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src/share/vm/c1/c1_Instruction.hpp@b812ff5abc73 (annotated)

src/share/vm/c1/c1_Instruction.hpp

Fri, 04 Jun 2010 11:18:04 -0700

author
iveresov
date
Fri, 04 Jun 2010 11:18:04 -0700
changeset 1939
b812ff5abc73
parent 1907
c18cbe5936b8
child 2138
d5d065957597
permissions
-rw-r--r--

6958292: C1: Enable parallel compilation
Summary: Enable parallel compilation in C1
Reviewed-by: never, kvn

duke@435 1 /*
trims@1907 2 * Copyright (c) 1999, 2010, Oracle and/or its affiliates. All rights reserved.
duke@435 3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
duke@435 4 *
duke@435 5 * This code is free software; you can redistribute it and/or modify it
duke@435 6 * under the terms of the GNU General Public License version 2 only, as
duke@435 7 * published by the Free Software Foundation.
duke@435 8 *
duke@435 9 * This code is distributed in the hope that it will be useful, but WITHOUT
duke@435 10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
duke@435 11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
duke@435 12 * version 2 for more details (a copy is included in the LICENSE file that
duke@435 13 * accompanied this code).
duke@435 14 *
duke@435 15 * You should have received a copy of the GNU General Public License version
duke@435 16 * 2 along with this work; if not, write to the Free Software Foundation,
duke@435 17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
duke@435 18 *
trims@1907 19 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
trims@1907 20 * or visit www.oracle.com if you need additional information or have any
trims@1907 21 * questions.
duke@435 22 *
duke@435 23 */
duke@435 24
duke@435 25 // Predefined classes
duke@435 26 class ciField;
duke@435 27 class ValueStack;
duke@435 28 class InstructionPrinter;
duke@435 29 class IRScope;
duke@435 30 class LIR_OprDesc;
duke@435 31 typedef LIR_OprDesc* LIR_Opr;
duke@435 32
duke@435 33
duke@435 34 // Instruction class hierarchy
duke@435 35 //
duke@435 36 // All leaf classes in the class hierarchy are concrete classes
duke@435 37 // (i.e., are instantiated). All other classes are abstract and
duke@435 38 // serve factoring.
duke@435 39
duke@435 40 class Instruction;
duke@435 41 class HiWord;
duke@435 42 class Phi;
duke@435 43 class Local;
duke@435 44 class Constant;
duke@435 45 class AccessField;
duke@435 46 class LoadField;
duke@435 47 class StoreField;
duke@435 48 class AccessArray;
duke@435 49 class ArrayLength;
duke@435 50 class AccessIndexed;
duke@435 51 class LoadIndexed;
duke@435 52 class StoreIndexed;
duke@435 53 class NegateOp;
duke@435 54 class Op2;
duke@435 55 class ArithmeticOp;
duke@435 56 class ShiftOp;
duke@435 57 class LogicOp;
duke@435 58 class CompareOp;
duke@435 59 class IfOp;
duke@435 60 class Convert;
duke@435 61 class NullCheck;
duke@435 62 class OsrEntry;
duke@435 63 class ExceptionObject;
duke@435 64 class StateSplit;
duke@435 65 class Invoke;
duke@435 66 class NewInstance;
duke@435 67 class NewArray;
duke@435 68 class NewTypeArray;
duke@435 69 class NewObjectArray;
duke@435 70 class NewMultiArray;
duke@435 71 class TypeCheck;
duke@435 72 class CheckCast;
duke@435 73 class InstanceOf;
duke@435 74 class AccessMonitor;
duke@435 75 class MonitorEnter;
duke@435 76 class MonitorExit;
duke@435 77 class Intrinsic;
duke@435 78 class BlockBegin;
duke@435 79 class BlockEnd;
duke@435 80 class Goto;
duke@435 81 class If;
duke@435 82 class IfInstanceOf;
duke@435 83 class Switch;
duke@435 84 class TableSwitch;
duke@435 85 class LookupSwitch;
duke@435 86 class Return;
duke@435 87 class Throw;
duke@435 88 class Base;
duke@435 89 class RoundFP;
duke@435 90 class UnsafeOp;
duke@435 91 class UnsafeRawOp;
duke@435 92 class UnsafeGetRaw;
duke@435 93 class UnsafePutRaw;
duke@435 94 class UnsafeObjectOp;
duke@435 95 class UnsafeGetObject;
duke@435 96 class UnsafePutObject;
duke@435 97 class UnsafePrefetch;
duke@435 98 class UnsafePrefetchRead;
duke@435 99 class UnsafePrefetchWrite;
duke@435 100 class ProfileCall;
duke@435 101 class ProfileCounter;
duke@435 102
duke@435 103 // A Value is a reference to the instruction creating the value
duke@435 104 typedef Instruction* Value;
duke@435 105 define_array(ValueArray, Value)
duke@435 106 define_stack(Values, ValueArray)
duke@435 107
duke@435 108 define_array(ValueStackArray, ValueStack*)
duke@435 109 define_stack(ValueStackStack, ValueStackArray)
duke@435 110
duke@435 111 // BlockClosure is the base class for block traversal/iteration.
duke@435 112
duke@435 113 class BlockClosure: public CompilationResourceObj {
duke@435 114 public:
duke@435 115 virtual void block_do(BlockBegin* block) = 0;
duke@435 116 };
duke@435 117
duke@435 118
iveresov@1939 119 // A simple closure class for visiting the values of an Instruction
iveresov@1939 120 class ValueVisitor: public StackObj {
iveresov@1939 121 public:
iveresov@1939 122 virtual void visit(Value* v) = 0;
iveresov@1939 123 };
iveresov@1939 124
iveresov@1939 125
duke@435 126 // Some array and list classes
duke@435 127 define_array(BlockBeginArray, BlockBegin*)
duke@435 128 define_stack(_BlockList, BlockBeginArray)
duke@435 129
duke@435 130 class BlockList: public _BlockList {
duke@435 131 public:
duke@435 132 BlockList(): _BlockList() {}
duke@435 133 BlockList(const int size): _BlockList(size) {}
duke@435 134 BlockList(const int size, BlockBegin* init): _BlockList(size, init) {}
duke@435 135
duke@435 136 void iterate_forward(BlockClosure* closure);
duke@435 137 void iterate_backward(BlockClosure* closure);
duke@435 138 void blocks_do(void f(BlockBegin*));
iveresov@1939 139 void values_do(ValueVisitor* f);
duke@435 140 void print(bool cfg_only = false, bool live_only = false) PRODUCT_RETURN;
duke@435 141 };
duke@435 142
duke@435 143
duke@435 144 // InstructionVisitors provide type-based dispatch for instructions.
duke@435 145 // For each concrete Instruction class X, a virtual function do_X is
duke@435 146 // provided. Functionality that needs to be implemented for all classes
duke@435 147 // (e.g., printing, code generation) is factored out into a specialised
duke@435 148 // visitor instead of added to the Instruction classes itself.
duke@435 149
duke@435 150 class InstructionVisitor: public StackObj {
duke@435 151 public:
duke@435 152 void do_HiWord (HiWord* x) { ShouldNotReachHere(); }
duke@435 153 virtual void do_Phi (Phi* x) = 0;
duke@435 154 virtual void do_Local (Local* x) = 0;
duke@435 155 virtual void do_Constant (Constant* x) = 0;
duke@435 156 virtual void do_LoadField (LoadField* x) = 0;
duke@435 157 virtual void do_StoreField (StoreField* x) = 0;
duke@435 158 virtual void do_ArrayLength (ArrayLength* x) = 0;
duke@435 159 virtual void do_LoadIndexed (LoadIndexed* x) = 0;
duke@435 160 virtual void do_StoreIndexed (StoreIndexed* x) = 0;
duke@435 161 virtual void do_NegateOp (NegateOp* x) = 0;
duke@435 162 virtual void do_ArithmeticOp (ArithmeticOp* x) = 0;
duke@435 163 virtual void do_ShiftOp (ShiftOp* x) = 0;
duke@435 164 virtual void do_LogicOp (LogicOp* x) = 0;
duke@435 165 virtual void do_CompareOp (CompareOp* x) = 0;
duke@435 166 virtual void do_IfOp (IfOp* x) = 0;
duke@435 167 virtual void do_Convert (Convert* x) = 0;
duke@435 168 virtual void do_NullCheck (NullCheck* x) = 0;
duke@435 169 virtual void do_Invoke (Invoke* x) = 0;
duke@435 170 virtual void do_NewInstance (NewInstance* x) = 0;
duke@435 171 virtual void do_NewTypeArray (NewTypeArray* x) = 0;
duke@435 172 virtual void do_NewObjectArray (NewObjectArray* x) = 0;
duke@435 173 virtual void do_NewMultiArray (NewMultiArray* x) = 0;
duke@435 174 virtual void do_CheckCast (CheckCast* x) = 0;
duke@435 175 virtual void do_InstanceOf (InstanceOf* x) = 0;
duke@435 176 virtual void do_MonitorEnter (MonitorEnter* x) = 0;
duke@435 177 virtual void do_MonitorExit (MonitorExit* x) = 0;
duke@435 178 virtual void do_Intrinsic (Intrinsic* x) = 0;
duke@435 179 virtual void do_BlockBegin (BlockBegin* x) = 0;
duke@435 180 virtual void do_Goto (Goto* x) = 0;
duke@435 181 virtual void do_If (If* x) = 0;
duke@435 182 virtual void do_IfInstanceOf (IfInstanceOf* x) = 0;
duke@435 183 virtual void do_TableSwitch (TableSwitch* x) = 0;
duke@435 184 virtual void do_LookupSwitch (LookupSwitch* x) = 0;
duke@435 185 virtual void do_Return (Return* x) = 0;
duke@435 186 virtual void do_Throw (Throw* x) = 0;
duke@435 187 virtual void do_Base (Base* x) = 0;
duke@435 188 virtual void do_OsrEntry (OsrEntry* x) = 0;
duke@435 189 virtual void do_ExceptionObject(ExceptionObject* x) = 0;
duke@435 190 virtual void do_RoundFP (RoundFP* x) = 0;
duke@435 191 virtual void do_UnsafeGetRaw (UnsafeGetRaw* x) = 0;
duke@435 192 virtual void do_UnsafePutRaw (UnsafePutRaw* x) = 0;
duke@435 193 virtual void do_UnsafeGetObject(UnsafeGetObject* x) = 0;
duke@435 194 virtual void do_UnsafePutObject(UnsafePutObject* x) = 0;
duke@435 195 virtual void do_UnsafePrefetchRead (UnsafePrefetchRead* x) = 0;
duke@435 196 virtual void do_UnsafePrefetchWrite(UnsafePrefetchWrite* x) = 0;
duke@435 197 virtual void do_ProfileCall (ProfileCall* x) = 0;
duke@435 198 virtual void do_ProfileCounter (ProfileCounter* x) = 0;
duke@435 199 };
duke@435 200
duke@435 201
duke@435 202 // Hashing support
duke@435 203 //
duke@435 204 // Note: This hash functions affect the performance
duke@435 205 // of ValueMap - make changes carefully!
duke@435 206
duke@435 207 #define HASH1(x1 ) ((intx)(x1))
duke@435 208 #define HASH2(x1, x2 ) ((HASH1(x1 ) << 7) ^ HASH1(x2))
duke@435 209 #define HASH3(x1, x2, x3 ) ((HASH2(x1, x2 ) << 7) ^ HASH1(x3))
duke@435 210 #define HASH4(x1, x2, x3, x4) ((HASH3(x1, x2, x3) << 7) ^ HASH1(x4))
duke@435 211
duke@435 212
duke@435 213 // The following macros are used to implement instruction-specific hashing.
duke@435 214 // By default, each instruction implements hash() and is_equal(Value), used
duke@435 215 // for value numbering/common subexpression elimination. The default imple-
duke@435 216 // mentation disables value numbering. Each instruction which can be value-
duke@435 217 // numbered, should define corresponding hash() and is_equal(Value) functions
duke@435 218 // via the macros below. The f arguments specify all the values/op codes, etc.
duke@435 219 // that need to be identical for two instructions to be identical.
duke@435 220 //
duke@435 221 // Note: The default implementation of hash() returns 0 in order to indicate
duke@435 222 // that the instruction should not be considered for value numbering.
duke@435 223 // The currently used hash functions do not guarantee that never a 0
duke@435 224 // is produced. While this is still correct, it may be a performance
duke@435 225 // bug (no value numbering for that node). However, this situation is
duke@435 226 // so unlikely, that we are not going to handle it specially.
duke@435 227
duke@435 228 #define HASHING1(class_name, enabled, f1) \
duke@435 229 virtual intx hash() const { \
duke@435 230 return (enabled) ? HASH2(name(), f1) : 0; \
duke@435 231 } \
duke@435 232 virtual bool is_equal(Value v) const { \
duke@435 233 if (!(enabled) ) return false; \
duke@435 234 class_name* _v = v->as_##class_name(); \
duke@435 235 if (_v == NULL ) return false; \
duke@435 236 if (f1 != _v->f1) return false; \
duke@435 237 return true; \
duke@435 238 } \
duke@435 239
duke@435 240
duke@435 241 #define HASHING2(class_name, enabled, f1, f2) \
duke@435 242 virtual intx hash() const { \
duke@435 243 return (enabled) ? HASH3(name(), f1, f2) : 0; \
duke@435 244 } \
duke@435 245 virtual bool is_equal(Value v) const { \
duke@435 246 if (!(enabled) ) return false; \
duke@435 247 class_name* _v = v->as_##class_name(); \
duke@435 248 if (_v == NULL ) return false; \
duke@435 249 if (f1 != _v->f1) return false; \
duke@435 250 if (f2 != _v->f2) return false; \
duke@435 251 return true; \
duke@435 252 } \
duke@435 253
duke@435 254
duke@435 255 #define HASHING3(class_name, enabled, f1, f2, f3) \
duke@435 256 virtual intx hash() const { \
duke@435 257 return (enabled) ? HASH4(name(), f1, f2, f3) : 0; \
duke@435 258 } \
duke@435 259 virtual bool is_equal(Value v) const { \
duke@435 260 if (!(enabled) ) return false; \
duke@435 261 class_name* _v = v->as_##class_name(); \
duke@435 262 if (_v == NULL ) return false; \
duke@435 263 if (f1 != _v->f1) return false; \
duke@435 264 if (f2 != _v->f2) return false; \
duke@435 265 if (f3 != _v->f3) return false; \
duke@435 266 return true; \
duke@435 267 } \
duke@435 268
duke@435 269
duke@435 270 // The mother of all instructions...
duke@435 271
duke@435 272 class Instruction: public CompilationResourceObj {
duke@435 273 private:
duke@435 274 int _id; // the unique instruction id
duke@435 275 int _bci; // the instruction bci
duke@435 276 int _use_count; // the number of instructions refering to this value (w/o prev/next); only roots can have use count = 0 or > 1
duke@435 277 int _pin_state; // set of PinReason describing the reason for pinning
duke@435 278 ValueType* _type; // the instruction value type
duke@435 279 Instruction* _next; // the next instruction if any (NULL for BlockEnd instructions)
duke@435 280 Instruction* _subst; // the substitution instruction if any
duke@435 281 LIR_Opr _operand; // LIR specific information
duke@435 282 unsigned int _flags; // Flag bits
duke@435 283
duke@435 284 XHandlers* _exception_handlers; // Flat list of exception handlers covering this instruction
duke@435 285
duke@435 286 #ifdef ASSERT
duke@435 287 HiWord* _hi_word;
duke@435 288 #endif
duke@435 289
duke@435 290 friend class UseCountComputer;
iveresov@1939 291 friend class BlockBegin;
duke@435 292
duke@435 293 protected:
duke@435 294 void set_bci(int bci) { assert(bci == SynchronizationEntryBCI || bci >= 0, "illegal bci"); _bci = bci; }
duke@435 295 void set_type(ValueType* type) {
duke@435 296 assert(type != NULL, "type must exist");
duke@435 297 _type = type;
duke@435 298 }
duke@435 299
duke@435 300 public:
iveresov@1939 301 void* operator new(size_t size) {
iveresov@1939 302 Compilation* c = Compilation::current();
iveresov@1939 303 void* res = c->arena()->Amalloc(size);
iveresov@1939 304 ((Instruction*)res)->_id = c->get_next_id();
iveresov@1939 305 return res;
iveresov@1939 306 }
iveresov@1939 307
duke@435 308 enum InstructionFlag {
duke@435 309 NeedsNullCheckFlag = 0,
duke@435 310 CanTrapFlag,
duke@435 311 DirectCompareFlag,
duke@435 312 IsEliminatedFlag,
duke@435 313 IsInitializedFlag,
duke@435 314 IsLoadedFlag,
duke@435 315 IsSafepointFlag,
duke@435 316 IsStaticFlag,
duke@435 317 IsStrictfpFlag,
duke@435 318 NeedsStoreCheckFlag,
duke@435 319 NeedsWriteBarrierFlag,
duke@435 320 PreservesStateFlag,
duke@435 321 TargetIsFinalFlag,
duke@435 322 TargetIsLoadedFlag,
duke@435 323 TargetIsStrictfpFlag,
duke@435 324 UnorderedIsTrueFlag,
duke@435 325 NeedsPatchingFlag,
duke@435 326 ThrowIncompatibleClassChangeErrorFlag,
duke@435 327 ProfileMDOFlag,
duke@435 328 InstructionLastFlag
duke@435 329 };
duke@435 330
duke@435 331 public:
duke@435 332 bool check_flag(InstructionFlag id) const { return (_flags & (1 << id)) != 0; }
duke@435 333 void set_flag(InstructionFlag id, bool f) { _flags = f ? (_flags | (1 << id)) : (_flags & ~(1 << id)); };
duke@435 334
duke@435 335 // 'globally' used condition values
duke@435 336 enum Condition {
duke@435 337 eql, neq, lss, leq, gtr, geq
duke@435 338 };
duke@435 339
duke@435 340 // Instructions may be pinned for many reasons and under certain conditions
duke@435 341 // with enough knowledge it's possible to safely unpin them.
duke@435 342 enum PinReason {
duke@435 343 PinUnknown = 1 << 0
duke@435 344 , PinExplicitNullCheck = 1 << 3
duke@435 345 , PinStackForStateSplit= 1 << 12
duke@435 346 , PinStateSplitConstructor= 1 << 13
duke@435 347 , PinGlobalValueNumbering= 1 << 14
duke@435 348 };
duke@435 349
duke@435 350 static Condition mirror(Condition cond);
duke@435 351 static Condition negate(Condition cond);
duke@435 352
duke@435 353 // initialization
iveresov@1939 354 static int number_of_instructions() {
iveresov@1939 355 return Compilation::current()->number_of_instructions();
iveresov@1939 356 }
duke@435 357
duke@435 358 // creation
duke@435 359 Instruction(ValueType* type, bool type_is_constant = false, bool create_hi = true)
iveresov@1939 360 : _bci(-99)
duke@435 361 , _use_count(0)
duke@435 362 , _pin_state(0)
duke@435 363 , _type(type)
duke@435 364 , _next(NULL)
duke@435 365 , _subst(NULL)
duke@435 366 , _flags(0)
duke@435 367 , _operand(LIR_OprFact::illegalOpr)
duke@435 368 , _exception_handlers(NULL)
duke@435 369 #ifdef ASSERT
duke@435 370 , _hi_word(NULL)
duke@435 371 #endif
duke@435 372 {
duke@435 373 assert(type != NULL && (!type->is_constant() || type_is_constant), "type must exist");
duke@435 374 #ifdef ASSERT
duke@435 375 if (create_hi && type->is_double_word()) {
duke@435 376 create_hi_word();
duke@435 377 }
duke@435 378 #endif
duke@435 379 }
duke@435 380
duke@435 381 // accessors
duke@435 382 int id() const { return _id; }
duke@435 383 int bci() const { return _bci; }
duke@435 384 int use_count() const { return _use_count; }
duke@435 385 int pin_state() const { return _pin_state; }
duke@435 386 bool is_pinned() const { return _pin_state != 0 || PinAllInstructions; }
duke@435 387 ValueType* type() const { return _type; }
duke@435 388 Instruction* prev(BlockBegin* block); // use carefully, expensive operation
duke@435 389 Instruction* next() const { return _next; }
duke@435 390 bool has_subst() const { return _subst != NULL; }
duke@435 391 Instruction* subst() { return _subst == NULL ? this : _subst->subst(); }
duke@435 392 LIR_Opr operand() const { return _operand; }
duke@435 393
duke@435 394 void set_needs_null_check(bool f) { set_flag(NeedsNullCheckFlag, f); }
duke@435 395 bool needs_null_check() const { return check_flag(NeedsNullCheckFlag); }
duke@435 396
duke@435 397 bool has_uses() const { return use_count() > 0; }
duke@435 398 bool is_root() const { return is_pinned() || use_count() > 1; }
duke@435 399 XHandlers* exception_handlers() const { return _exception_handlers; }
duke@435 400
duke@435 401 // manipulation
duke@435 402 void pin(PinReason reason) { _pin_state |= reason; }
duke@435 403 void pin() { _pin_state |= PinUnknown; }
duke@435 404 // DANGEROUS: only used by EliminateStores
duke@435 405 void unpin(PinReason reason) { assert((reason & PinUnknown) == 0, "can't unpin unknown state"); _pin_state &= ~reason; }
duke@435 406 virtual void set_lock_stack(ValueStack* l) { /* do nothing*/ }
duke@435 407 virtual ValueStack* lock_stack() const { return NULL; }
duke@435 408
duke@435 409 Instruction* set_next(Instruction* next, int bci) {
duke@435 410 if (next != NULL) {
duke@435 411 assert(as_BlockEnd() == NULL, "BlockEnd instructions must have no next");
duke@435 412 assert(next->as_Phi() == NULL && next->as_Local() == NULL, "shouldn't link these instructions into list");
duke@435 413 next->set_bci(bci);
duke@435 414 }
duke@435 415 _next = next;
duke@435 416 return next;
duke@435 417 }
duke@435 418
duke@435 419 void set_subst(Instruction* subst) {
duke@435 420 assert(subst == NULL ||
duke@435 421 type()->base() == subst->type()->base() ||
duke@435 422 subst->type()->base() == illegalType, "type can't change");
duke@435 423 _subst = subst;
duke@435 424 }
duke@435 425 void set_exception_handlers(XHandlers *xhandlers) { _exception_handlers = xhandlers; }
duke@435 426
duke@435 427 #ifdef ASSERT
duke@435 428 // HiWord is used for debugging and is allocated early to avoid
duke@435 429 // allocation at inconvenient points
duke@435 430 HiWord* hi_word() { return _hi_word; }
duke@435 431 void create_hi_word();
duke@435 432 #endif
duke@435 433
duke@435 434
duke@435 435 // machine-specifics
duke@435 436 void set_operand(LIR_Opr operand) { assert(operand != LIR_OprFact::illegalOpr, "operand must exist"); _operand = operand; }
duke@435 437 void clear_operand() { _operand = LIR_OprFact::illegalOpr; }
duke@435 438
duke@435 439 // generic
duke@435 440 virtual Instruction* as_Instruction() { return this; } // to satisfy HASHING1 macro
duke@435 441 virtual HiWord* as_HiWord() { return NULL; }
duke@435 442 virtual Phi* as_Phi() { return NULL; }
duke@435 443 virtual Local* as_Local() { return NULL; }
duke@435 444 virtual Constant* as_Constant() { return NULL; }
duke@435 445 virtual AccessField* as_AccessField() { return NULL; }
duke@435 446 virtual LoadField* as_LoadField() { return NULL; }
duke@435 447 virtual StoreField* as_StoreField() { return NULL; }
duke@435 448 virtual AccessArray* as_AccessArray() { return NULL; }
duke@435 449 virtual ArrayLength* as_ArrayLength() { return NULL; }
duke@435 450 virtual AccessIndexed* as_AccessIndexed() { return NULL; }
duke@435 451 virtual LoadIndexed* as_LoadIndexed() { return NULL; }
duke@435 452 virtual StoreIndexed* as_StoreIndexed() { return NULL; }
duke@435 453 virtual NegateOp* as_NegateOp() { return NULL; }
duke@435 454 virtual Op2* as_Op2() { return NULL; }
duke@435 455 virtual ArithmeticOp* as_ArithmeticOp() { return NULL; }
duke@435 456 virtual ShiftOp* as_ShiftOp() { return NULL; }
duke@435 457 virtual LogicOp* as_LogicOp() { return NULL; }
duke@435 458 virtual CompareOp* as_CompareOp() { return NULL; }
duke@435 459 virtual IfOp* as_IfOp() { return NULL; }
duke@435 460 virtual Convert* as_Convert() { return NULL; }
duke@435 461 virtual NullCheck* as_NullCheck() { return NULL; }
duke@435 462 virtual OsrEntry* as_OsrEntry() { return NULL; }
duke@435 463 virtual StateSplit* as_StateSplit() { return NULL; }
duke@435 464 virtual Invoke* as_Invoke() { return NULL; }
duke@435 465 virtual NewInstance* as_NewInstance() { return NULL; }
duke@435 466 virtual NewArray* as_NewArray() { return NULL; }
duke@435 467 virtual NewTypeArray* as_NewTypeArray() { return NULL; }
duke@435 468 virtual NewObjectArray* as_NewObjectArray() { return NULL; }
duke@435 469 virtual NewMultiArray* as_NewMultiArray() { return NULL; }
duke@435 470 virtual TypeCheck* as_TypeCheck() { return NULL; }
duke@435 471 virtual CheckCast* as_CheckCast() { return NULL; }
duke@435 472 virtual InstanceOf* as_InstanceOf() { return NULL; }
duke@435 473 virtual AccessMonitor* as_AccessMonitor() { return NULL; }
duke@435 474 virtual MonitorEnter* as_MonitorEnter() { return NULL; }
duke@435 475 virtual MonitorExit* as_MonitorExit() { return NULL; }
duke@435 476 virtual Intrinsic* as_Intrinsic() { return NULL; }
duke@435 477 virtual BlockBegin* as_BlockBegin() { return NULL; }
duke@435 478 virtual BlockEnd* as_BlockEnd() { return NULL; }
duke@435 479 virtual Goto* as_Goto() { return NULL; }
duke@435 480 virtual If* as_If() { return NULL; }
duke@435 481 virtual IfInstanceOf* as_IfInstanceOf() { return NULL; }
duke@435 482 virtual TableSwitch* as_TableSwitch() { return NULL; }
duke@435 483 virtual LookupSwitch* as_LookupSwitch() { return NULL; }
duke@435 484 virtual Return* as_Return() { return NULL; }
duke@435 485 virtual Throw* as_Throw() { return NULL; }
duke@435 486 virtual Base* as_Base() { return NULL; }
duke@435 487 virtual RoundFP* as_RoundFP() { return NULL; }
duke@435 488 virtual ExceptionObject* as_ExceptionObject() { return NULL; }
duke@435 489 virtual UnsafeOp* as_UnsafeOp() { return NULL; }
duke@435 490
duke@435 491 virtual void visit(InstructionVisitor* v) = 0;
duke@435 492
duke@435 493 virtual bool can_trap() const { return false; }
duke@435 494
iveresov@1939 495 virtual void input_values_do(ValueVisitor* f) = 0;
iveresov@1939 496 virtual void state_values_do(ValueVisitor* f) { /* usually no state - override on demand */ }
iveresov@1939 497 virtual void other_values_do(ValueVisitor* f) { /* usually no other - override on demand */ }
iveresov@1939 498 void values_do(ValueVisitor* f) { input_values_do(f); state_values_do(f); other_values_do(f); }
duke@435 499
duke@435 500 virtual ciType* exact_type() const { return NULL; }
duke@435 501 virtual ciType* declared_type() const { return NULL; }
duke@435 502
duke@435 503 // hashing
duke@435 504 virtual const char* name() const = 0;
duke@435 505 HASHING1(Instruction, false, id()) // hashing disabled by default
duke@435 506
duke@435 507 // debugging
duke@435 508 void print() PRODUCT_RETURN;
duke@435 509 void print_line() PRODUCT_RETURN;
duke@435 510 void print(InstructionPrinter& ip) PRODUCT_RETURN;
duke@435 511 };
duke@435 512
duke@435 513
duke@435 514 // The following macros are used to define base (i.e., non-leaf)
duke@435 515 // and leaf instruction classes. They define class-name related
duke@435 516 // generic functionality in one place.
duke@435 517
duke@435 518 #define BASE(class_name, super_class_name) \
duke@435 519 class class_name: public super_class_name { \
duke@435 520 public: \
duke@435 521 virtual class_name* as_##class_name() { return this; } \
duke@435 522
duke@435 523
duke@435 524 #define LEAF(class_name, super_class_name) \
duke@435 525 BASE(class_name, super_class_name) \
duke@435 526 public: \
duke@435 527 virtual const char* name() const { return #class_name; } \
duke@435 528 virtual void visit(InstructionVisitor* v) { v->do_##class_name(this); } \
duke@435 529
duke@435 530
duke@435 531 // Debugging support
duke@435 532
iveresov@1939 533
duke@435 534 #ifdef ASSERT
iveresov@1939 535 class AssertValues: public ValueVisitor {
iveresov@1939 536 void visit(Value* x) { assert((*x) != NULL, "value must exist"); }
iveresov@1939 537 };
iveresov@1939 538 #define ASSERT_VALUES { AssertValues assert_value; values_do(&assert_value); }
duke@435 539 #else
duke@435 540 #define ASSERT_VALUES
duke@435 541 #endif // ASSERT
duke@435 542
duke@435 543
duke@435 544 // A HiWord occupies the 'high word' of a 2-word
duke@435 545 // expression stack entry. Hi & lo words must be
duke@435 546 // paired on the expression stack (otherwise the
duke@435 547 // bytecode sequence is illegal). Note that 'hi'
duke@435 548 // refers to the IR expression stack format and
duke@435 549 // does *not* imply a machine word ordering. No
duke@435 550 // HiWords are used in optimized mode for speed,
duke@435 551 // but NULL pointers are used instead.
duke@435 552
duke@435 553 LEAF(HiWord, Instruction)
duke@435 554 private:
duke@435 555 Value _lo_word;
duke@435 556
duke@435 557 public:
duke@435 558 // creation
duke@435 559 HiWord(Value lo_word)
duke@435 560 : Instruction(illegalType, false, false),
duke@435 561 _lo_word(lo_word) {
duke@435 562 // hi-words are also allowed for illegal lo-words
duke@435 563 assert(lo_word->type()->is_double_word() || lo_word->type()->is_illegal(),
duke@435 564 "HiWord must be used for 2-word values only");
duke@435 565 }
duke@435 566
duke@435 567 // accessors
duke@435 568 Value lo_word() const { return _lo_word->subst(); }
duke@435 569
duke@435 570 // for invalidating of HiWords
duke@435 571 void make_illegal() { set_type(illegalType); }
duke@435 572
duke@435 573 // generic
iveresov@1939 574 virtual void input_values_do(ValueVisitor* f) { ShouldNotReachHere(); }
duke@435 575 };
duke@435 576
duke@435 577
duke@435 578 // A Phi is a phi function in the sense of SSA form. It stands for
duke@435 579 // the value of a local variable at the beginning of a join block.
duke@435 580 // A Phi consists of n operands, one for every incoming branch.
duke@435 581
duke@435 582 LEAF(Phi, Instruction)
duke@435 583 private:
duke@435 584 BlockBegin* _block; // the block to which the phi function belongs
duke@435 585 int _pf_flags; // the flags of the phi function
duke@435 586 int _index; // to value on operand stack (index < 0) or to local
duke@435 587 public:
duke@435 588 // creation
duke@435 589 Phi(ValueType* type, BlockBegin* b, int index)
duke@435 590 : Instruction(type->base())
duke@435 591 , _pf_flags(0)
duke@435 592 , _block(b)
duke@435 593 , _index(index)
duke@435 594 {
duke@435 595 if (type->is_illegal()) {
duke@435 596 make_illegal();
duke@435 597 }
duke@435 598 }
duke@435 599
duke@435 600 // flags
duke@435 601 enum Flag {
duke@435 602 no_flag = 0,
duke@435 603 visited = 1 << 0,
duke@435 604 cannot_simplify = 1 << 1
duke@435 605 };
duke@435 606
duke@435 607 // accessors
duke@435 608 bool is_local() const { return _index >= 0; }
duke@435 609 bool is_on_stack() const { return !is_local(); }
duke@435 610 int local_index() const { assert(is_local(), ""); return _index; }
duke@435 611 int stack_index() const { assert(is_on_stack(), ""); return -(_index+1); }
duke@435 612
duke@435 613 Value operand_at(int i) const;
duke@435 614 int operand_count() const;
duke@435 615
duke@435 616 BlockBegin* block() const { return _block; }
duke@435 617
duke@435 618 void set(Flag f) { _pf_flags |= f; }
duke@435 619 void clear(Flag f) { _pf_flags &= ~f; }
duke@435 620 bool is_set(Flag f) const { return (_pf_flags & f) != 0; }
duke@435 621
duke@435 622 // Invalidates phis corresponding to merges of locals of two different types
duke@435 623 // (these should never be referenced, otherwise the bytecodes are illegal)
duke@435 624 void make_illegal() {
duke@435 625 set(cannot_simplify);
duke@435 626 set_type(illegalType);
duke@435 627 }
duke@435 628
duke@435 629 bool is_illegal() const {
duke@435 630 return type()->is_illegal();
duke@435 631 }
duke@435 632
duke@435 633 // generic
iveresov@1939 634 virtual void input_values_do(ValueVisitor* f) {
duke@435 635 }
duke@435 636 };
duke@435 637
duke@435 638
duke@435 639 // A local is a placeholder for an incoming argument to a function call.
duke@435 640 LEAF(Local, Instruction)
duke@435 641 private:
duke@435 642 int _java_index; // the local index within the method to which the local belongs
duke@435 643 public:
duke@435 644 // creation
duke@435 645 Local(ValueType* type, int index)
duke@435 646 : Instruction(type)
duke@435 647 , _java_index(index)
duke@435 648 {}
duke@435 649
duke@435 650 // accessors
duke@435 651 int java_index() const { return _java_index; }
duke@435 652
duke@435 653 // generic
iveresov@1939 654 virtual void input_values_do(ValueVisitor* f) { /* no values */ }
duke@435 655 };
duke@435 656
duke@435 657
duke@435 658 LEAF(Constant, Instruction)
duke@435 659 ValueStack* _state;
duke@435 660
duke@435 661 public:
duke@435 662 // creation
duke@435 663 Constant(ValueType* type):
duke@435 664 Instruction(type, true)
duke@435 665 , _state(NULL) {
duke@435 666 assert(type->is_constant(), "must be a constant");
duke@435 667 }
duke@435 668
duke@435 669 Constant(ValueType* type, ValueStack* state):
duke@435 670 Instruction(type, true)
duke@435 671 , _state(state) {
duke@435 672 assert(state != NULL, "only used for constants which need patching");
duke@435 673 assert(type->is_constant(), "must be a constant");
duke@435 674 // since it's patching it needs to be pinned
duke@435 675 pin();
duke@435 676 }
duke@435 677
duke@435 678 ValueStack* state() const { return _state; }
duke@435 679
duke@435 680 // generic
duke@435 681 virtual bool can_trap() const { return state() != NULL; }
iveresov@1939 682 virtual void input_values_do(ValueVisitor* f) { /* no values */ }
iveresov@1939 683 virtual void other_values_do(ValueVisitor* f);
duke@435 684
duke@435 685 virtual intx hash() const;
duke@435 686 virtual bool is_equal(Value v) const;
duke@435 687
duke@435 688 virtual BlockBegin* compare(Instruction::Condition condition, Value right,
duke@435 689 BlockBegin* true_sux, BlockBegin* false_sux);
duke@435 690 };
duke@435 691
duke@435 692
duke@435 693 BASE(AccessField, Instruction)
duke@435 694 private:
duke@435 695 Value _obj;
duke@435 696 int _offset;
duke@435 697 ciField* _field;
duke@435 698 ValueStack* _state_before; // state is set only for unloaded or uninitialized fields
duke@435 699 ValueStack* _lock_stack; // contains lock and scope information
duke@435 700 NullCheck* _explicit_null_check; // For explicit null check elimination
duke@435 701
duke@435 702 public:
duke@435 703 // creation
duke@435 704 AccessField(Value obj, int offset, ciField* field, bool is_static, ValueStack* lock_stack,
duke@435 705 ValueStack* state_before, bool is_loaded, bool is_initialized)
duke@435 706 : Instruction(as_ValueType(field->type()->basic_type()))
duke@435 707 , _obj(obj)
duke@435 708 , _offset(offset)
duke@435 709 , _field(field)
duke@435 710 , _lock_stack(lock_stack)
duke@435 711 , _state_before(state_before)
duke@435 712 , _explicit_null_check(NULL)
duke@435 713 {
duke@435 714 set_needs_null_check(!is_static);
duke@435 715 set_flag(IsLoadedFlag, is_loaded);
duke@435 716 set_flag(IsInitializedFlag, is_initialized);
duke@435 717 set_flag(IsStaticFlag, is_static);
duke@435 718 ASSERT_VALUES
duke@435 719 if (!is_loaded || (PatchALot && !field->is_volatile())) {
duke@435 720 // need to patch if the holder wasn't loaded or we're testing
duke@435 721 // using PatchALot. Don't allow PatchALot for fields which are
duke@435 722 // known to be volatile they aren't patchable.
duke@435 723 set_flag(NeedsPatchingFlag, true);
duke@435 724 }
duke@435 725 // pin of all instructions with memory access
duke@435 726 pin();
duke@435 727 }
duke@435 728
duke@435 729 // accessors
duke@435 730 Value obj() const { return _obj; }
duke@435 731 int offset() const { return _offset; }
duke@435 732 ciField* field() const { return _field; }
duke@435 733 BasicType field_type() const { return _field->type()->basic_type(); }
duke@435 734 bool is_static() const { return check_flag(IsStaticFlag); }
duke@435 735 bool is_loaded() const { return check_flag(IsLoadedFlag); }
duke@435 736 bool is_initialized() const { return check_flag(IsInitializedFlag); }
duke@435 737 ValueStack* state_before() const { return _state_before; }
duke@435 738 ValueStack* lock_stack() const { return _lock_stack; }
duke@435 739 NullCheck* explicit_null_check() const { return _explicit_null_check; }
duke@435 740 bool needs_patching() const { return check_flag(NeedsPatchingFlag); }
duke@435 741
duke@435 742 // manipulation
duke@435 743 void set_lock_stack(ValueStack* l) { _lock_stack = l; }
duke@435 744 // Under certain circumstances, if a previous NullCheck instruction
duke@435 745 // proved the target object non-null, we can eliminate the explicit
duke@435 746 // null check and do an implicit one, simply specifying the debug
duke@435 747 // information from the NullCheck. This field should only be consulted
duke@435 748 // if needs_null_check() is true.
duke@435 749 void set_explicit_null_check(NullCheck* check) { _explicit_null_check = check; }
duke@435 750
duke@435 751 // generic
duke@435 752 virtual bool can_trap() const { return needs_null_check() || needs_patching(); }
iveresov@1939 753 virtual void input_values_do(ValueVisitor* f) { f->visit(&_obj); }
iveresov@1939 754 virtual void other_values_do(ValueVisitor* f);
duke@435 755 };
duke@435 756
duke@435 757
duke@435 758 LEAF(LoadField, AccessField)
duke@435 759 public:
duke@435 760 // creation
duke@435 761 LoadField(Value obj, int offset, ciField* field, bool is_static, ValueStack* lock_stack,
duke@435 762 ValueStack* state_before, bool is_loaded, bool is_initialized)
duke@435 763 : AccessField(obj, offset, field, is_static, lock_stack, state_before, is_loaded, is_initialized)
duke@435 764 {}
duke@435 765
duke@435 766 ciType* declared_type() const;
duke@435 767 ciType* exact_type() const;
duke@435 768
duke@435 769 // generic
duke@435 770 HASHING2(LoadField, is_loaded() && !field()->is_volatile(), obj()->subst(), offset()) // cannot be eliminated if not yet loaded or if volatile
duke@435 771 };
duke@435 772
duke@435 773
duke@435 774 LEAF(StoreField, AccessField)
duke@435 775 private:
duke@435 776 Value _value;
duke@435 777
duke@435 778 public:
duke@435 779 // creation
duke@435 780 StoreField(Value obj, int offset, ciField* field, Value value, bool is_static, ValueStack* lock_stack,
duke@435 781 ValueStack* state_before, bool is_loaded, bool is_initialized)
duke@435 782 : AccessField(obj, offset, field, is_static, lock_stack, state_before, is_loaded, is_initialized)
duke@435 783 , _value(value)
duke@435 784 {
duke@435 785 set_flag(NeedsWriteBarrierFlag, as_ValueType(field_type())->is_object());
duke@435 786 ASSERT_VALUES
duke@435 787 pin();
duke@435 788 }
duke@435 789
duke@435 790 // accessors
duke@435 791 Value value() const { return _value; }
duke@435 792 bool needs_write_barrier() const { return check_flag(NeedsWriteBarrierFlag); }
duke@435 793
duke@435 794 // generic
iveresov@1939 795 virtual void input_values_do(ValueVisitor* f) { AccessField::input_values_do(f); f->visit(&_value); }
duke@435 796 };
duke@435 797
duke@435 798
duke@435 799 BASE(AccessArray, Instruction)
duke@435 800 private:
duke@435 801 Value _array;
duke@435 802 ValueStack* _lock_stack;
duke@435 803
duke@435 804 public:
duke@435 805 // creation
duke@435 806 AccessArray(ValueType* type, Value array, ValueStack* lock_stack)
duke@435 807 : Instruction(type)
duke@435 808 , _array(array)
duke@435 809 , _lock_stack(lock_stack) {
duke@435 810 set_needs_null_check(true);
duke@435 811 ASSERT_VALUES
duke@435 812 pin(); // instruction with side effect (null exception or range check throwing)
duke@435 813 }
duke@435 814
duke@435 815 Value array() const { return _array; }
duke@435 816 ValueStack* lock_stack() const { return _lock_stack; }
duke@435 817
duke@435 818 // setters
duke@435 819 void set_lock_stack(ValueStack* l) { _lock_stack = l; }
duke@435 820
duke@435 821 // generic
duke@435 822 virtual bool can_trap() const { return needs_null_check(); }
iveresov@1939 823 virtual void input_values_do(ValueVisitor* f) { f->visit(&_array); }
iveresov@1939 824 virtual void other_values_do(ValueVisitor* f);
duke@435 825 };
duke@435 826
duke@435 827
duke@435 828 LEAF(ArrayLength, AccessArray)
duke@435 829 private:
duke@435 830 NullCheck* _explicit_null_check; // For explicit null check elimination
duke@435 831
duke@435 832 public:
duke@435 833 // creation
duke@435 834 ArrayLength(Value array, ValueStack* lock_stack)
duke@435 835 : AccessArray(intType, array, lock_stack)
duke@435 836 , _explicit_null_check(NULL) {}
duke@435 837
duke@435 838 // accessors
duke@435 839 NullCheck* explicit_null_check() const { return _explicit_null_check; }
duke@435 840
duke@435 841 // setters
duke@435 842 // See LoadField::set_explicit_null_check for documentation
duke@435 843 void set_explicit_null_check(NullCheck* check) { _explicit_null_check = check; }
duke@435 844
duke@435 845 // generic
duke@435 846 HASHING1(ArrayLength, true, array()->subst())
duke@435 847 };
duke@435 848
duke@435 849
duke@435 850 BASE(AccessIndexed, AccessArray)
duke@435 851 private:
duke@435 852 Value _index;
duke@435 853 Value _length;
duke@435 854 BasicType _elt_type;
duke@435 855
duke@435 856 public:
duke@435 857 // creation
duke@435 858 AccessIndexed(Value array, Value index, Value length, BasicType elt_type, ValueStack* lock_stack)
duke@435 859 : AccessArray(as_ValueType(elt_type), array, lock_stack)
duke@435 860 , _index(index)
duke@435 861 , _length(length)
duke@435 862 , _elt_type(elt_type)
duke@435 863 {
duke@435 864 ASSERT_VALUES
duke@435 865 }
duke@435 866
duke@435 867 // accessors
duke@435 868 Value index() const { return _index; }
duke@435 869 Value length() const { return _length; }
duke@435 870 BasicType elt_type() const { return _elt_type; }
duke@435 871
duke@435 872 // perform elimination of range checks involving constants
duke@435 873 bool compute_needs_range_check();
duke@435 874
duke@435 875 // generic
iveresov@1939 876 virtual void input_values_do(ValueVisitor* f) { AccessArray::input_values_do(f); f->visit(&_index); if (_length != NULL) f->visit(&_length); }
duke@435 877 };
duke@435 878
duke@435 879
duke@435 880 LEAF(LoadIndexed, AccessIndexed)
duke@435 881 private:
duke@435 882 NullCheck* _explicit_null_check; // For explicit null check elimination
duke@435 883
duke@435 884 public:
duke@435 885 // creation
duke@435 886 LoadIndexed(Value array, Value index, Value length, BasicType elt_type, ValueStack* lock_stack)
duke@435 887 : AccessIndexed(array, index, length, elt_type, lock_stack)
duke@435 888 , _explicit_null_check(NULL) {}
duke@435 889
duke@435 890 // accessors
duke@435 891 NullCheck* explicit_null_check() const { return _explicit_null_check; }
duke@435 892
duke@435 893 // setters
duke@435 894 // See LoadField::set_explicit_null_check for documentation
duke@435 895 void set_explicit_null_check(NullCheck* check) { _explicit_null_check = check; }
duke@435 896
duke@435 897 ciType* exact_type() const;
duke@435 898 ciType* declared_type() const;
duke@435 899
duke@435 900 // generic
duke@435 901 HASHING2(LoadIndexed, true, array()->subst(), index()->subst())
duke@435 902 };
duke@435 903
duke@435 904
duke@435 905 LEAF(StoreIndexed, AccessIndexed)
duke@435 906 private:
duke@435 907 Value _value;
duke@435 908
duke@435 909 public:
duke@435 910 // creation
duke@435 911 StoreIndexed(Value array, Value index, Value length, BasicType elt_type, Value value, ValueStack* lock_stack)
duke@435 912 : AccessIndexed(array, index, length, elt_type, lock_stack)
duke@435 913 , _value(value)
duke@435 914 {
duke@435 915 set_flag(NeedsWriteBarrierFlag, (as_ValueType(elt_type)->is_object()));
duke@435 916 set_flag(NeedsStoreCheckFlag, (as_ValueType(elt_type)->is_object()));
duke@435 917 ASSERT_VALUES
duke@435 918 pin();
duke@435 919 }
duke@435 920
duke@435 921 // accessors
duke@435 922 Value value() const { return _value; }
duke@435 923 IRScope* scope() const; // the state's scope
duke@435 924 bool needs_write_barrier() const { return check_flag(NeedsWriteBarrierFlag); }
duke@435 925 bool needs_store_check() const { return check_flag(NeedsStoreCheckFlag); }
duke@435 926
duke@435 927 // generic
iveresov@1939 928 virtual void input_values_do(ValueVisitor* f) { AccessIndexed::input_values_do(f); f->visit(&_value); }
duke@435 929 };
duke@435 930
duke@435 931
duke@435 932 LEAF(NegateOp, Instruction)
duke@435 933 private:
duke@435 934 Value _x;
duke@435 935
duke@435 936 public:
duke@435 937 // creation
duke@435 938 NegateOp(Value x) : Instruction(x->type()->base()), _x(x) {
duke@435 939 ASSERT_VALUES
duke@435 940 }
duke@435 941
duke@435 942 // accessors
duke@435 943 Value x() const { return _x; }
duke@435 944
duke@435 945 // generic
iveresov@1939 946 virtual void input_values_do(ValueVisitor* f) { f->visit(&_x); }
duke@435 947 };
duke@435 948
duke@435 949
duke@435 950 BASE(Op2, Instruction)
duke@435 951 private:
duke@435 952 Bytecodes::Code _op;
duke@435 953 Value _x;
duke@435 954 Value _y;
duke@435 955
duke@435 956 public:
duke@435 957 // creation
duke@435 958 Op2(ValueType* type, Bytecodes::Code op, Value x, Value y) : Instruction(type), _op(op), _x(x), _y(y) {
duke@435 959 ASSERT_VALUES
duke@435 960 }
duke@435 961
duke@435 962 // accessors
duke@435 963 Bytecodes::Code op() const { return _op; }
duke@435 964 Value x() const { return _x; }
duke@435 965 Value y() const { return _y; }
duke@435 966
duke@435 967 // manipulators
duke@435 968 void swap_operands() {
duke@435 969 assert(is_commutative(), "operation must be commutative");
duke@435 970 Value t = _x; _x = _y; _y = t;
duke@435 971 }
duke@435 972
duke@435 973 // generic
duke@435 974 virtual bool is_commutative() const { return false; }
iveresov@1939 975 virtual void input_values_do(ValueVisitor* f) { f->visit(&_x); f->visit(&_y); }
duke@435 976 };
duke@435 977
duke@435 978
duke@435 979 LEAF(ArithmeticOp, Op2)
duke@435 980 private:
duke@435 981 ValueStack* _lock_stack; // used only for division operations
duke@435 982 public:
duke@435 983 // creation
duke@435 984 ArithmeticOp(Bytecodes::Code op, Value x, Value y, bool is_strictfp, ValueStack* lock_stack)
duke@435 985 : Op2(x->type()->meet(y->type()), op, x, y)
duke@435 986 , _lock_stack(lock_stack) {
duke@435 987 set_flag(IsStrictfpFlag, is_strictfp);
duke@435 988 if (can_trap()) pin();
duke@435 989 }
duke@435 990
duke@435 991 // accessors
duke@435 992 ValueStack* lock_stack() const { return _lock_stack; }
duke@435 993 bool is_strictfp() const { return check_flag(IsStrictfpFlag); }
duke@435 994
duke@435 995 // setters
duke@435 996 void set_lock_stack(ValueStack* l) { _lock_stack = l; }
duke@435 997
duke@435 998 // generic
duke@435 999 virtual bool is_commutative() const;
duke@435 1000 virtual bool can_trap() const;
iveresov@1939 1001 virtual void other_values_do(ValueVisitor* f);
duke@435 1002 HASHING3(Op2, true, op(), x()->subst(), y()->subst())
duke@435 1003 };
duke@435 1004
duke@435 1005
duke@435 1006 LEAF(ShiftOp, Op2)
duke@435 1007 public:
duke@435 1008 // creation
duke@435 1009 ShiftOp(Bytecodes::Code op, Value x, Value s) : Op2(x->type()->base(), op, x, s) {}
duke@435 1010
duke@435 1011 // generic
duke@435 1012 HASHING3(Op2, true, op(), x()->subst(), y()->subst())
duke@435 1013 };
duke@435 1014
duke@435 1015
duke@435 1016 LEAF(LogicOp, Op2)
duke@435 1017 public:
duke@435 1018 // creation
duke@435 1019 LogicOp(Bytecodes::Code op, Value x, Value y) : Op2(x->type()->meet(y->type()), op, x, y) {}
duke@435 1020
duke@435 1021 // generic
duke@435 1022 virtual bool is_commutative() const;
duke@435 1023 HASHING3(Op2, true, op(), x()->subst(), y()->subst())
duke@435 1024 };
duke@435 1025
duke@435 1026
duke@435 1027 LEAF(CompareOp, Op2)
duke@435 1028 private:
duke@435 1029 ValueStack* _state_before; // for deoptimization, when canonicalizing
duke@435 1030 public:
duke@435 1031 // creation
duke@435 1032 CompareOp(Bytecodes::Code op, Value x, Value y, ValueStack* state_before)
duke@435 1033 : Op2(intType, op, x, y)
duke@435 1034 , _state_before(state_before)
duke@435 1035 {}
duke@435 1036
duke@435 1037 // accessors
duke@435 1038 ValueStack* state_before() const { return _state_before; }
duke@435 1039
duke@435 1040 // generic
duke@435 1041 HASHING3(Op2, true, op(), x()->subst(), y()->subst())
iveresov@1939 1042 virtual void other_values_do(ValueVisitor* f);
duke@435 1043 };
duke@435 1044
duke@435 1045
duke@435 1046 LEAF(IfOp, Op2)
duke@435 1047 private:
duke@435 1048 Value _tval;
duke@435 1049 Value _fval;
duke@435 1050
duke@435 1051 public:
duke@435 1052 // creation
duke@435 1053 IfOp(Value x, Condition cond, Value y, Value tval, Value fval)
duke@435 1054 : Op2(tval->type()->meet(fval->type()), (Bytecodes::Code)cond, x, y)
duke@435 1055 , _tval(tval)
duke@435 1056 , _fval(fval)
duke@435 1057 {
duke@435 1058 ASSERT_VALUES
duke@435 1059 assert(tval->type()->tag() == fval->type()->tag(), "types must match");
duke@435 1060 }
duke@435 1061
duke@435 1062 // accessors
duke@435 1063 virtual bool is_commutative() const;
duke@435 1064 Bytecodes::Code op() const { ShouldNotCallThis(); return Bytecodes::_illegal; }
duke@435 1065 Condition cond() const { return (Condition)Op2::op(); }
duke@435 1066 Value tval() const { return _tval; }
duke@435 1067 Value fval() const { return _fval; }
duke@435 1068
duke@435 1069 // generic
iveresov@1939 1070 virtual void input_values_do(ValueVisitor* f) { Op2::input_values_do(f); f->visit(&_tval); f->visit(&_fval); }
duke@435 1071 };
duke@435 1072
duke@435 1073
duke@435 1074 LEAF(Convert, Instruction)
duke@435 1075 private:
duke@435 1076 Bytecodes::Code _op;
duke@435 1077 Value _value;
duke@435 1078
duke@435 1079 public:
duke@435 1080 // creation
duke@435 1081 Convert(Bytecodes::Code op, Value value, ValueType* to_type) : Instruction(to_type), _op(op), _value(value) {
duke@435 1082 ASSERT_VALUES
duke@435 1083 }
duke@435 1084
duke@435 1085 // accessors
duke@435 1086 Bytecodes::Code op() const { return _op; }
duke@435 1087 Value value() const { return _value; }
duke@435 1088
duke@435 1089 // generic
iveresov@1939 1090 virtual void input_values_do(ValueVisitor* f) { f->visit(&_value); }
duke@435 1091 HASHING2(Convert, true, op(), value()->subst())
duke@435 1092 };
duke@435 1093
duke@435 1094
duke@435 1095 LEAF(NullCheck, Instruction)
duke@435 1096 private:
duke@435 1097 Value _obj;
duke@435 1098 ValueStack* _lock_stack;
duke@435 1099
duke@435 1100 public:
duke@435 1101 // creation
duke@435 1102 NullCheck(Value obj, ValueStack* lock_stack) : Instruction(obj->type()->base()), _obj(obj), _lock_stack(lock_stack) {
duke@435 1103 ASSERT_VALUES
duke@435 1104 set_can_trap(true);
duke@435 1105 assert(_obj->type()->is_object(), "null check must be applied to objects only");
duke@435 1106 pin(Instruction::PinExplicitNullCheck);
duke@435 1107 }
duke@435 1108
duke@435 1109 // accessors
duke@435 1110 Value obj() const { return _obj; }
duke@435 1111 ValueStack* lock_stack() const { return _lock_stack; }
duke@435 1112
duke@435 1113 // setters
duke@435 1114 void set_lock_stack(ValueStack* l) { _lock_stack = l; }
duke@435 1115 void set_can_trap(bool can_trap) { set_flag(CanTrapFlag, can_trap); }
duke@435 1116
duke@435 1117 // generic
duke@435 1118 virtual bool can_trap() const { return check_flag(CanTrapFlag); /* null-check elimination sets to false */ }
iveresov@1939 1119 virtual void input_values_do(ValueVisitor* f) { f->visit(&_obj); }
iveresov@1939 1120 virtual void other_values_do(ValueVisitor* f);
duke@435 1121 HASHING1(NullCheck, true, obj()->subst())
duke@435 1122 };
duke@435 1123
duke@435 1124
duke@435 1125 BASE(StateSplit, Instruction)
duke@435 1126 private:
duke@435 1127 ValueStack* _state;
duke@435 1128
duke@435 1129 protected:
duke@435 1130 static void substitute(BlockList& list, BlockBegin* old_block, BlockBegin* new_block);
duke@435 1131
duke@435 1132 public:
duke@435 1133 // creation
duke@435 1134 StateSplit(ValueType* type) : Instruction(type), _state(NULL) {
duke@435 1135 pin(PinStateSplitConstructor);
duke@435 1136 }
duke@435 1137
duke@435 1138 // accessors
duke@435 1139 ValueStack* state() const { return _state; }
duke@435 1140 IRScope* scope() const; // the state's scope
duke@435 1141
duke@435 1142 // manipulation
duke@435 1143 void set_state(ValueStack* state) { _state = state; }
duke@435 1144
duke@435 1145 // generic
iveresov@1939 1146 virtual void input_values_do(ValueVisitor* f) { /* no values */ }
iveresov@1939 1147 virtual void state_values_do(ValueVisitor* f);
duke@435 1148 };
duke@435 1149
duke@435 1150
duke@435 1151 LEAF(Invoke, StateSplit)
duke@435 1152 private:
twisti@1730 1153 Bytecodes::Code _code;
twisti@1730 1154 Value _recv;
twisti@1730 1155 Values* _args;
twisti@1730 1156 BasicTypeList* _signature;
twisti@1730 1157 int _vtable_index;
twisti@1730 1158 ciMethod* _target;
twisti@1730 1159 ValueStack* _state_before; // Required for deoptimization.
duke@435 1160
duke@435 1161 public:
duke@435 1162 // creation
duke@435 1163 Invoke(Bytecodes::Code code, ValueType* result_type, Value recv, Values* args,
twisti@1730 1164 int vtable_index, ciMethod* target, ValueStack* state_before);
duke@435 1165
duke@435 1166 // accessors
duke@435 1167 Bytecodes::Code code() const { return _code; }
duke@435 1168 Value receiver() const { return _recv; }
duke@435 1169 bool has_receiver() const { return receiver() != NULL; }
duke@435 1170 int number_of_arguments() const { return _args->length(); }
duke@435 1171 Value argument_at(int i) const { return _args->at(i); }
duke@435 1172 int vtable_index() const { return _vtable_index; }
duke@435 1173 BasicTypeList* signature() const { return _signature; }
duke@435 1174 ciMethod* target() const { return _target; }
twisti@1730 1175 ValueStack* state_before() const { return _state_before; }
duke@435 1176
duke@435 1177 // Returns false if target is not loaded
duke@435 1178 bool target_is_final() const { return check_flag(TargetIsFinalFlag); }
duke@435 1179 bool target_is_loaded() const { return check_flag(TargetIsLoadedFlag); }
duke@435 1180 // Returns false if target is not loaded
duke@435 1181 bool target_is_strictfp() const { return check_flag(TargetIsStrictfpFlag); }
duke@435 1182
twisti@1730 1183 // JSR 292 support
twisti@1730 1184 bool is_invokedynamic() const { return code() == Bytecodes::_invokedynamic; }
twisti@1730 1185
duke@435 1186 // generic
duke@435 1187 virtual bool can_trap() const { return true; }
iveresov@1939 1188 virtual void input_values_do(ValueVisitor* f) {
duke@435 1189 StateSplit::input_values_do(f);
iveresov@1939 1190 if (has_receiver()) f->visit(&_recv);
iveresov@1939 1191 for (int i = 0; i < _args->length(); i++) f->visit(_args->adr_at(i));
duke@435 1192 }
iveresov@1939 1193 virtual void state_values_do(ValueVisitor *f);
duke@435 1194 };
duke@435 1195
duke@435 1196
duke@435 1197 LEAF(NewInstance, StateSplit)
duke@435 1198 private:
duke@435 1199 ciInstanceKlass* _klass;
duke@435 1200
duke@435 1201 public:
duke@435 1202 // creation
duke@435 1203 NewInstance(ciInstanceKlass* klass) : StateSplit(instanceType), _klass(klass) {}
duke@435 1204
duke@435 1205 // accessors
duke@435 1206 ciInstanceKlass* klass() const { return _klass; }
duke@435 1207
duke@435 1208 // generic
duke@435 1209 virtual bool can_trap() const { return true; }
duke@435 1210 ciType* exact_type() const;
duke@435 1211 };
duke@435 1212
duke@435 1213
duke@435 1214 BASE(NewArray, StateSplit)
duke@435 1215 private:
duke@435 1216 Value _length;
duke@435 1217 ValueStack* _state_before;
duke@435 1218
duke@435 1219 public:
duke@435 1220 // creation
duke@435 1221 NewArray(Value length, ValueStack* state_before) : StateSplit(objectType), _length(length), _state_before(state_before) {
duke@435 1222 // Do not ASSERT_VALUES since length is NULL for NewMultiArray
duke@435 1223 }
duke@435 1224
duke@435 1225 // accessors
duke@435 1226 ValueStack* state_before() const { return _state_before; }
duke@435 1227 Value length() const { return _length; }
duke@435 1228
duke@435 1229 // generic
duke@435 1230 virtual bool can_trap() const { return true; }
iveresov@1939 1231 virtual void input_values_do(ValueVisitor* f) { StateSplit::input_values_do(f); f->visit(&_length); }
iveresov@1939 1232 virtual void other_values_do(ValueVisitor* f);
duke@435 1233 };
duke@435 1234
duke@435 1235
duke@435 1236 LEAF(NewTypeArray, NewArray)
duke@435 1237 private:
duke@435 1238 BasicType _elt_type;
duke@435 1239
duke@435 1240 public:
duke@435 1241 // creation
duke@435 1242 NewTypeArray(Value length, BasicType elt_type) : NewArray(length, NULL), _elt_type(elt_type) {}
duke@435 1243
duke@435 1244 // accessors
duke@435 1245 BasicType elt_type() const { return _elt_type; }
duke@435 1246 ciType* exact_type() const;
duke@435 1247 };
duke@435 1248
duke@435 1249
duke@435 1250 LEAF(NewObjectArray, NewArray)
duke@435 1251 private:
duke@435 1252 ciKlass* _klass;
duke@435 1253
duke@435 1254 public:
duke@435 1255 // creation
duke@435 1256 NewObjectArray(ciKlass* klass, Value length, ValueStack* state_before) : NewArray(length, state_before), _klass(klass) {}
duke@435 1257
duke@435 1258 // accessors
duke@435 1259 ciKlass* klass() const { return _klass; }
duke@435 1260 ciType* exact_type() const;
duke@435 1261 };
duke@435 1262
duke@435 1263
duke@435 1264 LEAF(NewMultiArray, NewArray)
duke@435 1265 private:
duke@435 1266 ciKlass* _klass;
duke@435 1267 Values* _dims;
duke@435 1268
duke@435 1269 public:
duke@435 1270 // creation
duke@435 1271 NewMultiArray(ciKlass* klass, Values* dims, ValueStack* state_before) : NewArray(NULL, state_before), _klass(klass), _dims(dims) {
duke@435 1272 ASSERT_VALUES
duke@435 1273 }
duke@435 1274
duke@435 1275 // accessors
duke@435 1276 ciKlass* klass() const { return _klass; }
duke@435 1277 Values* dims() const { return _dims; }
duke@435 1278 int rank() const { return dims()->length(); }
duke@435 1279
duke@435 1280 // generic
iveresov@1939 1281 virtual void input_values_do(ValueVisitor* f) {
duke@435 1282 // NOTE: we do not call NewArray::input_values_do since "length"
duke@435 1283 // is meaningless for a multi-dimensional array; passing the
duke@435 1284 // zeroth element down to NewArray as its length is a bad idea
duke@435 1285 // since there will be a copy in the "dims" array which doesn't
duke@435 1286 // get updated, and the value must not be traversed twice. Was bug
duke@435 1287 // - kbr 4/10/2001
duke@435 1288 StateSplit::input_values_do(f);
iveresov@1939 1289 for (int i = 0; i < _dims->length(); i++) f->visit(_dims->adr_at(i));
duke@435 1290 }
duke@435 1291 };
duke@435 1292
duke@435 1293
duke@435 1294 BASE(TypeCheck, StateSplit)
duke@435 1295 private:
duke@435 1296 ciKlass* _klass;
duke@435 1297 Value _obj;
duke@435 1298 ValueStack* _state_before;
duke@435 1299
duke@435 1300 public:
duke@435 1301 // creation
duke@435 1302 TypeCheck(ciKlass* klass, Value obj, ValueType* type, ValueStack* state_before) : StateSplit(type), _klass(klass), _obj(obj), _state_before(state_before) {
duke@435 1303 ASSERT_VALUES
duke@435 1304 set_direct_compare(false);
duke@435 1305 }
duke@435 1306
duke@435 1307 // accessors
duke@435 1308 ValueStack* state_before() const { return _state_before; }
duke@435 1309 ciKlass* klass() const { return _klass; }
duke@435 1310 Value obj() const { return _obj; }
duke@435 1311 bool is_loaded() const { return klass() != NULL; }
duke@435 1312 bool direct_compare() const { return check_flag(DirectCompareFlag); }
duke@435 1313
duke@435 1314 // manipulation
duke@435 1315 void set_direct_compare(bool flag) { set_flag(DirectCompareFlag, flag); }
duke@435 1316
duke@435 1317 // generic
duke@435 1318 virtual bool can_trap() const { return true; }
iveresov@1939 1319 virtual void input_values_do(ValueVisitor* f) { StateSplit::input_values_do(f); f->visit(&_obj); }
iveresov@1939 1320 virtual void other_values_do(ValueVisitor* f);
duke@435 1321 };
duke@435 1322
duke@435 1323
duke@435 1324 LEAF(CheckCast, TypeCheck)
duke@435 1325 private:
duke@435 1326 ciMethod* _profiled_method;
duke@435 1327 int _profiled_bci;
duke@435 1328
duke@435 1329 public:
duke@435 1330 // creation
duke@435 1331 CheckCast(ciKlass* klass, Value obj, ValueStack* state_before)
duke@435 1332 : TypeCheck(klass, obj, objectType, state_before)
duke@435 1333 , _profiled_method(NULL)
duke@435 1334 , _profiled_bci(0) {}
duke@435 1335
duke@435 1336 void set_incompatible_class_change_check() {
duke@435 1337 set_flag(ThrowIncompatibleClassChangeErrorFlag, true);
duke@435 1338 }
duke@435 1339 bool is_incompatible_class_change_check() const {
duke@435 1340 return check_flag(ThrowIncompatibleClassChangeErrorFlag);
duke@435 1341 }
duke@435 1342
duke@435 1343 // Helpers for methodDataOop profiling
duke@435 1344 void set_should_profile(bool value) { set_flag(ProfileMDOFlag, value); }
duke@435 1345 void set_profiled_method(ciMethod* method) { _profiled_method = method; }
duke@435 1346 void set_profiled_bci(int bci) { _profiled_bci = bci; }
duke@435 1347 bool should_profile() const { return check_flag(ProfileMDOFlag); }
duke@435 1348 ciMethod* profiled_method() const { return _profiled_method; }
duke@435 1349 int profiled_bci() const { return _profiled_bci; }
duke@435 1350
duke@435 1351 ciType* declared_type() const;
duke@435 1352 ciType* exact_type() const;
duke@435 1353
duke@435 1354 };
duke@435 1355
duke@435 1356
duke@435 1357 LEAF(InstanceOf, TypeCheck)
duke@435 1358 public:
duke@435 1359 // creation
duke@435 1360 InstanceOf(ciKlass* klass, Value obj, ValueStack* state_before) : TypeCheck(klass, obj, intType, state_before) {}
duke@435 1361 };
duke@435 1362
duke@435 1363
duke@435 1364 BASE(AccessMonitor, StateSplit)
duke@435 1365 private:
duke@435 1366 Value _obj;
duke@435 1367 int _monitor_no;
duke@435 1368
duke@435 1369 public:
duke@435 1370 // creation
duke@435 1371 AccessMonitor(Value obj, int monitor_no)
duke@435 1372 : StateSplit(illegalType)
duke@435 1373 , _obj(obj)
duke@435 1374 , _monitor_no(monitor_no)
duke@435 1375 {
duke@435 1376 set_needs_null_check(true);
duke@435 1377 ASSERT_VALUES
duke@435 1378 }
duke@435 1379
duke@435 1380 // accessors
duke@435 1381 Value obj() const { return _obj; }
duke@435 1382 int monitor_no() const { return _monitor_no; }
duke@435 1383
duke@435 1384 // generic
iveresov@1939 1385 virtual void input_values_do(ValueVisitor* f) { StateSplit::input_values_do(f); f->visit(&_obj); }
duke@435 1386 };
duke@435 1387
duke@435 1388
duke@435 1389 LEAF(MonitorEnter, AccessMonitor)
duke@435 1390 private:
duke@435 1391 ValueStack* _lock_stack_before;
duke@435 1392
duke@435 1393 public:
duke@435 1394 // creation
duke@435 1395 MonitorEnter(Value obj, int monitor_no, ValueStack* lock_stack_before)
duke@435 1396 : AccessMonitor(obj, monitor_no)
duke@435 1397 , _lock_stack_before(lock_stack_before)
duke@435 1398 {
duke@435 1399 ASSERT_VALUES
duke@435 1400 }
duke@435 1401
duke@435 1402 // accessors
duke@435 1403 ValueStack* lock_stack_before() const { return _lock_stack_before; }
iveresov@1939 1404 virtual void state_values_do(ValueVisitor* f);
duke@435 1405
duke@435 1406 // generic
duke@435 1407 virtual bool can_trap() const { return true; }
duke@435 1408 };
duke@435 1409
duke@435 1410
duke@435 1411 LEAF(MonitorExit, AccessMonitor)
duke@435 1412 public:
duke@435 1413 // creation
duke@435 1414 MonitorExit(Value obj, int monitor_no) : AccessMonitor(obj, monitor_no) {}
duke@435 1415 };
duke@435 1416
duke@435 1417
duke@435 1418 LEAF(Intrinsic, StateSplit)
duke@435 1419 private:
duke@435 1420 vmIntrinsics::ID _id;
duke@435 1421 Values* _args;
duke@435 1422 ValueStack* _lock_stack;
duke@435 1423 Value _recv;
duke@435 1424
duke@435 1425 public:
duke@435 1426 // preserves_state can be set to true for Intrinsics
duke@435 1427 // which are guaranteed to preserve register state across any slow
duke@435 1428 // cases; setting it to true does not mean that the Intrinsic can
duke@435 1429 // not trap, only that if we continue execution in the same basic
duke@435 1430 // block after the Intrinsic, all of the registers are intact. This
duke@435 1431 // allows load elimination and common expression elimination to be
duke@435 1432 // performed across the Intrinsic. The default value is false.
duke@435 1433 Intrinsic(ValueType* type,
duke@435 1434 vmIntrinsics::ID id,
duke@435 1435 Values* args,
duke@435 1436 bool has_receiver,
duke@435 1437 ValueStack* lock_stack,
duke@435 1438 bool preserves_state,
duke@435 1439 bool cantrap = true)
duke@435 1440 : StateSplit(type)
duke@435 1441 , _id(id)
duke@435 1442 , _args(args)
duke@435 1443 , _lock_stack(lock_stack)
duke@435 1444 , _recv(NULL)
duke@435 1445 {
duke@435 1446 assert(args != NULL, "args must exist");
duke@435 1447 ASSERT_VALUES
duke@435 1448 set_flag(PreservesStateFlag, preserves_state);
duke@435 1449 set_flag(CanTrapFlag, cantrap);
duke@435 1450 if (has_receiver) {
duke@435 1451 _recv = argument_at(0);
duke@435 1452 }
duke@435 1453 set_needs_null_check(has_receiver);
duke@435 1454
duke@435 1455 // some intrinsics can't trap, so don't force them to be pinned
duke@435 1456 if (!can_trap()) {
duke@435 1457 unpin(PinStateSplitConstructor);
duke@435 1458 }
duke@435 1459 }
duke@435 1460
duke@435 1461 // accessors
duke@435 1462 vmIntrinsics::ID id() const { return _id; }
duke@435 1463 int number_of_arguments() const { return _args->length(); }
duke@435 1464 Value argument_at(int i) const { return _args->at(i); }
duke@435 1465 ValueStack* lock_stack() const { return _lock_stack; }
duke@435 1466
duke@435 1467 bool has_receiver() const { return (_recv != NULL); }
duke@435 1468 Value receiver() const { assert(has_receiver(), "must have receiver"); return _recv; }
duke@435 1469 bool preserves_state() const { return check_flag(PreservesStateFlag); }
duke@435 1470
duke@435 1471 // generic
duke@435 1472 virtual bool can_trap() const { return check_flag(CanTrapFlag); }
iveresov@1939 1473 virtual void input_values_do(ValueVisitor* f) {
duke@435 1474 StateSplit::input_values_do(f);
iveresov@1939 1475 for (int i = 0; i < _args->length(); i++) f->visit(_args->adr_at(i));
duke@435 1476 }
iveresov@1939 1477 virtual void state_values_do(ValueVisitor* f);
duke@435 1478
duke@435 1479 };
duke@435 1480
duke@435 1481
duke@435 1482 class LIR_List;
duke@435 1483
duke@435 1484 LEAF(BlockBegin, StateSplit)
duke@435 1485 private:
duke@435 1486 int _block_id; // the unique block id
duke@435 1487 int _depth_first_number; // number of this block in a depth-first ordering
duke@435 1488 int _linear_scan_number; // number of this block in linear-scan ordering
duke@435 1489 int _loop_depth; // the loop nesting level of this block
duke@435 1490 int _loop_index; // number of the innermost loop of this block
duke@435 1491 int _flags; // the flags associated with this block
duke@435 1492
duke@435 1493 // fields used by BlockListBuilder
duke@435 1494 int _total_preds; // number of predecessors found by BlockListBuilder
duke@435 1495 BitMap _stores_to_locals; // bit is set when a local variable is stored in the block
duke@435 1496
duke@435 1497 // SSA specific fields: (factor out later)
duke@435 1498 BlockList _successors; // the successors of this block
duke@435 1499 BlockList _predecessors; // the predecessors of this block
duke@435 1500 BlockBegin* _dominator; // the dominator of this block
duke@435 1501 // SSA specific ends
duke@435 1502 BlockEnd* _end; // the last instruction of this block
duke@435 1503 BlockList _exception_handlers; // the exception handlers potentially invoked by this block
duke@435 1504 ValueStackStack* _exception_states; // only for xhandler entries: states of all instructions that have an edge to this xhandler
duke@435 1505 int _exception_handler_pco; // if this block is the start of an exception handler,
duke@435 1506 // this records the PC offset in the assembly code of the
duke@435 1507 // first instruction in this block
duke@435 1508 Label _label; // the label associated with this block
duke@435 1509 LIR_List* _lir; // the low level intermediate representation for this block
duke@435 1510
duke@435 1511 BitMap _live_in; // set of live LIR_Opr registers at entry to this block
duke@435 1512 BitMap _live_out; // set of live LIR_Opr registers at exit from this block
duke@435 1513 BitMap _live_gen; // set of registers used before any redefinition in this block
duke@435 1514 BitMap _live_kill; // set of registers defined in this block
duke@435 1515
duke@435 1516 BitMap _fpu_register_usage;
duke@435 1517 intArray* _fpu_stack_state; // For x86 FPU code generation with UseLinearScan
duke@435 1518 int _first_lir_instruction_id; // ID of first LIR instruction in this block
duke@435 1519 int _last_lir_instruction_id; // ID of last LIR instruction in this block
duke@435 1520
duke@435 1521 void iterate_preorder (boolArray& mark, BlockClosure* closure);
duke@435 1522 void iterate_postorder(boolArray& mark, BlockClosure* closure);
duke@435 1523
duke@435 1524 friend class SuxAndWeightAdjuster;
duke@435 1525
duke@435 1526 public:
iveresov@1939 1527 void* operator new(size_t size) {
iveresov@1939 1528 Compilation* c = Compilation::current();
iveresov@1939 1529 void* res = c->arena()->Amalloc(size);
iveresov@1939 1530 ((BlockBegin*)res)->_id = c->get_next_id();
iveresov@1939 1531 ((BlockBegin*)res)->_block_id = c->get_next_block_id();
iveresov@1939 1532 return res;
iveresov@1939 1533 }
iveresov@1939 1534
duke@435 1535 // initialization/counting
iveresov@1939 1536 static int number_of_blocks() {
iveresov@1939 1537 return Compilation::current()->number_of_blocks();
iveresov@1939 1538 }
duke@435 1539
duke@435 1540 // creation
duke@435 1541 BlockBegin(int bci)
duke@435 1542 : StateSplit(illegalType)
duke@435 1543 , _depth_first_number(-1)
duke@435 1544 , _linear_scan_number(-1)
duke@435 1545 , _loop_depth(0)
duke@435 1546 , _flags(0)
duke@435 1547 , _dominator(NULL)
duke@435 1548 , _end(NULL)
duke@435 1549 , _predecessors(2)
duke@435 1550 , _successors(2)
duke@435 1551 , _exception_handlers(1)
duke@435 1552 , _exception_states(NULL)
duke@435 1553 , _exception_handler_pco(-1)
duke@435 1554 , _lir(NULL)
duke@435 1555 , _loop_index(-1)
duke@435 1556 , _live_in()
duke@435 1557 , _live_out()
duke@435 1558 , _live_gen()
duke@435 1559 , _live_kill()
duke@435 1560 , _fpu_register_usage()
duke@435 1561 , _fpu_stack_state(NULL)
duke@435 1562 , _first_lir_instruction_id(-1)
duke@435 1563 , _last_lir_instruction_id(-1)
duke@435 1564 , _total_preds(0)
duke@435 1565 , _stores_to_locals()
duke@435 1566 {
duke@435 1567 set_bci(bci);
duke@435 1568 }
duke@435 1569
duke@435 1570 // accessors
duke@435 1571 int block_id() const { return _block_id; }
duke@435 1572 BlockList* successors() { return &_successors; }
duke@435 1573 BlockBegin* dominator() const { return _dominator; }
duke@435 1574 int loop_depth() const { return _loop_depth; }
duke@435 1575 int depth_first_number() const { return _depth_first_number; }
duke@435 1576 int linear_scan_number() const { return _linear_scan_number; }
duke@435 1577 BlockEnd* end() const { return _end; }
duke@435 1578 Label* label() { return &_label; }
duke@435 1579 LIR_List* lir() const { return _lir; }
duke@435 1580 int exception_handler_pco() const { return _exception_handler_pco; }
duke@435 1581 BitMap& live_in() { return _live_in; }
duke@435 1582 BitMap& live_out() { return _live_out; }
duke@435 1583 BitMap& live_gen() { return _live_gen; }
duke@435 1584 BitMap& live_kill() { return _live_kill; }
duke@435 1585 BitMap& fpu_register_usage() { return _fpu_register_usage; }
duke@435 1586 intArray* fpu_stack_state() const { return _fpu_stack_state; }
duke@435 1587 int first_lir_instruction_id() const { return _first_lir_instruction_id; }
duke@435 1588 int last_lir_instruction_id() const { return _last_lir_instruction_id; }
duke@435 1589 int total_preds() const { return _total_preds; }
duke@435 1590 BitMap& stores_to_locals() { return _stores_to_locals; }
duke@435 1591
duke@435 1592 // manipulation
duke@435 1593 void set_bci(int bci) { Instruction::set_bci(bci); }
duke@435 1594 void set_dominator(BlockBegin* dom) { _dominator = dom; }
duke@435 1595 void set_loop_depth(int d) { _loop_depth = d; }
duke@435 1596 void set_depth_first_number(int dfn) { _depth_first_number = dfn; }
duke@435 1597 void set_linear_scan_number(int lsn) { _linear_scan_number = lsn; }
duke@435 1598 void set_end(BlockEnd* end);
duke@435 1599 void disconnect_from_graph();
duke@435 1600 static void disconnect_edge(BlockBegin* from, BlockBegin* to);
duke@435 1601 BlockBegin* insert_block_between(BlockBegin* sux);
duke@435 1602 void substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux);
duke@435 1603 void set_lir(LIR_List* lir) { _lir = lir; }
duke@435 1604 void set_exception_handler_pco(int pco) { _exception_handler_pco = pco; }
duke@435 1605 void set_live_in (BitMap map) { _live_in = map; }
duke@435 1606 void set_live_out (BitMap map) { _live_out = map; }
duke@435 1607 void set_live_gen (BitMap map) { _live_gen = map; }
duke@435 1608 void set_live_kill (BitMap map) { _live_kill = map; }
duke@435 1609 void set_fpu_register_usage(BitMap map) { _fpu_register_usage = map; }
duke@435 1610 void set_fpu_stack_state(intArray* state) { _fpu_stack_state = state; }
duke@435 1611 void set_first_lir_instruction_id(int id) { _first_lir_instruction_id = id; }
duke@435 1612 void set_last_lir_instruction_id(int id) { _last_lir_instruction_id = id; }
duke@435 1613 void increment_total_preds(int n = 1) { _total_preds += n; }
duke@435 1614 void init_stores_to_locals(int locals_count) { _stores_to_locals = BitMap(locals_count); _stores_to_locals.clear(); }
duke@435 1615
duke@435 1616 // generic
iveresov@1939 1617 virtual void state_values_do(ValueVisitor* f);
duke@435 1618
duke@435 1619 // successors and predecessors
duke@435 1620 int number_of_sux() const;
duke@435 1621 BlockBegin* sux_at(int i) const;
duke@435 1622 void add_successor(BlockBegin* sux);
duke@435 1623 void remove_successor(BlockBegin* pred);
duke@435 1624 bool is_successor(BlockBegin* sux) const { return _successors.contains(sux); }
duke@435 1625
duke@435 1626 void add_predecessor(BlockBegin* pred);
duke@435 1627 void remove_predecessor(BlockBegin* pred);
duke@435 1628 bool is_predecessor(BlockBegin* pred) const { return _predecessors.contains(pred); }
duke@435 1629 int number_of_preds() const { return _predecessors.length(); }
duke@435 1630 BlockBegin* pred_at(int i) const { return _predecessors[i]; }
duke@435 1631
duke@435 1632 // exception handlers potentially invoked by this block
duke@435 1633 void add_exception_handler(BlockBegin* b);
duke@435 1634 bool is_exception_handler(BlockBegin* b) const { return _exception_handlers.contains(b); }
duke@435 1635 int number_of_exception_handlers() const { return _exception_handlers.length(); }
duke@435 1636 BlockBegin* exception_handler_at(int i) const { return _exception_handlers.at(i); }
duke@435 1637
duke@435 1638 // states of the instructions that have an edge to this exception handler
duke@435 1639 int number_of_exception_states() { assert(is_set(exception_entry_flag), "only for xhandlers"); return _exception_states == NULL ? 0 : _exception_states->length(); }
duke@435 1640 ValueStack* exception_state_at(int idx) const { assert(is_set(exception_entry_flag), "only for xhandlers"); return _exception_states->at(idx); }
duke@435 1641 int add_exception_state(ValueStack* state);
duke@435 1642
duke@435 1643 // flags
duke@435 1644 enum Flag {
duke@435 1645 no_flag = 0,
duke@435 1646 std_entry_flag = 1 << 0,
duke@435 1647 osr_entry_flag = 1 << 1,
duke@435 1648 exception_entry_flag = 1 << 2,
duke@435 1649 subroutine_entry_flag = 1 << 3,
duke@435 1650 backward_branch_target_flag = 1 << 4,
duke@435 1651 is_on_work_list_flag = 1 << 5,
duke@435 1652 was_visited_flag = 1 << 6,
never@1813 1653 parser_loop_header_flag = 1 << 7, // set by parser to identify blocks where phi functions can not be created on demand
never@1813 1654 critical_edge_split_flag = 1 << 8, // set for all blocks that are introduced when critical edges are split
never@1813 1655 linear_scan_loop_header_flag = 1 << 9, // set during loop-detection for LinearScan
never@1813 1656 linear_scan_loop_end_flag = 1 << 10 // set during loop-detection for LinearScan
duke@435 1657 };
duke@435 1658
duke@435 1659 void set(Flag f) { _flags |= f; }
duke@435 1660 void clear(Flag f) { _flags &= ~f; }
duke@435 1661 bool is_set(Flag f) const { return (_flags & f) != 0; }
duke@435 1662 bool is_entry_block() const {
duke@435 1663 const int entry_mask = std_entry_flag | osr_entry_flag | exception_entry_flag;
duke@435 1664 return (_flags & entry_mask) != 0;
duke@435 1665 }
duke@435 1666
duke@435 1667 // iteration
duke@435 1668 void iterate_preorder (BlockClosure* closure);
duke@435 1669 void iterate_postorder (BlockClosure* closure);
duke@435 1670
iveresov@1939 1671 void block_values_do(ValueVisitor* f);
duke@435 1672
duke@435 1673 // loops
duke@435 1674 void set_loop_index(int ix) { _loop_index = ix; }
duke@435 1675 int loop_index() const { return _loop_index; }
duke@435 1676
duke@435 1677 // merging
duke@435 1678 bool try_merge(ValueStack* state); // try to merge states at block begin
duke@435 1679 void merge(ValueStack* state) { bool b = try_merge(state); assert(b, "merge failed"); }
duke@435 1680
duke@435 1681 // debugging
duke@435 1682 void print_block() PRODUCT_RETURN;
duke@435 1683 void print_block(InstructionPrinter& ip, bool live_only = false) PRODUCT_RETURN;
duke@435 1684 };
duke@435 1685
duke@435 1686
duke@435 1687 BASE(BlockEnd, StateSplit)
duke@435 1688 private:
duke@435 1689 BlockBegin* _begin;
duke@435 1690 BlockList* _sux;
duke@435 1691 ValueStack* _state_before;
duke@435 1692
duke@435 1693 protected:
duke@435 1694 BlockList* sux() const { return _sux; }
duke@435 1695
duke@435 1696 void set_sux(BlockList* sux) {
duke@435 1697 #ifdef ASSERT
duke@435 1698 assert(sux != NULL, "sux must exist");
duke@435 1699 for (int i = sux->length() - 1; i >= 0; i--) assert(sux->at(i) != NULL, "sux must exist");
duke@435 1700 #endif
duke@435 1701 _sux = sux;
duke@435 1702 }
duke@435 1703
duke@435 1704 public:
duke@435 1705 // creation
duke@435 1706 BlockEnd(ValueType* type, ValueStack* state_before, bool is_safepoint)
duke@435 1707 : StateSplit(type)
duke@435 1708 , _begin(NULL)
duke@435 1709 , _sux(NULL)
duke@435 1710 , _state_before(state_before) {
duke@435 1711 set_flag(IsSafepointFlag, is_safepoint);
duke@435 1712 }
duke@435 1713
duke@435 1714 // accessors
duke@435 1715 ValueStack* state_before() const { return _state_before; }
duke@435 1716 bool is_safepoint() const { return check_flag(IsSafepointFlag); }
duke@435 1717 BlockBegin* begin() const { return _begin; }
duke@435 1718
duke@435 1719 // manipulation
duke@435 1720 void set_begin(BlockBegin* begin);
duke@435 1721
duke@435 1722 // generic
iveresov@1939 1723 virtual void other_values_do(ValueVisitor* f);
duke@435 1724
duke@435 1725 // successors
duke@435 1726 int number_of_sux() const { return _sux != NULL ? _sux->length() : 0; }
duke@435 1727 BlockBegin* sux_at(int i) const { return _sux->at(i); }
duke@435 1728 BlockBegin* default_sux() const { return sux_at(number_of_sux() - 1); }
duke@435 1729 BlockBegin** addr_sux_at(int i) const { return _sux->adr_at(i); }
duke@435 1730 int sux_index(BlockBegin* sux) const { return _sux->find(sux); }
duke@435 1731 void substitute_sux(BlockBegin* old_sux, BlockBegin* new_sux);
duke@435 1732 };
duke@435 1733
duke@435 1734
duke@435 1735 LEAF(Goto, BlockEnd)
duke@435 1736 public:
duke@435 1737 // creation
duke@435 1738 Goto(BlockBegin* sux, ValueStack* state_before, bool is_safepoint = false) : BlockEnd(illegalType, state_before, is_safepoint) {
duke@435 1739 BlockList* s = new BlockList(1);
duke@435 1740 s->append(sux);
duke@435 1741 set_sux(s);
duke@435 1742 }
duke@435 1743
duke@435 1744 Goto(BlockBegin* sux, bool is_safepoint) : BlockEnd(illegalType, NULL, is_safepoint) {
duke@435 1745 BlockList* s = new BlockList(1);
duke@435 1746 s->append(sux);
duke@435 1747 set_sux(s);
duke@435 1748 }
duke@435 1749
duke@435 1750 };
duke@435 1751
duke@435 1752
duke@435 1753 LEAF(If, BlockEnd)
duke@435 1754 private:
duke@435 1755 Value _x;
duke@435 1756 Condition _cond;
duke@435 1757 Value _y;
duke@435 1758 ciMethod* _profiled_method;
duke@435 1759 int _profiled_bci; // Canonicalizer may alter bci of If node
duke@435 1760 public:
duke@435 1761 // creation
duke@435 1762 // unordered_is_true is valid for float/double compares only
duke@435 1763 If(Value x, Condition cond, bool unordered_is_true, Value y, BlockBegin* tsux, BlockBegin* fsux, ValueStack* state_before, bool is_safepoint)
duke@435 1764 : BlockEnd(illegalType, state_before, is_safepoint)
duke@435 1765 , _x(x)
duke@435 1766 , _cond(cond)
duke@435 1767 , _y(y)
duke@435 1768 , _profiled_method(NULL)
duke@435 1769 , _profiled_bci(0)
duke@435 1770 {
duke@435 1771 ASSERT_VALUES
duke@435 1772 set_flag(UnorderedIsTrueFlag, unordered_is_true);
duke@435 1773 assert(x->type()->tag() == y->type()->tag(), "types must match");
duke@435 1774 BlockList* s = new BlockList(2);
duke@435 1775 s->append(tsux);
duke@435 1776 s->append(fsux);
duke@435 1777 set_sux(s);
duke@435 1778 }
duke@435 1779
duke@435 1780 // accessors
duke@435 1781 Value x() const { return _x; }
duke@435 1782 Condition cond() const { return _cond; }
duke@435 1783 bool unordered_is_true() const { return check_flag(UnorderedIsTrueFlag); }
duke@435 1784 Value y() const { return _y; }
duke@435 1785 BlockBegin* sux_for(bool is_true) const { return sux_at(is_true ? 0 : 1); }
duke@435 1786 BlockBegin* tsux() const { return sux_for(true); }
duke@435 1787 BlockBegin* fsux() const { return sux_for(false); }
duke@435 1788 BlockBegin* usux() const { return sux_for(unordered_is_true()); }
duke@435 1789 bool should_profile() const { return check_flag(ProfileMDOFlag); }
duke@435 1790 ciMethod* profiled_method() const { return _profiled_method; } // set only for profiled branches
duke@435 1791 int profiled_bci() const { return _profiled_bci; } // set only for profiled branches
duke@435 1792
duke@435 1793 // manipulation
duke@435 1794 void swap_operands() {
duke@435 1795 Value t = _x; _x = _y; _y = t;
duke@435 1796 _cond = mirror(_cond);
duke@435 1797 }
duke@435 1798
duke@435 1799 void swap_sux() {
duke@435 1800 assert(number_of_sux() == 2, "wrong number of successors");
duke@435 1801 BlockList* s = sux();
duke@435 1802 BlockBegin* t = s->at(0); s->at_put(0, s->at(1)); s->at_put(1, t);
duke@435 1803 _cond = negate(_cond);
duke@435 1804 set_flag(UnorderedIsTrueFlag, !check_flag(UnorderedIsTrueFlag));
duke@435 1805 }
duke@435 1806
duke@435 1807 void set_should_profile(bool value) { set_flag(ProfileMDOFlag, value); }
duke@435 1808 void set_profiled_method(ciMethod* method) { _profiled_method = method; }
duke@435 1809 void set_profiled_bci(int bci) { _profiled_bci = bci; }
duke@435 1810
duke@435 1811 // generic
iveresov@1939 1812 virtual void input_values_do(ValueVisitor* f) { BlockEnd::input_values_do(f); f->visit(&_x); f->visit(&_y); }
duke@435 1813 };
duke@435 1814
duke@435 1815
duke@435 1816 LEAF(IfInstanceOf, BlockEnd)
duke@435 1817 private:
duke@435 1818 ciKlass* _klass;
duke@435 1819 Value _obj;
duke@435 1820 bool _test_is_instance; // jump if instance
duke@435 1821 int _instanceof_bci;
duke@435 1822
duke@435 1823 public:
duke@435 1824 IfInstanceOf(ciKlass* klass, Value obj, bool test_is_instance, int instanceof_bci, BlockBegin* tsux, BlockBegin* fsux)
duke@435 1825 : BlockEnd(illegalType, NULL, false) // temporary set to false
duke@435 1826 , _klass(klass)
duke@435 1827 , _obj(obj)
duke@435 1828 , _test_is_instance(test_is_instance)
duke@435 1829 , _instanceof_bci(instanceof_bci)
duke@435 1830 {
duke@435 1831 ASSERT_VALUES
duke@435 1832 assert(instanceof_bci >= 0, "illegal bci");
duke@435 1833 BlockList* s = new BlockList(2);
duke@435 1834 s->append(tsux);
duke@435 1835 s->append(fsux);
duke@435 1836 set_sux(s);
duke@435 1837 }
duke@435 1838
duke@435 1839 // accessors
duke@435 1840 //
duke@435 1841 // Note 1: If test_is_instance() is true, IfInstanceOf tests if obj *is* an
duke@435 1842 // instance of klass; otherwise it tests if it is *not* and instance
duke@435 1843 // of klass.
duke@435 1844 //
duke@435 1845 // Note 2: IfInstanceOf instructions are created by combining an InstanceOf
duke@435 1846 // and an If instruction. The IfInstanceOf bci() corresponds to the
duke@435 1847 // bci that the If would have had; the (this->) instanceof_bci() is
duke@435 1848 // the bci of the original InstanceOf instruction.
duke@435 1849 ciKlass* klass() const { return _klass; }
duke@435 1850 Value obj() const { return _obj; }
duke@435 1851 int instanceof_bci() const { return _instanceof_bci; }
duke@435 1852 bool test_is_instance() const { return _test_is_instance; }
duke@435 1853 BlockBegin* sux_for(bool is_true) const { return sux_at(is_true ? 0 : 1); }
duke@435 1854 BlockBegin* tsux() const { return sux_for(true); }
duke@435 1855 BlockBegin* fsux() const { return sux_for(false); }
duke@435 1856
duke@435 1857 // manipulation
duke@435 1858 void swap_sux() {
duke@435 1859 assert(number_of_sux() == 2, "wrong number of successors");
duke@435 1860 BlockList* s = sux();
duke@435 1861 BlockBegin* t = s->at(0); s->at_put(0, s->at(1)); s->at_put(1, t);
duke@435 1862 _test_is_instance = !_test_is_instance;
duke@435 1863 }
duke@435 1864
duke@435 1865 // generic
iveresov@1939 1866 virtual void input_values_do(ValueVisitor* f) { BlockEnd::input_values_do(f); f->visit(&_obj); }
duke@435 1867 };
duke@435 1868
duke@435 1869
duke@435 1870 BASE(Switch, BlockEnd)
duke@435 1871 private:
duke@435 1872 Value _tag;
duke@435 1873
duke@435 1874 public:
duke@435 1875 // creation
duke@435 1876 Switch(Value tag, BlockList* sux, ValueStack* state_before, bool is_safepoint)
duke@435 1877 : BlockEnd(illegalType, state_before, is_safepoint)
duke@435 1878 , _tag(tag) {
duke@435 1879 ASSERT_VALUES
duke@435 1880 set_sux(sux);
duke@435 1881 }
duke@435 1882
duke@435 1883 // accessors
duke@435 1884 Value tag() const { return _tag; }
duke@435 1885 int length() const { return number_of_sux() - 1; }
duke@435 1886
duke@435 1887 // generic
iveresov@1939 1888 virtual void input_values_do(ValueVisitor* f) { BlockEnd::input_values_do(f); f->visit(&_tag); }
duke@435 1889 };
duke@435 1890
duke@435 1891
duke@435 1892 LEAF(TableSwitch, Switch)
duke@435 1893 private:
duke@435 1894 int _lo_key;
duke@435 1895
duke@435 1896 public:
duke@435 1897 // creation
duke@435 1898 TableSwitch(Value tag, BlockList* sux, int lo_key, ValueStack* state_before, bool is_safepoint)
duke@435 1899 : Switch(tag, sux, state_before, is_safepoint)
duke@435 1900 , _lo_key(lo_key) {}
duke@435 1901
duke@435 1902 // accessors
duke@435 1903 int lo_key() const { return _lo_key; }
duke@435 1904 int hi_key() const { return _lo_key + length() - 1; }
duke@435 1905 };
duke@435 1906
duke@435 1907
duke@435 1908 LEAF(LookupSwitch, Switch)
duke@435 1909 private:
duke@435 1910 intArray* _keys;
duke@435 1911
duke@435 1912 public:
duke@435 1913 // creation
duke@435 1914 LookupSwitch(Value tag, BlockList* sux, intArray* keys, ValueStack* state_before, bool is_safepoint)
duke@435 1915 : Switch(tag, sux, state_before, is_safepoint)
duke@435 1916 , _keys(keys) {
duke@435 1917 assert(keys != NULL, "keys must exist");
duke@435 1918 assert(keys->length() == length(), "sux & keys have incompatible lengths");
duke@435 1919 }
duke@435 1920
duke@435 1921 // accessors
duke@435 1922 int key_at(int i) const { return _keys->at(i); }
duke@435 1923 };
duke@435 1924
duke@435 1925
duke@435 1926 LEAF(Return, BlockEnd)
duke@435 1927 private:
duke@435 1928 Value _result;
duke@435 1929
duke@435 1930 public:
duke@435 1931 // creation
duke@435 1932 Return(Value result) :
duke@435 1933 BlockEnd(result == NULL ? voidType : result->type()->base(), NULL, true),
duke@435 1934 _result(result) {}
duke@435 1935
duke@435 1936 // accessors
duke@435 1937 Value result() const { return _result; }
duke@435 1938 bool has_result() const { return result() != NULL; }
duke@435 1939
duke@435 1940 // generic
iveresov@1939 1941 virtual void input_values_do(ValueVisitor* f) {
duke@435 1942 BlockEnd::input_values_do(f);
iveresov@1939 1943 if (has_result()) f->visit(&_result);
duke@435 1944 }
duke@435 1945 };
duke@435 1946
duke@435 1947
duke@435 1948 LEAF(Throw, BlockEnd)
duke@435 1949 private:
duke@435 1950 Value _exception;
duke@435 1951
duke@435 1952 public:
duke@435 1953 // creation
duke@435 1954 Throw(Value exception, ValueStack* state_before) : BlockEnd(illegalType, state_before, true), _exception(exception) {
duke@435 1955 ASSERT_VALUES
duke@435 1956 }
duke@435 1957
duke@435 1958 // accessors
duke@435 1959 Value exception() const { return _exception; }
duke@435 1960
duke@435 1961 // generic
duke@435 1962 virtual bool can_trap() const { return true; }
iveresov@1939 1963 virtual void input_values_do(ValueVisitor* f) { BlockEnd::input_values_do(f); f->visit(&_exception); }
iveresov@1939 1964 virtual void state_values_do(ValueVisitor* f);
duke@435 1965 };
duke@435 1966
duke@435 1967
duke@435 1968 LEAF(Base, BlockEnd)
duke@435 1969 public:
duke@435 1970 // creation
duke@435 1971 Base(BlockBegin* std_entry, BlockBegin* osr_entry) : BlockEnd(illegalType, NULL, false) {
duke@435 1972 assert(std_entry->is_set(BlockBegin::std_entry_flag), "std entry must be flagged");
duke@435 1973 assert(osr_entry == NULL || osr_entry->is_set(BlockBegin::osr_entry_flag), "osr entry must be flagged");
duke@435 1974 BlockList* s = new BlockList(2);
duke@435 1975 if (osr_entry != NULL) s->append(osr_entry);
duke@435 1976 s->append(std_entry); // must be default sux!
duke@435 1977 set_sux(s);
duke@435 1978 }
duke@435 1979
duke@435 1980 // accessors
duke@435 1981 BlockBegin* std_entry() const { return default_sux(); }
duke@435 1982 BlockBegin* osr_entry() const { return number_of_sux() < 2 ? NULL : sux_at(0); }
duke@435 1983 };
duke@435 1984
duke@435 1985
duke@435 1986 LEAF(OsrEntry, Instruction)
duke@435 1987 public:
duke@435 1988 // creation
duke@435 1989 #ifdef _LP64
duke@435 1990 OsrEntry() : Instruction(longType, false) { pin(); }
duke@435 1991 #else
duke@435 1992 OsrEntry() : Instruction(intType, false) { pin(); }
duke@435 1993 #endif
duke@435 1994
duke@435 1995 // generic
iveresov@1939 1996 virtual void input_values_do(ValueVisitor* f) { }
duke@435 1997 };
duke@435 1998
duke@435 1999
duke@435 2000 // Models the incoming exception at a catch site
duke@435 2001 LEAF(ExceptionObject, Instruction)
duke@435 2002 public:
duke@435 2003 // creation
duke@435 2004 ExceptionObject() : Instruction(objectType, false) {
duke@435 2005 pin();
duke@435 2006 }
duke@435 2007
duke@435 2008 // generic
iveresov@1939 2009 virtual void input_values_do(ValueVisitor* f) { }
duke@435 2010 };
duke@435 2011
duke@435 2012
duke@435 2013 // Models needed rounding for floating-point values on Intel.
duke@435 2014 // Currently only used to represent rounding of double-precision
duke@435 2015 // values stored into local variables, but could be used to model
duke@435 2016 // intermediate rounding of single-precision values as well.
duke@435 2017 LEAF(RoundFP, Instruction)
duke@435 2018 private:
duke@435 2019 Value _input; // floating-point value to be rounded
duke@435 2020
duke@435 2021 public:
duke@435 2022 RoundFP(Value input)
duke@435 2023 : Instruction(input->type()) // Note: should not be used for constants
duke@435 2024 , _input(input)
duke@435 2025 {
duke@435 2026 ASSERT_VALUES
duke@435 2027 }
duke@435 2028
duke@435 2029 // accessors
duke@435 2030 Value input() const { return _input; }
duke@435 2031
duke@435 2032 // generic
iveresov@1939 2033 virtual void input_values_do(ValueVisitor* f) { f->visit(&_input); }
duke@435 2034 };
duke@435 2035
duke@435 2036
duke@435 2037 BASE(UnsafeOp, Instruction)
duke@435 2038 private:
duke@435 2039 BasicType _basic_type; // ValueType can not express byte-sized integers
duke@435 2040
duke@435 2041 protected:
duke@435 2042 // creation
duke@435 2043 UnsafeOp(BasicType basic_type, bool is_put)
duke@435 2044 : Instruction(is_put ? voidType : as_ValueType(basic_type))
duke@435 2045 , _basic_type(basic_type)
duke@435 2046 {
duke@435 2047 //Note: Unsafe ops are not not guaranteed to throw NPE.
duke@435 2048 // Convservatively, Unsafe operations must be pinned though we could be
duke@435 2049 // looser about this if we wanted to..
duke@435 2050 pin();
duke@435 2051 }
duke@435 2052
duke@435 2053 public:
duke@435 2054 // accessors
duke@435 2055 BasicType basic_type() { return _basic_type; }
duke@435 2056
duke@435 2057 // generic
iveresov@1939 2058 virtual void input_values_do(ValueVisitor* f) { }
iveresov@1939 2059 virtual void other_values_do(ValueVisitor* f) { }
duke@435 2060 };
duke@435 2061
duke@435 2062
duke@435 2063 BASE(UnsafeRawOp, UnsafeOp)
duke@435 2064 private:
duke@435 2065 Value _base; // Base address (a Java long)
duke@435 2066 Value _index; // Index if computed by optimizer; initialized to NULL
duke@435 2067 int _log2_scale; // Scale factor: 0, 1, 2, or 3.
duke@435 2068 // Indicates log2 of number of bytes (1, 2, 4, or 8)
duke@435 2069 // to scale index by.
duke@435 2070
duke@435 2071 protected:
duke@435 2072 UnsafeRawOp(BasicType basic_type, Value addr, bool is_put)
duke@435 2073 : UnsafeOp(basic_type, is_put)
duke@435 2074 , _base(addr)
duke@435 2075 , _index(NULL)
duke@435 2076 , _log2_scale(0)
duke@435 2077 {
duke@435 2078 // Can not use ASSERT_VALUES because index may be NULL
duke@435 2079 assert(addr != NULL && addr->type()->is_long(), "just checking");
duke@435 2080 }
duke@435 2081
duke@435 2082 UnsafeRawOp(BasicType basic_type, Value base, Value index, int log2_scale, bool is_put)
duke@435 2083 : UnsafeOp(basic_type, is_put)
duke@435 2084 , _base(base)
duke@435 2085 , _index(index)
duke@435 2086 , _log2_scale(log2_scale)
duke@435 2087 {
duke@435 2088 }
duke@435 2089
duke@435 2090 public:
duke@435 2091 // accessors
duke@435 2092 Value base() { return _base; }
duke@435 2093 Value index() { return _index; }
duke@435 2094 bool has_index() { return (_index != NULL); }
duke@435 2095 int log2_scale() { return _log2_scale; }
duke@435 2096
duke@435 2097 // setters
duke@435 2098 void set_base (Value base) { _base = base; }
duke@435 2099 void set_index(Value index) { _index = index; }
duke@435 2100 void set_log2_scale(int log2_scale) { _log2_scale = log2_scale; }
duke@435 2101
duke@435 2102 // generic
iveresov@1939 2103 virtual void input_values_do(ValueVisitor* f) { UnsafeOp::input_values_do(f);
iveresov@1939 2104 f->visit(&_base);
iveresov@1939 2105 if (has_index()) f->visit(&_index); }
duke@435 2106 };
duke@435 2107
duke@435 2108
duke@435 2109 LEAF(UnsafeGetRaw, UnsafeRawOp)
duke@435 2110 private:
duke@435 2111 bool _may_be_unaligned; // For OSREntry
duke@435 2112
duke@435 2113 public:
duke@435 2114 UnsafeGetRaw(BasicType basic_type, Value addr, bool may_be_unaligned)
duke@435 2115 : UnsafeRawOp(basic_type, addr, false) {
duke@435 2116 _may_be_unaligned = may_be_unaligned;
duke@435 2117 }
duke@435 2118
duke@435 2119 UnsafeGetRaw(BasicType basic_type, Value base, Value index, int log2_scale, bool may_be_unaligned)
duke@435 2120 : UnsafeRawOp(basic_type, base, index, log2_scale, false) {
duke@435 2121 _may_be_unaligned = may_be_unaligned;
duke@435 2122 }
duke@435 2123
duke@435 2124 bool may_be_unaligned() { return _may_be_unaligned; }
duke@435 2125 };
duke@435 2126
duke@435 2127
duke@435 2128 LEAF(UnsafePutRaw, UnsafeRawOp)
duke@435 2129 private:
duke@435 2130 Value _value; // Value to be stored
duke@435 2131
duke@435 2132 public:
duke@435 2133 UnsafePutRaw(BasicType basic_type, Value addr, Value value)
duke@435 2134 : UnsafeRawOp(basic_type, addr, true)
duke@435 2135 , _value(value)
duke@435 2136 {
duke@435 2137 assert(value != NULL, "just checking");
duke@435 2138 ASSERT_VALUES
duke@435 2139 }
duke@435 2140
duke@435 2141 UnsafePutRaw(BasicType basic_type, Value base, Value index, int log2_scale, Value value)
duke@435 2142 : UnsafeRawOp(basic_type, base, index, log2_scale, true)
duke@435 2143 , _value(value)
duke@435 2144 {
duke@435 2145 assert(value != NULL, "just checking");
duke@435 2146 ASSERT_VALUES
duke@435 2147 }
duke@435 2148
duke@435 2149 // accessors
duke@435 2150 Value value() { return _value; }
duke@435 2151
duke@435 2152 // generic
iveresov@1939 2153 virtual void input_values_do(ValueVisitor* f) { UnsafeRawOp::input_values_do(f);
iveresov@1939 2154 f->visit(&_value); }
duke@435 2155 };
duke@435 2156
duke@435 2157
duke@435 2158 BASE(UnsafeObjectOp, UnsafeOp)
duke@435 2159 private:
duke@435 2160 Value _object; // Object to be fetched from or mutated
duke@435 2161 Value _offset; // Offset within object
duke@435 2162 bool _is_volatile; // true if volatile - dl/JSR166
duke@435 2163 public:
duke@435 2164 UnsafeObjectOp(BasicType basic_type, Value object, Value offset, bool is_put, bool is_volatile)
duke@435 2165 : UnsafeOp(basic_type, is_put), _object(object), _offset(offset), _is_volatile(is_volatile)
duke@435 2166 {
duke@435 2167 }
duke@435 2168
duke@435 2169 // accessors
duke@435 2170 Value object() { return _object; }
duke@435 2171 Value offset() { return _offset; }
duke@435 2172 bool is_volatile() { return _is_volatile; }
duke@435 2173 // generic
iveresov@1939 2174 virtual void input_values_do(ValueVisitor* f) { UnsafeOp::input_values_do(f);
iveresov@1939 2175 f->visit(&_object);
iveresov@1939 2176 f->visit(&_offset); }
duke@435 2177 };
duke@435 2178
duke@435 2179
duke@435 2180 LEAF(UnsafeGetObject, UnsafeObjectOp)
duke@435 2181 public:
duke@435 2182 UnsafeGetObject(BasicType basic_type, Value object, Value offset, bool is_volatile)
duke@435 2183 : UnsafeObjectOp(basic_type, object, offset, false, is_volatile)
duke@435 2184 {
duke@435 2185 ASSERT_VALUES
duke@435 2186 }
duke@435 2187 };
duke@435 2188
duke@435 2189
duke@435 2190 LEAF(UnsafePutObject, UnsafeObjectOp)
duke@435 2191 private:
duke@435 2192 Value _value; // Value to be stored
duke@435 2193 public:
duke@435 2194 UnsafePutObject(BasicType basic_type, Value object, Value offset, Value value, bool is_volatile)
duke@435 2195 : UnsafeObjectOp(basic_type, object, offset, true, is_volatile)
duke@435 2196 , _value(value)
duke@435 2197 {
duke@435 2198 ASSERT_VALUES
duke@435 2199 }
duke@435 2200
duke@435 2201 // accessors
duke@435 2202 Value value() { return _value; }
duke@435 2203
duke@435 2204 // generic
iveresov@1939 2205 virtual void input_values_do(ValueVisitor* f) { UnsafeObjectOp::input_values_do(f);
iveresov@1939 2206 f->visit(&_value); }
duke@435 2207 };
duke@435 2208
duke@435 2209
duke@435 2210 BASE(UnsafePrefetch, UnsafeObjectOp)
duke@435 2211 public:
duke@435 2212 UnsafePrefetch(Value object, Value offset)
duke@435 2213 : UnsafeObjectOp(T_VOID, object, offset, false, false)
duke@435 2214 {
duke@435 2215 }
duke@435 2216 };
duke@435 2217
duke@435 2218
duke@435 2219 LEAF(UnsafePrefetchRead, UnsafePrefetch)
duke@435 2220 public:
duke@435 2221 UnsafePrefetchRead(Value object, Value offset)
duke@435 2222 : UnsafePrefetch(object, offset)
duke@435 2223 {
duke@435 2224 ASSERT_VALUES
duke@435 2225 }
duke@435 2226 };
duke@435 2227
duke@435 2228
duke@435 2229 LEAF(UnsafePrefetchWrite, UnsafePrefetch)
duke@435 2230 public:
duke@435 2231 UnsafePrefetchWrite(Value object, Value offset)
duke@435 2232 : UnsafePrefetch(object, offset)
duke@435 2233 {
duke@435 2234 ASSERT_VALUES
duke@435 2235 }
duke@435 2236 };
duke@435 2237
duke@435 2238
duke@435 2239 LEAF(ProfileCall, Instruction)
duke@435 2240 private:
duke@435 2241 ciMethod* _method;
duke@435 2242 int _bci_of_invoke;
duke@435 2243 Value _recv;
duke@435 2244 ciKlass* _known_holder;
duke@435 2245
duke@435 2246 public:
duke@435 2247 ProfileCall(ciMethod* method, int bci, Value recv, ciKlass* known_holder)
duke@435 2248 : Instruction(voidType)
duke@435 2249 , _method(method)
duke@435 2250 , _bci_of_invoke(bci)
duke@435 2251 , _recv(recv)
duke@435 2252 , _known_holder(known_holder)
duke@435 2253 {
duke@435 2254 // The ProfileCall has side-effects and must occur precisely where located
duke@435 2255 pin();
duke@435 2256 }
duke@435 2257
duke@435 2258 ciMethod* method() { return _method; }
duke@435 2259 int bci_of_invoke() { return _bci_of_invoke; }
duke@435 2260 Value recv() { return _recv; }
duke@435 2261 ciKlass* known_holder() { return _known_holder; }
duke@435 2262
iveresov@1939 2263 virtual void input_values_do(ValueVisitor* f) { if (_recv != NULL) f->visit(&_recv); }
duke@435 2264 };
duke@435 2265
duke@435 2266
duke@435 2267 //
duke@435 2268 // Simple node representing a counter update generally used for updating MDOs
duke@435 2269 //
duke@435 2270 LEAF(ProfileCounter, Instruction)
duke@435 2271 private:
duke@435 2272 Value _mdo;
duke@435 2273 int _offset;
duke@435 2274 int _increment;
duke@435 2275
duke@435 2276 public:
duke@435 2277 ProfileCounter(Value mdo, int offset, int increment = 1)
duke@435 2278 : Instruction(voidType)
duke@435 2279 , _mdo(mdo)
duke@435 2280 , _offset(offset)
duke@435 2281 , _increment(increment)
duke@435 2282 {
duke@435 2283 // The ProfileCounter has side-effects and must occur precisely where located
duke@435 2284 pin();
duke@435 2285 }
duke@435 2286
duke@435 2287 Value mdo() { return _mdo; }
duke@435 2288 int offset() { return _offset; }
duke@435 2289 int increment() { return _increment; }
duke@435 2290
iveresov@1939 2291 virtual void input_values_do(ValueVisitor* f) { f->visit(&_mdo); }
duke@435 2292 };
duke@435 2293
duke@435 2294
duke@435 2295 class BlockPair: public CompilationResourceObj {
duke@435 2296 private:
duke@435 2297 BlockBegin* _from;
duke@435 2298 BlockBegin* _to;
duke@435 2299 public:
duke@435 2300 BlockPair(BlockBegin* from, BlockBegin* to): _from(from), _to(to) {}
duke@435 2301 BlockBegin* from() const { return _from; }
duke@435 2302 BlockBegin* to() const { return _to; }
duke@435 2303 bool is_same(BlockBegin* from, BlockBegin* to) const { return _from == from && _to == to; }
duke@435 2304 bool is_same(BlockPair* p) const { return _from == p->from() && _to == p->to(); }
duke@435 2305 void set_to(BlockBegin* b) { _to = b; }
duke@435 2306 void set_from(BlockBegin* b) { _from = b; }
duke@435 2307 };
duke@435 2308
duke@435 2309
duke@435 2310 define_array(BlockPairArray, BlockPair*)
duke@435 2311 define_stack(BlockPairList, BlockPairArray)
duke@435 2312
duke@435 2313
duke@435 2314 inline int BlockBegin::number_of_sux() const { assert(_end == NULL || _end->number_of_sux() == _successors.length(), "mismatch"); return _successors.length(); }
duke@435 2315 inline BlockBegin* BlockBegin::sux_at(int i) const { assert(_end == NULL || _end->sux_at(i) == _successors.at(i), "mismatch"); return _successors.at(i); }
duke@435 2316 inline void BlockBegin::add_successor(BlockBegin* sux) { assert(_end == NULL, "Would create mismatch with successors of BlockEnd"); _successors.append(sux); }
duke@435 2317
duke@435 2318 #undef ASSERT_VALUES

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