 return (element_type() == v->element_type()) && (length() == v->length()); 2762 } 2763 2764 const Type *TypeVectMask::xdual() const { 2765 return new TypeVectMask(element_type()->dual(), length()); 2766 } 2767 2768 const TypeVectMask *TypeVectMask::make(const BasicType elem_bt, uint length) { 2769 return make(get_const_basic_type(elem_bt), length); 2770 } 2771 2772 const TypeVectMask *TypeVectMask::make(const Type* elem, uint length) { 2773 const TypeVectMask* mtype = Matcher::predicate_reg_type(elem, length); 2774 return (TypeVectMask*) const_cast<TypeVectMask*>(mtype)->hashcons(); 2775 } 2776 2777 //============================================================================= 2778 // Convenience common pre-built types. 2779 const TypePtr *TypePtr::NULL_PTR; 2780 const TypePtr *TypePtr::NOTNULL; 2781 const TypePtr *TypePtr::BOTTOM; 2782 2783 //------------------------------meet------------------------------------------- 2784 // Meet over the PTR enum 2785 const TypePtr::PTR TypePtr::ptr_meet[TypePtr::lastPTR][TypePtr::lastPTR] = { 2786 // TopPTR, AnyNull, Constant, Null, NotNull, BotPTR, 2787 { /* Top */ TopPTR, AnyNull, Constant, Null, NotNull, BotPTR,}, 2788 { /* AnyNull */ AnyNull, AnyNull, Constant, BotPTR, NotNull, BotPTR,}, 2789 { /* Constant*/ Constant, Constant, Constant, BotPTR, NotNull, BotPTR,}, 2790 { /* Null */ Null, BotPTR, BotPTR, Null, BotPTR, BotPTR,}, 2791 { /* NotNull */ NotNull, NotNull, NotNull, BotPTR, NotNull, BotPTR,}, 2792 { /* BotPTR */ BotPTR, BotPTR, BotPTR, BotPTR, BotPTR, BotPTR,} 2793 }; 2794 2795 //------------------------------make------------------------------------------- 2796 const TypePtr* TypePtr::make(TYPES t, enum PTR ptr, Offset offset, const TypePtr* speculative, int inline_depth) { 2797 return (TypePtr*)(new TypePtr(t,ptr,offset, speculative, inline_depth))->hashcons(); 2798 } 2799 2800 //------------------------------cast_to_ptr_type------------------------------- 2801 const TypePtr* TypePtr::cast_to_ptr_type(PTR ptr) const { 2802 assert(_base == AnyPtr, "subclass must override cast_to_ptr_type"); 2803 if( ptr == _ptr ) return this; 2804 return make(_base, ptr, _offset, _speculative, _inline_depth); 2805 } 2806 2807 //------------------------------get_con---------------------------------------- 2808 intptr_t TypePtr::get_con() const { 2809 assert( _ptr == Null, "" ); 2810 return offset(); 2811 } 2812 2813 //------------------------------meet------------------------------------------- 2814 // Compute the MEET of two types. It returns a new Type object. 2815 const Type *TypePtr::xmeet(const Type *t) const { 2816 const Type* res = xmeet_helper(t); 2817 if (res->isa_ptr() == nullptr) { 2818 return res; 2819 } 2820 2821 const TypePtr* res_ptr = res->is_ptr(); 2822 if (res_ptr->speculative() != nullptr) { 2823 // type->speculative() is null means that speculation is no better 2824 // than type, i.e. type->speculative() == type. So there are 2 2825 // ways to represent the fact that we have no useful speculative 2826 // data and we should use a single one to be able to test for 2827 // equality between types. Check whether type->speculative() == 2828 // type and set speculative to null if it is the case. 2829 if (res_ptr->remove_speculative() == res_ptr->speculative()) { 2830 return res_ptr->remove_speculative(); 2831 } 2832 } 2833 2834 return res; 2835 } 2836 2837 const Type *TypePtr::xmeet_helper(const Type *t) const { 2838 // Perform a fast test for common case; meeting the same types together. 2839 if( this == t ) return this; // Meeting same type-rep? 2840 2841 // Current "this->_base" is AnyPtr 2842 switch (t->base()) { // switch on original type 2843 case Int: // Mixing ints & oops happens when javac 2844 case Long: // reuses local variables 2845 case FloatTop: 2846 case FloatCon: 2847 case FloatBot: 2848 case DoubleTop: 2849 case DoubleCon: 2850 case DoubleBot: 2851 case NarrowOop: 2852 case NarrowKlass: 2853 case Bottom: // Ye Olde Default 2854 return Type::BOTTOM; 2855 case Top: 2856 return this; 2857 2858 case AnyPtr: { // Meeting to AnyPtrs 2859 const TypePtr *tp = t->is_ptr(); 2860 const TypePtr* speculative = xmeet_speculative(tp); 2861 int depth = meet_inline_depth(tp->inline_depth()); 2862 return make(AnyPtr, meet_ptr(tp->ptr()), meet_offset(tp->offset()), speculative, depth); 2863 } 2864 case RawPtr: // For these, flip the call around to cut down 2865 case OopPtr: 2866 case InstPtr: // on the cases I have to handle. 2867 case AryPtr: 2868 case MetadataPtr: 2869 case KlassPtr: 2870 case InstKlassPtr: 2871 case AryKlassPtr: 2872 return t->xmeet(this); // Call in reverse direction 2873 default: // All else is a mistake 2874 typerr(t); 2875 2876 } 2877 return this; 2878 } 2879 2880 //------------------------------meet_offset------------------------------------ 2881 Type::Offset TypePtr::meet_offset(int offset) const { 2882 return _offset.meet(Offset(offset)); 2883 } 2884 2885 //------------------------------dual_offset------------------------------------ 2886 Type::Offset TypePtr::dual_offset() const { 2887 return _offset.dual(); 2888 } 2889 2890 //------------------------------xdual------------------------------------------ 2891 // Dual: compute field-by-field dual 2892 const TypePtr::PTR TypePtr::ptr_dual[TypePtr::lastPTR] = { 2893 BotPTR, NotNull, Constant, Null, AnyNull, TopPTR 2894 }; 2895 const Type *TypePtr::xdual() const { 2896 return new TypePtr(AnyPtr, dual_ptr(), dual_offset(), dual_speculative(), dual_inline_depth()); 2897 } 2898 2899 //------------------------------xadd_offset------------------------------------ 2900 Type::Offset TypePtr::xadd_offset(intptr_t offset) const { 2901 return _offset.add(offset); 2902 } 2903 2904 //------------------------------add_offset------------------------------------- 2905 const TypePtr *TypePtr::add_offset( intptr_t offset ) const { 2906 return make(AnyPtr, _ptr, xadd_offset(offset), _speculative, _inline_depth); 2907 } 2908 2909 const TypePtr *TypePtr::with_offset(intptr_t offset) const { 2910 return make(AnyPtr, _ptr, Offset(offset), _speculative, _inline_depth); 2911 } 2912 2913 //------------------------------eq--------------------------------------------- 2914 // Structural equality check for Type representations 2915 bool TypePtr::eq( const Type *t ) const { 2916 const TypePtr *a = (const TypePtr*)t; 2917 return _ptr == a->ptr() && _offset == a->_offset && eq_speculative(a) && _inline_depth == a->_inline_depth; 2918 } 2919 2920 //------------------------------hash------------------------------------------- 2921 // Type-specific hashing function. 2922 uint TypePtr::hash(void) const { 2923 return (uint)_ptr + (uint)offset() + (uint)hash_speculative() + (uint)_inline_depth; 2924 } 2925 2926 /** 2927 * Return same type without a speculative part 2928 */ 2929 const TypePtr* TypePtr::remove_speculative() const { 2930 if (_speculative == nullptr) { 2931 return this; 2932 } 2933 assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); 2934 return make(AnyPtr, _ptr, _offset, nullptr, _inline_depth); 2935 } 2936 2937 /** 2938 * Return same type but drop speculative part if we know we won't use 2939 * it 2940 */ 2941 const Type* TypePtr::cleanup_speculative() const { 2942 if (speculative() == nullptr) { 2943 return this; 2944 } 2945 const Type* no_spec = remove_speculative(); 2946 // If this is NULL_PTR then we don't need the speculative type 2947 // (with_inline_depth in case the current type inline depth is 2948 // InlineDepthTop) 2949 if (no_spec == NULL_PTR->with_inline_depth(inline_depth())) { 2950 return no_spec; 2951 } 2952 if (above_centerline(speculative()->ptr())) { 2953 return no_spec; 2954 } 2955 const TypeOopPtr* spec_oopptr = speculative()->isa_oopptr(); 2956 // If the speculative may be null and is an inexact klass then it 2957 // doesn't help 2958 if (speculative() != TypePtr::NULL_PTR && speculative()->maybe_null() && 2959 (spec_oopptr == nullptr || !spec_oopptr->klass_is_exact())) { 2960 return no_spec; 2961 } 2962 return this; 2963 } 2964 2965 /** 2966 * dual of the speculative part of the type 2967 */ 2968 const TypePtr* TypePtr::dual_speculative() const { 2969 if (_speculative == nullptr) { 2970 return nullptr; 2971 } 2972 return _speculative->dual()->is_ptr(); 2973 } 2974 2975 /** 2976 * meet of the speculative parts of 2 types 2977 * 2978 * @param other type to meet with 2979 */ 2980 const TypePtr* TypePtr::xmeet_speculative(const TypePtr* other) const { 2981 bool this_has_spec = (_speculative != nullptr); 2982 bool other_has_spec = (other->speculative() != nullptr); 2983 2984 if (!this_has_spec && !other_has_spec) { 2985 return nullptr; 2986 } 2987 2988 // If we are at a point where control flow meets and one branch has 2989 // a speculative type and the other has not, we meet the speculative 2990 // type of one branch with the actual type of the other. If the 2991 // actual type is exact and the speculative is as well, then the 2992 // result is a speculative type which is exact and we can continue 2993 // speculation further. 2994 const TypePtr* this_spec = _speculative; 2995 const TypePtr* other_spec = other->speculative(); 2996 2997 if (!this_has_spec) { 2998 this_spec = this; 2999 } 3000 3001 if (!other_has_spec) { 3002 other_spec = other; 3003 } 3004 3005 return this_spec->meet(other_spec)->is_ptr(); 3006 } 3007 3008 /** 3009 * dual of the inline depth for this type (used for speculation) 3010 */ 3011 int TypePtr::dual_inline_depth() const { 3012 return -inline_depth(); 3013 } 3014 3015 /** 3016 * meet of 2 inline depths (used for speculation) 3017 * 3018 * @param depth depth to meet with 3019 */ 3020 int TypePtr::meet_inline_depth(int depth) const { 3021 return MAX2(inline_depth(), depth); 3022 } 3023 3024 /** 3025 * Are the speculative parts of 2 types equal? 3026 * 3027 * @param other type to compare this one to 3028 */ 3029 bool TypePtr::eq_speculative(const TypePtr* other) const { 3030 if (_speculative == nullptr || other->speculative() == nullptr) { 3031 return _speculative == other->speculative(); 3032 } 3033 3034 if (_speculative->base() != other->speculative()->base()) { 3035 return false; 3036 } 3037 3038 return _speculative->eq(other->speculative()); 3039 } 3040 3041 /** 3042 * Hash of the speculative part of the type 3043 */ 3044 int TypePtr::hash_speculative() const { 3045 if (_speculative == nullptr) { 3046 return 0; 3047 } 3048 3049 return _speculative->hash(); 3050 } 3051 3052 /** 3053 * add offset to the speculative part of the type 3054 * 3055 * @param offset offset to add 3056 */ 3057 const TypePtr* TypePtr::add_offset_speculative(intptr_t offset) const { 3058 if (_speculative == nullptr) { 3059 return nullptr; 3060 } 3061 return _speculative->add_offset(offset)->is_ptr(); 3062 } 3063 3064 const TypePtr* TypePtr::with_offset_speculative(intptr_t offset) const { 3065 if (_speculative == nullptr) { 3066 return nullptr; 3067 } 3068 return _speculative->with_offset(offset)->is_ptr(); 3069 } 3070 3071 /** 3072 * return exact klass from the speculative type if there's one 3073 */ 3074 ciKlass* TypePtr::speculative_type() const { 3075 if (_speculative != nullptr && _speculative->isa_oopptr()) { 3076 const TypeOopPtr* speculative = _speculative->join(this)->is_oopptr(); 3077 if (speculative->klass_is_exact()) { 3078 return speculative->exact_klass(); 3079 } 3080 } 3081 return nullptr; 3082 } 3083 3084 /** 3085 * return true if speculative type may be null 3086 */ 3087 bool TypePtr::speculative_maybe_null() const { 3088 if (_speculative != nullptr) { 3089 const TypePtr* speculative = _speculative->join(this)->is_ptr(); 3090 return speculative->maybe_null(); 3091 } 3092 return true; 3093 } 3094 3095 bool TypePtr::speculative_always_null() const { 3096 if (_speculative != nullptr) { 3097 const TypePtr* speculative = _speculative->join(this)->is_ptr(); 3098 return speculative == TypePtr::NULL_PTR; 3099 } 3100 return false; 3101 } 3102 3103 /** 3104 * Same as TypePtr::speculative_type() but return the klass only if 3105 * the speculative tells us is not null 3106 */ 3107 ciKlass* TypePtr::speculative_type_not_null() const { 3108 if (speculative_maybe_null()) { 3109 return nullptr; 3110 } 3111 return speculative_type(); 3112 } 3113 3114 /** 3115 * Check whether new profiling would improve speculative type 3116 * 3117 * @param exact_kls class from profiling 3118 * @param inline_depth inlining depth of profile point 3119 * 3120 * @return true if type profile is valuable 3121 */ 3122 bool TypePtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const { 3123 // no profiling? 3124 if (exact_kls == nullptr) { 3125 return false; 3126 } 3127 if (speculative() == TypePtr::NULL_PTR) { 3128 return false; 3129 } 3130 // no speculative type or non exact speculative type? 3131 if (speculative_type() == nullptr) { 3132 return true; 3133 } 3134 // If the node already has an exact speculative type keep it, 3135 // unless it was provided by profiling that is at a deeper 3136 // inlining level. Profiling at a higher inlining depth is 3137 // expected to be less accurate. 3138 if (_speculative->inline_depth() == InlineDepthBottom) { 3139 return false; 3140 } 3141 assert(_speculative->inline_depth() != InlineDepthTop, "can't do the comparison"); 3142 return inline_depth < _speculative->inline_depth(); 3143 } 3144 3145 /** 3146 * Check whether new profiling would improve ptr (= tells us it is non 3147 * null) 3148 * 3149 * @param ptr_kind always null or not null? 3150 * 3151 * @return true if ptr profile is valuable 3152 */ 3153 bool TypePtr::would_improve_ptr(ProfilePtrKind ptr_kind) const { 3154 // profiling doesn't tell us anything useful 3155 if (ptr_kind != ProfileAlwaysNull && ptr_kind != ProfileNeverNull) { 3156 return false; 3157 } 3158 // We already know this is not null 3159 if (!this->maybe_null()) { 3160 return false; 3161 } 3162 // We already know the speculative type cannot be null 3163 if (!speculative_maybe_null()) { 3164 return false; 3165 } 3166 // We already know this is always null 3167 if (this == TypePtr::NULL_PTR) { 3168 return false; 3169 } 3170 // We already know the speculative type is always null 3171 if (speculative_always_null()) { 3172 return false; 3173 } 3174 if (ptr_kind == ProfileAlwaysNull && speculative() != nullptr && speculative()->isa_oopptr()) { 3175 return false; 3176 } 3177 return true; 3178 } 3179 3180 //------------------------------dump2------------------------------------------ 3181 const char *const TypePtr::ptr_msg[TypePtr::lastPTR] = { 3182 "TopPTR","AnyNull","Constant","null","NotNull","BotPTR" 3183 }; 3184 3185 #ifndef PRODUCT 3186 void TypePtr::dump2( Dict &d, uint depth, outputStream *st ) const { 3187 if( _ptr == Null ) st->print("null"); 3188 else st->print("%s *", ptr_msg[_ptr]); 3189 _offset.dump2(st); 3190 dump_inline_depth(st); 3191 dump_speculative(st); 3192 } 3193 3194 /** 3195 *dump the speculative part of the type 3196 */ 3197 void TypePtr::dump_speculative(outputStream *st) const { 3198 if (_speculative != nullptr) { 3199 st->print(" (speculative="); 3200 _speculative->dump_on(st); 3201 st->print(")"); 3202 } 3203 } 3204 3205 /** 3206 *dump the inline depth of the type 3207 */ 3208 void TypePtr::dump_inline_depth(outputStream *st) const { 3209 if (_inline_depth != InlineDepthBottom) { 3210 if (_inline_depth == InlineDepthTop) { 3211 st->print(" (inline_depth=InlineDepthTop)"); 3212 } else { 3213 st->print(" (inline_depth=%d)", _inline_depth); 3214 } 3215 } 3216 } 3217 #endif 3218 3219 //------------------------------singleton-------------------------------------- 3220 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 3221 // constants 3222 bool TypePtr::singleton(void) const { 3223 // TopPTR, Null, AnyNull, Constant are all singletons 3224 return (_offset != Offset::bottom) && !below_centerline(_ptr); 3225 } 3226 3227 bool TypePtr::empty(void) const { 3228 return (_offset == Offset::top) || above_centerline(_ptr); 3229 } 3230 3231 //============================================================================= 3232 // Convenience common pre-built types. 3233 const TypeRawPtr *TypeRawPtr::BOTTOM; 3234 const TypeRawPtr *TypeRawPtr::NOTNULL; 3235 3236 //------------------------------make------------------------------------------- 3237 const TypeRawPtr *TypeRawPtr::make( enum PTR ptr ) { 3238 assert( ptr != Constant, "what is the constant?" ); 3239 assert( ptr != Null, "Use TypePtr for null" ); 3240 return (TypeRawPtr*)(new TypeRawPtr(ptr,0))->hashcons(); 3241 } 3242 3243 const TypeRawPtr *TypeRawPtr::make( address bits ) { 3244 assert( bits, "Use TypePtr for null" ); 3245 return (TypeRawPtr*)(new TypeRawPtr(Constant,bits))->hashcons(); 3246 } 3247 3248 //------------------------------cast_to_ptr_type------------------------------- 3249 const TypeRawPtr* TypeRawPtr::cast_to_ptr_type(PTR ptr) const { 3250 assert( ptr != Constant, "what is the constant?" ); 3251 assert( ptr != Null, "Use TypePtr for null" ); 3252 assert( _bits==0, "Why cast a constant address?"); 3253 if( ptr == _ptr ) return this; 3254 return make(ptr); 3255 } 3256 3257 //------------------------------get_con---------------------------------------- 3258 intptr_t TypeRawPtr::get_con() const { 3259 assert( _ptr == Null || _ptr == Constant, "" ); 3260 return (intptr_t)_bits; 3261 } 3262 3263 //------------------------------meet------------------------------------------- 3264 // Compute the MEET of two types. It returns a new Type object. 3265 const Type *TypeRawPtr::xmeet( const Type *t ) const { 3266 // Perform a fast test for common case; meeting the same types together. 3267 if( this == t ) return this; // Meeting same type-rep? 3268 3269 // Current "this->_base" is RawPtr 3270 switch( t->base() ) { // switch on original type 3271 case Bottom: // Ye Olde Default 3272 return t; 3273 case Top: 3274 return this; 3275 case AnyPtr: // Meeting to AnyPtrs 3276 break; 3277 case RawPtr: { // might be top, bot, any/not or constant 3278 enum PTR tptr = t->is_ptr()->ptr(); 3279 enum PTR ptr = meet_ptr( tptr ); 3280 if( ptr == Constant ) { // Cannot be equal constants, so... 3281 if( tptr == Constant && _ptr != Constant) return t; 3282 if( _ptr == Constant && tptr != Constant) return this; 3283 ptr = NotNull; // Fall down in lattice 3284 } 3285 return make( ptr ); 3286 } 3287 3288 case OopPtr: 3289 case InstPtr: 3290 case AryPtr: 3291 case MetadataPtr: 3292 case KlassPtr: 3293 case InstKlassPtr: 3294 case AryKlassPtr: 3295 return TypePtr::BOTTOM; // Oop meet raw is not well defined 3296 default: // All else is a mistake 3297 typerr(t); 3298 } 3299 3300 // Found an AnyPtr type vs self-RawPtr type 3301 const TypePtr *tp = t->is_ptr(); 3302 switch (tp->ptr()) { 3303 case TypePtr::TopPTR: return this; 3304 case TypePtr::BotPTR: return t; 3305 case TypePtr::Null: 3306 if( _ptr == TypePtr::TopPTR ) return t; 3307 return TypeRawPtr::BOTTOM; 3308 case TypePtr::NotNull: return TypePtr::make(AnyPtr, meet_ptr(TypePtr::NotNull), tp->meet_offset(0), tp->speculative(), tp->inline_depth()); 3309 case TypePtr::AnyNull: 3310 if( _ptr == TypePtr::Constant) return this; 3311 return make( meet_ptr(TypePtr::AnyNull) ); 3312 default: ShouldNotReachHere(); 3313 } 3314 return this; 3315 } 3316 3317 //------------------------------xdual------------------------------------------ 3318 // Dual: compute field-by-field dual 3319 const Type *TypeRawPtr::xdual() const { 3320 return new TypeRawPtr( dual_ptr(), _bits ); 3321 } 3322 3323 //------------------------------add_offset------------------------------------- 3324 const TypePtr* TypeRawPtr::add_offset(intptr_t offset) const { 3325 if( offset == OffsetTop ) return BOTTOM; // Undefined offset-> undefined pointer 3326 if( offset == OffsetBot ) return BOTTOM; // Unknown offset-> unknown pointer 3327 if( offset == 0 ) return this; // No change 3328 switch (_ptr) { 3329 case TypePtr::TopPTR: 3330 case TypePtr::BotPTR: 3331 case TypePtr::NotNull: 3332 return this; 3333 case TypePtr::Null: 3334 case TypePtr::Constant: { 3335 address bits = _bits+offset; 3336 if ( bits == 0 ) return TypePtr::NULL_PTR; 3337 return make( bits ); 3338 } 3339 default: ShouldNotReachHere(); 3340 } 3341 return nullptr; // Lint noise 3342 } 3343 3344 //------------------------------eq--------------------------------------------- 3345 // Structural equality check for Type representations 3346 bool TypeRawPtr::eq( const Type *t ) const { 3347 const TypeRawPtr *a = (const TypeRawPtr*)t; 3348 return _bits == a->_bits && TypePtr::eq(t); 3349 } 3350 3351 //------------------------------hash------------------------------------------- 3352 // Type-specific hashing function. 3353 uint TypeRawPtr::hash(void) const { 3354 return (uint)(uintptr_t)_bits + (uint)TypePtr::hash(); 3355 } 3356 3357 //------------------------------dump2------------------------------------------ 3358 #ifndef PRODUCT 3359 void TypeRawPtr::dump2( Dict &d, uint depth, outputStream *st ) const { 3360 if( _ptr == Constant ) 3361 st->print(INTPTR_FORMAT, p2i(_bits)); 3362 else 3363 st->print("rawptr:%s", ptr_msg[_ptr]); 3364 } 3365 #endif 3366 3367 //============================================================================= 3368 // Convenience common pre-built type. 3369 const TypeOopPtr *TypeOopPtr::BOTTOM; 3370 3371 TypeInterfaces::TypeInterfaces() 3372 : Type(Interfaces), _list(Compile::current()->type_arena(), 0, 0, nullptr), 3373 _hash(0), _exact_klass(nullptr) { 3374 DEBUG_ONLY(_initialized = true); 3375 } 3376 3377 TypeInterfaces::TypeInterfaces(GrowableArray<ciInstanceKlass*>* interfaces) 3378 : Type(Interfaces), _list(Compile::current()->type_arena(), interfaces->length(), 0, nullptr), 3379 _hash(0), _exact_klass(nullptr) { 3380 for (int i = 0; i < interfaces->length(); i++) { 3381 add(interfaces->at(i)); 3382 } 3383 initialize(); 3384 } 3385 3386 const TypeInterfaces* TypeInterfaces::make(GrowableArray<ciInstanceKlass*>* interfaces) { 3387 TypeInterfaces* result = (interfaces == nullptr) ? new TypeInterfaces() : new TypeInterfaces(interfaces); 3388 return (const TypeInterfaces*)result->hashcons(); 3389 } 3390 3391 void TypeInterfaces::initialize() { 3392 compute_hash(); 3393 compute_exact_klass(); 3394 DEBUG_ONLY(_initialized = true;) 3395 } 3396 3397 int TypeInterfaces::compare(ciInstanceKlass* const& k1, ciInstanceKlass* const& k2) { 3398 if ((intptr_t)k1 < (intptr_t)k2) { 3399 return -1; 3400 } else if ((intptr_t)k1 > (intptr_t)k2) { 3401 return 1; 3402 } 3403 return 0; 3404 } 3405 3406 void TypeInterfaces::add(ciInstanceKlass* interface) { 3407 assert(interface->is_interface(), "for interfaces only"); 3408 _list.insert_sorted<compare>(interface); 3409 verify(); 3410 } 3411 3412 bool TypeInterfaces::eq(const Type* t) const { 3413 const TypeInterfaces* other = (const TypeInterfaces*)t; 3414 if (_list.length() != other->_list.length()) { 3415 return false; 3416 } 3417 for (int i = 0; i < _list.length(); i++) { 3418 ciKlass* k1 = _list.at(i); 3419 ciKlass* k2 = other->_list.at(i); 3420 if (!k1->equals(k2)) { 3421 return false; 3422 } 3423 } 3424 return true; 3425 } 3426 3427 bool TypeInterfaces::eq(ciInstanceKlass* k) const { 3428 assert(k->is_loaded(), "should be loaded"); 3429 GrowableArray<ciInstanceKlass *>* interfaces = k->transitive_interfaces(); 3430 if (_list.length() != interfaces->length()) { 3431 return false; 3432 } 3433 for (int i = 0; i < interfaces->length(); i++) { 3434 bool found = false; 3435 _list.find_sorted<ciInstanceKlass*, compare>(interfaces->at(i), found); 3436 if (!found) { 3437 return false; 3438 } 3439 } 3440 return true; 3441 } 3442 3443 3444 uint TypeInterfaces::hash() const { 3445 assert(_initialized, "must be"); 3446 return _hash; 3447 } 3448 3449 const Type* TypeInterfaces::xdual() const { 3450 return this; 3451 } 3452 3453 void TypeInterfaces::compute_hash() { 3454 uint hash = 0; 3455 for (int i = 0; i < _list.length(); i++) { 3456 ciKlass* k = _list.at(i); 3457 hash += k->hash(); 3458 } 3459 _hash = hash; 3460 } 3461 3462 static int compare_interfaces(ciInstanceKlass** k1, ciInstanceKlass** k2) { 3463 return (int)((*k1)->ident() - (*k2)->ident()); 3464 } 3465 3466 void TypeInterfaces::dump(outputStream* st) const { 3467 if (_list.length() == 0) { 3468 return; 3469 } 3470 ResourceMark rm; 3471 st->print(" ("); 3472 GrowableArray<ciInstanceKlass*> interfaces; 3473 interfaces.appendAll(&_list); 3474 // Sort the interfaces so they are listed in the same order from one run to the other of the same compilation 3475 interfaces.sort(compare_interfaces); 3476 for (int i = 0; i < interfaces.length(); i++) { 3477 if (i > 0) { 3478 st->print(","); 3479 } 3480 ciKlass* k = interfaces.at(i); 3481 k->print_name_on(st); 3482 } 3483 st->print(")"); 3484 } 3485 3486 #ifdef ASSERT 3487 void TypeInterfaces::verify() const { 3488 for (int i = 1; i < _list.length(); i++) { 3489 ciInstanceKlass* k1 = _list.at(i-1); 3490 ciInstanceKlass* k2 = _list.at(i); 3491 assert(compare(k2, k1) > 0, "should be ordered"); 3492 assert(k1 != k2, "no duplicate"); 3493 } 3494 } 3495 #endif 3496 3497 const TypeInterfaces* TypeInterfaces::union_with(const TypeInterfaces* other) const { 3498 GrowableArray<ciInstanceKlass*> result_list; 3499 int i = 0; 3500 int j = 0; 3501 while (i < _list.length() || j < other->_list.length()) { 3502 while (i < _list.length() && 3503 (j >= other->_list.length() || 3504 compare(_list.at(i), other->_list.at(j)) < 0)) { 3505 result_list.push(_list.at(i)); 3506 i++; 3507 } 3508 while (j < other->_list.length() && 3509 (i >= _list.length() || 3510 compare(other->_list.at(j), _list.at(i)) < 0)) { 3511 result_list.push(other->_list.at(j)); 3512 j++; 3513 } 3514 if (i < _list.length() && 3515 j < other->_list.length() && 3516 _list.at(i) == other->_list.at(j)) { 3517 result_list.push(_list.at(i)); 3518 i++; 3519 j++; 3520 } 3521 } 3522 const TypeInterfaces* result = TypeInterfaces::make(&result_list); 3523 #ifdef ASSERT 3524 result->verify(); 3525 for (int i = 0; i < _list.length(); i++) { 3526 assert(result->_list.contains(_list.at(i)), "missing"); 3527 } 3528 for (int i = 0; i < other->_list.length(); i++) { 3529 assert(result->_list.contains(other->_list.at(i)), "missing"); 3530 } 3531 for (int i = 0; i < result->_list.length(); i++) { 3532 assert(_list.contains(result->_list.at(i)) || other->_list.contains(result->_list.at(i)), "missing"); 3533 } 3534 #endif 3535 return result; 3536 } 3537 3538 const TypeInterfaces* TypeInterfaces::intersection_with(const TypeInterfaces* other) const { 3539 GrowableArray<ciInstanceKlass*> result_list; 3540 int i = 0; 3541 int j = 0; 3542 while (i < _list.length() || j < other->_list.length()) { 3543 while (i < _list.length() && 3544 (j >= other->_list.length() || 3545 compare(_list.at(i), other->_list.at(j)) < 0)) { 3546 i++; 3547 } 3548 while (j < other->_list.length() && 3549 (i >= _list.length() || 3550 compare(other->_list.at(j), _list.at(i)) < 0)) { 3551 j++; 3552 } 3553 if (i < _list.length() && 3554 j < other->_list.length() && 3555 _list.at(i) == other->_list.at(j)) { 3556 result_list.push(_list.at(i)); 3557 i++; 3558 j++; 3559 } 3560 } 3561 const TypeInterfaces* result = TypeInterfaces::make(&result_list); 3562 #ifdef ASSERT 3563 result->verify(); 3564 for (int i = 0; i < _list.length(); i++) { 3565 assert(!other->_list.contains(_list.at(i)) || result->_list.contains(_list.at(i)), "missing"); 3566 } 3567 for (int i = 0; i < other->_list.length(); i++) { 3568 assert(!_list.contains(other->_list.at(i)) || result->_list.contains(other->_list.at(i)), "missing"); 3569 } 3570 for (int i = 0; i < result->_list.length(); i++) { 3571 assert(_list.contains(result->_list.at(i)) && other->_list.contains(result->_list.at(i)), "missing"); 3572 } 3573 #endif 3574 return result; 3575 } 3576 3577 // Is there a single ciKlass* that can represent the interface set? 3578 ciInstanceKlass* TypeInterfaces::exact_klass() const { 3579 assert(_initialized, "must be"); 3580 return _exact_klass; 3581 } 3582 3583 void TypeInterfaces::compute_exact_klass() { 3584 if (_list.length() == 0) { 3585 _exact_klass = nullptr; 3586 return; 3587 } 3588 ciInstanceKlass* res = nullptr; 3589 for (int i = 0; i < _list.length(); i++) { 3590 ciInstanceKlass* interface = _list.at(i); 3591 if (eq(interface)) { 3592 assert(res == nullptr, ""); 3593 res = interface; 3594 } 3595 } 3596 _exact_klass = res; 3597 } 3598 3599 #ifdef ASSERT 3600 void TypeInterfaces::verify_is_loaded() const { 3601 for (int i = 0; i < _list.length(); i++) { 3602 ciKlass* interface = _list.at(i); 3603 assert(interface->is_loaded(), "Interface not loaded"); 3604 } 3605 } 3606 #endif 3607 3608 // Can't be implemented because there's no way to know if the type is above or below the center line. 3609 const Type* TypeInterfaces::xmeet(const Type* t) const { 3610 ShouldNotReachHere(); 3611 return Type::xmeet(t); 3612 } 3613 3614 bool TypeInterfaces::singleton(void) const { 3615 ShouldNotReachHere(); 3616 return Type::singleton(); 3617 } 3618 3619 //------------------------------TypeOopPtr------------------------------------- 3620 TypeOopPtr::TypeOopPtr(TYPES t, PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, bool xk, ciObject* o, Offset offset, Offset field_offset, 3621 int instance_id, const TypePtr* speculative, int inline_depth) 3622 : TypePtr(t, ptr, offset, speculative, inline_depth), 3623 _const_oop(o), _klass(k), 3624 _interfaces(interfaces), 3625 _klass_is_exact(xk), 3626 _is_ptr_to_narrowoop(false), 3627 _is_ptr_to_narrowklass(false), 3628 _is_ptr_to_boxed_value(false), 3629 _instance_id(instance_id) { 3630 #ifdef ASSERT 3631 if (klass() != nullptr && klass()->is_loaded()) { 3632 interfaces->verify_is_loaded(); 3633 } 3634 #endif 3635 if (Compile::current()->eliminate_boxing() && (t == InstPtr) && 3636 (offset.get() > 0) && xk && (k != 0) && k->is_instance_klass()) { 3637 _is_ptr_to_boxed_value = k->as_instance_klass()->is_boxed_value_offset(offset.get()); 3638 } 3639 #ifdef _LP64 3640 if (this->offset() > 0 || this->offset() == Type::OffsetTop || this->offset() == Type::OffsetBot) { 3641 if (this->offset() == oopDesc::klass_offset_in_bytes()) { 3642 _is_ptr_to_narrowklass = UseCompressedClassPointers; 3643 } else if (klass() == nullptr) { 3644 // Array with unknown body type 3645 assert(this->isa_aryptr(), "only arrays without klass"); 3646 _is_ptr_to_narrowoop = UseCompressedOops; 3647 } else if (UseCompressedOops && this->isa_aryptr() && this->offset() != arrayOopDesc::length_offset_in_bytes()) { 3648 if (klass()->is_obj_array_klass()) { 3649 _is_ptr_to_narrowoop = true; 3650 } else if (klass()->is_flat_array_klass() && field_offset != Offset::top && field_offset != Offset::bottom) { 3651 // Check if the field of the inline type array element contains oops 3652 ciInlineKlass* vk = klass()->as_flat_array_klass()->element_klass()->as_inline_klass(); 3653 int foffset = field_offset.get() + vk->first_field_offset(); 3654 ciField* field = vk->get_field_by_offset(foffset, false); 3655 assert(field != nullptr, "missing field"); 3656 BasicType bt = field->layout_type(); 3657 _is_ptr_to_narrowoop = UseCompressedOops && ::is_reference_type(bt); 3658 } 3659 } else if (klass()->is_instance_klass()) { 3660 if (this->isa_klassptr()) { 3661 // Perm objects don't use compressed references 3662 } else if (_offset == Offset::bottom || _offset == Offset::top) { 3663 // unsafe access 3664 _is_ptr_to_narrowoop = UseCompressedOops; 3665 } else { 3666 assert(this->isa_instptr(), "must be an instance ptr."); 3667 if (klass() == ciEnv::current()->Class_klass() && 3668 (this->offset() == java_lang_Class::klass_offset() || 3669 this->offset() == java_lang_Class::array_klass_offset())) { 3670 // Special hidden fields from the Class. 3671 assert(this->isa_instptr(), "must be an instance ptr."); 3672 _is_ptr_to_narrowoop = false; 3673 } else if (klass() == ciEnv::current()->Class_klass() && 3674 this->offset() >= InstanceMirrorKlass::offset_of_static_fields()) { 3675 // Static fields 3676 ciField* field = nullptr; 3677 if (const_oop() != nullptr) { 3678 ciInstanceKlass* k = const_oop()->as_instance()->java_lang_Class_klass()->as_instance_klass(); 3679 // TODO 8325106 remove? 3680 if (k->is_inlinetype() && this->offset() == k->as_inline_klass()->default_value_offset()) { 3681 // Special hidden field that contains the oop of the default inline type 3682 // basic_elem_type = T_PRIMITIVE_OBJECT; 3683 _is_ptr_to_narrowoop = UseCompressedOops; 3684 } else { 3685 field = k->get_field_by_offset(this->offset(), true); 3686 if (field != nullptr) { 3687 BasicType basic_elem_type = field->layout_type(); 3688 _is_ptr_to_narrowoop = UseCompressedOops && ::is_reference_type(basic_elem_type); 3689 } else { 3690 // unsafe access 3691 _is_ptr_to_narrowoop = UseCompressedOops; 3692 } 3693 } 3694 } 3695 } else { 3696 // Instance fields which contains a compressed oop references. 3697 ciInstanceKlass* ik = klass()->as_instance_klass(); 3698 ciField* field = ik->get_field_by_offset(this->offset(), false); 3699 if (field != nullptr) { 3700 BasicType basic_elem_type = field->layout_type(); 3701 _is_ptr_to_narrowoop = UseCompressedOops && ::is_reference_type(basic_elem_type); 3702 } else if (klass()->equals(ciEnv::current()->Object_klass())) { 3703 // Compile::find_alias_type() cast exactness on all types to verify 3704 // that it does not affect alias type. 3705 _is_ptr_to_narrowoop = UseCompressedOops; 3706 } else { 3707 // Type for the copy start in LibraryCallKit::inline_native_clone(). 3708 _is_ptr_to_narrowoop = UseCompressedOops; 3709 } 3710 } 3711 } 3712 } 3713 } 3714 #endif 3715 } 3716 3717 //------------------------------make------------------------------------------- 3718 const TypeOopPtr *TypeOopPtr::make(PTR ptr, Offset offset, int instance_id, 3719 const TypePtr* speculative, int inline_depth) { 3720 assert(ptr != Constant, "no constant generic pointers"); 3721 ciKlass* k = Compile::current()->env()->Object_klass(); 3722 bool xk = false; 3723 ciObject* o = nullptr; 3724 const TypeInterfaces* interfaces = TypeInterfaces::make(); 3725 return (TypeOopPtr*)(new TypeOopPtr(OopPtr, ptr, k, interfaces, xk, o, offset, Offset::bottom, instance_id, speculative, inline_depth))->hashcons(); 3726 } 3727 3728 3729 //------------------------------cast_to_ptr_type------------------------------- 3730 const TypeOopPtr* TypeOopPtr::cast_to_ptr_type(PTR ptr) const { 3731 assert(_base == OopPtr, "subclass must override cast_to_ptr_type"); 3732 if( ptr == _ptr ) return this; 3733 return make(ptr, _offset, _instance_id, _speculative, _inline_depth); 3734 } 3735 3736 //-----------------------------cast_to_instance_id---------------------------- 3737 const TypeOopPtr *TypeOopPtr::cast_to_instance_id(int instance_id) const { 3738 // There are no instances of a general oop. 3739 // Return self unchanged. 3740 return this; 3741 } 3742 3743 //-----------------------------cast_to_exactness------------------------------- 3744 const TypeOopPtr* TypeOopPtr::cast_to_exactness(bool klass_is_exact) const { 3745 // There is no such thing as an exact general oop. 3746 // Return self unchanged. 3747 return this; 3748 } 3749 3750 //------------------------------as_klass_type---------------------------------- 3751 // Return the klass type corresponding to this instance or array type. 3752 // It is the type that is loaded from an object of this type. 3753 const TypeKlassPtr* TypeOopPtr::as_klass_type(bool try_for_exact) const { 3754 ShouldNotReachHere(); 3755 return nullptr; 3756 } 3757 3758 //------------------------------meet------------------------------------------- 3759 // Compute the MEET of two types. It returns a new Type object. 3760 const Type *TypeOopPtr::xmeet_helper(const Type *t) const { 3761 // Perform a fast test for common case; meeting the same types together. 3762 if( this == t ) return this; // Meeting same type-rep? 3763 3764 // Current "this->_base" is OopPtr 3765 switch (t->base()) { // switch on original type 3766 3767 case Int: // Mixing ints & oops happens when javac 3768 case Long: // reuses local variables 3769 case FloatTop: 3770 case FloatCon: 3771 case FloatBot: 3772 case DoubleTop: 3773 case DoubleCon: 3774 case DoubleBot: 3775 case NarrowOop: 3776 case NarrowKlass: 3777 case Bottom: // Ye Olde Default 3778 return Type::BOTTOM; 3779 case Top: 3780 return this; 3781 3782 default: // All else is a mistake 3783 typerr(t); 3784 3785 case RawPtr: 3786 case MetadataPtr: 3787 case KlassPtr: 3788 case InstKlassPtr: 3789 case AryKlassPtr: 3790 return TypePtr::BOTTOM; // Oop meet raw is not well defined 3791 3792 case AnyPtr: { 3793 // Found an AnyPtr type vs self-OopPtr type 3794 const TypePtr *tp = t->is_ptr(); 3795 Offset offset = meet_offset(tp->offset()); 3796 PTR ptr = meet_ptr(tp->ptr()); 3797 const TypePtr* speculative = xmeet_speculative(tp); 3798 int depth = meet_inline_depth(tp->inline_depth()); 3799 switch (tp->ptr()) { 3800 case Null: 3801 if (ptr == Null) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); 3802 // else fall through: 3803 case TopPTR: 3804 case AnyNull: { 3805 int instance_id = meet_instance_id(InstanceTop); 3806 return make(ptr, offset, instance_id, speculative, depth); 3807 } 3808 case BotPTR: 3809 case NotNull: 3810 return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); 3811 default: typerr(t); 3812 } 3813 } 3814 3815 case OopPtr: { // Meeting to other OopPtrs 3816 const TypeOopPtr *tp = t->is_oopptr(); 3817 int instance_id = meet_instance_id(tp->instance_id()); 3818 const TypePtr* speculative = xmeet_speculative(tp); 3819 int depth = meet_inline_depth(tp->inline_depth()); 3820 return make(meet_ptr(tp->ptr()), meet_offset(tp->offset()), instance_id, speculative, depth); 3821 } 3822 3823 case InstPtr: // For these, flip the call around to cut down 3824 case AryPtr: 3825 return t->xmeet(this); // Call in reverse direction 3826 3827 } // End of switch 3828 return this; // Return the double constant 3829 } 3830 3831 3832 //------------------------------xdual------------------------------------------ 3833 // Dual of a pure heap pointer. No relevant klass or oop information. 3834 const Type *TypeOopPtr::xdual() const { 3835 assert(klass() == Compile::current()->env()->Object_klass(), "no klasses here"); 3836 assert(const_oop() == nullptr, "no constants here"); 3837 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()); 3838 } 3839 3840 //--------------------------make_from_klass_common----------------------------- 3841 // Computes the element-type given a klass. 3842 const TypeOopPtr* TypeOopPtr::make_from_klass_common(ciKlass *klass, bool klass_change, bool try_for_exact, InterfaceHandling interface_handling) { 3843 if (klass->is_instance_klass() || klass->is_inlinetype()) { 3844 Compile* C = Compile::current(); 3845 Dependencies* deps = C->dependencies(); 3846 assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity"); 3847 // Element is an instance 3848 bool klass_is_exact = false; 3849 if (klass->is_loaded()) { 3850 // Try to set klass_is_exact. 3851 ciInstanceKlass* ik = klass->as_instance_klass(); 3852 klass_is_exact = ik->is_final(); 3853 if (!klass_is_exact && klass_change 3854 && deps != nullptr && UseUniqueSubclasses) { 3855 ciInstanceKlass* sub = ik->unique_concrete_subklass(); 3856 if (sub != nullptr) { 3857 deps->assert_abstract_with_unique_concrete_subtype(ik, sub); 3858 klass = ik = sub; 3859 klass_is_exact = sub->is_final(); 3860 } 3861 } 3862 if (!klass_is_exact && try_for_exact && deps != nullptr && 3863 !ik->is_interface() && !ik->has_subklass()) { 3864 // Add a dependence; if concrete subclass added we need to recompile 3865 deps->assert_leaf_type(ik); 3866 klass_is_exact = true; 3867 } 3868 } 3869 const TypeInterfaces* interfaces = TypePtr::interfaces(klass, true, true, false, interface_handling); 3870 return TypeInstPtr::make(TypePtr::BotPTR, klass, interfaces, klass_is_exact, nullptr, Offset(0)); 3871 } else if (klass->is_obj_array_klass()) { 3872 // Element is an object or inline type array. Recursively call ourself. 3873 const TypeOopPtr* etype = TypeOopPtr::make_from_klass_common(klass->as_array_klass()->element_klass(), /* klass_change= */ false, try_for_exact, interface_handling); 3874 // Determine null-free/flat properties 3875 const TypeOopPtr* exact_etype = etype; 3876 if (etype->can_be_inline_type()) { 3877 // Use exact type if element can be an inline type 3878 exact_etype = TypeOopPtr::make_from_klass_common(klass->as_array_klass()->element_klass(), /* klass_change= */ true, /* try_for_exact= */ true, interface_handling); 3879 } 3880 bool not_null_free = !exact_etype->can_be_inline_type(); 3881 bool not_flat = !UseFlatArray || not_null_free || (exact_etype->is_inlinetypeptr() && !exact_etype->inline_klass()->flat_in_array()); 3882 3883 // TODO 8325106 Fix comment 3884 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 3885 bool xk = etype->klass_is_exact() && !etype->is_inlinetypeptr(); 3886 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS, /* stable= */ false, /* flat= */ false, not_flat, not_null_free); 3887 // We used to pass NotNull in here, asserting that the sub-arrays 3888 // are all not-null. This is not true in generally, as code can 3889 // slam nullptrs down in the subarrays. 3890 const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, nullptr, xk, Offset(0)); 3891 return arr; 3892 } else if (klass->is_type_array_klass()) { 3893 // Element is an typeArray 3894 const Type* etype = get_const_basic_type(klass->as_type_array_klass()->element_type()); 3895 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS, 3896 /* stable= */ false, /* flat= */ false, /* not_flat= */ true, /* not_null_free= */ true); 3897 // We used to pass NotNull in here, asserting that the array pointer 3898 // is not-null. That was not true in general. 3899 const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, klass, true, Offset(0)); 3900 return arr; 3901 } else if (klass->is_flat_array_klass()) { 3902 const TypeOopPtr* etype = TypeOopPtr::make_from_klass_raw(klass->as_array_klass()->element_klass(), trust_interfaces); 3903 etype = etype->join_speculative(TypePtr::NOTNULL)->is_oopptr(); 3904 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::POS, /* stable= */ false, /* flat= */ true); 3905 const TypeAryPtr* arr = TypeAryPtr::make(TypePtr::BotPTR, arr0, klass, true, Offset(0)); 3906 return arr; 3907 } else { 3908 ShouldNotReachHere(); 3909 return nullptr; 3910 } 3911 } 3912 3913 //------------------------------make_from_constant----------------------------- 3914 // Make a java pointer from an oop constant 3915 const TypeOopPtr* TypeOopPtr::make_from_constant(ciObject* o, bool require_constant) { 3916 assert(!o->is_null_object(), "null object not yet handled here."); 3917 3918 const bool make_constant = require_constant || o->should_be_constant(); 3919 3920 ciKlass* klass = o->klass(); 3921 if (klass->is_instance_klass() || klass->is_inlinetype()) { 3922 // Element is an instance or inline type 3923 if (make_constant) { 3924 return TypeInstPtr::make(o); 3925 } else { 3926 return TypeInstPtr::make(TypePtr::NotNull, klass, true, nullptr, Offset(0)); 3927 } 3928 } else if (klass->is_obj_array_klass()) { 3929 // Element is an object array. Recursively call ourself. 3930 const TypeOopPtr* etype = TypeOopPtr::make_from_klass_raw(klass->as_array_klass()->element_klass(), trust_interfaces); 3931 bool is_flat = o->as_obj_array()->is_flat(); 3932 bool is_null_free = o->as_obj_array()->is_null_free(); 3933 if (is_null_free) { 3934 etype = etype->join_speculative(TypePtr::NOTNULL)->is_oopptr(); 3935 } 3936 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length()), 3937 /* stable= */ false, /* flat= */ false, /* not_flat= */ !is_flat, /* not_null_free= */ !is_null_free); 3938 // We used to pass NotNull in here, asserting that the sub-arrays 3939 // are all not-null. This is not true in generally, as code can 3940 // slam nulls down in the subarrays. 3941 if (make_constant) { 3942 return TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, Offset(0)); 3943 } else { 3944 return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, Offset(0)); 3945 } 3946 } else if (klass->is_type_array_klass()) { 3947 // Element is an typeArray 3948 const Type* etype = (Type*)get_const_basic_type(klass->as_type_array_klass()->element_type()); 3949 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length()), 3950 /* stable= */ false, /* flat= */ false, /* not_flat= */ true, /* not_null_free= */ true); 3951 // We used to pass NotNull in here, asserting that the array pointer 3952 // is not-null. That was not true in general. 3953 if (make_constant) { 3954 return TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, Offset(0)); 3955 } else { 3956 return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, Offset(0)); 3957 } 3958 } else if (klass->is_flat_array_klass()) { 3959 const TypeOopPtr* etype = TypeOopPtr::make_from_klass_raw(klass->as_array_klass()->element_klass(), trust_interfaces); 3960 etype = etype->join_speculative(TypePtr::NOTNULL)->is_oopptr(); 3961 const TypeAry* arr0 = TypeAry::make(etype, TypeInt::make(o->as_array()->length()), /* stable= */ false, /* flat= */ true); 3962 // We used to pass NotNull in here, asserting that the sub-arrays 3963 // are all not-null. This is not true in generally, as code can 3964 // slam nullptrs down in the subarrays. 3965 if (make_constant) { 3966 return TypeAryPtr::make(TypePtr::Constant, o, arr0, klass, true, Offset(0)); 3967 } else { 3968 return TypeAryPtr::make(TypePtr::NotNull, arr0, klass, true, Offset(0)); 3969 } 3970 } 3971 3972 fatal("unhandled object type"); 3973 return nullptr; 3974 } 3975 3976 //------------------------------get_con---------------------------------------- 3977 intptr_t TypeOopPtr::get_con() const { 3978 assert( _ptr == Null || _ptr == Constant, "" ); 3979 assert(offset() >= 0, ""); 3980 3981 if (offset() != 0) { 3982 // After being ported to the compiler interface, the compiler no longer 3983 // directly manipulates the addresses of oops. Rather, it only has a pointer 3984 // to a handle at compile time. This handle is embedded in the generated 3985 // code and dereferenced at the time the nmethod is made. Until that time, 3986 // it is not reasonable to do arithmetic with the addresses of oops (we don't 3987 // have access to the addresses!). This does not seem to currently happen, 3988 // but this assertion here is to help prevent its occurrence. 3989 tty->print_cr("Found oop constant with non-zero offset"); 3990 ShouldNotReachHere(); 3991 } 3992 3993 return (intptr_t)const_oop()->constant_encoding(); 3994 } 3995 3996 3997 //-----------------------------filter------------------------------------------ 3998 // Do not allow interface-vs.-noninterface joins to collapse to top. 3999 const Type *TypeOopPtr::filter_helper(const Type *kills, bool include_speculative) const { 4000 4001 const Type* ft = join_helper(kills, include_speculative); 4002 const TypeInstPtr* ftip = ft->isa_instptr(); 4003 const TypeInstPtr* ktip = kills->isa_instptr(); 4004 4005 if (ft->empty()) { 4006 return Type::TOP; // Canonical empty value 4007 } 4008 4009 return ft; 4010 } 4011 4012 //------------------------------eq--------------------------------------------- 4013 // Structural equality check for Type representations 4014 bool TypeOopPtr::eq( const Type *t ) const { 4015 const TypeOopPtr *a = (const TypeOopPtr*)t; 4016 if (_klass_is_exact != a->_klass_is_exact || 4017 _instance_id != a->_instance_id) return false; 4018 ciObject* one = const_oop(); 4019 ciObject* two = a->const_oop(); 4020 if (one == nullptr || two == nullptr) { 4021 return (one == two) && TypePtr::eq(t); 4022 } else { 4023 return one->equals(two) && TypePtr::eq(t); 4024 } 4025 } 4026 4027 //------------------------------hash------------------------------------------- 4028 // Type-specific hashing function. 4029 uint TypeOopPtr::hash(void) const { 4030 return 4031 (uint)(const_oop() ? const_oop()->hash() : 0) + 4032 (uint)_klass_is_exact + 4033 (uint)_instance_id + TypePtr::hash(); 4034 } 4035 4036 //------------------------------dump2------------------------------------------ 4037 #ifndef PRODUCT 4038 void TypeOopPtr::dump2( Dict &d, uint depth, outputStream *st ) const { 4039 st->print("oopptr:%s", ptr_msg[_ptr]); 4040 if( _klass_is_exact ) st->print(":exact"); 4041 if( const_oop() ) st->print(INTPTR_FORMAT, p2i(const_oop())); 4042 _offset.dump2(st); 4043 if (_instance_id == InstanceTop) 4044 st->print(",iid=top"); 4045 else if (_instance_id != InstanceBot) 4046 st->print(",iid=%d",_instance_id); 4047 4048 dump_inline_depth(st); 4049 dump_speculative(st); 4050 } 4051 #endif 4052 4053 //------------------------------singleton-------------------------------------- 4054 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 4055 // constants 4056 bool TypeOopPtr::singleton(void) const { 4057 // detune optimizer to not generate constant oop + constant offset as a constant! 4058 // TopPTR, Null, AnyNull, Constant are all singletons 4059 return (offset() == 0) && !below_centerline(_ptr); 4060 } 4061 4062 //------------------------------add_offset------------------------------------- 4063 const TypePtr* TypeOopPtr::add_offset(intptr_t offset) const { 4064 return make(_ptr, xadd_offset(offset), _instance_id, add_offset_speculative(offset), _inline_depth); 4065 } 4066 4067 const TypeOopPtr* TypeOopPtr::with_offset(intptr_t offset) const { 4068 return make(_ptr, Offset(offset), _instance_id, with_offset_speculative(offset), _inline_depth); 4069 } 4070 4071 /** 4072 * Return same type without a speculative part 4073 */ 4074 const TypeOopPtr* TypeOopPtr::remove_speculative() const { 4075 if (_speculative == nullptr) { 4076 return this; 4077 } 4078 assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); 4079 return make(_ptr, _offset, _instance_id, nullptr, _inline_depth); 4080 } 4081 4082 /** 4083 * Return same type but drop speculative part if we know we won't use 4084 * it 4085 */ 4086 const Type* TypeOopPtr::cleanup_speculative() const { 4087 // If the klass is exact and the ptr is not null then there's 4088 // nothing that the speculative type can help us with 4089 if (klass_is_exact() && !maybe_null()) { 4090 return remove_speculative(); 4091 } 4092 return TypePtr::cleanup_speculative(); 4093 } 4094 4095 /** 4096 * Return same type but with a different inline depth (used for speculation) 4097 * 4098 * @param depth depth to meet with 4099 */ 4100 const TypePtr* TypeOopPtr::with_inline_depth(int depth) const { 4101 if (!UseInlineDepthForSpeculativeTypes) { 4102 return this; 4103 } 4104 return make(_ptr, _offset, _instance_id, _speculative, depth); 4105 } 4106 4107 //------------------------------with_instance_id-------------------------------- 4108 const TypePtr* TypeOopPtr::with_instance_id(int instance_id) const { 4109 assert(_instance_id != -1, "should be known"); 4110 return make(_ptr, _offset, instance_id, _speculative, _inline_depth); 4111 } 4112 4113 //------------------------------meet_instance_id-------------------------------- 4114 int TypeOopPtr::meet_instance_id( int instance_id ) const { 4115 // Either is 'TOP' instance? Return the other instance! 4116 if( _instance_id == InstanceTop ) return instance_id; 4117 if( instance_id == InstanceTop ) return _instance_id; 4118 // If either is different, return 'BOTTOM' instance 4119 if( _instance_id != instance_id ) return InstanceBot; 4120 return _instance_id; 4121 } 4122 4123 //------------------------------dual_instance_id-------------------------------- 4124 int TypeOopPtr::dual_instance_id( ) const { 4125 if( _instance_id == InstanceTop ) return InstanceBot; // Map TOP into BOTTOM 4126 if( _instance_id == InstanceBot ) return InstanceTop; // Map BOTTOM into TOP 4127 return _instance_id; // Map everything else into self 4128 } 4129 4130 4131 const TypeInterfaces* TypeOopPtr::meet_interfaces(const TypeOopPtr* other) const { 4132 if (above_centerline(_ptr) && above_centerline(other->_ptr)) { 4133 return _interfaces->union_with(other->_interfaces); 4134 } else if (above_centerline(_ptr) && !above_centerline(other->_ptr)) { 4135 return other->_interfaces; 4136 } else if (above_centerline(other->_ptr) && !above_centerline(_ptr)) { 4137 return _interfaces; 4138 } 4139 return _interfaces->intersection_with(other->_interfaces); 4140 } 4141 4142 /** 4143 * Check whether new profiling would improve speculative type 4144 * 4145 * @param exact_kls class from profiling 4146 * @param inline_depth inlining depth of profile point 4147 * 4148 * @return true if type profile is valuable 4149 */ 4150 bool TypeOopPtr::would_improve_type(ciKlass* exact_kls, int inline_depth) const { 4151 // no way to improve an already exact type 4152 if (klass_is_exact()) { 4153 return false; 4154 } 4155 return TypePtr::would_improve_type(exact_kls, inline_depth); 4156 } 4157 4158 //============================================================================= 4159 // Convenience common pre-built types. 4160 const TypeInstPtr *TypeInstPtr::NOTNULL; 4161 const TypeInstPtr *TypeInstPtr::BOTTOM; 4162 const TypeInstPtr *TypeInstPtr::MIRROR; 4163 const TypeInstPtr *TypeInstPtr::MARK; 4164 const TypeInstPtr *TypeInstPtr::KLASS; 4165 4166 // Is there a single ciKlass* that can represent that type? 4167 ciKlass* TypeInstPtr::exact_klass_helper() const { 4168 if (_interfaces->empty()) { 4169 return _klass; 4170 } 4171 if (_klass != ciEnv::current()->Object_klass()) { 4172 if (_interfaces->eq(_klass->as_instance_klass())) { 4173 return _klass; 4174 } 4175 return nullptr; 4176 } 4177 return _interfaces->exact_klass(); 4178 } 4179 4180 //------------------------------TypeInstPtr------------------------------------- 4181 TypeInstPtr::TypeInstPtr(PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, bool xk, ciObject* o, Offset off, 4182 bool flat_in_array, int instance_id, const TypePtr* speculative, int inline_depth) 4183 : TypeOopPtr(InstPtr, ptr, k, interfaces, xk, o, off, Offset::bottom, instance_id, speculative, inline_depth), 4184 _flat_in_array(flat_in_array) { 4185 assert(k == nullptr || !k->is_loaded() || !k->is_interface(), "no interface here"); 4186 assert(k != nullptr && 4187 (k->is_loaded() || o == nullptr), 4188 "cannot have constants with non-loaded klass"); 4189 assert(!klass()->flat_in_array() || flat_in_array, "Should be flat in array"); 4190 assert(!flat_in_array || can_be_inline_type(), "Only inline types can be flat in array"); 4191 }; 4192 4193 //------------------------------make------------------------------------------- 4194 const TypeInstPtr *TypeInstPtr::make(PTR ptr, 4195 ciKlass* k, 4196 const TypeInterfaces* interfaces, 4197 bool xk, 4198 ciObject* o, 4199 Offset offset, 4200 bool flat_in_array, 4201 int instance_id, 4202 const TypePtr* speculative, 4203 int inline_depth) { 4204 assert( !k->is_loaded() || k->is_instance_klass(), "Must be for instance"); 4205 // Either const_oop() is null or else ptr is Constant 4206 assert( (!o && ptr != Constant) || (o && ptr == Constant), 4207 "constant pointers must have a value supplied" ); 4208 // Ptr is never Null 4209 assert( ptr != Null, "null pointers are not typed" ); 4210 4211 assert(instance_id <= 0 || xk, "instances are always exactly typed"); 4212 if (ptr == Constant) { 4213 // Note: This case includes meta-object constants, such as methods. 4214 xk = true; 4215 } else if (k->is_loaded()) { 4216 ciInstanceKlass* ik = k->as_instance_klass(); 4217 if (!xk && ik->is_final()) xk = true; // no inexact final klass 4218 assert(!ik->is_interface(), "no interface here"); 4219 if (xk && ik->is_interface()) xk = false; // no exact interface 4220 } 4221 4222 // Check if this type is known to be flat in arrays 4223 flat_in_array = flat_in_array || k->flat_in_array(); 4224 4225 // Now hash this baby 4226 TypeInstPtr *result = 4227 (TypeInstPtr*)(new TypeInstPtr(ptr, k, interfaces, xk, o, offset, flat_in_array, instance_id, speculative, inline_depth))->hashcons(); 4228 4229 return result; 4230 } 4231 4232 const TypeInterfaces* TypePtr::interfaces(ciKlass*& k, bool klass, bool interface, bool array, InterfaceHandling interface_handling) { 4233 if (k->is_instance_klass()) { 4234 if (k->is_loaded()) { 4235 if (k->is_interface() && interface_handling == ignore_interfaces) { 4236 assert(interface, "no interface expected"); 4237 k = ciEnv::current()->Object_klass(); 4238 const TypeInterfaces* interfaces = TypeInterfaces::make(); 4239 return interfaces; 4240 } 4241 GrowableArray<ciInstanceKlass *>* k_interfaces = k->as_instance_klass()->transitive_interfaces(); 4242 const TypeInterfaces* interfaces = TypeInterfaces::make(k_interfaces); 4243 if (k->is_interface()) { 4244 assert(interface, "no interface expected"); 4245 k = ciEnv::current()->Object_klass(); 4246 } else { 4247 assert(klass, "no instance klass expected"); 4248 } 4249 return interfaces; 4250 } 4251 const TypeInterfaces* interfaces = TypeInterfaces::make(); 4252 return interfaces; 4253 } 4254 assert(array, "no array expected"); 4255 assert(k->is_array_klass(), "Not an array?"); 4256 ciType* e = k->as_array_klass()->base_element_type(); 4257 if (e->is_loaded() && e->is_instance_klass() && e->as_instance_klass()->is_interface()) { 4258 if (interface_handling == ignore_interfaces) { 4259 k = ciObjArrayKlass::make(ciEnv::current()->Object_klass(), k->as_array_klass()->dimension()); 4260 } 4261 } 4262 return TypeAryPtr::_array_interfaces; 4263 } 4264 4265 /** 4266 * Create constant type for a constant boxed value 4267 */ 4268 const Type* TypeInstPtr::get_const_boxed_value() const { 4269 assert(is_ptr_to_boxed_value(), "should be called only for boxed value"); 4270 assert((const_oop() != nullptr), "should be called only for constant object"); 4271 ciConstant constant = const_oop()->as_instance()->field_value_by_offset(offset()); 4272 BasicType bt = constant.basic_type(); 4273 switch (bt) { 4274 case T_BOOLEAN: return TypeInt::make(constant.as_boolean()); 4275 case T_INT: return TypeInt::make(constant.as_int()); 4276 case T_CHAR: return TypeInt::make(constant.as_char()); 4277 case T_BYTE: return TypeInt::make(constant.as_byte()); 4278 case T_SHORT: return TypeInt::make(constant.as_short()); 4279 case T_FLOAT: return TypeF::make(constant.as_float()); 4280 case T_DOUBLE: return TypeD::make(constant.as_double()); 4281 case T_LONG: return TypeLong::make(constant.as_long()); 4282 default: break; 4283 } 4284 fatal("Invalid boxed value type '%s'", type2name(bt)); 4285 return nullptr; 4286 } 4287 4288 //------------------------------cast_to_ptr_type------------------------------- 4289 const TypeInstPtr* TypeInstPtr::cast_to_ptr_type(PTR ptr) const { 4290 if( ptr == _ptr ) return this; 4291 // Reconstruct _sig info here since not a problem with later lazy 4292 // construction, _sig will show up on demand. 4293 return make(ptr, klass(), _interfaces, klass_is_exact(), ptr == Constant ? const_oop() : nullptr, _offset, _flat_in_array, _instance_id, _speculative, _inline_depth); 4294 } 4295 4296 4297 //-----------------------------cast_to_exactness------------------------------- 4298 const TypeInstPtr* TypeInstPtr::cast_to_exactness(bool klass_is_exact) const { 4299 if( klass_is_exact == _klass_is_exact ) return this; 4300 if (!_klass->is_loaded()) return this; 4301 ciInstanceKlass* ik = _klass->as_instance_klass(); 4302 if( (ik->is_final() || _const_oop) ) return this; // cannot clear xk 4303 assert(!ik->is_interface(), "no interface here"); 4304 return make(ptr(), klass(), _interfaces, klass_is_exact, const_oop(), _offset, _flat_in_array, _instance_id, _speculative, _inline_depth); 4305 } 4306 4307 //-----------------------------cast_to_instance_id---------------------------- 4308 const TypeInstPtr* TypeInstPtr::cast_to_instance_id(int instance_id) const { 4309 if( instance_id == _instance_id ) return this; 4310 return make(_ptr, klass(), _interfaces, _klass_is_exact, const_oop(), _offset, _flat_in_array, instance_id, _speculative, _inline_depth); 4311 } 4312 4313 //------------------------------xmeet_unloaded--------------------------------- 4314 // Compute the MEET of two InstPtrs when at least one is unloaded. 4315 // Assume classes are different since called after check for same name/class-loader 4316 const TypeInstPtr *TypeInstPtr::xmeet_unloaded(const TypeInstPtr *tinst, const TypeInterfaces* interfaces) const { 4317 Offset off = meet_offset(tinst->offset()); 4318 PTR ptr = meet_ptr(tinst->ptr()); 4319 int instance_id = meet_instance_id(tinst->instance_id()); 4320 const TypePtr* speculative = xmeet_speculative(tinst); 4321 int depth = meet_inline_depth(tinst->inline_depth()); 4322 4323 const TypeInstPtr *loaded = is_loaded() ? this : tinst; 4324 const TypeInstPtr *unloaded = is_loaded() ? tinst : this; 4325 if( loaded->klass()->equals(ciEnv::current()->Object_klass()) ) { 4326 // 4327 // Meet unloaded class with java/lang/Object 4328 // 4329 // Meet 4330 // | Unloaded Class 4331 // Object | TOP | AnyNull | Constant | NotNull | BOTTOM | 4332 // =================================================================== 4333 // TOP | ..........................Unloaded......................| 4334 // AnyNull | U-AN |................Unloaded......................| 4335 // Constant | ... O-NN .................................. | O-BOT | 4336 // NotNull | ... O-NN .................................. | O-BOT | 4337 // BOTTOM | ........................Object-BOTTOM ..................| 4338 // 4339 assert(loaded->ptr() != TypePtr::Null, "insanity check"); 4340 // 4341 if (loaded->ptr() == TypePtr::TopPTR) { return unloaded; } 4342 else if (loaded->ptr() == TypePtr::AnyNull) { return make(ptr, unloaded->klass(), interfaces, false, nullptr, off, false, instance_id, speculative, depth); } 4343 else if (loaded->ptr() == TypePtr::BotPTR) { return TypeInstPtr::BOTTOM; } 4344 else if (loaded->ptr() == TypePtr::Constant || loaded->ptr() == TypePtr::NotNull) { 4345 if (unloaded->ptr() == TypePtr::BotPTR) { return TypeInstPtr::BOTTOM; } 4346 else { return TypeInstPtr::NOTNULL; } 4347 } 4348 else if (unloaded->ptr() == TypePtr::TopPTR) { return unloaded; } 4349 4350 return unloaded->cast_to_ptr_type(TypePtr::AnyNull)->is_instptr(); 4351 } 4352 4353 // Both are unloaded, not the same class, not Object 4354 // Or meet unloaded with a different loaded class, not java/lang/Object 4355 if (ptr != TypePtr::BotPTR) { 4356 return TypeInstPtr::NOTNULL; 4357 } 4358 return TypeInstPtr::BOTTOM; 4359 } 4360 4361 4362 //------------------------------meet------------------------------------------- 4363 // Compute the MEET of two types. It returns a new Type object. 4364 const Type *TypeInstPtr::xmeet_helper(const Type *t) const { 4365 // Perform a fast test for common case; meeting the same types together. 4366 if( this == t ) return this; // Meeting same type-rep? 4367 4368 // Current "this->_base" is Pointer 4369 switch (t->base()) { // switch on original type 4370 4371 case Int: // Mixing ints & oops happens when javac 4372 case Long: // reuses local variables 4373 case FloatTop: 4374 case FloatCon: 4375 case FloatBot: 4376 case DoubleTop: 4377 case DoubleCon: 4378 case DoubleBot: 4379 case NarrowOop: 4380 case NarrowKlass: 4381 case Bottom: // Ye Olde Default 4382 return Type::BOTTOM; 4383 case Top: 4384 return this; 4385 4386 default: // All else is a mistake 4387 typerr(t); 4388 4389 case MetadataPtr: 4390 case KlassPtr: 4391 case InstKlassPtr: 4392 case AryKlassPtr: 4393 case RawPtr: return TypePtr::BOTTOM; 4394 4395 case AryPtr: { // All arrays inherit from Object class 4396 // Call in reverse direction to avoid duplication 4397 return t->is_aryptr()->xmeet_helper(this); 4398 } 4399 4400 case OopPtr: { // Meeting to OopPtrs 4401 // Found a OopPtr type vs self-InstPtr type 4402 const TypeOopPtr *tp = t->is_oopptr(); 4403 Offset offset = meet_offset(tp->offset()); 4404 PTR ptr = meet_ptr(tp->ptr()); 4405 switch (tp->ptr()) { 4406 case TopPTR: 4407 case AnyNull: { 4408 int instance_id = meet_instance_id(InstanceTop); 4409 const TypePtr* speculative = xmeet_speculative(tp); 4410 int depth = meet_inline_depth(tp->inline_depth()); 4411 return make(ptr, klass(), _interfaces, klass_is_exact(), 4412 (ptr == Constant ? const_oop() : nullptr), offset, flat_in_array(), instance_id, speculative, depth); 4413 } 4414 case NotNull: 4415 case BotPTR: { 4416 int instance_id = meet_instance_id(tp->instance_id()); 4417 const TypePtr* speculative = xmeet_speculative(tp); 4418 int depth = meet_inline_depth(tp->inline_depth()); 4419 return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth); 4420 } 4421 default: typerr(t); 4422 } 4423 } 4424 4425 case AnyPtr: { // Meeting to AnyPtrs 4426 // Found an AnyPtr type vs self-InstPtr type 4427 const TypePtr *tp = t->is_ptr(); 4428 Offset offset = meet_offset(tp->offset()); 4429 PTR ptr = meet_ptr(tp->ptr()); 4430 int instance_id = meet_instance_id(InstanceTop); 4431 const TypePtr* speculative = xmeet_speculative(tp); 4432 int depth = meet_inline_depth(tp->inline_depth()); 4433 switch (tp->ptr()) { 4434 case Null: 4435 if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); 4436 // else fall through to AnyNull 4437 case TopPTR: 4438 case AnyNull: { 4439 return make(ptr, klass(), _interfaces, klass_is_exact(), 4440 (ptr == Constant ? const_oop() : nullptr), offset, flat_in_array(), instance_id, speculative, depth); 4441 } 4442 case NotNull: 4443 case BotPTR: 4444 return TypePtr::make(AnyPtr, ptr, offset, speculative,depth); 4445 default: typerr(t); 4446 } 4447 } 4448 4449 /* 4450 A-top } 4451 / | \ } Tops 4452 B-top A-any C-top } 4453 | / | \ | } Any-nulls 4454 B-any | C-any } 4455 | | | 4456 B-con A-con C-con } constants; not comparable across classes 4457 | | | 4458 B-not | C-not } 4459 | \ | / | } not-nulls 4460 B-bot A-not C-bot } 4461 \ | / } Bottoms 4462 A-bot } 4463 */ 4464 4465 case InstPtr: { // Meeting 2 Oops? 4466 // Found an InstPtr sub-type vs self-InstPtr type 4467 const TypeInstPtr *tinst = t->is_instptr(); 4468 Offset off = meet_offset(tinst->offset()); 4469 PTR ptr = meet_ptr(tinst->ptr()); 4470 int instance_id = meet_instance_id(tinst->instance_id()); 4471 const TypePtr* speculative = xmeet_speculative(tinst); 4472 int depth = meet_inline_depth(tinst->inline_depth()); 4473 const TypeInterfaces* interfaces = meet_interfaces(tinst); 4474 4475 ciKlass* tinst_klass = tinst->klass(); 4476 ciKlass* this_klass = klass(); 4477 4478 ciKlass* res_klass = nullptr; 4479 bool res_xk = false; 4480 bool res_flat_in_array = false; 4481 const Type* res; 4482 MeetResult kind = meet_instptr(ptr, interfaces, this, tinst, res_klass, res_xk, res_flat_in_array); 4483 4484 if (kind == UNLOADED) { 4485 // One of these classes has not been loaded 4486 const TypeInstPtr* unloaded_meet = xmeet_unloaded(tinst, interfaces); 4487 #ifndef PRODUCT 4488 if (PrintOpto && Verbose) { 4489 tty->print("meet of unloaded classes resulted in: "); 4490 unloaded_meet->dump(); 4491 tty->cr(); 4492 tty->print(" this == "); 4493 dump(); 4494 tty->cr(); 4495 tty->print(" tinst == "); 4496 tinst->dump(); 4497 tty->cr(); 4498 } 4499 #endif 4500 res = unloaded_meet; 4501 } else { 4502 if (kind == NOT_SUBTYPE && instance_id > 0) { 4503 instance_id = InstanceBot; 4504 } else if (kind == LCA) { 4505 instance_id = InstanceBot; 4506 } 4507 ciObject* o = nullptr; // Assume not constant when done 4508 ciObject* this_oop = const_oop(); 4509 ciObject* tinst_oop = tinst->const_oop(); 4510 if (ptr == Constant) { 4511 if (this_oop != nullptr && tinst_oop != nullptr && 4512 this_oop->equals(tinst_oop)) 4513 o = this_oop; 4514 else if (above_centerline(_ptr)) { 4515 assert(!tinst_klass->is_interface(), ""); 4516 o = tinst_oop; 4517 } else if (above_centerline(tinst->_ptr)) { 4518 assert(!this_klass->is_interface(), ""); 4519 o = this_oop; 4520 } else 4521 ptr = NotNull; 4522 } 4523 res = make(ptr, res_klass, interfaces, res_xk, o, off, res_flat_in_array, instance_id, speculative, depth); 4524 } 4525 4526 return res; 4527 4528 } // End of case InstPtr 4529 4530 } // End of switch 4531 return this; // Return the double constant 4532 } 4533 4534 template<class T> TypePtr::MeetResult TypePtr::meet_instptr(PTR& ptr, const TypeInterfaces*& interfaces, const T* this_type, const T* other_type, 4535 ciKlass*& res_klass, bool& res_xk, bool& res_flat_in_array) { 4536 ciKlass* this_klass = this_type->klass(); 4537 ciKlass* other_klass = other_type->klass(); 4538 const bool this_flat_in_array = this_type->flat_in_array(); 4539 const bool other_flat_in_array = other_type->flat_in_array(); 4540 const bool this_not_flat_in_array = this_type->not_flat_in_array(); 4541 const bool other_not_flat_in_array = other_type->not_flat_in_array(); 4542 4543 bool this_xk = this_type->klass_is_exact(); 4544 bool other_xk = other_type->klass_is_exact(); 4545 PTR this_ptr = this_type->ptr(); 4546 PTR other_ptr = other_type->ptr(); 4547 const TypeInterfaces* this_interfaces = this_type->interfaces(); 4548 const TypeInterfaces* other_interfaces = other_type->interfaces(); 4549 // Check for easy case; klasses are equal (and perhaps not loaded!) 4550 // If we have constants, then we created oops so classes are loaded 4551 // and we can handle the constants further down. This case handles 4552 // both-not-loaded or both-loaded classes 4553 if (ptr != Constant && this_klass->equals(other_klass) && this_xk == other_xk && this_flat_in_array == other_flat_in_array) { 4554 res_klass = this_klass; 4555 res_xk = this_xk; 4556 res_flat_in_array = this_flat_in_array; 4557 return QUICK; 4558 } 4559 4560 // Classes require inspection in the Java klass hierarchy. Must be loaded. 4561 if (!other_klass->is_loaded() || !this_klass->is_loaded()) { 4562 return UNLOADED; 4563 } 4564 4565 // !!! Here's how the symmetry requirement breaks down into invariants: 4566 // If we split one up & one down AND they subtype, take the down man. 4567 // If we split one up & one down AND they do NOT subtype, "fall hard". 4568 // If both are up and they subtype, take the subtype class. 4569 // If both are up and they do NOT subtype, "fall hard". 4570 // If both are down and they subtype, take the supertype class. 4571 // If both are down and they do NOT subtype, "fall hard". 4572 // Constants treated as down. 4573 4574 // Now, reorder the above list; observe that both-down+subtype is also 4575 // "fall hard"; "fall hard" becomes the default case: 4576 // If we split one up & one down AND they subtype, take the down man. 4577 // If both are up and they subtype, take the subtype class. 4578 4579 // If both are down and they subtype, "fall hard". 4580 // If both are down and they do NOT subtype, "fall hard". 4581 // If both are up and they do NOT subtype, "fall hard". 4582 // If we split one up & one down AND they do NOT subtype, "fall hard". 4583 4584 // If a proper subtype is exact, and we return it, we return it exactly. 4585 // If a proper supertype is exact, there can be no subtyping relationship! 4586 // If both types are equal to the subtype, exactness is and-ed below the 4587 // centerline and or-ed above it. (N.B. Constants are always exact.) 4588 4589 // Check for subtyping: 4590 // Flat in array matrix, yes = y, no = n, maybe = m, top/empty = T: 4591 // yes maybe no -> Super Klass 4592 // yes y y y 4593 // maybe y m m 4594 // no T n n 4595 // | 4596 // v 4597 // Sub Klass 4598 4599 const T* subtype = nullptr; 4600 bool subtype_exact = false; 4601 bool flat_in_array = false; 4602 if (this_type->is_same_java_type_as(other_type)) { 4603 subtype = this_type; 4604 subtype_exact = below_centerline(ptr) ? (this_xk && other_xk) : (this_xk || other_xk); 4605 flat_in_array = below_centerline(ptr) ? (this_flat_in_array && other_flat_in_array) : (this_flat_in_array || other_flat_in_array); 4606 } else if (!other_xk && is_meet_subtype_of(this_type, other_type)) { 4607 subtype = this_type; // Pick subtyping class 4608 subtype_exact = this_xk; 4609 bool other_flat_this_maybe_flat = other_flat_in_array && (!this_flat_in_array && !this_not_flat_in_array); 4610 flat_in_array = this_flat_in_array || other_flat_this_maybe_flat; 4611 } else if (!this_xk && is_meet_subtype_of(other_type, this_type)) { 4612 subtype = other_type; // Pick subtyping class 4613 subtype_exact = other_xk; 4614 bool this_flat_other_maybe_flat = this_flat_in_array && (!other_flat_in_array && !other_not_flat_in_array); 4615 flat_in_array = other_flat_in_array || this_flat_other_maybe_flat; 4616 } 4617 4618 if (subtype) { 4619 if (above_centerline(ptr)) { 4620 // Both types are empty. 4621 this_type = other_type = subtype; 4622 this_xk = other_xk = subtype_exact; 4623 } else if (above_centerline(this_ptr) && !above_centerline(other_ptr)) { 4624 // this_type is empty while other_type is not. Take other_type. 4625 this_type = other_type; 4626 this_xk = other_xk; 4627 flat_in_array = other_flat_in_array; 4628 } else if (above_centerline(other_ptr) && !above_centerline(this_ptr)) { 4629 // other_type is empty while this_type is not. Take this_type. 4630 other_type = this_type; // this is down; keep down man 4631 flat_in_array = this_flat_in_array; 4632 } else { 4633 // this_type and other_type are both non-empty. 4634 this_xk = subtype_exact; // either they are equal, or we'll do an LCA 4635 } 4636 } 4637 4638 // Check for classes now being equal 4639 if (this_type->is_same_java_type_as(other_type)) { 4640 // If the klasses are equal, the constants may still differ. Fall to 4641 // NotNull if they do (neither constant is null; that is a special case 4642 // handled elsewhere). 4643 res_klass = this_type->klass(); 4644 res_xk = this_xk; 4645 res_flat_in_array = subtype ? flat_in_array : this_flat_in_array; 4646 return SUBTYPE; 4647 } // Else classes are not equal 4648 4649 // Since klasses are different, we require a LCA in the Java 4650 // class hierarchy - which means we have to fall to at least NotNull. 4651 if (ptr == TopPTR || ptr == AnyNull || ptr == Constant) { 4652 ptr = NotNull; 4653 } 4654 4655 interfaces = this_interfaces->intersection_with(other_interfaces); 4656 4657 // Now we find the LCA of Java classes 4658 ciKlass* k = this_klass->least_common_ancestor(other_klass); 4659 4660 res_klass = k; 4661 res_xk = false; 4662 res_flat_in_array = this_flat_in_array && other_flat_in_array; 4663 4664 return LCA; 4665 } 4666 4667 template<class T> bool TypePtr::is_meet_subtype_of(const T* sub_type, const T* super_type) { 4668 return sub_type->is_meet_subtype_of(super_type) && !(super_type->flat_in_array() && sub_type->not_flat_in_array()); 4669 } 4670 4671 //------------------------java_mirror_type-------------------------------------- 4672 ciType* TypeInstPtr::java_mirror_type(bool* is_null_free_array) const { 4673 // must be a singleton type 4674 if( const_oop() == nullptr ) return nullptr; 4675 4676 // must be of type java.lang.Class 4677 if( klass() != ciEnv::current()->Class_klass() ) return nullptr; 4678 return const_oop()->as_instance()->java_mirror_type(is_null_free_array); 4679 } 4680 4681 4682 //------------------------------xdual------------------------------------------ 4683 // Dual: do NOT dual on klasses. This means I do NOT understand the Java 4684 // inheritance mechanism. 4685 const Type *TypeInstPtr::xdual() const { 4686 return new TypeInstPtr(dual_ptr(), klass(), _interfaces, klass_is_exact(), const_oop(), dual_offset(), flat_in_array(), dual_instance_id(), dual_speculative(), dual_inline_depth()); 4687 } 4688 4689 //------------------------------eq--------------------------------------------- 4690 // Structural equality check for Type representations 4691 bool TypeInstPtr::eq( const Type *t ) const { 4692 const TypeInstPtr *p = t->is_instptr(); 4693 return 4694 klass()->equals(p->klass()) && 4695 flat_in_array() == p->flat_in_array() && 4696 _interfaces->eq(p->_interfaces) && 4697 TypeOopPtr::eq(p); // Check sub-type stuff 4698 } 4699 4700 //------------------------------hash------------------------------------------- 4701 // Type-specific hashing function. 4702 uint TypeInstPtr::hash(void) const { 4703 return klass()->hash() + TypeOopPtr::hash() + _interfaces->hash() + (uint)flat_in_array(); 4704 } 4705 4706 bool TypeInstPtr::is_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const { 4707 return TypePtr::is_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact); 4708 } 4709 4710 4711 bool TypeInstPtr::is_same_java_type_as_helper(const TypeOopPtr* other) const { 4712 return TypePtr::is_same_java_type_as_helper_for_instance(this, other); 4713 } 4714 4715 bool TypeInstPtr::maybe_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const { 4716 return TypePtr::maybe_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact); 4717 } 4718 4719 4720 //------------------------------dump2------------------------------------------ 4721 // Dump oop Type 4722 #ifndef PRODUCT 4723 void TypeInstPtr::dump2(Dict &d, uint depth, outputStream* st) const { 4724 // Print the name of the klass. 4725 klass()->print_name_on(st); 4726 _interfaces->dump(st); 4727 4728 switch( _ptr ) { 4729 case Constant: 4730 if (WizardMode || Verbose) { 4731 ResourceMark rm; 4732 stringStream ss; 4733 4734 st->print(" "); 4735 const_oop()->print_oop(&ss); 4736 // 'const_oop->print_oop()' may emit newlines('\n') into ss. 4737 // suppress newlines from it so -XX:+Verbose -XX:+PrintIdeal dumps one-liner for each node. 4738 char* buf = ss.as_string(/* c_heap= */false); 4739 StringUtils::replace_no_expand(buf, "\n", ""); 4740 st->print_raw(buf); 4741 } 4742 case BotPTR: 4743 if (!WizardMode && !Verbose) { 4744 if( _klass_is_exact ) st->print(":exact"); 4745 break; 4746 } 4747 case TopPTR: 4748 case AnyNull: 4749 case NotNull: 4750 st->print(":%s", ptr_msg[_ptr]); 4751 if( _klass_is_exact ) st->print(":exact"); 4752 break; 4753 default: 4754 break; 4755 } 4756 4757 _offset.dump2(st); 4758 4759 st->print(" *"); 4760 4761 if (flat_in_array() && !klass()->is_inlinetype()) { 4762 st->print(" (flat in array)"); 4763 } 4764 4765 if (_instance_id == InstanceTop) 4766 st->print(",iid=top"); 4767 else if (_instance_id != InstanceBot) 4768 st->print(",iid=%d",_instance_id); 4769 4770 dump_inline_depth(st); 4771 dump_speculative(st); 4772 } 4773 #endif 4774 4775 //------------------------------add_offset------------------------------------- 4776 const TypePtr* TypeInstPtr::add_offset(intptr_t offset) const { 4777 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), xadd_offset(offset), flat_in_array(), 4778 _instance_id, add_offset_speculative(offset), _inline_depth); 4779 } 4780 4781 const TypeInstPtr* TypeInstPtr::with_offset(intptr_t offset) const { 4782 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), Offset(offset), flat_in_array(), 4783 _instance_id, with_offset_speculative(offset), _inline_depth); 4784 } 4785 4786 const TypeInstPtr* TypeInstPtr::remove_speculative() const { 4787 if (_speculative == nullptr) { 4788 return this; 4789 } 4790 assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); 4791 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, flat_in_array(), 4792 _instance_id, nullptr, _inline_depth); 4793 } 4794 4795 const TypePtr* TypeInstPtr::with_inline_depth(int depth) const { 4796 if (!UseInlineDepthForSpeculativeTypes) { 4797 return this; 4798 } 4799 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, flat_in_array(), _instance_id, _speculative, depth); 4800 } 4801 4802 const TypePtr* TypeInstPtr::with_instance_id(int instance_id) const { 4803 assert(is_known_instance(), "should be known"); 4804 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, flat_in_array(), instance_id, _speculative, _inline_depth); 4805 } 4806 4807 const TypeInstPtr *TypeInstPtr::cast_to_flat_in_array() const { 4808 return make(_ptr, klass(), _interfaces, klass_is_exact(), const_oop(), _offset, true, _instance_id, _speculative, _inline_depth); 4809 } 4810 4811 const TypeKlassPtr* TypeInstPtr::as_klass_type(bool try_for_exact) const { 4812 bool xk = klass_is_exact(); 4813 ciInstanceKlass* ik = klass()->as_instance_klass(); 4814 if (try_for_exact && !xk && !ik->has_subklass() && !ik->is_final()) { 4815 if (_interfaces->eq(ik)) { 4816 Compile* C = Compile::current(); 4817 Dependencies* deps = C->dependencies(); 4818 deps->assert_leaf_type(ik); 4819 xk = true; 4820 } 4821 } 4822 return TypeInstKlassPtr::make(xk ? TypePtr::Constant : TypePtr::NotNull, klass(), _interfaces, Offset(0), flat_in_array()); 4823 } 4824 4825 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) { 4826 static_assert(std::is_base_of<T2, T1>::value, ""); 4827 4828 if (!this_one->is_instance_type(other)) { 4829 return false; 4830 } 4831 4832 if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty()) { 4833 return true; 4834 } 4835 4836 return this_one->klass()->is_subtype_of(other->klass()) && 4837 (!this_xk || this_one->_interfaces->contains(other->_interfaces)); 4838 } 4839 4840 4841 bool TypeInstPtr::is_meet_subtype_of_helper(const TypeOopPtr *other, bool this_xk, bool other_xk) const { 4842 return TypePtr::is_meet_subtype_of_helper_for_instance(this, other, this_xk, other_xk); 4843 } 4844 4845 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) { 4846 static_assert(std::is_base_of<T2, T1>::value, ""); 4847 if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty()) { 4848 return true; 4849 } 4850 4851 if (this_one->is_instance_type(other)) { 4852 return other->klass() == ciEnv::current()->Object_klass() && this_one->_interfaces->contains(other->_interfaces); 4853 } 4854 4855 int dummy; 4856 bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM); 4857 if (this_top_or_bottom) { 4858 return false; 4859 } 4860 4861 const T1* other_ary = this_one->is_array_type(other); 4862 const TypePtr* other_elem = other_ary->elem()->make_ptr(); 4863 const TypePtr* this_elem = this_one->elem()->make_ptr(); 4864 if (other_elem != nullptr && this_elem != nullptr) { 4865 return this_one->is_reference_type(this_elem)->is_meet_subtype_of_helper(this_one->is_reference_type(other_elem), this_xk, other_xk); 4866 } 4867 if (other_elem == nullptr && this_elem == nullptr) { 4868 return this_one->klass()->is_subtype_of(other->klass()); 4869 } 4870 4871 return false; 4872 } 4873 4874 bool TypeAryPtr::is_meet_subtype_of_helper(const TypeOopPtr *other, bool this_xk, bool other_xk) const { 4875 return TypePtr::is_meet_subtype_of_helper_for_array(this, other, this_xk, other_xk); 4876 } 4877 4878 bool TypeInstKlassPtr::is_meet_subtype_of_helper(const TypeKlassPtr *other, bool this_xk, bool other_xk) const { 4879 return TypePtr::is_meet_subtype_of_helper_for_instance(this, other, this_xk, other_xk); 4880 } 4881 4882 bool TypeAryKlassPtr::is_meet_subtype_of_helper(const TypeKlassPtr *other, bool this_xk, bool other_xk) const { 4883 return TypePtr::is_meet_subtype_of_helper_for_array(this, other, this_xk, other_xk); 4884 } 4885 4886 //============================================================================= 4887 // Convenience common pre-built types. 4888 const TypeAryPtr *TypeAryPtr::RANGE; 4889 const TypeAryPtr *TypeAryPtr::OOPS; 4890 const TypeAryPtr *TypeAryPtr::NARROWOOPS; 4891 const TypeAryPtr *TypeAryPtr::BYTES; 4892 const TypeAryPtr *TypeAryPtr::SHORTS; 4893 const TypeAryPtr *TypeAryPtr::CHARS; 4894 const TypeAryPtr *TypeAryPtr::INTS; 4895 const TypeAryPtr *TypeAryPtr::LONGS; 4896 const TypeAryPtr *TypeAryPtr::FLOATS; 4897 const TypeAryPtr *TypeAryPtr::DOUBLES; 4898 const TypeAryPtr *TypeAryPtr::INLINES; 4899 4900 //------------------------------make------------------------------------------- 4901 const TypeAryPtr* TypeAryPtr::make(PTR ptr, const TypeAry *ary, ciKlass* k, bool xk, Offset offset, Offset field_offset, 4902 int instance_id, const TypePtr* speculative, int inline_depth) { 4903 assert(!(k == nullptr && ary->_elem->isa_int()), 4904 "integral arrays must be pre-equipped with a class"); 4905 if (!xk) xk = ary->ary_must_be_exact(); 4906 assert(instance_id <= 0 || xk, "instances are always exactly typed"); 4907 if (k != nullptr && k->is_loaded() && k->is_obj_array_klass() && 4908 k->as_obj_array_klass()->base_element_klass()->is_interface()) { 4909 k = nullptr; 4910 } 4911 if (k != nullptr && k->is_flat_array_klass() && !ary->_flat) { 4912 k = nullptr; 4913 } 4914 return (TypeAryPtr*)(new TypeAryPtr(ptr, nullptr, ary, k, xk, offset, field_offset, instance_id, false, speculative, inline_depth))->hashcons(); 4915 } 4916 4917 //------------------------------make------------------------------------------- 4918 const TypeAryPtr* TypeAryPtr::make(PTR ptr, ciObject* o, const TypeAry *ary, ciKlass* k, bool xk, Offset offset, Offset field_offset, 4919 int instance_id, const TypePtr* speculative, int inline_depth, 4920 bool is_autobox_cache) { 4921 assert(!(k == nullptr && ary->_elem->isa_int()), 4922 "integral arrays must be pre-equipped with a class"); 4923 assert( (ptr==Constant && o) || (ptr!=Constant && !o), "" ); 4924 if (!xk) xk = (o != nullptr) || ary->ary_must_be_exact(); 4925 assert(instance_id <= 0 || xk, "instances are always exactly typed"); 4926 if (k != nullptr && k->is_loaded() && k->is_obj_array_klass() && 4927 k->as_obj_array_klass()->base_element_klass()->is_interface()) { 4928 k = nullptr; 4929 } 4930 if (k != nullptr && k->is_flat_array_klass() && !ary->_flat) { 4931 k = nullptr; 4932 } 4933 return (TypeAryPtr*)(new TypeAryPtr(ptr, o, ary, k, xk, offset, field_offset, instance_id, is_autobox_cache, speculative, inline_depth))->hashcons(); 4934 } 4935 4936 //------------------------------cast_to_ptr_type------------------------------- 4937 const TypeAryPtr* TypeAryPtr::cast_to_ptr_type(PTR ptr) const { 4938 if( ptr == _ptr ) return this; 4939 return make(ptr, ptr == Constant ? const_oop() : nullptr, _ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 4940 } 4941 4942 4943 //-----------------------------cast_to_exactness------------------------------- 4944 const TypeAryPtr* TypeAryPtr::cast_to_exactness(bool klass_is_exact) const { 4945 if( klass_is_exact == _klass_is_exact ) return this; 4946 if (_ary->ary_must_be_exact()) return this; // cannot clear xk 4947 return make(ptr(), const_oop(), _ary, klass(), klass_is_exact, _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 4948 } 4949 4950 //-----------------------------cast_to_instance_id---------------------------- 4951 const TypeAryPtr* TypeAryPtr::cast_to_instance_id(int instance_id) const { 4952 if( instance_id == _instance_id ) return this; 4953 return make(_ptr, const_oop(), _ary, klass(), _klass_is_exact, _offset, _field_offset, instance_id, _speculative, _inline_depth, _is_autobox_cache); 4954 } 4955 4956 4957 //-----------------------------max_array_length------------------------------- 4958 // A wrapper around arrayOopDesc::max_array_length(etype) with some input normalization. 4959 jint TypeAryPtr::max_array_length(BasicType etype) { 4960 if (!is_java_primitive(etype) && !::is_reference_type(etype)) { 4961 if (etype == T_NARROWOOP) { 4962 etype = T_OBJECT; 4963 } else if (etype == T_ILLEGAL) { // bottom[] 4964 etype = T_BYTE; // will produce conservatively high value 4965 } else { 4966 fatal("not an element type: %s", type2name(etype)); 4967 } 4968 } 4969 return arrayOopDesc::max_array_length(etype); 4970 } 4971 4972 //-----------------------------narrow_size_type------------------------------- 4973 // Narrow the given size type to the index range for the given array base type. 4974 // Return null if the resulting int type becomes empty. 4975 const TypeInt* TypeAryPtr::narrow_size_type(const TypeInt* size) const { 4976 jint hi = size->_hi; 4977 jint lo = size->_lo; 4978 jint min_lo = 0; 4979 jint max_hi = max_array_length(elem()->array_element_basic_type()); 4980 //if (index_not_size) --max_hi; // type of a valid array index, FTR 4981 bool chg = false; 4982 if (lo < min_lo) { 4983 lo = min_lo; 4984 if (size->is_con()) { 4985 hi = lo; 4986 } 4987 chg = true; 4988 } 4989 if (hi > max_hi) { 4990 hi = max_hi; 4991 if (size->is_con()) { 4992 lo = hi; 4993 } 4994 chg = true; 4995 } 4996 // Negative length arrays will produce weird intermediate dead fast-path code 4997 if (lo > hi) 4998 return TypeInt::ZERO; 4999 if (!chg) 5000 return size; 5001 return TypeInt::make(lo, hi, Type::WidenMin); 5002 } 5003 5004 //-------------------------------cast_to_size---------------------------------- 5005 const TypeAryPtr* TypeAryPtr::cast_to_size(const TypeInt* new_size) const { 5006 assert(new_size != nullptr, ""); 5007 new_size = narrow_size_type(new_size); 5008 if (new_size == size()) return this; 5009 const TypeAry* new_ary = TypeAry::make(elem(), new_size, is_stable(), is_flat(), is_not_flat(), is_not_null_free()); 5010 return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 5011 } 5012 5013 //-------------------------------cast_to_not_flat------------------------------ 5014 const TypeAryPtr* TypeAryPtr::cast_to_not_flat(bool not_flat) const { 5015 if (not_flat == is_not_flat()) { 5016 return this; 5017 } 5018 assert(!not_flat || !is_flat(), "inconsistency"); 5019 const TypeAry* new_ary = TypeAry::make(elem(), size(), is_stable(), is_flat(), not_flat, is_not_null_free()); 5020 const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 5021 // We keep the speculative part if it contains information about flat-/nullability. 5022 // Make sure it's removed if it's not better than the non-speculative type anymore. 5023 if (res->speculative() == res->remove_speculative()) { 5024 return res->remove_speculative(); 5025 } 5026 return res; 5027 } 5028 5029 //-------------------------------cast_to_not_null_free------------------------- 5030 const TypeAryPtr* TypeAryPtr::cast_to_not_null_free(bool not_null_free) const { 5031 if (not_null_free == is_not_null_free()) { 5032 return this; 5033 } 5034 assert(!not_null_free || !is_flat(), "inconsistency"); 5035 const TypeAry* new_ary = TypeAry::make(elem(), size(), is_stable(), is_flat(), /* not_flat= */ not_null_free ? true : is_not_flat(), not_null_free); 5036 const TypeAryPtr* res = make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, 5037 _instance_id, _speculative, _inline_depth, _is_autobox_cache); 5038 // We keep the speculative part if it contains information about flat-/nullability. 5039 // Make sure it's removed if it's not better than the non-speculative type anymore. 5040 if (res->speculative() == res->remove_speculative()) { 5041 return res->remove_speculative(); 5042 } 5043 return res; 5044 } 5045 5046 //---------------------------------update_properties--------------------------- 5047 const TypeAryPtr* TypeAryPtr::update_properties(const TypeAryPtr* from) const { 5048 if ((from->is_flat() && is_not_flat()) || 5049 (from->is_not_flat() && is_flat()) || 5050 (from->is_null_free() && is_not_null_free()) || 5051 (from->is_not_null_free() && is_null_free())) { 5052 return nullptr; // Inconsistent properties 5053 } else if (from->is_not_null_free()) { 5054 return cast_to_not_null_free(); // Implies not flat 5055 } else if (from->is_not_flat()) { 5056 return cast_to_not_flat(); 5057 } 5058 return this; 5059 } 5060 5061 jint TypeAryPtr::flat_layout_helper() const { 5062 return klass()->as_flat_array_klass()->layout_helper(); 5063 } 5064 5065 int TypeAryPtr::flat_elem_size() const { 5066 return klass()->as_flat_array_klass()->element_byte_size(); 5067 } 5068 5069 int TypeAryPtr::flat_log_elem_size() const { 5070 return klass()->as_flat_array_klass()->log2_element_size(); 5071 } 5072 5073 //------------------------------cast_to_stable--------------------------------- 5074 const TypeAryPtr* TypeAryPtr::cast_to_stable(bool stable, int stable_dimension) const { 5075 if (stable_dimension <= 0 || (stable_dimension == 1 && stable == this->is_stable())) 5076 return this; 5077 5078 const Type* elem = this->elem(); 5079 const TypePtr* elem_ptr = elem->make_ptr(); 5080 5081 if (stable_dimension > 1 && elem_ptr != nullptr && elem_ptr->isa_aryptr()) { 5082 // If this is widened from a narrow oop, TypeAry::make will re-narrow it. 5083 elem = elem_ptr = elem_ptr->is_aryptr()->cast_to_stable(stable, stable_dimension - 1); 5084 } 5085 5086 const TypeAry* new_ary = TypeAry::make(elem, size(), stable, is_flat(), is_not_flat(), is_not_null_free()); 5087 5088 return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 5089 } 5090 5091 //-----------------------------stable_dimension-------------------------------- 5092 int TypeAryPtr::stable_dimension() const { 5093 if (!is_stable()) return 0; 5094 int dim = 1; 5095 const TypePtr* elem_ptr = elem()->make_ptr(); 5096 if (elem_ptr != nullptr && elem_ptr->isa_aryptr()) 5097 dim += elem_ptr->is_aryptr()->stable_dimension(); 5098 return dim; 5099 } 5100 5101 //----------------------cast_to_autobox_cache----------------------------------- 5102 const TypeAryPtr* TypeAryPtr::cast_to_autobox_cache() const { 5103 if (is_autobox_cache()) return this; 5104 const TypeOopPtr* etype = elem()->make_oopptr(); 5105 if (etype == nullptr) return this; 5106 // The pointers in the autobox arrays are always non-null. 5107 etype = etype->cast_to_ptr_type(TypePtr::NotNull)->is_oopptr(); 5108 const TypeAry* new_ary = TypeAry::make(etype, size(), is_stable(), is_flat(), is_not_flat(), is_not_null_free()); 5109 return make(ptr(), const_oop(), new_ary, klass(), klass_is_exact(), _offset, _field_offset, _instance_id, _speculative, _inline_depth, /*is_autobox_cache=*/true); 5110 } 5111 5112 //------------------------------eq--------------------------------------------- 5113 // Structural equality check for Type representations 5114 bool TypeAryPtr::eq( const Type *t ) const { 5115 const TypeAryPtr *p = t->is_aryptr(); 5116 return 5117 _ary == p->_ary && // Check array 5118 TypeOopPtr::eq(p) &&// Check sub-parts 5119 _field_offset == p->_field_offset; 5120 } 5121 5122 //------------------------------hash------------------------------------------- 5123 // Type-specific hashing function. 5124 uint TypeAryPtr::hash(void) const { 5125 return (uint)(uintptr_t)_ary + TypeOopPtr::hash() + _field_offset.get(); 5126 } 5127 5128 bool TypeAryPtr::is_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const { 5129 return TypePtr::is_java_subtype_of_helper_for_array(this, other, this_exact, other_exact); 5130 } 5131 5132 bool TypeAryPtr::is_same_java_type_as_helper(const TypeOopPtr* other) const { 5133 return TypePtr::is_same_java_type_as_helper_for_array(this, other); 5134 } 5135 5136 bool TypeAryPtr::maybe_java_subtype_of_helper(const TypeOopPtr* other, bool this_exact, bool other_exact) const { 5137 return TypePtr::maybe_java_subtype_of_helper_for_array(this, other, this_exact, other_exact); 5138 } 5139 //------------------------------meet------------------------------------------- 5140 // Compute the MEET of two types. It returns a new Type object. 5141 const Type *TypeAryPtr::xmeet_helper(const Type *t) const { 5142 // Perform a fast test for common case; meeting the same types together. 5143 if( this == t ) return this; // Meeting same type-rep? 5144 // Current "this->_base" is Pointer 5145 switch (t->base()) { // switch on original type 5146 5147 // Mixing ints & oops happens when javac reuses local variables 5148 case Int: 5149 case Long: 5150 case FloatTop: 5151 case FloatCon: 5152 case FloatBot: 5153 case DoubleTop: 5154 case DoubleCon: 5155 case DoubleBot: 5156 case NarrowOop: 5157 case NarrowKlass: 5158 case Bottom: // Ye Olde Default 5159 return Type::BOTTOM; 5160 case Top: 5161 return this; 5162 5163 default: // All else is a mistake 5164 typerr(t); 5165 5166 case OopPtr: { // Meeting to OopPtrs 5167 // Found a OopPtr type vs self-AryPtr type 5168 const TypeOopPtr *tp = t->is_oopptr(); 5169 Offset offset = meet_offset(tp->offset()); 5170 PTR ptr = meet_ptr(tp->ptr()); 5171 int depth = meet_inline_depth(tp->inline_depth()); 5172 const TypePtr* speculative = xmeet_speculative(tp); 5173 switch (tp->ptr()) { 5174 case TopPTR: 5175 case AnyNull: { 5176 int instance_id = meet_instance_id(InstanceTop); 5177 return make(ptr, (ptr == Constant ? const_oop() : nullptr), 5178 _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth); 5179 } 5180 case BotPTR: 5181 case NotNull: { 5182 int instance_id = meet_instance_id(tp->instance_id()); 5183 return TypeOopPtr::make(ptr, offset, instance_id, speculative, depth); 5184 } 5185 default: ShouldNotReachHere(); 5186 } 5187 } 5188 5189 case AnyPtr: { // Meeting two AnyPtrs 5190 // Found an AnyPtr type vs self-AryPtr type 5191 const TypePtr *tp = t->is_ptr(); 5192 Offset offset = meet_offset(tp->offset()); 5193 PTR ptr = meet_ptr(tp->ptr()); 5194 const TypePtr* speculative = xmeet_speculative(tp); 5195 int depth = meet_inline_depth(tp->inline_depth()); 5196 switch (tp->ptr()) { 5197 case TopPTR: 5198 return this; 5199 case BotPTR: 5200 case NotNull: 5201 return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); 5202 case Null: 5203 if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, speculative, depth); 5204 // else fall through to AnyNull 5205 case AnyNull: { 5206 int instance_id = meet_instance_id(InstanceTop); 5207 return make(ptr, (ptr == Constant ? const_oop() : nullptr), 5208 _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth); 5209 } 5210 default: ShouldNotReachHere(); 5211 } 5212 } 5213 5214 case MetadataPtr: 5215 case KlassPtr: 5216 case InstKlassPtr: 5217 case AryKlassPtr: 5218 case RawPtr: return TypePtr::BOTTOM; 5219 5220 case AryPtr: { // Meeting 2 references? 5221 const TypeAryPtr *tap = t->is_aryptr(); 5222 Offset off = meet_offset(tap->offset()); 5223 Offset field_off = meet_field_offset(tap->field_offset()); 5224 const TypeAry *tary = _ary->meet_speculative(tap->_ary)->is_ary(); 5225 PTR ptr = meet_ptr(tap->ptr()); 5226 int instance_id = meet_instance_id(tap->instance_id()); 5227 const TypePtr* speculative = xmeet_speculative(tap); 5228 int depth = meet_inline_depth(tap->inline_depth()); 5229 5230 ciKlass* res_klass = nullptr; 5231 bool res_xk = false; 5232 bool res_flat = false; 5233 bool res_not_flat = false; 5234 bool res_not_null_free = false; 5235 const Type* elem = tary->_elem; 5236 if (meet_aryptr(ptr, elem, this, tap, res_klass, res_xk, res_flat, res_not_flat, res_not_null_free) == NOT_SUBTYPE) { 5237 instance_id = InstanceBot; 5238 } else if (this->is_flat() != tap->is_flat()) { 5239 // Meeting flat inline type array with non-flat array. Adjust (field) offset accordingly. 5240 if (tary->_flat) { 5241 // Result is in a flat representation 5242 off = Offset(is_flat() ? offset() : tap->offset()); 5243 field_off = is_flat() ? field_offset() : tap->field_offset(); 5244 } else if (below_centerline(ptr)) { 5245 // Result is in a non-flat representation 5246 off = Offset(flat_offset()).meet(Offset(tap->flat_offset())); 5247 field_off = (field_off == Offset::top) ? Offset::top : Offset::bottom; 5248 } else if (flat_offset() == tap->flat_offset()) { 5249 off = Offset(!is_flat() ? offset() : tap->offset()); 5250 field_off = !is_flat() ? field_offset() : tap->field_offset(); 5251 } 5252 } 5253 5254 ciObject* o = nullptr; // Assume not constant when done 5255 ciObject* this_oop = const_oop(); 5256 ciObject* tap_oop = tap->const_oop(); 5257 if (ptr == Constant) { 5258 if (this_oop != nullptr && tap_oop != nullptr && 5259 this_oop->equals(tap_oop)) { 5260 o = tap_oop; 5261 } else if (above_centerline(_ptr)) { 5262 o = tap_oop; 5263 } else if (above_centerline(tap->_ptr)) { 5264 o = this_oop; 5265 } else { 5266 ptr = NotNull; 5267 } 5268 } 5269 return make(ptr, o, TypeAry::make(elem, tary->_size, tary->_stable, res_flat, res_not_flat, res_not_null_free), res_klass, res_xk, off, field_off, instance_id, speculative, depth); 5270 } 5271 5272 // All arrays inherit from Object class 5273 case InstPtr: { 5274 const TypeInstPtr *tp = t->is_instptr(); 5275 Offset offset = meet_offset(tp->offset()); 5276 PTR ptr = meet_ptr(tp->ptr()); 5277 int instance_id = meet_instance_id(tp->instance_id()); 5278 const TypePtr* speculative = xmeet_speculative(tp); 5279 int depth = meet_inline_depth(tp->inline_depth()); 5280 const TypeInterfaces* interfaces = meet_interfaces(tp); 5281 const TypeInterfaces* tp_interfaces = tp->_interfaces; 5282 const TypeInterfaces* this_interfaces = _interfaces; 5283 5284 switch (ptr) { 5285 case TopPTR: 5286 case AnyNull: // Fall 'down' to dual of object klass 5287 // For instances when a subclass meets a superclass we fall 5288 // below the centerline when the superclass is exact. We need to 5289 // do the same here. 5290 if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) && !tp->klass_is_exact() && !tp->flat_in_array()) { 5291 return TypeAryPtr::make(ptr, _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth); 5292 } else { 5293 // cannot subclass, so the meet has to fall badly below the centerline 5294 ptr = NotNull; 5295 instance_id = InstanceBot; 5296 interfaces = this_interfaces->intersection_with(tp_interfaces); 5297 return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, false, nullptr, offset, false, instance_id, speculative, depth); 5298 } 5299 case Constant: 5300 case NotNull: 5301 case BotPTR: // Fall down to object klass 5302 // LCA is object_klass, but if we subclass from the top we can do better 5303 if (above_centerline(tp->ptr())) { 5304 // If 'tp' is above the centerline and it is Object class 5305 // then we can subclass in the Java class hierarchy. 5306 // For instances when a subclass meets a superclass we fall 5307 // below the centerline when the superclass is exact. We need 5308 // to do the same here. 5309 if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->contains(tp_interfaces) && !tp->klass_is_exact() && !tp->flat_in_array()) { 5310 // that is, my array type is a subtype of 'tp' klass 5311 return make(ptr, (ptr == Constant ? const_oop() : nullptr), 5312 _ary, _klass, _klass_is_exact, offset, _field_offset, instance_id, speculative, depth); 5313 } 5314 } 5315 // The other case cannot happen, since t cannot be a subtype of an array. 5316 // The meet falls down to Object class below centerline. 5317 if (ptr == Constant) { 5318 ptr = NotNull; 5319 } 5320 if (instance_id > 0) { 5321 instance_id = InstanceBot; 5322 } 5323 interfaces = this_interfaces->intersection_with(tp_interfaces); 5324 return TypeInstPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, false, nullptr, offset, false, instance_id, speculative, depth); 5325 default: typerr(t); 5326 } 5327 } 5328 } 5329 return this; // Lint noise 5330 } 5331 5332 5333 template<class T> TypePtr::MeetResult TypePtr::meet_aryptr(PTR& ptr, const Type*& elem, const T* this_ary, const T* other_ary, 5334 ciKlass*& res_klass, bool& res_xk, bool &res_flat, bool& res_not_flat, bool& res_not_null_free) { 5335 int dummy; 5336 bool this_top_or_bottom = (this_ary->base_element_type(dummy) == Type::TOP || this_ary->base_element_type(dummy) == Type::BOTTOM); 5337 bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM); 5338 ciKlass* this_klass = this_ary->klass(); 5339 ciKlass* other_klass = other_ary->klass(); 5340 bool this_xk = this_ary->klass_is_exact(); 5341 bool other_xk = other_ary->klass_is_exact(); 5342 PTR this_ptr = this_ary->ptr(); 5343 PTR other_ptr = other_ary->ptr(); 5344 bool this_flat = this_ary->is_flat(); 5345 bool this_not_flat = this_ary->is_not_flat(); 5346 bool other_flat = other_ary->is_flat(); 5347 bool other_not_flat = other_ary->is_not_flat(); 5348 bool this_not_null_free = this_ary->is_not_null_free(); 5349 bool other_not_null_free = other_ary->is_not_null_free(); 5350 res_klass = nullptr; 5351 MeetResult result = SUBTYPE; 5352 res_flat = this_flat && other_flat; 5353 res_not_flat = this_not_flat && other_not_flat; 5354 res_not_null_free = this_not_null_free && other_not_null_free; 5355 5356 if (elem->isa_int()) { 5357 // Integral array element types have irrelevant lattice relations. 5358 // It is the klass that determines array layout, not the element type. 5359 if (this_top_or_bottom) { 5360 res_klass = other_klass; 5361 } else if (other_top_or_bottom || other_klass == this_klass) { 5362 res_klass = this_klass; 5363 } else { 5364 // Something like byte[int+] meets char[int+]. 5365 // This must fall to bottom, not (int[-128..65535])[int+]. 5366 // instance_id = InstanceBot; 5367 elem = Type::BOTTOM; 5368 result = NOT_SUBTYPE; 5369 if (above_centerline(ptr) || ptr == Constant) { 5370 ptr = NotNull; 5371 res_xk = false; 5372 return NOT_SUBTYPE; 5373 } 5374 } 5375 } else {// Non integral arrays. 5376 // Must fall to bottom if exact klasses in upper lattice 5377 // are not equal or super klass is exact. 5378 if ((above_centerline(ptr) || ptr == Constant) && !this_ary->is_same_java_type_as(other_ary) && 5379 // meet with top[] and bottom[] are processed further down: 5380 !this_top_or_bottom && !other_top_or_bottom && 5381 // both are exact and not equal: 5382 ((other_xk && this_xk) || 5383 // 'tap' is exact and super or unrelated: 5384 (other_xk && !other_ary->is_meet_subtype_of(this_ary)) || 5385 // 'this' is exact and super or unrelated: 5386 (this_xk && !this_ary->is_meet_subtype_of(other_ary)))) { 5387 if (above_centerline(ptr) || (elem->make_ptr() && above_centerline(elem->make_ptr()->_ptr))) { 5388 elem = Type::BOTTOM; 5389 } 5390 ptr = NotNull; 5391 res_xk = false; 5392 return NOT_SUBTYPE; 5393 } 5394 } 5395 5396 res_xk = false; 5397 switch (other_ptr) { 5398 case AnyNull: 5399 case TopPTR: 5400 // Compute new klass on demand, do not use tap->_klass 5401 if (below_centerline(this_ptr)) { 5402 res_xk = this_xk; 5403 if (this_ary->is_flat()) { 5404 elem = this_ary->elem(); 5405 } 5406 } else { 5407 res_xk = (other_xk || this_xk); 5408 } 5409 break; 5410 case Constant: { 5411 if (this_ptr == Constant) { 5412 res_xk = true; 5413 } else if (above_centerline(this_ptr)) { 5414 res_xk = true; 5415 } else { 5416 // Only precise for identical arrays 5417 res_xk = this_xk && (this_ary->is_same_java_type_as(other_ary) || (this_top_or_bottom && other_top_or_bottom)); 5418 // TODO 8325106 Fix comment 5419 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 5420 if (res_xk && !res_not_null_free) { 5421 res_xk = false; 5422 } 5423 } 5424 break; 5425 } 5426 case NotNull: 5427 case BotPTR: 5428 // Compute new klass on demand, do not use tap->_klass 5429 if (above_centerline(this_ptr)) { 5430 res_xk = other_xk; 5431 if (other_ary->is_flat()) { 5432 elem = other_ary->elem(); 5433 } 5434 } else { 5435 res_xk = (other_xk && this_xk) && 5436 (this_ary->is_same_java_type_as(other_ary) || (this_top_or_bottom && other_top_or_bottom)); // Only precise for identical arrays 5437 // TODO 8325106 Fix comment 5438 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 5439 if (res_xk && !res_not_null_free) { 5440 res_xk = false; 5441 } 5442 } 5443 break; 5444 default: { 5445 ShouldNotReachHere(); 5446 return result; 5447 } 5448 } 5449 return result; 5450 } 5451 5452 5453 //------------------------------xdual------------------------------------------ 5454 // Dual: compute field-by-field dual 5455 const Type *TypeAryPtr::xdual() const { 5456 return new TypeAryPtr(dual_ptr(), _const_oop, _ary->dual()->is_ary(), _klass, _klass_is_exact, dual_offset(), dual_field_offset(), dual_instance_id(), is_autobox_cache(), dual_speculative(), dual_inline_depth()); 5457 } 5458 5459 Type::Offset TypeAryPtr::meet_field_offset(const Type::Offset offset) const { 5460 return _field_offset.meet(offset); 5461 } 5462 5463 //------------------------------dual_offset------------------------------------ 5464 Type::Offset TypeAryPtr::dual_field_offset() const { 5465 return _field_offset.dual(); 5466 } 5467 5468 //------------------------------dump2------------------------------------------ 5469 #ifndef PRODUCT 5470 void TypeAryPtr::dump2( Dict &d, uint depth, outputStream *st ) const { 5471 _ary->dump2(d,depth,st); 5472 _interfaces->dump(st); 5473 5474 switch( _ptr ) { 5475 case Constant: 5476 const_oop()->print(st); 5477 break; 5478 case BotPTR: 5479 if (!WizardMode && !Verbose) { 5480 if( _klass_is_exact ) st->print(":exact"); 5481 break; 5482 } 5483 case TopPTR: 5484 case AnyNull: 5485 case NotNull: 5486 st->print(":%s", ptr_msg[_ptr]); 5487 if( _klass_is_exact ) st->print(":exact"); 5488 break; 5489 default: 5490 break; 5491 } 5492 5493 if (is_flat()) { 5494 st->print(":flat"); 5495 st->print("("); 5496 _field_offset.dump2(st); 5497 st->print(")"); 5498 } 5499 if (is_null_free()) { 5500 st->print(":null_free"); 5501 } 5502 if (offset() != 0) { 5503 int header_size = objArrayOopDesc::header_size() * wordSize; 5504 if( _offset == Offset::top ) st->print("+undefined"); 5505 else if( _offset == Offset::bottom ) st->print("+any"); 5506 else if( offset() < header_size ) st->print("+%d", offset()); 5507 else { 5508 BasicType basic_elem_type = elem()->basic_type(); 5509 if (basic_elem_type == T_ILLEGAL) { 5510 st->print("+any"); 5511 } else { 5512 int array_base = arrayOopDesc::base_offset_in_bytes(basic_elem_type); 5513 int elem_size = type2aelembytes(basic_elem_type); 5514 st->print("[%d]", (offset() - array_base)/elem_size); 5515 } 5516 } 5517 } 5518 st->print(" *"); 5519 if (_instance_id == InstanceTop) 5520 st->print(",iid=top"); 5521 else if (_instance_id != InstanceBot) 5522 st->print(",iid=%d",_instance_id); 5523 5524 dump_inline_depth(st); 5525 dump_speculative(st); 5526 } 5527 #endif 5528 5529 bool TypeAryPtr::empty(void) const { 5530 if (_ary->empty()) return true; 5531 // FIXME: Does this belong here? Or in the meet code itself? 5532 if (is_flat() && is_not_flat()) { 5533 return true; 5534 } 5535 return TypeOopPtr::empty(); 5536 } 5537 5538 //------------------------------add_offset------------------------------------- 5539 const TypePtr* TypeAryPtr::add_offset(intptr_t offset) const { 5540 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); 5541 } 5542 5543 const TypeAryPtr* TypeAryPtr::with_offset(intptr_t offset) const { 5544 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); 5545 } 5546 5547 const TypeAryPtr* TypeAryPtr::with_ary(const TypeAry* ary) const { 5548 return make(_ptr, _const_oop, ary, _klass, _klass_is_exact, _offset, _field_offset, _instance_id, _speculative, _inline_depth, _is_autobox_cache); 5549 } 5550 5551 const TypeAryPtr* TypeAryPtr::remove_speculative() const { 5552 if (_speculative == nullptr) { 5553 return this; 5554 } 5555 assert(_inline_depth == InlineDepthTop || _inline_depth == InlineDepthBottom, "non speculative type shouldn't have inline depth"); 5556 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); 5557 } 5558 5559 const Type* TypeAryPtr::cleanup_speculative() const { 5560 if (speculative() == nullptr) { 5561 return this; 5562 } 5563 // Keep speculative part if it contains information about flat-/nullability 5564 const TypeAryPtr* spec_aryptr = speculative()->isa_aryptr(); 5565 if (spec_aryptr != nullptr && !above_centerline(spec_aryptr->ptr()) && 5566 (spec_aryptr->is_not_flat() || spec_aryptr->is_not_null_free())) { 5567 return this; 5568 } 5569 return TypeOopPtr::cleanup_speculative(); 5570 } 5571 5572 const TypePtr* TypeAryPtr::with_inline_depth(int depth) const { 5573 if (!UseInlineDepthForSpeculativeTypes) { 5574 return this; 5575 } 5576 return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _field_offset, _instance_id, _speculative, depth, _is_autobox_cache); 5577 } 5578 5579 const TypeAryPtr* TypeAryPtr::with_field_offset(int offset) const { 5580 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); 5581 } 5582 5583 const TypePtr* TypeAryPtr::add_field_offset_and_offset(intptr_t offset) const { 5584 int adj = 0; 5585 if (is_flat() && offset != Type::OffsetBot && offset != Type::OffsetTop) { 5586 if (_offset.get() != OffsetBot && _offset.get() != OffsetTop) { 5587 adj = _offset.get(); 5588 offset += _offset.get(); 5589 } 5590 uint header = arrayOopDesc::base_offset_in_bytes(T_OBJECT); 5591 if (_field_offset.get() != OffsetBot && _field_offset.get() != OffsetTop) { 5592 offset += _field_offset.get(); 5593 if (_offset.get() == OffsetBot || _offset.get() == OffsetTop) { 5594 offset += header; 5595 } 5596 } 5597 if (elem()->make_oopptr()->is_inlinetypeptr() && (offset >= (intptr_t)header || offset < 0)) { 5598 // Try to get the field of the inline type array element we are pointing to 5599 ciInlineKlass* vk = elem()->inline_klass(); 5600 int shift = flat_log_elem_size(); 5601 int mask = (1 << shift) - 1; 5602 intptr_t field_offset = ((offset - header) & mask); 5603 ciField* field = vk->get_field_by_offset(field_offset + vk->first_field_offset(), false); 5604 if (field != nullptr) { 5605 return with_field_offset(field_offset)->add_offset(offset - field_offset - adj); 5606 } 5607 } 5608 } 5609 return add_offset(offset - adj); 5610 } 5611 5612 // Return offset incremented by field_offset for flat inline type arrays 5613 int TypeAryPtr::flat_offset() const { 5614 int offset = _offset.get(); 5615 if (offset != Type::OffsetBot && offset != Type::OffsetTop && 5616 _field_offset != Offset::bottom && _field_offset != Offset::top) { 5617 offset += _field_offset.get(); 5618 } 5619 return offset; 5620 } 5621 5622 const TypePtr* TypeAryPtr::with_instance_id(int instance_id) const { 5623 assert(is_known_instance(), "should be known"); 5624 return make(_ptr, _const_oop, _ary->remove_speculative()->is_ary(), _klass, _klass_is_exact, _offset, _field_offset, instance_id, _speculative, _inline_depth); 5625 } 5626 5627 //============================================================================= 5628 5629 5630 //------------------------------hash------------------------------------------- 5631 // Type-specific hashing function. 5632 uint TypeNarrowPtr::hash(void) const { 5633 return _ptrtype->hash() + 7; 5634 } 5635 5636 bool TypeNarrowPtr::singleton(void) const { // TRUE if type is a singleton 5637 return _ptrtype->singleton(); 5638 } 5639 5640 bool TypeNarrowPtr::empty(void) const { 5641 return _ptrtype->empty(); 5642 } 5643 5644 intptr_t TypeNarrowPtr::get_con() const { 5645 return _ptrtype->get_con(); 5646 } 5647 5648 bool TypeNarrowPtr::eq( const Type *t ) const { 5649 const TypeNarrowPtr* tc = isa_same_narrowptr(t); 5650 if (tc != nullptr) { 5651 if (_ptrtype->base() != tc->_ptrtype->base()) { 5652 return false; 5653 } 5654 return tc->_ptrtype->eq(_ptrtype); 5655 } 5656 return false; 5657 } 5658 5659 const Type *TypeNarrowPtr::xdual() const { // Compute dual right now. 5660 const TypePtr* odual = _ptrtype->dual()->is_ptr(); 5661 return make_same_narrowptr(odual); 5662 } 5663 5664 5665 const Type *TypeNarrowPtr::filter_helper(const Type *kills, bool include_speculative) const { 5666 if (isa_same_narrowptr(kills)) { 5667 const Type* ft =_ptrtype->filter_helper(is_same_narrowptr(kills)->_ptrtype, include_speculative); 5668 if (ft->empty()) 5669 return Type::TOP; // Canonical empty value 5670 if (ft->isa_ptr()) { 5671 return make_hash_same_narrowptr(ft->isa_ptr()); 5672 } 5673 return ft; 5674 } else if (kills->isa_ptr()) { 5675 const Type* ft = _ptrtype->join_helper(kills, include_speculative); 5676 if (ft->empty()) 5677 return Type::TOP; // Canonical empty value 5678 return ft; 5679 } else { 5680 return Type::TOP; 5681 } 5682 } 5683 5684 //------------------------------xmeet------------------------------------------ 5685 // Compute the MEET of two types. It returns a new Type object. 5686 const Type *TypeNarrowPtr::xmeet( const Type *t ) const { 5687 // Perform a fast test for common case; meeting the same types together. 5688 if( this == t ) return this; // Meeting same type-rep? 5689 5690 if (t->base() == base()) { 5691 const Type* result = _ptrtype->xmeet(t->make_ptr()); 5692 if (result->isa_ptr()) { 5693 return make_hash_same_narrowptr(result->is_ptr()); 5694 } 5695 return result; 5696 } 5697 5698 // Current "this->_base" is NarrowKlass or NarrowOop 5699 switch (t->base()) { // switch on original type 5700 5701 case Int: // Mixing ints & oops happens when javac 5702 case Long: // reuses local variables 5703 case FloatTop: 5704 case FloatCon: 5705 case FloatBot: 5706 case DoubleTop: 5707 case DoubleCon: 5708 case DoubleBot: 5709 case AnyPtr: 5710 case RawPtr: 5711 case OopPtr: 5712 case InstPtr: 5713 case AryPtr: 5714 case MetadataPtr: 5715 case KlassPtr: 5716 case InstKlassPtr: 5717 case AryKlassPtr: 5718 case NarrowOop: 5719 case NarrowKlass: 5720 case Bottom: // Ye Olde Default 5721 return Type::BOTTOM; 5722 case Top: 5723 return this; 5724 5725 default: // All else is a mistake 5726 typerr(t); 5727 5728 } // End of switch 5729 5730 return this; 5731 } 5732 5733 #ifndef PRODUCT 5734 void TypeNarrowPtr::dump2( Dict & d, uint depth, outputStream *st ) const { 5735 _ptrtype->dump2(d, depth, st); 5736 } 5737 #endif 5738 5739 const TypeNarrowOop *TypeNarrowOop::BOTTOM; 5740 const TypeNarrowOop *TypeNarrowOop::NULL_PTR; 5741 5742 5743 const TypeNarrowOop* TypeNarrowOop::make(const TypePtr* type) { 5744 return (const TypeNarrowOop*)(new TypeNarrowOop(type))->hashcons(); 5745 } 5746 5747 const TypeNarrowOop* TypeNarrowOop::remove_speculative() const { 5748 return make(_ptrtype->remove_speculative()->is_ptr()); 5749 } 5750 5751 const Type* TypeNarrowOop::cleanup_speculative() const { 5752 return make(_ptrtype->cleanup_speculative()->is_ptr()); 5753 } 5754 5755 #ifndef PRODUCT 5756 void TypeNarrowOop::dump2( Dict & d, uint depth, outputStream *st ) const { 5757 st->print("narrowoop: "); 5758 TypeNarrowPtr::dump2(d, depth, st); 5759 } 5760 #endif 5761 5762 const TypeNarrowKlass *TypeNarrowKlass::NULL_PTR; 5763 5764 const TypeNarrowKlass* TypeNarrowKlass::make(const TypePtr* type) { 5765 return (const TypeNarrowKlass*)(new TypeNarrowKlass(type))->hashcons(); 5766 } 5767 5768 #ifndef PRODUCT 5769 void TypeNarrowKlass::dump2( Dict & d, uint depth, outputStream *st ) const { 5770 st->print("narrowklass: "); 5771 TypeNarrowPtr::dump2(d, depth, st); 5772 } 5773 #endif 5774 5775 5776 //------------------------------eq--------------------------------------------- 5777 // Structural equality check for Type representations 5778 bool TypeMetadataPtr::eq( const Type *t ) const { 5779 const TypeMetadataPtr *a = (const TypeMetadataPtr*)t; 5780 ciMetadata* one = metadata(); 5781 ciMetadata* two = a->metadata(); 5782 if (one == nullptr || two == nullptr) { 5783 return (one == two) && TypePtr::eq(t); 5784 } else { 5785 return one->equals(two) && TypePtr::eq(t); 5786 } 5787 } 5788 5789 //------------------------------hash------------------------------------------- 5790 // Type-specific hashing function. 5791 uint TypeMetadataPtr::hash(void) const { 5792 return 5793 (metadata() ? metadata()->hash() : 0) + 5794 TypePtr::hash(); 5795 } 5796 5797 //------------------------------singleton-------------------------------------- 5798 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 5799 // constants 5800 bool TypeMetadataPtr::singleton(void) const { 5801 // detune optimizer to not generate constant metadata + constant offset as a constant! 5802 // TopPTR, Null, AnyNull, Constant are all singletons 5803 return (offset() == 0) && !below_centerline(_ptr); 5804 } 5805 5806 //------------------------------add_offset------------------------------------- 5807 const TypePtr* TypeMetadataPtr::add_offset( intptr_t offset ) const { 5808 return make( _ptr, _metadata, xadd_offset(offset)); 5809 } 5810 5811 //-----------------------------filter------------------------------------------ 5812 // Do not allow interface-vs.-noninterface joins to collapse to top. 5813 const Type *TypeMetadataPtr::filter_helper(const Type *kills, bool include_speculative) const { 5814 const TypeMetadataPtr* ft = join_helper(kills, include_speculative)->isa_metadataptr(); 5815 if (ft == nullptr || ft->empty()) 5816 return Type::TOP; // Canonical empty value 5817 return ft; 5818 } 5819 5820 //------------------------------get_con---------------------------------------- 5821 intptr_t TypeMetadataPtr::get_con() const { 5822 assert( _ptr == Null || _ptr == Constant, "" ); 5823 assert(offset() >= 0, ""); 5824 5825 if (offset() != 0) { 5826 // After being ported to the compiler interface, the compiler no longer 5827 // directly manipulates the addresses of oops. Rather, it only has a pointer 5828 // to a handle at compile time. This handle is embedded in the generated 5829 // code and dereferenced at the time the nmethod is made. Until that time, 5830 // it is not reasonable to do arithmetic with the addresses of oops (we don't 5831 // have access to the addresses!). This does not seem to currently happen, 5832 // but this assertion here is to help prevent its occurrence. 5833 tty->print_cr("Found oop constant with non-zero offset"); 5834 ShouldNotReachHere(); 5835 } 5836 5837 return (intptr_t)metadata()->constant_encoding(); 5838 } 5839 5840 //------------------------------cast_to_ptr_type------------------------------- 5841 const TypeMetadataPtr* TypeMetadataPtr::cast_to_ptr_type(PTR ptr) const { 5842 if( ptr == _ptr ) return this; 5843 return make(ptr, metadata(), _offset); 5844 } 5845 5846 //------------------------------meet------------------------------------------- 5847 // Compute the MEET of two types. It returns a new Type object. 5848 const Type *TypeMetadataPtr::xmeet( const Type *t ) const { 5849 // Perform a fast test for common case; meeting the same types together. 5850 if( this == t ) return this; // Meeting same type-rep? 5851 5852 // Current "this->_base" is OopPtr 5853 switch (t->base()) { // switch on original type 5854 5855 case Int: // Mixing ints & oops happens when javac 5856 case Long: // reuses local variables 5857 case FloatTop: 5858 case FloatCon: 5859 case FloatBot: 5860 case DoubleTop: 5861 case DoubleCon: 5862 case DoubleBot: 5863 case NarrowOop: 5864 case NarrowKlass: 5865 case Bottom: // Ye Olde Default 5866 return Type::BOTTOM; 5867 case Top: 5868 return this; 5869 5870 default: // All else is a mistake 5871 typerr(t); 5872 5873 case AnyPtr: { 5874 // Found an AnyPtr type vs self-OopPtr type 5875 const TypePtr *tp = t->is_ptr(); 5876 Offset offset = meet_offset(tp->offset()); 5877 PTR ptr = meet_ptr(tp->ptr()); 5878 switch (tp->ptr()) { 5879 case Null: 5880 if (ptr == Null) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 5881 // else fall through: 5882 case TopPTR: 5883 case AnyNull: { 5884 return make(ptr, _metadata, offset); 5885 } 5886 case BotPTR: 5887 case NotNull: 5888 return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 5889 default: typerr(t); 5890 } 5891 } 5892 5893 case RawPtr: 5894 case KlassPtr: 5895 case InstKlassPtr: 5896 case AryKlassPtr: 5897 case OopPtr: 5898 case InstPtr: 5899 case AryPtr: 5900 return TypePtr::BOTTOM; // Oop meet raw is not well defined 5901 5902 case MetadataPtr: { 5903 const TypeMetadataPtr *tp = t->is_metadataptr(); 5904 Offset offset = meet_offset(tp->offset()); 5905 PTR tptr = tp->ptr(); 5906 PTR ptr = meet_ptr(tptr); 5907 ciMetadata* md = (tptr == TopPTR) ? metadata() : tp->metadata(); 5908 if (tptr == TopPTR || _ptr == TopPTR || 5909 metadata()->equals(tp->metadata())) { 5910 return make(ptr, md, offset); 5911 } 5912 // metadata is different 5913 if( ptr == Constant ) { // Cannot be equal constants, so... 5914 if( tptr == Constant && _ptr != Constant) return t; 5915 if( _ptr == Constant && tptr != Constant) return this; 5916 ptr = NotNull; // Fall down in lattice 5917 } 5918 return make(ptr, nullptr, offset); 5919 break; 5920 } 5921 } // End of switch 5922 return this; // Return the double constant 5923 } 5924 5925 5926 //------------------------------xdual------------------------------------------ 5927 // Dual of a pure metadata pointer. 5928 const Type *TypeMetadataPtr::xdual() const { 5929 return new TypeMetadataPtr(dual_ptr(), metadata(), dual_offset()); 5930 } 5931 5932 //------------------------------dump2------------------------------------------ 5933 #ifndef PRODUCT 5934 void TypeMetadataPtr::dump2( Dict &d, uint depth, outputStream *st ) const { 5935 st->print("metadataptr:%s", ptr_msg[_ptr]); 5936 if( metadata() ) st->print(INTPTR_FORMAT, p2i(metadata())); 5937 switch (offset()) { 5938 case OffsetTop: st->print("+top"); break; 5939 case OffsetBot: st->print("+any"); break; 5940 case 0: break; 5941 default: st->print("+%d",offset()); break; 5942 } 5943 } 5944 #endif 5945 5946 5947 //============================================================================= 5948 // Convenience common pre-built type. 5949 const TypeMetadataPtr *TypeMetadataPtr::BOTTOM; 5950 5951 TypeMetadataPtr::TypeMetadataPtr(PTR ptr, ciMetadata* metadata, Offset offset): 5952 TypePtr(MetadataPtr, ptr, offset), _metadata(metadata) { 5953 } 5954 5955 const TypeMetadataPtr* TypeMetadataPtr::make(ciMethod* m) { 5956 return make(Constant, m, Offset(0)); 5957 } 5958 const TypeMetadataPtr* TypeMetadataPtr::make(ciMethodData* m) { 5959 return make(Constant, m, Offset(0)); 5960 } 5961 5962 //------------------------------make------------------------------------------- 5963 // Create a meta data constant 5964 const TypeMetadataPtr* TypeMetadataPtr::make(PTR ptr, ciMetadata* m, Offset offset) { 5965 assert(m == nullptr || !m->is_klass(), "wrong type"); 5966 return (TypeMetadataPtr*)(new TypeMetadataPtr(ptr, m, offset))->hashcons(); 5967 } 5968 5969 5970 const TypeKlassPtr* TypeAryPtr::as_klass_type(bool try_for_exact) const { 5971 const Type* elem = _ary->_elem; 5972 bool xk = klass_is_exact(); 5973 if (elem->make_oopptr() != nullptr) { 5974 elem = elem->make_oopptr()->as_klass_type(try_for_exact); 5975 if (elem->is_klassptr()->klass_is_exact() && 5976 // TODO 8325106 Fix comment 5977 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 5978 (is_null_free() || is_flat() || !_ary->_elem->make_oopptr()->is_inlinetypeptr())) { 5979 xk = true; 5980 } 5981 } 5982 return TypeAryKlassPtr::make(xk ? TypePtr::Constant : TypePtr::NotNull, elem, klass(), Offset(0), is_not_flat(), is_not_null_free(), is_null_free()); 5983 } 5984 5985 const TypeKlassPtr* TypeKlassPtr::make(ciKlass* klass, InterfaceHandling interface_handling) { 5986 if (klass->is_instance_klass()) { 5987 return TypeInstKlassPtr::make(klass, interface_handling); 5988 } 5989 return TypeAryKlassPtr::make(klass, interface_handling); 5990 } 5991 5992 const TypeKlassPtr* TypeKlassPtr::make(PTR ptr, ciKlass* klass, Offset offset, InterfaceHandling interface_handling) { 5993 if (klass->is_instance_klass()) { 5994 const TypeInterfaces* interfaces = TypePtr::interfaces(klass, true, true, false, interface_handling); 5995 return TypeInstKlassPtr::make(ptr, klass, interfaces, offset); 5996 } 5997 return TypeAryKlassPtr::make(ptr, klass, offset, interface_handling); 5998 } 5999 6000 TypeKlassPtr::TypeKlassPtr(TYPES t, PTR ptr, ciKlass* klass, const TypeInterfaces* interfaces, Offset offset) 6001 : TypePtr(t, ptr, offset), _klass(klass), _interfaces(interfaces) { 6002 assert(klass == nullptr || !klass->is_loaded() || (klass->is_instance_klass() && !klass->is_interface()) || 6003 klass->is_type_array_klass() || klass->is_flat_array_klass() || !klass->as_obj_array_klass()->base_element_klass()->is_interface(), "no interface here"); 6004 } 6005 6006 // Is there a single ciKlass* that can represent that type? 6007 ciKlass* TypeKlassPtr::exact_klass_helper() const { 6008 assert(_klass->is_instance_klass() && !_klass->is_interface(), "No interface"); 6009 if (_interfaces->empty()) { 6010 return _klass; 6011 } 6012 if (_klass != ciEnv::current()->Object_klass()) { 6013 if (_interfaces->eq(_klass->as_instance_klass())) { 6014 return _klass; 6015 } 6016 return nullptr; 6017 } 6018 return _interfaces->exact_klass(); 6019 } 6020 6021 //------------------------------eq--------------------------------------------- 6022 // Structural equality check for Type representations 6023 bool TypeKlassPtr::eq(const Type *t) const { 6024 const TypeKlassPtr *p = t->is_klassptr(); 6025 return 6026 _interfaces->eq(p->_interfaces) && 6027 TypePtr::eq(p); 6028 } 6029 6030 //------------------------------hash------------------------------------------- 6031 // Type-specific hashing function. 6032 uint TypeKlassPtr::hash(void) const { 6033 return TypePtr::hash() + _interfaces->hash(); 6034 } 6035 6036 //------------------------------singleton-------------------------------------- 6037 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 6038 // constants 6039 bool TypeKlassPtr::singleton(void) const { 6040 // detune optimizer to not generate constant klass + constant offset as a constant! 6041 // TopPTR, Null, AnyNull, Constant are all singletons 6042 return (offset() == 0) && !below_centerline(_ptr); 6043 } 6044 6045 // Do not allow interface-vs.-noninterface joins to collapse to top. 6046 const Type *TypeKlassPtr::filter_helper(const Type *kills, bool include_speculative) const { 6047 // logic here mirrors the one from TypeOopPtr::filter. See comments 6048 // there. 6049 const Type* ft = join_helper(kills, include_speculative); 6050 const TypeKlassPtr* ftkp = ft->isa_instklassptr(); 6051 const TypeKlassPtr* ktkp = kills->isa_instklassptr(); 6052 6053 if (ft->empty()) { 6054 return Type::TOP; // Canonical empty value 6055 } 6056 6057 return ft; 6058 } 6059 6060 const TypeInterfaces* TypeKlassPtr::meet_interfaces(const TypeKlassPtr* other) const { 6061 if (above_centerline(_ptr) && above_centerline(other->_ptr)) { 6062 return _interfaces->union_with(other->_interfaces); 6063 } else if (above_centerline(_ptr) && !above_centerline(other->_ptr)) { 6064 return other->_interfaces; 6065 } else if (above_centerline(other->_ptr) && !above_centerline(_ptr)) { 6066 return _interfaces; 6067 } 6068 return _interfaces->intersection_with(other->_interfaces); 6069 } 6070 6071 //------------------------------get_con---------------------------------------- 6072 intptr_t TypeKlassPtr::get_con() const { 6073 assert( _ptr == Null || _ptr == Constant, "" ); 6074 assert( offset() >= 0, "" ); 6075 6076 if (offset() != 0) { 6077 // After being ported to the compiler interface, the compiler no longer 6078 // directly manipulates the addresses of oops. Rather, it only has a pointer 6079 // to a handle at compile time. This handle is embedded in the generated 6080 // code and dereferenced at the time the nmethod is made. Until that time, 6081 // it is not reasonable to do arithmetic with the addresses of oops (we don't 6082 // have access to the addresses!). This does not seem to currently happen, 6083 // but this assertion here is to help prevent its occurrence. 6084 tty->print_cr("Found oop constant with non-zero offset"); 6085 ShouldNotReachHere(); 6086 } 6087 6088 ciKlass* k = exact_klass(); 6089 6090 return (intptr_t)k->constant_encoding(); 6091 } 6092 6093 //------------------------------dump2------------------------------------------ 6094 // Dump Klass Type 6095 #ifndef PRODUCT 6096 void TypeKlassPtr::dump2(Dict & d, uint depth, outputStream *st) const { 6097 switch(_ptr) { 6098 case Constant: 6099 st->print("precise "); 6100 case NotNull: 6101 { 6102 const char *name = klass()->name()->as_utf8(); 6103 if (name) { 6104 st->print("%s: " INTPTR_FORMAT, name, p2i(klass())); 6105 } else { 6106 ShouldNotReachHere(); 6107 } 6108 _interfaces->dump(st); 6109 } 6110 case BotPTR: 6111 if (!WizardMode && !Verbose && _ptr != Constant) break; 6112 case TopPTR: 6113 case AnyNull: 6114 st->print(":%s", ptr_msg[_ptr]); 6115 if (_ptr == Constant) st->print(":exact"); 6116 break; 6117 default: 6118 break; 6119 } 6120 if (Verbose) { 6121 if (isa_instklassptr() && is_instklassptr()->flat_in_array()) st->print(":flat in array"); 6122 } 6123 _offset.dump2(st); 6124 st->print(" *"); 6125 } 6126 #endif 6127 6128 //============================================================================= 6129 // Convenience common pre-built types. 6130 6131 // Not-null object klass or below 6132 const TypeInstKlassPtr *TypeInstKlassPtr::OBJECT; 6133 const TypeInstKlassPtr *TypeInstKlassPtr::OBJECT_OR_NULL; 6134 6135 bool TypeInstKlassPtr::eq(const Type *t) const { 6136 const TypeKlassPtr *p = t->is_klassptr(); 6137 return 6138 klass()->equals(p->klass()) && 6139 flat_in_array() == p->flat_in_array() && 6140 TypeKlassPtr::eq(p); 6141 } 6142 6143 uint TypeInstKlassPtr::hash(void) const { 6144 return klass()->hash() + TypeKlassPtr::hash() + (uint)flat_in_array(); 6145 } 6146 6147 const TypeInstKlassPtr *TypeInstKlassPtr::make(PTR ptr, ciKlass* k, const TypeInterfaces* interfaces, Offset offset, bool flat_in_array) { 6148 flat_in_array = flat_in_array || k->flat_in_array(); 6149 6150 TypeInstKlassPtr *r = 6151 (TypeInstKlassPtr*)(new TypeInstKlassPtr(ptr, k, interfaces, offset, flat_in_array))->hashcons(); 6152 6153 return r; 6154 } 6155 6156 //------------------------------add_offset------------------------------------- 6157 // Access internals of klass object 6158 const TypePtr *TypeInstKlassPtr::add_offset( intptr_t offset ) const { 6159 return make(_ptr, klass(), _interfaces, xadd_offset(offset), flat_in_array()); 6160 } 6161 6162 const TypeInstKlassPtr* TypeInstKlassPtr::with_offset(intptr_t offset) const { 6163 return make(_ptr, klass(), _interfaces, Offset(offset), flat_in_array()); 6164 } 6165 6166 //------------------------------cast_to_ptr_type------------------------------- 6167 const TypeInstKlassPtr* TypeInstKlassPtr::cast_to_ptr_type(PTR ptr) const { 6168 assert(_base == InstKlassPtr, "subclass must override cast_to_ptr_type"); 6169 if( ptr == _ptr ) return this; 6170 return make(ptr, _klass, _interfaces, _offset, flat_in_array()); 6171 } 6172 6173 6174 bool TypeInstKlassPtr::must_be_exact() const { 6175 if (!_klass->is_loaded()) return false; 6176 ciInstanceKlass* ik = _klass->as_instance_klass(); 6177 if (ik->is_final()) return true; // cannot clear xk 6178 return false; 6179 } 6180 6181 //-----------------------------cast_to_exactness------------------------------- 6182 const TypeKlassPtr* TypeInstKlassPtr::cast_to_exactness(bool klass_is_exact) const { 6183 if (klass_is_exact == (_ptr == Constant)) return this; 6184 if (must_be_exact()) return this; 6185 ciKlass* k = klass(); 6186 return make(klass_is_exact ? Constant : NotNull, k, _interfaces, _offset, flat_in_array()); 6187 } 6188 6189 6190 //-----------------------------as_instance_type-------------------------------- 6191 // Corresponding type for an instance of the given class. 6192 // It will be NotNull, and exact if and only if the klass type is exact. 6193 const TypeOopPtr* TypeInstKlassPtr::as_instance_type(bool klass_change) const { 6194 ciKlass* k = klass(); 6195 bool xk = klass_is_exact(); 6196 Compile* C = Compile::current(); 6197 Dependencies* deps = C->dependencies(); 6198 assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity"); 6199 // Element is an instance 6200 bool klass_is_exact = false; 6201 const TypeInterfaces* interfaces = _interfaces; 6202 if (k->is_loaded()) { 6203 // Try to set klass_is_exact. 6204 ciInstanceKlass* ik = k->as_instance_klass(); 6205 klass_is_exact = ik->is_final(); 6206 if (!klass_is_exact && klass_change 6207 && deps != nullptr && UseUniqueSubclasses) { 6208 ciInstanceKlass* sub = ik->unique_concrete_subklass(); 6209 if (sub != nullptr) { 6210 if (_interfaces->eq(sub)) { 6211 deps->assert_abstract_with_unique_concrete_subtype(ik, sub); 6212 k = ik = sub; 6213 xk = sub->is_final(); 6214 } 6215 } 6216 } 6217 } 6218 return TypeInstPtr::make(TypePtr::BotPTR, k, interfaces, xk, nullptr, Offset(0), flat_in_array() && !klass()->is_inlinetype()); 6219 } 6220 6221 //------------------------------xmeet------------------------------------------ 6222 // Compute the MEET of two types, return a new Type object. 6223 const Type *TypeInstKlassPtr::xmeet( const Type *t ) const { 6224 // Perform a fast test for common case; meeting the same types together. 6225 if( this == t ) return this; // Meeting same type-rep? 6226 6227 // Current "this->_base" is Pointer 6228 switch (t->base()) { // switch on original type 6229 6230 case Int: // Mixing ints & oops happens when javac 6231 case Long: // reuses local variables 6232 case FloatTop: 6233 case FloatCon: 6234 case FloatBot: 6235 case DoubleTop: 6236 case DoubleCon: 6237 case DoubleBot: 6238 case NarrowOop: 6239 case NarrowKlass: 6240 case Bottom: // Ye Olde Default 6241 return Type::BOTTOM; 6242 case Top: 6243 return this; 6244 6245 default: // All else is a mistake 6246 typerr(t); 6247 6248 case AnyPtr: { // Meeting to AnyPtrs 6249 // Found an AnyPtr type vs self-KlassPtr type 6250 const TypePtr *tp = t->is_ptr(); 6251 Offset offset = meet_offset(tp->offset()); 6252 PTR ptr = meet_ptr(tp->ptr()); 6253 switch (tp->ptr()) { 6254 case TopPTR: 6255 return this; 6256 case Null: 6257 if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 6258 case AnyNull: 6259 return make(ptr, klass(), _interfaces, offset, flat_in_array()); 6260 case BotPTR: 6261 case NotNull: 6262 return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 6263 default: typerr(t); 6264 } 6265 } 6266 6267 case RawPtr: 6268 case MetadataPtr: 6269 case OopPtr: 6270 case AryPtr: // Meet with AryPtr 6271 case InstPtr: // Meet with InstPtr 6272 return TypePtr::BOTTOM; 6273 6274 // 6275 // A-top } 6276 // / | \ } Tops 6277 // B-top A-any C-top } 6278 // | / | \ | } Any-nulls 6279 // B-any | C-any } 6280 // | | | 6281 // B-con A-con C-con } constants; not comparable across classes 6282 // | | | 6283 // B-not | C-not } 6284 // | \ | / | } not-nulls 6285 // B-bot A-not C-bot } 6286 // \ | / } Bottoms 6287 // A-bot } 6288 // 6289 6290 case InstKlassPtr: { // Meet two KlassPtr types 6291 const TypeInstKlassPtr *tkls = t->is_instklassptr(); 6292 Offset off = meet_offset(tkls->offset()); 6293 PTR ptr = meet_ptr(tkls->ptr()); 6294 const TypeInterfaces* interfaces = meet_interfaces(tkls); 6295 6296 ciKlass* res_klass = nullptr; 6297 bool res_xk = false; 6298 bool res_flat_in_array = false; 6299 switch(meet_instptr(ptr, interfaces, this, tkls, res_klass, res_xk, res_flat_in_array)) { 6300 case UNLOADED: 6301 ShouldNotReachHere(); 6302 case SUBTYPE: 6303 case NOT_SUBTYPE: 6304 case LCA: 6305 case QUICK: { 6306 assert(res_xk == (ptr == Constant), ""); 6307 const Type* res = make(ptr, res_klass, interfaces, off, res_flat_in_array); 6308 return res; 6309 } 6310 default: 6311 ShouldNotReachHere(); 6312 } 6313 } // End of case KlassPtr 6314 case AryKlassPtr: { // All arrays inherit from Object class 6315 const TypeAryKlassPtr *tp = t->is_aryklassptr(); 6316 Offset offset = meet_offset(tp->offset()); 6317 PTR ptr = meet_ptr(tp->ptr()); 6318 const TypeInterfaces* interfaces = meet_interfaces(tp); 6319 const TypeInterfaces* tp_interfaces = tp->_interfaces; 6320 const TypeInterfaces* this_interfaces = _interfaces; 6321 6322 switch (ptr) { 6323 case TopPTR: 6324 case AnyNull: // Fall 'down' to dual of object klass 6325 // For instances when a subclass meets a superclass we fall 6326 // below the centerline when the superclass is exact. We need to 6327 // do the same here. 6328 if (klass()->equals(ciEnv::current()->Object_klass()) && tp_interfaces->contains(this_interfaces) && !klass_is_exact()) { 6329 return TypeAryKlassPtr::make(ptr, tp->elem(), tp->klass(), offset, tp->is_not_flat(), tp->is_not_null_free(), tp->is_null_free()); 6330 } else { 6331 // cannot subclass, so the meet has to fall badly below the centerline 6332 ptr = NotNull; 6333 interfaces = _interfaces->intersection_with(tp->_interfaces); 6334 return make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, false); 6335 } 6336 case Constant: 6337 case NotNull: 6338 case BotPTR: // Fall down to object klass 6339 // LCA is object_klass, but if we subclass from the top we can do better 6340 if( above_centerline(_ptr) ) { // if( _ptr == TopPTR || _ptr == AnyNull ) 6341 // If 'this' (InstPtr) is above the centerline and it is Object class 6342 // then we can subclass in the Java class hierarchy. 6343 // For instances when a subclass meets a superclass we fall 6344 // below the centerline when the superclass is exact. We need 6345 // to do the same here. 6346 if (klass()->equals(ciEnv::current()->Object_klass()) && tp_interfaces->contains(this_interfaces) && !klass_is_exact()) { 6347 // that is, tp's array type is a subtype of my klass 6348 return TypeAryKlassPtr::make(ptr, tp->elem(), tp->klass(), offset, tp->is_not_flat(), tp->is_not_null_free(), tp->is_null_free()); 6349 } 6350 } 6351 // The other case cannot happen, since I cannot be a subtype of an array. 6352 // The meet falls down to Object class below centerline. 6353 if( ptr == Constant ) 6354 ptr = NotNull; 6355 interfaces = this_interfaces->intersection_with(tp_interfaces); 6356 return make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, false); 6357 default: typerr(t); 6358 } 6359 } 6360 6361 } // End of switch 6362 return this; // Return the double constant 6363 } 6364 6365 //------------------------------xdual------------------------------------------ 6366 // Dual: compute field-by-field dual 6367 const Type *TypeInstKlassPtr::xdual() const { 6368 return new TypeInstKlassPtr(dual_ptr(), klass(), _interfaces, dual_offset(), flat_in_array()); 6369 } 6370 6371 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) { 6372 static_assert(std::is_base_of<T2, T1>::value, ""); 6373 if (!this_one->is_loaded() || !other->is_loaded()) { 6374 return false; 6375 } 6376 if (!this_one->is_instance_type(other)) { 6377 return false; 6378 } 6379 6380 if (!other_exact) { 6381 return false; 6382 } 6383 6384 if (other->klass()->equals(ciEnv::current()->Object_klass()) && other->_interfaces->empty()) { 6385 return true; 6386 } 6387 6388 return this_one->klass()->is_subtype_of(other->klass()) && this_one->_interfaces->contains(other->_interfaces); 6389 } 6390 6391 bool TypeInstKlassPtr::is_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const { 6392 return TypePtr::is_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact); 6393 } 6394 6395 template <class T1, class T2> bool TypePtr::is_same_java_type_as_helper_for_instance(const T1* this_one, const T2* other) { 6396 static_assert(std::is_base_of<T2, T1>::value, ""); 6397 if (!this_one->is_loaded() || !other->is_loaded()) { 6398 return false; 6399 } 6400 if (!this_one->is_instance_type(other)) { 6401 return false; 6402 } 6403 return this_one->klass()->equals(other->klass()) && this_one->_interfaces->eq(other->_interfaces); 6404 } 6405 6406 bool TypeInstKlassPtr::is_same_java_type_as_helper(const TypeKlassPtr* other) const { 6407 return TypePtr::is_same_java_type_as_helper_for_instance(this, other); 6408 } 6409 6410 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) { 6411 static_assert(std::is_base_of<T2, T1>::value, ""); 6412 if (!this_one->is_loaded() || !other->is_loaded()) { 6413 return true; 6414 } 6415 6416 if (this_one->is_array_type(other)) { 6417 return !this_exact && this_one->klass()->equals(ciEnv::current()->Object_klass()) && other->_interfaces->contains(this_one->_interfaces); 6418 } 6419 6420 assert(this_one->is_instance_type(other), "unsupported"); 6421 6422 if (this_exact && other_exact) { 6423 return this_one->is_java_subtype_of(other); 6424 } 6425 6426 if (!this_one->klass()->is_subtype_of(other->klass()) && !other->klass()->is_subtype_of(this_one->klass())) { 6427 return false; 6428 } 6429 6430 if (this_exact) { 6431 return this_one->klass()->is_subtype_of(other->klass()) && this_one->_interfaces->contains(other->_interfaces); 6432 } 6433 6434 return true; 6435 } 6436 6437 bool TypeInstKlassPtr::maybe_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const { 6438 return TypePtr::maybe_java_subtype_of_helper_for_instance(this, other, this_exact, other_exact); 6439 } 6440 6441 const TypeKlassPtr* TypeInstKlassPtr::try_improve() const { 6442 if (!UseUniqueSubclasses) { 6443 return this; 6444 } 6445 ciKlass* k = klass(); 6446 Compile* C = Compile::current(); 6447 Dependencies* deps = C->dependencies(); 6448 assert((deps != nullptr) == (C->method() != nullptr && C->method()->code_size() > 0), "sanity"); 6449 const TypeInterfaces* interfaces = _interfaces; 6450 if (k->is_loaded()) { 6451 ciInstanceKlass* ik = k->as_instance_klass(); 6452 bool klass_is_exact = ik->is_final(); 6453 if (!klass_is_exact && 6454 deps != nullptr) { 6455 ciInstanceKlass* sub = ik->unique_concrete_subklass(); 6456 if (sub != nullptr) { 6457 if (_interfaces->eq(sub)) { 6458 deps->assert_abstract_with_unique_concrete_subtype(ik, sub); 6459 k = ik = sub; 6460 klass_is_exact = sub->is_final(); 6461 return TypeKlassPtr::make(klass_is_exact ? Constant : _ptr, k, _offset); 6462 } 6463 } 6464 } 6465 } 6466 return this; 6467 } 6468 6469 bool TypeInstKlassPtr::can_be_inline_array() const { 6470 return _klass->equals(ciEnv::current()->Object_klass()) && TypeAryKlassPtr::_array_interfaces->contains(_interfaces); 6471 } 6472 6473 bool TypeAryKlassPtr::can_be_inline_array() const { 6474 return _elem->isa_instklassptr() && _elem->is_instklassptr()->_klass->can_be_inline_klass(); 6475 } 6476 6477 bool TypeInstPtr::can_be_inline_array() const { 6478 return _klass->equals(ciEnv::current()->Object_klass()) && TypeAryPtr::_array_interfaces->contains(_interfaces); 6479 } 6480 6481 bool TypeAryPtr::can_be_inline_array() const { 6482 return elem()->make_ptr() && elem()->make_ptr()->isa_instptr() && elem()->make_ptr()->is_instptr()->_klass->can_be_inline_klass(); 6483 } 6484 6485 const TypeAryKlassPtr *TypeAryKlassPtr::make(PTR ptr, const Type* elem, ciKlass* k, Offset offset, bool not_flat, bool not_null_free, bool null_free) { 6486 return (TypeAryKlassPtr*)(new TypeAryKlassPtr(ptr, elem, k, offset, not_flat, not_null_free, null_free))->hashcons(); 6487 } 6488 6489 const TypeAryKlassPtr* TypeAryKlassPtr::make(PTR ptr, ciKlass* k, Offset offset, InterfaceHandling interface_handling, bool not_flat, bool not_null_free, bool null_free) { 6490 if (k->is_obj_array_klass()) { 6491 // Element is an object array. Recursively call ourself. 6492 ciKlass* eklass = k->as_obj_array_klass()->element_klass(); 6493 const TypeKlassPtr* etype = TypeKlassPtr::make(eklass, interface_handling)->cast_to_exactness(false); 6494 // TODO 8325106 Fix comment 6495 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 6496 if (etype->klass_is_exact() && etype->isa_instklassptr() && etype->is_instklassptr()->klass()->is_inlinetype() && !null_free) { 6497 etype = TypeInstKlassPtr::make(NotNull, etype->is_instklassptr()->klass(), Offset(etype->is_instklassptr()->offset())); 6498 } 6499 return TypeAryKlassPtr::make(ptr, etype, nullptr, offset, not_flat, not_null_free, null_free); 6500 } else if (k->is_type_array_klass()) { 6501 // Element is an typeArray 6502 const Type* etype = get_const_basic_type(k->as_type_array_klass()->element_type()); 6503 return TypeAryKlassPtr::make(ptr, etype, k, offset, not_flat, not_null_free, null_free); 6504 } else if (k->is_flat_array_klass()) { 6505 ciKlass* eklass = k->as_flat_array_klass()->element_klass(); 6506 const TypeKlassPtr* etype = TypeKlassPtr::make(eklass); 6507 return TypeAryKlassPtr::make(ptr, etype, k, offset, not_flat, not_null_free, null_free); 6508 } else { 6509 ShouldNotReachHere(); 6510 return nullptr; 6511 } 6512 } 6513 6514 const TypeAryKlassPtr* TypeAryKlassPtr::make(PTR ptr, ciKlass* k, Offset offset, InterfaceHandling interface_handling) { 6515 bool null_free = k->as_array_klass()->is_elem_null_free(); 6516 bool not_null_free = (ptr == Constant) ? !null_free : !k->is_flat_array_klass() && (k->is_type_array_klass() || !k->as_array_klass()->element_klass()->can_be_inline_klass(false)); 6517 6518 bool not_flat = !UseFlatArray || not_null_free || (k->as_array_klass()->element_klass() != nullptr && 6519 k->as_array_klass()->element_klass()->is_inlinetype() && 6520 !k->as_array_klass()->element_klass()->flat_in_array()); 6521 6522 return TypeAryKlassPtr::make(ptr, k, offset, interface_handling, not_flat, not_null_free, null_free); 6523 } 6524 6525 const TypeAryKlassPtr* TypeAryKlassPtr::make(ciKlass* klass, InterfaceHandling interface_handling) { 6526 return TypeAryKlassPtr::make(Constant, klass, Offset(0), interface_handling); 6527 } 6528 6529 //------------------------------eq--------------------------------------------- 6530 // Structural equality check for Type representations 6531 bool TypeAryKlassPtr::eq(const Type *t) const { 6532 const TypeAryKlassPtr *p = t->is_aryklassptr(); 6533 return 6534 _elem == p->_elem && // Check array 6535 _not_flat == p->_not_flat && 6536 _not_null_free == p->_not_null_free && 6537 _null_free == p->_null_free && 6538 TypeKlassPtr::eq(p); // Check sub-parts 6539 } 6540 6541 //------------------------------hash------------------------------------------- 6542 // Type-specific hashing function. 6543 uint TypeAryKlassPtr::hash(void) const { 6544 return (uint)(uintptr_t)_elem + TypeKlassPtr::hash() + (uint)(_not_flat ? 43 : 0) + 6545 (uint)(_not_null_free ? 44 : 0) + (uint)(_null_free ? 45 : 0); 6546 } 6547 6548 //----------------------compute_klass------------------------------------------ 6549 // Compute the defining klass for this class 6550 ciKlass* TypeAryPtr::compute_klass() const { 6551 // Compute _klass based on element type. 6552 ciKlass* k_ary = nullptr; 6553 const TypeInstPtr *tinst; 6554 const TypeAryPtr *tary; 6555 const Type* el = elem(); 6556 if (el->isa_narrowoop()) { 6557 el = el->make_ptr(); 6558 } 6559 6560 // Get element klass 6561 if (is_flat() && el->is_inlinetypeptr()) { 6562 // Klass is required by TypeAryPtr::flat_layout_helper() and others 6563 if (el->inline_klass() != nullptr) { 6564 k_ary = ciArrayKlass::make(el->inline_klass(), /* null_free */ true); 6565 } 6566 } else if ((tinst = el->isa_instptr()) != nullptr) { 6567 // Leave k_ary at nullptr. 6568 } else if ((tary = el->isa_aryptr()) != nullptr) { 6569 // Leave k_ary at nullptr. 6570 } else if ((el->base() == Type::Top) || 6571 (el->base() == Type::Bottom)) { 6572 // element type of Bottom occurs from meet of basic type 6573 // and object; Top occurs when doing join on Bottom. 6574 // Leave k_ary at null. 6575 } else { 6576 assert(!el->isa_int(), "integral arrays must be pre-equipped with a class"); 6577 // Compute array klass directly from basic type 6578 k_ary = ciTypeArrayKlass::make(el->basic_type()); 6579 } 6580 return k_ary; 6581 } 6582 6583 //------------------------------klass------------------------------------------ 6584 // Return the defining klass for this class 6585 ciKlass* TypeAryPtr::klass() const { 6586 if( _klass ) return _klass; // Return cached value, if possible 6587 6588 // Oops, need to compute _klass and cache it 6589 ciKlass* k_ary = compute_klass(); 6590 6591 if( this != TypeAryPtr::OOPS && this->dual() != TypeAryPtr::OOPS ) { 6592 // The _klass field acts as a cache of the underlying 6593 // ciKlass for this array type. In order to set the field, 6594 // we need to cast away const-ness. 6595 // 6596 // IMPORTANT NOTE: we *never* set the _klass field for the 6597 // type TypeAryPtr::OOPS. This Type is shared between all 6598 // active compilations. However, the ciKlass which represents 6599 // this Type is *not* shared between compilations, so caching 6600 // this value would result in fetching a dangling pointer. 6601 // 6602 // Recomputing the underlying ciKlass for each request is 6603 // a bit less efficient than caching, but calls to 6604 // TypeAryPtr::OOPS->klass() are not common enough to matter. 6605 ((TypeAryPtr*)this)->_klass = k_ary; 6606 } 6607 return k_ary; 6608 } 6609 6610 // Is there a single ciKlass* that can represent that type? 6611 ciKlass* TypeAryPtr::exact_klass_helper() const { 6612 if (_ary->_elem->make_ptr() && _ary->_elem->make_ptr()->isa_oopptr()) { 6613 ciKlass* k = _ary->_elem->make_ptr()->is_oopptr()->exact_klass_helper(); 6614 if (k == nullptr) { 6615 return nullptr; 6616 } 6617 k = ciArrayKlass::make(k, is_null_free()); 6618 return k; 6619 } 6620 6621 return klass(); 6622 } 6623 6624 const Type* TypeAryPtr::base_element_type(int& dims) const { 6625 const Type* elem = this->elem(); 6626 dims = 1; 6627 while (elem->make_ptr() && elem->make_ptr()->isa_aryptr()) { 6628 elem = elem->make_ptr()->is_aryptr()->elem(); 6629 dims++; 6630 } 6631 return elem; 6632 } 6633 6634 //------------------------------add_offset------------------------------------- 6635 // Access internals of klass object 6636 const TypePtr* TypeAryKlassPtr::add_offset(intptr_t offset) const { 6637 return make(_ptr, elem(), klass(), xadd_offset(offset), is_not_flat(), is_not_null_free(), _null_free); 6638 } 6639 6640 const TypeAryKlassPtr* TypeAryKlassPtr::with_offset(intptr_t offset) const { 6641 return make(_ptr, elem(), klass(), Offset(offset), is_not_flat(), is_not_null_free(), _null_free); 6642 } 6643 6644 //------------------------------cast_to_ptr_type------------------------------- 6645 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_ptr_type(PTR ptr) const { 6646 assert(_base == AryKlassPtr, "subclass must override cast_to_ptr_type"); 6647 if (ptr == _ptr) return this; 6648 return make(ptr, elem(), _klass, _offset, is_not_flat(), is_not_null_free(), _null_free); 6649 } 6650 6651 bool TypeAryKlassPtr::must_be_exact() const { 6652 if (_elem == Type::BOTTOM) return false; 6653 if (_elem == Type::TOP ) return false; 6654 const TypeKlassPtr* tk = _elem->isa_klassptr(); 6655 if (!tk) return true; // a primitive type, like int 6656 // TODO 8325106 Fix comment 6657 // Even if MyValue is exact, [LMyValue is not exact due to [QMyValue <: [LMyValue. 6658 if (tk->isa_instklassptr() && tk->klass()->is_inlinetype() && !is_null_free()) { 6659 return false; 6660 } 6661 return tk->must_be_exact(); 6662 } 6663 6664 6665 //-----------------------------cast_to_exactness------------------------------- 6666 const TypeKlassPtr *TypeAryKlassPtr::cast_to_exactness(bool klass_is_exact) const { 6667 if (must_be_exact() && !klass_is_exact) return this; // cannot clear xk 6668 if (klass_is_exact == this->klass_is_exact()) { 6669 return this; 6670 } 6671 ciKlass* k = _klass; 6672 const Type* elem = this->elem(); 6673 if (elem->isa_klassptr() && !klass_is_exact) { 6674 elem = elem->is_klassptr()->cast_to_exactness(klass_is_exact); 6675 } 6676 bool not_flat = is_not_flat(); 6677 bool not_null_free = is_not_null_free(); 6678 if (_elem->isa_klassptr()) { 6679 if (klass_is_exact || _elem->isa_aryklassptr()) { 6680 assert(!is_null_free() && !is_flat(), "null-free (or flat) inline type arrays should always be exact"); 6681 // TODO 8325106 Still correct? 6682 // An array can't be null-free (or flat) if the klass is exact 6683 not_null_free = true; 6684 not_flat = true; 6685 } else { 6686 // Klass is not exact (anymore), re-compute null-free/flat properties 6687 const TypeOopPtr* exact_etype = TypeOopPtr::make_from_klass_unique(_elem->is_instklassptr()->instance_klass()); 6688 not_null_free = !exact_etype->can_be_inline_type(); 6689 not_flat = !UseFlatArray || not_null_free || (exact_etype->is_inlinetypeptr() && !exact_etype->inline_klass()->flat_in_array()); 6690 } 6691 } 6692 return make(klass_is_exact ? Constant : NotNull, elem, k, _offset, not_flat, not_null_free, _null_free); 6693 } 6694 6695 const TypeAryKlassPtr* TypeAryKlassPtr::cast_to_null_free() const { 6696 return make(_ptr, elem(), klass(), _offset, is_not_flat(), false, true); 6697 } 6698 6699 //-----------------------------as_instance_type-------------------------------- 6700 // Corresponding type for an instance of the given class. 6701 // It will be NotNull, and exact if and only if the klass type is exact. 6702 const TypeOopPtr* TypeAryKlassPtr::as_instance_type(bool klass_change) const { 6703 ciKlass* k = klass(); 6704 bool xk = klass_is_exact(); 6705 const Type* el = nullptr; 6706 if (elem()->isa_klassptr()) { 6707 el = elem()->is_klassptr()->as_instance_type(false)->cast_to_exactness(false); 6708 k = nullptr; 6709 } else { 6710 el = elem(); 6711 } 6712 bool null_free = _null_free; 6713 if (null_free && el->isa_ptr()) { 6714 el = el->is_ptr()->join_speculative(TypePtr::NOTNULL); 6715 } 6716 return TypeAryPtr::make(TypePtr::BotPTR, TypeAry::make(el, TypeInt::POS, false, is_flat(), is_not_flat(), is_not_null_free()), k, xk, Offset(0)); 6717 } 6718 6719 6720 //------------------------------xmeet------------------------------------------ 6721 // Compute the MEET of two types, return a new Type object. 6722 const Type *TypeAryKlassPtr::xmeet( const Type *t ) const { 6723 // Perform a fast test for common case; meeting the same types together. 6724 if( this == t ) return this; // Meeting same type-rep? 6725 6726 // Current "this->_base" is Pointer 6727 switch (t->base()) { // switch on original type 6728 6729 case Int: // Mixing ints & oops happens when javac 6730 case Long: // reuses local variables 6731 case FloatTop: 6732 case FloatCon: 6733 case FloatBot: 6734 case DoubleTop: 6735 case DoubleCon: 6736 case DoubleBot: 6737 case NarrowOop: 6738 case NarrowKlass: 6739 case Bottom: // Ye Olde Default 6740 return Type::BOTTOM; 6741 case Top: 6742 return this; 6743 6744 default: // All else is a mistake 6745 typerr(t); 6746 6747 case AnyPtr: { // Meeting to AnyPtrs 6748 // Found an AnyPtr type vs self-KlassPtr type 6749 const TypePtr *tp = t->is_ptr(); 6750 Offset offset = meet_offset(tp->offset()); 6751 PTR ptr = meet_ptr(tp->ptr()); 6752 switch (tp->ptr()) { 6753 case TopPTR: 6754 return this; 6755 case Null: 6756 if( ptr == Null ) return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 6757 case AnyNull: 6758 return make(ptr, _elem, klass(), offset, is_not_flat(), is_not_null_free(), is_null_free()); 6759 case BotPTR: 6760 case NotNull: 6761 return TypePtr::make(AnyPtr, ptr, offset, tp->speculative(), tp->inline_depth()); 6762 default: typerr(t); 6763 } 6764 } 6765 6766 case RawPtr: 6767 case MetadataPtr: 6768 case OopPtr: 6769 case AryPtr: // Meet with AryPtr 6770 case InstPtr: // Meet with InstPtr 6771 return TypePtr::BOTTOM; 6772 6773 // 6774 // A-top } 6775 // / | \ } Tops 6776 // B-top A-any C-top } 6777 // | / | \ | } Any-nulls 6778 // B-any | C-any } 6779 // | | | 6780 // B-con A-con C-con } constants; not comparable across classes 6781 // | | | 6782 // B-not | C-not } 6783 // | \ | / | } not-nulls 6784 // B-bot A-not C-bot } 6785 // \ | / } Bottoms 6786 // A-bot } 6787 // 6788 6789 case AryKlassPtr: { // Meet two KlassPtr types 6790 const TypeAryKlassPtr *tap = t->is_aryklassptr(); 6791 Offset off = meet_offset(tap->offset()); 6792 const Type* elem = _elem->meet(tap->_elem); 6793 PTR ptr = meet_ptr(tap->ptr()); 6794 ciKlass* res_klass = nullptr; 6795 bool res_xk = false; 6796 bool res_flat = false; 6797 bool res_not_flat = false; 6798 bool res_not_null_free = false; 6799 MeetResult res = meet_aryptr(ptr, elem, this, tap, 6800 res_klass, res_xk, res_flat, res_not_flat, res_not_null_free); 6801 assert(res_xk == (ptr == Constant), ""); 6802 bool null_free = meet_null_free(tap->_null_free); 6803 if (res == NOT_SUBTYPE) { 6804 null_free = false; 6805 } else if (res == SUBTYPE) { 6806 if (above_centerline(tap->ptr()) && !above_centerline(this->ptr())) { 6807 null_free = _null_free; 6808 } else if (above_centerline(this->ptr()) && !above_centerline(tap->ptr())) { 6809 null_free = tap->_null_free; 6810 } else if (above_centerline(this->ptr()) && above_centerline(tap->ptr())) { 6811 null_free = _null_free || tap->_null_free; 6812 } 6813 } 6814 return make(ptr, elem, res_klass, off, res_not_flat, res_not_null_free, null_free); 6815 } // End of case KlassPtr 6816 case InstKlassPtr: { 6817 const TypeInstKlassPtr *tp = t->is_instklassptr(); 6818 Offset offset = meet_offset(tp->offset()); 6819 PTR ptr = meet_ptr(tp->ptr()); 6820 const TypeInterfaces* interfaces = meet_interfaces(tp); 6821 const TypeInterfaces* tp_interfaces = tp->_interfaces; 6822 const TypeInterfaces* this_interfaces = _interfaces; 6823 6824 switch (ptr) { 6825 case TopPTR: 6826 case AnyNull: // Fall 'down' to dual of object klass 6827 // For instances when a subclass meets a superclass we fall 6828 // below the centerline when the superclass is exact. We need to 6829 // do the same here. 6830 if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->intersection_with(tp_interfaces)->eq(tp_interfaces) && !tp->klass_is_exact()) { 6831 return TypeAryKlassPtr::make(ptr, _elem, _klass, offset, is_not_flat(), is_not_null_free(), is_null_free()); 6832 } else { 6833 // cannot subclass, so the meet has to fall badly below the centerline 6834 ptr = NotNull; 6835 interfaces = this_interfaces->intersection_with(tp->_interfaces); 6836 return TypeInstKlassPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, false); 6837 } 6838 case Constant: 6839 case NotNull: 6840 case BotPTR: // Fall down to object klass 6841 // LCA is object_klass, but if we subclass from the top we can do better 6842 if (above_centerline(tp->ptr())) { 6843 // If 'tp' is above the centerline and it is Object class 6844 // then we can subclass in the Java class hierarchy. 6845 // For instances when a subclass meets a superclass we fall 6846 // below the centerline when the superclass is exact. We need 6847 // to do the same here. 6848 if (tp->klass()->equals(ciEnv::current()->Object_klass()) && this_interfaces->intersection_with(tp_interfaces)->eq(tp_interfaces) && !tp->klass_is_exact()) { 6849 // that is, my array type is a subtype of 'tp' klass 6850 return make(ptr, _elem, _klass, offset, is_not_flat(), is_not_null_free(), is_null_free()); 6851 } 6852 } 6853 // The other case cannot happen, since t cannot be a subtype of an array. 6854 // The meet falls down to Object class below centerline. 6855 if (ptr == Constant) 6856 ptr = NotNull; 6857 interfaces = this_interfaces->intersection_with(tp_interfaces); 6858 return TypeInstKlassPtr::make(ptr, ciEnv::current()->Object_klass(), interfaces, offset, false); 6859 default: typerr(t); 6860 } 6861 } 6862 6863 } // End of switch 6864 return this; // Return the double constant 6865 } 6866 6867 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) { 6868 static_assert(std::is_base_of<T2, T1>::value, ""); 6869 6870 if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty() && other_exact) { 6871 return true; 6872 } 6873 6874 int dummy; 6875 bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM); 6876 6877 if (!this_one->is_loaded() || !other->is_loaded() || this_top_or_bottom) { 6878 return false; 6879 } 6880 6881 if (this_one->is_instance_type(other)) { 6882 return other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->intersection_with(this_one->_interfaces)->eq(other->_interfaces) && other_exact; 6883 } 6884 6885 assert(this_one->is_array_type(other), ""); 6886 const T1* other_ary = this_one->is_array_type(other); 6887 bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM); 6888 if (other_top_or_bottom) { 6889 return false; 6890 } 6891 6892 const TypePtr* other_elem = other_ary->elem()->make_ptr(); 6893 const TypePtr* this_elem = this_one->elem()->make_ptr(); 6894 if (this_elem != nullptr && other_elem != nullptr) { 6895 if (other->is_null_free() && !this_one->is_null_free()) { 6896 // TODO 8325106 Fix comment 6897 return false; // [LMyValue is not a subtype of [QMyValue 6898 } 6899 return this_one->is_reference_type(this_elem)->is_java_subtype_of_helper(this_one->is_reference_type(other_elem), this_exact, other_exact); 6900 } 6901 if (this_elem == nullptr && other_elem == nullptr) { 6902 return this_one->klass()->is_subtype_of(other->klass()); 6903 } 6904 return false; 6905 } 6906 6907 bool TypeAryKlassPtr::is_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const { 6908 return TypePtr::is_java_subtype_of_helper_for_array(this, other, this_exact, other_exact); 6909 } 6910 6911 template <class T1, class T2> bool TypePtr::is_same_java_type_as_helper_for_array(const T1* this_one, const T2* other) { 6912 static_assert(std::is_base_of<T2, T1>::value, ""); 6913 6914 int dummy; 6915 bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM); 6916 6917 if (!this_one->is_array_type(other) || 6918 !this_one->is_loaded() || !other->is_loaded() || this_top_or_bottom) { 6919 return false; 6920 } 6921 const T1* other_ary = this_one->is_array_type(other); 6922 bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM); 6923 6924 if (other_top_or_bottom) { 6925 return false; 6926 } 6927 6928 const TypePtr* other_elem = other_ary->elem()->make_ptr(); 6929 const TypePtr* this_elem = this_one->elem()->make_ptr(); 6930 if (other_elem != nullptr && this_elem != nullptr) { 6931 return this_one->is_reference_type(this_elem)->is_same_java_type_as(this_one->is_reference_type(other_elem)); 6932 } 6933 if (other_elem == nullptr && this_elem == nullptr) { 6934 return this_one->klass()->equals(other->klass()); 6935 } 6936 return false; 6937 } 6938 6939 bool TypeAryKlassPtr::is_same_java_type_as_helper(const TypeKlassPtr* other) const { 6940 return TypePtr::is_same_java_type_as_helper_for_array(this, other); 6941 } 6942 6943 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) { 6944 static_assert(std::is_base_of<T2, T1>::value, ""); 6945 if (other->klass() == ciEnv::current()->Object_klass() && other->_interfaces->empty() && other_exact) { 6946 return true; 6947 } 6948 int dummy; 6949 bool this_top_or_bottom = (this_one->base_element_type(dummy) == Type::TOP || this_one->base_element_type(dummy) == Type::BOTTOM); 6950 if (!this_one->is_loaded() || !other->is_loaded() || this_top_or_bottom) { 6951 return true; 6952 } 6953 if (this_one->is_instance_type(other)) { 6954 return other->klass()->equals(ciEnv::current()->Object_klass()) && other->_interfaces->intersection_with(this_one->_interfaces)->eq(other->_interfaces); 6955 } 6956 assert(this_one->is_array_type(other), ""); 6957 6958 const T1* other_ary = this_one->is_array_type(other); 6959 bool other_top_or_bottom = (other_ary->base_element_type(dummy) == Type::TOP || other_ary->base_element_type(dummy) == Type::BOTTOM); 6960 if (other_top_or_bottom) { 6961 return true; 6962 } 6963 if (this_exact && other_exact) { 6964 return this_one->is_java_subtype_of(other); 6965 } 6966 6967 const TypePtr* this_elem = this_one->elem()->make_ptr(); 6968 const TypePtr* other_elem = other_ary->elem()->make_ptr(); 6969 if (other_elem != nullptr && this_elem != nullptr) { 6970 return this_one->is_reference_type(this_elem)->maybe_java_subtype_of_helper(this_one->is_reference_type(other_elem), this_exact, other_exact); 6971 } 6972 if (other_elem == nullptr && this_elem == nullptr) { 6973 return this_one->klass()->is_subtype_of(other->klass()); 6974 } 6975 return false; 6976 } 6977 6978 bool TypeAryKlassPtr::maybe_java_subtype_of_helper(const TypeKlassPtr* other, bool this_exact, bool other_exact) const { 6979 return TypePtr::maybe_java_subtype_of_helper_for_array(this, other, this_exact, other_exact); 6980 } 6981 6982 //------------------------------xdual------------------------------------------ 6983 // Dual: compute field-by-field dual 6984 const Type *TypeAryKlassPtr::xdual() const { 6985 return new TypeAryKlassPtr(dual_ptr(), elem()->dual(), klass(), dual_offset(), !is_not_flat(), !is_not_null_free(), dual_null_free()); 6986 } 6987 6988 // Is there a single ciKlass* that can represent that type? 6989 ciKlass* TypeAryKlassPtr::exact_klass_helper() const { 6990 if (elem()->isa_klassptr()) { 6991 ciKlass* k = elem()->is_klassptr()->exact_klass_helper(); 6992 if (k == nullptr) { 6993 return nullptr; 6994 } 6995 k = ciArrayKlass::make(k, _null_free); 6996 return k; 6997 } 6998 6999 return klass(); 7000 } 7001 7002 ciKlass* TypeAryKlassPtr::klass() const { 7003 if (_klass != nullptr) { 7004 return _klass; 7005 } 7006 ciKlass* k = nullptr; 7007 if (elem()->isa_klassptr()) { 7008 // leave null 7009 } else if ((elem()->base() == Type::Top) || 7010 (elem()->base() == Type::Bottom)) { 7011 } else { 7012 k = ciTypeArrayKlass::make(elem()->basic_type()); 7013 ((TypeAryKlassPtr*)this)->_klass = k; 7014 } 7015 return k; 7016 } 7017 7018 //------------------------------dump2------------------------------------------ 7019 // Dump Klass Type 7020 #ifndef PRODUCT 7021 void TypeAryKlassPtr::dump2( Dict & d, uint depth, outputStream *st ) const { 7022 switch( _ptr ) { 7023 case Constant: 7024 st->print("precise "); 7025 case NotNull: 7026 { 7027 st->print("["); 7028 _elem->dump2(d, depth, st); 7029 _interfaces->dump(st); 7030 st->print(": "); 7031 } 7032 case BotPTR: 7033 if( !WizardMode && !Verbose && _ptr != Constant ) break; 7034 case TopPTR: 7035 case AnyNull: 7036 st->print(":%s", ptr_msg[_ptr]); 7037 if( _ptr == Constant ) st->print(":exact"); 7038 break; 7039 default: 7040 break; 7041 } 7042 if (is_flat()) st->print(":flat"); 7043 if (_null_free) st->print(":null free"); 7044 if (Verbose) { 7045 if (_not_flat) st->print(":not flat"); 7046 if (_not_null_free) st->print(":not null free"); 7047 } 7048 7049 _offset.dump2(st); 7050 7051 st->print(" *"); 7052 } 7053 #endif 7054 7055 const Type* TypeAryKlassPtr::base_element_type(int& dims) const { 7056 const Type* elem = this->elem(); 7057 dims = 1; 7058 while (elem->isa_aryklassptr()) { 7059 elem = elem->is_aryklassptr()->elem(); 7060 dims++; 7061 } 7062 return elem; 7063 } 7064 7065 //============================================================================= 7066 // Convenience common pre-built types. 7067 7068 //------------------------------make------------------------------------------- 7069 const TypeFunc *TypeFunc::make(const TypeTuple *domain_sig, const TypeTuple* domain_cc, 7070 const TypeTuple *range_sig, const TypeTuple *range_cc) { 7071 return (TypeFunc*)(new TypeFunc(domain_sig, domain_cc, range_sig, range_cc))->hashcons(); 7072 } 7073 7074 const TypeFunc *TypeFunc::make(const TypeTuple *domain, const TypeTuple *range) { 7075 return make(domain, domain, range, range); 7076 } 7077 7078 //------------------------------osr_domain----------------------------- 7079 const TypeTuple* osr_domain() { 7080 const Type **fields = TypeTuple::fields(2); 7081 fields[TypeFunc::Parms+0] = TypeRawPtr::BOTTOM; // address of osr buffer 7082 return TypeTuple::make(TypeFunc::Parms+1, fields); 7083 } 7084 7085 //------------------------------make------------------------------------------- 7086 const TypeFunc* TypeFunc::make(ciMethod* method, bool is_osr_compilation) { 7087 Compile* C = Compile::current(); 7088 const TypeFunc* tf = nullptr; 7089 if (!is_osr_compilation) { 7090 tf = C->last_tf(method); // check cache 7091 if (tf != nullptr) return tf; // The hit rate here is almost 50%. 7092 } 7093 // Inline types are not passed/returned by reference, instead each field of 7094 // the inline type is passed/returned as an argument. We maintain two views of 7095 // the argument/return list here: one based on the signature (with an inline 7096 // type argument/return as a single slot), one based on the actual calling 7097 // convention (with an inline type argument/return as a list of its fields). 7098 bool has_scalar_args = method->has_scalarized_args() && !is_osr_compilation; 7099 // Fall back to the non-scalarized calling convention when compiling a call via a mismatching method 7100 if (method != C->method() && method->get_Method()->mismatch()) { 7101 has_scalar_args = false; 7102 } 7103 const TypeTuple* domain_sig = is_osr_compilation ? osr_domain() : TypeTuple::make_domain(method, ignore_interfaces, false); 7104 const TypeTuple* domain_cc = has_scalar_args ? TypeTuple::make_domain(method, ignore_interfaces, true) : domain_sig; 7105 ciSignature* sig = method->signature(); 7106 bool has_scalar_ret = !method->is_native() && sig->return_type()->is_inlinetype() && sig->return_type()->as_inline_klass()->can_be_returned_as_fields(); 7107 const TypeTuple* range_sig = TypeTuple::make_range(sig, ignore_interfaces, false); 7108 const TypeTuple* range_cc = has_scalar_ret ? TypeTuple::make_range(sig, ignore_interfaces, true) : range_sig; 7109 tf = TypeFunc::make(domain_sig, domain_cc, range_sig, range_cc); 7110 if (!is_osr_compilation) { 7111 C->set_last_tf(method, tf); // fill cache 7112 } 7113 return tf; 7114 } 7115 7116 //------------------------------meet------------------------------------------- 7117 // Compute the MEET of two types. It returns a new Type object. 7118 const Type *TypeFunc::xmeet( const Type *t ) const { 7119 // Perform a fast test for common case; meeting the same types together. 7120 if( this == t ) return this; // Meeting same type-rep? 7121 7122 // Current "this->_base" is Func 7123 switch (t->base()) { // switch on original type 7124 7125 case Bottom: // Ye Olde Default 7126 return t; 7127 7128 default: // All else is a mistake 7129 typerr(t); 7130 7131 case Top: 7132 break; 7133 } 7134 return this; // Return the double constant 7135 } 7136 7137 //------------------------------xdual------------------------------------------ 7138 // Dual: compute field-by-field dual 7139 const Type *TypeFunc::xdual() const { 7140 return this; 7141 } 7142 7143 //------------------------------eq--------------------------------------------- 7144 // Structural equality check for Type representations 7145 bool TypeFunc::eq( const Type *t ) const { 7146 const TypeFunc *a = (const TypeFunc*)t; 7147 return _domain_sig == a->_domain_sig && 7148 _domain_cc == a->_domain_cc && 7149 _range_sig == a->_range_sig && 7150 _range_cc == a->_range_cc; 7151 } 7152 7153 //------------------------------hash------------------------------------------- 7154 // Type-specific hashing function. 7155 uint TypeFunc::hash(void) const { 7156 return (uint)(intptr_t)_domain_sig + (uint)(intptr_t)_domain_cc + (uint)(intptr_t)_range_sig + (uint)(intptr_t)_range_cc; 7157 } 7158 7159 //------------------------------dump2------------------------------------------ 7160 // Dump Function Type 7161 #ifndef PRODUCT 7162 void TypeFunc::dump2( Dict &d, uint depth, outputStream *st ) const { 7163 if( _range_sig->cnt() <= Parms ) 7164 st->print("void"); 7165 else { 7166 uint i; 7167 for (i = Parms; i < _range_sig->cnt()-1; i++) { 7168 _range_sig->field_at(i)->dump2(d,depth,st); 7169 st->print("/"); 7170 } 7171 _range_sig->field_at(i)->dump2(d,depth,st); 7172 } 7173 st->print(" "); 7174 st->print("( "); 7175 if( !depth || d[this] ) { // Check for recursive dump 7176 st->print("...)"); 7177 return; 7178 } 7179 d.Insert((void*)this,(void*)this); // Stop recursion 7180 if (Parms < _domain_sig->cnt()) 7181 _domain_sig->field_at(Parms)->dump2(d,depth-1,st); 7182 for (uint i = Parms+1; i < _domain_sig->cnt(); i++) { 7183 st->print(", "); 7184 _domain_sig->field_at(i)->dump2(d,depth-1,st); 7185 } 7186 st->print(" )"); 7187 } 7188 #endif 7189 7190 //------------------------------singleton-------------------------------------- 7191 // TRUE if Type is a singleton type, FALSE otherwise. Singletons are simple 7192 // constants (Ldi nodes). Singletons are integer, float or double constants 7193 // or a single symbol. 7194 bool TypeFunc::singleton(void) const { 7195 return false; // Never a singleton 7196 } 7197 7198 bool TypeFunc::empty(void) const { 7199 return false; // Never empty 7200 } 7201 7202 7203 BasicType TypeFunc::return_type() const{ 7204 if (range_sig()->cnt() == TypeFunc::Parms) { 7205 return T_VOID; 7206 } 7207 return range_sig()->field_at(TypeFunc::Parms)->basic_type(); 7208 }